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Summary of Content
FOREWORD This manual includes theory of operation and procedures for diagnosis, maintenance and adjustments, minor service operations, and removal and installation for components of Chevrolet Light Duty Trucks. Procedures involving dis­ assembly and assembly of major components for these vehicles are contained in the 1973 Chevrolet Passenger Car and Light Duty Truck Overhaul Manual. Wiring diagrams for 1973 trucks are contained in a separate Wiring Diagram Booklet. The Section Index on the contents page enables the user to quickly locate any desired section. At the beginning of each section containing more than one major subject is a Table of Contents, which gives the page number on which each major subject begins. An Index is placed at the beginning of each major subject within the section. Summaries of Special Tools, when required, are found at the end of major sections while specifications covering vehicle components are presented at the rear of the manual. This manual should be kept in a handy place for ready reference. If properly used, it will enable the technician to better serve the owners of Chevrolet vehicles. All information, illustrations and specifications contained in this literature are based on the latest product information available at the time of publication approval. The right is reserved to make changes at any time without notice. CHEVROLET MOTOR DIVISION General Motors Corporation DETROIT, MICHIGAN IMPORTANT SAFETY NOTICE Proper service and repair is important to the safe, reliable operation of all motor vehicles. The service procedures recommended and described in this service manual are effective methods, for performing service operations. Some of these service operations require the use of tools specially designed for the purpose. The special tools should be used when and as recommended. # It is important to note that some warnings against the use of specific service methods that can damage the vehicle or render it unsafe are stated in this service manual. It is also important to understand these warnings are not exhaustive. We could not possibly know, evaluate and advise the service trade of all conceivable ways in which service might be done or of the possible hazardous consequences of each way. Consequently, we have not undertaken any such broad evaluation. Accordingly, anyone who uses a service procedure or tool which is not recommended by the manufacturer must first satisfy himself thoroughly that neither his safety nor vehicle safety will be jeopardized by the service method he selects. S E C T IO N IN D E X SECTION 0 1A IB 2 3 4 5 6 6K 6M 6T 6Y 7 8 9 10 11 12 13 14 15 1973 LIGHT DUTY TRUCK (SERIES 10-30) SERVICE MANUAL NAME GENERAL INFORMATION AND LUBRICATION HEATER AND AIR CONDITIONING BODY FRAME FRONT SUSPENSION 4-WHEEL DRIVE REAR SUSPENSION AND DRIVELINE BRAKES ENGINE ENGINE COOLING FUEL SYSTEM EMISSION CONTROL SYSTEMS ENGINE ELECTRICAL CLUTCH AND TRANSMISSION FUEL TANK AND EXHAUST SYSTEM STEERING WHEELS AND TIRES CHASSIS SHEET METAL ELECTRICAL— BODY AND CHASSIS RADIATOR AND GRILLE BUMPERS ACCESSORIES SPECIFICATIONS © 1972 General Motors Corporation Printed in U.S.A. GENERAL IN F O R M A T IO N A N D L UBRICATION 0-1 SECTION 0 GENERAL INFORMATION AND LUBRICATION CONTENTS OF THIS SECTION I General Inform ation........................................................................ 0-1 Lubrication........................................................................................... 0-12 GENERAL INFO RM ATIO N INDEX Model Line U p ................................................................. .....0-1 Truck Model Designation............................................... .....0-1 Vehicle Identification Number and Rating Plate .........0-1 Engine Number................................................................. .....0-2 Unit and Serial Number Locations ............................ .....0-2 MODEL LINE UP The 10 through 35 Series truck model line-up for 1973 consists of the models shown in the Charts in this section. Truck Model Designation A five digit number preceded by a letter is used to designate truck models. For example, vehicle C 10703 would be: Conventional C, 4500 lbs.-6800 lbs. GVW _l_j 42 in. -47 in. Cab-to-Axle dimension 07, Chassis cab 03, as listed below. Service Parts Identification Plate .................. ...................0-2 Keys and Locks ................................................ ...................0-3 Emergency Starting .......................................... ...................0-3 Towing.................................................................. ...................0-4 Load Capacity Chart ...................................... ...................0-4 08 - 48-53 in. 09 - 54-59 in. 10 - 60-65 in. 14 - 84-89 in. Fourth and Fifth Numbers-Body Styles C - Conventional (Conventional Cab, Suburban) G - Light Duty Forward Control K - Four-Wheel Drive P - Forward Control Pickup boxes, tailgate and drop glass, van bodies, and trim are options. 03.- Cab 05 - Van (windowless) 06 - Suburban and Van (with windows) 14 - Utility 32 - Motor Home Chassis 42 - Forward Control Chassis 63 - Four-Door Crew Cab First Number-GVW Range VEHICLE IDENTIFICATION NUMBER AND RATING PLATE First Letter • Chassis J_- 4500-7150 lbs. 2 - 5500-8200 lbs. 3 - 6200-14000 lbs. Second and Third NumbersCab-To-Axle Dimension 05 - 30-35 in. 07 - 42-47 in. A combination vehicle identification number and rating plate used on all models (fig. 1) is located on the left door pillar, except on School Bus, and some Forward Control Motor Home models. On School Bus models the plate is attached to the air intake plenum panel. On Forward Control models (P10, P20, P30 except P30 Motor Home Chassis) it is attached to the dash and toe panel. The vehicle identification num ber stamped on the plate decodes into the information shown in Figure 2. LIGHT DUTY TRUCK SERVICE MANUAL 0 -2 GENERAL IN F O R M A TIO N A N D LU B R IC A TIO N ENGINE DESIGNATION ENGINE NUMBER The engine number indicates manufacturing plant, month and day of manufacture, and transmission type. A typical engine number would be F1210TFA, which would breakdown thus: F - M anufacturing Plant (F-Flint, T-Tonawanda) 12 - Month of Manufacture (December) 10 - Day of Manufacture (tenth) T - Truck FA - Transmission and engine type UNIT AND SERIAL NUMBER LOCATIONS For the convenience of service technicians and engineers when writing up certain business papers such as W arranty Reports, Product Information Reports, or reporting product failures in any way, the location of the various unit numbers have been indicated. These unit numbers and their prefix or suffix are necessary on these papers for various reasons - such as accounting, followup on production, etc. The prefixes on certain units identify the plant in which the unit was manufactured and thereby permits proper follow-up of the plant involved to get corrections made when necessary. Always include the prefix in the number. Axles • Series 10 Rear Axle Serial Number Located at the Bottom Flange of Carrier Housing. • Series 20-30 Rear Axle Located at the Forward Upper Surface of Carrier. Transmissions • 3-Speed Transmission Unit Number Located on Lower Left Side of Case Adjacent to Rear of Cover. • 4-Speed Transmission Unit Num ber Stamped on Rear of Case, Above Output. w G E N E R A L M O T O R S C O R P O R A T IO N w WARRANTY MAY BE VOIDED IF WEIGHT EXCEEDS ANY OF RATINGS SHOWN. GROSS VEHICLE WEIGHT INCLUOES WEIGHT OF BASE TRUCK, ALL ADOED EQUIPMENT, DRIVER AND PASSENGERS, AND ALL PROPERTY LOADED INTO TRUCK. * REFER TO OWNERS MANUAL FOR EQUIPMENT REQUIRED FOR INTERMEDIATE ORMAXIMUM GVW RATINGS, AND FOR OTHER LOADING INFORMATION, INCLUDING TIRE INFLATION. DIVISION Q = L6-2 5 0 T = L 6-292 X = V8 Y = V8 Z — V8 MODEL YEAR C = CHEVROLET T = GMT 3 = 1973 fo r all Series. SEQUENTIAL NUMBER CHASSIS T Y P E C = 2 WHEEL DRIVE G = L IG H T DUTY FO RW ARD CO NTRO L K = 4 WHEEL DRIVE P = FO RW AR D C O NTRO L BODY 2-Forw ard Control chassis only 3-Cab-chassis 4-C a b a n d pickup 5-F orw ard Control chassis only (S teel-A lum inum 6-S ub urban body ASSEMBLY PLANT A -L ak ew o o d STYLE B -B altim ore C-So uth gate D -D o raville F-Flint box G -F ra m in g h a m J-Janesville K-Leeds Body) L-Van N uys N -N o rw o o d V -G M Truck-Pontiac R -A rlington S-St. Louis T-Tarrytow n U-Lordstown W -W illo w Run Y -W ilm in g to n Z-Frem ont 1-Oshawa 2-Ste. Therese 7-Forw ard Control (Rec. Vehicle Chassis) 8-U tility (Blazer) Fig. 2—Vehicle Identification Number • Turbo Hydra-Matic 350 Transmission Unit Number Located on Right Rear Vertical Surface of Oil Pan. • The Turbo Hydra-Matic Transmission 400 Serial Number is Located on the Light Blue Plate on the Right Side of the Transmission. Engines • 6-Cylinder Engine Right Hand Side Distributor. • 8-Cylinder Engine Front, Right Hand Unit N um ber Located on Pad at of Cylinder Block at Rear of Unit N um ber Located on Pad at Side of Cylinder Block. Deicotrons Delcotron Unit Serial Num ber Located at Top of Rear Housing. Batteries Battery Code Number Located on Cell Cover Top of Battery. RATINGS IN POUNDS - AS MANUFACTURED *MAXIMUM CAPABILITY GROSS VEH IC LE W EIGHT FOR THIS VEHICLE MAXIMUM FR O N T END W EIGHT AT GROUND Starters Starter Serial N um ber and Production Date Stamped on Outer Case, Toward Rear. M AXIMUM R EA R END W EIGHT AT GROUNO VEHIC LE IDENTIFIC ATIO N NO. v! Fig. 1—Vehicle Identification Number and Rating Plate Information SERVICE PARTS IDENTIFICATION PLATE The Service Parts Identification Plate (fig. 3) is provided on all Truck models. On most series it will be located on the inside of the glove box door, or, on Forward Control series, it will be located on an inner body panel. The plate lists the vehicle serial number, wheelbase, and all Production options or Special Equipment on the vehicle LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N AND LUBRICATION SERVICE IN . ■ NOTE: ■ ■ ■ ■ P A R TS ■ I D E N T I F I C A T I O N ____________ W /B A S E ■ ■ ■ S E B B H B V I N —VEHICLE IDENTIFICATION NUMBER T H E S P E C IA L E Q U IP M E N T L IS T E D B E L O W H A S BEEN IN S T A L L E D ON IMPORTANT: RETAIN THIS PLATE AS A PERMANENT RECORD Fig. 3—Service Parts Identification Plate when it was shipped from the factory including paint information. ALWAYS REFER TO THIS INFORM ATIO N WHEN ORDERING PARTS. KEYS AND LOCKS Two keys are provided with each vehicle. Different lock cylinders operated by a separate key are available as an option for the sliding side load door and rear load doors. EMERGENCY STARTING • Never tow the vehicle to start because the surge forward when the engine starts could cause a collision with the tow vehicle. • Engines in vehicles with automatic transmissions cannot be started by towing or pushing the vehicle. • To start the vehicle when the Energizer (battery) is discharged, use a single auxiliary battery or Energizer of the same nominal voltage (12 volts) as the discharged battery, with suitable jum per cables. • Make connections as set forth below under "Jump Starting With Auxiliary (Booster) Battery" to lessen the chance of personal injury or property damage. CAUTION: Never expose battery to open flame or electric spark-battery action generates hydrogen gas which is flammable and explo­ sive. Don’t allow battery fluid to contact skin, eyes, fabrics, or painted surfaces-fluid is a sulfuric acid solution which could cause serious personal injury or property damage. Wear eye protection when working with battery. 0-3 discharged batteries. Lay a cloth over the open vent wells of each battery. These two actions help reduce the explosion hazard always present in either battery when connecting "live" booster batteries to "dead" batteries. 3. Attach one end of one jum per cable to the positive terminal of the booster battery (identified by a red color, " + " or "P" on the battery case, post or clamp) and the other end of same cable to positive terminal of discharged battery Do NOT permit vehicles to touch each other, as this could establish a ground connection and counteract the benefits of this procedure. 4. Attach one end of the remaining negative(—) cable to the negative terminal (black color, or "N ") of the booster battery, and the other end to the engine lift bracket on 6 cylinder models and the delcotron mounting bracket on V-8 models (see Figure 4) (do not connect directly to negative post of dead battery)-taking care that clamps from one cable do not touch the clamps on the other cable. Do not lean over the battery when making this connection. Reverse this sequence exactly when removing the jumper cables. Re-install vent caps and throw cloths away as the cloths may have corrosive acid on them. CAUTI0N:^4/iy procedure other than the above could result in: (1) personal injury caused by electrolyte squirting out the battery vents, (2) personal injury or property damage due to battery explosion, (3) damage to the charging system of the booster vehicle or of the immobilized vehicle. L 6 ENGINE Jump Starting With Auxiliary (Booster) Battery Both booster and discharged battery should be treated carefully when using jum per cables. Follow exactly the procedure outlined below, being careful not to cause sparks: 1. Set parking brake and place automatic transmission in "PARK" (neutral for manual transmission). Turn off lights, heater and other electrical loads. 2. Remove vent caps from both the booster and the V 8 ENGINE Fig. 4—Booster Battery Cable Ground Connection LIGHT DUTY TRUCK SERVICE MANUAL 0 -4 GENERAL IN F O R M A T IO N A N D LUBRICATIO N PUSH STARTING If your truck is equipped with a manual 3-speed or 4-speed transmission, it can be started in an emergency by pushing. When being pushed to start the engine, turn off all unnecessary electrical loads, turn ignition to "O N ," depress the clutch pedal and place the shift lever in high gear. Release the clutch pedal when speed reaches 10 to 15 miles per hour. Bumpers and other parts contacted by the pushing vehicle should be protected from damage during pushing. Never tow the truck to start. TOWING All Except Four Wheel Drive Trucks Normally your vehicle may be towed with all four wheels on the ground for distances up to 50 miles at speeds of less than 35 MPH. The engine should be off and the transmission in neutral. However, the rear wheels must be raised off the ground or the drive shaft disconnected when the transmission is not operating properly or when a speed of 35 MPH or distance of 50 miles will be exceeded. CAUTION: I f a truck is towed on its front wheels only, the steering wheel must be secured with the wheels in a straight ahead position. Four Wheel Drive Trucks It is recommended that the truck be towed with the front wheels off the ground. The truck can be towed, however, with the rear wheels off the ground if there is damage in the rear wheel area. In this event, the transmission selector lever should be placed in the "N " (neutral) position and with conventional four wheel drive the front drive disengaged. With Full Time four wheel drive the transfer case should be in high. Towing speeds LOAD CAPACITY Ch The first column of the Load Capacity Chart on the following pages shows the basic model series. The next column reflects the wheelbases available within each series. The third column shows the Gross Vehicle Weight (GVW) rating applicable to each series vehicle. GVW means the maximum design weight of the vehicle including the vehicle itself and all equipment added to the vehicle after it has left the factory, the driver weight and occupant weight and everything that is loaded into or onto the vehicle. Following the GVW columns are the minimum recommended tires to qualify the vehicle for each GVW rating. should not exceed 35 MPH for distances up to 50 miles. If truck is towed on its front wheels, the steering wheel should be secured to keep the front wheels in a straight­ ahead position. When towing the vehicle at slow speeds (approx. 20 MPH), for a very short distance only, the transmission must be in NEUTRAL and with conventional four wheel drive the transfer case M UST be in "T W O WHEEL H IG H " . With Full Time four wheel drive the transfer case should be in high. When towing the vehicle at faster speeds for greater distances, the following steps MUST be taken: • If front wheels are on the road, disconnect the front drive shaft. • If rear wheels are on the road, disconnect the rear drive shaft. STEEL TUBING REPLACEMENT In the event that replacement of steel tubing is required on brake line, fuel line, evaporative emission, and transmission cooling lines, only the recommended steel replacement tubing should be used. Only special steel tubing should be used to replace brake line. That is, a double wrapped and brazed steel tubing meeting G.M. Specification 123 M. Further, any other steel tubing should be replaced only with the released steel tubing or its equivalent. Under no condition should copper or aluminum tubing be used to replace steel tubing. Those materials do not have satisfactory fatigue durability to withstand normal vehicle vibrations. All steel tubing should be flared using the upset (double lap) flare method which is detailed in Section 5 of this Manual. \T INTERPRETATION The tire pressures listed in the column adjacent to the tire sizes in the chart are the minimum required tire pressures for maximum permissible loads. The letter under the Front and Rear Axle and Spring columns indicates that base equipment is satisfactory to qualify the vehicle for any given GVW rating. When the letters "RPO" denoting Regular Production Option, followed by a number appears in these columns (example RPO G50), the vehicle must be equipped with the extra cost equipment specified by the RPO to qualify the vehicle for the given GVW rating. In loading the vehicle, the combined front and rear end weights at the ground must not exceed the GVW specified for the vehicle as manufactured. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A ND LUBR IC A TION LOADED-MAXIMUM GVW: 6000-LBSFRONT AXLE CAPACITY: 3250 LBS. Front Curb Front Cargo Load 2100 lbs. 400 lbs. 2500 lbs. REAR AXLE CAPACITY: 3582 LBS. Rear Curb Rear Cargo Load 0-5 In trailer hauling applications, the vehicle rear end weight at the ground with trailer attached must not exceed the "Maximum Rear End Weight at Ground" rating of the vehicle. A typical example of a Truck in a loaded condition is shown in Figure 5. Note that the axle or GVW capabilities are not exceeded. 1585 lbs. 1915 lbs3500 lbs. TOTAL WEIGHT AT GROUND: 6000 lbs. Fig. 5—Typical Vehicle Loaded Condition LIGHT DUTY TRUCK SERVICE MANUAL . 4 0 6 GENERAL IN F O R M A T IO N A N D LUBRICATIO N LOAD CAPACITY CHART W HEEL BASE C l0514 and C10514 + Z58 or Z59 C l0703 Cab Chassis C10703 + E62 or E63 ickups C10903 Cab Chassis C10903 + E62 or E63 Pickups 106.5 • 117.5 • 117.5 • 131.5 • 131.5 C10906, and C10906 + E55 Suburbans 129.5 C20903 Cab Chassis 131.5 C20903 + E62 or E63 Pickups 131.5 C20906, and C20906 + E55 Suburbans C20963 Crew Cab Chassis C20963 + E63 GROSS V EHICLE W EIGHT RATING (POUNDS)* 129.5 4900 5200 5700 4900 5400 6000 4900 5400 6000 4900 5400 6000 4900 5400 6000 5400 6000 6800 6400 7500 8200 6400 7500 8200 6650 7500 8200 FRONT T IR E PRES­ SURE FRONT TIR ES E78-15B G78-15B H78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15D 8.75-16.5C 9.50-16.5D 9.50-16.5D 8.57-16.5C 9.50-16.5D 9.50-16.5D 8.75-16.5C 9.50-16.5D 9.50-16.5D b b b b b b b b b 30 32 32 32 30 28 32 30 28 32 30 28 32 30 28 32 30 30 40 30 30 40 30 30 40 30 30 REAR TIRES E78-15B G78-15B H78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15D 8.75-16.5C 9.50-16.5D 9.50-16.5D 8.57-16.5C 9.50-16.5D 9.50-16.5D 8.75-16.5C 9.50-16.5D 9.50-16.5D M INIMUM M A N D A T O R Y E Q U IP M E N T F O R GVW R A T IN G GROSS REAR AXLE W EIGHT TIR E FRONT FRONT REAR PRES RATIN G AXLE SPRINGS FRONT* AXLE SURE b b b b b b b b b 30 32 32 32 30 32 32 30 32 32 30 32 32 30 32 32 32 36 45 55 60 45 55 60 45 55 60 3250 3250 3250 3100 3100 3250 3100 3100 3250 3100 3100 3250 3100 3100 3250 3100 3100 3250 3800 3800 3800 3800 3800 3800 3800 3800 3800 b b b b b b b b b b b b b b b b b b b b b b b b b b b 3100 b 3100 b 3250 F60 3100 b 3100 b 3250 F60 3100 b 3100 b 3250 F60 3100 b 3100 b 3250 F60 3100 b 3100 b 3250 F60 3100 b 3250 F60 3250 F60 3500 b 3500 b 3800 F60 3500 b 3500 b 3800 F60 3500 b 3500 b 3800 F60 2546 2946 3218 2946 3100 3250 2946 3100 3250 2946 3100 3250 2946 3100 3250 2946 3100 3250 3500 3500 3800 3500 3500 3800 3500 3500 3800 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 5700 5700 5700 5700 5700 5700 5700 5700 5700 b b b b b b b b b b b b b b b b b b b b b b b b b b b REAR SPRINGS GROSS AXLE W EIGHT RATING REAR* 3000 b 3000 b 3400 G50 3100 b 3100 b 4000 G50 3100 b 3100 b 4000 G50 3100 b 3100 b 4000 G50 3100 b 3100 b 4000 G50 3100 b 4000 G50 4000 G50 4000 b 5200 G50 5700 G51 4000 b 5200 G50 5700 G51 4000 b 5200 G50 5700 G51 2546 2946 3218 2946 3100 3582 2946 3100 3582 2946 3100 3582 2946 3100 3582 2946 3218 3750 3980 5200 5560 3980 5200 5560 3980 5200 5560 164.5 8200 9.50-16.5D b 35 9.50-16.5D b 60 3800 b 3800 b 3800 7500 b 5700 b 5560 164.5 8200 9.50-16.5D b 35 9.50-16.5D b 60 3800 b 3800 b 3800 7500 b 5700 b 5560 6600 8200 9000 6600 8200 9000 8.75-16.5C b 9.50-16.5D 9.50-16.5D 8.75-16.5C b 9.50-16.5D 9.50-16.5D 40 30 35 40 30 35 8.75-16.5C b 9.50-16.50 9.50-16.5E 8.75-16.5C b 9.50-16.5D 9.50-16.5E 45 60 75 45 60 75 3800 3800 3800 3800 3800 3800 3500 b 3500 b 3800 F60 3500 b 3500 b 3800 F60 3500 3500 3800 3500 3500 3800 7500 7500 7500 7500 7500 7500 4800 b 5700 G50 7000 G51 4800 b 5700 G50 7000 G51 3980 5560 6340 3980 5560 6340 C30903 Cab Chassis w ith single rear wheels 131.5 C30903 + E62 or E63 Pickups 131.5 b b b b b b b b b b b b REQUIRED OPTIONS J70 J70 J70 J70 J70 J70 J70 J70 AS3 or A T 5 * Refer to the Gross Vehicle Weight Rating plate on the vehicle. Gross A xle Weight Rating-Front, and Gross A xle Weight Rating-Rear on this chart are based upon component m inim um capacity o f axles, springs, or tires. b = base equipment RESTRICTIONS C10703-10903 and C10703-10903 + E62 or +63, w ith LF8 V8 engines on 4900 GVWR vehicles: RPO J70 power brakes required. C10906 and C10906 + E55: RPO A T5 not available on 5400 GVW. When RPO A T 5 is used on 6000 GVWR, RPO F60 is required. RPO AS3 available o nly on 6800 GVWR vehicles, AS3 requires F59. When RPO AS3 or A T 5 are not specified, GVWR is restricted to 5400 or 6000. L78-15 and 9.50-16.5 tires: Heavy d u ty wheels are required w ith these tires, and are included when installed at the factory. For detailed inform atio n , see tire and wheel restrictions in "O w ner’s and D river’s Manual". * - 5 3 0 0 GVW avail, these models w ith J70 Power Brakes add requirement. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A N D LUBRICATION 0-7 LOAD CAPACITY CHART 1973 M O D E L S C31003 Cab Chassis w ith single rear wheels C31403 Cab Chassis w ith single rear wheels C30903 + E63 Pickup w ith dual rear wheels C31003 Cab Chassis w ith dual rear wheels C31403 Cab Chassis w ith dual rear wheels C30963 Crew Cab chassis w ith W HEEL­ BASE 135.5 159.5 131.5 135.5 159.5 GROSS VEHICLE W EIGHT RATIN G (POUNDS)* M INIM UM M A N D A T O R Y E Q U I P M E N T F O R GVW R A T IN G GROSS REAR AXLE TIR E W EIGHT PRES FRONT FRONT RATING REAR SURE AXLE SPRINGS FRONT* AXLE FRONT TIR ES FRONT TIR E PRES SURE REAR TIR ES 6600 8200 9000 6600 8200 9000 8.75 16.5C b 9.50 16.5D 9 50-16.5D 8.75-16.5C b 9.50-16.5D 9.50-16.5D 40 30 35 40 30 35 8.75-16.5C b 9.50-16.5D 9.50-16.5E 8.75 16.5C b 9.50-16.5D 9.50-16.5E 10000 8.75-16.5C b 45 8.75-16.5C b 8000 9000 10000 8000 9000 10000 7.00-16C 7.00-16C 7.50-16C 7.00-16C 7.0016C 7.50-16C 45 45 45 45 45 45 7.00-16C 7.00-16C 7.50-16C 7.00-16C 7.00- 16C 7.50 16C b b b b b b b b 45 60 75 45 60 75 3800 3800 3800 3800 3800 3800 REAR SPRINGS GROSS AXLE W EIGHT RATIN G REAR * 4800 b 5700 G50 7000 G51 4800 b 5700 G50 7000 G51 3980 5560 6340 3980 5560 6340 b b b b b b 3500 b 3500 b 3800 F60 3500 b 3500 b 3800 F60 3500 3500 3800 3500 3500 3800 45 3800 b 3800 F60 3800 7500 Ft 05 7500 G60 7000 40 45 45 40 45 45 3800 3800 3800 3800 3800 3800 3500 b 3800 F60 3800 F60 3500 b 3800 F60 3800 F60 3500 3600 3800 3500 3600 3800 7500 7500 7500 7500 7500 7500 5700 b 7000 G51 7500 G60 5700 b 7000 G51 7500 G60 5700 6320 7260 5700 6320 7260 b b b b b b 7500 7500 7500 7500 7500 7500 b b b b b b R05 R05 R05 R05 R05 R05 164.5 9000 9.50-16.5E b 35 9.50-16.5E b 75 3800 b 3800 b 3800 7500 b 7000 G51 6340 164.5 9000 9.50 16.5E b 35 9.50-16.5E b 75 3800 b 3800 F60 3800 7500 b 7000 G51 6340 164.5 10000 8.75-16.5C b 45 8.75-16 5C b 45 3800 b 3800 F60 3800 7500 R05 7500 G60 7000 164.5 10000 8 75-16.5C b 45 8.75 16.5C b 45 3800 b 3800 F60 3900 7500 R05 7500 G60 7000 REQUIRED OPTIONS LS9 or LF8 single rear wheels C30963 + E63 w ith single rear wheels C30963 Crew Cab chassis w ith dual rear wheels C30963 + E63 w ith dual rear wheels Refer to the Gross Vehicle Weight Rating plate on the vehicle. Gross A xle Weight R ating-Front, and Gross A xle Weight Rating-Rear on this chart are based upon component m inim um capacity o f axles, springs, or tires, b = base equipment. LIGHT DUTY TRUCK SERVICE MANUAL r r — tf-8 GENERAL IN F O R M A T IO N A N D LU BR IC A TIO N LOAD CAPACITY CHART 1973 M O D E L S +Z58 or +Z59 K10703 Cab Chassis (Not Merchandised) W HEEL­ BASE 106.5 117.5 K10703 + E62 or E63 Pickups 117.5 K 10903 Cab Chassis (Not Merchandised) 131.5 K 10903 + E62 or E63 Pickups K 10906, and K10906 + E55 131.5 129.5 GROSS VEHICLE W EIGHT R A TIN G (POUNDS) # 4900 5350 5800 6200 5200 5600 6000 5200 5600 6000 5200 5600 6000 5200 5600 6000 5600 6000 6600 7150 6800 K20903 Cab Chassis 131.5 7500 8200 6800 K20903 + E62 or E63 Pickups 131.5 7500 8200 6800 K20906, and K 2 0 9 0 6 + E55 Suburbans 129.5 7500 8200 MINIMUM M A N D A T O R Y EQ U IP M EN T FO R GVW R A T IN G GROSS REAR AXLE TIR E W EIGHT PRES­ FRONT FRONT RATING REAR REAR SURE AXLE SPRINGS F R O N T * AXLE SPRINGS FRONT TIR E FRONT TIRES E78-15B G 78 1 5B H78-15B H78-15B G78-15B H78-15B L 7815B G78 15B H78-15B L78-15B G78-15B H78-15B L 7815B G 7815B H78 15B L78-15B G 7815B H78 15B L78-15B L78-15D 8.75 16.5C or 7.50-16C 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50 16C 8.75-16.5C or 7.50-16C 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50 16C 8.75 16 5C or 7.50 16C 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50-16C PRES­ SURE b b b b b b b b b b 32 32 32 32 . 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 40 40 40 40 30 40 40 40 40 40 30 40 40 40 40 40 30 40 REAR TIRES E78-15B G 78 1 5B H 7815B H78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B G78-15B H78-15B L78-15B L78-15D 8.75-16.5C or 7.50-16C 8.75-16.5D or 7.50-16D 9.50-16.5D or 7.50-16E 8,75-16.5C or 7.50-16C 8.75-16.5D or 7.50 16D 9.50-16.5D or 7.50-16E 8.75-16.5C or 7.50 16C 8.75-16.5D 7.50-16D 9.50-16.5D 7.50-16E b b b b b b b b b b 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 36 45 45 60 60 60 75 45 45 60 60 60 75 45 45 60 60 60 75 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3400 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b 3300 3300 3300 3300 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 3700 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b 2546 2946 3218 3218 2946 3218 3400 2946 3218 3400 2946 3218 3400 2946 3218 3400 2946 3218 3400 3400 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3500 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 3750 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b GROSS AXLE W EIGHT R A TIN G REAR * 3400 b 3400 b 3400 b 3400 b 3400 b 3400 b 4000 G50 3400 b 3400 b 4000 G50 3400 b 3400 b 4000 G50 3400 b 3400 b 4000 G50 4500 b 4500 b 4500 b 4500 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 5600 b 2546 2946 3218 3218 2946 3218 3582 2946 3218 3582 2946 3218 3582 2946 3218 3582 2946 3218 3582 3750 3980 4120 4700 4880 5560 5560 3980 4120 4700 4880 5560 5560 3980 4120 4700 4880 5560 5560 REQUIRED OPTIONS F58 AS3, F58 F58 F58 F58 F58 F58 F58 F58 A T 5, F58 F58, A T5 F58 F58 F58 F58 F58 F58 F58 F58 F58 F58 F58 F58 'R e fe r to the Gross Vehicle Weight Rating plate on the vehicle. Gross A xle Weight Rating-Front, and Gross A xle Weight Rating Rear on this chart are based upon component m inim um capacity o f axles, springs, or tires. b = base equipment RESTRICTIONS K10514 and K10514 + Z58 or Z59 RPO AS3 rear seat not available on 4900 GVWR vehicles. K 10906 and K10906 + E55 RPO A T5 or AS3 not available on 5600 GVWR models RPO AS3 not available on 6000 GVWR models L78-15 and 9.50-16.5 Tires Heavy d uty wheels are required w ith these tires, and are included when installed at the factory. For detailed inform ation, see tire and wheel restrictions in "O wner's and Driver's Manual". LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A N D LUBRICATION 0 -9 LOAD CAPACITY CHART GROSS VEHICLE 1973 M O D E L S W HEEL BA SE P10542 Forward Control Chassis 102 P10542+ E32 Forward Control w ith steel body 102 W EIGHT RATING (POUN DS)* 4900 5200 5600 6000 4900 5200 5600 6000 6800 P20842 P21042 Forward Control chassis 125 133 P20842, P21042 Forward Control + E32 (steel body), or + E33 (aluminum body) 125 133 P30842, P31042, P31442 Forward Control chassis w ith single rear wheels 125 133 157 7500 8000 6800 7500 8000 7600 8200 9000 9000 P30842, P31042, P31442 Forward Control chassis with dual rear wheels 125 133 157 P30842, P31042, P31442 Forward Control + E32 (steel body), or + E33 (aluminum body), w ith single rear wheels. 125 133 157 P30842, P31042, P31442 forward Control + E32 (steel body), or + E33 (aluminum body) w ith dual rear wheels. 125 133 157 10000 12000 14000 7600 8200 9000 9000 10000 12000 14000 M I N I M U M M A N D A T O R Y E Q U I P M E N T F O R G VW R A T I N G G R OS S REAR AXLE TIR E W EIGHT PRES­ FRONT RATING REAR REAR FRONT AXLE SURE AXLE S PR I N G S F R O N T * SPRINGS FRONT TIR E FRONT TIR ES G 7815B G78-15B H78-15B L78-15B G78-15B G78-15B H78-15B L78-15B 8.75-16.5C or 7.50-16C 8.75-16.5C or 7.50 16C 9.50-16.5D or 7.50-16C 8.75-16.5C or 7.50-16C 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50-16C 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50-16C 9.50-16.5D 8.00-16.5D or 7.50 16C 8.00-16.5D or 7.50-16C 7.00-18D 8-19.5D 8.75-16.5C or 7.50-16C 9.50-16.5D or 7.50-16C 9.50-16.5D 8.00-16.5D or 7.50-16C 8.00-16.50 or 7.50-16C 7.00-18D 8-19.5D PRES­ SURE b b b b b b 32 32 32 26 32 32 32 26 40 40 40 40 30 40 40 40 40 40 30 40 45 45 35 45 35 60 45 60 45 55 50 45 45 35 45 35 60 45 60 45 55 50 REAR TIR ES G 78 1 5B G78-15B H78-15B L78-15B G78-15B G78-15B H78-15B L78 15B 8.75-16.5C or 7.50-16C 8.75-16.5D or 7.50-16D 9.50-16.5D or 7.50-16E 8.75-16.5C or 7.50-16C 8.75-16.5D or 7.50-16D 9.50-16.5D or 7.50-16E 8.75-16.5D or 7.50-16D 9.50-16.5D or 7.50-16E 9.50-16.5E 8.00 16.5D or 7.50 16C 8 00 16.5D or 7.50-16C 7.00-18D 8-19.5E 8.75 16.5D or 7.50-16D 9.50-16.5D or 7.50-16E 9.50 16.5E 8.00 16.5D or 7.50-16C 8.00-16.5D or 7.50-16C 7.00-18D 8-19.5E b b b b b b 32 32 32 32 32 32 32 32 45 45 60 60 60 75 45 45 60 60 60 75 60 60 60 75 65 60 45 60 45 65 80 60 60 60 75 65 60 45 60 45 65 80 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 3700 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 H22 4000 H22 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 b 4000 H22 4000 H22 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3100 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 3600 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 H22 4400 H22 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 b 4400 H22 4400 H22 2946 2946 3100 3100 2946 2946 3100 3100 3600 3600 3600 3600 3600 3600 3600 3600 3600 3600 3600 3600 3980 4000 4000 4000 4000 4000 4000 4000 4000 4000 4000 3980 4000 4000 4000 4000 4000 4000 4000 4000 4000 4000 3000 b 3500 b 3500 b 3000 b 4400 G50 3500 b 3500 b 4400 G50 3500 b 3000 b 3000 b 3500 b 4400 G50 3500 b 3500 b 4400 G50 4400 b 5700 b 5700 b 4400 b 5700 b 5700 G50 5700 G50 5700 b 5700 b 5700 G50 5700 b 5700 G50 5700 b 4400 b 4400 b 5700 b 5700 b 5700 G50 5700 G50 5700 b 5700 b 5700 G50 5700 G50 5700 b 7500 b 6200 b 7500 b 6200 b 7500 b 6200 b 7500 b 6200 b 6200 b 7500 b 6200 b 7500 R05 7500 R05 6200 b 8000 G60 7500 R05 8000 G60 7500 R05 11000 H22 11800 H22 11000 H22 11800 H22 6200 b 7500 b 6200 b 7500 b 7500 b 6200 b 6200 b 7500 b 7500 b 6200 b 6200 b 7500 R05 7500 R05 6200 b 8000 G60 7500 R05 8000 G60 7500 R05 11000 H22 11800 H22 11000 H22 11800 H22 * Refer to the Gross Vehicle Weight Rating plate on the vehicle. Gross Axle Weight Rating-Front, and Gross A xle Weight Rating-Rear on this chart are based upon component m inim um capacity of axles, springs, or tires. b. Base equipment. RESTRICTIONS L78-1 5 and 9.50-16.5 tires Heavy d uty wheels are required w ith these tires, and are included when installed at the factory. For detailed in form ation, see tire and wheel restrictions in "O wner's and Driver's Manual". RPO H22 rear axle When RPO LS9 (350 V8) is used instead of the 307 V8, RPO H23 is required, replacing H22. LIGHT DUTY TRUCK SERVICE MANUAL GROSS AXLE W EIGHT RATIN G REAR * 2946 2946 3218 3500 2946 2946 3218 3500 3980 4120 4700 4880 5560 5560 3980 4120 4700 4880 5560 5560 4700 4880 5560 5560 6200 6200 6200 7200 7260 9080 11000 4700 4880 5560 5560 6200 6200 6200 7200 7260 9080 11000 REQUIRED OPTIONS J70 J70 J70 J70 J70 J70 f /0 - 1 0 GENERAL IN F O R M A T IO N A N D LUBRIC ATIO N LOAD CAPACITY CHART 1973 M O D E L S W HEEL BA SE P30832, P31132, P31432 Forward Control M otor Home chassis w ith single rear wheels 125 137 158.5 P30832,P31132, P31432 Forward Control m otor home chassis w ith dual rear wheels. 125 137 158,5 P31432,P31832 Forward Control M otor home chassis w ith dual GROSS V EHICLE W EIGHT R ATIN G (POUNDS)* GROSS AXLE W EIGHT RA TIN G REAR * FRONT TIRES FRONT T IR E PRES­ SURE REAR TIR ES 8.75-16 5C b or 7.50-16C 9 50 16.5D 45 45 40 8.75 16.5D b or 7.50-16D 9.50-16 5E 60 60 65 4300 b 4300 b 4300 b 4400 b 4400 b 4400 b 4120 4300 7500 b 7500 b 7500 b 6200 b 6200 b 8.00-16.5D 60 45 8.00-16 5D or 7.50-16C 60 45 4300 b 4300 b 4400 b 4400 b 4090 4120 7500 R05 7500 R05 6200 b 6200 b 6200 o r 7.50-16C 10500 7.50-16D 45 7.50-16C 45 4300 b 4400 b 4300 7500 R05 6200 b 6200 11300 11800 7.50-16D 7.50-16D 50 50 7.50-16C 7.50-16D 45 50 4300 b 4300 b 4400 b 4400 b 4300 4300 7500 R05 7500 R05 7500 G50 7500 G50 7260 7500 14000 7.00-18D or 8-19.5D 75 65 7.00-18D or 8-19.5D 65 65 5000 HF7 5000 HF7 5000 HF7 5000 HF7 5000 5000 10000 HF7 10000 HF7 9500 HF7 9500 HF7 9080 9500 7600 9000 10100 158.5 178 MINIMUM M A N D A T O R Y EQ U IP M EN T FO R GVW R A T IN G GROSS REAR AXLE TIR E W EIGHT FRONT PRES FRONT RATIN G REAR REAR SURE AXLE SPRINGS F R O N T * AXLE SPRINGS 3980 6200 b REQUIRED OPTIONS 4700 4880 6200 6200 Refer to the Gross Vehicle Weight Rating plate on the vehicle. Gross A xle Weight Rating-Front, and Gross A xle Weight Rating-Rear on this chart are based upon component m inim um capacity of axles, springs, or tires. b. Base equipment. RESTRICTIONS 9.50-16.5 tires Heavy d uty wheels are required w ith these tires, and are included when installed at the factory. For detailed inform ation, see tire and wheel restrictions in "O wner's and Driver's M anual". RPO HF7 rear axle has a 4.56-to-1 gear ratio. RPO HF8, which has a 4.88-to-1 gear ratio, may be specified in place of HF7. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A N D LUBR IC A TION 0-11 LO A D C A P A C ITY C H A R T M I N I M U M M A N D A T O R Y E Q U I P M E N T F O R G VW R A T I N G G R OS S 1973 M O D E L S W HEEL B ASE VEHICLE W EIGHT RATIN G (P O U N D S ) * 4500 G11005 G11305 125 G31005 G31305 110 125 E78-14B 32 b 5000 F78-14B or 7.00- 14D 4600 F78-14B or 7.00-14C 32 60 32 45 32 60 32 32 32 32 45 35 35 45 45 45 35 35 45 45 5100 G21305 TIRES 45 125 110 FRONT or 7.00-14C 110 G21005 FRONT TIR E PRES SURE 5500 6000 5600 6000 6200 6900 7100 7700 8100 6400 7100 7300 7900 8300 F78-14B or 7.00-14D G78-15B H78-15B G78-15B H78-15B 8.00-16.5C 8.75-16.5C 8.75-16.5D 8.75-16.5D 8.75-16.5E 8.00-16.5C 8.75-16.5C 8.75-16.5D 8.75 16.5D 8.75-16.5E b b b b b TIRES REAR TIR E PRES­ SURE E78-14B b or 7.00-14C 40 REAR F78-14B or 7.00 14D F78-14B b or 7.00-14C F78-14B or 7.00-14D G78-15B b H78-15B G78-15B b H78-15B 8 .0 0 1 6 .5C b 8.75-16.5C 8.75-16.5D 8.75-16.5D 8.75-16.5E 8.00-16.5C b 8.75-16.5C 8.75-16.5D 8.75-16.5D 8.57-16.5E 32 32 60 32 /.0 32 60 32 32 32 32 45 45 50 60 75 45 45 50 60 75 GR OS S AXLE W EIGHT RATIN G FRONT * REAR AXLE REAR S PR I N G S GROSS1 AXLE W EIGHT R A TIN G REAR * 2546 2620 3100 b 3100 b 2300 b 2300 b 2300 2300 3100 F60 3100 F60 2620 b 2620 b 3100 F60 3100 F60 3200 b 3200 b 3200 b 2728 3000 2620 2620 3100 3100 3100 3100 3100 b b b b b 3200 G50 3200 G50 2300 b 2300 b 2728 3100 2300 2300 J70 J70 b b b b 3200 b 3400 b 3400 b 3400 b 3900 F60 3900 F60 3400 b 3400 b 3400 b 3900 F60 3900 F60 3200 3400 3400 3400 3900 3900 3400 3400 3400 3900 3900 3500 5700 5700 5700 5700 5700 5700 5700 5700 5700 5700 b b b b b b b b b b b 3200 G50 3200 G50 3200 b 3200 b 3200 b 3200 b 2728 3100 2946 3200 2946 3200 J70 3100 3500 3500 3500 4200 b 4200 b 4200 b 5500 G50 5500 G50 4200 b 4200 b 4200 b 5500 G50 5500 G50 3460 3980 4200 4700 5360 3460 3980 4200 4700 5360 FRONT AXLE FRONT S PR I N G S 3000 b 3000 b 2620 b 3000 3000 3000 3000 3000 3000 3200 3200 3200 3200 3900 3900 3900 3900 3900 3900 3900 3900 3900 3900 b b b b b b b b b b b b b b b b b b b b 2620 b 2728 3000 2946 3200 2946 REQUIRED OPTIONS J70 LS9, F59 LS9, F59 LO AD C A P A C IT Y C H A R T 1973 M O D E L S G 11006, and G 11006+ E94 G11306, and G11306 + E94 G21006, and G21006 + E94 G21306, and G21306 + E94 G31306, and G 3 1 3 0 6 + E94 W HEEL B A SE GROSS VEHICLE W EIGHT RATIN G (POUN DS)* FRONT TIR E PRES­ SURE FRONT TIR ES REAR TIR ES 3000 b 3100 b 2946 3100 b 3200 b 2946 32 32 32 32 3200 3200 3200 3200 3900 3900 3900 3900 3900 3200 b 3200 b 3200 b 3200 b 3400 b 3400 b 3400 b 3900 F60 3900 F60 2946 3200 2946 3500 b 3500 b 3500 b 3200 b 3200 b 3200 b 3200 3400 3400 3500 b 5700 b 5700 b 5700 b 5700 b 5700 b 3200 b 4200 b 4200 b 4200 b 5500 G50 5500 G50 2946 3200 2946 3200 32 45 35 35 45 45 H78-15B 8.00-16.5C 8.75-16.5C 8.75-16.5D 8.75-16.5D 8.75-16.5E 5400 G78-14B b 32 5700 G78 15B H78-15B b 32 G 78 1 5B H78-15B 8.00-16.5C 8.75-16.5C b 8.75-16.5D 8.75-16.5D 8.75-16.5E 32 32 32 125 7800 8300 2728 2946 b F78-14B G78-14B 125 3200 b 3200 b b 32 32 7100 7300 3100 b 3100 b G78-15B H78 15B G78-15B b b 2728 2946 G78-14B F78-14B G78-14B 125 3100 b 3100 b 32 32 5200 5400 b b GROSS AXLE W EIGHT RATING REAR * 3000 b 3000 b b 110 6000 5800 6200 6600 MINIM UM M A N D A T O R Y E Q U I P M EN T F O R GVW R A T IN G G RO S S AXLE REAR W EIGHT TIR E REAR REAR FRONT RATIN G PRES FRONT AXLE SPRINGS AXLE SPRINGS F R O N T * SURE 45 45 50 60 75 b b b b b b b b b 3400 3900 3900 3460 3980 4200 4700 5360 REQUIRED OPTIONS LS9, F59 ' Refer to the Gross Vehicle Rating plate on the vehicle. Gross Axle Weight Rating-Front, and Gross Axle Weight Rating-Rear on this chart are based upon component minim um capacity of axles, springs, or tires. b = base equipment. RESTRICTIONS G 11006 and G11006 + E94 RPO C62, C63 not available on 5200 GVWR models. G 11306+ E94 RPO C62, C63 not available. G21006 + E94 RPO C62, C63 not available on 5700 GVWR models having RPO AQ3. G21306 and G21306 + E94 RPO C62, C63 not available on 5800 GVWR models. RPO AQ3 not available on 5800 GVWR models. G21306 RPO C62, C63 not available on 5800 GVWR models w ith AQ3. G31306 and G31306 + E94 RPO AQ4 not available on 6600 GVWR models, 7800 and 8300 GVWR models, and RPO F60 (heavy duty fro n t springs), and RPO G50 (heavy d uty rear springs) are not recommended fo r normal passenger use LIGHT DUTY TRUCK SERVICE MANUAL 0 -1 2 GENERAL IN F O R M A T IO N A N D LUBRIC ATIO N LUBRICATION INDEX Maintenance Schedule........................................................ E ngine..................................................................................... Oil and Filter Recommendations................................ Drive Belts........................................................................... Positive Crankcase V entilation..................................... Air Injection Reactor System ....................................... Controlled Combustion System .................................... GM Evaporation Control System................................ Manifold Heat Control V alve...................................... Air Cleaner.......................................................................... Fuel Filter............................................................................ Distributor............................................................................ G overnor.............................................................................. Accelerator Linkage.......................................................... Automatic Transmission Fluid Recommendations... Manual Transmission......................................................... Transmission Shift Linkage............................................ Clutch...................................................................................... Rear Axle S tandard............................................................................... Positraction.......................................................................... Propeller Shaft Slip Joints.............................................. Universal Joints................................................................... 0-12 Wheel Bearings 0-12 Front....................................................................................... 0-12 R ear........................................................................................ 0-13 Brake Master Cylinder...................................................... 0-13 Brake and Clutch Pedal Springs................................... 0-13 Parking Brake....................................................................... 0-13 Steering 0-13 Manual Steering G ear..................................................... 0-13 Steering Linkage and Suspension................................ 0-14 Hood Latch and Hood H inge........................................ 0-14 Body Lubrication.................................................................. 0-14 Four Wheel Drive 0-14 Propeller Shaft Centering Ball..................................... 0-14 Front A xle........................................................................... 0-14 Air Vent H ose.................................................................... 0-14 Transfer Case...................................................................... 0-14 Control Lever and Linkage........................................... 0-14 Speedometer A dapter......................................................... 0-15 0-15 0-15 0-15 MAINTENANCE SCHEDULE »> A separate maintenance folder has been provided with each car which contains a complete schedule and brief explanation of the safety, emission control, lubrication and general maintenance it requires. The maintenance folder information is supplemented by this section of this manual, as well as the separate emission control systems folder also furnished with each car. Read all three publications for a full understanding of vehicle maintenance requirements. The time or mileage intervals for lubrication and maintenance services outlined in this section are intended as a general guide for establishing regular maintenance and lubrication periods. Sustained heavy duty and high speed operation or operation under adverse conditions may require more frequent servicing. ENGINE 0-15 0-15 0-15 0-15 0-15 0-15 0-16 0-16 0-16 0-17 0-17 0-17 0-17 0-17 0-17 Lubrication Diagrams Conventional and Forward Control Models............ 0-18 Four Wheel Drive M odels............................................. 0-19 1/2, 3/4 and 1 ton G Models..................................... 0-20 than 6,000 miles are driven in a 4-month period, change oil each 6,000 miles. • Change oil each 2 months or 3,000 miles, whichever occurs first, under the following conditions: —Driving in dusty conditions —Trailer pulling or camper use. —Frequent long runs at high speeds and high ambient temperatures. —Motor Home use. —Stop and go type service such as delivery trucks, etc. —Extensive idling —Short-trip operation at freezing temperatures (engine not thoroughly warmed-up). Oil & Filter Recommendations The letter designation "SE" has been established to correspond with the requirements of GM 6136-M. "SE" engine oils will be better quality and perform better than those identified with "SA" through "SD " designations and are recommended for all light-duty gasoline trucks regardless of model year and previous engine oil quality recommendations. Oil Change Period • Use only SE engine oil. • Change oil each 4 months or 6,000 miles. If more • Operation in dust storms may require an immediate oil change. • Replace the oil filter at the first oil change, and every second oil change thereafter. AC oil filters provide excellent engine protection. The above recommendations apply to the first change as well as subsequent oil changes. The oil change interval for the engine is based on the use of SE oils and quality oil filters. Oil change intervals LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N AND LU BRICATION longer than those listed above will seriously reduce engine life and may affect the m anufacturer’s obligation under the provisions of the New Vehicle W arranty. A high quality SE oil was installed in the engine at the factory. It is not necessary to change this factory-installed oil prior to the recommended normal change period. However, check the oil level more frequently during the break-in period since higher oil consumption is normal until the piston rings become seated. NOTE: Non-detergent and other low quality oils are specifically not recommended. Oil Filter Type and Capacity • Throwaway type, l quart U.S. measure, .75 quart Imperial measure. • 250 cu. in., 292 cu. in., AC Type PF-25. 307 cu. in., 350 cu. in. 454 cu. in., AC Type PF-35. Crankcase Capacity (Does Not Include Filter) • 292 L6 Engine; 5 quarts U.S. measure, 4.25 quarts Imperial measure. • All other engines; 4 quarts U.S. measure, 3.25 quarts Imperial measure. Recommended Viscosity Select the proper oil viscosity from the following chart: 0 -1 3 mark on the dipstick, oil should be added as necessary. The oil level should be maintained in the safety margin, neither going above the "FU LL" line nor below "ADD OIL" line. NOTE: The oil gauge rod is also marked "Use SE Engine Oil" as a reminder to use only SE oils. Supplemental Engine Oil Additives The regular use of supplemental additives is specifically not recommended and will increase operating costs. However, supplemental additives are available that can effectively and economically solve certain specific problems without causing other difficulties. For example, if higher detergency is required to reduce varnish and sludge deposits resulting from some unusual operational difficulty, a thoroughly tested and approved additive "Super Engine Oil Supplement"- is available. Drive Belts Drive belts should be checked every 6,000 miles or 4 months for proper tension. A loose belt will affect water pump and generator operation. POSITIVE CRANKCASE VENTILATION VALVE Every 24,000 miles or 24 months the valve should be replaced. Connecting hoses, fittings and flame arrestor should be cleaned. At every oil change the system should be tested for proper function and serviced, if necessary. RECOMMENDED SAE VISCOSITY NUMBER AIR INJECTION REACTOR SYSTEM (A.I.R.) CONTROLLED COMBUSTION SYSTEM (C.C.S.) 10W , 5W -3 0 , I0 W -3 0 , 10W -40 r .3 0 i i i i i— i -2 0 0 20 40 60 80 TEMPERATURE RANGE ANTICIPATED BEFORE NEXT OIL CHANGE, °F. 100 NOTE: SAE 5W-20 oils are not recom­ mended for sustained high-speed driving. SAE 30 oils may be used at temperatures above 40°F. SAE 5W-30 oils are recom­ mended for all seasons in vehicles normally operated in Canada. The proper oil viscosity helps assure good cold and hot starting. Checking Oil Level The engine oil should be maintained at proper level. The best time to check it is before operating the engine or as the last step in a fuel stop. This will allow the oil accumulation in the engine to drain back in the crankcase. To check the level, remove the oil gauge rod (dip stick), wipe it clean and reinsert it firmly for an accurate reading. The oil gauge rod is marked "FU LL" and "ADD OIL". If the oil is at or below the "A DD " The Air Injection Reactor system should have the drive belt inspected for wear and tension every 12 months or 12,000 miles, whichever occurs first. In addition, complete effectiveness of either system, as well as full power and performance, depends upon idle speed, ignition timing, and idle fuel mixture being set according to specification. A quality tune-up which includes these adjustm ents should be perform ed periodically to assure normal engine efficiency, operation and performance. GM EVAPORATION CONTROL SYSTEM Every 24 months or 24,000 miles (more often under dusty conditions) the filter in the base of the canister must be replaced and the canister inspected. MANIFOLD HEAT CONTROL VALVE Every 6,000 miles or 4 months, check valve for freedom of operation. If valve shaft is sticking, free it up with GM Manifold Heat Control Solvent or its equivalent. LIGHT DUTY TRUCK SERVICE MANUAL 0 - 1 4 GENERAL IN F O R M A T IO N A N D LUBRICATIO N AIR CLEANER CAUTION: Do not remove the engine air cleaner unless temporary removal is necessary during repair or maintenance of the vehicle. When the air cleaner is removed backfiring can cause fire in the engine compartment. NOTE: Under prolonged dusty driving conditions, it is recommended that these operations be performed more often. 011 Wetted Paper Element Type L-6 engine, replace every 12,000 miles. V-8 engine, every 12,000 miles inspect element for dust leaks, holes or other damage. Replace if necessary. If satisfactory, rotate element 180° from originally installed position. Replace at 24,000 miles. Element must not be washed, oiled, tapped or cleaned with an air hose. Crankcase Ventilation Filter (Located Within Air Cleaner) If so equipped, inspect every oil change and replace if necessary. Replace at least every 24,000 miles; more often under dusty driving conditions. FUEL FILTER Replace filter element located in carburetor inlet every 12 months or 12,000 miles whichever occurs first, or, if an in-line filter is also used, every 24,000 miles. Replace in-line filter every 24,000 miles. DISTRIBUTOR Replace cam lubricator at 24,000 mile intervals. GOVERNOR The attaching bolts should be kept tight, the optionally available governor should be kept clean externally and the filter element should be replaced every 12,000 miles. ACCELERATOR LINKAGE Lubricate with engine oil every 12,000 miles as follows: 1. On V8 engine, lubricate the ball stud at the carburetor lever. 2. On L6 engine, lubricate the two ball studs at the carburetor lever and lubricate the lever mounting stud. Do not lubricate the accelerator cable. AUTOMATIC TRANSMISSION FLUID RECOMMENDATION Use only automatic transmission fluids identified with the mark DEXRON (or equivalent). These fluids have been specially formulated and tested for use in the automatic transmission. Check the fluid level at each engine oil change period. To make an accurate fluid level check: 1. Drive vehicle several miles, making frequent starts and stops, to bring transmission up to normal operating temperature (approximately 180-190°F). 2. Park vehicle on a level surface. 3. Place selector lever in "Park" and leave engine running. 4. Remove dipstick and wipe clean. 5. Reinsert dipstick until cap seats. 6. Remove dipstick and note reading. If oil level is at or below the ADD mark on the dipstick, oil should be added as necessary. One pint raises the level from ADD to FULL. Do not overfill. Under normal driving conditions, the transmission fluid should be changed every 24,000 miles. If the vehicle is driven extensively in heavy city traffic during hot weather, or is used to pull a trailer, change fluid every 12,000 miles. Likewise, operators of trucks in commercial use where the engine idles for long periods, should change fluid every 12,000 miles. To Change Turbo Hydra-Matic 400 and Turbo HydraMatic 350 fluid, remove fluid from the transmission sump, add approximately 7.5 pints U.S. measure (6.25 pints Imperial measure) for the Turbo Hydra-Matic 400 and 2 1/2 qts. U.S. measure (2 qts. Imperial measure) for the Turbo Hydra-Matic 350 of fresh fluid, to return level to proper mark on the dipstick. Every 24,0 00 Miles—the Turbo Hydra-M atic 400 transmission sump filter should be replaced. 3-AND 4-SPEED MANUAL TRANSMISSION LUBRICANT Every 4 months or 6,000 miles, whichever occurs first, check lubricant level and add lubricant, if necessary, to fill to level of filler plug hole with SAE 80 or SAE 90 GL5 Gear Lubricant. If temperatures below + 32°F are expected, use SAE 80 GL-5 Gear Lubricant only. For those vehicles normally operated in Canada, use SAE 80 GL-5 Gear Lubricant. TRANSMISSION SHIFT LINKAGE (MANUAL AND AUTOMATIC) Every 6,000 miles or 4 months-lubricate shift linkage and, on Manual transmission floor control, lever contacting faces with water resistant EP chassis lubricant which meets General Motors Specification GM6031-M. Clutch The clutch pedal free travel should be checked at regular intervals. Lubricate the clutch cross-shaft at fitting (on Series 10 Forward Control models also lubricate the clutch linkage idler lever at fitting) every 6,000 miles or 4 months with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A ND L UBRICATION REAR AXLES Standard Every 4 months or 6,000 miles, whichever occurs first, check lubricant level and add lubricant, if necessary, to fill to level of filler plug hole. Use GL-5 G ear Lubricant as shown in the following table. (For vehicles normally operated in Canada, use SAE 80 GL-5 G ear Lubricant.) 0 -1 5 The bearings should be thoroughly cleaned before repacking with lubricant. Front wheels are equipped with tapered roller bearings on all trucks. Wheel bearings should be lubricated every 24.000 miles. Do not mix wheel bearing lubricants. CAUTION: " Long fibre" type greases should not be used on roller bearing front wheels. Rear O u tsid e T e m p e ra tu re BELOW 10°F Viscosity Lu b ric a n t T o Be Used SAE 80 UP TO 100°F SAE 90 ABOVE 100°F C ONSISTENTLY SAE 140 On 20 or 30 Series trucks, drain lubricant every 24,000 miles. If vehicle is operated in exceptionally heavy work or at continuous high speeds, the lubricant should be changed every 12,000 miles. It may be necessary to change lubricant more often if vehicle is used off road in dusty areas. Positraction Drain and refill at first 12,000 miles then maintain same as standard axle but use only the special Positractign lubricant available at your authorized dealer. PROPELLER SHAFT SLIP JOINTS Propeller shaft slip joints should be lubricated every 6,000 miles or 4 months with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M. UNIVERSAL JOINTS All universal joints are the needle bearing type. Lubricate those universal joints (depending on truck model) equipped with lube fittings every 6,000 miles or 4 months with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M. More frequent lubes may be required on heavy duty or "Off the Road" operations. WHEEL BEARINGS Front NOTE: Use wheel bearing lubricant GM Part No. 1051344 or equivalent. This is a premium high melting point lubricant which meets all requirements of General Motors Specification GM 6031-M. Due to the weight of the tire and wheel assembly it is recommended that they be removed from hub before lubricating bearings to prevent damage to oil seal. Then remove the front wheel hub to lubricate the bearings. The rear wheel bearings receive their lubrication from the rear axle. When installing bearings which have been cleaned, prelube with wheel bearing grease. BRAKE MASTER CYLINDER Check master cylinder fluid level in both reservoirs every 6.000 miles or 4 months. If the fluid is low in the reservoir, it should be filled to a point about 1/4" from the top rear of each reservoir with Delco Supreme No. 11 or D.O.T.-3 Hydraulic Brake Fluid or equivalent. BRAKE AND CLUTCH PEDAL SPRINGS Lubricate brake and clutch pedal springs every 6,000 miles or 4 months with engine oil for all models. PARKING BRAKE Every 6,000 miles or 4 months clean and lubricate all parking brake pivot points with water resistant EP chassis lubricant which meets General Motors Specifica­ tion GM 6031-M. STEERING Manual Steering Gear The steering gear is factory-filled with steering gear lubricant. Seasonal change of this lubricant should not be performed and the housing should not be drained-no lubrication is required for the life of the steering gear. Every 36,000 miles, the gear should be inspected for seal leakage (actual solid grease-not just oily film). If a seal is replaced or the gear is overhauled, the gear housing should be refilled with No. 1051052 (13 oz. container) Steering Gear Lubricant which meets GM Specification GM 4673-M, or its equivalent. NOTE: Do not use EP Chassis Lube, which meets GM Specification GM 6031-M, to lubricate the gear. DO NOT OVER-FILL the gear housing. NOTE: Lubricate intermediate steering shaft with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M every 6,000 miles or 4 months on P-10 models only. Power Steering System Check the fluid level in the pump reservoir at each oil change period. Add GM Power Steering Fluid or LIGHT DUTY TRUCK SERVICE MANUAL 0 - 1 6 GENERAL IN F O R M A T IO N A N D LUBRICATIO N DEXRON automatic Transmission Fluid or equivalent as necessary to bring level into proper range on filler cap indicator depending upon fluid temperature. 2. Apply Lubriplate or equivalent to latch pilot bolt and latch locking plate. 3. Apply light engine oil to all pivot points in release mechanism, as well as prim ary and secondary latch mechanisms. 4. Lubricate hood hinges. 5. Make hood hinge and latch mechanism functional check to assure the assembly is working correctly. BODY LUBRICATION If at operating temperature (approximately 150°F—hot to the touch), fluid should be between "HOT" and "COLD" marks. If at room temperature (approximately 70°F), fluid should be between "A DD " and "COLD" marks. Fluid does not require periodic changing. STEERING LINKAGE AND SUSPENSION M aintain correct front end alignment to provide easy steering, longer tire life, and driving stability. Check control arm bushings and ball joints for wear. Lubricate tie rods, upper and lower control arms, and ball joints at fittings with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M every 6,000 miles or 4 months. Lubricate every 3,000 miles or 2 months whichever occurs first under the following conditions: • Driving in dusty or muddy conditions. • Extensive ofF-road use. NOTE: Ball joints must be at + 10°F. or more before lubricating. Keep spring to axle U bolts and shackle bolts properly tightened (see Specifications Section for torque recom­ mendations). Check U bolt nuts after the first 1,000 miles of operation if the U bolt or U bolt nuts are changed in service. HOOD LATCH AND HOOD HINGE Every 6,000 miles or 4 months, whichever occurs first, lubricate hood latch assembly and hood hinge assembly as follows: 1. Wipe off any accumulation of dirt or contamination on latch parts. Normal use of a truck causes metal-to-metal movement at certain points in the cab or body. Noise, wear and improper operation at these points will result when a protective film of lubricant is not provided. For exposed surfaces, such as door checks, door lock bolts, lock striker plates, dovetail bumper wedges, etc., apply a thin film of light engine oil. Where oil holes are provided in body parts a dripless oil can be safely used, but any lubricant should be used sparingly, and after application all excess should be carefully wiped off. The seat adjusters and seat track, ordinarily overlooked, should be lubricated with water resistant EP chassis lubricant which meets General Motors Specification GM 6031-M. There are other points on bodies which may occasionally require lubrication and which are difficult to service. Window regulators and controls are confined in the space between the upholstery and the outside door panel. Easy access to the working parts may be made by removing the trim. Door weatherstrips and rubber hood bumpers should be lightly coated with a rubber lubricant. UNDERBODY MAINTENANCE The effects of salt and other corrosive materials used for ice and snow removal and dust control can result in accelerated rusting and deterioration of underbody components such as brake and fuel lines, frame, underbody floor pan, exhaust system, brackets, parking brake cables. These corrosive effects, however, can be reduced by periodic flushing of the underbody with plain water. In geographic areas having a heavy concentration of such corrosive materials, it is recommended that the complete underbody be inspected and flushed at least once a year, preferably after a winter’s exposure. Particular attention should be given to cleaning out underbody members where dirt and other foreign materials may have collected. FOUR WHEEL DRIVE Most lubrication recommendations and procedures for 4 wheel drive-equipped trucks are the same for corre­ sponding components of conventional drive trucks. In addition, the following items require lubrication at the intervals mentioned. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A ND LUBRIC ATIO N 0 -1 7 Conventional Four Wheel Drive Propeller Shaft Centering Ball A centering ball at the transfer case end of the front propeller shaft on Four Wheel Drive Models should be lubricated every 24,000 miles with water resistant EP chassis lubricant which meets General Motors Specifica­ tion GM 6031-M. More frequent lubrication may be required on heavy duty off the road operations. NOTE: A special needle nose grease gun adapter for flush type grease fitting is required to lubricate the centering ball. Front Axle The front axle should be checked every 6,000 miles or 4 months and refilled with SAE 90 GL-5 Gear Lubricant when necessary. With the differential at operating temperature, fill to the level of filler plug hole. If differential is cold, fill to level of 1/2" below the filler plug hole. For vehicles normally operated in Canada use SAE 80 GL-5 Gear Lubricant. Add SAE 80 or SAE 90 GL-5 Gear Lubricant to bring to level of filler plug hole. Full Time Four Wheel Drive Add engine oil to bring to level 1/2" below filler plug hole. Control Lever and Linkage Since no grease fitting is provided in the control lever it is necessary to brush or spray engine oil on the lever pivot point and on all exposed control linkage every 6,000 miles or 4 months. SPEEDOMETER ADAPTER On vehicles so equipped, lubricate adapter at fitting with water resistant EP chassis grease which meets General Motors Specification GM 6031-M every 6,000 miles. Air Vent Hoses Check vent hose at front axle and at transfer case for kinks and proper installation every 6,000 miles or 4 months. Transfer Case Check the transfer case level every 6,000 miles or 4 months and, if necessary, add lubricant as follows: DRIVE O N HOIST BUMPER JACK LIFTING FLOOR JACK OR HOIST LIFT Fig. 7—G Model Lifting Points LIGHT DUTY TRUCK SERVICE MANUAL 0 -1 8 GENERAL IN F O R M A T IO N A N D LUBRIC ATIO N Fig. 8—Lubrication—Conventional Models Lubrication Period No. Lubrication Points 1 2 3 b 6 / Lower Control Arms Upper Control Arms Upper and Lower Control Arm Ball Joints Intermediate Steering Shaft (PA10) Tie Rod Ends Wheel Bearings Steering Gear 6,000 Miles 30,000 Miles 36,000 Miles 8 A ir Cleaner — Element 12,000 Miles 9 10 11 D istributor — L-6 D istributor — V-8 Master Cylinder 12,000 Miles 12,000 Miles 6,000 Miles 12 Transmission — Manual — Autom atic T hrottle Bell Crank — L-6 Carburetor Linkage — V-8 Brake and Clutch Pedal Springs Universal Joints Propeller Shaft Slip Joint Rear Axle 4 13 14 15 16 17 18 Type of Lubrication Quantity Remarks 6,000 Miles 6,000 Miles 6,000 Miles Chassis Lubricant Chassis Lubricant Chassis Lubricant 4 places as required 4 places as required 4 places as required 6,000 Miles Chassis Lubricant 2 places as required Chassis Lubricant Whl. Brq. Lubricant 4 places as required 2 places as required 6.000 6.000 6,000 6,000 6,000 Miles Miles Miles Miles Miles 6,000 Miles 6,000 Miles 6,000 Miles Delco Supreme No. 11 or equivalent GL-5 Dexron or equivalent Enqine Oil Enqine Oil Engine Oil As required As As As As As Chassis Lubricant Chassis Lubricant GL-5 As required As required As required required required required required required Check fo r Grease Leak— Do not Lubricate Replace L-6. Rotate V-8 Replace V-8 at 24.000 miles. Replace cam lubricator* Replace cam lubricator* Check — add fluid when necessary Keep even w /fille r plug. See Lubrication Section Not shown Check See Lubrication section * Replace Points and Lubricator at 24,000 mile intervals. LIGHT DUTY TRUCK SERVICE MANUAL GENERAL IN F O R M A T IO N A N D LUBRICATION 0 -1 9 Fig. 9—Lubrication—Four Wheel Drive Models No. Lubrication Points Lubrication Period 1 A ir Cleaner 12,000 Miles 2 Distributor — L-6 12,000 Miles 3 Distributor — V-8 12,000 Miles 4 Control Linkage Points 7 8 Tie Rod Ends Wheel Bearings 6,000 Miles 30,000 Miles 9 Steering Gear 36,000 Miles 10 Master Cylinder 6,000 Miles 11 Transmission — Manual — Autom atic Carburetor Linkaqe — V-8 Universal Joints Propeller Shaft Slip Joints Front and Rear Axle 6.000 6.000 6,000 6,000 6,000 6,000 21 Drag Link Brake and Clutch Pedal Sprinqs Transfer Case 22 T hrottle Bell Crank — L-6 12 13 14 15 17 18 6,000 Miles Type of Lubrication Engine Oil As required Chassis Lubricant Wheel Bearing Grease 2 places as required 2 places as required As required Delco Supreme No. 11 or equivalent GL-5 Dexron or equivalent Enqine Oil Chassis Lubricant Chassis Lubricant G L-6 As required As required As required As required 3 places as required As required 6,000 Miles Chassis B 2 places as required 6,000 Miles 6,000 Miles Enqine Oil GL-5 As required As required 6,000 Miles Engine Oil As required Miles Miles Miles Miles Miles Miles Remarks Quantity Replace L-6. Rotate V-8. Replace V-8 at 24,000 miles. Replace Cam Lubricator* Replace Cam Lubricator* Brush or Spray to apply Check fo r Grease Leak Do not Lubricate Check — add fluid when necessary Keep even w /fille r plug See Lubrication Section See Lubrication Section Check See Lubrication Section Check See Lubrication Section * Replace Points and Lubricator at 24,000 mile intervals. LIGHT DUTY TRUCK SERVICE MANUAL 0 -2 0 GENERAL IN F O R M A T IO N A N D LUBRIC ATIO N Fig. 10—Lubrication—1/2, 3/4 and 1 Ton G Models No. 1 Lubrication Points Lubrication Period Type of Lubrication 8 9 Control Arm Bushings and Ball Joints Tie Rod Ends Wheel Bearings Steering Gear Clutch Cross-Shaft Trans. Control Shaft A ir Cleaner—Element 6,000 6,000 30,000 36,000 6,000 6,000 12,000 10 D istributor—L-6, V-8 12,000 Miles 11 12 13 T ransmission—Synchromesh —A utom atic Rear Axle Oil Filter GL-5 Dexron or Equivalent GL-5 14 Battery 6.000 Miles 6.000 Miles 6,000 Miles Every Second Oil Change 5,000 Miles 15 Brake Master Cylinder 6,000 Miles 16 Parking Brake Linkage 6,000 Miles Delco Supreme No. 11 or Equivalent Chassis Lubricant 2 4 b Miles Miles Miles Miles Miles Miles Miles Q uantity Chassis Lubricant Chassis Lubricant Whl. Brq. Lubricant 12 places as required 4 places as required 2 places as required Chassis Lubricant Chassis Lubricant As required As required As required As required As required Engine Oil As required Remarks 2 fittinqs each side Replace L-6, Rotate V-8, Replace V-8 at 24.000 Miles. Replace Cam Lubricator* See Lubrication Section See Lubrication Section See Lubrication Section Oil Terminals and Felt Washers Check—Add fluid when necessary Lubricate Linkage and Cables * Replace Points and Lubricator at 24,000 Mile Intervals. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-1 SECTION 1A HEATER AND AIR CONDITIONING CONTENTS OF THIS SECTION Standard H eater.............................................................................. 1A-1 Auxiliary H eater.............................................................................. 1A-14 Air C onditioning............................................................................. 1A-18 STANDARD HEATER INDEX General Description........................................................ Theory of Operation....................................................... System Components....................................................... System Controls............................................................... Component Replacement and R ep air...................... Blower M otor................................................................... Heater Distributor and Core Assembly................. Heater Hoses.................................................................... 1A-1 1A-3 1A-3 1A-3 1A-4 1A-4 1A-4 1A-5 Center Distributor Duct - G M odels..................... Left Distributor Duct - G M odels......................... Defroster D uct................................................................ Control Assembly........................................................... Control Cables................................................................. Blower Switch................................................................... Resistor U nit.................................................................... Diagnosis............................................................................. 1A-5 1A-6 1A-6 1A-7 1A-7 1A-9 1A-9 1A-10 GENERAL DESCRIPTION Heating components are attached to the dash panel on the right side of the vehicle. The blower and air inlet assembly and water hoses are located on the forward side of the dash panel while the heater core and distributor duct are on the passenger side. The heater system is an air mix type system in which outside air is heated and then mixed in varying amounts with cooler outside air to attain the desired air temperature. The system consists basically of three parts: (1) the blower and air inlet assembly, (2) the heater distributor assembly and (3) the heater control assembly. Fig. 1A--Heater A ir Flow Schematic G Models LIGHT DUTY TRUCK SERVICE MANUAL HEATER A DEFROSTER ASM (H E AT E R IN OFF P O S I T I O N ) 1 A- 2 HEATER H EA TE R A D E F R O S T E R A S M AND AIR AI R OU T L E T VI EW A S T E E RI N G COLUMN VI EW B DEFROSTER DUCT ASM B L O W E R A AIR I NLE T A SM VIEW B LIGHT AI R F L O W L E G E N D DUTY TRUCK H E A T ER A S M SERVICE C-K MODELS MANUAL Fig. 1B--Heater A ir F lo w Schematic C -K Models CONDITIO NING AIR OUTLET HEATER A N D AIR C O N D IT IO N IN G 1A-3 THEORY OF OPERATION BLOWER AND AIR INLET ASSEMBLY The blower and air inlet assembly draws outside air through the outside air inlet grille located forward of the windshield reveal molding and channels the air into the heater distributor assembly. The operation of the blower motor is controlled by the FAN switch on the heater control. The motor is connected in series with the FAN switch and also the blower resistor assembly. Located in the fuse block, in series between the blower motor and the battery, is a 25 amp. fuse C-K models - a 20 amp fuse on G models. TURE door in the heater distributor assembly. All incoming "outside" air is directed around the heater core in the COLD position or through the core in the HOT position. The desired outlet temperature is obtained by blending the heated and unheated air according to the setting of the temperature lever. Heater-Def Lever The heater distributor assembly houses the heater core and the doors necessary to control mixing and channeling of the air. Since the unit has no water valve, water circulation keeps the core hot at all times. That portion of the air passing through the core receives maximum heat from the core. Air entering the distributor assembly is channeled as follows: The HEATER-DEF lever controls the position of the DEFROSTER door and the PURGE door. In the OFF position, the blower is "on" and incoming air is directed up under the dash through the purge door opening. As the lever is moved to the right of the OFF position, the door closes, directing airflow on into the distributor assembly. With the lever at HEATER, the DEFROSTER door directs almost all airflow to the heater (floor) outlets - a small amount of air is directed to the defroster (dash) outlets. In the DEF position, most airflow is diverted to the defroster outlets. Moving the lever part way, as desired, will split airflow between the floor and defroster outlets. C-K Models Fan Control HEATER DISTRIBUTOR ASSEMBLY Air entering the distributor can be directed out the purge door opening, on the right end of the distributor assembly, by the purge door. If the purge door is closed, then air is directed through and/or around the heater core by the temperature door. Air is then directed into the passenger compartment through the heater (floor) outlets and/or the defroster (dash) outlets by the defroster door. The temperature of the outlet air is dependent on the ratio of heated to unheated air (controlled by the temperature door). The blower fan lever is located at the left hand side of the control assembly. The blower motor will operate as soon as the ignition switch is turned to the RUN position. The control has three positions only; LO, MED, HI. There is no OFF position. G Models (Fig. 3) The controls are located in the instrument panel, just to the right of the instrument cluster. In operation, two levers control all heating operations. G Models Airflow is controlled by three doors in the distributor assembly. The air door can be adjusted to vary airflow. If air is allowed to enter the distributor assembly, it is then directed through and/or around the heater core by the temperature door. Air is directed into the passenger compartment through the heater (floor) and/or defroster (dash) outlets by the defroster door. The temperature of the outlet air is dependent on the ratio of heated to unheated air (controlled by the temperature door). — Hl - I - ■ . HOI C01D j f ~ DEF _ ■j HEATER ■ OFF \ < 10 n , j - FAN Fig. 2-Heater Control--C-K Models CONTROLS C-K Models (Fig. 2) These controls are mounted in the center of the dash, above the radio assembly. The control incorporates two levers which make use of bowden cables to control positioning of the purge, temperature and defroster doors. Temperature Lever This lever controls the positioning of the TEMPERA- Fig. 3-Heater Control-G Models LIGHT DUTY TRUCK SERVICE MANUAL 1 A-4 HEATER A N D AIR C O N D IT IO N IN G Temperature Lever This lever controls the positioning of the TEMPERA­ TURE door in the heater distributor assembly. All incoming "outside" air is directed around the heater core in the COLD position on through the core in the HOT position. The desired outlet temperature is obtained by blending heated and unheated air according to the setting of the temperature lever. the system. Moving the lever to the right (toward HEATER) opens the air door with the AIR door being fully open at the HEATER position. Incoming air is directed to the heater outlets (with slight air bleed to the defroster outlets). Moving the lever between HEATER and DEF, directs increasing amounts of air to the defroster outlets until all air is directed to the defroster outlets in the DEF position. Fan Control Heater-Def Lever The HEATER-DEF lever controls positioning of the AIR and DEFROSTER doors in the heater distributor assembly. In the OFF position, no air is allowed to enter The blower fan lever is located on the left hand side of the control assembly. When the lever is fully down, the blower motor is inoperative. Moving the lever upward actuates the three speed blower motor (LOW-MED-HI). C O M P O N E N T PART REPLACEMENT BLOWER MOTOR Removal (Fig. 4) 1. Disconnect battery ground cable. G Models - Remove the battery. 2. Disconnect the blower motor lead wire. 3. Remove the five blower motor mounting screws and remove the motor and wheel assembly. Pry gently on the blower flange if the sealer acts as an adhesive. 4. Remove the blower wheel to motor shaft nut and separate the wheel and motor assemblies. 5. To install a new motor, reverse Steps l-4 above. NOTE: The following precautions should be taken to assure proper installation: a. Assemble the blower wheel to the motor with the open end of the wheel away from the blower motor. b. If the motor mounting flange sealer has hardened, or is not intact, remove the old sealer and apply a new bead of sealer to the entire circumference of the mounting flange. c. Check blower operation; blower wheel should rotate freely with no interference. HEATER DISTRIBUTOR AND CORE ASSEMBLY C-K Models Replacement (Fig. 5) Fig. 4-Blower Motor Assembly 1. Disconnect the battery ground cable. 2. Disconnect the heater hoses at the core tubes and drain engine coolant into a clean pan. Plug the core tubes to prevent coolant spillage at removal. 3. Remove the nuts from the distributor duct studs projecting into the engine compartment. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 4. Remove the glove box and door assembly. 5. Disconnect the Air-Defrost and Temperature door cables. 6. Remove the floor outlet and remove the defroster duct to heater distributor duct screw. 7. Remove the heater distributor to dash panel screws. Pull the assembly rearward to gain access to wiring harness and disconnect all harness attached to the unit. 8. Remove the heater-distributor from the vehicle. 9. Remove the core retaining straps and remove the core. 10. To install, reverse Steps 1-9 above. NOTE: Be sure core to case and case to dash panel sealer is intact before assembling unit. G Models Replacement (Fig. 6) 1. Disconnect the battery ground cable. 2. Place a clean pan under the vehicle and then disconnect the heater core inlet and outlet hoses at the core connections (see "H eater Hoses-Replacem ent" later in this section). Quickly plug the heater hoses and support them in a raised position. Allow the coolant in the heater core to drain into the pan on the floor. 3. Disconnect the right hand air distributor hose from the heater case and rotate it up out of the way. 4. Pry off the temperature door cable eyelet clip and then remove the bowden cable attaching screw. 5. Remove the distributor duct to heater case screws and pull the duct rearward out of the heater case retainer. 6. Remove the four heater case to dash screws and 1A-5 then remove the heater case and core as an assembly. Tilt the case assembly rearward at the top while lifting up until the core tubes clear the dash openings. 7. Remove the core retaining strap screws and remove the core. 8. To install a new core, reverse Steps 1-7 above. NOTE: Be sure core to case and case to dash panel sealer is intact before assembling unit. HEATER HOSES Heater hoses are routed from the water pump and thermostat housing (radiator on automatic transmission vehicles) to the core inlet and outlet pipes as shown in Figure 7. Hoses are attached at each end with screw type clamps. Replacement The heater core can be easily damaged in the area of the core tube attachment seams whenever undue force is exerted on them. Whenever the heater core hoses do not readily come off the tubes, the hoses should be cut just forward of the core tubes. The portion of the hose remaining on the core tube should then be split longitudinally. Once the hoses have been split, they can be removed from the tubes without damage to the core. CENTER DISTRIBUTOR DUCT - G Models Replacement (Fig. 8) 1. Disconnect the battery ground cable. 2. Unsnap the engine cover front latches. Remove the two cover to floorpan screws and remove the cover. 3. Remove the heater core case and core as an LIGHT DUTY TRUCK SERVICE MANUAL 1A-6 HEATER A N D AIR C O N D IT IO N IN G Fig. 7 -Heater Hose Routings 4. 5. 6. 7. assembly (see "Heater Distributor and CoreReplacement"). Disconnect the right hand heater outlet hose and the two defroster hoses from the distributor duct. Disconnect the air and defroster door cables by prying off the eyelet clips and removing the cable attaching screws. Pull the center distributor duct to the right and remove it from the vehicle. To install, reverse Steps 1-6 above. NOTE: Check cable and door operation; cables should be free from kinks or binding and doors should close properly. If cable adjustment is necessary, see "Bowden CableAdjustment." LEFT DISTRIBUTOR DUCT - G Models Replacement (Fig. 8) 1. Disconnect the battery ground cable. 2. Unsnap the engine cover front latches. Remove the two cover to floorpan screws and remove the cover. 3. Remove the duct bracket screw and remove the duct. 4. To install, reverse Steps 1-3. NOTE: All three bowden cables are routed under the duct. It may be necessary to hold the cables down as the duct is being installed. Be sure the left duct is fully installed over the center duct. DEFROSTER DUCT The defroster hose and outlet assemblies are illustrated in Figure 9. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-7 LEFT DISTRIBUTOR DUCT CENTER DISTRIBUTOR DUCT HEATER CORE CASE Fig. 8-Distributor Ducts-G Models CONTROL ASSEMBLY C-K Models Replacement (Fig. 10) 1. Disconnect the battery ground cable. 2. Remove the radio as outlined in Setction 15 of this manual. 3. Remove the instrument panel bezel. 4. Remove the control to instrument panel screws and lower the control far enough to gain access to the bowden cable attachments. CAUTION: Be careful not to kink the bowden cables. 5. Disconnect the bowden cables and the blower switch wiring harness. 6. Remove the control through the radio opening. 7. If a new unit is being installed, transfer the blower switch to the new unit. 8. To reinstall, reverse Steps 1-6 above. G Models Replacement (Fig. 11) 1. Disconnect the battery ground cable. 2. Remove the ignition switch from the instrument panel (see Section 12 of this manual). 3. Remove the control to instrument panel mounting screws and carefully lower the control far enough to gain access to the bowden cable attachments. CAUTION: Care should be taken to prevent kinking the bowden cables while lowering the control. 4. Disconnect the three bowden cables, the control illumination bulb, the blower switch connector and remove the control from the vehicle. 5. Remove the blower switch screws and remove the blower switch. 6. To install, reverse Steps 1-5 above. CONTROL CABLES C-K Models Replacement 1. 2. 3. 4. Disconnect the battery ground cable. Remove the instrument panel bezel. Remove the control to instrument panel screws. Raise or lower control as necessary to remove cable push nuts and tab attaching screws. 5. Remove glove box and door as an assembly. 6. Remove cable push nut and tab attaching screw at door end of cable. LIGHT DUTY TRUCK SERVICE MANUAL 1 A-8 HEATER A N D AIR C O N D IT IO N IN G C-K MODELS DEFROSTER HOSES G MODELS Fig. 9 - D e f r o s t e r O u tle ts 7. Remove cable from retaining clip and remove cable assembly. 8. To install, reverse Steps l-7 above. CAUTION: Be careful not to kink the cable during installation. Be sure to route the cable as when removed. G Models Replacement (Fig. 12) 1. Disconnect the battery ground cable. 2. Unsnap the engine cover front latches. Remove the two cover to floorpan screws and remove the cover. 3. Remove the left distributor duct attaching screw and remove the duct. 4. Defroster Cable Only - Remove the radio speaker bracket to dash panel (2) screws. 5. Pry off the cable eyelet clip at both the door and control lever. Remove the cable attaching screw at both door and control locations. 6. Attach a 4’ piece of wire to the door end of the cable. Place protective tape around the cable mounting tab and attached wire and carefully pull the cable from the vehicle. Remove the tape and disconnect the 4’ piece of wire. NOTE: On defroster cables, pull rearward slightly on the radio speaker bracket to get clearance for cable removal. 7. To install, attach the new cable to the 4’ piece of wire. Tape the mounting tab and attached wire. Carefully pull the new cable into position. 8. Reverse Steps 1-5. NOTE: If cable adjustment is required, see below. Adjustment 1. Disconnect the battery ground cable. 2. G Model Air and Defroster Door Cables-Unsnap the LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1A-9 DEFROSTER CABLE JER CABLE AIR CABLE W ITHOUT RADIO WITH RADIO VIEW A Fig. 1 2 -Control Cable Routing-G Models 3. 4. 5. 6. engine cover front latches. Remove the two cover to floorpan screws and remove the engine cover. C-K Models-Remove glove box and door as an assembly. Pry off the appropriate cable eyelet clip and disconnect the cable from the door. Remove the cable retaining screw. While holding the cable with pliers, rotate the mounting tab on the cable to lengthen or shorten the cable, whichever is required. NOTE: Do not pinch the cable too tightly or damage to the cable could result. Install the cable, reversing Steps 1-4 above. BLOWER SWITCH C-K Models Replacement (Fig. 10) 1. Disconnect the battery ground cable. 2. Remove the instrument panel bezel. 3. Remove the control to instrument panel screws and lower the control onto the radio. 4. Disconnect the switch electrical harness. 5. Remove the switch attaching screws and remove the switch. 6. To install, reverse Steps 1-5 above. G Models Replacement (Fig. 11) 1. Disconnect the battery ground cable. 2. Disconnect the blower switch wiring harness connector at the switch. 3. Remove the two switch attaching screws and remove the switch assembly. 4. To install a new switch, reverse Steps 1-3 above. RESISTOR Replacement (Figs. 4 and 6) 1. Disconnect the wiring harness at the resistor connector. 2. Remove the two resistor mounting screws and remove the resistor. 3. To install a new resistor, reverse Steps 1 and 2 above. LIGHT DUTY TRUCK SERVICE MANUAL 1A-10 HEATER A N D AIR C O N D IT IO N IN G DIAGNOSIS C AUSE AND C O R R E C T I O N TROUBLE Temperature o f heater a i r a t o u tle ts senger compartment. too Temperature o f heater a i r a t o u tle ts w i l l n o t b u i l d up s u f f i c i e n t h e a t . adequate but Inadequate d e fr o s tin g Inadequate c i r c u l a t i o n Erratic or h e a t up p a s ­ the action. of heated a i r heater o p e ra tio n . Hard o p e r a t i n g low to through ve h ic le . 1. See " I n s u f f i c i e n t Check f o r vehicle 1. Floor 2. Leaking Heat body le a ks side kick Diagnostic such a s : pad v e n t i l a t o r s grommets Chart". partially open. in dash. 3. Lea kin g welded 4. Leaks s e a ms a l o n g 5. Leaking 6. L ea ks bet ween s e a l i n g edge o f and d a s h , and b e t we e n s e a l i n g a ss e m b l y and d a s h . 1. Check t h a t D E FR O ST l e v e r c o m p l e t e l y opens d e f r o s t e r d o o r in DEF p o s itio n - A d ju s t i f necessary. 2. Insure 3. Look f o r o b s tru ctions obstructions. 4. Check f o r a i r l e a k i n d u c t i n g b e t we e n d e f r o s t e r o u t l e t on h e a t e r a s s e m b l y and d e f r o s t e r d u c t u n d e r i n s t r u m e n t panel Seal a r e a as n e c e s s a r y . 5. Check p o s i t i o n o f Adjust. 6. Check p o s i t i o n o f d e f r o s t e r n o z z l e op e ni n gs ment panel o p e n i n g s . Mounting tabs provide i f properly in stalle d . 1. Check h e a t e r a i r o u t l e t 2. I n spec t f l o o r c a r p e t to i n su re t h a t c a r p e t l i e s f l a t under f r o n t s e a t and does n o t o b s t r u c t a i r f l o w u n d e r s e a t , and a l s o i n s p e c t around o u t l e t du ct s to i n s u r e t h a t c a r p e t is well fastened to f l o o r to prevent cupping o f a i r flow - Correc t as n e c e s s a r y . 1. Check c o o l a n t 2. Check f o r 3. Check o p e r a t i o n necessary. 4. S e d i m e n t i n h e a t e r l i n e s and r a d i a t o r c a u s i n g e n g i n e t h e r m o ­ s t a t t o s t i c k open - f l u s h s ys t e m and c l e a n o r r e p l a c e t h e r m o ­ s t a t as n e c e s s a r y . 5. Partially 1. Ch eck f o r l o o s e bowden c a b l e t a b ca b le s - C o r r e c t as r e q u i r e d . 2. Check f o r s t i c k i n g h e a t e r using a s ilic o n e spray. through access rubber molding that ro cker holes and b l o w e r and a i r i n l e t a ss e m b l y edge o f h e a t e r d i s t r i b u t o r kinked plugged for Fill heater of all doo rs open f u l l y in d e f r o s te r ducts bottom o f - and w i n d s h i e l d . ar o u n d d o o r and w i nd o ws . t e m p e r a t u r e and a i r level panel s cr ew h o l e s . nozzle to correct to hoses proper - heater core - Adjust. Remove a n y heater locating relative positive installation - tab - to i n s t r u ­ position Reinstall. level. relieve bowden c a b l e s - - kinks or and doo rs backflush re place hoses. - A d j u s t as c o r e as necessary. broken c o n t r o l s . scr ews system d o o r ( s ) or mis-adjusted - Lubricate bowden as r e q u i r e d LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-11 INSUFFICIENT HEAT DIAGNOSIS P o sitio n th e c o n tro ls so th a t the: T e m p eratu re lever is o n fu ll heat. S elector o r heater lever is on Heater. Fan sw itch is o n Hi. •CHECK DUMP DOOR OUTLET FOR A IR FLOW NO AIR FLOW CHECK DEFROSTER OUTLETS FOR AIR FLOW A d ju s t d u m p d o o r fo r no air flo w . ( I f in d o u b t as to High o r L o w a ir flo w set selector on DEF w h ich is High and com pare. Reset selector on Heater) | NO OR LOW AIR FLOW | | HIGH AIR FLOW CHECK HEATER OUTLET A IR FLOW | A d ju s t d e fro ste r d o o r fo r lo w a ir flo w . ( If in d o u b t, sw itch fan sw itch fro m Hi to Lo) CHANGE IN AIR FLOW Z . I LITTLE OR NO CHANGE IN A IR FLOW ...— NORMAL AIR FLOW | LOW OR NO A IR FLOW Check heater o u tle t te m pe ra ture w ith 2 20 F range the rm o m e te r. * *C h e c k s h u to ff d o o r p o s itio n fo r fu ll system a ir flo w . A d ju s t if necessary. (a p p ro x im a te o u tle t a ir tem peratures) O u tle t A ir A m b ie n t A ir 145 0 150 25 155 40 165 75 LOW A IR FLOW NO A IR FLOW Check heater o u tle t fo r o b s tru c tio n - re ­ move. CHECK FUSE NORMAL TEMPERATURE Remove a ll o b s tru c tio n s u nd er fr o n t seat. Check m o to r voltage at closest m o to r lin e co n n e c tio n w ith a vo ltm e te r. Car does n o t b u ild up heat - o perate ve nt c o n tro ls and see th a t th e a ir ve nt d oors close c o m p le te ly , if n o t, a djust. I FUSE B LO W N - replace fuse. A IR F L O W -s y s te m okay. LOW TEMPERATURE IE (Check th e system te m p e ra tu re a fte r re ­ p airin g th e item checked to c o m p le te th e diagnosis.) Check c o o la n t level; if or feel all ra d ia to r and co n n e ctio n s fo r leaks. Check th e ra d ia to r cap place if re q uired . lo w , f ill. L o o k fo r heater hoses and Repair o r replace. fo r damage and re­ UNDER 10 VOLTS Check b a tte ry v o lts - u nd er 10 vo lts, recharge th e n recheck m o to r voltage. Check w irin g and c o n n e ctio n s fo r u nd er 10 v o lts fro m m o to r to fan s w itch . Repair o r replace last p o in t o f u nd er 10 v o lt reading. Check heater a nd ra d ia to r hoses fo r k in k s stra ig hte n and replace as necessary. Check te m p e ra tu re d o o r fo r m ax heat po­ sitio n . A d ju s t if necessary. BLOWS FUSE OVER 10 VOLTS Remove p o sitive lead fro m m o to r and replace fuse. FUSE R E M A IN S O K - rem ove m o to r and check fo r o b s tru c tio n in system opening, if none, R E P LA C E M O T O R . If o b s tru c tio n , rem ove m aterial and re -in s ta ll m o to r. BLO W S FUSE - check fo r shorted w ire in b lo w e r e lectric c ir c u it See Heater C irc u it D ia g no stic C h art. A p p ly exte rn a l g ro un d, (ju m p e r w ire) to m o to r case. IN C R E A S E D A l R FLO W re p air g round. | HEATER CORE | FUSE OK | Feel tem peratures o f heater in le t and o u tle t hoses. [ WARM INLE T AND OUTLET HOSES S AM E A l R FLO W - rem ove m o to r and check f o r o b s tru c tio n in system o p e n ­ ing. I f none, R E P LA C E M O T O R . If o b s tru c tio n , rem ove m aterial and re ­ install m o to r. | FUSE O K - See Heater C irc u it D iagnostic C h art. Check engine th e rm o s ta t. | HOT IN LET AND WARM O UTLET HOSES | Check p u lleys, b e lt te n sio n , etc., f o r p ro ­ per o p e ra tio n . Replace o r service as neces­ sary. I ............ 'CH ECK FOR C-K MODELS ONLY ■CHECK FOR G MODELS ONLY Remove hoses fro m heater core. Reverse flu sh w ith tap w a ter. I f plugged, re p air or replace. LIGHT DUTY TRUCK SERVICE MANUAL 1A-12 HEATER HEATER C I R C U I T D I A G N O S I S * BLOW ER M OTO R IN O P E R A T IV E (A N Y SPEED) AND Check fuse in fuse panel. AIR X FUSE BLOW N FUSE OK I C O N D IT IO N IN G ' 1 The fo llo w in g tests should be made w ith W ith Ig n itio n sw itch in " R U N " p o s itio n and blow er the ig n itio n switch in " R U N " po s itio n speed sw itch " O N " use the blow er speed sw itch " O N " and the lever on heat position. meter to locate sh o rt in one I o f the fo llo w in g w ires: 1. From fuse panel to blow er Check blower m o to r ground speed sw itch . 1 2. From b lo w e r speed sw itch to heater resistor. POOR OR NO G RO UND G R O U N D OK Repair ground Check m o to r conn ector ~'I 3. From heater resistor to blow er. T w ith 12 v o lt test lig h t. N ote: S h o rt c ir c u it m ay be in te rm itte n t. If m eter does n o t in dicate a s hort c irc u it, move harness around as LA M P LIG H TS I m uch as possible to re-create short c irc u it. W atch and Replace M otor listen fo r arcing. L A M P DOES NO T L IG H T Use 12 v o lt test lig h t and check feed te rm in a l (b ro w n ) on blow er speed switch. L A M P DOES NO T L IG H T I Check blower feed wire in connector on resistor with 12 volt test light. L A M P L IG H T S Repair open in feed wire from resistor to blower motor. LIGHT L A M P L IG H T S Repair open in b ro w n w ire Replace sw itch DUTY L A M P DOES NO T L IG H T TRUCK fro m b low er speed sw itch to fuse panel. SERVICE MANUAL Fig. 1 3 -Heater Circuit Diagnosis * See heater c irc u it diagrams HEATER A N D AIR C O N D IT IO N IN G 1A-13 Fig. 14-Heater Wiring Diagrams LIGHT DUTY TRUCK SERVICE MANUAL 1A-14 HEATER A ND AIR C O N D IT IO N IN G AUXILIARY HEATER INDEX General D escription...................................................................... C ontrols........................................................................................... Component Replacement and Repairs.................................... Diagnosis........................................................................................... 1A-14 1A-14 1A-16 1A-17 GENERAL DESCRIPTION An auxiliary heater is available as a dealer installed accessory to provide additional heating capacity for the rearmost extremities of the C-K (06) and G models. This unit operates entirely independent of the standard heater and is regulated through its own controls at the instrument panel. This system consists of a separate core and fan unit mounted as shown in Figures 15 and 16. Heater hoses extend from the unit to the front of the vehicle where they are connected to the standard heater hoses with "tees". An "on-off" water valve is installed in the heater core inlet line in the engine compartment. This valve must be operated manually—"on" for cold weather, "off" in warm weather. The purpose of the valve is to cut off coolant flow to the auxiliary core during warm weather and eliminate the radiant heat that would result. CONTROLS Two methods of control are employed with this system: Water Valve (Fig. 17) When heat is desired, the water valve must be in the "on" position (valve located in the engine compartment LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-15 AUXILIARY HEATER (110" W.B. WITH REAR SEATS) EXISTING HEATER CONTROL SWITCH AUXILIARY HEATER (110" W.B. WITHOUT REAR SEATS) (ALL 125" W.B. MODELS) WATER VALVE Fig. 1 6 -A u x ilia ry H e a te r In s ta lla tio n s (G M o d e ls ) IN S T A L L V A L V E W IT H A R R O W P O IN T IN G A W A Y F R O M TEE. O R IE N T V A L V E S O '■ O N '" 'O F F ” IS VISIB LE Fig. 1 7 - W a t e r Valve In s ta lla tio n - G M o d e l S how n as Fig. 1 8 -A u x ilia r y H e a te r C o n tro l T y p ic a l in the core inlet line). During the summer months, this valve should be placed in the "off" position. the instrument panel, to the right of the steering column. Fully up, the blower is inoperative; fully down the blower is on HI. Fan Switch (Fig. 18) The three speed fan switch (LOW-MED-HI) is located in LIGHT DUTY TRUCK SERVICE MANUAL 1A-16 HEATER A N D AIR C O N D IT IO N IN G Fig. 19--Control and Resistor Mountings C O M P O N E N T REPLACEMENT A N D REPAIRS Since a detailed list of installation instructions is included with the auxiliary heater unit, replacement procedures will not be repeated in this section. CAUTION: G Models-- When replacing heater hoses, maintain a 1-1/4" minimum clearance between the auxiliary heater core lines and the exhaust pipe. Observe minimum clearances as shown in Figure 20. All Models-Draw hoses tight to prevent sag or rub against other components. Be sure to route hoses through all clamps as originally installed. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-17 D IA G N O S IS inoperative on C-K models (equipped with Overhead Air Conditioning), check that the connectors have not been interchanged with one another. Refer to the "Standard Heater" section of this manual for diagnostic information; see Electrical Diagram Figure 21. NOTE: If the heater blower motor is MED 3 BLOWER M RESISTOR — | 5 l1 | 552k 2 k — 140RG--------[ 52] [ 52I - I 4 BLK — 1791 72 I-----------uI40RGn p n --------------------- -14 LT BLU■14 YEL- ■14 BLK— [5 2 ] [5 2 ]— 14 BLK-------- D 0 FUSE PANa IGN UNFUSED ________ 12 BRN—- | 15AMP J-12 BRN' INLINE FUSE 50 140RG BLOWER MOTOR >— 14 LT BLU' 14 YEL■12BRN- 50 52 F L 14 BLK BLOWER SWITCH Fig. 21—Electrical Diagram - All Models LIGHT DUTY TRUCK SERVICE MANUAL 1A-18 HEATER A ND AIR C O N D IT IO N IN G AIR CONDITIONING INDEX General Description.........................................................1A-19 Four-Season System (C-K M odels)......................... .1A-19 Floor Mounted System (G Models)........................ .1A-19 Overhead Systems (C-K-G Models)........................ .1A-19 Motor Home Chassis System..................................... .1A-19 Theory of Operation........................................................1A-20 H eat.................................................................................... .1A-20 Refrigerants.......................................................................1A-23 Air Conditioning.............................................................1A-26 Basic Air Conditioner....................................................1A-26 Main Units of the System......................................... .1A-28 Chemical Ingredients of an Air Conditioning System...............................................................................1A-35 Primary Causes of System Failures........................ .1A-36 System Controls.............................................................. .1A-38 General Inform ation........................................................1A-39 Precautions in Handling R efrigerant-12.................1A-39 Precautions in Handling Refrigerant Lines...........1A-40 M aintaining Chemical Stability in the Refrigeration System ............................................... .1A-40 J-8393 Charging Station................................................1A-41 Gauge S et..........................................................................1A-41 Vacuum Pump................................................................. .1A-42 Leak Testing the System ............................................ .1A-42 Availability of Refrigerant-12....................................1A-43 Compressor O il............................................................... .1A-44 Compressor Serial N um ber........................................ .1A-44 Inspection and Periodic Service...................................1A-44 Pre-Delivery Inspection..................................................1A-44 6000 Mile Inspection......................................................1A-44 Periodic Service.............................................................. .1A-44 Evacuating and Charging Procedures....................... .1A-44 Air Conditioning System C apacity......................... .1A-44 Installing Charging Station........................................ .1A-44 Purging the System........................................................1A-45 Evacuating and Charging the System.....................1A-45 Performance Test........................................................... .1A-47 Performance D ata.......................................................... .1A-48 Checking O il.....................................................................1A-49 Refrigerant Quick-Check Procedure....................... ..1A-50 Maintenance and Adjustm ents.....................................1A-51 Thermostatic Switch.......................................................1A-51 Expansion Valve............................................................. .1A-52 Engine Idle Com pensator.............................................1A-53 General Repair Procedures.......................................... .1A-53 Preparing System for Replacement of Component Parts.................................................................................. .1A-53 Foreign Material in the System ................................1A-53 Refrigerant Line Connections....................................1A-53 Repair of Refrigerant Leaks..................................... .1A-54 Refrigerant Hose Failure..............................................1A-54 Com pressor........................................................................1A-55 Compressor F ailure........................................................1A-57 False Compressor Seizure........................................... .1A-57 Collision Procedure-All Vehicles................................1A-57 Component Part Replacement—Four-Season System.............................................................................. Condenser.......................................................................... Accumulator...................................................................... Blower Assembly............................................................ Evaporator Core.............................................................. Expansion Tube............................................................... Selector Duct and Heater C o re................................ Kick Panel Air Valve................................................... Plenum Air Valve.......................................................... Control Assembly........................................................... Master Switch and/or Blower Switch..................... Vacuum Tank................................................................... Blower Resistor U nit..................................................... Blower Motor Relay...................................................... Thermostatic Switch...................................................... Discharge Pressure Switch........................................... Fuse..................................................................................... Component Part Replacement - Overhead System (C-K Models)................................................................. Rear D uct......................................................................... Blower Motor Resistor.................................................. Blower Motor Assembly............................................... Expansion Valve.............................................................. Evaporator Core.............................................................. Blower Motor Switch.................................................... Fuse..................................................................................... Component Part Replacement - Floor Mounted System (G Models)...................................................... Condenser.......................................................................... Receiver-Dehydrator...................................................... Sight Glass Replacem ent............................................. Blower-Evaporator Cover............................................. Blower-Evaporator Assembly...................................... Expansion Valve and/or Evaporator C o re........... Blower M otor................................................................... Electrical Components................................................... Low Refrigerant Charge Protection System........ Super Heat Switch....................................................... Thermal Fuse................................................................. Circuit Breaker................................................................ Component Part Replacement - Overhead System (G M odels)..................................................................... Blower-Evaporator Shroud........................................... Blower Motor Assemblies............................................ Expansion Valves............................................................ Evaporator Core.............................................................. Resistor............................................................................... Blower Switch................................................................... Rear Blower R elay........................................................ Tie R elay.......................................................................... Component Part Replacement - Motor Home Chassis U nits................................................................. Condenser.......................................................................... 1A-58 1A-58 1A-58 1A-59 1A-59 1A-59 1A-60 1A-60 1A-60 1A-60 1A-61 1A-61 1A-61 1A-62 1A-62 1A-62 1A-63 1A-64 1A-64 1A-64 1A-65 1A-66 1A-66 1A-67 1A-67 1A-67 1A-67 1A-68 1A-68 1A-68 1A-68 1A-68 1A-70 1A-70 1A-70 1A-71 1A-71 1A-72 1A-72 1A-73 1A-73 1A-73 1A-75 1A-75 1A-75 1A-75 1A-75 1A-75 1A-75 LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G Receiver-Dehydrator.......................................................1A-76 Sight G lass........................................................................1A-76 Blower-Evaporator Assembly...................................... .1A-76 Blower Assembly............................................................ .1A-77 Expansion Valve, Evaporator Case or Core..........1A-77 Thermostatic and/or Blower Switches.................... .1A-78 Resistor...............................................................................1A-78 1A-19 F use.....................................................................................1A-78 Diagnosis..............................................................................1A-78 Refrigerant System.........................................................1A-78 Compressor Diagnosis....................................................1A-80 Insufficient Cooling........................................................ 1A-81 Electrical System Diagnosis........................................ .1A-83 Vacuum System Diagnosis.......................................... .1A-87 Special Tools.......................................................................1A-94 GENERAL DESCRIPTION FOUR-SEASON SYSTEM (C-K MODELS) Both the heating and cooling functions are performed by this system. Air enterning the vehicle must pass through the cooling unit (evaporator) and through (or around) the heating unit, in that order, and the system is thus referred to as a "reheat" system. The evaporator provides maximum cooling of the air passing through the core when the air conditioning system is calling for cooling. A thermostatic switch, located in the blower-evaporator case, acts to control compressor operation by sensing the fin temperature of the evaporator core. System operation is as follows: Air, either outside air or recirculated air, enters the system and is forced through the system by the blower. As the air passes through the evaporator core, it receives maximum cooling if the air conditioning controls are calling for cooling. After leaving the evaporator, the air enters the Heater and Air Conditioner Selector Duct Assembly where, by means of diverter doors, it is caused to pass through or to bypass the heater core in the proportions necessary to provide the desired outlet temperature. Conditioned air then enters the vehicle through either the floor distributor duct or the dash outlets. When, during cooling operations, the air is cooled by the evaporator to below comfort level, it is then warmed by the heater to the desired temperature. During "heating only" operations, the evaporator will not be in operation and ambient air will be warmed to the desired level in the same manner. The dash outlets are rectangular in design. The outlets can be rotated horizontally or vertically to direct air as desired. Under the left distributor duct is located a floor cooler which can be rotated to provide cooling air or shut off completely. cooling) and then directed into the vehicle through adjustable outlets located in the ducts. A thermostatic switch, located on the evaporator cover, is used to control compressor operation by sensing air temperature as it leaves the evaporator core. OVERHEAD SYSTEMS (C-K-G MODELS) These systems (C69 on C-K Models, C63 on G Models) operate in conjunction with the Four-Season System (CK Models) or Floor Mounted System (G M odels)-they do not operate independently. NOTE: Overhead system kits are available for non-factory installation on C-K Models, providing the vehicle is equipped with the front system. Like the floor-mounted system, these units are self contained, operating on inside (recirculated) air only. Air is drawn into the unit, passed through the evaporator core and then directed into the passenger compartment through adjustable outlets in the air distributor duct. System control is through the thermostatic switch in the front system. The only control on the overhead system is a three speed blower switch. MOTOR HOME CHASSIS SYSTEM This system performs the cooling functions only. When FLOOR MOUNTED SYSTEM (G MODELS) This system (C62) performs the cooling functions only. When heating (above ambient temperatures) is desired, the standard equipment heater must be used. When air conditioning is desired, be sure the heater is completely shut off. This self contained unit (fig. 22), operates on recirculated inside air only. Recirculated air is drawn into the unit, passes through the evaporator core (receiving maximum Fig. 22--C62 Interior Components (G Models) LIGHT DUTY TRUCK SERVICE MANUAL 1A-20 HEATER A N D AIR C O N D IT IO N IN G heating (above ambient temperatures) is desired, the vehicle heater must be used. When air conditioning is desired, the heater should be completely shut off. This self-contained unit is bracket mounted to the dash by the body manufacturer. It operates on inside (recirculated) air only. Air is drawn into the unit, passed through the evaporator core (receiving maximum cooling) and then directed into the vehicle through adjustable outlets. A thermostatic switch, located on the face plate is used to control compressor operation by sensing air temperature as it leaves the evaporator core. THEORY OF OPERATION HEAT We all know what air conditioning does for us but very few understand how or why it works. An air conditioner is functionally very similar to a refrigerator. A refrigerator is a simple mechanism which, surprisingly enough, works quite a bit like a teakettle boiling on a stove. That may sound far-fetched, but there is more similarity between the two than most of us would suspect. A modern refrigerator can make icecubes and keep food cool and fresh only because a liquid called the refrigerant boils inside the freezer. Everyone knows a boiling teakettle is "hot" and a refrigerator is "cold". We usually think of "cold" as a definite, positive condition. The only way we can define it is in a rather negative sort of way by saying "cold" is simply the lack of heat, just as darkness is the lack of light. We can’t make things cold directly. All we can do is remove some of the heat they contain and they will become cold as a result. And that is the main job of any icebox or refrigerator. Both are simply devices for removing heat. All substances contain some heat. Theoretically, the lowest temperature that any substance could obtain is 459° Fahrenheit below Zero. This is called "absolute zero" and anything warmer than this contains heat. Since man has never succeeded in getting all the heat out of an object, we must think about the transfer of heat from one object to another when talking about controlling temperatures. Fahrenheit) They can tell how hot a substance is, but they can’t tell us everything about heat. When we put a teakettle on a stove, we expect it to get hotter and hotter until it finally boils. All during the process, we can tell exactly how hot the water is by means of a thermometer (fig. 24). Our thermometer will show us that the flame is just as hot when we first put the teakettle on the stove as it is when the water finally boils. Why doesn’t the water boil immediately? Why does it take longer to boil a quart of water than a cupful? Obviously temperature isn’t the only measurement of heat. Even though heat is intangible, it can be measured by quantity as well as intensity. Thermometers indicate only the intensity of heat. The unit for measuring quantity of heat is specified as that amount necessary to make 1 pound of water 1 degree warmer (fig. 25). We call this quantity of heat a British Thermal Unit. Oftentimes, it is abbreviated to B.T.U. Perhaps we can get a better idea of these two characteristics of heat if we think of heat as a sort of coloring dye. If we add one drop of red dye to a glass of water, it will turn slightly pink. Another drop will make the water more reddish in color (fig. 26). The more drops of dye we add, the redder the water will get. Each drop of dye corresponds to 1 B.T.U. and the succeedingly deeper shades of red are like increases in temperature. Transfer of Heat The only thing that will attract heat is a colder object. Like water, which always flows downhill, heat always flows down a temperature scale - from a warm level down to a colder one. When we hold our hands out toward the fireplace, heat flows from the hot fire out to our cold hands (fig. 23). When we make a snowball, heat always flows from our warm hands to the colder snow. In an icebox, the ice always is colder than the stored food, so heat is drawn out of the warm food by the colder ice. Measurement of Heat Everyone thinks he knows how heat is measured. Thermometers are used in every home. (Whenever we speak of temperature from now on, we will mean Fig. 23-Heat Transfer LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-21 Fig. 25-Quantity of Heat = B.T.U. Fig. 24--Measurement of Heat It may seem a little puzzling to talk about heat in a book on air conditioning...but, when you stop to think about it, we are handling heat exclusively. Although we ordinarily think of an air conditioner as a device for making air cold, it does that indirectly. W hat it does is to take heat away from the air and transfer that heat outside the vehicle. We know now that cold is nothing more than the absence of heat, and that heat always flows from a warm object to a colder one. We also have a clearer idea of how heat is measured. From everything we’ve learned about heat so far, it seems to behave in a perfectly normal manner. Yet sometimes heat will disappear without leaving a single clue. Ice vs Water For Cooling Every once in a while in the old days, the iceman would forget to stop by to refill the icebox. Ocassionally, as the last sliver of ice melted away, somebody would come up with a bright idea. He would remember that the water in the drainpan always felt icecold when he emptied it other times. So, he would get the thermometer out and check its temperature. Sure enough, it usually was about as cold as the ice. Why not put the drainpan back in the ice compartment to keep things cold until the iceman returned the next day? For some strange reason, the icebox never stayed cold. The drain water soon got quite warm and in a couple of hours, the butter in the icebox would begin to melt, the milk would start to sour, and the vegetables would wilt. The drain water was only a few degrees warmer than the ice yet it didn’t draw nearly as much heat out of the stored foods. The difference between the behavior of cold drain water and ice is the real secret as to how any refrigerator works, and we can easily see this by using an ordinary thermometer. When we put a drainpan full of cold water into the ice compartment, we expect the heat to flow from the warm foods to the colder water. Remember, that heat always flows from a warm object to a colder object and when we add heat to water, it gets warmer. Each B.T.U. of heat added to a pound of water makes it one degree warmer. If we were to put a thermometer in the cold drain water, we would see the temperature gradually creep upwards. That is to be expected because heat is flowing into the cold water making it warmer. Before long the water would be as warm as the stored foods. Then the water could no longer attract heat because heat will not flow from one warm object to another equally warm object. Since we no longer can draw heat out of the foods we no longer are cooling them. Now, let’s see what happens when we put ice instead of cold water into the icebox. This time, we’ll set the thermometer on top of the ice (fig. 27). W hen we first look at the thermometer, it reads 32°. A couple of hours later, the ice chunk is smaller because some of the ice LIGHT DUTY TRUCK SERVICE MANUAL 1A 2 2 HEATER A N D AIR C O N D IT IO N IN G has already melted aw ay-but the thermometer still reads 32°. All this time, the ice has been soaking up heat, yet it never gets any warmer no matter how much heat it draws from the stored food. On the other hand, the cold drain water got progressively warmer as it soaked up heat. The addition of heat will make water warmer yet won’t raise the temperature of ice above the 32° mark. If we fill one drinking glass with ice and another with cold water, and put both glasses in the same room where they could absorb equal amounts of heat from the room air, we will find it takes much, much longer for the ice to melt and reach room temperature than it did for the water in the other glass to reach the same temperature. Obviously, most of the heat was being used to melt the ice. But it was the heat that apparently disappeared or was transformed because it couldn’t be located with a thermometer. To describe this disappearing heat, scientists chose the word "latent" which means hidden. Latent Heat So latent heat is nothing more nor less than hidden heat which can’t be found with a thermometer. At first it was thought that latent heat was in the water that melted from the ice. But that wasn’t exactly the right answer because, upon checking water temperature as it melts from ice, it will be found that it is only a shade warmer than the ice itself. It is not nearly warm enough to account for all the heat the ice had absorbed. The only possible answer is that the latent heat had been used up to change the ice from a solid into a liquid. Many substances can be either a solid, or a liquid, or a gas. It just depends on the temperature whether water for example was a liquid, or a solid (ice), or gas (steam) (fig. 28). All solids soak up huge amounts of heat without getting any warmer when they change into liquids, and the same thing will happen when a substance changes from a liquid into a gas. Fig. 2 7 -M e ltin g Ice Remains at 32" Fig. 2 8 -T e m p e ra tu r e D e te r m in e s T h e S ta te O f W a te r Put some water in a teakettle, set it over a fire and watch the thermometer as the water gets hotter and hotter, the mercury will keep rising until the water starts to boil. Then the mercury seems to stick at the 212° mark. Put more wood on the fire, despite all the increased heat, the mercury will not budge above the 212° mark (fig. 29). No matter how large or hot you make the flame, you can’t make water any hotter than 212° at sea level. As a liquid changes into a gas, it absorbs abnormally great amounts of heat without getting any hotter. Now we have two different kinds of latent heat, which are quite a bit alike. To keep their identities separate, the first one is called latent heat of fusion, which means the same as melting. The other kind is called latent heat of vaporization because that means the same as evaporation. Refrigeration It may seem as though we have discussed heat instead of Fig. 29--Boiling Water Never Exceeds 212° at Sea l_evel LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G refrigeration. But in doing so, we have learned how a simple icebox works. It’s because the latent heat of fusion gives ice the ability to soak up quantities of heat without getting any warmer. Since it stays cold, it can continue to draw heat away from stored foods and make them cooler. The latent heat of vaporization can be even better because it will soak up even more heat. Whenever we think of anything boiling, we think of it being pretty hot, but that’s not true in every case. Just because water boils at 212° doesn’t mean that all other substances will boil at the same temperature. Some would have to be put into a blast furnace to make them bubble and give off vapor. On the other hand, others will boil violently while sitting on a cake of ice. And so each substance has its own particular boiling point temperature. But regardless of whether it is high or low, they all absorb unusually large quantities of heat without getting any warmer when they change from a liquid into a vapor. Consequently, any liquid that will boil at a temperature below the freezing point of water, will make ice cubes and keep vegetables cool in a mechanical refrigerator. REFRIGERANTS The substance that carries heat out of a refrigerator cabinet is the refrigerant. There are many refrigerants known to man. In fact, any liquid that can boil at temperatures somewhere near the freezing point of water can be used. But a boiling point below the temperature at which ice forms is not the only thing that makes a good refrigerant. A refrigerant should also be non-poisonous and non-explosive to be safe. Besides that, we want a refrigerant that is non-corrosive and one that will mix with oil. Chemists tried to improve existing natural refrigerants. But after exploring along that line, they still hadn’t succeeded. They started from scratch and juggled molecules around to make an entirely new refrigerant. Eventually they succeeded by remodeling the molecules in carbon tetrachloride. This is the same fluid that is used in fire extinguishers and dry-cleaners’ solvents. From this fluid, the chemists removed two chlorine atoms and replaced them with two flourine atoms. This newly formed fluid carried the technical chemical name of dichlorodifluoromethane. Today, it is sold commer­ cially by manufacturers as R efrigerant-12 or R-12. Flourine is a temperamental substance, under most conditions, it is toxic and highly corrosive. After it is manufactured, it has to be stored in special containers because it will eat through glass and will dissolve most metals in short order. Despite its rambunctious character though, fluorine is completely tamed when it is combined with the other substances that go to make up the refrigerant. Each is 1A-23 non-toxic, non-inflammable, non-explosive, and nonpoisonous, however, breathing large quantities of R-12 should be avoided. Refrigerant-12 Refrigerant-12, which we use in Air Conditioning Systems, boils at 21.7° below zero. Picture a flask of R-12 sitting on the North Pole boiling away just like a teakettle on a stove. No one would dare pick up the flask with his bare hands because, even though boiling, it would be so cold and it would be drawing heat away from nearby objects so fast that human flesh would freeze in a very short time. If we were to put a flask of R-12 inside a refrigerator cabinet, it would boil and draw heat away from everything surrounding it (fig. 30). So long as any refrigerant remained in the flask, it would keep on soaking up heat until the temperature got clear down to 21.7° below zero. Now we can begin to see the similarity between a boiling teakettle and a refrigerator. Ordinarily we think of the flame pushing heat into the teakettle. Yet, it is just as logical to turn our thinking around and picture the teakettle pulling heat out of the flame. Both the teakettle and the flask of refrigerant do the same thing-they both draw in heat to boil although they do so at different temperature levels. There also is another similarity between the icebox and the mechanical refrigerator. In the icebox, water from melting ice literally carried heat out of the cabinet. In our simple refrigerator, rising vapors do the same job. Reusing R-12 R-12, or any other refrigerant, is too expensive just to let float away into the Atmosphere. If there was some way to remove the heat from the vapor and change it back into a liquid, it could be returned to the flask and used over again (fig. 31). LIGHT DUTY TRUCK SERVICE MANUAL 1A-24 HEATER A ND AIR C O N D IT IO N IN G ra3S2Qp3pj|3 This is where pressure helps, with pressure, we can compress the vapor, thereby concentrating the heat it contains. When we concentrate heat in a vapor that way, we increase the intensity of the heat or, we increase the temperature, because temperature is merely a measure­ ment of heat intensity (fig. 32). Pressure in Refrigeration Fig. 3 1- R eu sin g R e frig e ra n t That is where we find the biggest difference between the old icebox and the modern refrigerator. We used to put in new ice to replace that lost by melting. Now we use the same refrigerant over and over again. We can change a vapor back into a liquid by chilling it, or do the same thing with pressure. When we condense a vapor we will find that the heat removed just exactly equals the amount of heat that was necessary to make the substance vaporize in the first place. This is called the latent heat of vaporization - the heat that apparently disappeared when a liquid boiled into a vapor—again reappears - when that same vapor reverts back into a liquid. It is just like putting air into a balloon to expand it and then letting the same amount of air out again to return the balloon to its original condition. We know that any substance will condense at the same temperature at which it boiled. This temperature point is a clear-cut division like a fence. On one side, a substance is a liquid. Immediately on the other side it is a vapor. Whichever way a substance would go, from hot to cold or cold to hot, it will change its character the moment it crosses over the fence. W ater will boil at 212° under normal conditions. Naturally, we expect steam to condense at the same temperature. But whenever we put pressure on steam, it doesn’t. It will condense at some temperature higher than 212°. The greater the pressure, the higher the boiling point and the temperature at which a vapor will condense. This is the reason why pressure cookers cook food faster, since the pressure on the water permits it to boil out at a higher temperature. We know that R-12 boils at 21.7° below zero. A thermometer will show us that the rising vapors, even though they have soaked up lots of heat, are only slightly warmer. But the vapors must be made warmer than the room air if we expect heat to flow out of them. The condensing point temperature must be above that of room air or else the vapors won’t condense. Because we must use pressures and gauges in air conditioning service, the following points are mentioned so that we will all be talking about the same thing when we speak of pressures. All pressure, regardless of how it is produced, is measured in pounds per square inch (psi). Atmospheric Pressure is pressure exerted in every direction by the weight of the atmosphere. At sea level atmospheric pressure is 14.7 psi. At higher altitudes air has less weight (lower psi). Any pressure less than atmospheric (14.7) is known as a partial vacuum or commonly called a vacuum. A perfect vacuum or region of no pressure has never been mechanically produced. Gauge pressure is used in refrigeration work. Gauges are calibrated in pounds (psi) of pressure and inches of Mercury for vacuum. At sea level, "O " lbs. gauge pressure is equivalent to 14.7 lbs. atmospheric pressure. Pressure greater than atmospheric is measured in pounds (psi) and pressure below atmospheric is measured in inches of vacuum. The "O " on the gauge will always correspond to the surrounding atmospheric pressure, regardless of the elevation where the gauge is being used. Pressure-Temperature Relationships of R-12 A definite pressure and temperature relationship exists in the case of liquid refrigerants and their saturated vapors. Increasing the temperature of a substance causes it to expand. When the substance is confined in a closed container, the increase in tem perature will be accompa­ nied by an increase in pressure, even though no mechanical device was used. For every temperature, there will be a corresponsing pressure within the container of refrigerant. A table of the temperaturepressure relationship of R-12 is presented below. Pressures are indicated in gauge pressure, either positive pressure (above atmospheric) in pounds or negative pressure (below atmospheric) in inches of vacuum. Thus if a gauge is attached to a container of R-12 and the room temperature is 70°, the gauge will register approximately 70 psi pressure; in a 100° room, the pressure would be 117 psi. Pressure and Flow When we use a tire pump to inflate an automobile tire, we are creating pressure only because we are "pushing" against the air already entrapped inside the tire. If a tire has a puncture in it, you could pump all day, and still not be able to build up any pressure. As fast as you would LIGHT DUTY TRUCK SERVICE MANUAL HEATER AND AIR C O N D IT IO N IN G °F Pressure (psi) -4 0 -3 5 -3 0 -2 5 -2 0 - 15 - 10 - 5 0 + 5 + 10 + 15 + 20 + 25 + 30 + 32 + 35 + 40 + 45 11 . 0 * 8 .3 * 5 .5 * 2 .3 * 0.6 2.4 4.5 6.8 9.2 11.8 14.7 17.7 21.1 24.6 28.5 30.1 32.6 37.0 41.7 °F + + + + + + + + + + + + + + + + + + + 50 55 60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 140 150 Pressure (psi) 46.7 52.0 57.7 63.7 70.1 76.9 84.1 91.7 99.6 108.1 116.9 126.2 136.0 146.5 157.1 167.5 179.0 204.5 232.0 In c h e s o f V a c u u m pump the air in, it would leak out through the puncture. Unless you have something to push against—to block the flow of air—you can’t create more than a mere semblance of pressure. The same situation holds ture in an air conditioning system. The compressor can pump refrigerant vapor through the system, but unless it has something to push against, it cannot build up pressure. All the compressor would be doing would be to circulate the vapor without increasing its pressure. We can’t just block the flow through the system entirely. All we want to do is put pressure on the refrigerant vapor so it will condense at normal temperatures. This must be done sometime after the vapor leaves the evaporator and before it returns again as a liquid. High pressure in the evaporator would slow down the boiling of the refrigerant and penalize the refrigerating effect. 1A-25 and, of course, the float rides up along with it. When the surface level of the refrigerant liquid reaches a desired height, the float will have risen far enough to close the valve and stop the flow of refrigerant liquid. We have described the float and valve action as being in a sort of definite wide open or tight shut condition. Actually, the liquid level falls rather slowly as the refrigerant boils away. The float goes down gradually and gradually opens the valve just a crack. At such a slow rate of flow, it raises the liquid level in the evaporator very slowly. It is easy to see how it would be possible for a stablized condition to exist. By that, we mean a condition wherein the valve would be opened enough to allow just exactly the right amount of refrigerant liquid to enter the system to take the place of that leaving as a vapor. Refrigerator Operation W e’ve now covered all the scientific ground-rules that apply to refrigeration. Try to remember these main points. All liquids soak up lots of heat without getting any warmer when they boil into a vapor, and, we can use pressure to make the vapor condense back into a liquid so it can be used over again. W ith just that amount of scientific knowledge, here is how we can build a refrigerator. We can place a flask of refrigerant in an icebox. We know it will boil at a very cold temperature and will draw heat away from everything inside the cabinet (fig. 32). We can pipe the rising vapors outside the cabinet and thus provide a way for carrying the heat out. Once we get the heat-laden vapor outside, we can compress it with a pump. With enough pressure, we can squeeze the heat Controlling Pressure and Flow Pressure and flow can be controlled with a float valve, or with a pressure-regulating valve. The float valve type will give us a better idea of pressure and flow control, let’s look at it first. It consists simply of a float that rides on the surface of the liquid refrigerant. As the refrigerant liquid boils and passes off as a vapor, naturally the liquid level drops lower and lower. Correspondingly, the float, because it rides on the surface of the refrigerant, also drops lower and lower as the liquid goes down. By means of a simple system of mechanical linkage, the downward movement of the float opens a valve to let refrigerant in. The incoming liquid raises the fluid level Fig. 32--Basic Refrigerant Circuit LIGHT DUTY TRUCK SERVICE MANUAL 1A-26 HEATER AND AIR C O N D IT IO N IN G out of "cold" vapor even in a warm room. An ordinary radiator will help us get rid of heat. By removing the heat, and making the refrigerant into a liquid, it becomes the same as it was before. So, we can run another pipe back into the cabinet and return the refrigerant to the flask to be used over again. That is the way most mechanical refrigerators work today. Now, let’s look at air conditioning to see the benefits of air conditioning and how an air conditioner works. AIR CONDITIONING Because air-conditioning has always been very closely allied with mechanical refrigeration, most of us are apt to think of it only as a process for cooling room air. Air Conditioning goes beyond the mere cooling of the air. It controls the humidity, cleanliness and circulation of the air. Whenever it gets warm and muggy in the summertime, someone is almost sure to say, "It’s not the heat...it’s the humidity." But that is only partly right. Actually it is a combination of the two that makes us feel so warm...temperature alone is not the only thing that makes us uncomfortable. Humidity is the moisture content of the air. To a certain extent, it is tied in with the temperature of the air. Warm air will hold more moisture than will cold air. When air contains all the moisture it can hold, it is saturated, and the relative humidity is 100%. If the air contains only half as much water as it could hold at any given temperature, we say that the relative humidity is 50%. If it contains only a fifth of its maximum capacity, we say that the relative humidity is 20%. This amount of water vapor, or relative humidity, affects the way we perspire on hot days. Nature has equipped our bodies with a network of sweat glands that carry perspiration to the skin surfaces. Normally, this perspiration evaporates and absorbs heat just like a refrigerant absorbs heat when it is vaporized in a freezer. Most of the heat is drawn from our bodies, giving us a sensation of coolness. A drop of alcohol on the back of your hand will demonstrate this principle convincingly. Alcohol is highly volatile, and will evaporate very rapidly and absorb quite a bit of heat in doing so, making the spot on your hand feel cool. The ease and rapidity with which evaporation takes place, whether it be alcohol or perspiration, governs our sensation of coolness and to a certain extent, independently of the temperature. The ease and rapidity of the evaporation are directly affected by the relative humidity or comparative dampness of the air. When the air is dry, perspiration will evaporate quite readily. But when the air contains a lot of moisture, perspiration will evaporate more slowly; consequently less heat is carried away from our body. From the standpoint of comfort, air-conditioning should control the relative humidity of the air as well as its temperature. By reducing the humidity, we oftentimes can be just as "cool" in a higher room tem perature than otherwise would be comfortable. Laboratory tests have shown that the average person will feel just as cool in a temperature of 79° when the relative humidity is down around 30% as he will in a cooler temperature of 72° with a high relative humidity of 90%. There are practical limits though within which we must stay when it comes to juggling humidity. For comfort, we can’t go much below a relative humidity of 30% because anything lower than that would cause an unpleasant and unhealthy dryness in the throat and nasal passages. Summertime temperatures of 85° sometimes bring with them relative humidities around 75% to 80%. To gain maximum human comfort, an air conditioning system should cool the air down and reduce the humidity to comfortable limits. Along with the cooling job it does, the evaporator unit also removes much of the moisture from the air. Everyone is familiar with the sight of thick frost on the freezer of a refrigerator. That frost is simply frozen moisture that has come out of the air. The evaporator unit as an air conditioning system does the same thing with this one exception. Because its temperature is above the freezing point, the moisture does not collect in the form of ice or frost. The moisture remains fluid and drips off the chilling unit. A further advantage of air conditioning is that dust and pollen particles are trapped by the wet surfaces of the evaporator core and then drained off along with the condensed moisture. This provides very clean, pure air for breathing. BASIC AIR CONDITIONER When we look at an air conditioning unit, we will always find a set of coils or a finned radiator core through which the air to be cooled passes. This is known as the "evaporator". It does the same job as the flask of refrigerant we spoke about previously. The refrigerant boils in the evaporator. In boiling, of course, the refrigerant absorbs heat and changes into a vapor. By piping this vapor outside the car we can bodily carry out the heat that caused its creation. Once we get vapor out of the evaporator, all we have to do is remove the heat it contains. Since heat is the only thing that expanded the refrigerant from a liquid to a vapor in the first place, removal of that same heat will let the vapor condense into a liquid again. Then we can return the liquid refrigerant to the evaporator to be used over again. Actually, the vapor coming out of the evaporator is very cold. We know the liquid refrigerant boils at temperatures considerably below freezing and that the vapors arising from it are only a shade warmer even LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-27 LIGHT DUTY TRUCK SERVICE MANUAL 1A-28 HEATER A N D AIR C O N D IT IO N IN G though they do contain quantities of heat. Consequently, we can’t expect to remove heat from sub-freezing vapors by "cooling" them in air temperatures that usually range between 60° and 100°...heat refuses to flow from a cold object toward a warmer object. But with a pump, we can squeeze the heat-laden vapor into a smaller space. And, when we compress the vapor, we also concentrate the heat it contains. In this way, we can make the vapor hotter without adding any heat. Then we can cool it in comparatively warm air. That is the only responsibility of a compressor in an air conditioning system. It is not intended to be a pump just for circulating the refrigerant. Rather, its job is to exert pressure for two reasons. Pressure makes the vapor hot enough to cool off in warm air. At the same time, the compressor raises the refrigerant’s pressure above the condensing point at the temperature of the surrounding air so it will condense. As the refrigerant leaves the compressor, it is still a vapor although it is now quite hot and ready to give up the heat that it absorbed in the evaporator. One of the easiest ways to help refrigerant vapor discharge its heat is to send it through a radiator-like component known as a condenser. The condenser really is a very simple device having no moving parts. It does exactly the same job as the familiar radiator in a typical home steam-heating system. There, the steam is nothing more than water vapor. In passing through the radiator, the steam gives up its heat and condenses back into water. The purpose of the condenser, as the name implies, is to condense the high pressure, high temperature refrigerant vapor discharged by the compressor into a high pressure liquid refrigerant. This occurs when the high pressure, high tem perature refrigerant is subjected to the considerably cooler metal surfaces of the condenser. This is due to the fundamental laws, covered earlier, which state that "heat travels from the warmer to the cooler surface," and that "when heat is removed from vapor, liquid is produced." When the refrigerant condenses into a liquid, it again is ready for boiling in the evaporator. So, we run a pipe from the condenser back to the evaporator. MAIN UNITS OF THE SYSTEM These three units then; the evaporator, the compressor, and the condenser...are the main working parts in any typical air conditioning system. We have the evaporator where the refrigerant boils and changes into a vapor, absorbing heat as it does so. We have the pump or compressor to put pressure on the refrigerant so it can get rid of its heat. And we have a condenser outside the car body to help discharge the heat into the surrounding air. Now let’s look at the compressor in detail, and some of the components that work with these main units to complete the air conditioning system. Compressor The prime purpose of the compressor (fig. 34) is to take the low pressure refrigerant vapor produced by the evaporator and compress it into a high pressure, high temperature vapor which will be sent on to the condenser. It utilizes the principle that "when a vapor is compressed, both its pressure and temperature are raised" which we have already discussed. The compres­ sor is mounted above the engine in a special rubber mounted bracket and is belt driven from the engine through an electromagnetic clutch pulley on the compressor. The compressor has three double-acting pistons, making it a six cylinder compressor. The compressor has a 1.5 inch bore and 1.1875 inch stroke, giving it a total displacement of 12.6 cu. in. Identification of the compressor is by model and serial num ber stamped on a plate on top of the compressor. Clutch-Pulley The movable part of the clutch drive plate is in front of the pulley and bearing assembly. The armature plate, the movable member, is attached to the drive hub through driver springs and is riveted to both members. The hub of the drive plate is pressed over a square drive key located in the compressor shaft. A spacer and retainer ring are assembled to the shaft and the assembly is held in place with a self-locking nut. The pulley rim, power element ring and pulley hub are formed into a final assembly by molding a frictional material between the rim and the hub with the power element ring imbedded in the forward face of the assembly. A two-row ball bearing is pressed into the pulley hub and held in place by a retainer ring. The entire pulley and bearing assembly is then pressed over the front head of the compressor and secured by a retainer ring. Clutch Coil The coil is molded into the coil housing with a filled epoxy resin and must be replaced as a complete assembly. Three protrusions on the rear of the housing fit into alignment holes in the compressor front head. A retainer ring secures the coil and housing in place. The coil has 3.85 ohms resistance at 80°F. ambient temperature and will require no more than 3.2 amperes at 12 volts D.C. Since the clutch coil is not grounded internally, a ground lead is required as well as a "hot" lead. Shaft Seal The main shaft seal, located in the neck of the compressor front head, consists of the seal assembly with its ceramic seal face in a spring loaded cage. An "O " ring seal, located within the ceramic seal, provides a seal to the shaft surface. The contact surface of the shaft seal seat is finished to a high polish and must be protected against nicks, scratches and even fingerprints. Any surface damage will cause a poor seal. An "O " ring, LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1 20 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 21 2 22 3 23 4 5 24 Rear Head Rear Head to Shell " O " Ring Rear Discharge Valve Plate Rear Suction Reed Plate Piston Ring Piston Drive Ball Ball Seat Piston Front Suction Reed Plate Front Discharge Valve Plate Front Head to Shell " O ” Ring F ront Head Coil and Housing Assembly Coil Housing Retainer Ring 6 25 7 8 26 27 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 9 10 28 29 11 12 30 13 31 14 32 15 33 Pulley and Bearing Assembly Pulley Bearing Pulley Bearing Retainer Ring Pulley and Bearing Retainer Ring Clutch Hub and Drive Plate Assembly Super Heat Switch, " O ” Ring and Retainer Ring (G Models Only) High Pressure Relief Valve Oil Pump Gears Mainshaft Bearing (Rear) Oil Inlet Tube " 0 " Ring Oil Inlet Tube Wobble Plate and Mainshaft Assembly Thrust Race 16 34 35 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 1A-29 17 18 19 3 6 37 38 3 9 40 Thrust Bearing Thrust Race Compressor Shell C ylinder Assembly Shaft Seal Shaft Seal Seat ” 0 " Ring Shaft Seal Seat Shaft Seal Seat Retainer Ring Absorbent Sleeve Absorbent Sleeve Retainer Spacer Clutch Hub Retainer Ring Shaft Nut Fig. 34 -Six Cylinder Compressor- Cross Sectional View located in an internal groove in the neck of the front head provides a seal with the outer diam eter of the seal seat. A retainer ring, tapered side away from the seat, secures the seat in place. The hub and armature plate must be removed to gain access to the seal. A shaft seal kit contains all necessary replacement parts for field service. After removing the clutch drive, pulley-bearing and coil housing assemblies, the rear head and internal mechanism (fig. 34) may be removed from the compressor shell. Four threaded stu4s, welded to the compressor shell, locate the rear head and four lock nuts secure it in place. Rear Head The rear head (fig. 35) has a machined cavity in the center for the oil pump gears. This cavity, in all compressors, is machined so that the eccentricity of the bore is approximately .042 inch to the LEFT of the centerline of the cavity. The counterclockwise rotation compressor used in some other systems has the eccentricity machined approximately .042 inch to the RIGHT of the cavity centerline. A small diameter hole is LIGHT DUTY TRUCK SERVICE MANUAL 1A-30 HEATER A ND AIR C O N D IT IO N IN G drilled in the head between the two. The unit number is stamped on a plate attached to the counterclockwise rotation head and a decal arrow indicates the direction of rotation. Mainshaft The central mainshaft, driven by the clutch-pulley when the coil is energized, extends through the front head to the rear head and oil pump cavity of the compressor. The shaft revolves in needle roller bearings located in the front and rear halves of the cylinder assembly. A 3/16" internally drilled passage extends through the shaft from the rear oil pump cavity to the shaft seal cavity in the front compressor head. Four .078 inch holes, drilled at 90° to the main passage, direct oil under pump pressure to the shaft seal surfaces, thrust bearings and shaft-cylinder bearings. Wobble Plate The wobble plate is an angular shaped member pressed onto the mainshaft forming the mainshaft and wobble plate assembly (fig. 35). A woodruff key prevents movement of the plate around the shaft. Location of the plate on the shaft is factory set and must not be changed. The very smooth angular faces of the plate are ground to be parallel within .0003 inches of each other. The plate changes the rotating action of the shaft into the reciprocating driving force for three pistons. The driving force is applied, through the drive balls and ball seats (shoe discs) to the midpoint of each of the double end pistons. Cylinder Block The cylinder block consists of a front and a rear half. Three piston bores are line bored in each half during production to assure proper alignment and parallelism. The two halves must be serviced as an assembly to assure correct relationship of parts. Pistons simple field gauging operations. Seats are marked with their size which corresponds to the last three digits of the piece part number. Selection from this group must be made to provide .0005 inch to .0010 inch total clearance between the ball seats and the wobble plate at the tightest place throughout its 360° rotation (fig. 36). Thrust Bearings The thrust bearings, sandwiched between two thrust races (see below) are located between the shoulders of the wobble plate and the shoulders of both the front and rear cylinder hubs. Thrust Races The steel thrust races are ground to fixed thicknesses. A total of 14 races in increments of .0005 inch thickness are available for field service. As in the case of the ball seats the thrust races will be identified on the part by their thickness, the number on the race corresponding to the last three digits of the piece part number. The FRONT combination of a race, bearing and race is selected to provide the proper head clearance between the top of the cylinder and the underside of the suction and discharge valve plates. The REAR end combination of bearing and races is selected to obtain .0005 inch low limit to .0015 inch high limit running clearance between the hub surfaces of the wobble plate and the front and rear hubs of the cylinder (fig. 36). This allows .001 inch tolerance between the high and low limits. Oil Pump Gears The oil pump gears are made of sintered iron. The inner, or driver gear has a "D " shaped hole in the center which fits over a similar area on the rear of the mainshaft. Shell The compressor shell has a mounting flange on the front end and four threaded studs welded to the outside of the rear end. The oil sump is formed into the shell and a baffle plate is welded over the sump on the inside of the shell. The cast aluminum double end pistons (fig. 35), have grooves to receive piston rings. Each ring has an oil scraper groove which should face away from the piston face. Two oil return passages are drilled from each ring groove. A notch in the casting web of each piston identifies the end of the piston which should be positioned toward the front end of the compressor. A spherical cavity is located on both inner faces of each piston to receive the piston drive balls. Both front and rear heads have an irregular shaped casting web. These webs provide the necessary seals to the surfaces of the discharge plates and prevent high pressure vapor from flowing into the low pressure cavity. Drive Balls Suction Screen The hardened steel drive balls have a micro-finish. They are manufactured to a .0001 inch spherical tolerance and a .6248 - .6250 inch diameter tolerance. A fine mesh inlet (or suction) screen is located in the low pressure cavity of the rear head. Its purpose is to stop any material which could damage the compressor mechanism. Ball Seats The bronze ball seats have one flat side, which contacts the wobble plate, and one concave surface into which the drive ball fits. Ten seats are provided in .0005 inch thickness variations including a basic ZERO seat for Heads Suction Cross-Over Cover The suction cross-over cover, with its neoprene seal is pressed into the dove-tail cavity in the front and rear cylinder castings to form a passage for the low pressure LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. S h a ft N u t C lutch H ub R etain er R ing Spacer C lutch H u b and D rive Plate A ssem bly Pulley and Bearing R etain er Ring Pulley Bearing R etainer Ring Pulley Bearing Pulley C oil Housing R etain er R ing C oil Housing Compressor Shell A bsorbent Sleeve A bsorbent Sleeve R etainer O il D rain Plug and Gasket F ro n t Head-to-Shell " 0 ” Ring 16. 17. 18. 19. 2 0. 21. 22. 2 3. 24. 25. 2 6. 27. 28. S h a ft Seal Seat R etain er Ring S h a ft Seal Seat S h a ft Seal S h a ft Seal Seat " 0 ” R ing Compressor F ro n t Head F ro n t Discharge Valve Plate F ro n t S uction Reed Valve Discharge Crossover T u b e F ro n t " 0 ” Ring and Spacer M ainshaft F ro n t Bearing H ead Locating Pins F ro n t C ylin d er H alf F ro n t T h ru st Race and Bearing Pack S uction Crossover Cover D rive Key 44. 2 9. 30. Discharge Crossover 31. 32. Tube Piston Ring Piston F ro n t D rive Ball Piston F ro n t Ball 46. 3 3. Seat Piston Piston R ear Ball Seat Piston Rear D rive 47. 48. 49. Ball Piston R ing D rive S h a ft and W obble Plate Assem bly Rear T h ru s t Race and Bearing Pack Rear C y lin d e r H a lf 50. 51. 34. 35. 36. 37. 38. 39. 40. 41. 42. 4 3. O il In le t T u b e " 0 ” Ring O il In le t T u b e M ainshaft Rear Bearing 45. 52. 1A-31 Discharge Crossover T u b e Rear " 0 ” R ing and Spacer Rear S u c tio n Reed Plate Rear Discharge V alve Plate O il Pum p D rive Gear O il Pum p D riven Gear Rear H ead-to-S hell " 0 ” Ring S train e r Screen C om pressor Rear Head Superheat S w itc h , " 0 ” R ing and R etain er Ring (G Models O n ly) 53. High Pressure R elief 54. V alve and " 0 ” Ring R ear H ead-to-S hell R etain ing N uts 55. C om pressor-toC onn ector " 0 " Ring Fig. 3 5 -Six Cylinder Compressor -Exploded View vapor to flow from the rear head of the compressor to the front head. Discharge Cross-Over Tube Since the double acting pistons supply high pressure vapor at both ends of the compressor the discharge tube is needed to supply a path for the high pressure vapor to pass from the front to the rear head. Should the cylinder halves be separated during service operations a service type discharge tube must be substituted. Suction Reed Valves A separate three-reed suction valve disc is assembled to both front and rear heads. These reeds open when the piston is on the intake portion of the stroke to allow the low pressure vapor to flow into the cylinder. When the piston reverses and begins the compression portion of its stroke the reed valves close against their seats, thus preventing the high pressure vapor from being forced back into the low side of the system. Discharge Valves The two discharge valve plate assemblies act to direct high pressure vapor into the head castings. When the piston reverses into its suction stroke the high pressure on the opposite side of the plate causes the reeds to close thus maintaining the differential of pressure between high and low pressure areas. The discharge plates include the valves and the retainers which prevent the LIGHT DUTY TRUCK SERVICE MANUAL 1A-32 HEATER A N D AIR C O N D IT IO N IN G Refrigerant Lines BALL SEATS USED TO GIVE .0005 TO .0010 TOTAL CLEARANCE THRUST UNIT CONTROLS HEAD CLEARANCE '* ^ 0 1 0 Special refrigerant hose lines are required to carry the refrigerant liquid and vapor between the various system components. The hose line with the smallest diameter is called the high pressure liquid line. It is routed from the condenser or receiver-dehydrator to the evaporator or thermostatic expansion valve. The large diameter hose line connecting the compressor and evaporator is the low pressure vapor line. The large diam eter hose between the compressor and condenser is the high pressure vapor discharge line. These hoses are constructed with a synthetic material core covered with a woven metal mesh which is, in turn, covered by a woven fabric and coated for extra protection. This hose is so constructed to withstand the extreme pressures and temperatures found in the modern refrigeration system. None but special refrigerant type hoses should be used. THRUST UNIT CONTROLS RUNNING CLEARANCE .0005 TO .0015 Fig. 36- General Running Clearances high pressure from distorting the valves during the pressure stroke of the piston. Head to Shell Seals Two large diameter "O " rings internally seal the front and rear heads to the shell. A chamfered edge on the head castings creates a squeezing action between the discharge valve plates, the compressor, and the inside surface of the shell. Compressor Connector Compressor connectors, are attached to the compressor rear head by means of a single bolt and lock washer. All have inlet and outlet connections connected by a strap to form an integral unit. G Models have gauge fittings located on the muffler and compressor inlet line. Motor Home Chassis unit fittings are located on the inlet and outlet lines. C-K model gauge fittings are located on the accumulator and evaporator inlet line. All fittings are equipped with a valve core. Pressure Relief Valve The pressure relief valve, located on the compressor rear head, is simply a safety valve designed to open automatically if the system pressure should reach a pre­ determined level high enough to cause system damage. After the pressure drops to a safe level the valve will close. After such an occurrence, the system should be thoroughly checked to discover and correct the cause of the abnormal pressure increase, and then should be purged, evacuated and charged. All systems make use of swaged type connections (hose to metal fittings) with metal to metal fittings being made using "O " rings. Care must be taken when making these connections that they not be turned down too tightly or damage to the "O " rings may result. Flexible refrigerant hoses should not be permitted to contact the hot engine manifold nor should they be bent into a radius of less than 10 times their diameter. Muffler A muffler, located in the high pressure line from the compressor to the condenser, serves as a surge chamber for high pressure gas to reduce the noise level of the system while in operation. The muffler is actually a welded portion of the compressor connector assembly. It is found on all truck air conditioning systems. Fan Slip Clutch A special engine fan is used on most systems. It is an 18 inch five bladed fan, limited by means of a viscous clutch to a maximum speed of 3200 rpm, regardless of the speed of the engine. The silicone fluid in the clutch transmits only enough torque to drive the fan at this limited speed, thus avoiding excessive noise and power consumption by the fan at higher engine speeds. A temperature modulating device further limits fan speed to 1000 rpm. until am bient tem perature at the modulating device reaches 140°F. at which time fan speed will be allowed to increase to 3200 rpm. Some adjustment of the modulating device is possible. Condenser In a properly charged system, the condenser delivers sub­ cooled liquid. This is because all the vapor condenses before the end of the condenser and the remaining portion of the condenser subcools the liquid. Receiver-Dehydrator (G and Motor Home Chassis Models) The receiver-dehydrator, serving as a reservoir for LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-33 storage of high pressure liquid produced in the condenser, incorporates a screen sack filled with the dehydrating agent. The receiver-dehydrator, used prim arily as a liquid storage tank, also functions to trap minute quantities of moisture and foreign material which may have remained in the system after installation or service operations. A refrigerant sight glass is built into the receiverdehydrator to be used as a quick check of the state and condition of charge of the entire system. The receiverdehydrator is mounted near the condenser. Sight Glass (G and Motor Home Chassis Models) While having no real function to perform in the system, the sight glass is a valuable aid in determining whether or not the refrigerant charge is sufficient and for eliminating some guess work in diagnosing difficulties. The sight glass, is built into the receiver-dehydrator outlet connection and is designed and located so that a shortage of refrigerant at this point will be indicated by the appearance of bubbles beneath the glass. The dust cap provided should be kept in place when the sight glass is not in use. Fig. 37- Expansion Valve Thermostatic Expansion Valve (Fig. 37) C-K Overhead, G Floor and Overhead and Motor Home Chassis systems use a thermostatic expansion valve in place of a float system. The valve consists primarily of the power element, body, actuating pins, seat and orifice. At the high pressure liquid inlet, is a fine mesh screen which prevents dirt, filings or other foreign matter from entering the valve orifice. When the valve is connected in the system, high pressure liquid refrigerant enters the valve through the screen from the receiver-dehydrator or condenser and passes on to the seat and orifice. Upon passing through the orifice the high pressure liquid becomes low pressure liquid. The low pressure liquid leaves the valve and flows into the evaporator core where it absorbs heat from the evaporator core and changes to a low pressure vapor, and leaves the evaporator core as such. The power element bulb is clamped to the low pressure vapor line just beyond the outlet of the evaporator (fig. 37). The operation of the valve is quite simple. It is a matter of controlling opposing forces produced by a spring and the refrigerant pressures. For example: The pressure in the power element is trying to push the seat away from the orifice, while the adjusting spring is trying to force the seat toward the orifice. These opposing pressures are established in the design of the valve so that during idle periods the adjusting spring tension and the refrigerant pressure in the cooling coil are always greater than the opposing pressure in the power element. Therefore, the valve remains closed. When the compressor is started, it will reduce the pressure and temperature of the refrigerant in the cooling coil to a point where the vapor pressure in the power element becomes the stronger. The seat then moves off the orifice and liquid starts to flow through the valve orifice into the cooling coil. The purpose of the power element is to help determine the quantity of liquid that is being metered into the cooling coil. As the temperature of the low pressure line changes at the bulb, the pressure of the vapor in the power element changes, resulting in a change of the position of the seat. For example, if the cooling coil gets more liquid than is required, the temperature of the low pressure line is reduced and the resultant lowering of the bulb temperature reduces the pressure of the vapor in the power element, allowing the seat to move closer to the orifice. This immediately reduces the amount of liquid leaving the valve. Under normal operation, the power element provides accurate control of the quantity of refrigerant to the cooling coil. To employ our tire pump analogy once more for clarity, it is the same situation that would exist if you were inflating a tire with a very slow leak. Providing you pumped the air into the tire as fast as it leaked out, you would be able to m aintain pressure even though the air would merely be circulating through the tire and leaking out through the puncture. Accumulator--C-K Models (Fig. 38) The accumulator is located at the evaporator outlet. Its most important function is not to "accumulate" although this too is important. Its prim ary function is to separate liquid retained from vapor, retain the liquid and release the vapor to the compressor. Thus, in an ideal accumulator with no oil bleed hole, and LIGHT DUTY TRUCK SERVICE MANUAL 1A-34 HEATER A N D AIR C O N D IT IO N IN G “ O ” RING \ INLET Fig. 39-Expansion Tube The expansion tube is located in the enlarged portion of the evaporator inlet line. Thermostatic Switch Fig. 38--Accumulator in a correctly designed system, no liquid can get to the compressor. In an actual accumulator, there is some entrained liquid in the vapor stream to the compressor. The measure of a good accumulator is how well it separates vapor from liquid and how little entrained liquid is released to the compressor. Also, in an actual accumulator, an oil bleed hole is required to prevent trapping of oil in the bottom of the accumulator; this oil bleed hole bleeds some liquid refrigerant as well. Therefore, flow out of the accumulator to the compressor consists mostly of vapor with the addition of entrained liquid and liquid flow through the oil bleed hole. A bag of desiccant (dehydrating agent) is located in the base of the accumulator as a moisture collecting device. NOTE: There is no sight glass in the accumulator clutch cycle system. Expansion Tube--C-K Models Expansion tube flow rate depends on pressure difference and on subcooling; however, the flow rate is more sensitive to subcooling. System temperature is controlled by running the compressor intermittently, automatically turning it on and off as necessary to m aintain proper temperatures. The compressor is started and stopped through the use of an electro-magnetic clutch and a thermostat affected by variations in temperature. The thermostatic switch incorporates a metallic tube which contains a highly expansive gas. This tube is inserted into the evaporator core (C-K Four-Season System) or is located in the air stream as it leaves the evaporator (all other systems). The tube leads to a bellows operated switch. As air temperature rises, the gas inside the tube expands, travels through the tube to the bellows and closes the electrical switch which engages the compressor clutch. As soon as the compressor starts running, the temperature begins to go down. As the air being cooled gets colder, the gas in the thermostatic tube begins to reduce the pressure on the switch bellows. This allows the switch contacts to open and the compressor clutch disengages. Low Refrigerant Charge Protection System C-K Models The compressor discharge pressure switch performs the function of shutting off the compressor when it senses low refrigerant pressure. The switch is located in the evaporator inlet line (high pressure). The switch electrically is wired in series between the compressor clutch and the master switch on the control. When the switch senses low pressure it breaks contact and opens the circuit to the compressor clutch, thus shutting off the A /C system and preventing compressor failure or seizure. LIGHT DUTY TRUCK SERVICE MANUAL HEATER AND AIR C O N D IT IO N IN G The compressor discharge pressure switch also performs the function of the ambient switch as the pressure at the switch varies directly with ambient temperatures. The compressor should not run below 25°F. am bient or 37 psi at the switch. The compressor should run in A /C modes above 45°F. ambient or 42 psi at the switch. The switch interacts with other switches so that in an A /C system where the compressor will not operate above 45° ambient the following components should be checked for continuity: 1. Compressor discharge pressure switch. 2. Master switch (on control head). If both switches show proper continuity, check the harness for shorts or improper ground conditions. G Models This low refrigerant charge protector system consists of a superheat shutoff switch located in the rear head of the compressor, connected in series by an electrical lead to a thermal fuse. During normal air conditioning system operating conditions, current flows through the air conditioner switch, the ambient switch, and through the thermal fuse link to the clutch coil to actuate the compressor clutch. Should a partial or total loss of refrigerant in the system cause the superheat switch to sense low system pressure and a high suction gas temperature, the superheat switch contacts will close. When the contacts close, current flows to energize the resistance type heater in the thermal fuse. The resultant heat warms the fuse link to its specific melt temperature, thus opening the circuit to the compressor clutch coil. Compressor operation ceases and compressor damage due to a loss of refrigerant charge is prevented. The cause of the refrigerant loss must be corrected and the system charged prior to replacing the thermal fuse. The superheat switch does not have to be replaced when it cycles and is reusable unless it is determined that the switch is faulty. CHEMICAL INGREDIENTS OF AN AIR CONDITIONING SYSTEM All systems involve metals, refrigerant, and oil which are basic and essential. The desiccant, or dehydrating agent, and another chemical ingredient, synthetic rubber, makes it even more complex. All of these ingredients have chemical properties which are entirely different from each of the others. By proper selection of the ingredients and controlled processes in manufacture, plus careful servicing procedures, they can be combined so that they provide many years of satisfactory and trouble-free operation. Only one undesirable element added or allowed to enter the system can start a chain of chemical reactions which upsets stability and interferes with the operation of the unit. 1A-35 Chemical Instability and Refrigerant System Failures A sealed refrigerating system is a complex physicalchemical combination which is designed for stability within certain operating limits. If these limits are exceeded, many physical and chemical reactions occur to the system. Since the results of these reactions within the system cannot be easily removed, they build up into a constantly accelerating vicious circle to eventually fail the system. Metals In most cases, metals contribute to the decomposition of R-12 and oil in varying amounts. All metals are attacked by acids. Each of the metals in common use in a system has been selected for a specific reason; heat conductivity, durability, strength, and chemical composition. Under favorable conditions, the amount of decomposi­ tion of Refrigerant-12 and oil produced by these metals is negligible. If undersirable substances are added and the temperature is increased, the rate of decomposition and the production of harm ful acids increases proportionally. Refrigerant The chemical properties of refrigerants are very important factors in the stability of a system since the refrigerant penetrates to every part of the unit. Among the many desirable properties of R-12, is its stability under operating conditions. While more stable than the other refrigerants under the same conditions, it can be caused to form harmful acids which will eventually fail the system. Oil Oil is the most complex of all organic chemicals. Its stability in a refrigerating system is dependent upon the source of crude oil and its method of refining. A good refrigeration oil must be free of sludge, gum-forming substances and impurities such as sulphur. It must be stabilized to resist oxidation and must have a high degree of resistance to carbonization. The chemical properties of the lubricating oil form another very important consideration in the chemical stability within the system. Like the refrigerant, it travels to every part of the system. The factory obtains the finest oils which have been refined from the most desirable crudes. It is reprocessed at the factory before it is charged into a system or poured into a container for resale. Its viscosity and flash point are checked and it is forced through many sheets of filtering paper. Even the containers in which it is poured for resale are processed. It is the cleanest, dryest, and purest oil that is humanly possible to make. Leaving the container LIGHT DUTY TRUCK SERVICE MANUAL 1A-36 HEATER A N D AIR C O N D IT IO N IN G uncapped even for a few minutes allows the oil to absorb moisture from the air. System failures can result if contaminated oil is added to the system. Desiccant (Dehydrating Agent) An ideal desiccant must have the following characteristics: 1. High capacity. 2. High efficiency. 3. Low tendency to powder. 4. Absorb moisture without reacting chemically with it. 5. Allow refrigerant to flow through it with minimum restriction. 6. Retain moisture at high temperature. While some desiccants excel in several of the desirable characteristics, they are unsatisfactory in others. Activated Silica Alumina is a most satisfactory desiccant; however, its ability to retain moisture is affected by its temperature. As the temperature increases, its ability decreases. This means that moisture which is retained at a lower temperature may be put back into the system at a higher temperature. PRIMARY CAUSES OF SYSTEM FAILURES Leaks A shortage of refrigerant causes oil to be trapped in the evaporator. Oil may be lost with the refrigerant at point of leakage. Both of these can cause compressor seizure. Oil circulates in the globules with the vapor. It leaves the compressor by the action of the pistons and mixes with the refrigerant liquid in the condenser. The oil then enters the evaporator with the liquid and, with the evaporator properly flooded, is returned to the compressor through the low pressure line. Some of the oil returns as globules in the vapor but more importantly, it is swept as a liquid along the walls of the tubing by the velocity of the vapor. If the evaporator is starved, the oil cannot return in sufficient quantities to keep the compressor properly lubricated. High Temperature and Pressure An increase in temperature causes an increase in pressure. This accelerates chemical instability in clean systems. Other results are brittle hoses, "O " ring gaskets, and by-pass valve diaphragms with possible decomposi­ tion, broken compressor discharge reeds, and seized compressor bearings. A fundamental law of nature accounts for the fact that when a substance, such as a refrigerant, is increased in temperature, its pressure is also increased. Any chemical reactions caused by contaminants already in the system are greatly accelerated as the temperature increases. A 15° rise in temperature doubles the chemical action. While temperature alone can cause the synthetic rubber parts to become brittle and possibly to decompose, the increased pressure can cause them to rupture or blow. As the temperature and pressure increases, the stress and strain on the discharge reeds also increases. This can result in broken reeds. Due to the effect of the contaminants caused by high temperature and pressure, compressor bearings can be caused to seize. High temperature and pressure is also caused by air in the system. Air in the System Air results from a discharged system or careless servicing procedures. This reduces system capacity and efficiency and causes oxidation of oil into gum and varnish. When a leak causes the system to become discharged, the resulting vacuum within the system will cause air to be drawn in. Air in a system is a non-condensable gas and will build up in the condenser as it would in an air compressor tank. The resultant heat produced will contribute to the conditions discussed previously. Many systems are contaminated and also reduced in capacity and efficiency by careless servicing procedures. Too frequently, systems which have been open to the atmosphere during service operations have not been properly purged or evacuated. Air is also introduced into the system by unpurged gauge and charging lines. Remember that any air in the system is too much air. Poor Connections Hose clamp type fittings must be properly made. Hose should be installed over the sealing flanges and with the end of the hose at the stop flange. The hose should never extend beyond the stop flange. Locate the clamp properly and torque as recommended. Be especially careful that the sealing flanges are not nicked or scored or a future leak will result. When compression fittings are used, over-tightening can cause physical damage to the "O " ring gasket and will result in leaks. The use of torque and backing wrenches is highly recommended. When making a connection with compression fittings, the gaskets should always be first placed over the tube before inserting it in the connection. Another precaution - inspect the fitting for burrs which can cut the "O " ring. Restrictions Restrictions may be due to powdered desiccant or dirt and foreign matter. This may result in starved evaporator and loss of cooling, high temperature at the bypass hose, or a seized compressor. When the amount of moisture in a system sufficiently exceeds the capacity of the desiccant, it can break down LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G the desiccant and cause it to powder. The powder passes through the dehydrator screen with the refrigerant liquid and is carried to the expansion valve screen. While some of it may pass through the valve screen into the evaporator, it may quickly build up to cause a restriction. Due to the fact that sufficient oil then cannot be returned to the compressor, it may seize. 1A-37 Dirt, which is any foreign material, may come from cleaner residues, cutting, machining, or preserving oils, metal dust or chips, lint or dust, loose rust, soldering or brazing fluxes, paint or loose oxide scale. These can also cause seized bearings by abrasion or wedging, discharge and expansion valve failure, decomposition of refriger­ ant and oil, or corrosion of metal parts. many difficulties in refrigerating systems, in most instances it is the presence of moisture in the system that accelerates these conditions. It can be said, therefore, that moisture is the greatest problem of all. The acids that it produces, in combination with both the metals and the refrigerant, causes dam aging corrosion. While the corrosion may not form as rapidly with R-12 as with some other refrigerants, the eventual formation is as damaging. If the operating pressure and temperature in the evaporator is reduced to the freezing point, moisture in the refrigerant can collect at the orifice of the expansion valve and freeze. This temporarily restricts the flow of liquid causing erratic cooling. As previously mentioned, moisture in excess of the desiccant’s capacity can cause it to powder. Corrosion Points to Remember Dirt Corrosion and its by-products can restrict valve and drier screens, roughen bearing surfaces or hasten fatiguing of discharge reeds. This can result in high temperature and pressure, decomposition or leaks. In any event, this means a damaged compressor. From this, we can see the vicious circle that can be produced in a refrigerating system to cause its failure. Corrosion can be the indirect cause of leaks and leaks can be the direct cause of corrosion. We can also see the im portant role servicemen play in m aintaining chemical stability. The major cause of corrosion is moisture. Moisture Moisture is the greatest enemy of refrigerating systems. Combined with metal, it produces oxide, Iron Hydroxide, and Aluminum Hydroxide. Combined with R-12, it produces Carbonic acid, Hydrochloric acid, and Hydro­ fluoric acid. Moisture can also cause freeze-up of an expansion valve and powdered desiccant. Although high temperature and dirt are responsible for Fig. 40-System Contaminants That the inside of the refrigerant system is completely sealed from the outside world. If that seal remains broken at any point—the system will soon be damaged. That complete and positive sealing of the entire system is vitally im portant and that this sealed condition is absolutely necessary to retain the chemicals and keep them in a pure and proper condition. That all parts of the refrigerant system are under pressure at all times, whether operating or idle, and that any leakage points are continuously losing refrigerant and oil. That the leakage of refrigerant can be so silent that the complete charge may be lost without warning. That refrigerant gas is heavier than air and will rapidly drop to the floor as it flows from a point of leakage. That the pressure in the system may momentarily become as high as 480 lbs. per square inch. That the total refrigerant charge circulates through the entire system at least once each minute. That the compressor is continually giving up some lubricating oil to the circulating refrigerant and depends upon oil in the returning refrigerant for continuous replenishment. Any stoppage or major loss of refrigerant will therefore damage the compressor. That the extreme internal dryness of a properly processed system is a truly desert condition, with the drying material in the receiver or accumulator holding tightly onto the tiny droplets of residual moisture. That the attraction of the drying m aterial for moisture is so powerful that if the receiver or accumulator is left open, moisture will be drawn in from the outside air. That water added to the refrigerant will start chemical changes that can result in corrosion and eventual breakdown of the chemicals in the system. Hydrochloric acid is one result of an R-12 mixture with water. That air in the refrigerant system may start reactions that can cause malfunctions. LIGHT DUTY TRUCK SERVICE MANUAL 1A-38 HEATER A N D AIR C O N D IT IO N IN G That the drying agent in the receiver or accumulator is Activated Silica Alumina. That the inert gas in the expansion valve-capillary line is carbon dioxide. SYSTEM CONTROLS Four-Season System (C-K Models) - Fig. 41 The system selector level (air control lever) determines the mode of operation: OFF, A/C, VENT, HEATER, BILEVEL or DEF. When the system selector lever is placed in the A/C, BI-LEVEL or DEF positions, electrical circuit connection is made to the compressor clutch through the control panel switch and the discharge pressure switch. If the switch is closed (ambient temperature above 40°F.), the compressor will run. In the OFF, VENT or HEATER positions, the com­ pressor is not energized. recirculation of interior air (recirc. operation) provides a source of fast cool down of interior temperatures. Fan Switch The blower (FAN) switch provides a means of selecting the amount of airflow from the system by regulating the speed of the blower motor. There are, however, limitations to the control of blower speed. To provide constant ventilation, the blower motor electrical circuitry prevents the blower motor from being shut off when the ignition switch is on. Therefore, the blower speeds available are HI, LO and two medium speeds. The control panel also has a "recirc. override" switch which overrides the blower speed switch and automati­ cally provides HI blower speed when the system selector lever is in A /C and the temperature lever is set to full COLD. Overhead System (C-K Models) The system selector lever also determines the direction of outlet air flow. Moving the lever from mode to mode varies the position of a rotary vacuum valve on the control. The position of the vacuum valve will supply vacuum to, or vent, vacuum diaphragms which position the upper and lower mode and defroster air doors in the selector duct assembly. The position of these air doors determines if output air flow is from heater outlet (OFF), the heater outlet with slight air flow from defroster nozzles (HEATER), heater and A /C outlets (VENT), A /C outlet only (A/C), heater, A /C and defroster outlets (BI-LEVEL), or the defroster nozzles with slight air flow from the heater outlet (DEF). Temperature Control The temperature lever determines the temperature of outlet airflow by positioning the temperature door in the selector duct assembly, through the motion of a bowden cable linking the control panel lever to the temperature door. In addition, the temperature lever is connected to a second vacuum valve on the control panel. The vacuum valve supplies vacuum to the air inlet diaphragm through the system selector lever rotary vacuum valve. When the system is in A /C mode and the temperature lever is at full COLD, the air inlet door is positioned to reduce the supply of outside air to the system from 100% to approximately 20%. The remainder of the air input (80%) to the A /C system is then taken from the interior of the passenger compartment. This HI 1: l mS3 # 11 8 • 10 FAN Off ■ r A/C ■ .. VINT • HEMER m Bl LEVEL m - ....... COID ^ - .... This system operates in conjunction with the FourSeason System. Since refrigerant flow is controlled by the front system, the only control provided for on the overhead system is a three-speed fan switch (LOW), MED, HI). The fan switch is mounted in the instrument panel, to the right of the steering column (fig. 42). In the OFF position, the blower is inoperative; however, refrigerant is circulating in the system if the FourSeason System is ON. In any of the three blower positions (LOW, MED, HI), the blower will be operative regardless if the Four-Season System is ON. NOTE: To obtain maximum cooling, the Four-Season System should be on A/C, temperature lever on COLD, blower switch on HI and the overhead unit blower switch should be on HI. Floor Mounted System (G Models) Controls for the front floor mounted system consist of a Off m HOI *1 Fig. 41-Four-Season System Controls (C-K Models) Fig. 42-Overhead Unit Control (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-39 Fig. 44- Motor Home Unit Control Fig. 43--Floor and Overhead Controls (G Models) temperature knob and a three speed blower switch. The controls are mounted on the blower-evaporator cover to the right of the driver (fig. 43). The temperature knob is used to control the degree of cooling desired. Fully clockwise at CITY provides maximum cooling while turning the knob to HIWAY provides adequate cooling for highway operation. The three speed blower fan switch (LOW-MED-HI) is used to control the quantity of air flow. NOTE: Reduced cooling and freezing of the evaporator could be encountered when operating at highway speeds with the controls at the "CITY" setting. Overhead System (G Models) This system operates in conjunction with the front floor mounted system. Since refrigerant is controlled by the front system the only control provided on the rear overhead system in a three speed blower switch (fig. 43). In the OFF position, the blower is inoperative; however, refrigerant is circulating in the system if the front system in ON. To operate the rear overhead system, simply select the desired blower speed (LOW, MED, HI). NOTE: The rear unit will not operate unless the front unit is calling for cooling. Dash Mounted Unit (Motor Home Chassis Units) This system is self contained and is mounted below the dash by the body manufacturer. System controls consist of an AIR knob and TEMP knob located in the center of the unit face plate (fig. 44). Air Knob Turning the AIR knob clockwise operates a three speed (LOW-MED-HI) blower motor. Temp Knob This knob is used to control the degree of cooling desired. Fully clockwise at CITY provides maximum cooling, while turning the knob to HIWAY provides adequate cooling for highway operation. NOTE: Reduced cooling could be encoun­ tered when operating at highway speeds with the controls at the CITY setting. The heater must be fully off to obtain maximum cooling. GENERAL IN FO R M A TIO N In any vocation or trade, there are established procedures and practices that have been developed after many years of experience. In addition, occupational hazards may be present that require the observation of certain precautions or use of special tools and equipment. Observing the procedures, practices and precautions of servicing refrigeration equipment will greatly reduce the possibilities of damage to the customers’ equipment as well as virtually eliminate the element of hazard to the serviceman. PRECAUTIONS IN HANDLING REFRIGERANT-12 Refrigerant-12 is transparent and colorless in both the gaseous and liquid state. It has a boiling point of 21.7°F below zero and, therefore, at all normal temperatures and pressures it will be a vapor. The vapor is heavier than air, and is noninflammable, nonexplosive, nonpoisonous (except when in contact with an open flame) and noncorrosive (except when in contact with water). WARNING: The following precautions in handling R-12 should be observed at all times. • If it is ever necessary to transport or carry a cylinder or can of refrigerant in a car, keep it in the luggage compartment. Refrigerant should not be exposed to the radiant heat from the sun since the resulting increase in pressure may cause the safety valve to release or the cylinder or can to burst. LIGHT DUTY TRUCK SERVICE MANUAL 1A-40 HEATER A ND AIR C O N D IT IO N IN G • Cylinders or disposable cans should never be subjected to high tem perature when adding refrigerant to the system. In most instances, heating the cylinder or can is required to raise the pressure in the container higher than the pressure in the system during the operation. It would be unwise to place the cylinder on a gas stove, radiator or use a blow torch while preparing for the charging operation, for a serious accident can result. Remember, high pressure means that great forces are being exerted against the walls of the container. A bucket of warm water, not over 125°F, or warm wet rags around the container is all the heat that is required. • Do not weld or steam clean on or near the system. Welding or steam cleaning can result in a dangerous pressure buildup in the system. • Discharging large quantities of R-12 into a room can usually be done safely as the vapor would produce no ill effects; however, in the event of an accidental rapid discharge of the system, it is recommended that inhalation of large quantities of R-12 be avoided. This caution is especially important if the area contains a flame producing device such as a gas heater. While R-12 normally is nonpoisonous, heavy concentrations of it in contact with a live flame will produce a toxic gas. The same gas will also attack all bright metal surfaces. • Protection of the eyes is of vital importance! When working around a refrigerating system, an accident may cause liquid refrigerant to hit the face. If the eyes are protected with goggles or glasses, no serious damage can result. Just remember, any R-12 liquid that touches you is at least 21.7°F below zero. If R-12 liquid should strike the eyes, here is what to do: 1. Keep calm. 2. Do not rub the eyes. Splash the affected area with quantities of cold water to gradually get the temperature above the freezing point. The use of mineral, cod liver or an antiseptic oil is important in providing a protective film to reduce the possibility of infection. 3. As soon as possible, call or consult an eye specialist for immediate and future treatment. PRECAUTIONS IN HANDLING REFRIGERANT LINES CAUTIO N: The following precautions should be observed when handling refrigerant lines: • All metal tubing lines should be free of kinks, because of the restriction that kinks will offer to the flow of refrigerant. The refrigeration capacity of the entire system can be greatly reduced by a single kink. • The flexible hose lines should never be bent to a • • • • radius of less than 10 times the diam eter of the hose. The flexible hose lines should never be allowed to come within a distance of 2-1/2" of the exhaust manifold. Flexible hose lines should be inspected at least once a year for leaks or brittleness. If found brittle or leaking they should be replaced with new lines. Use only new lines that have been sealed during storage. When disconnecting any fitting in the refrigeration system, the system must first be discharged of all refrigerant. However, proceed very cautiously regardless of gauge readings. Open very slowly, keeping face and hands away so that no injury can occur if there happens to be liquid refrigerant in the line. If pressure is noticed when fitting is loosened, allow it to bleed off as described under "Purging the System" in this section. WARNING: Always wear safety goggles when opening refrigerant lines. • In the event any line is opened to atmosphere, it should be immediately capped to prevent entrance of moisture and dirt. • The use of the proper wrenches when making connections on "O " ring fittings is important. The use of im proper wrenches may damage the connection. The opposing fitting should always be backed up with a wrench to prevent distortion of connecting lines or components. When connecting the flexible hose connections it is important that the swaged fitting and the flare nut, as well as the coupling to which it is attached, be held at the same time using three different wrenches to prevent turning the fitting and dam aging the ground seat. • "O " rings and seats must be in perfect condition. A burr or piece of dirt may cause a leak. • Sealing beads on hose clamp connections must be free of nicks and scratches to assure a perfect seal. MAINTAINING CHEMICAL STABILITY IN THE REFRIGERATION SYSTEM The metal internal parts of the refrigeration system and the refrigerant and oil contained in the system are designed to remain in a state of chemical stability as long as pure R-12 and uncontaminated refrigeration oil is used in the system. However, when abnormal amounts of foreign materials, such as dirt, air or moisture are allowed to enter the system, the chemical stability may be upset. When accelerated by heat, these contaminants may form acids and sludge and eventually cause the breakdown of components within the system. In addition, contaminants may affect the temperature-pressure relationship of R-12, LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G resulting in im proper operating tem perature and pressures and decreased efficiency of the system. CAUTIO N: The following general practices should be observed to ensure chemical stability in the system: • Whenever it becomes necessary to disconnect a refrigerant or gauge line, it should be immediately capped. Capping the tubing will also prevent dirt and foreign matter from entering. • Tools should be kept clean and dry. This also includes the gauge set and replacement parts. • When adding oil, the container should be exception­ ally clean and dry due to the fact that the refrigeration oil in the container is as moisture-free as it is possible to make it; therefore, it will quickly absorb any moisture with which it comes in contact. For this same reason the oil container should not be opened until ready for use and then it should be capped immediately after use. • When it is necessary to open a system, have everything you will need ready and handy so that as little time as possible will be required to perform the operation. Don’t leave the system open any longer than is necessary. • Finally, after the operation has been completed and the system sealed again, air and moisture should be evacuated from the system before recharging. J-8393 CHARGING STATION The J-8393 Charging Station is a portable assembly of a vacuum pump, refrigerant supply, gauges, valves, and most important, a five (5) pound metering refrigerant charging cylinder. The use of a charging cylinder eliminates the need for scales, hot water pails, etc. The chief advantage of this unit is savings. A very definite savings in refrigerant and time can be obtained by using this unit. Since the refrigerant is metered into the system by volume, the correct amount may be added to the system. This, coupled with the fact that the unit remains "plum bed" at all times and thus eliminates loss of refrigerant in purging of lines and hooking-up, combines to enable the operator to get full use of all refrigerant purchased. All evacuation and charging equipment is hooked together in a compact portable unit (fig. 45). It brings air conditioning service down to the basic problem of hooking on two hoses, and manipulating clearly labeled valves. This will tend to ensure that the job will be done without skipping operations. As a result, you can expect to save time and get higher quality work, less chance of an over or under charge, thus reducing comebacks. The pump mount is such that the dealer may use his own vacuum pump. The gauges and manifold are in common LOW PRESSURE CONTROL ( l) 1A-41 HIGH PRESSURE CONTROL ( 2) VACUUM CONTROL REFRIGERANT CONTROL (3) (4) LOW PRESSURE GAUGE LINE HiGH PRESSURE GAUGE LINE 5 LB. CHARGING ' CYLINDER -LEAK DETECTOR REFRIGERANT •CONTROL VALVE Fig. 4 5 -J-8393 Charging Station use. Thus a current air conditioning dealer can use the equipment on hand and avoid duplication. GAUGE SET The gauge set (fig. 46) is an integral part of the J-8393 Charging Station. It is used when purging, evacuating, charging or diagnosing trouble in the system. The gauge at the left is known as the low pressure gauge. The face is graduated into pounds of pressure and, in the opposite 1 2 LOW PRESSURE CONTROL HIGH PRESSURE CONTROL 4 3 REFRIGERANT CONTROL VACUUM CONTROL Fig. 46 -Gauge Set LIGHT DUTY TRUCK SERVICE MANUAL 1A-42 HEATER A N D AIR C O N D IT IO N IN G direction, in inches of vacuum. This is the gauge that should always be used in checking pressures on the low pressure side of the system. When all parts of the system are functioning properly the refrigerant pressure on the low pressure side never falls below 0 pounds pressure. However, several abnormal conditions can occur that will cause the low pressure to fall into a partial vacuum. Therefore, a low pressure gauge is required. The high pressure gauge is used for checking pressures on the high pressure side of the system. The hand shutoff valves on the gauge manifold do not control the opening or closing off of pressure to the gauges. They merely close each opening to the center connector and to each other. During most diagnosing and service operation, the valves must be closed. Both valves will be open at the same time during purging, evacuating and charging operations. The charging station provides two flexible lines for connecting the gauge set to the system components. FIVE AMP TIME DELAY FUSE CORD TO 110 AC SOURCE PUMP INLET PUMP DISCHARGE OUTLET VACUUM PUMP A vacuum pump should be used for evacuating air and moisture from the air conditioning system. The vacuum pump (fig. 47), is a component part of Charging Station J-8393, described previously. CAU TIO N : The following precautions should be observed relative to the operation and maintenance o f this pump: • Make sure dust cap on discharge outlet of vacuum pump is removed before operating. • Keep all openings capped when not in use to avoid moisture being drawn into the system. • Oil should be changed after every 250 hours of normal operation. To change oil, simply unscrew hex nut located on back side of pump, tilt backward and drain out oil (fig. 47). Recharge with 8 ounces of vacuum pump oil Frigidaire 150 or equivalent. If you desire to flush out the pump, use this same type clean oil. Do not use solvent. Im proper Lubrication will shorten pump life. • If this pump is subjected to extreme or prolonged cold, allow it to remain indoors until oil has reached approximate room temperature. Failure to warm oil will result in a blown fuse. • A five ampere time delay cartridge fuse has been installed in the common line to protect the windings of the compressor. The fuse will blow if an excessive load is placed on the pump. In the event the fuse is blown, replace with a five ampere time delay fuse. Do not use a substitute fuse as it will result in damage to the starting windings. Fig. 47-Vacuum Pump • If the pump is being utilized to evacuate a burntout system, a filter must be connected to the intake fitting to prevent any sludge from contaminating the working parts, which will result in malfunction of the pump. • Do not use the vacuum pump as an air compressor. LEAK TESTING THE SYSTEM Whenever a refrigerant leak is suspected in the system or a service operation performed which results in disturbing lines or connections, it is advisable to test for leaks. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G Common sense should be the governing factor in performing any leak test, since the necessity and extent of any such test will, in general, depend upon the nature of the complaint and the type of service performed on the system. Leak Detector Tool J-6084 (fig. 48) is a propane gas-burning torch which is used to locate a leak in any part of the system. Refrigerant gas drawn into the sampling tube attached to the torch will cause the torch flame to change color in proportion to the size of the leak. Propane gas fuel cylinders used with the torch are readily available commercially throughout the country. W ARNING: Do not use lighted detector in any place where combustible or explosive gases, dusts or vapors may be present. Operating Detector 1. Determine if there is sufficient refrigerant in the system for leak testing. 2. Open control valve only until a low hiss of gas is heard, then light gas at opening in chimney. 3. Adjust flame until desired volume is obtained. This is most satisfactory when blue flame is approx­ imately 3/8" above reactor plate. The reaction plate will quickly heat to a cherry red. 4. Explore for leaks by moving the end of the 1A-43 sampling hose around possible leak points in the system. Do not pinch or kink hose. NOTE: Since R-12 is heavier than air, it is good practice to place open end of sampling tube immediately below point being tested, particularly in cases of small leaks. W ARNING: Do not breathe the fumes that are produced by the burning of R-12 gas in the detector flame, since such fumes can be toxic in large concentrations. 5. Watch for color changes. The color of the flame which passes through the reaction plate will change to green or yellow-green when sampling hose draws in very small leaks of R-12. Large leaks will be indicated by a change in color to a brilliant blue or purple; when the sampling hose passes the leaks, the flame will clear to an almost colorless pale-blue again. Observations are best made in a semi­ darkened area. If the flame remains yellow when unit is removed from leak, insufficient air is being drawn in or the reaction plate is dirty. NOTE: A refrigerant leak in the high pressure side of the system may be more easily detected if the system is operated for a few minutes, then shut off and checked immediately (before system pressures equal­ ize). A leak on the low pressure side may be more easily detected after the engine has been shut off for several minutes (system pressures equalized); this applies particularly to the front seal. AVAILABILITY OF REFRIGERANT-12 Refrigerant-12 is available in 30 lb. and in 15 oz. disposable containers. Normally, air conditioning systems are charged making use of the J-8393 Charging Station which uses the 30 lb. container. Evacuating and charging procedures are noted later in this section. The 15 oz. disposable cans are generally used for miscellaneous operations such as flushing. W ARNING: The following precautions should be observed when adding refrigerant to a system using 15 oz. disposable cans: Fig. 48-Leak Detector 1. Do not charge while compressor system is hot. 2. Empty container completely before disposing. 3. Use opening valves designed for use with container - follow valve m anufacturer’s directions carefully. 4. Always use pressure gauges before and during charging. 5. NEVER connect on high pressure side of system or LIGHT DUTY TRUCK SERVICE MANUAL 1A-44 HEATER A N D AIR C O N D IT IO N IN G to any system having a pressure higher than indicated on refrigerant containers. 6. If inexperienced, seek professional assistance. COMPRESSOR OIL Special refrigeration lubricant should be used in the system. This oil is as free from moisture and contaminants as it is possible to attain by human processes. This condition should be preserved by immediately capping the bottle when not in use. See "Air Conditioning System Capacities" for the total system oil capacity. Due to the porosity of the refrigerant hoses and connections, the system refrigerant level will show a definite drop after a period of time. Since the compressor oil is carried throughout the entire system mixed with the refrigerant, a low refrigerant level will cause a dangerous lack of lubrication. Therefore the refrigerant charge in the system has a definite tie-in with the amount of oil found in the compressor and an insufficient charge may eventually lead to an oil build-up in the evaporator. COMPRESSOR SERIAL NUMBER The compressor serial number is located on the serial number plate on top of the compressor. The serial number consists of a series of numbers and letters. This serial number should be referenced on all forms and correspondence related to the servicing of this assembly. INSPECTION A N D PERIODIC SERVICE PRE-DELIVERY INSPECTION 1. Check that engine exhaust in suitably ventilated. 2. Check the belt for proper tension. 3. With controls positioned for operation of the system, operate the unit for five minutes at approximately 2000 rpm. Observe the clutch pulley bolt to see that the compressor is operating at the same speed as the clutch pulley. Any speed variation indicates clutch slippage. 4. Before turning off the engine, check refrigerant charge (see "Refrigerant Quick Check Procedure"). 5. Check refrigerant hose connections: " 0 " Ring Connections-- Check torque of fittings as charted later in this section under "Refrigerant Line Connections;" retorque if required. Leak test the complete system. 6. If there is evidence of an oil leak, check the compressor to see that the oil charge is satisfactory. NOTE: A slight amount of oil leakage at the compressor front seal is considered normal. 7. Check the system controls for proper operation. 6000 MILE INSPECTION 1. Check unit for any indication of a refrigerant leak. 2. If there is an indication of an oil leak, check the compressor for proper oil charge. NOTE: A slight amount of oil leakage at the compressor front seal is considered normal. 3. Check refrigerant charge (see "R efrigerant Quick Check Procedure"). 4. Tighten the compressor brace and support bolts and check the belt tension. 5. Check refrigerant hose connections as in Step 5 of "Pre-Delivery Inspection." PERIODIC SERVICE • Inspect condenser regularly to be sure that the fins are not plugged with leaves or other foreign material. • Check evaporator drain tubes regularly for dirt or restrictions. • At least once a year, check the system for proper refrigerant charge and the flexible hoses for brittleness, wear or leaks. • Every 6000 miles check for low refrigerant level. • Check belt tension regularly. EVACUATING A N D C HA RG IN G PROCEDURES AIR CONDITIONING SYSTEM CAPACITY See Capacity Chart on Page 1A-45. INSTALLING CHARGING STATION 1. High and low pressure gauge line fittings are provided in the air conditioning system for attaching the Charging Station. C-K Models~The low pressure fitting is located on the accumulator and the high pressure fitting on the evaporator inlet line. G Models-The low pressure fitting is on the compressor inlet line and the high pressure fitting on the muffler. Motor Home Chassis~The low pressure fitting is on LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G Refrigerant Charge Four-Season System (C-K Models) Overhead System (C-K-G Models) Floor Mounted System (G Models) Dash Mounted Unit (Motor Home Chassis) 2. 3. 4. 5. 6. 3 lbs. 1A-45 Oil Charge 10 oz. 525 Viscosity REFRIGERANT LINE LOW PRESSURE ACCUMULATOR (CONDENSER TO M|G n PRESSURE 5 lbs. 4 oz. 13 oz. 525 Viscosity 3 lbs. 4 oz. 10 oz. 525 Viscosity 3 lbs. 4 oz. 10 oz. 525 Viscosity the compressor inlet line and the high pressure fitting is on the compressor outlet line. W ith the engine stopped, remove the caps from the cored valve gauge fittings. Install Gauge Adapters J-5420 and J-9459 onto the high and low pressure lines of the Charging Station. Be certain all the valves on the Charging Station are closed. Connect the high pressure gauge line to the high pressure fitting on the system. Referring to Figure 49, turn the high pressure control (2) one turn counterclockwise (open). Crack open the low pressure control (1) and allow refrigerant gas to hiss from the low pressure gauge line for three seconds, and then connect the low pressure line to the low pressure fitting on the system. W ARNING: When removing the gauge lines from the fittings, be sure to remove the adapters from the system fittings rather than the gauge lines from the adapter. 7. The system is now ready for purging or performance testing. PURGING THE SYSTEM In replacing any of the air conditioning components, the system must be completely purged or drained of refrigerant. The purpose is to lower the pressure inside the system so that a component part can be safety removed. 1. With the engine stopped, install high and low pressure lines of Charging Station gauge set to the proper high and low pressure gauge fittings (See "Installing The Charging Station"). CAUTIO N: Before installing lines, be sure that all four controls on the gauge set are closed. 2. Disconnect vacuum line at Charging Station Fig. 49--Charging Schematic-C-K Truck Shown vacuum pump and put the line in a covered can as shown in Figure 50. NOTE: An empty 3 lb. coffee can with a plastic cover which has been cross-slit (X’ed), to allow hose entry, works well for this purpose. 3. Fully open high (2) and low (1) pressure control valves, and allow refrigerant to purge from system at a rapid rate into the covered can. 4. Oil loss will be minimal. It may be added to the system during evacuation as described later. 5. Toward the end of the purge stage, Tool J-24095 should be flushed with refrigerant to eliminate possible contamination. a. Disconnect refrigerant line at supply tank. b. Flush Tool J-24095 by cracking open valve on refrigerant tank. After flushing for approx­ imately three seconds, close valve. c. Temporarily refasten the tool. d. Reconnect refrigerant line to supply tank. EVACUATING AND CHARGING THE SYSTEM GENERAL NOTE: In all evacuating procedures shown below, the specification of 28-29 inches of Mercury vacuum is used. These figures are only attainable at or near Sea Level Elevation. For each 1000 feet above sea level where this operation is being performed, the specifications should be lowered by 1 inch. Example: at +5000 ft. elevation, LIGHT DUTY TRUCK SERVICE MANUAL 1A-46 HEATER A N D AIR C O N D IT IO N IN G only 23 to 24 inches of vacuum can normally be obtained. Whenever the air conditioning system is open for any reason, it should not be put into operation again until it has been evacuated to remove air and moisture which may have entered the system. The following procedures are based on the use of the J-8393 Charging Station: Adding Oil If necessary, refrigeration oil may be added to the system by the following method: 1. Install charging station and purge system as previously described. 2. After system has been purged, connect the vacuum line to the vacuum pump. 3. Measure oil loss collected as a result of purging the system. a. Disconnect the Charging Station low pressure line. Install Tool J-24095 (with valve closed) onto the system low pressure fitting. Insert pick­ up tube into graduated container of clean refrigerant oil (fig. 51). NOTE: Tool J-24095 will hold 1/2 of an ounce of oil in the tool itself. So if 1 oz. has to be added, the level of the oil in the bottle should decrease 1-1/2 ounces to add 1 oz. to the system. CAUTIO N: When removing the gauge lines from the fittings, be sure to remove the adapters J-8393 CHARGING STATION TO HIGH PRESSURE FITTING OIL COLLECTING CAN Fig. 50-Collecting Refrigerant Oil During "Purging" from the system fittings rather than the gauge lines from the adapter. b. Turn on vacuum pump, and open vacuum control valve (slowly open high pressure side of manifold gauge set to avoid forcing oil out of refrigerant system and pump). NOTE: When valve on Tool J-24095 is opened, the vacuum applied to the discharge side of the system will suck oil into system from container. Therefore, close observation of oil level in the container is necessary. c. Note level of oil in container. Open valve on oil adding tool until oil level in container is reduced by an amount equal to that lost during discharge of system plus 1/2 ounce, then close valve. Take care not to add more oil than was lost d. Disconnect and cap Tool J-24095 and reinstall charging station low pressure line to the system. Open low pressure valve (1). Evacuation After oil has been added to the system (as outlined above), run pump until 28-29 inches vacuum is obtained (See General Note under "Evacuating and Charging the System"). Continue to run pump for 10 minutes after the system reaches 28-29 inches vacuum. NOTE: If 28-29 inches cannot be obtained, close Vacuum Control Valve (3) and shut off vacuum pump. Open Refrigerant Control Valve (4) and allow 1/2 pound of R-12 to enter system. Locate and repair all leaks. Purge this 1/2 pound and re-evacuate for 10 minutes. 1. During the ten minute evacuation period, prepare for charging the system by filling the charging cylinder as follows: a. Open valve on bottom of charging cylinder allowing refrigerant to enter cylinder. NOTE: It will be necessary to close bleed valve periodically to allow boiling to subside to check level in the sight glass of Charging Station cylinder. b. Bleed cylinder valve on top (behind control panel) as required to allow refrigerant to enter. When refrigerant reaches desired level (see "System Capacity"), close valve at bottom of cylinder and be certain bleed valve is closed securely. 2. Continue to evacuate for rem ainder of 10 minute period. 3. Turn hand shut-off valves at low and high pressure gauges of gauge set to full clockwise position with vacuum pump operating, then stop pump. Carefully check low pressure gauge for approximately two minutes to see that vacuum remains constant. If LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G vacuum reduces, it indicates a leak in the system or gauge connections; locate and repair all leaks. Charging the System 1. Only after evacuating as above, is system ready for charging. Note reading on sight glass of charging cylinder. If it does not contain a sufficient amount of refrigerant for a full charge, fill to the proper level. 2. With High and Low Pressure Valves (1 and 2) open, close Vacuum Control Valve (3), turn off vacuum pump, open refrigerant control valve (4) and allow refrigerant to enter system. NOTE: If the charge will not transfer completely from the station to the system, close the high pressure valve at the gauge set, set the air conditioning controls for cooling, check that the engine com partment is clear of obstructions, and start the engine. Compres­ sor operation will decrease the low side pressure in the system. System is now charged and should be checked as outlined below: Checking System Operation 1. Operate system for a maximum of five minutes at maximum cooling, high blower speed and with engine operating at 2000 RPM (exhaust should be vented if inside). 2. When system is stabilized, the pressure gauges on J -2 4 0 9 5 TO LOW PRESSURE FITTING CHARGING STATION HIGH PRESSURE LINE REFRIGERANT OIL TO HIGH PRESSURE FITTING Fig. 51-Adding Refrigeration Oil Using Tool J-24095 1A-47 the charging station should read pressures corre­ sponding to values listed under PERFORMANCE DATA. 3. When correct system pressures are observed, check system charge as described under "Refrigerant Quick Check Procedure". 4. Feel outlet air distribution to ensure that cold air is being distributed. 5. Disconnect gauge lines and cap fittings. CAUTIO N: When removing gauge lines from fittings, be sure to remove the adapters from the fittings rather than the gauge lines from the adapters. PERFORMANCE TEST Under normal circumstances, it will not be necessary to Performance Test a system as outlined below; however, in certain instances, the following procedure may be advantageous in diagnosing system malfunction. The following fixed conditions must be adhered to in order to make it possible to compare the performance of the system being tested with the standards below: 1. Doors and windows closed. (Vehicle inside or in shade.) 2. Hood up and engine exhaust suitably ventilated. 3. Vehicle in NEUTRAL with engine running at 2000 rpm. 4. Air Conditioning controls set for • Maximum cooling. • High blower speed 5. TEMP control set at "CO LD " and all air conditioning outlets open. 6. Gauge set installed. 7. System settled out (run-in approxim ately 10 minutes). 8. A thermometer placed in front of vehicle grille and another in the right hand diffuser outlet. NOTE: On Overhead Systems, place a third thermometer in the rear unit center outlet. 9. An 18" fan placed in front of the vehicle and blowing into the condenser. NOTE: Higher temperatures and pressures will occur at higher ambient temperatures. In areas of high humidity it is possible to have thermometer and gauge readings approach but not reach the figures listed in the performance tables and still have a satisfac­ tory operating unit. However, it is im portant to remember that low pressure has a direct relationship to nozzle outlet temperature. If pressure is too low, ice will gradually form on the evaporator fins, restricting air flow into LIGHT DUTY TRUCK SERVICE MANUAL 1A-48 HEATER A N D AIR C O N D IT IO N IN G the passenger area and resulting in insuffi­ cient or no cooling. Floor Mounted System (G Models) PERFORMANCE DATA The following Performance Data define normal opera­ tion of the system under the above conditions. Relative humidity does not appear in the tables because after running the prescribed length of time on recirculated air and maximum cooling, the relative humidity of the air passing over the evaporator core will remain at approximately 35% to 40% regardless of the ambient temperature or humidity. Four-Season Air Conditioning (C-K Models) lbs.-4 oz.) 90° 100° 110° 120° 80° 2000 RPM 150- 160- ISO- 205- 240165 175 195 220 255 888- 11- 1210 10 10 14 15 4144 4245 4548 5053 5558 Overhead System (G Models) 100° 110° 2000 190240 2129 220270 2230 240290 2332 4250 4351 4351 (Refrigerant Charge — 5 lbs.-4 oz. Temperature of Air Entering 90° 100° 110° 120° Condenser 2000 Engine rpm Compressor 165- 175- 210- 230 265- 305Head Pressure* 180 190 225 245 280 320 Suction 12- 14- 16- 20- 26- 31Pressure* 15 17 19 23 34 29 Discharge Air Temp, at Right 40- 41- 45- 52- 60- 65Front Upper 43 44 48 55 63 68 Outlet* o O 00 90° o O (Refrigerant Charge - 3 Lbs.) Temperature of Air Entering 70° 80° Condenser Engine rpm Compressor Head 150- 170Pressure * 205 220 Accumulator 2020Pressure * 26 28 Discharge Air 4141Temp, at Right 47 47 Hand Outlet * (Refrigerant Charge — 3 Temperature of Air Entering 70° Condenser Engine rpm Compressor 130Head Pressure* 145 Suction 8Pressure* 10 Discharge Air Temp, at Right 41Upper Outlet* 44 Overhead System (C-K Models) (Refrigerant Charge - 5 lbs.-4 oz.) Temperature of Air Entering 70° 80° 90° 100° 110° Condenser Engine rpm 2000 Compressor 135- 160- 195- 230- 270Head 185 210 245 280 320 Pressure * Accumulator 2222- 30- 33- 37Pressure * 28 30 38 41 47 Discharge Air 4242- 50- 54- 57Temp, at Right 48 48 58 62 67 Hand Outlet * Rear Center 4347- 50- 55- 58Outlet * 49 53 58 63 68 Dash Mounted Unit (Motor Home Chassis) (Refrigerant Charge — 3 lbs.-4 oz.) Temperature of Air Entering Condenser 70° 80° Engine rpm 90° 100° 110° 120° 2000 Compressor 110- 135- 160- 190- 220- 260Head Pressure* 120 145 170 200 230 270 Suction Pressure psi* 6 7 9 10 10 13 Discharge Air Temperature* 4045 4146 4146 4247 4449 4449 * Just prior to compressor clutch disengagement. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G CHECKING OIL In the six cylinder compressor it is not recommended that the oil be checked as a matter of course. Generally, compressor oil level should be checked only where there is evidence of a major loss of system oil such as might be caused by: • A broken refrigerant hose • A severe hose fitting leak • A very badly leaking compressor seal • Collision damage to the system components As a quick check on compressor oil charge, operate the engine at idle on maximum cold for approximately 10 minutes, turn off the engine and momentarily crack open the oil drain plug on bottom of the compressor letting a slight amount of oil drain out. Retighten plug. Again slightly crack open the plug. If oil comes out, the compressor has the required amount of oil. NOTE: The oil may appear foamy. This is considered normal. To further check the compressor oil charge, should the above test show insufficient oil, it is necessary to remove the compressor from the vehicle, drain and measure the oil as outlined under "Checking Compressor Oil Charge." Checking Compressor Oil Charge 1. Run the system for 10 minutes at 500-600 engine rpm with controls set for maximum cooling and high blower speed. 2. Turn off engine, discharge the system, remove compressor from vehicle, place it in a horizontal position with the drain plug downward. Remove the drain plug and, tipping the compressor back and forth and rotating the compressor shaft, drain the oil into a clean container, measure and discard the oil. 3. Add new refrigeration oil to the compressor as follows. a. If the quantity drained was 4 fluid oz. or more, add the same amount of new refrigeration oil to the replacement compressor. 1A-49 b. If the quantity drained was less than 4 fluid oz., add 6 fluid oz. of new refrigeration oil to the replacement compressor. c. If a new service compressor is being installed, drain all oil from it and replace only the amount specified in Steps 3a and 3b above. d. If a field repaired compressor is being installed, add an additional 1 fluid oz. to the compressor. 4. In the event that it is not possible to idle the compressor as outlined in Step 1 to effect oil return to it, proceed as follows: a. Remove the compressor, drain, measure and discard the oil. b. If the amount drained is more than 1-1/2 fluid oz. and the system shows no signs of a major leak, add the same amount to the replacement compressor. c. If the amount drained is less than 1-1/2 fluid oz. and the system appears to have lost an excessive amount of oil, add 6 fluid oz. of clean refrigeration oil to replacement compressor, 7 fluid oz. to a repaired compressor. If the oil contains chips or other foreign material, replace the receiver-dehydrator (expan­ sion tube on C-K models) and flush or replace all component parts as necessary. Add the full 11 fluid oz. of new refrigeration oil to the replacement compressor. 5. Add additional oil in the following amounts for any system components being replaced. Evaporator C ore....................................... 3 fluid oz. Condenser................................................... 1 fluid oz. Receiver-Dehydrator............................... 1 fluid oz. Accum ulator............................................... 1 fluid oz. CAUTIO N: When adding oil to the compressor, it will be necessary to tilt the rear end of the compressor up so that the oil will not run out of the suction and discharge ports. Do not set the compressor on the shaft end. LIGHT DUTY TRUCK SERVICE MANUAL 1A-50 HEATER A N D AIR C O N D IT IO N IN G REFRIGERANT QUICK-CHECK PROCEDURE The following procedure can be used to quickly determine whether or not an air conditioning system has a proper charge of refrigerant. This check can be made in a manner of minutes thus facilitating system diagnosis by pinpointing the problem to the amount of charge in the system or by eliminating this possibility from the overall checkout. C-K Models 1. 2. 3. 4. Engine must be warm (thermostat open). Hood and body doors open. Selector lever set at A/C. Temperature lever at first detent to the right of COLD (set for outside air). 5. Blower on HI. 6. Engine idling at 1000 RPM. 7. Feel temperature of evaporator inlet and accumulator out­ let pipes with compressor engaged (fig. 52). a. If both are cold this is a proper condition. b. If inlet pipe is cooler than outlet pipe, system is low on charge. • Add a slight amount of refrigerant until both pipes feel the same (system stabilized —3-5 minutes). • Then add 15 oz. (1 can) additional refrigerant. G Models and Motor Home Chassis Units Start engine and place on fast idle. Set controls for maximum cold with blower on high. Bubbles present in sight No bubbles. Sight glass clear. « glass. ? System low on charge. System is either fully Check with leak detector. charged or empty. Feel Correct leak, if any, and high and low pressure fill system to proper pipes at compressor. High pressure pipe should be charge. warm; low pressure pipe should be cold. r 11— 1 1 No appreciable tempera­ Temperature differential ture differential noted at noted at compressor. compressor. | I System empty or nearly Even though a differential empty. Turn off engine is noted, there exists a and connect Charging possibility of overcharge. Station. Induce 1/2# of An overfilled system will refrigerant in system (if result in poor cooling dur­ system will not accept ing low speed operation charge, start engine and (as a result of excessive draw 1/2# in through low head pressure). An overfill pressure side). Check is easily checked by dis­ system with leak detector. connecting the compressor clutch connector while observing the sight glass. r 1" "1.... If refrigerant in sight glass If refrigerant foams and remains clear for more then settles away from than 45 seconds (before sight glass in less than 45 foaming and then settling seconds, it can be assumed away from sight glass) an that there is a proper overcharge is indicated. charge of refrigerant in Verify with a performance system. Continue checking check. out system using perfor­ m ance checks outlined previously. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1A-51 Fig. 52-Checking Evaporator Inlet and Accumulator Outlet Temperatures M A IN TEN A N C E A N D ADJUSTMENTS THERMOSTATIC SWITCH All systems make use of a thermostatic switch with either an air or fin sensing capillary. This capillary controls the switch by sensing the temperature of the air leaving the fins (G and Motor Home Units) or temperature of the fins (C-K models). Checking for Proper Operation G and Motor Home Chassis Units 1. Install the gauge set and set up the vehicle as described under "Perform ance Test." 2. Movement of the temperature control knob should result in a definite change in suction pressure and cycling of the compressor clutch. • If compressor continued to operate regardless of the knob adjustment, it indicates that the switch points are fused which will lead to evaporator freeze-up. Replace the switch. • If the compressor does not operate, regardless of the position of the knob, a loss of the power element charge is indicated (provided that it has been established that power is supplied to the switch). This, of course, results in no cooling. Replace the switch. • Check the switch adjusting screw for stripped or otherwise damaged threads. C-K Models 1. Install the gauge set and set up the vehicle as described under "Perform ance Test". 2. Set the control at A/C, HI blower, max COLD and run the engine at 2000 rpm. • The therm ostatic switch should cycle the compressor off when the low limit of the outlet air temperature is reached (see Performance Data). If it does not, the switch points are fused which will lead to evaporator freeze up. Replace the switch. • If the compressor does not operate, a loss of power element charge is indicated (provided that it has been established that power is supplied to the switch). This, of course, results in no cooling. Replace the switch. • Check the switch adjusting screw for stripped or otherwise damaged threads. Adjusting Switch If, after the above checks, the switch seems to be operating properly, adjust for proper setting if necessary, as follows: 1. Vehicle must be set up as described in "Perform ­ ance Test." 2. The suction side of the system, read on the low pressure gauge, should pull down to the pressure shown in the chart in "Perform ance D ata" under the ambient temperature at the time the switch is being set. 3. Remove the switch as outlined in the "Component Part Replacement" section of this manual. 4. Remove the switch non-metal end plate to gain access to the switch adjusting screw. LIGHT DUTY TRUCK SERVICE MANUAL 1A-52 HEATER A N D AIR C O N D IT IO N IN G 5. If the outlet temperature was less than the prescribed temperature at the end of each cooling cycle, turn the adjusting screw a partial turn counterclockwise (fig. 53). If the outlet temperature was more than prescribed temperature, turn the adjusting screw clockwise. NOTE: One turn of the adjusting screw will change the outlet temperature approximately 4 degrees. 6. Reinstall switch end plate and reinstall switch. Reinstall face plate (Motor Home Chassis Units) or evaporator cover (G models) before attempting a performance test. Be sure that the air sensing capillary has been replaced properly. 7. Check system performance. If further adjustment is needed, repeat Steps 3 through 6 until the prescribed pressure is reached. NOTE: Do not attempt to run a Performance Check with the system disassembled since inaccurate readings would be the result. ALWAYS reinstall switch and capillary and any duct work before running a performance check. EXPANSION VALVE (Fig. 54) An expansion valve is used on C-K Model Overhead Systems, all G Model systems and Motor Home Chassis Units. A malfunction of the expansion valve will be caused by one of the following conditions; valve stuck open, valve stuck closed, broken power element, a restricted screen or an improperly located or installed power element bulb. Attachment of the expansion valve bulb to the evaporator outlet pipe is very critical. The bulb must be attached tightly to the pipe and must make good contact with the pipe along the entire length of the bulb. A loose THERMOSTATIC SWITCH Fig. 54-Expansion Valve bulb will result in high "high side" pressures and poor cooling. On bulbs located outside the evaporator case, insulation must be properly installed. Indications of expansion valve trouble provided by the Performance Test are as follows: VALVE STUCK OPEN Noisy Compressor. No Cooling - Freeze Up. VALVE STUCK CLOSED, PLUGGED SCREEN OR BROKEN POWER ELEM ENT Very Low Suction Pressure. No Cooling. POORLY LOCATED POWER ELEMENT BULB Normal Pressure. Poor Cooling. Check for Defective Valve FOAM INSULATION SWITCH TOCOVER SCREWS COVER Fig. 53-Thermostatic Switch Adjustment The following procedure must be followed to determine if a malfunction is due to a defective expansion valve. 1. Check to determine if the system will meet the performance test as outlined previously. If the expansion valve is defective, the low pressure readings will be above specification. 2. The loss of system performance is not as evident when the high side pressure is below 200 PSI. Therefore, it may be necessary to increase the system high side pressure by partially blocking the condenser. Disconnect the blower lead wire and repeat the "Performance Check" to determine if the low side pressure can be obtained. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 3. The system will also indicate a low refrigerant charge by bubbles occurring in the sight glass. ENGINE IDLE COMPENSATOR This additional aid to prevent stalling during prolonged hot weather periods is included with all air conditioned 1A-53 vehicles. The idle compensator is a thermostatically controlled air bleed which supplies additional air to the idle mixture. On V-8 engines, with factory installed air conditioning systems, the compensator is located within the carburetor and is accessible when the engine air cleaner is remove. GENERAL REPAIR PROCEDURES PREPARING SYSTEM FOR REPLACEMENT OF COMPONENT PARTS Air conditioning, like many other things, is fairly simple to service once it is understood. However, there are certain procedures, practices and precautions that should be followed. For this reason it is strongly recommended that the preceding information in this section be studied thoroughly before attempting to service the system. G reat emphasis must be placed upon keeping the system clean. Use plugs or caps to close system components and hoses when they are opened to the atmosphere. Keep your work area clean. In removing and replacing any part which requires unsealing the refrigerant circuit the following operations, which are described in this section, must be performed in the sequence shown. 1. Purge the system by releasing the refrigerant to the atmosphere. 2. Remove and replace the defective part. 3. Evacuate, charge and check the system. W ARNING: Always wear protective goggles when working on refrigeration systems. Goggles J-5453 are included in the set of air conditioning special tools. Also, beware of the danger of carbon monoxide fumes by avoiding running the engine in closed or improperly ventilated garages. FOREIGN MATERIAL IN THE SYSTEM Whenever foreign material is found in the system, it must be removed before restoring the system to operation. In the case of compressor mechanical failure, perform the following operations: 1. Remove the compressor. 2. Remove the receiver-dehydrator or expansion tube and discard the unit. 3. Flush the condenser to remove foreign material which has been pumped into it. 4. Disconnect the line at the evaporator core inlet (CK Four-Season System) or inlet line to the expansion valve (except C-K Four-Season System). Inspect the expansion tube or inlet screen of the expansion valve for the presence of metal chips or other foreign material. If the tube or screen is plugged, replace it. Reconnect the line to the evaporator core or expansion valve. 5. Install the replacement compressor. 6. Add the necessary quantity of oil to the system (one fluid ounce because of receiver-dehydrator replace­ ment plus the quantity needed for the replacement compressor - see "Checking Compressor Oil Charge" under "Checking Oil." 7. Evacuate, charge and check system. REFRIGERANT LINE CONNECTIONS " 0 " Rings Always replace the "O " ring when a connection has been broken. When replacing the "O " ring, first dip it in clean refrigeration oil. Always use a backing wrench on "O " ring fittings to prevent the pipe from twisting and damaging the "O " ring. Do not overtighten. Correct torque specifications are as follows: CAUTION: Where steel to aluminum connec­ tions are being made, use torque for aluminum tubing. Metal Thread and Tube Fitting O.D. Size 7/16 1/4 3/8 5/8 3/4 1/2 5/8 7/8 3/4 1-1/16 * Foot Pounds Steel Tubing Torque* 13 33 33 33 33 Alum. Tubing Torque* 6 12 n 20 25 Hose Clamps When hose clamp connections are encountered, special procedures are necessary for both removal and installation. Removal 1. Carefully, with a sharp knife, make an angle cut in LIGHT DUTY TRUCK SERVICE MANUAL 1A-54 HEATER A N D AIR C O N D IT IO N IN G the hose as shown in Figure 55. This should loosen the hose so that it may be worked off the fitting. 2. Cut off slit end of hose. CAUTIO N : Use only approved refrigeration hose. Never use heater hose. Use extreme care not to nick or score the sealing beads when cutting off the hose. Cutting the hose lengthwise may result in this problem. Installation 1. Coat tube and hose with clean refrigeration oil. 2. Carefully insert hose over the three beads on the fitting and down as far as the fourth, or locating bead. Hose must butt against this fourth bead. CAUTIO N: Use no sealer o f any kind. 3. Install clamps on hose, hooking the locating arms over the cut end of the hose. 4. Tighten the hose clamp screw to 35-42 in. lbs. torque. DO NOT RETORQUE. The clamp screw torque will normally decrease as the hose conforms to the force of the clamp. The screw should be retorqued only if its torque falls below 10 in. lbs. In this case, retorque to 20-25 in. lbs. Further tightening may damage the hose. REPAIR OF REFRIGERANT LEAKS Any refrigerant leaks found in the system should be repaired in the m anner given below: Leaks at " 0 " Ring Connection 1. Check the torque on the fitting and, if too loose, tighten to the proper torque. Always use a backing wrench to prevent twisting and damage to the "O " ring. Do not overtighten. Again leak test the joint. 2. If the leak is still present, discharge the refrigerant from the system as described under "Evacuating and Charging Procedures." 3. Inspect the "O " ring and the fitting and replace if damaged in any way. Coat the new "O " ring with clean refrigeration oil and install carefully. 4. Retorque the fitting, using a backing wrench. 5. Evacuate, charge and check the system. Leaks at Hose Clamp Connection 1. Check the tightness of the clamp itself and tighten if necessary. Recheck for leak. 2. If leak has not been corrected, discharge the system and loosen clamp and remove hose from connec­ tion. Inspect condition of hose and connector. Replace scored or damaged parts. 3. Dip end of new hose in clean refrigeration oil and carefully reinstall over connector. Never push end of hose beyond the locating bead. Properly torque the clamp. 4. Evacuate, charge and check the system. Compressor Leaks MAKE ANGULAR CUT FOR HOSE REMOVAL If leaks are located around the compressor shaft seal or shell, replacement of necessary seals should be made as outlined under “Compressor” in the Overhaul Manual. NOTE: A slight amount of oil leakage past the compressor front seal is considered normal. HOSE CLAMP LOCATING BEAD HOSE CLAMP HOSE HOSE SEALING BEADS Fig. 55 -Hose Clamp Connections LOCATING BEAD REFRIGERANT HOSE FAILURE After a leak or rupture has occurred in a refrigerant hose, or if a fitting has loosened and caused a considerable loss of refrigerant and oil, the entire system should be flushed and recharged after repairs have been made. If the system has been open to atmosphere for any prolonged period of time the receiver-dehydrator or accumulator should be replaced. Because of the length of the hoses on these systems, hose leaks may be repaired using the following procedure: 1. Locate the leak. This may require removing the body inner side panels to gain access to the hoses (Overhead Systems). 2. Discharge the system. 3. Cut out the leaking portion of the hose, making LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G sure that all of the failed portion is removed. If only a very small portion of the hose was removed, it may be possible to splice the two ends together using a special hose connector and two hose clamps. If several inches of hose must be removed, a new piece of hose should be spliced in using two connectors and four hose clamps. Dip the ends of the hoses in clean refrigeration oil before installing the hoses onto the connector. Never push the end of the hose beyond the locating bead of the connector. Torque the clamp to 35-42 in. lbs. NOTE: Be sure to replace the hose in the body in the same m anner as when removed. If the hose protective grommets are badly mutilated, they should be replaced. 4. Evacuate, charge and check the system. COMPRESSOR C-K Models Removal (Fig. 56) 1. Purge the refrigerant from the system. 2. Remove connector attaching bolt and connector. Seal connector outlets. 3. Disconnect electrical lead to clutch actuating coil. 4. Loosen brace and pivot bolts and detach belt. 5. Remove the nuts and bolts attaching the compres­ sor brackets to the mounting bracket. 6. Before beginning any compressor disassembly, drain and measure oil in the compressor. Check for evidence of contamination to determine if rem ain­ der of system requires servicing. Compressor servicing information is located in the Overhaul Manual. Installation 1. If oil previously drained from the compressor upon removal shows no evidence of contamination, replace a like amount of fresh refrigeration oil into the compressor before reinstallation. If it was necessary to service the entire system because of excessive contamination in the oil removed, install a full charge of fresh refrigeration oil into the compressor. 2. Position compressor on the mounting bracket and install all nuts, bolts and lock washers. 3. Install the connector assembly to the compressor rear head, using new "O " rings coated with clean refrigeration oil. 4. Connect the electrical lead to the coil and install and adjust compressor belt. 5. Evacuate, charge and check the system. 1A-55 G and Motor Home Chassis Models Removal (Fig. 56) 1. 2. 3. 4. Disconnect battery ground cable. Disconnect compressor clutch connector. Purge the system of refrigerant. Release the belt tension at the idler pulley and remove the belt from the compressor pulley. On some vehicles it may be necessary to remove the crankshaft pulley in order to remove the belt. 5. G Models-Remove the front air conditioning distributor duct described later in this section. 6. G Models-Remove the two bolts and two clamps that hold the engine cover and remove the cover. 7. Remove the air cleaner to aid access to the compressor. 8. Remove fitting and muffler assembly and cap or plug all open connections. 9. Remove the nuts and bolts attaching the compres­ sor to the bracket. 10. Remove the engine oil tube support bracket bolt and nut from the compressor, also compressor clutch ground lead. 11. Remove bolt and nut holding muffler assembly to front of compressor (also holds vacuum line on power assisted brake equipped vehicles; if neces­ sary, remove vacuum hose at manifold end). Before beginning any compressor disassembly, drain and measure oil in the compressor. Check for evidence of contamination to determine if rem ainder of system requires servicing. Compressor Servicing inform ation is located in the Overhaul Manual. Installation 1. If the oil drained from the compressor showed no evidence of contamination, replace a like amount of fresh refrigeration oil into the compressor before reinstallation. If it was necessary to service the entire system because of excessive contamination in the oil removed, install a full charge of fresh refrigeration oil in the compressor. (See Checking Compressor Oil Charge in the Service Manual.) 2. Position compressor on the mounting bracket and install all nuts, bolts, lock washers, and mount oil dip stick tube, muffler, vacuum brake hose (if equipped), and ground wire. 3. Install the connector assembly to the compressor rear head, using new "O " rings coated with clean refrigeration oil. 4. Connect the electrical lead to the coil and install and adjust compressor belt, using idler pulley. See "Compressor Belt Tension Adjustment." 5. Evacuate, charge and check the system. 6. Replace air cleaner. On G models, replace the engine cover and air distributor duct. LIGHT DUTY TRUCK SERVICE MANUAL 1A-56 HEATER A N D AIR C O N D IT IO N IN G 307- 350 V- 8 G C-K MODELS AND MOTOR HOME CHASSIS 4 5 4 V -8 C-K MODELS Fig. 56-Compressor Mountings Compressor Belt Tension Adjustment Adjust the compressor belt to the specifications shown in the Tune-Up chart in the Engine section of the Service Manual. NOTE: On some G and Motor Home Chassis models it may be necessary to increase idler pulley slack adjustm ent. This may be accomplished by (1) Remove and discard the idler adjustment bolt. (2) Remove the idler backing plate and elongate all 3 adjusting slots 1/2 inch inboard or outboard as required. (3) Reinstall the idler assembly and adjust belt tension using a lever (screwdriver, etc.) to move the pulley outboard until proper belt tension is reached. If the belt is being LIGHT DUTY TRUCK SERVICE MANUAL HEATER AND AIR C O N D IT IO N IN G replaced it may be necessary to remove and replace the throttle cable during the belt replacement. If so check throttle cable adjustment upon completion. It may also be necessary to remove the crankshaft pulley to install a new compressor belt. COMPRESSOR FAILURE If the compressor has failed mechanically to the extent that metal chips and shavings are found in it, the system should be checked for foreign material and cleaned as described under Foreign M aterial in the System. FALSE COMPRESSOR SEIZURE Slipping or broken air conditioning drive belts and/or scored clutch surfaces may be experienced on initial start up of an air conditioning compressor after an extended period of storage or non-operation of the compressor. This would indicate a seized compressor; however, an overhaul or replacement of the compressor may not be necessary. During extended periods of non-operation, changes in temperature cause the refrigerant in the air conditioning compressor to expand and contract. During this movement, lubricating oil carried by the refrigerant tends to migrate from highly polished surfaces in the compressor such as the ball seats and wobble plate. W ithout lubricating oil at these polished surfaces, they "w ring" together and appear to be seized. Before the time and expense of an overhaul is invested, use the following check to determine if the compressor is actually seized. With a wrench on the compressor shaft lock nut or Spanner Wrench J-9403 on ihe clutch drive plate, "rock" the shaft in the opposite direction of normal rotation. After the compressor is broken loose, "rock" the shaft back and forth. This should be sufficient to return lubricating oil to the "wrung" surfaces and allow the compressor shaft to be turned by hand. Once the compressor turns freely, rotate the compressor at least three complete turns. Start the engine and operate the compressor for a minimum of one minute. This procedure will not affect a compressor that is actually seized but should be attem pted before overhauling a compressor known to be idle for a month or longer. COLLISION PROCEDURE-ALL SYSTEMS Whenever a vehicle equipped with an air conditioning unit is involved in a collision or wreck, it should be inspected as soon as possible. The extent of damage to any or all of the component parts and the length of time the system has been exposed to the atmosphere will determine the replacement of parts and processing that will be required. The greater the length of time of exposure to the atmosphere, the greater will have been the chances for air, moisture and dirt to have entered and damaged the system. Every case may be entirely 1A-57 different so it is not possible to establish a hard and fast procedure to follow each time. Good judgment must be used to determine what steps should be taken in each specific case. The following procedure is presented as a guide for use when inspecting a damaged vehicle equipped with air conditioning. 1. Remove the drive belt. 2. Visually inspect the condenser, accumulator, receiver-dehydrator, compressor, mounting brack­ ets, conditioning unit, all connecting lines, and all controls to determine the extent and nature of the damage. a. No repairs, such as soldering, welding or brazing, should be attempted on the condenser because of its construction. If the vapor passages in the horizontal tubes or return bends or manifolds have been damaged in any way, the condenser should be replaced with a new one. b. The accumulator or receiver-dehydrator should be replaced if there is any evidence of its having sustained either internal damage or a fracture at any of the lines or welded joints or if the system has been exposed to the atmosphere for an undetermined period of time. c. Examine the compressor for any visible external damage. d. The evaporator should be examined for damage and, if necessary, removed or replaced or the entire unit processed where damaged or exposed to the atmosphere. e. All connecting lines and flexible hoses should be examined throughout their entire length for damage. If damaged in any manner, replace with new lines. f. Check all controls and connecting wires for damage and replace with new parts where needed. g. Check the clutch pulley for proper operation and freedom from damage. 3. Install Charging Station. 4. Purge the system. 5. Remove the compressor from mounting and remove the oil test fitting. 6. Pour out the oil into a clean glass container and examine it for any foreign substance such as dirt, water, metal particles, etc. If any of these are present, the compressor, expansion tube, and accumulator or receiver-dehydrator should be replaced and the other system components should be flushed with liquid refrigerant. 7. If the oil is clean and free of any harmful substance, replace oil with Frigidaire 525 Viscosity Oil, or equivalent. NOTE: If the system components have been LIGHT DUTY TRUCK SERVICE MANUAL 1A-58 HEATER A N D AIR C O N D IT IO N IN G replaced or flushed, replace the full charge of oil. If not, add no more fresh oil than was drained in Step 6. 8. Charge up the compressor to cylinder or can pressure and leak test the compressor seals prior to installation of compressor. 9. Reinstall the compressor and evacuate the system by following the Evacuating Procedure. 10. Introduce R-12 vapor at cylinder (room) tempera­ ture and pressure. 11. Leak test all fittings and connections and give particular attention to a leak test at the compressor shaft seal if compressor has not been leak tested on the bench. 12. Complete system processing and charge system. C O M P O N E N T PART REPLACEMENT FOUR-SEASON SYSTEM-C-K MODELS CONDENSER (Fig. 57) Replacement 1. 2. 3. 4. 5. 6. 7. 8. 9. Disconnect battery ground cable. Purge the system of refrigerant. Remove the grille assembly. Remove the radiator grille center support. Remove the left grille support to upper fender support (2) screws. Disconnect the condenser inlet and outlet lines and the outlet tube line at the right end of the condenser. Cap or plug all open connections at once. Remove the condenser to radiator support screws. Bend the left grille support outboard to gain clearance for condenser removal. Remove the condenser assembly by pulling it forward and then lowering it from the vehicle. Fig. 5 7 -Condenser Installation (C-K Models) 10. To install a new condenser, reverse Steps 1-9 above. Add one fluid ounce of clean refrigeration oil to a new condenser. NOTE: Use new "O " rings, coated with clean refrigeration oil, when connecting all refrig­ erant lines. 11. Evacuate, charge and check the system. ACCUMULATOR Replacement (Fig. 58) 1. Disconnect the battery ground cable and the compressor clutch connector. 2. Purge the system of refrigerant. WARNING: Be sure system is completely purged of refrigerant before completely disconnecting refrigerant lines. Fig. 58--Accumulator Installation (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 3. Disconnect the accumulator inlet and outlet lines and cap or plug the open connections at once. 4. Remove the outlet line clamp screw and the accumulator clamp screw and remove the unit from the vehicle. 5. If a new accumulator is being installed, add 1 fluid ounce of clean refrigeration oil to the new accumulator. 6. Install the new unit following Steps 1-4 in reverse order. Connect all lines using new "O " rings, coated with clean refrigeration oil. CAUTION: Do not uncap the new unit until ready to fasten the inlet and outlet line to the unit. 7. Evacuate charge and check the system. BLOWER ASSEMBLY Replacement 1. Disconnect the battery ground cable. 2. Disconnect the blower motor lead and ground wires. 3. Disconnect the blower motor cooling tube. 4. Remove the blower to case attaching screws and remove the blower assembly. Pry the blower flange away from the case carefully if the sealer acts as an adhesive. 5. Remove the nut attaching the blower wheel to the motor shaft and separate the assemblies. 6. To install, reverse Steps 1-5 above; replace sealer as necessary. EVAPORATOR CORE Replacement (Fig. 59) 1. Disconnect the battery ground cable. 1A-59 2. Purge the system of refrigerant. 3. Remove the nuts from the selector duct studs projecting through the dash panel. 4. Remove the cover to dash and cover to case screws and remove the evaporator case cover. 5. Disconnect the evaporator core inlet and outlet lines and cap or plug all open connections at once. 6. Remove the thermostatic switch and the expansion tube assemblies. 7. Remove the evaporator core assembly. 8. To install, reverse Steps 1-7 above. Add three ounces of clean refrigeration oil to a new evaporator core. CAUTION: Be sure to install the thermostatic switch capillary in the hole provided in the new core. NOTE: Use new "O " rings, coated with clean refrigeration oil, when connecting refrigerant lines. Be sure cover to case and dash panel sealer is intact before reinstalling cover. 9. Evacuate, charge and check the system. EXPANSION TUBE The expansion tube is located in the evaporator core inlet line. Replacement (Fig. 60) 1. Purge the system of refrigerant. 2. Disconnect the condenser to evaporator line at the evaporator inlet. Cap the open line at once. Fig. 60 -Expansion Tube (C-K Four-Season System) LIGHT DUTY TRUCK SERVICE MANUAL 1A-60 HEATER A N D AIR C O N D IT IO N IN G 3. Using needle-nose pliers, remove the expansion tube from the evaporator core inlet line (fig. 60). 4. Remove the expansion tube "O " ring from the core inlet line. 5. To install, reverse Steps l-4 above. NOTE: Install the expansion tube using a new "O " ring, coated with clean refrigeration oil. 6. Evacuate, charge and check the system. SELECTOR DUCT AND HEATER CORE ASSEMBLY Replacement (Figs. 61 and 62) 1. Disconnect the battery ground cable. 2. Drain the radiator and remove the heater hoses from the core tubes. Plug the core tubes to prevent coolant spillage during removal. 3. Remove the glove box and door as an assembly. 4. Remove the center duct to selector duct and instrument panel screws and remove the center lower and center upper ducts. 5. Disconnect the bowden cable at the temperature door. 6. Remove the nuts from the three selector duct studs projecting through the dash panel. 7. Remove the selector duct to dash panel screw (inside vehicle). 8. Pull the selector duct assembly rearward until the core tubes clear the dash panel. Lower the selector assembly for enough to gain access to all vacuum and electrical harness. 9. Disconnect the vacuum and electrical harness and remove the selector duct assembly. 10. Remove the core mounting strap screws and remove the core. 11. To install, reverse Steps 1-10 above. 12. Refill coolant system and connect the battery ground strap. KICK PAD VALVE Replacement (Fig. 63) 1. 2. 3. 4. Disconnect the vacuum hose at the actuator. Unhook the valve return spring at the actuator end. Remove the actuator bracket mounting screws. Remove the cam to actuator arm screw and separate the actuator and bracket from the cam. 5. Remove the actuator to bracket nuts and separate the actuator and bracket. 6. To install reverse Steps 1-5 above. PLENUM VALVE Replacement (Fig. 63) 1. Raise the hood. 2. Remove the cowl plastic grille. 3. Remove the three cowl to valve assembly screws and remove the valve assembly from the vehicle. 4. Remove the actuator arm push nut. 5. Remove the actuator to valve nuts and separate the valve and actuator. 6. To install, reverse Steps 1-5 above. CONTROL ASSEMBLY Removal (Fig. 64) 1. Disconnect the battery ground cable. 2. Remove the radio as outlined in Section 15 of this manual. 3. Remove the instrument panel bezel. 4. Remove the control to instrum ent panel screws and lower the control far enough to gain access to the control assembly. CAUTIO N: Be careful not to kink the bowden cable. Disconnect the bowden cable, vacuum harness and electrical harness at the control. Remove the control through the radio opening. If a new unit is being installed, transfer all electrical switches and vacuum valves to the new control. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-61 Fig. 62 -Air Selector and Ducts (C-K Models) 8. To reinstall, reverse Steps 1-6 above. Check control operation. MASTER SWITCH AND/OR BLOWER SWITCH The master switch is located on top of the control assembly. Replacement 1. Disconnect the battery ground cable. 2. Remove the instrument panel bezel. 3. Remove the control to instrument panel screws and allow control to rest on top of the radio. 4. Remove the switch to control screws, disconnect the electrical harness at the switch and remove the switch assembly. 5. To install a new switch, reverse Steps 1-4 above. VACUUM TANK The vacuum tank is mounted to the engine side of the dash panel above the blower assembly (fig. 65). Replacement 1. Disconnect the vacuum lines at the tank. 2. Remove the tank to dash panel screws and remove the tank. 3. To install, reverse Steps 1 and 2 above. BLOWER MOTOR RESISTOR The blower motor resistor is located in the blower side of the blower-evaporator case (fig. 66). Replacement 1. Disconnect the wiring harness at the resistor. 2. Remove the resistor to case attaching screws and remove the resistor. 3. Place the new resistor in position and install the attaching screws. 4. Connect the resistor wiring harness. LIGHT DUTY TRUCK SERVICE MANUAL 1A-62 HEATER A N D AIR C O N D IT IO N IN G BLOWER MOTOR RELAY The blower motor relay is located on the blower side of the blower-evaporator case (fig. 66). Replacement 1. Disconnect the wiring harness at the relay. 2. Remove the relay to case attaching screws and remove the relay. 3. Place the new relay in position and drive the mounting screws. 4. Connect the relay wiring harness. THERMOSTATIC SWITCH The thermostatic switch is mounted to the blower side of the blower-evaporator case. The switch sensing capillary extends into the evaporator core. Replacement 1. Disconnect the battery ground strap. 2. Disconnect the wiring harness at the switch. 3. Remove the switch to case screws and remove the switch carefully so as not to damage the capillary tube. NOTE: Note capillary tube position in the core so that the capillary may be reinstalled in the same position (fig. 67). 4. Place the new switch in position, installing the capillary in the core in the same m anner as at switch removal. 5. Drive the switch mounting screws, connect the wiring harness and the battery ground strap. DISCHARGE PRESSURE SWITCH The discharge pressure switch is located in the condenser to evaporator line (fig. 68). Replacement 1. 2. 3. 4. Disconnect the battery ground cable. Purge the system of refrigerant. Disconnect the wiring harness at the switch. Remove the switch from the refrigerant line. LIGHT DUTY TRUCK SERVICE MANUAL HEATER AND AIR C O N D IT IO N IN G 1A-63 BLOWER RESISTOR THERMOSTATIC SWITCH ASSEMBLY EVAPORATOR CORE i BLOWER RELAY CAPILLARY POSITION IN CORE THERMOSTATIC SWITCH Fig. 67-Replacing Thermostatic Switch Fig. 66-Resistor, Relay and Thermostatic Switch (C-K Models) 5. To replace, reverse Steps 1-4 above. NOTE: Be sure to use new "O " rings, coated with clean refrigeration oil, when installing the switch. 6. Evacuate charge and check system operation. FUSE A 25 amp fuse, located in the junction block protects the entire air conditioning system except for the blower when operating at HI. A second 25 amp fuse, to protect the HI speed blower circuit, is located in the electrical wiring between the junction block and the blower relay (fig. 69). LIGHT DUTY TRUCK SERVICE MANUAL 1A -64 HEATER A N D AIR C O N D IT IO N IN G C O M P O N E N T PART REPLACEMENT OVERHEAD SYSTEM-C-K MODELS The Overhead System is used in conjunction with the Four-Season System. Since replacement of Four-Season System components has been covered previously, only those components peculiar to the Overhead System will be covered in this section. REAR DUCT This duct covers the blower-evaporator assembly, at the rear of the vehicle, and incorporates four adjustable air outlets (fig. 70). Replacement 1. Disconnect the battery ground cable. 2. Disconnect the drain tube from the rear duct. 3. Remove the screws securing the duct to the roof panel. 4. Remove the duct from the side and rear retaining flanges and remove the duct. 5. To install, reverse Steps 1-4 above. BLOWER MOTOR RESISTOR The blower motor resistor is located on the cover side of LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-65 Fig. 71-Overhead System Front Wiring (C-K Models) the Four-Season System blower-evaporator as shown in Figure 71. Replacement 1. Disconnect battery ground cable. 2. Disconnect the electrical harness at the resistor. 3. Remove the resistor attaching screws and remove the resistor. 4. To install a new resistor, reverse Steps 1-3 above. BLOWER MOTOR ASSEMBLY Removal 1. 2. 3. 4. 5. Disconnect the battery ground cable. Remove the rear duct as outlined previously. Disconnect the blower motor ground strap. Disconnect the blower motor lead wire. Remove the lower to upper blower-evaporator case screws and lower the lower case and motor assembly. CAUTION: Before removing the case screws, support the lower case to prevent damage to the case or motor assemblies. 6. Remove the motor retaining strap and remove the motor and wheels. Remove the wheels from the motor shaft. Installation 1. Place the blower wheels onto the motor shaft and install the setscrews; do not tighten the setscrews at this time. CAUTION: Be sure that the blower wheels are installed as shown in Figure 73. 2. Install the blower motor retaining strap and foam. 3. Place the blower motor and wheel assembly into the lower case. Align the blower wheels so that they do LIGHT DUTY TRUCK SERVICE MANUAL 1A-66 HEATER A N D AIR C O N D IT IO N IN G EVAPORATOR SCREEN EXPANSION VALVE Fig. Fig. 73 -Blower Motor (C-K Overhead System) 4. 5. 6. 7. not contact the case and then tighten the wheel setscrews. Place the lower case and blower motor assembly in position in the vehicle and install the lower to upper case screws. NOTE: Rotate the blower wheels to make sure that they do not rub on the case. Install the center ground wire and connect the blower lead wire. Install the rear duct assembly as described previously. Connect the battery ground cable. EXPANSION VALVE This system incorporates an expansion valve which does not utilize an external equalizer line (fig. 74). 2. 3. 4. 5. 6. Disconnect the battery ground cable. Purge the system of refrigerant. Remove the rear duct as outlined previously. Disconnect the blower motor lead and ground wires. 5. Remove the lower to upper blower-evaporator case screws and lower the lower case and motor assembly. CAUTION: Before removing the case screws, support the lower case and motor assemblies. 6. Remove the expansion valve sensing bulb clamps. 7. Disconnect the valve inlet and outlet lines and remove the expansion valve assembly. Cap or plug the open connections at once. Installation 1. Remove caps or plugs from system connections and EVAPORATOR CORE 7 4 -E x p a n s io n V alve (C-K SENSING BULB O v e rh e a d S y s te m ) install the new valve assembly using new "O " rings coated with clean refrigeration oil. Install the sensing bulb, making sure that the bulb makes good contact with the core outlet line. Install the lower case and blower motor assemblies. Connect the blower motor lead and ground wires. Install the rear duct as outlined previously. Connect the battery ground cable. Evacuate, charge and check the system. EVAPORATOR CORE (Fig. 74) Removal 1. 2. 3. 4. 5. Removal 1. 2. 3. 4. BLOWER-EVAPORATOR UPPER CASE 6. 7. 8. 9. Disconnect the battery ground cable. Purge the system or refrigerant. Remove the rear duct as outlined previously. Disconnect the blower motor lead and ground wire connections. Disconnect the refrigerant lines at the rear of the blower-evaporator assembly. Cap or plug the open connections at once. Remove the blower-evaporator to roof panel support nuts and washers, lower the blowerevaporator assembly and place it on a work bench upside down. Remove the lower to upper case screws and remove the lower case assembly. Remove the upper case from the evaporator core. Remove the expansion valve inlet and outlet lines and cap or plug the open connections at once. Remove the expansion valve capillary bulb from the evaporator outlet line and remove the valve. Remove the plastic pins holding the screen to the core and remove the screen. Installation 1. Install the wire screen to the front of the core and insert the plastic pins. 2. Install the expansion valve inlet and outlet lines LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1A-67 5. Install the blower-evaporator to the roof panel support. 6. Connect the refrigerant lines to the blowerevaporator unit using new "O " rings coated with clean refrigeration oil. 7. Connect the blower lead and ground wires. 8. Install the rear duct as outlined previously. 9. Connect the battery ground cable. 10. Evacuate, charge and check the system. BLOWER MOTOR SWITCH The three-speed (LO-MED-HI) blower motor switch is located in the instrument panel, just to the left of the ash tray (fig. 75). Replacement Fig. 75-Blower Switch (C-K Overhead System) using new "O " rings coated with clean refrigeration oil. Install the sensing bulb to the evaporator outlet line as shown in Figure 74; make sure the bulb has good contact with the line. NOTE: Add 3 oz. clean refrigeration oil when installing a new core. 3. Install the upper case to the core. 4. Install the lower core case and blower assembly. 1. Disconnect the battery ground cable. 2. Remove the switch retaining screws. 3. Disconnect the wiring harness at the switch and remove the switch. 4. To install, reverse Steps 1-3 above. FUSE The Four Season portion of this system is protected by a 25 amp fuse in the junction block. The rear blower high speed circuit is protected by a 25 amp in-line fuse, located between the junction block and the rear blower motor switch. C O M P O N E N T PART REPLACEMENT FLOOR M O UNTED SYSTEM -G MODELS CONDENSER Replacement (Fig. 76) 1. Remove the battery ground cable and compressor clutch connector. 2. Purge the system of refrigerant. 3. Remove the screws that retain the headlight mouldings and remove the screws for the grille. Remove the mouldings then remove the grille. 4. Remove the screws from radiator center brace and remove the brace. 5. Disconnect the condenser inlet and outlet lines and cap or plug the open connections at once. 6. Disconnect the receiver-dehydrator outlet line and cap or plug the open connections at once. 7. Remove the (4) condenser bracket bolts and remove the condenser from the vehicle. 8. Remove the condenser mounting brackets from the condenser. LIGHT DUTY TRUCK SERVICE MANUAL 1A-68 HEATER AND AIR C O N D IT IO N IN G 9. To install, reverse Steps l-8 above. Add l fluid ounce of clean refrigeration oil to a new condenser. CAU TIO N : Use new "O" rings, coated with clean refrigeration oil, when connecting all refrigerant lines. 10. Evacuate, charge and check the system. 2. Lift upward and rearward on the top of the distributor duct assembly and move it away from the evaporator and blower motor assembly cover, being careful not to damage the seal. 3. To reinstall, reverse Steps 1 and 2, making sure seal to evaporator and blower motor cover is properly positioned. RECEIVER-DEHYDRATOR BLOWER-EVAPORATOR COVER Replacement (Fig. 76) Replacement (Fig. 78) 1. Disconnect the battery ground cable, and the compressor clutch connector. 2. Purge the system of refrigerant. 3. Remove the screws that retain the headlight mouldings and the screws for the grille. Remove the mouldings and remove the grille. 4. Disconnect the receiver-dehydrator inlet and outlet lines and cap or plug the connections at once. 5. Remove the receiver-dehydrator bracket attaching screws. 6. Remove the receiver-dehydrator from the vehicle. 7. If a new receiver-dehydrator is being installed, add 1 fluid ounce of clean refrigeration oil to the new unit. 8. Connect the inlet and outlet lines using new "O " rings coated with clean refrigeration oil. CAU TIO N : Do not uncap the new unit until ready to fasten the inlet and outlet lines to the unit. 9. Install receiver-dehydrator by reversing Steps 1-6 above. 10. Evacuate, charge and check the system. SIGHT GLASS REPLACEMENT If damage to the sight glass should occur, a new sight glass kit should be installed. The kit contains the sight glass, seal and retainer. (See Figure 77). 1. Purge system. 2. Remove the sight glass retainer nut using a screwdriver and remove old glass and "O " ring seal. 3. Install the new glass and seal and retainer nut, being careful not to turn the nut past the face of the housing. To do so may damage the "O " ring seal. 4. Evacuate, charge and check the system. AIR DISTRIBUTOR DUCT ASSEMBLY Replacement (Fig. 78) 1. Remove four screws that hold the duct to the engine cover. 1. Remove four screws holding the cover to the evaporator assembly. 2. Remove the temperature control knob and place the blower switch on M. 3. Remove the cover being careful not to damage the seal to the air distributor duct. 4. To reinstall, reverse Steps 1-3, being sure seal to air distributor duct is properly positioned. BLOWER-EVAPORATOR ASSEMBLY Removal (Fig. 79) 1. Disconnect battery ground cable, and compressor clutch lead from connector. 2. Purge system of refrigerant. 3. Remove the blower-evaporator cover as described previously. 4. Disconnect inlet and outlet refrigerant lines from underneath the unit, and cap or plug the connections at once. 5. Disconnect drain tubes from evaporator case. 6. Remove blower-evaporator assembly bracket bolts. 7. Remove electrical connections from switches, resistors, relays and blower motor. 8. To install reverse Steps 1-7 above. Make all refrigerant line connections using new "O " rings, coated with clean refrigeration oil. 9. Evacuate, charge and check the system. EXPANSION VALVE and/or EVAPORATOR CORE Replacement 1. Remove the blow er-evaporator as described previously. 2. Remove the cover plate and separate upper and lower case halves. 3. Disconnect inlet and outlet lines from the expansion valve. Cap or plug all open connections at once. Remove sensing bulb from the evaporator outlet manifold. Remove expansion valve. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A ND AIR C O N D IT IO N IN G 1A-69 Fig. 77-Sight Glass Replacement EVAPORATOR CONTROL. , BLOWER MOTOR Fig. 78-Air Distributor Duct and Blower-Evaporator Cover (Floor Mounted G Models) 4. Remove evaporator core retaining screws and remove core. 5. Remove blower motor and harness assembly from case. 6. To install, reverse Steps 1-5 above. NOTE: Add 3 fluid ounces of new refrigera­ Fig. 79-Blower-Evaporator (G Floor Mounted System) tion oil to a new core. Use new "O " rings, coated with clean refrigeration oil, when connecting all lines. LIGHT DUTY TRUCK SERVICE MANUAL 1A-70 HEATER A N D AIR C O N D IT IO N IN G 7. Evacuate, charge and check the system. Replacement BLOWER MOTOR Removal 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Remove the Front Blower-Evaporator Cover as previously described. 3. Disconnect the blower motor feed wire and ground wires. 4. Remove the blower-evaporator cover brackets from the assembly. 5. Remove the top half of the blower-evaporator case. 6. Remove blower motor mounting strap. 7. Remove blower assembly. Loosen the blower wheel setscrews and remove the wheels from the motor shaft. Installation 1. Install the blower wheels on the motor so that the lower blades curve toward the dash panel side of the unit when the motor is placed in the case. Do not tighten setscrews at this point. 2. Place the motor in the bracket with the electrical connector side of the motor to the right side of the bracket. Attach the mounting strap. Aligh blower wheels so that they do not contact case. Tighten setscrews. 3. Reverse removal Steps 1-5 for proper installation. 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Remove the blower-evaporator cover as described previously. 3. Disconnect the electrical harness at the switch. 4. Remove the attaching screws and remove the switch. 5. To install, reverse Steps 1-4 above. Check system operation. LOW REFRIGERANT CHARGE PROTECTION SYSTEM The low refrigerant charge protector system consists of a superheat shutoff switch located in the rear head of the compressor, connected in series by an electrical lead to a thermal fuse. During normal air conditioning system operating conditions, current flows through the air conditioner thermostatic control switch, and through the thermal fuse link to the clutch coil to actuate the compressor clutch. Should a partial or total loss of refrigerant in the system cause the superheat switch to sense low system pressure and a high suction gas temperature, the superheat switch contacts will close. When the contacts close, current flows to energize the resistance type heater in the thermal fuse, Figure 81. The resultant heat warms the fuse link to its specific melt temperature, thus opening the circuit to the compressor clutch coil. Compressor operation ceases and com- ELECTRICAL COMPONENTS The front and rear blower switches, thermostatic switch, front and rear resistors, blower and tie relays are attached to the blower-evaporator assembly (fig. 80). BLOWER SWITCHFLOOR SYSTEM THERMOSTATIC BLOWER RELAYFLOOR SYSTEM RESISTOROVERHEAD SYSTEM Sw i t c h - ™ J fRLATv0 ' SYSTEM SYSTEM Fig. 80- Electrical Components (G Floor Mounted System) Fig. 81-Superheat Switch Electrical Schematic LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-71 pressor damage due to a loss of refrigerant charge is prevented. The cause of the refrigerant loss must be corrected and the system charged prior to replacing the thermal fuse. The super­ heat switch does not have to be replaced when it cycles and is reusable unless it is determined that the switch is faulty. Superheat Switch (Fig. 82) The switch diaphragm and sensing tube assembly is charged with R -114 refrigerant and the sensing tube protrudes into the suction cavity of the rear compressor head to sense suction gas temperatures. The internal pressure of the diaphragm and sensing tube assembly is affected thermally by the suction gas temperature and the diaphragm affected externally by the suction pressure. The electrical contact welded to the diaphragm will only contact the terminal pin during a low pressure-high temperature condition. High pressure-high temperature or low pressure-low temperature conditions will not cause the contacts to close. The contacts may be either "open" or "closed" in a Tolerance Zone depending on the characteristics of the switch and accuracy of pressure and temperature readings taken. Fig. 83--Superheat Switch Removal Replacement 1. Completely discharge the air conditioning system. 2. After the system is discharged, remove the superheat switch retainer ring, using J-5403 Internal Snap Ring Pliers (fig. 83). 3. Remove superheat switch from the rear head by 4. 5. 6. TERMINAL ELECTRICAL CONTACT H O U S IN G 7. 8. D IAP H R AG M M TG . BASE BASE O P E N IN G S (4) D IA P H R A G M ASSEMBLY S E N S IN G TUBE 9. 10. pulling at the terminal housing groove with J-9393 or a pair of screwdrivers. Remove "O " ring from the switch cavity in the rear head. Use "O " ring removal Tool J-9553. Recheck superheat switch for closed contacts. See Superheat Switch Check in Service Diagnosis Table. Replace as necessary. Check the superheat switch cavity and "O " ring groove in the rear head for dirt or foreign material and be sure area is clean before installing the "O " ring. Install a new "O " ring in the groove of the superheat switch cavity in the rear head. Lubricate the "O " ring liberally with new refrigeration oil before installing. Lubricate housing of the superheat switch with new refrigeration oil, and insert switch carefully into switch cavity until switch bottoms. J-9393 may also be used to install the switch. Using J-5403 Internal Snap Ring Pliers, install superheat switch retaining ring with high point of the curved sides adjacent to the switch housing. Be sure retainer ring is properly seated in the snap ring groove. Check for electrical continuity between the switch terminal and switch housing to be sure the contacts are open according to the Calibration Chart (fig. 84). Evacuate, charge and check system operation. Thermal Fuse (Fig. 85) Fig. 82-Superheat Switch Schematic The thermal fuse consists of a temperature sensitive fuse LIGHT DUTY TRUCK SERVICE MANUAL 1A-72 HEATER A ND AIR C O N D IT IO N IN G TOLERANCE ZONE Fig. 85--Thermal Fuse SU CTIO N PRESSURE (PSIG) N O TE: For gauges c a lib ra te d in inches Hg vacuum , d ivid e ga u g e re a d in g by 2 .3 0 6 to o b ta in PSIG. Fig. 84-Superheat Switch Calibration Chart link, a wire wound resistor and three spade type electrical terminals, potted with epoxy in a plastic housing. The terminals are positioned for in-line plug-on connection with a wiring harness. The thermal fuse construction provides for a time delay in blowing the fuse link which prevents "blown fuse" nuisance due to m om entary switch contact closings during certain transient conditions. A blown thermal fuse indicates that the air conditioning system is either low or completely out of refrigerant charge, a m alfunctioning expansion valve or an improperly located thermal limiter. CIRCUIT BREAKER The entire air conditioning system is protected by a 45 amp circuit breaker located on the left side of the dash, in the engine compartment. C O M P O N E N T PART REPLACEMENT OVERHEAD SYSTEM -G MODELS This system is used in conjunction with the floor mounted system. Since replacement of the floor Mounted System Components has been covered previously, only those components peculiar to the Overhead system will be covered in this section. LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 1A-73 BLOWER-EVAPORATOR SHROUD This shroud covers the blower-evaporator at the rear of the vehicle, and incorporates four adjustable air outlets. CORRECT BLADE Replacement (Fig. 87) 1. Disconnect the battery ground cable. 2. Disconnect the drain tubes at the rear corners of the shroud. 3. Remove the screws securing the shroud to the unit and roof panel. 4. Remove the shroud from the side and rear retaining flanges and remove the shroud. 5. To install, reverse Steps 1-4 above. BLOWER MOTOR ASSEMBLIES Removal (Fig. 88) 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Remove the rear shroud as outlined previously. 3. Remove the blower motor ground straps at the center connector between the motors. 4. Disconnect the blower motor lead wires. W ARNING: Before removing the case screws, support the lower case to prevent damage to the case or motor assemblies. 5. Remove the lower to upper blower-evaporator case screws and lower the lower case and motor assemblies. 6. Remove the motor retaining strap and remove the LOWER CASE HALF Fig. 88- Blower Motors (G Overhead System) motor and wheels. Remove the wheels from the motor shaft. Installation 1. Place the blower wheels onto the motor shaft and install the setscrews; do not tighten the setscrews at this time. CAUTIO N: Be sure that the blower wheels are installed as shown in Figure 88. 2. Install the blower motor retaining strap and foam strip. 3. Place the two blower motor and wheel assemblies into the lower case. Align the blower wheels so that they do not contact the case and then tighten the wheel setscrews. 4. Place the lower case and blower motor assemblies in position in the vehicle and install the lower to upper case screws. NOTE: Rotate the blower wheels to make sure that they do not rub on the case. 5. Install the center ground wires and connect the blower lead wires. 6. Install the rear shroud assembly as described previously. 7. Connect the battery ground cable and compressor clutch connector. EXPANSION VALVES This system incorporates two expansion valves. These valves do not use an external equalizer line (fig. 89). Removal (Inner Valve) Fig. 87-Blower-Evaporator Shroud (G Overhead System) 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Purge the system of refrigerant. 3. Remove the rear shroud as outlined previously. LIGHT DUTY TRUCK SERVICE MANUAL 1A-74 HEATER A N D AIR C O N D IT IO N IN G VALVE SENSING BULBS 6. Remove the blower-evaporator to roof panel attachm ents and lower the blower-evaporator assembly. Remove the assembly and place on a work bench upside down. 7. Remove the lower to upper case screws and remove the lower case assembly. Remove the upper shroud from the upper case and then remove the upper case from the core. 8. Remove the expansion valve bulb from the evaporator outlet line. Remove the expansion valve inlet and outlet lines and cap or plug the open connections at once. Remove the valve. Installation (Outer Valve) VALVES Fig. 89--Expansion Valves (G Overhead System) W ARNING: Before removing the lower case screws, support the case to prevent damage to the case or motor assemblies. 4. Disconnect the center ground wire and the blower motor lead wires. Remove the lower to upper case screws and lower the lower case and blower motor assemblies. 5. Disconnect the valve sensing bulb from the core outlet line. 6. Disconnect the core inlet and outlet lines and remove the valve assembly. Cap or plug the open connections at once. installation (Inner Valve) 1. Remove caps or plugs from system connections and install the new valve assembly using new "O " rings coated with clean refrigeration oil. 2. Install the sensing bulb, making sure that the bulb makes good contact with the core outlet line. 3. Install the lower case and blower motor assemblies. 4. Install the rear shroud as outlined previously. 5. Connect the battery ground cable and compressor clutch connector. 6. Evacuate, charge and check the system. 1. Remove the caps or plugs from the refrigerant connections and install the new valve using new "O " rings coated with clean refrigeration oil. Install the sensing bulb, making sure that the bulb makes good contact with the core outlet line. 2. Install the upper case to the core making sure the sealing strips are positioned correctly. Install the upper shroud on the upper case. 3. Install the lower case and blower assemblies. 4. Install the blower-evaporator to the roof panel. 5. Connect the refrigerant lines at the rear of the blower-evaporator unit using new "O " rings coated with clean refrigeration oil. 6. Connect the blower lead wires and ground straps. 7. Install the rear shroud as described previously. 8. Connect the battery ground cable and the compressor clutch connector. 9. Evacuate, charge and check the system. BOW SUPPORT Removal (Outer Valve) 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Purge the system of refrigerant. 3. Remove the rear shroud as outlined previously. 4. Disconnect the blower motor ground straps and leads. 5. Disconnect the refrigerant lines at the rear of the blower-evaporator assembly. Cap or plug all open connections at once. EVAP & BLOWER ASM SUPPORT BLOWER M O TO R GRD WIRES BRACKET Fig. 90-Blower-Evaporator (G Overhead System) LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G EVAPORATOR CORE (Fig. 90) 1. Disconnect the battery ground cable and compres­ sor clutch connector. 2. Purge the system of refrigerant. 3. Remove the rear shroud as outlined previously. 4. Disconnect the blower motor leads and ground wire. 5. Disconnect the refrigerant lines at the rear of the blower-evaporator assembly. Cap or plug open connections at once. WARNING: Before removing the blowerevaporator unit, support the case to prevent damage to components. 6. Remove the blower-evaporator to roof panel attachm ents and lower the blower-evaporator assembly. Remove the assembly and place it on a work bench upside down. 7. Remove the lower to upper case screws and remove the lower case assembly. Remove the upper shroud and upper case from the evaporator core. 8. Remove the expansion valve inlet and outlet lines and cap or plug the open connections at once. Remove the expansion valve capillary bulbs from the evaporator outlet line and remove the valves. 9. Remove the plastic pins holding the screen to the core and remove the screen. 1A-75 7. Connect the blower lead wires and ground straps. Install the rear shroud as outlined previously. 9. Connect the battery ground cable and the compressor clutch connector. 10 . Evacuate, charge and check the system. RESISTOR See Electrical Components in the Floor Mounted System Section of this manaul (fig. 80). BLOWER SWITCH See Blower Switch in the Floor Mounted System Section of this manual (fig. 80). REAR BLOWER RELAY The rear blower relay is attached to the instrument panel reinforcement, just left of the steering column (fig. 91). Replacement 1. Disconnect battery ground cable. Disconnect relay wiring harness at the relay. 3. Remove the relay attaching screw and remove the relay. 4. To install, reverse Steps 1-3 above. Check system operation. 2. TIE RELAY See Electrical Components in the Floor Mounted System Section of this manual (fig. 80). Installation 1. Install the wire screen to the front of the new core and insert the plastic pins. 2. Install the expansion valve inlet and outlet lines using new "O " rings coated with clean refrigeration oil. Install the sensing bulbs to the evaporator outlet line. Make sure the bulbs have good contact with the line. NOTE: Add 3 oz. clean refrigeration oil when installing a new core. 3. Install the upper case and upper shroud to the core. 4. Install the lower core case and blower assemblies. 5. Install the blower-evaporator to the roof panel. 6. Connect the refrigerant lines to the blowerevaporator unit using new "O " rings coated with clean refrigeration oil. C O M P O N E N T PART REPLACEMENT DASH M O U N TED SYSTE M -M O TO R HO M E CHASSIS This system is installed on the vehicle and checked at CONDENSER assembly. The blower-evaporator is then disconnected Replacement and shipped with the chassis unit to the body supplier. For this reason, it will only be possible to give basic replacement procedures on some components. 1. Disconnect the battery ground cable. LIGHT DUTY TRUCK SERVICE MANUAL 1A-76 HEATER A N D AIR C O N D IT IO N IN G Fig. 92--Condenser (Motor Home Chassis Unit) 2. Purge the system of refrigerant. 3. Disconnect the condenser inlet and outlet lines and cap or plug all open connections at once. 4. Remove the condenser to radiator support screws and remove the condenser. 5. To install a new condenser, reverse Steps l -4 above. Add one fluid ounce of clean refrigeration oil to a new condenser. NOTE: Use new "O " rings, coated with clean refrigeration oil, when connecting all refrig­ erant lines. 6. Evacuate, charge and check the system. Fig. 93--Receiver-Dehydrator (Motor Home Chassis Unit) 6. Evacuate, charge and check the system. SIGHT GLASS REPLACEMENT Refer to "Sight Glass Replacement" in the Floor Mounted System Section of this manual. BLOWER-EVAPORATOR ASSEMBLY (Fig. 94) Removal 1. Disconnect battery ground cable. RECEIVER-DEHYDRATOR Replacement (Fig. 93) 1. Disconnect the battery ground cable. 2. Purge the system of refrigerant. 3. Disconnect the inlet and outlet lines at the receiverdehydrator and cap or plug the open lines at once. 4. Remove the receiver-dehydrator bracket attaching screws and remove the bracket and receiverdehydrator. 5. To install a new receiver-dehydrator, reverse Steps 1-4 above. Add one fluid ounce of clean refrigeration oil to a new receiver-dehydrator. NOTE: Use new "O " rings, coated with clean refrigeration oil, when connecting all refrig­ erant lines. Units) LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G 2. Purge system of refrigerant. 3. Disconnect inlet and outlet refrigerant lines from the back of unit. Cap or plug all open connections at once. 4. Disconnect drain tubes from evaporator case. 5. Disconnect electrical connector from compressor. Remove the terminal (See Figure 95) and allow connector to hang on ground wire. 6. Remove screws securing grommet retainer to dash panel. Remove wire from grommet through slit. 7. Disconnect electrical lead at connector. 8. Remove unit mounting bolts. Remove unit from vehicle, carefully pulling compressor electrical lead through dash panel. Once the unit has been removed from the vehicle, continue with component replacement as follows: BLOWER ASSEMBLY Removal (Fig. 96) 1. Remove the cover plate and separate the upper and lower case halves. Remove blower motor mounting strap screw and remove strap. 2. Remove blower assembly. Loosen the blower wheel setscrews and remove the wheels from the motor shaft. Installation 1. Install the blower wheels on the motor so that the lower blades curve toward the dash panel side of the unit when the motor is placed in the case as illustrated in Figure 96. Do not tighten setscrews at this point. 2. Place the motor in the bracket with the electrical connector side of the motor to the right side of the bracket. Attach the mounting strap. Align blower 1A-77 CORRECT BLOWER BLADE ANGLE Fig. 96--B!ower Assembly (Motor Home Chassis Unit) wheels so that they do not contact case. Tighten setscrews. 3. Assemble the case halves and attach the cover plate. 4. Reverse steps 1-8 on the "Blower-Evaporator Assembly" removal procedure. 5. Evacuate, charge and check the system. EXPANSION VALVE, EVAPORATOR AND/OR EVAPORATOR CASE Removal (Fig. 97) 1. Remove the cover plate and separate upper and lower case halves. 2. Remove inlet and outlet lines from the expansion valve. Remove sensing bulb from the evaporator outlet manifold. Remove expansion valve. Cap or plug open connections at once. TERMINAL SCREW DRIVER (NARROW BLADE) THERMOSTATIC SWITCH CAPILLARY TUBE SCREEN MESH CONNECTOR TANG GROOVE A. Insert screw driver in groove & press tang toward terminal to release. BUMPER EXPANSION VALVE B. Pry tang back out to insure locking when reinstalled into connector._____ Fig. 95-Terminal Removal Fig. 97-Expansion Valve (Motor Home Chassis Unit) LIGHT DUTY TRUCK SERVICE MANUAL 1A-78 HEATER A ND AIR C O N D IT IO N IN G AIR SENSING CAPILLARY SWITCH 2. Reverse steps 1-8 of the "Blower Evaporator Assembly" removal procedure. 3. Evacuate, charge and check the system. THERMOSTATIC AND/OR BLOWER SWITCHES Replacement BUMPER BLOWER SWITCH Fig. 98- Thermostatic and Blower Switches 3. Remove evaporator core retaining screws and remove core. 4. Remove blower motor and harness assembly from case. Installation 1. Reverse applicable steps in the removal procedure. CAUTIO N: Use new "O" rings coated with clean refrigeration oil when connecting lines. Add 3 oz. of new refrigeration oil to a new core. 1. Remove the cover plate assembly from the evaporator case. 2. Remove two screws securing either switch to the cover plate and remove appropriate switch (fig. 98). 3. Install replacement switch, reinstall cover plate and reverse steps 1-8 of the "Blower-Evaporator Assembly" removal procedure. NOTE: When installing thermostatic switch, be sure to position sensing capillary as when unit was removed. RESISTOR The blower motor resistor is located on the top of the unit. The entire unit must be removed to replace the resistor. FUSE This Unit does not incorporate an in-line fuse. The lead wire is connected to the Heater W iring Harness and operates off the 20 amp Heater Fuse. D IA G N O S IS REFRIGERANT SYSTEM The following is a description of the type of symptom each refrigerant component will evidence if a defect occurs: Compressor A compressor defect will appear in one of four ways: Noise, seizure, leakage, or low discharge pressure (fig. 99). NOTE: Resonant compressor noises are not cause for alarm; however, irregular noise or rattles may indicate broken parts or excessive clearances due to wear. To check seizure, de­ energize the magnetic clutch and check to see if drive plate can be rotated. If rotation is impossible, compressor is seized (See "False Compressor Seizure"). To check for a leak, refer to leak testing in the service manual. Low discharge pressure may be due to a faulty internal seal of the compressor, or a restriction in the compressor. Low discharge pressure may also be due to an insufficient refrigerant charge or a restriction elsewhere in the system. These possibilities should be checked prior to servicing the compressor. If the compressor is inoperative, but is not seized, check to see if current is being supplied to the magnetic clutch coil terminals. Condenser A condenser may be defective in two ways: it may leak, or it may be restricted. A condenser restriction will result in excessive compressor discharge pressure. If a partial restriction is present, sometimes ice or frost will form immediately after the restriction as the refrigerant expands after passing through the restriction. If air flow through the condenser or radiator is blocked, high discharge pressures will result. During normal condenser operation, the outlet pipe will be slightly cooler than the inlet pipe. Receiver-Dehydrator A defective receiver-dehydrator may be due to a restriction inside the body of the unit. A restriction at the inlet to the receiver-dehydrator will cause high head LIGHT DUTY TRUCK SERVICE MANUAL HEATER A N D AIR C O N D IT IO N IN G pressures. Outlet tube restrictions will be indicated by low head pressures and little or no cooling. An excessively cold receiver-dehydrator outlet may be indicative of a restriction. Expansion Valve A malfunction of the expansion valve will be caused by one of the following conditions: valve stuck open, valve stuck closed, broken power element, a restricted screen or an improperly located or installed power element bulb. The first three conditions require valve replacement. The last two may be corrected by replacing the valve inlet screen and by properly installing the power element bulb. Attachment of the expansion valve bulb to the evaporator outlet line is very critical. The bulb must be attached tightly to the line and must make good contact with the line along the entire length of the bulb. A loose bulb will result in high low side pressures and poor cooling. Indications of expansion valve trouble are provided by Performance Tests; consult Diagnostic Charts. VALVE STUCK OPEN Noisy Compressor. No Cooling - Freeze Up. VALVE STUCK CLOSED, BROKEN POWER ELEMENT OR PLUGGED SCREEN Very Low Suction Pressure. No Cooling. POORLY LOCATED POWER ELEMENT BULB Normal Pressure. Poor Cooling. Diagnosis for Defective Valve The following procedure must be followed to determine if a malfunction is due to a defective expansion valve. 1. Check to determine if the system will meet the performance test as outlined previously. If the expansion valve is defective, the low pressure readings (evaporator pressure) will be above specifications. 2. The loss of system performance is not as evident when the compressor head pressure is below 200 psi. Therefore, it may be necessary to increase the system head pressure by partially blocking the 1A-79 condenser. Disconnect the blower lead wire and repeat the "perform ance check" to determine if the evaporator pressure can be obtained. 3. The system will also indicate a low refrigerant charge by bubbles occurring in the sight glass. Evaporator When the evaporator is defective, the trouble will show up as an inadequate supply of cool air. A partially plugged core due to dirt, a cracked case, or a leaking seal will generally be the cause. Refrigerant Line Restrictions Restrictions in the refrigerant lines will be indicated as follows: 1. Suction Line - A restricted suction line will cause low suction pressure at the compressor, low discharge pressure and little or no cooling. 2. Discharge Line - A restriction in the discharge line generally will cause the pressure relief valve to open. 3. Liquid Line - A liquid line restriction will be evidenced by low discharge and suction pressure, and insufficient cooling. Sight Glass Diagnosis (G and Motor Home Chassis Units) At temperatures higher than 70 degrees F, the sight glass may indicate whether the refrigerant charge is sufficient. A shortage of liquid refrigerant is indicated after about five minutes of compressor operation by the appearance of slow-moving bubles (vapor) or a broken column of refrigerant under the glass. Continuous bubbles may appear in a properly charged system on a cool day. This is a normal situation. If the sight glass is generally clear and performance is satisfactory, occasional bubbles do not indicate refrigerant shortage. If the sight glass consistently shows foaming or a broken liquid column, it should be observed after partially blocking the air to the condenser. If under this condition the sight glass clears and the performance is otherwise satisfactory, the charge shall be considered adequate. In all instances where the indications of refrigerant shortage continues, additional refrigerant should be added in 1/4 lb. increments until the sight glass is clear. An additional charge of 1/2 lb. should be added as a reserve after the glass clears. In no case should the system be overcharged. LIGHT DUTY TRUCK SERVICE MANUAL 1A-80 HEATER COMPRESSOR DIAGNOSIS COMPRESSOR NOT EN G A G E D . Check fo r proper ground and good clean electrical contact If coil is s till inoperative, at term inals. replace compressor coil. Check fo r proper air gap. If previous step does not C orrect if necessary. correct clu tch slippage, (.0 2 2 .0 5 7 ) COMPRESSOR EN G A G E D C O N D IT IO N IN G CLUTCH SLIPPIN G . AIR PROPER V O LT A G E TO COMPRESSOR C O IL. repair compressor. BUT NOT O P E R A T IO N A L . B E L T SLIPPIN G . Check and correct belt tension. R E F R IG E R A T IO N IS D E P L E T E D . HIGH TO RQ UE CO M PRESSOR. (S E IZ E D ) CHARGE SYS T EM HAS SOME R E F R IG E R A N T . L E A K S FR E O N . COMPRESSOR THRO W S O IL. Blow out seal cavity w ith air hose and leak test. L Add one pound refrigerant. Leak test com plete Repair compressor. system before Operate and leak removing compressor. test system. Repair compressor. DOES NOT Wipe o ff o il - O.K. LIGHT DUTY TRUCK SERVICE MANUAL Fig. 99-Compressor Diagnosis AND Retrace electrical circuit back to source of power loss. (See wiring diagrams). C-K Models: Check for defective discharge Pressure Switch by jumping switch connector terminals. If compressor operates, check for low refrigerant charge. If charge is satisfactory, switch is defective-replace.________ NO V O LT A G E A T COMPRESSOR CO IL. i INSUFFICENT C O O L IN G -F O U R SEASON SY STEM (C-K M ODELS) M ove temperature lever rapidly back and forth from max heat to max. cold Listen for temperature door hitting at each end | Not Hitting I Hitting 1 2 3. 4. 5 6 Set Temperature Lever at Detent to the Right of Cold Set Selector Lever at A / C Set Blower Switch on High O pen Doors and Hood W arm Engine Run Engine at ldle( Except 06 Models) 1000 RPM ( C -K 06 Models) Adjust Door Feel For Air Flow A t Heater And A / C Outlets Some or All A ir Flow From Heater Outlet Check M ode Door O peration-Repair, ---1------- O ff All the Time A ir Flow From A / C Outlets O nly Engaged or Cycling NOTE Check Compressor Hot Lead W ire W ith Test I Check Visually For Compressor Clutch O peration ______________________ ______________________ Light or Place a Jumper W ire From The Compressor to The Positive ( +) Terminal of THIS SYSTEM DOES N O T H A V E A SIG H T GLASS. UNDER N O CIRCUMSTANCES SHOULD A SIGHT GLASS BE INSTALLED The Battery. I I_________________ Feel Liquid Line Before Expansion Tube | N ot Engaged W a rm l Cold Locate Restriction, Repair, Evacuate -----------------1------------------ Charge and Check The System I ( O K .) Lov Plugged Expansion Tube.Repair or Replace and Evacuate, Charge and Check System. Below 50 PSIG | A b o ve 50 PSIG _ ___ Lost Charge Leak Test and Repair. Evacuate, D efective Switch Charge and Check System, Jump Switch Cycles on and O ff O n Continuously ( O K.) Check For Missing Expansion Tube LIGHT | Compressor Runs M issing""}1 l r ^ DUTY In Place Replace System System Install Expansion Tube, Evacuate, Check Compressor ( O K .) Charge and Check System. Inlet Screen TRUCK Plugged i I Leak Check System, Replace Switch, Evacuate, Charge and Check System. ( O K .) I System ( O K.) Defective Thermostatic Switch I System Clean ( O K .) i System ( O K .) CONDITIONING Defective Thermostatic Switch I I Replace System ( O K .) r (O K .)Check Compressor Cycling I System Replace I I Frost I I at High Side Fitting ( At Pressure Switch) System r D efective Switch AIR System System ( O K .) and Evacuate, Charge and Check System Thermostatic Switch AND I (OK.) N o Frost Pipes Same Temperature ( Cold) or O utlet C older Than Inlet Replace Expansion Tube High To Normal and O bserve Accumulator and Evaporator Pipes For Frost. ( OK.) Discharge Pressure Switch Check Refrigerant Pressure Check Accumulator Pressure ( See Performance Data) Change Blower Speed To Low, System 1 Pipes Still Cold and W arm as A bove Outlet Temperature High See Performance Data j I Check For O p e n Circuit at the Follow ing t HEATER Outlet Temperature Satisfactory or too cold - See Performance Data O veraul Manual T Leak Check System-Repair Leak If No Leak is Found, Check Expansion Tube For Plugged Filter Evacuate and Charge System. Check Inlet & O utlet Pipe Temperatures. Install the Thermometer in A / C O utlet and Check Performance-See Performance Test and Performance Data O utlined Earler in This Section I System A p p ly External G round to Compressor, if Clutch is Still not Engaged , Replace Compresor Clutch - See the IL Inlet Pipe Colder Than Outlet Pipe Pipes same Temperature or Outlet Colder Than Inlet Engaged Check For Blown M ain Fuse Feel Evaporator Inlet and Accumulator Outlet Pipes Restriction in High Side of System. Visually Look For Frost Spot to | T i System O ver-C harged.P urge, i Evacuate, Charge and Check System, M ANUAL System System ( O.K.) ( O K .) Fig. 100--lnsufficient Cooling Diagnosis-C-K Four-Season System 1A-81 SERVICE Repair or Replace Screen, E vacuate, Charge and Check System, 1A-82 INSUFFICIENT COOLING DIA GNO SIS CHART (EXCEPT C -K FOUR-SEASON SYSTEM) NO RM AL A IR FLOW IN O OR LOW A IR FLOW CHECK BLOWER OPERATIO N )_ t NO R M A L I CHECK SIGHT GLASS ICE BLO C KIN G EVAP O R ATO R |- NO FO AM ING SYSTEM IS PR O B A B LY LOW ON R E FR IG E R A N T. CHECK FOR LEAK S, REPA IR , AN D ADD R E F R IG E R A N T. IF FO AM IN G S T IL L OCCURS, CHECK FOR RESTR IC TIO N IN R E FR IG E R A N T SYSTEM BETW EEN CONDENSER A N D SIGHT GLASS. CHECK FOR LOW EVAP O R ATO R PRESSURE 1. A LLO W SYSTEM TO W ARM UP. 2. STOP A N D R ESTART ENGINE. 3. CHECK EVAP O R ATO R PRESSURE IM M E D IA T E L Y A FTE R RESTART AN D PULL DOWN OF EVAP O R ATO R PRESSURE. 1. SYSTEM MAY BE EITH E R F U L L Y CHARG ED OR EM PTY. FEEL HIGH AND LOW PRESSURE PIPES A T COMPRESSOR. HIGH PRESSURE PIPE SHO U LD BE W ARM . LOW PRESSURE PIPES SHOULD BE COLD. 2. IF PIPES ARE NOT IN D IC A T IN G PROPER TEM PERATURES, RECHARGE SYSTEM AS RECO M M ENDED. IF N O ZZLE A IR TEMPERATURE IS S T IL L HIG H . CHECK EVAP O RATO R PRESSURE. N O R M A L EVAPO RATO R PRESSURE LOW EVAP O R ATO R * PRESSURE X LOW EVAP O RATO R ‘ PRESSURE 'C H E C K EVAPORATOR PRESSURE I Check fo r m alfunctioning expansion valve-See Component Diagnosis. HIGH EVAP O RATO R * PRESSURE CHECK EVAP O R ATO R O U TLE T LINE EVAP O RATO R O U TLET L IN E W ARM SYSTEM HAS EXCESS M O ISTURE. REPLACE RECEIVER D E H Y D R A TO R A N D E V AC U ATE TH O R O U G H LY . RECHARGE SYSTEM. I CHECK COMPRESSOR DISCH ARG E PRESSURE NORM AL EVAP O RATO R PRESSURE | Check Compressor Discharge Pressure. 1. CHECK FOR L IQ U ID LIN E RESTRICTION (FROST SPOT ON LIN E ). IF NOT, 2. CHECK FOR PLUGGED IN L E T SCREEN IN EXPANSION V A L V E . IF NOT, 3. CHECK FOR D E FE C TIVE EXPANSION V A L V E BY R EM O V IN G V A L V E AN D BLOW ING THRO UGH V A L V E . IF U N A B LE TO BLO W THRO UGH V A LV E , BULB IS D ISC H ARG ED. REPLACE EXPANSION VALV E. LOW DISCHARGE * PRESSURE I LIGHT Check fo r m alfunctioning expansion valve-See Component Diagnosis. HIG H DISCH ARGE PRESSURE LOW DISCHARGE PRESSURE X 1. Check engine cooling system, fan clutch and check fo r restricted air flo w thru condenser. 2. Check expansion valve bulb contact. Correct if necessary. 3. Check fo r refrigerant restriction in condenser. Return bends at equal elevation should be approxim ately same temperature. If temperature of bends is appreciably diffe re n t, the cooler bend indicates a restricted circuit, replace con­ denser if restriction is found, If condenser is OK, check fo r air in system. To check observe outle t air tem perature and compressor discharge pressure w hile slowly discharging system at receiver inlet connection. Check for restriction in liquid line, p artia lly plugged inlet screen at expansion valve, or defective expansion valve, replace valve if defective. X N O R M AL DISCH ARGE PRESSURE R efrigeration System is ok 1. Check fo r proper fu n c tio n of heater TEM P ER ATU R E door. 2. Check fo r proper sealing of evaporator case. 3. Check fo r proper operation and seal around tem perature door. 4. Non-Foam ing sight glass does not always indicate a fu lly charged system. Add 1/2 lb. refrigerant and observe performance. 5. Check fo r excess oil in system. A sym ptom of excess o il is a slipping clutch or belt or broken belt. To remove excess oil in system consult service manual. DUTY TRUCK ’ REFER TO PERFORM ANCE C H A R T FOR CORRECT PRESSURES SERVICE M ANUAL Fig. 101-Insufficient Cooling Diagnosis-Except C-K Four-Season System C O N D IT IO N IN G Check fo r loose or disconnected air distrib u tio n ducts, restricted or leaking air ducts, partially closed air o u t­ let valve or clogged evaporator core, if above check is OK, check for ice blocking evaporator. AIR CHECK FOR BLOWN FUSE, D E FE C TIVE BLOW ER SWITCH, BROKEN W IRE, LOOSE CONNECTIONS. LOOSE BLOWER MOTOR GROUND W IRE OR IN O P E R A T IV E BLOWER MOTOR. BLOWER O PE R ATIO N | AND a m in g fo r condenser air blockage due to foreign material. fo r proper air ducting hose connections. heater temperature door adjustm ent, adjust if incorrect. evaporator sealing fo r air leak, repair if leaking. pressure gages and therm om eter and make performance test. BLOWER NOT OPERATING HIGH O U TLET AIR TEMPERATURE CHECK FOR A IR LEAK S TH RO UG H DASH PANEL. DOORS, WINDOWS, OR FROM HEATER . Check Check Check Check Install CHECK A IR FLOW | CHECK DISCH ARGE A IR TEM P ERATURE (SEE PERFORMANCE D A T A ) | D ISCH ARG E TE M P ER ATU R E A T O U T L E T COLD 5. 6. 7. 8. 9. HEATER The fo llo w in g procedures should be applied before perform ance testing an A/C System. 1. Check fo r proper belt installation and tension w ith J-23600. 2. Check fo r proper clutch coil terminal connector installation. 3. Check fo r clutch air Gap (.022 - .057). 4. Check fo r broken, burst, or cut hoses. Also check fo r loose fittin g s on all components. ELEC TRIC A L SYSTEM D I A G N O S T IC CHART BLOW ER M OTOR IN O P E R A T IV E (C E R T A IN SPEEDS-EXCEPT HIGH OIM C-K FO U R -S EAS O N ) B LO W E R M O T O R IN O P E R A T IV E (A N Y S P E E D ) Check fo r proper fuse |F U S E | BLO W N ! fuse o k ! Disconnect resistor connectors, connect one lead of a self powered test lig h t to any one term inal and use the other lead to probe each o f the other term inals. T h e fo llo w in g tests sh o u ld be m ade W ith ign. switch in " R u n " position and heater or A /C on, locate short in one of the fo llo w in g wires: (see note) w it h th e ig n itio n s w itc h in ''R u n '' p o s itio n , h ea ter o r A /C on and b lo w e r s w itc h on h ig h . C-K Four-Season System C heck b lo w e r m o to r g ro u n d 1. From fuse panel to master switch on control. 2. From master switch to compressor clutch. 3. Master sw itch to blower switch. 4. From blow er speed switch to resistor. 5. From resistor to blow er m otor. |P O O R OR NO G R 0 U N D | I Repair g ro u n d | GROUND T E S T L IG H T OK DOES NO T T E S T L IG H T L IG H T O N A L L T E R M IN A L S ............. C heck m o to r c o n n e c to r w ith I 1 .................. R eplace re sisto r 12 v o lt te st lig h t. W ith ig n itio n switch in " R u n " p osition and heater or A /C on, use 12 v o lt test lamp to check fo r voltage at resistor connector w ith b low er speed switch in each position. -L L A M P D O E S N O T L IG H T | LA M P L IG H T S ] T Except C-K Four-Season C heck w ire c o n n e c to r on Replace m o to r 1. From fuse panel to blower switch. 2. From blow er switch to resistor. 3. From resistor to blow er m otor. L A M P L IG H T S |L A M P L IG H T S ! | L A M P D O E S N O T L IG H t | IN A L L R epair o pe n in m o to r to b lo w e r re sisto r to b lo w e r re la y ). re la y w it h 12 v o lt te s t lig h t. relay. | DOES N O T L IG H T ] I lam p l ig h t s ! la m p u g h t s ] Replace b lo w e r re la y. DUTY speed s w itc h . TRUCK o f f LA M P DOES N O T L IG H T ON A L L W IRES Replace b lo w e r speed R e p a ir o p e n in s w itc h . a ffe c te d w ire . | M ANUAL 1A-83 SERVICE T b lo w e r re la y. CONDITIONING LIGHT R eplace re sisto r re sisto r to b lo w e r la m p I R e pa ir o pe n in w ire fro m re sisto r to AIR _L | [ L A M P D O E S N O T L IG H T ! AND L A M P L IG H T S C heck F E E D w ire fro m P O S IT IO N S Turn ig n itio n key o ff and p u t Heater or A /C C ontrol in o ff position. W ith blow er resistor w ire connector disconnected, connect a ju m pe r lead fro m battery positive term inal to the w ire term in al in connector. Use 12 v o lt test lig h t to check fo r voltage at w ire at blow er speed switch connector. Repeat same test on the other wires. LA M P LIG H TS ON A L L W IRES w ire te rm in a ls a t re s is to r. L A M P O FF IN A L L HEATER w ire fro m b lo w e r fro m C heck w ire c o n n e c to r o n b lo w e r Replace re la y R eplace b lo w e r L A M P D O E S N O T L IG H T C o n n e c t 12 v o lt te s t lig h t a t w ire Use 12 v o lt test lig h t a nd ch eck speed s w itc h . P O S IT IO N S te rm in a l on b lo w e r re la y (w ire (L A M P T 1 b lo w e r re la y w it h 12 v o lt te s t lig h t. NOTE: S h ort c irc u it may be in te r­ m itte n t. If tester does not indicate a short c irc u it, move heater harness around as much as possible to re­ create short c irc u it. W atch and listen fo r arcing. IL A M P O N | L IG H T S ON A L L T E R M IN A L S R e pa ir o pen in w ire fro m b lo w e r speed sw itch . Fig. 102-Electrical System Diagnosis Chart 1A-84 BLOW ER M O TO R IN O P E R A T IV E A T H IG H SPEED O N LY (C-K FO U R -SEASO N SYSTEM ) HEATER ELECTRICAL SYSTEM D IA G N O S T IC CHART COM PRESSOR C LU TC H IN O P E R A T IV E 1 ... 1 Check fuse FUSE B LO W N AND X Check in-line fuse [ FUSE O K | FUSE BLO W N |F U S E O K | C onnect Tester. Use to check w ire fro m ju n c tio n to b lo w e r relay to locate sh o rt. Repair sh o rt c irc u it as .re q u ire d .* CL ICK H E A R D I I ' I NO C LIC K H E A R D ! 1 _ Check w ire te rm in a l on relay th a t goes to ju n c tio n blo ck w ith 12 v o lt test lam p. Check relay c o il c o n n e cto r w ith 12 v o lt te s t lig h t. X LA M P L IG H T S Replace b lo w e r relay. |L A M P DOES N O T L IG H T | ___ _ 1 Repair open in w ire fro m ju n c tio n b lo c k to relay. j LA M P 1 LIG H T S | 1 Check ground on relay | lA M P DOES N O T L IG H T | f—* Check w ire term in a l on b lo w e r speed sw itch c o n n e cto r w ith 12 v o lt test lig h t. r |G R O U N D O K | | b a d g r o u n d | |L A M P L IG H T S | 1 Replace relay R epair ground Repair open in w ire fro m blow e r speed sw itch to relay. i L A M P DOES N O T L IG H T W ith ig n itio n sw itch in " R u n ” p o s itio n , and A /C " O n " , connect tester and locate s h o rt in one o f the fo llo w in g w ires or co m p o ­ nents. Replace a shorted w ire o r defe ctive sw itch . C-K M O D E L S YSTEM S 1. W ire fro m fuse panel to m aster sw itch (on c o n tro l). 2. Master sw itch . 3. W ire fro m m aster sw itch to th e rm o sta tic sw itch . 4. T h e rm o sta tic sw itch . 5. W ire fro m th e rm o s ta tic sw itch to discharge pressure sw itch . 6. Discharge pressure sw itch . 7. W ire fro m discharge pressure sw itch to com pressor clu tc h solenoid. G M O D E L SYSTEM S 1. W ire fro m fuse panel to blow e r sw itch . 2. B low er sw itch . 3. W ire fro m b lo w e r sw itch to th e rm o s ta tic sw itch . 4. T h e rm o sta tic sw itc h . 5. W ire fro m th e rm o sta tic sw itch to the rm a l fuse. 6. Therm al fuse. 7. W ire fro m the rm a l fuse to com pressor c lu tc h solen oid. M O TO R H O M E U N IT 1. W ire fro m fuse panel to blow e r sw itch . 2. B low e r sw itch . 3. W ire fro m b lo w e r sw itch to th e rm o s ta tic sw itch . 4. T h e rm o sta tic sw itch . 5. W ire fro m th e rm o s ta tic sw itch to com pressor clu tc h solenoid. 1 Replace B lo w e r speed sw itch . LIGHT DUTY TRUCK * S h o rt c irc u it m ay be in te rm itte n t. If tester does n o t indicate a s h o rt c irc u it, m ove harness arou nd as m uch as possible to re-create sh o rt c irc u it. W atch and listen fo r arcing. SERVICE **R e fe r to W iring Diagrams w hile performing the follow ing checks. M ANUAL Fig. 103-Electrical System Diagnosis Chart |P O O R OR NO G R O U N D l Repair ground X NO C L IC K H E A R D ( G R O U N D 0~iT| Disconnect conn ector on com pressor clu tc h solenoid and a p p ly 12 vo lts to solenoid. C LIC K H E A R D Replace solenoid W ith ig n itio n sw itch in " R u n " p o s itio n and A /C " O n " , check fo r defective sw itch at the fo llo w in g locations. Using an exte rnal ju m p e r w ire , d isco nnect the electrical lead at the sw itch and ju m p the sw itch te rm in a ls (see "W irin g D iagra m s"). C-K M O D E L SYS T E M 1. Master S w itch . 2. T h e rm o sta tic S w itch . 3. Discharge Pressure S w itch . G M O D E L SYS T E M 1. B low e r sw itch . 2. T h e rm o sta tic S w itch . 3. T herm al fuse (See " L o w R e frig e ra n t Charge P ro te ctio n System D iagn osis"). M O T O R H O M E U N IT 1. B low e r sw itch . 2. T h e rm o sta tic sw itch . N O T E : If th e com pressor is still in o p e ra tive a fte r the above checks, check fo r pow er feed at each co m p o n e n t since tw o or m ore co m p o n e n ts are defe ctive or there is an open in the w ires co nn ecting the com p onents. C O N D IT IO N IN G W ith ig n itio n sw itch in the " R u n " p o sitio n and the heater o r A /C on, m ove the blow e r speed sw itch to H i. Relay " c lic k " should be heard when sw itch is m oved. AIR Check C om pressor S ole noid G round HEATER A ND AIR C O N D IT IO N IN G 1A-85 LOW R EFR IG ER A N T CHARGE PROTECTION SYSTEM DIAGNOSIS CHECK LIST SHOWING POSSIBLE CAUSES AND SUGGESTED CORRECTIONS FOR BLOWN THERMAL FUSE* CAUSE CORRECTION Low refrigerant charge or totally discharged system . Inspect for leaks, repair, evacuate, recharge system and th en replace therm al fuse. Inoperative expansion valve. (See Service Diagnosis chart.) Replace expansion valve according to norm al procedures, recharge system and then replace the therm al fuse. U nderhood tem peratures exceeded 26 0°F. Install new therm al fuse. Therm al fuse blow n during charging. Jum p connector plug “ B” & “ C ” term inals during charging and replace therm al fuse. F aulty Superheat Switch. Replace superheat sw itch according to proced ure, recharge system and replace therm al fuse. G rounded Superheat Switch. Repair ground condition and replace therm al fuse. New Therm al Fuse Blows Im m ediately. Check for and correct as follows: A. Pinched, broken or bare wires. B. Boot off of connector at switch. C. Connector on thermal limiter reversed. D. Connector shorted to switch body. E. Refrigerant pipes cutting through boot at switch. F. Connector off center on switch pin. *Due to Superheat Sw itch Sensing A bnorm al System C ondition and Protecting System . LIGHT DUTY TRUCK SERVICE MANUAL 1A-86 HEATER AND AIR C O N D IT IO N IN G LOW R EFR IG ER A N T CHARGE PROTECTION SYSTEM CHECK CHECK FOR Supply voltage at clutch coil term inals. E L E C T R IC A L (Com pressor Inoperative, Engine Running, A/C Selector Switch “ O N ” , Therm al Fuse D isconnected). Blown fuse at m ain circuit fuse panel. Voltage therm al fuse term inal “ B ” to ground. (If no voltage check for broken lead, loose or poor connections or open am bient switch.) Voltage, therm al fuse term inal “C ” to ground. (If no voltage, therm al fuse is blow n. If voltage present, check therm al fuse to clutch coil lead and connections.) THERM AL FUSE (Com pressor Inoperative, Engine Running. A/C Selector Switch “ O N ”, Therm al Fuse D isconnected). SUPERH EAT SWITCH (Engine “ O F F ” , l e a d disconnected from Superheat Sw itch term inal). C ontinuity betw een term inals “ B” and “ C” . (If no continuity, fuse link is blow n, repair system and replace therm al fuse.) Resistance, term inals “ S” to “ C ” to be 8.4 to 10.4 ohm . (If no t w ithin lim its, replace therm al fuse.) C ontinuity betw een sw itch housing and ground. (If no t grounded, check continuity, sw itch housing to retainer ring and retainer ring to rear head.) C ontinuity betw een sw itch term inal and sw itch housing. (If no continuity, contacts are open. If continuity exists, contacts are closed.) Install suction gauge and determine the suction pressure, determine the approxim ate rear head tem perature and com pare conditions noted to calibration chart. If contacts are n o t open or closed according to tem perature-pressure relations show n, discharge system and rem ove switch for bench check. SU PERHEAT SWITCH Closed contacts - (Housing to term inal contacts should be open at atm ospheric pressure and tem peratures below 1 0 0 °F.) (Switch Off Com pressor) A lternate Closed contacts (w ith sw itch in a h o t bath 15 0°F . or above). Closed contacts (w ith sensing tube held in m atch flam e for 15-20 seconds). Note: If switch contacts are not “OPEN” or “CLOSED” per these checks, the switch is defective and must be replaced. LIGHT DUTY TRUCK SERVICE MANUAL HEATER AND AIR C O N D IT IO N IN G selector lever positions, a leak is indicated in these circuits. VACUUM SYSTEM DIAGNOSIS (C-K FOUR-SEASON SYSTEM) Start the engine and allow it to idle - move the selector lever to each position and refer to the vacuum diagrams and operational charts for proper airflow, air door functioning and vacuum circuits. If airflow is not out of the proper outlets at each selector lever position, then proceed as follows: 1. Check for good hose connections-at the vacuum actuators, control head valve, reservoir, tees, etc. 2. Check the vacuum source circuit as follows: Install vacuum tee and gauge (with restrictor) at the vacuum tank outlet (see Vacuum Daigram). Idle the engine and read the vacuum (a normal vacuum is equivalent to manifold vacuum) at all selector lever positions. a. Vacuum Less Than Normal At All PositionsRemove the tee and connect the vacuum gauge line directly to the tank - read the vacuum. If still low, then the problem lies in the feed circuit, the feed circuit to the tank or in the tank itself. If vacuum is now normal, then the problem lies downstream. b. Vacuum Less Than Normal at Some PositionsIf vacuum was low at one or several of the 1A-87 c. 3. 4. Vacuum Normal at All Positions- If vacuum was normal and even at all positions, then the malfunction is probably caused by improperly connected or plugged lines or a defective vacuum valve or valves. Specific Vacuum Circuit Check Place the selector lever in the malfunctioning position and check for vacuum at the pertinent vacuum actuators. If vacuum exists at the actuator but the door does not move, then the actuator is defective or the door is mechanically bound. If low or no vacuum exists at the actuator, then the next step is to determine whether the cause is the vacuum harness or the vacuum valve. Check the vacuum harness first. Vacuum Harness Circuit Check a. Disconnect the vacuum harness at the control head. b. The black line (# 1 ) should show engine vacuum - if not, trace back through connector to vacuum tank. c. To check any individual circuit place the selector lever at the involved circuit position and check for vacuum presence. LIGHT DUTY TRUCK SERVICE MANUAL 1A-88 HEATER BLOWER MOTOR •BLK- THERMOSTATIC SWITCH AND DISCHARGE PRESSURE SWITCH AIR LIGHT DUTY TRUCK SERVICE M ANUAL Fig. 104-Four-Season System Wiring Diagram (C-K Models) POS CIRCUIT OFF BATT ONLY MED 1 BATT-M1 -RES MED 2 BATT-M2-RES HIGH BATT BLOWER C O N D IT IO N IN G O HEATER AND AIR DUTY TRUCK CONDITIONING LIGHT M ANUAL 1A-89 SERVICE 1A-90 HEATER AND IGN UNFUSED 10 ORN — 4 2 0 ~ A M P [|~I» INLINE FUSE v s 16 YEL1 ■16 ORN- /l 1 CN . j I. RESISTOR FUSE PANEL i4 i I 52 I 5 0 I 51 72 0 52 JHIS BAT _ !| POS CIRCUIT OFF B A H O NLY LO BATT-LO MED BATT-MED HI BATT-HI 10 PPL' LIGHT BLOWER SWITCH DUTY TRUCK SERVICE M ANUAL Fig. 106~0verhead System Wiring Diagram (C-K Models) BLOWER MOTOR C O N D IT IO N IN G Q AIR D raj GROUND -16 BRN 16 BRN — 4~50~ COMPRESSOR I C V '- , - I.P. WIRING | | l 5 0 l 59 SUPER HEAT SWITCH JL HEATER CONTROL SWITCH CONNECTOR x CO O ^=>— J I Q z' O o o J 18 BLK — r-l 3 ' 59 | 59 12021 6 10 ORN-BLK 31 — w 18 ORN ■p=t I •lh 01 J 16 YEL-BLK BLOWER RELAY I s ] 60 H POS 10 ORN-BLK1 16 GRN DK CIRCUIT OFF B A H . O NLY LO BATT. LO B A H . LO, MED HI B A H . L, M, HI DUTY TRUCK CONDITIO NING LIGHT JUNCTION BLOCK 16 YEL ■16 GRN DK DASH M ANUAL 1A-91 SERVICE TEMPERATURE CONTROL SWITCH (THERMOSTATIC SWITCH) Fig. 107 -Floor M ounted System W irin g Diagram (G M odels) AIR MED AND * 10 BLK-ORN HEATER THERMAL FUSE CIRCUIT BREAKER «=<§) 1A-92 HEATER BLOWER RELAY (REAR) AND AIR C O N D IT IO N IN G GRD LIGHT DUTY TRUCK TIE RELAY (FRONT TO SERVICE REAR) BLOWER SWITCH (FRONT) POS CIRCUIT OFF B A H . O NLY LO B A H . LO MED. BAH HI B A H . L, M, HI LO, MED BLOWER SWITCH (REAR) M ANUAL Fig. I08-Floor 0verhead System Wiring Diagram (G Models) BLOWER MOTOR (REAR) ■ fl | TO FUSE PANEL GROUND COMPRESSOR RESISTOR N TO 1 A 4 HIGH N TO 1, 3 4 4 DUTY TRUCK CONDITIONING N TO I & 2 MED AIR N TO NONE LOW AND LIGHT THERMOSTATIC SWITCH BLOWER SWITCH CONNECTION OFF HEATER BLOWER SWITCH SET AT 1A-93 SERVICE M ANUAL Fig. 109-Motor Home Chassis Wiring Diagram 1 A-9 4 HEATER A N D AIR C O N D IT IO N IN G SPECIAL TOOLS 1. 2. 2A. 3. 4. 5. 6. 7. 8. 9. 10. 11. Charging Station Oil Inducer Super Heat Switch Remover J-5453 Goggles 90 Degree Gauge Line J-9459 Adapter Gauge Line Adapter J-5420 Leak Detector J-6084 Puller J-8433 Puller Pilot J-9395 J-23595 Refrigerant Can Valve (Side-Tap) Refrigerant Can Valve J-6271 (Top-Tap) Pocket Thermometers (2) J-5421 J-8393 J-24095 J-9393 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. J-5403 J-643 5 J-9396 No. 21 Snap Ring Pliers No. 26 Snap Ring Pliers Compressor Holding Fixture J-9397 Compressing Fixture J-9403 Clutch Hub Holding Tool J 9399 9/16" Thin Wall Socket J-9401 Hub and Drive Plate Assembly Remover J 9480 Hub and Drive Plate Assembly Installer J 9392 Seal Remover J-23128 Seal Seat Remover J 9398 Pulley Bearing Remover 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. J-9481 Pulley and Bearing Installer J-8092 Handle J-21352 Internal Assembly Support Block J-5139 Oil Pickup Tube Remover J-9432 Needle Bearing Installer J-9553 Seal Seat "O ” Ring Remover J-21508 Seal Seat "O ” Ring Installer J-22974 Shaft Seal Protector J 9527 Pressure Test Connector J-9402 Parts Tray Fig. 110- Air Conditioning Special Tools LIGHT DUTY TRUCK SERVICE MANUAL SECTION IB BODY The following caution applies to one or more steps in the assembly procedure of components in this portion of the manual as indicated at appropriate locations by the terminology "See Caution on page 1 of this Section". CAUTIO N : THIS FASTENER IS AN IM PORTANT ATTACHING PART IN THAT IT COULD AFFECT THE PERFORMANCE OF VITAL COMPONENTS AND SYSTEM S, AND /O R COULD RESU LT IN MAJOR REPAIR EXPENSE. IT M U ST BE REPLACED WITH ONE OF THE SAME PART NUMBER OR WITH AN EQUIVALENT PART IF REPLA CEMENT BECOMES NECESSAR Y. DO NOT USE A REPLACEMENT PART OF LESSER QUALITY OR SUBSTITUTE DESIGN. TORQUE VALUES M U ST BE USED A S SPECIFIED DURING REASSEM BLY TO ASSU RE PROPER RETENTION OF THIS PART. CONTENTS OF THIS SECTION General Description........................................................................ C-K Models....................................................................................... G Models........................................................................................... Special Tools..................................................................................... IB-1 IB-4 IB-30 IB-48 GENERAL DESCRIPTION On the following pages, service procedures will be given for components on all 10-20-30 series trucks in C, K and G models. Reference will be made, both in text and illustrations, to vehicle model lines and to individual model numbers within these model lines. As an aid to identification of specific models, the following general descriptions are given. Chassis/Cabs All chassis/cabs use "03" as the model identification. See figure 1. Two-wheel drive units come in C-10, C-20 and C-30 series. Four-wheel drive units may be either K-10 or K-20. Optional pickup boxes are available. Crew Cab/Chassis Model number "63" designates the crew cab/chassis models. See figure 2. Optional pickup boxes are available. Fig. 1—Typical Chassis/Cab LIGHT DUTY TRUCK SERVICE MANUAL 1 B-2 BODY Fig. 3—Typical Coach Coach The four-door coach model number is "06". See figure 3. Base models have rear cargo doors. An optional endgate with moveable window is available. Utility Utility models are designated with the number "14". See figure 4. An optional removable roof is also available. Vans G-Series Vans are available in two model number designations. See figures 5 and 6. Vans without body windows use number "05"; vans with body windows are "06" models. Fig. 4—Typical Utility Vehicle LIGHT DUTY TRUCK SERVICE MANUAL BODY 1 B-3 Fig. 6—Typical "0 6 " Van LIGHT DUTY TRUCK SERVICE MANUAL I B 4 BODY C-K MODELS INDEX Front End Windshield W ipers...................................................... IB-4 Glove Box....................................................................... IB-5 Rear View Mirrors...................................................... IB-5 Body Glass Windshield Glass......................................................... IB-6 Stationary Body G lass............................................... IB-8 Side Doors Adjustments.................................................................... Front Side D oor.......................................................... Replacement............................................................... H inges......................................................................... Ventilator.................................................................... Window and Regulator........................................ Locks, Handles, Rods............................................. W eatherstrip............................................................. Rear Side Doors.......................................................... IB-9 IB-10 IB-10 IB-10 IB-10 IB-11 IB-12 IB-14 IB-14 Replacement............................................................... H inges.......................................................................... Stationary G lass....................................................... Window and Regulator......................................... Locks, Handles, Rods............................................. W eatherstrip.............................................................. IB-14 IB-14 IB-14 IB-14 IB-15 IB-16 Rear Doors Adjustments.................................................................... IB-16 Locks, Handles, Rods................................................. IB-17 Hinges................................................................................ ib -18 Gates Endgates.............................................................................IB-19 Tailgates.............................................................................IB-23 Removable Top (U tility ) ................................................ ..IB-24 S eats ..................................................................................... ..IB-25 Body M ou n tin g ................................................................. ..IB-26 FRONT END WINDSHIELD WIPERS Windshield wiper units on all models are of the twospeed electric type. A single wiper motor unit, mounted to the left side of the dash panel inside the engine compartment, powers both wiper blades. The wiper blade operating link rods and pivot mountings on these models are located in the outside air inlet plenum chamber. Arm Adjustment To adjust sweep of blades, turn on wipers and note sweep of arms. If necessary, remove one or both arms as follows: Pull outer end of arm away from glass which will trip lock spring at base of arm and release spring from undercut of pivot shaft. While holding arm in this position, pull outward on cap section at base of arm to remove arm. Arm can be reinstalled in any one of several positions due to serrations on pivot shaft and in arm cap. See figure 7. Installation 1. Place wiper linkage and transmission into position. Secure assembly with two screws at each transmission. 2. Attach end of cross rod to drive arm of motor assembly. Secure rod. 3. Before installing wiper arms, operate wiper motor momentarily which should rotate pivot shafts to park position. Install arms and shafts. Wiper Arm Pivot Shafts and Linkage Removal 1. Remove windshield wiper arms from pivot shafts. Procedure for removing arms is explained previ­ ously under "Arm Adjustment". 2. Remove two nut and lock washer assemblies from the connector link to motor drive arm via the plenum access hole. 3. Remove two screws from each transmission pivot shaft assembly to windshield frame. Remove wiper linkage and transmission from plenum. LIGHT DUTY TRUCK SERVICE MANUAL BODY Fig. 8 —Glove Box INSTRUMENT PANEL COMPARTMENT AND LOCK Replacement Removal of the entire assembly including door may be accomplished by removing four screws which attach hinge just below box. See figure 8. The outer door panel may be removed, leaving the compartment intact, by removal of four screws. Access to the door stop bumper is gained by reaching into compartment opening with door partially open. Fig. 9—Rear View Mirror—Base IB - 5 Fig. 10—Rear View Mirror—Below Eyeline Adjustment Engagement of lock in striker may be adjusted by loosening striker retaining screws and moving the striker to desired position. OUTSIDE REAR VIEW MIRRORS Rear view mirror installations are shown in figures 9, 10 and 11. Occasional tightening of mounting and assembly bolts and screws will sharply decrease occurrence of failure due to door slamming or road shock. Fig, 11—Rear View Mirror—West Coast 1 B-6 BODY INSIDE REAR VIEW MIRROR—FIG. 12 Replacement 1. Remove screw retaining mirror to its glass-mounted bracket and remove mirror. 2. Install mirror into its mounting bracket. Torque screw to specifications. NOTE: Camper mirror installation is similar to the below eyeline mirror installation. Fig. 12—Inside Rear View Mirror BODY GLASS WARNING: dling glass. Always wear gloves when han­ WINDSHIELD GLASS The windshield is a one-piece type and is retained in the windshield opening by a moulded rubber weatherstrip. See figure 13. When replacing a cracked windshield glass, it is very important that the cause of the glass breakage be determined and the condition corrected before a new glass is installed. Otherwise, it is highly possible that a small obstruction or high spot somewhere around the windshield opening will continue to crack or break the newly installed windshield especially when the strain on the glass caused by this obstruction is increased by such conditions as wind pressures, extremes of temperature, motion of the vehicle, etc. NOTE: The procedure for removal of the windshield applies to other stationary glass applications, such as in figures 20 and 21. Removal VIEW A Fig. 13—Typical Windshield 1. Before removing the windshield, mark the location of the break on the windshield rubber channel and the body. Protect the paint finish inside of the cab. Mask around the windshield opening and outside, lay a suitable covering across the hood and fenders. NOTE: The windshield glass rubber weatherstrip is one piece. The glass is held in a channel within the weatherstrip. 2. On vehicles without reveal moldings, "unzip" the locking strip shown in figure 18. 3. On vehicles with reveal moldings, remove reveal molding with tools shown in figure 19. 4. To free windshield rubber channel of weatherstrip loosen the lip of the windshield weatherstrip from the pinchweld flange along the top and at the sides by applying firm, controlled pressure to the edge of the glass. At the same time assist the lip of the rubber weatherstrip channel over the pinchweld flange with a flat bladed tool. See figures 14 and 15. LIGHT DUTY TRUCK SERVICE MANUAL BODY Fig. 14—Applying Pressure to Windshield IB - 7 Fig. 15—Assisting Weatherstrip over Flange 5. With the aid of an assistant outside the cab, remove the windshield from the opening. See figure 16. Checking Windshield Opening Due to the expanse and contour of the windshield it is imperative in the event of a stress crack that the windshield opening be thoroughly checked before installing a replacement windshield. The replacement glass is used as a template. 1. Check for the following conditions at the previously marked point of fracture. a. Chipped edges on glass. b. Irregularities in body opening. c. Irregularities in rubber channel weatherstrip. 2. Check flange area for solder, weld high spots, or hardened spot-weld sealer. Remove all high spots. 3. Check windshield glass to opening, by supporting glass with six spacers contained in packet J-22577. See figure 17. CAU TIO N : Do not strike glass against body metal. Chipped edges on the glass can lead to future breaks. 4. With the windshield supported and centered in its opening, check the relationship of the glass to the body opening flange around the entire perimeter of the glass. 5. Check the relationship of glass to opening as follows: a. Inside edge of glass to body flange. b. Outer edge of glass to parallel body metal. 6. Mark areas of body metal or flange to be reformed remove glass and correct as necessary. 7. Recheck windshield in its opening and if satisfac­ tory proceed as follows. Fjg 16_ Rem0ving Windshield from Opening Fig. 17—Checking Windshield Opening LIGHT DUTY TRUCK SERVICE MANUAL 1 B-8 BODY Installation 1. Place a protective covering over front fenders and hood, then apply soapy water to all grooves of the weatherstrip. 2. Install weatherstrip centrally to the body opening, with the pinchweld flange in the inner weatherstrip groove. See figure 18. NOTE: Because of the configuration of the weatherstrip and of the importance of centrally locating the weatherstrip in the body opening, it is not recommended to use the "cord-type" installation technique. 3. Position the lower edge of the windshield glass into the outer weatherstrip groove. Gently push the glass "into" the weatherstrip, assisting rubber over edge of glass. 4. When glass is in position, lock the weatherstrip to the glass as follows. a. Base W eatherstrip—Bend the "locking strip" over and use a thin bladed tool to lock weatherstrip tightly against windshield. See figure 18 for detail. b. Optional W eatherstrip—Use J-2189-24 and J-2189-23 in Handle J-2189 to install flexible reveal molding into locking slot of weatherstrip, as shown in figure 19. This will expand the weatherstrip to a tight fit against the windshield. Install reveal molding so that joint is at center of lower edge of windshield. Cover the joint with the molding cap. STATIONARY BODY GLASS Replacement The method used to remove the windshield glass may be applied to other stationary glass, such as shown in figures 20 and 21. Remember to check for cause of breakage, and to always wear gloves when handling glass. Installation procedures are similar to G-Van windshield. Refer to figures 9G and 10G, later in this section. Fig. 19—Installing Reveal Molding LIGHT DUTY TRUCK SERVICE MANUAL BODY BODY SI DOOR ADJUSTMENTS Doors can be adjusted for alignment of clearance in the cab door opening, and for proper latching. Door alignment adjustments are made at the striker bolt, and at door hinges. The door, when properly located in door opening, will have equal clearance around its perimeter. The door should be adjusted in the opening so the edge of the door across the top and also at the lock side is parallel with the body opening as nearly as possible. 1 B-9 DOORS bolt, adjust to desired height, and tighten bolt securely. NOTE: This adjustment is im portant to Hinge Adjustment Door hinge bolt holes are oversized to make adjustment possible. Alignment adjustments can be made by loosening the proper hinge bolts, aligning door to proper position, and tightening bolts securely. See figure 22, for typical adjustments. Striker Bolt Adjustment W ith the use of J-23457, shown in figure 23, the striker bolt can be adjusted in any of three ways. See figure 24. 1. Up and down—To adjust striker up or down, loosen LIGHT DUTY TRUCK SERVICE MANUAL I B - 1 0 BODY assure that the right proportion of door’s weight will rest on striker bolt when door is closed. If bolt is positioned too high on pillar, rapid wear will occur to the lock cam; if too low, an extra load will be placed on door hinges as well as pull door downward and out of alignment. 2. In and Out—To adjust striker in and out, loosen bolt, adjust horizontally to desired position and tighten bolt securely. 3. Forward and Rearward—To make this adjustment, loosen striker bolt, shim to desired position, and tighten bolt securely. FRONT DOOR ASSEMBLY DOOR HINGE The door check is part of the front door upper hinge. The front door torque rod check holds the door in either of two positions between full open and closed. The front door check-hinge assembly is replaced as a complete unit as follows. See figure 22. Removal 1. Loosen front fender rear bolts. 2. With special Tool J-22585 remove 3 bolts securing front door upper hinge to cowl pillar. a. Remove the door to upper hinge retaining bolts. b. With aid of an assistant to support weight of door, remove the door to lower hinge retaining bolts and remove door. Replacement Remove the door assembly from the body by removing the hinges from the door. Installation 1. Install hinge snugly on pillar in same location as hinge removed. 2. With the aid of an assistant fasten the door to the hinge. 3. Adjustment of the door lock and striker plate should be made after the door is positioned in the opening. DOOR VENTILATOR ASSEMBLY—FIG. 25 Removal Fig. 23—Loosening Striker Bolt NOTE: The channel between the door window glass and door vent is removed as part of the vent assembly. 1. Regulate the door window glass to the full down position. 2. Remove clip from the window regulator handle, and knob from lock rod. LIGHT DUTY TRUCK SERVICE MANUAL BODY 3. Remove arm rest screws and trim panel. See figure 26. 4. Remove screws attaching ventilator lower assembly to door panel. 5. Loosen inner to outer panel attaching screw through access hole just rearward of the lower vent pivot. 6. Slide door window glass rearward away from ventilator. 7. Remove three screws at the upper front of the door frame. 8. Turn vent assembly 90° and carefully remove by guiding up and out. See figure 27. Ventilator Glass Replacement l . Using an oil can or similar means, squirt prepsol or equivalent on the glass filler all around the glass 1B-11 channel or frame to soften the old seal. When the seal has softened, remove the glass from the channel. 2. Thoroughly clean the inside of the glass channel with sandpaper, removing all rust, etc. 3. Using new glass channel filler, cut the piece to be installed two inches longer than necessary for the channel. Place this piece of filler (soapstoned side of filler away from glass) evenly over the edge of the glass which will fit in the channel. The extra filler extending beyond the rear edge of the glass should be pinched together to hold it in place during glass installation. NOTE: One side of this filler (the outside of the roll) is soapstoned. This is the side which goes into the metal channel. 4. Brush the inside of the metal glass channel freely with ordinary engine oil. This will enable the glass and filler to slide freely into the channel. Push the glass with the filler around it into the channel until it is firmly seated. After the glass is firmly in place, the oil softens the filler, causing it to swell, thereby making a watertight seal. Trim off the excess filler material around the channel and at the ends of the channel. NOTE: Glass should be installed so that rear edge is parallel to the division post. Allow full cure before water testing. Installation 1. 2. 3. 4. 5. NOTE: Replace the door window glass and regulate to the full down position before installing the door ventilator assembly. Lower the ventilator assembly into the door frame. Make certain the rubber lip is positioned inside the inner and outer panel before tightening screws. Slide door glass forward engaging glass in vent channel. Reinstall all screws and tighten. Install and tighten the three screws at the upper front of the door. Adjustment 1. Adjust the ventilator by placing wrench on adjusting nut thru access hole and turning vent window to the desired tension. See figure 28. 2. After making adjustment bend tabs over the hex nut on base of assembly. See figure 29. 3. Install arm rest screws and trim panel. 4. Install window regulator handle. DOOR WINDOW ASSEMBLY—FIG. 30 Fig. 27—Removing Ventilator Assembly Replacement 1. Completely lower glass to bottom of door. LIGHT DUTY TRUCK SERVICE MANUAL 1B-12 BODY TO ADJUST T E N S IO N S TURN THE VENT WHILE HOLDING A WRENCH O N THE HEX NUT____ Fig. 30—Door Window and Regulator Fig. 28—Adjusting Tension 2. Remove window regulator handles using tool J-7797. 3. Remove door arm rest and trim pad. 4. Mask or cover upper portion of door window frame. Remove ventilator assembly as previously outlined. 5. Slide glass forward until front roller is in line with notch in sash channel. Disengage roller from channel. 6. Push window forward and tilt front portion of window up until rear roller is disengaged. See figure 31. 7. Put window assembly in normal position (level) and raise straight up and out. 8. Reverse above procedure for installation. WINDOW REGULATOR—FIG. 30 Replacement 1. Remove ventilator assembly and door window as outlined previously. 2. Remove screws attaching regulator to door inner panel. 3. Remove regulator assembly through door opening. 4. Install regulator by reversing above steps. Lubricate regulator gear with lubriplate or equivalent. LOCKS, HANDLES AND RODS The door lock, handles and control rods are shown in figure 32 as they would be installed in the vehicle. Note the clips which attach the three control rods to the lock assembly. NOTE: All clips which attach control rods to lock assembly must be replaced whenever removed. BEND TAB OVER HEX NUT no tch ijl ROLLER Fig. 29—Bend Tabs Over Hex Nut Fig. 31—Removing Door Glass LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-13 Door Lock Assembly Replacement 1. 2. 3. 4. 5. 6. Raise window to gain access to lock. Remove regulator handle. Remove remote control push button knob. Remove trim panel. Remove clip from inside handle rod-to-lock. Remove clip from outside handle rod-to-lock. This is best accomplished by inserting a long screwdriver through the daylight opening, as shown in figure 32. 7. Remove screws which attach lock assembly to door panel. 8. Remove lock and remote control rod as an assembly. 9. To install lock assembly, reverse above steps. Be sure to replace all clips removed earlier. Door Outside Handle—Fig. 33 Replacement 1. 2. 3. 4. 5. 6. Raise window to gain access to lock. Remove window regulator handle. Remove remote control rod. Remove trim panel. Remove clip from outside handle rod-to-lock. Remove screws which retain outside handle to door panel. 7. Remove handle and control rod. 8. Reverse above procedures to install outside handle. Door Lock Cylinder—Fig. 33 Replacement l . Raise door window. 2. Remove window regulator handle, remote control knob and trim panel. 3. Use a screwdriver or other suitable tool to slide the lock cylinder retaining clip out of engagement with the lock cylinder. 4. Remove lock cylinder. 5. To install, reverse the above steps. Door Inside Handle Replacement 1. Remove window regulator handle, remote control push button knob and trim panel. 2. Disconnect control rod from inside handle, as shown in figure 34. 3. Remove screws retaining inside handle to door. 4. Remove inside handle. 5. Reverse above steps to install. LIGHT DUTY TRUCK SERVICE MANUAL 1B-14 BODY DOOR TO BODY OPENING WEATHERSTRIP—FIGS. 35, 36 Side door sealing incorporates an inner seal. The inner seal is mounted on the body opening welding flange and goes completely around the periphery of the opening. The molded weatherstrip material is snapped in place. Success of weatherstrip replacement depends entirely upon the quality of the cement used and the care with which it is applied. All rust, road dirt and grease or oil must be completely removed as as should all old cement and bits of old weatherstrip. After removing all foreign material from door opening surface proceed as follows: 1. Open door and block open. 2. Remove sill plate retaining screws and remove sill plate. 3. Remove side door inner weatherstrip seal. 4. Install molded corner of inner weatherstrip, starting at the bottom of the door opening. 5. Trim inner weatherstrip with a notch and butt ends together. 6. Reinstall sill plate and sill plate retaining screws. Fig. 36—Door Weatherstrip (14) REAR SIDE DOOR (06 AND 63 ONLY) Adjustments and Hinge Replacement The procedures for hinge replacement, and for hinge and striker bolt adjustment are similar to those detailed in the front door adjustment procedure. Access to the hinges of the rear door is shown in figure 37. STATIONARY GLASS-REAR DOOR Replacement 1. Lower window to full down position. 2. Remove remote control knob and window regulator handle. 3. Remove screws retaining door trim pad, and remove trim pad. See figure 38. 4. Remove glass run channel by removing screws retaining channel to door. See figure 39. 5. Remove stationary glass. 6. Replace glass by reversing above procedure. WINDOW GLASS—FIG. 40 Replacement 1. Lower glass to full down position. 2. Remove remote control push button knob, window regulator handle and trim pad. 3. Remove stationary glass as previously outlined. Remove screws from rear division channel, and slide channel rearward in the opening. 4. Raise glass as far as possible, then slide glass until the roller is in line with the notch in the sash LIGHT DUTY TRUCK SERVICE MANUAL BODY channel. See figure 40. Disengage roller from channel. 5. Tilt window outboard and move until other roller can be removed from channel. 6. Raise window up and out. 7. Reverse above procedure for installation. IB -1 5 4. Install regulator by reversing above procedure. Lubricate regulator gear with lubriplate or equivalent. LOCKS, HANDLES AND RODS Lock Assembly—Fig. 41 Replacement WINDOW REGULATOR ASSEMBLY—FIG. 40 Replacement 1. Remove trim pad, stationary glass, and window glass as outlined earlier. 2. Remove screws attaching regulator assembly to door inner panel. 3. Remove regulator assembly through opening in door. 1. Remove window regulator handle and remote control push button knob. 2. Remove trim pad. 3. Disengage three clips which retain control rods to lock assembly. a. Inside handle control rod. b. Remote control lower rod. c. Outside handle control rod. 4. Remove screws retaining lock assembly to door panel, then remove lock assembly. 5. Install lock by reversing above procedure. Be sure to replace all clips removed with new clips on installation. Inside Handle—Fig. 41 Replacement Fig. 39—Glass Run Channel 1. Remove regulator handle, remote control knob and trim pad as outlined previously. 2. Disconnect control rod from inside handle by removing clip as shown in figure 41. 3. Remove inside handle by removing four screws which secure handle to door panel. 4. Replace handle by reversing above procedure. Install new clip when installing control rod. LIGHT DUTY TRUCK SERVICE MANUAL 1B-16 BODY 3. Remove two screws securing outside handle to door panel. 4. Remove handle assembly. 5. Replace by reversing above procedure. Be sure to use new clip when attaching control rod to lock assembly. WEATHERSTRIP—FIG. 44 The procedure outlined in Front Door W eatherstrip may be applied to the Rear Side Door W eatherstrip, shown in figure 44. REAR DOORS (06 ONLY) Adjustments Fig. 41—Lock Assembly and Inside Handle Rear doors may be adjusted in the body opening by loosening hinge bolts and repositioning door, then retightening bolts. See figure 47 for hinge bolt location. Remote Control—Fig. 42 Replacement 1. Remove regulator handle, remote control knob and trim pad. 2. Disconnect remote control lower rod from door lock assembly. 3. Remove two screws securing each remote control lever to door panel. 4. Remove remote control levers and rods through door opening. 5. Replace by reversing above procedure. Outside Handle—Fig. 43 Replacement 1. Remove regulator handle, remote control rod and trim pad. 2. Disengage outside handle control rod from lock assembly by removing clip, as shown in figure 43. Fig. 42—Remote Control Assembly LIGHT DUTY TRUCK SERVICE MANUAL BODY IB -1 7 Fig. 45—Rear Door Controls LOCKS, HANDLES AND RODS The rear door lock, outside handle, lock cylinder, control rods and latch are shown in figures 45 and 46. The rods can be disconnected from the lock, latch or handle by disengaging the retaining clips, as shown. The lock cylinder is removed in the same m anner as the front side door lock cylinder. Fig. 46—Rear Door Outside Handle and Lock Cylinder LIGHT DUTY TRUCK SERVICE MANUAL I B - 1 8 BODY WEATHERSTRIP W eatherstrip installation is shown in figures 48 and 49. Proper installation is dependent on completely cleaning all foreign material from old installation and using a quality cement on the new installation. REAR D O O R —F IG . 47 Replacement 1. Remove bolts securing check arm bracket to body pillar. 2. Remove upper and lower hinge bolts, and with aid from an assistant, remove the rear door. 3. Reverse above steps for reinstallation. Fig. 48—Weatherstrip—L.H. Rear Door C H E C K A R M —F IG . 4 7 Replacement 1. Remove bolts securing check arm bracket to body pillar. 2. Remove check arm access cover. 3. With one hand supporting housing assembly and insulator on the inside of the door panel, remove bolts securing housing assembly to door. 4. Remove housing, insulator and check arm. 5. To separate check arm from bracket, remove holding pin connecting the two parts. 6. To install check arm, reverse the procedure above. Fig. 49—Weatherstrip—R.H. Rear Door LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-19 ENDGATES (0 6 A N D 14) Coach models (06) and utility models (14) use endgates of similar, yet distinct design. Separate procedures follow for service on each of these endgates. ENDGATE ASSEMBLY(06) MODELS ONLY Replace 1. Lower endgate, and remove hinge access covers. See figure 50. 2. Remove endgate-to-hinge bolts. 3. Remove L.H. torque rod bracket, shown in figure 51. 4. Lift endgate to almost closed position and remove support cables. 5. Remove endgate with torque rod. 6. To install, reverse removal procedure. HINGES Replacement If necessary to remove hinges, remove endgate as outlined previously, and proceed as follows: 1. Remove bolts from each of the hinge assemblies on the underside of the body. See figure 50. 2. Remove hinge assemblies. If the hinge pins are to be removed, note the position of bushings so they may be reinstalled in the same position. 3. Reverse procedure to install. Fig. 50—Endgate, Hinges and Supports—(06 Only) Fig. 51—Torque Rod—(06 Only) ENDGATE DISASSEMBLY 1. Remove access cover shown in figure 52, to gain access to interior components. 2. Detach remote control rods from lock assembly by removing clips. 3. Remove bolts securing lock assembly, and remove lock assembly. 4. Remove handle assembly bolts and remove inside handle. 5. Remove R.H. torque rod bracket screws, figure 51, then remove torque rod from endgate. 6. Remove screws connecting cam assemblies to sash assembly, figure 53, then remove cam assemblies. 7. Remove glass from endgate. Fig. 52—Latch and Remote Controls—(06 Only) LIGHT DUTY TRUCK SERVICE MANUAL 1B-20 BODY Fig. 53—Window Glass and Regulator—(06 Only) 8. Unclip and remove inner and outer seal assemblies. 9. Remove screws connecting window regulator assembly to endgate, figure 53, and remove regulator. 10. From inside the endgate, remove the nuts fastening the outside handle to endgate and remove the outside handle. See figure 54. NOTE: If equipped with power tailgate window, detach wiring harness from motor. 11. Remove side bolts connecting left and right glass channels to endgate and remove channels. 12. Remove side latch bolts and remove side latches with control rods. See figure 52. NOTE: Detach wiring harness from R. H. latch if so equipped. 13. Separate side latch from control rod by pulling control rod thru nylon guide. 14. Reverse the above procedure for reassembly and installation. Fig. 54—Outside Handle (06 and 14) ENDGATE ASSEMBLY— (14) MODELS ONLY Replacement 1. Lower endgate, then remove four bolts securing hinge to body on each side. See figure 55. 2. Disconnect torque rod anchor plate on each side. It is necessary to remove lower bolt only, then let plate swing down. See figure 59. 3. With an assistant, raise endgate part way, then Adjustments Loosen bolts, adjust at either endgate hinge position or endgate latch, then retighten bolts. LIGHT DUTY TRUCK SERVICE MANUAL BODY IB -2 1 disconnect support cables from endgate. See figure 55. 4. Remove endgate by pulling disconnected hinge from body, figure 56, then grasping torque rod with one hand and pulling torque rod over gravel deflector, as shown in figure 57. 5. Individual components may be removed from the endgate now, or after reinstallation. 6. To install endgate, reverse the above procedure. HINGE Replacement 1. Lower endgate and disconnect hinge to be replaced by removing hinge-to-body bolts. See figure 55. 2. At the other hinge, loosen the hinge-to-body bolts. 3. On the hinge to be replaced, remove the hinge-toendgate bolts. Fig. 58—Removing Access Cover (14) 4. Pull the endgate away from the body several inches and withdraw hinge from body. Then lift endgate slightly to allow removal of hinge from endgate. See figure 56. 5. To install hinge, reverse the above procedure. Be sure to install hinge into endgate first, then into the body. TORQUE ROD Replacement 1. Lower endgate and remove access cover, as shown in figure 58. 2. Disconnect torque rod anchor plate. It is necessary to remove the lower bolt only, then let plate swing down. See figure 59. 3. Loosen four bolts retaining endgate hinge to body. 4 Move endgate slightly away from body. Fig. 56—Pulling Hinge Away From Body (14) Fig. 57—Grasping Torque Rod (14) Fig. 59—Torque Rod Installation (14) LIGHT DUTY TRUCK SERVICE MANUAL 1B-22 BODY 5. Remove torque rod retaining bracket on lower edge of endgate. See figure 59. 6. Remove torque rod retaining clip on side edge of endgate. 7. Lift torque rod up and slide from endgate as shown in figure 60. 8. Reverse the procedure above for installation. ENDGATE DISASSEMBLY 1. Lower endgate and remove access cover. 2. Disconnect side latch remote control rods from center control by removing retaining clips. See figure 61. 3. Remove four screws from each side latch, and withdraw latch and control rod from endgate, as shown in figure 62. 4. Disconnect control rod from latch. 5. Refer to figure 63 for installation of latch control and blockout rod. 6. Disconnect blockout rod from control assembly by detaching spring and removing two screws retaining rod to inner panel. 7. Disconnect inside handle control rod from control assembly, then remove screws which secure inside handle to inner panel. 8. Remove three screws which retain remote control assembly to inner panel. 9. Remove control assembly and inside handle as shown in figure 64. 10. Refer to figure 65 for window and regulator installation. 11. Roll window to up position. 12. Disconnect sash from regulator as shown in figure 66. Fig. 60—Removing Torque Rod (14) Fig. 62—Removing Side Latch Fig. 61—Latches and Rods Fig. 63—Control Assembly and Blockout Rod LIGHT DUTY TRUCK SERVICE MANUAL BODY Fig. 64—Removing Control Assembly and Inside Handle 1B-23 Fig. 66—Disconnecting Sash from Regulator 13. Remove glass from endgate. 14. Remove four regulator attaching screws and withdraw regulator from endgate as shown in figure 67. 15. Remove outside handle by removing nuts from inside of outer panel. See figure 68. 16. Reverse the above steps for reassembly. TAILGATES (03, 63 and 14) Replacement Utility vehicles (14) without removable tops utilize a tailgate shown in figure 69. Chassis/cab (03 and 63) models have optional pickup units which utilize tailgates as shown in figures 69 and 70. The tailgate shown in figure 69 can be removed by disconnecting both links from the tailgate, removing Fig. 65—Window and Regulator Fig. 67—Removing Regulator Fig. 68—Outside Handle LIGHT DUTY TRUCK SERVICE MANUAL I B - 2 4 BODY screws attaching both trunnions to body, and lifting the tailgate off the vehicle. The tailgate shown in figure 70 can be separated from the vehicle by removing the bolt and lock washer from each trunnion in carrier box, and removing the tailgate. REMOVABLE TOP (14 ONLY) Removal 1. Remove the bracket-to-roof bolt from each of the top-to-header panel attaching brackets as shown in Figure 71. 2. Remove the bolts which retain the top to the body side panels, shown in figure 72. 3. Lower the rear window into the endgate, and lower endgate. 4. Lower the door windows. 5. Slide top rearward approximately 18" to expose the bottom rear top-to-pickup box attaching holes. 6. To prevent possible flexing of the sides on removal, connect the sides of the top with support braces as follows. a. Fabricate 2 braces 72" long from wood or square aluminum tubing. Drill two (2) 3/8" diameter holes, 63 inches apart in the brace. b. Attach one brace to the holes exposed in Step 7. c. Slide top forward to expose the front bottom top-to-pickup box attaching holes. d. Attach the second brace to these holes. 7. With assistance, lift the top and move it rearward for removal. Fig. 72—Removable Top LIGHT DUTY TRUCK SERVICE MANUAL BODY SEATS Care and Cleaning of Interior Soft Trim Dust and loose dirt that accumulate on interior fabric trim should be removed frequently with a vacuum cleaner, whisk broom or soft brush. Vinyl or leather trim should be wiped clean with a damp cloth. Normal cleanable trim soilage, spots or stains can be cleaned with the proper use of trim cleaners available through General Motors dealers or other reputable supply outlets. Before attempting to remove spots or stains from upholstery, determine as accurately as possible the nature and age of the spot or stain. Some spots or stains can be removed satisfactorily with water or mild soap solution (refer to accompanying "Removal of Specific Stains"). For best results, spots or stains should be removed as soon as possible. Some types of stains or soilage such as lipsticks, some inks, certain types of grease, mustard, etc., are extremely difficult and, in some cases, impossible to completely remove. When cleaning this type of stain or soilage, care must be taken not to enlarge the soiled area. It is sometimes more desirable to have a small stain than an enlarged stain as a result of careless cleaning. CAUTION: When cleaning interior soft trim such as upholstery or carpeting, do not use volatile cleaning solvents such as: acetone, lacquer thinners, carbon tetrachloride, enamel reducers, nail polish removers; or such cleaning materials as laundry soaps, bleaches or reducing agents (except as noted in the instructions on stain removal). Never use gasoline or naphtha for any cleaning purpose. These materials may be toxic or flammable, or may cause damage to interior trim. Cleaning Fabrics with Cleaning Fluid This type of cleaner should be used for cleaning stains containing grease, oil or fats. Excess stain should be gently scraped off trim with a clean dull knife or scraper. Use very little cleaner, light pressure, and clean cloths (preferably cheese cloth). Cleaning action with cloth should be from outside of stain towards center and constantly changing to a clean section of cloth. When stain is cleaned from fabric, immediately wipe area briskly with a clean absorbent towel or cheese cloth to help dry area and prevent a cleaning ring. If ring forms, immediately clean entire area or panel section of the trim assembly. NOTE: Sometimes a difficult spot may require a second application of cleaning fluid followed immediately by a soft brush to completely remove the spot. Cleaning Fabrics with Detergent Foam Cleaners This type of cleaner is excellent for cleaning general soilage from fabrics and for cleaning a panel section where a minor cleaning ring may be left from spot 1B-25 cleaning. Vacuum area to remove excess loose dirt. Always clean at least a full trim panel or section of trim. Mask adjacent trim along stitch or weld lines. Mix detergent type foam cleaners in strict accordance with directions on label of container. Use foam only on a clean sponge or soft bristle brush. Do not wet fabric excessively or rub harshly with brush. Wipe clean with a slightly damp absorbent towel or cloth. Immediately after cleaning fabric, dry fabric, with a dry towel or hair dryer. Rewipe fabric with dry absorbent towel or cloth to restore the luster of the trim and to eliminate any dried residue. Removal of Specific Stains Candy Chocolate, use cloth soaked in lukewarm water; other than chocolate, use very hot water. Dry. If necessary, clean lightly with fabric cleaning fluid. Chewing Gum Harden gum with ice cube and scrape off with dull knife. Moisten with fabric cleaning fluid and scrape again. Fruit Stains, Coffee, Soft Drinks, Ice Cream and Milk Wipe with cloth soaked in cold water. If necessary clean lightly with fabric cleaning fluid. Soap and water is not recommended as it might set the stain. Catsup Wipe with cloth soaked in cool water. If further cleaning is necessary, use a detergent foam cleaner. Grease, Oil, Butter, Margarine and Crayon Scrape off excess with dull knife. Use fabric cleaning fluid. Paste or Wax Type Shoe Polish Light application of fabric cleaning fluid. Tar Remove excess with dull knife, moisten with fabric cleaning fluid, scrape again, rub lightly with additional cleaner. Blood Wipe with clean cloth moistened with cold water. Use no soap. Urine Sponge stain with lukewarm soap suds from mild neutral soap and clean cloth, rinse with cloth soaked in cold water, saturate cloth with one part household ammonia water and 5 parts water, apply for 1 minute, rinse with clean, wet cloth. Vomitus Sponge with clean cloth dipped in clean, cold water. W ash lightly with lukewarm water and mild neutral soap. If odor persists, treat area with a water-baking soda solution (1 teaspoon baking soda to one cup of tepid water). Rub again with cloth and cold water. Finally, if necessary, clean lightly with fabric cleaning fluid. LIGHT DUTY TRUCK SERVICE MANUAL 1B-26 BODY SEAT MOUNTING Typical Seat Mounting provisions are shown in figures 73 through 81. CAUTIO N : See CAUTION on page 1 o f this section regarding fasteners used on seats and seat belts. Fig. 75—Passenger’s Bucket Seat (03) Fig. 73—Front Bench Seat (03, 06 and 63) Fig. 74—Driver’s Bucket Seat (03) Fig. 77—Passenger’s Bucket Seai (14) LIGHT DUTY TRUCK SERVICE MANUAL BODY Fig. 78—Rear Bench Seat (63) Fig. 80—Rear Folding Seat (06) Fig. 79—Rear Bench Seat (06) Fig. 81—Rear Bench Seat (14) IB -2 7 LIGHT DUTY TRUCK SERVICE MANUAL 1B-28 BODY BODY MOUNTING The sequence of mounting attachments is shown in figures 82 through 85. LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-29 Fig. 84—Body Mounting (06) Fig. 85—Body Mounting (14) LIGHT DUTY TRUCK SERVICE MANUAL 1B-30 BODY G MODELS INDEX Front End Windshield Wipers...................................................... ..IB-30 Cowl Ventilator G rille.................................................IB-31 Side Ventilator Valve...................................................IB-31 Rear View M irror....................................................... ..IB-32 Body Glass Windshield Glass............................................................IB-32 Stationary Glass..............................................................IB-34 Swingout Glass................................................................IB-34 Front Door Adjustments......................................................................IB-34 Replacement.....................................................................IB-34 W eatherstrip................................................................... ..IB-34 Hinges.................................................................................IB-35 Ventilator..........................................................................IB-36 Window and R egulator...............................................IB-37 Locks, Handles, Rods...................................................IB-37 Sliding Side Door Front Latch.......................................................................IB-38 Rear Latch........................................................................IB-39 Upper Left H inge..........................................................IB-39 Door Strikers................................................................. ..IB-40 Adjustments.......................................................................IB-40 Rear Door H inge................................................................................ ..IB-44 Remote Control............................................................. ..IB-44 Latches and R ods..........................................................1B44 Adjustments.......................................................................IB-45 Seats Drivers Seat......................................................................IB-46 Passenger Seat............................................................... ..IB-47 Rear Seats.........................................................................1B47 FRONT END WINDSHIELD WIPERS Windshield wiper units on all models are of the twospeed electric type. A single wiper motor unit, mounted to dash panel at top and to left of engine cover inside cab, powers both wiper blades. The wiper blade operating link rods and pivot mountings on these models are located in the outside air inlet plenum chamber. Arm Adjustment To adjust sweep of blades turn on wipers, then note sweep of arms. If necessary, remove one or both arms as follows: Pull outer end of arm away from glass which will trip lock spring at base of arm and release spring from undercut of pivot shaft. While holding arm in this position, pull outward on cap section at base of arm to remove arm. Arm can be reinstalled in any one of several positions due to serrations on pivot shaft and in arm cap. See figure 1G. attach link rod to motor drive. Disengage link rods from pins. 4. Remove screws which attach each arm transmission pivot shaft assembly to cowl. Remove pivot shaft assembly with link rod from plenum chamber. Installation 1. Place pivot shaft assembly with link rod into position at cowl bracket. Secure assembly to bracket with two screws. 2. Attach end of link rod to motor drive and arm. Secure rod with the two attaching nuts. WIPER ARM PIVOT SHAFTS AND LINK ROD—FIG. 2G Removal 1. Remove windshield wiper arms from pivot shafts. Procedure for removing arms is explained previ­ ously under "Arm Adjustments." 2. Remove screws which attach outside air cowl ventilator grille to cowl. Carefully remove grille from cowl. 3. At center of cowl, remove two attaching nuts which LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-31 Fig. 2G—Windshield Wiper Linkage 3. Install outside air cowl ventilator grille to top of cowl. 4. Before installing wiper arms, operate wiper motor momentarily which should rotate pivot shafts to park position. Install arms. COWL SIDE VENT VALVE Replacement 1. Remove screws retaining valve guide to panel, as shown in figure 4G. 2. Remove valve assembly by depressing pins at top and bottom of valve. 3. Reverse the above steps for installation. COWL VENTILATOR GRILLE Replacement 1. 2. 3. 4. Remove windshield wiper blades. Remove screws retaining grille, figure 3G. Remove grille and seal. Reverse above steps to install grille. Fig. 3G—Cowl Ventilator Grille LIGHT DUTY TRUCK SERVICE MANUAL 1B-32 BODY REAR VIEW MIRRORS Inside Rear View Mirror Replacement The inside mirror may be removed by removing screw retaining mirror to its glass-mounted bracket, and lifting mirror off bracket. Outside Rear View Mirrors Outside rear view mirror installations are shown in figure 6G. Occasional tightening of mounting and assembly bolts and screws will sharply decrease occurence of failure due to door slamming or road shock. Fig. 5G—Inside Rear View Mirror Fig. 6G—Outside Rear View Mirrors BODY GLASS WARNING: dling glass. Always wear gloves when han­ WINDSHIELD GLASS The windshield is a one-piece type and is retained in the windshield opening by a moulded rubber weatherstrip. This weatherstrip is sealed in the windshield opening and sealed to the windshield glass. See figure 7G. When replacing a cracked windshield glass, it is very important that the cause of the glass breakage be determined and the condition corrected before a new glass is installed. Otherwise, it is highly possible that a small obstruction or high spot somewhere around the windshield opening will continue to crack or break the newly installed windshield, especially when the strain on the glass caused by this obstruction is increased by such conditions as wind pressures, extremes of temperature, motion of the vehicle, etc. The procedure for removal of the windshield applies to the complete windshield assembly and to other stationary glass, such as in figure 10G. Removal NOTE: Refer to figures 14-16 in the "C-K Models" portion of this section for illustra­ tion of removal technique. 1. Before removing the windshield, mark the location of the break on the windshield rubber channel and the body. Protect the paint finish inside of the cab. LIGHT DUTY TRUCK SERVICE MANUAL BODY •APPLY SEALER Fig. 7G—Windshield Glass Mask around the windshield opening and outside, lay a suitable covering across the hood and fenders. NOTE: The windshield glass rubber weather­ strip is one piece. The glass is held in a channel within the weatherstrip. 2. Do not try to remove reveal moldings while windshield is in body opening. Remove reveal molding from custom weatherstrip retention groove after windshield is removed from body opening. 3. To free windshield rubber channel of weatherstrip loosen the lip of the windshield weatherstrip from the pinchweld flange along the top and at the sides by applying firm, controlled pressure to the edge of the glass. At the same time assist the lip of the rubber weatherstrip channel over the pinchweld flange with a flat bladed tool. IB -3 3 3. Check flange area for solder, weld high spots, or hardened spot-weld sealer. Remove all high spots. 4. Check windshield glass to opening, by supporting glass with six spacers contained in packet J-22577, as shown in figure 8G. CAUTION: Do not strike glass against body metal. Chipped edges on the glass can lead to future breaks. NOTE: It is necessary to modify the spacers by cutting off 3/16" from the back of the spacer with a knife, as shown in figure 8G. 5. With the windshield supported and centered in its opening, check the relationship of the glass to the body opening flange around the entire perimeter of the glass. 6. Check the relationship of glass to opening as follows: a. Inside edge of glass to body flange. b. Outer edge of glass to parallel body metal. 7. Mark areas of body metal or flange to be reformed, remove glass and correct as necessary. 8. Recheck windshield in its opening and if satisfac­ tory proceed as follows: Installation 1. Apply sealer to weatherstrip and install on glass. 2. Install a cord around periphery of weatherstrip, leaving a loop at the top and the loose ends at the bottom. See figure 9G. 3. Place protective covering over plenum grille, front fenders and hood. 4. Place windshield and weatherstrip assembly in opening. With one technician lightly pushing in on windshield, another technician within the cab should pull on the cord as follows: CHECKING BLOCKS Checking Windshield Opening Due to the expanse and contour of the windshield it is imperative in the event of a stress crack that the windshield opening be thoroughly checked before installing a replacement windshield. The replacement glass is used as a template. 1. Check for the following conditions at the previously marked point of fracture. a. Chipped edges on glass. b. Irregularities in body opening. c. Irregularities in rubber channel weatherstrip. 2. Remove all sealer from flange and body around windshield opening. Fig. 8G—Checking Windshield Opening LIGHT DUTY TRUCK SERVICE MANUAL 1 B -34 BODY Fig. 11G—Swingout Window d. Seal windshield to weatherstrip and weatherstrip to body. SWINGOUT WINDOW Removal 1. Swing out the window. See figure 11G. 2. Remove screws retaining latch to body. 3. Remove window hinge retaining screws and window. 4. Remove latch from glass. Installation a. Pull on loose ends until each is within 2" of its respective upper corner. b. Pull on loop until cord is within 2" of the upper corners. c. Finish seating corners by simultaneously pulling on both ends of the cord at each corner. This will insure proper positioning of the critical upper corners. 1. Install latch to glass using escutcheon, spacer, washer, latch and screw. Torque to specifications. 2. Place window into opening and install hinge retaining screws and window. 3. Install latch to glass. LATCH SWINGOUT WINDOW Replacement 1. Swing out the window. 2. Remove latch to body and latch to window screws and remove latch. 3. Reverse above steps for installation. FRONT D O O R DOOR ADJUSTMENTS Doors can be adjusted for alignment of clearance in the cab door opening, and for proper latching. Door alignment adjustments are made at the striker bolt, and at door hinges. The door, when properly located in door opening, will have equal clearance around its perimeter. The door should be adjusted in the opening so the edge of the door across the top and also at the lock side is parallel with the body opening as nearly as possible. Hinge Adjustment Door hinge bolt holes are oversized to make adjustment LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-35 possible. Alignment adjustments can be made by loosening the proper hinge bolts, aligning door to proper position, and tightening bolts securely. See figure 12G, for typical adjustments. Striker Bolt Adjustment W ith the use of J-23457, shown in figure 13G, the striker bolt can be adjusted in any of three ways. See figure 14G. 1. Up and down—To adjust striker up or down, loosen bolt, adjust to desired height, and tighten bolt securely. NOTE: This adjustment is important to assure that the right proportion of door’s weight will rest on striker bolt when door is closed. If bolt is positioned too high on pillar, rapid wear will occur to the lock cam; if too low, an extra load will be placed on door hinges as well as pull door downward and out of alignment. 2. In and Out—To adjust striker in and out, loosen bolt, adjust horizontally to desired position and tighten bolt securely. 3. Forward and Rearward—To make this adjustment, loosen striker bolt, shim to desired position, and tighten bolt securely. Fig. 13G—Loosening Striker Bolt DOOR HINGE Remove 1. Remove hinge access hole cover from door hinge pillar. 2. If removing one hinge, support door in such a m anner that weight is taken off other hinge, and that the door will not move. 3. Remove hinge screws from both body and from door and remove hinge. See figure 12G. Installation 1. 2. 3. 4. 5. Install hinge to door and body. Snug bolts. Remove door supports. Adjust door as outlined under "Door Adjustment". Torque bolts to specifications. Install hinge access hole covers. DOOR WEATHERSTRIP Success of weatherstrip replacement depends entirely upon the quality of the cement used and the care with which it is applied. All rust, road dirt and grease or oil must be completely removed as should all old cement and bits of old weatherstrip. After removing all foreign material from door opening surface, wipe down with prepsol or its equivalent. Use only a good quality cement which is made specially for weatherstrip installation, following the m anufacturer’s directions. Proceed as follows: LIGHT DUTY TRUCK SERVICE MANUAL 1B 3 6 BODY 1. Open door and block open. 2. Remove side door weatherstrip. 3. Remove used adhesive from door with adhesive or cement remover. 4. Apply adhesive to door. 5. Install weatherstrip. 6. Trim weatherstrip with a notch, and butt ends together. TRIM PANEL, ARM REST AND HANDLES Removal 1. Remove screws retaining arm rest to trim panel. 2. Remove door handles with Tool J-7797 and pull from shaft. 3. Remove trim panel screws and remove panel. If seal is damaged, replace seal. Installation 1. Install trim panel. 2. Install arm rest. Install door handle washers and handles. DOOR VENTILATOR ASSEMBLY Removal 1. 2. 3. 4. 5. 6. 7. NOTE: The channel between the door window glass and door vent is removed as part of the vent assembly. Regulate the door window glass to the full down position. Remove door handles with Tool J-7797. Remove trim panel. Remove rear window run channel screws. Slide door window glass rearward away from ventilator. Remove three screws at the upper front of the door, as shown in figure 15G. Turn the vent assembly 90° and carefully remove by guiding up and out, as shown in figure 16G. Ventilator Glass Replacement 1. Using an oil can or similar means, squirt prepsol on the glass filler all around the glass channel or frame to soften the old seal. When the seal has softened, remove the glass from the channel. 2. Thoroughly clean the inside of the glass channel with sandpaper, removing all rust, etc. 3. Using new glass channel filler, cut the piece to be installed two inches longer than necessary for the channel. Place this piece of filler (soapstoned side of filler away from glass) evenly over the edge of the glass which will fit in the channel. The extra filler extending beyond the rear edge of the glass Fig. 16G—Removing Ventilator should be pinched together to hold it in place during glass installation. NOTE: One side of this filler (the outside of the roll) is soapstoned. This is the side which goes into the metal channel. 4. Brush the inside of the metal glass channel freely with ordinary engine oil. This will enable the glass and filler to slide freely into the channel. NOTE: Glass should be installed so that rear edge is parallel to the division post. Allow full cure before water testing. Installation NOTE: Replace the door window glass and regulate to the full down position before installing the door ventilator assembly. 1. Lower the ventilator assembly into the door frame. Center into position. LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-37 2. Make certain the rubber lip is positioned before tightening screws. 3. Slide door glass forward engaging glass in vent channel. 4. Reinstall all screws and tighten. 5. Install and tighten the three screws at the upper front of the door. Adjustment 1. Adjust the ventilator adjusting nut by turning clockwise to increase operating tension, as shown in figure 17G. 2. After making adjustment bend tabs over the hex nut. 3. Install trim panel. 4. Install door and window regulator handles. DOOR WINDOW ASSEMBLY Replacement 1. Completely lower glass to bottom of door. 2. Remove inside door and window regulator handles using Tool J-7797. 3. Remove door arm rest and trim pad. 4. Mask or cover upper portion of door window frame. Remove ventilator assembly as previously outlined. 5. Slide glass forward until front roller is in line with notch in sash channel. Disengage roller from channel. See figure 18G. 6. Push window forward and tilt front portion of window up until rear roller is disengaged. 7. Put window assembly in normal position (level) and raise straight up and out. 8. Reverse above procedure for installation. Fig. 18G—Window and Regulator WINDOW REGULATOR Replacement 1. 2. 3. 4. 5. Wind window all the way up. Remove inside door handles with Tool J-7797. Remove door trim pad. Remove screws securing regulator to inner panel. Push regulator out of door opening while holding rear of assembly, then slide assembly to the notches in the carrier channel and out through the door access hole. 6. Install regulator in reverse order of removal, lubricate regulator gears with lubriplate or equivalent. DOOR LOCK—FIGURE 19G Removal 1. 2. 3. 4. 5. Raise window. Remove inside handles with Tool J-7797. Remove trim panel. Remove remote control sill knob. From outside the door remove screws retaining lock to door edge and lower the lock assembly. 6. Remove screws retaining remote control. 7. Remove screws securing glass run guide channel. 8. Remove lock, push button rod and remote control rod as an assembly. Installation Fig. 17G—Adjusting Ventilator Tension 1. Transfer remote rod with clip to new lock. 2. Connect remote door handle rod to lock after lock is positioned. 3. Secure lock screws. 4. Secure remote handle. LIGHT DUTY TRUCK SERVICE MANUAL 1B-38 BODY 5. Check all controls for proper operation before reinstalling trim and handles. 6. Install remote control sill knob. NOTE: Connecting rod can be removed at this point by disconnecting spring clip from lock. 4. To install, reverse removal procedure. REMOTE CONTROL AND CONNECTING ROD—FIG. 19G LOCK CYLINDER ASSEMBLY—FIG. 20G Replacement Replacement 1. Raise door window and remove door trim pad. 2. Remove bolts securing remote control to door inner panel. 3. Pivot remote inboard slightly, to disengage connecting rod, and remove remote control from door. SLIDING FRONT LATCH ASSEMBLY Removal 1. 2. 3. 4. Remove trim panel (if so equipped). Remove access cover. Unscrew door lock knob from rod. Disconnect the following rods from latch. See figure 21G. a. Rear latch rods. b. Lock cylinder rod. c. Door lock rod. 5. Remove door handle. 6. Remove screws retaining latch assembly to door. 7. Slide latch rearward and lift front of latch. Disconnect rod leading to lower hinge door catch 1. Raise door window and remove door trim pad. 2. With a screwdriver, or other suitable tool, slide lock cylinder retaining clip (on door outer panel) out of engagement and remove lock cylinder. 3. To install, reverse removal procedure. )E D O O R by pushing rod out of hole and rotating rod clear of latch. See figure 22G. 8. Remove latch assembly from door. Installation 1. Install latch assembly into door by working latch assembly behind the lower hinge door catch. 2. Connect lower hinge door catch, lock cylinder rod, door lock rod, and both rear latch rods. 3. Install latch assembly-to-door attaching screws. Torque to specifications. 4. Install door lock knob and door handle. 5. Install access cover and trim panel. 6. Adjust door front striker as outlined under "Door Adjustments". LIGHT DUTY TRUCK SERVICE MANUAL BODY Fig. 21G—Sliding Door Front Latch REAR LATCH AND/OR LATCH ACTUATING RODS Removal 1. Remove trim panel (if so equipped). 2. Remove front latch assembly access cover. 3. Disconnect rear latch rods from front latch assembly. See figure 2lG . 4. Remove rear latch attaching screws. See figure 23G. 5. Slide rear latch toward front of door until rod clips become exposed. Disconnect rod clips and remove latch from door. Installation 1. Connect rods to latch and install latch to door. Torque screws to specifications. 2. Connect rods to front latch assembly. Fig. 1B-39 23G—S lid in g Door Rear Latch 3. Install access covers and trim panels (if so equipped). 4. Adjust door rear latch as outlined under "Door Adjustments". UPPER LEFT HINGE Removal 1. Open the door. 2. Disengage spring from bolt using a spring removal tool such as a brake spring removal tool. 3. Close door. 4. Remove hinge assembly. Disassembly—Fig. 24G 1. 2. 3. 4. 5. 6. Remove rod connecting hinge and roller assembly. Remove roller. Remove levers, noting position of the springs. Remove nylon block. Remove bushings by tapping out with a drift. Reverse Steps l-5 to reassemble. Torque all parts to specifications. 7. When holding hinge assembly as in figure 25G, the lower latch must engage cam. Installation Fig. 22G—Disconnecting Lower Latch Rod from Latch 1. Install hinge assembly to door. Torque bolts to specifications. 2. Check and adjust latch to striker position as outlined under "Door Adjustments". 3. Turn handle and let door pop open. 4. Connect spring using a brake spring removal tool or a similar tool. 5. Check operation of door hinge. LIGHT DUTY TRUCK SERVICE MANUAL 1B-40 BODY 1. 2. 3. 4. 5. 6. 7. Roller Lockwashers Nut Cam Washer Bushing Bushing 8. 9. 10. 11. 12. 13. 14. Bolt 15. Screw Plate 16. Guide Block Upper lines 17. Hinge (Body Half) Spacer 18. Nut Spring (Upper Lever) 19. Bushing Spring (Lower Level) 20. Bushing Lower Lever 21. Cam 22 . Bushing 23. Hinge (Door Half) 24. Spring 25. Spring retainer 26. Hinge liner Fig. 24G—Upper Left Hinge Components DOOR STRIKERS CAUTION: See CAUTION on page 1 of this section regarding Door Strikerfasteners. Rear Lock Striker Front Latch Striker 1. Remove striker. 2. Install new striker. Adjust as outlined under "Door Adjustments" Torque to specifications. Removal 1. Open door. 2. Remove door striker using tool J-23457. See figure 13G. installation 1. Install door striker using tool J-23457. Torque to specifications. 2. Adjust striker as outlined under "D oor Adjustments". SLIDING DOOR ADJUSTMENTS The side door can be adjusted for alignment and/or clearance in the body opening and for proper latching. When properly positioned in the body opening, the door should have equal clearances around its perimeter. Door adjustments consist of the following: Up and down, fore and aft, in and out, front and rear strikers, rear door wedge, upper left hinge striker, and lower catch. LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-41 In and Out Front in and out adjustments, figure 26G, are provided by means of an adjustable lower roller mounting bracket, and for the upper front in and out adjustment the upper bracket is slotted so the roller can be moved in and out. Rear in and out adjustment is provided by adjusting the rear lock striker laterally. Front and Rear Striker The front striker provides latching for the front of the door. The rear striker latches the rear of the door as well as providing in and out adjustment. Rear Door Wedge The rear door wedge located below the door lock striker helps support the door. Fig. 25G—Checking Assembly of Hinge Up and Down Front up and down adjustments are provided by means of slotted holes in the door. Rear up and down adjustments are provided by slotted holes in the upper left hinge. Refer to figure 26G. Fore and Aft Fore and aft adjustments are provided by loosening the upper left hinge striker (body mounted). ROLLER A N D BRACKET ASSEMBLY IN A N D OUT ADJUSTMENT FRONT LATCH STRIKER UP A N D D O W N ADJUSTMENT Upper Left Hinge Striker This striker provides adjustment for fore and aft movement. Also, it acts as a stop for the hinge roller assembly. Lower Catch The lower catch, mounted on the lower front roller, holds the door in the full open position. The catch engages a striker installed at the rear of the lower roller channel. Reposition Door "Up" or "Down" 1. Partially open door and loosen front latch striker on pillar. 2. Remove upper left door hinge cover. 3. Loosen upper left hinge-to-door bolts. 4. Loosen rear lock striker and door wedge. 5. Loosen upper front roller bracket-to-door bolts. 6. Partially close door and align front edge of door up or down by loosening front lower hinge-to-door bolts. Torque bolts to specifications. 7. Align rear edge of door up or down and tighten upper left hinge-to-door bolts. Torque bolts to specifications. 8. Position upper front roller in center of track and tighten roller bracket to door. Torque bolts to specifications. See figure 27G. 9. Adjust front and rear strikers as outlined under "Front and Rear Striker Adjustment". Reposition Door "Fore" or "Aft" ROLLER A N D BRACKET ASSEMBLY Fig. 26G—Sliding Door Front Adjustments 1. Partially open door and remove front latch striker and rear lock striker. 2. Loosen upper left hinge stop (on body). 3. Move door assembly forward or rearward as necessary. 4. Reinstall front and rear strikers and adjust as outlined under "F ront and Rear Striker Adjustment". LIGHT DUTY TRUCK SERVICE MANUAL 1B-42 BODY 5. Adjust upper left hinge stop as outlined under "U pper Left Hinge Latch and Stop Adjustment". Reposition Door "In " or "Out" 1. 2. 3. 4. 5. 6. 7. 8. Loosen front latch striker. Loosen upper front roller from its bracket. Loosen lower front roller bracket to arm bolts. Adjust front of door in or out and tighten bolts. Torque to specifications. Adjust rear of door in or out by adjusting rear lock striker. Adjust front upper roller so it travels in the center of its channel. See figure 27G. Adjust front and rear strikers as outlined under "Front and Rear Striker Adjustment". Adjust upper left hinge stop as outlined under "U pper Left Hinge Latch and Stop Adjustment". Front and Rear Striker Adjustment Front Striker 1. Loosen front striker. 2. Visually align latch to striker relationship and adjust if necessary. See figure 28G. 3. Slide door forward slowly. Guide on door (just above latch) must fit snugly within rubber lined opening on striker assembly. 4. Assure that latch catches fully. Add or delete shims behind striker as necessary. Rear Striker NOTE: The rear striker is adjustable vertically and transversly after loosening with Tool J-23457. Also, loosen door wedge located below striker. Fore and aft adjustment is obtained by adding or deleting washers between the bolt and body pillar. The striker must enter the lock freely. Up and Down (Vertical) Adjustment 1. Loosen striker with Tool J-23457. 2. Center striker vertically to door striker opening. 3. Adjust laterally to match door outer panel and body side outer surfaces. 4. Adjust door wedge by aligning wedge on door with its striker on pillar. Centerline of wedge must enter centerline of striker opening on pillar. Fore and Aft (Transverse) Adjustment 5. Smear grease or paint on striker. 6. Gently push door in until lock just contacts striker enough to make an impression in the grease. 7. Open door and measure distance from rear of striker head to the impression. Distance should be .20" minimum to .30" maximum. Refer to figure 29G. 8. Adjust striker by adding or deleting washers between striker and pillar. 9. Torque striker and wedge to specifications. Upper Left Door Hinge Striker and Latch Adjustment (On Body) CAUTION: If door has been removed and is being reinstalled adjust striker to lower hinge lever before closing door. Failure to do so may cause possible lever breakage. I. Adjust hinge lower lever to striker contact by LIGHT DUTY TRUCK SERVICE MANUAL BODY 1B-43 adding or deleting shims between the striker and body to provide at least .10 inch of lever contact. Also, striker must be positioned at least .06" above bottom of striker tang. See figure 30G. 2. Adjust fore and aft (centering door in opening) by moving striker horizontally. 3. If necessary to shim roller away from guide, shims are added between the nylon block and hinge and between roller and hinge. They must be installed in pairs. For example, if one shim is added behind the nylon block another must be added behind the roller. See figure 31G. Lower Catch Adjustment 1. Loosen screws retaining catch rod bracket to door. See figure 32G. 2. Adjust catch to striker engagement by sliding bracket laterally. Catch should fully engage striker. Fig. 30G—Hinge Lower Lever to Striker Adjustment Fig. 32G—Adjusting Lower Catch Fig. 31G—Shimming Hinge Roller LIGHT DUTY TRUCK SERVICE MANUAL 1 B -44 BODY REAR DOORS REAR DOOR HINGE STRAP REAR DOOR REMOTE CONTROL Replacement Removal 1. Remove strap release pin. See figure 33G. 2. Remove screws retaining strap to door. 3. Install strap to door. Torque retaining screws to specifications. REAR DOOR HINGE Removal 1. Open door. Support door so that when hinge screws are removed door weight will be on support. 2. Remove hinge strap release pin. 3. Remove hinge-to-door bolts and remove door assembly. 4. Remove hinge-to-body bolts and hinge. Installation 1. Install grommet into door hinge opening (if removed). 2. Install hinge into door. Snug bolts. 3. Install grommet into body hinge opening (if removed). 4. Install hinge into body opening and install bolts. Snug bolts. 5. Install hinge strap and its retaining pin. 6. Adjust door and torque hinge bolts to specifications. 1. Remove trim panel. 2. Disengage upper and lower latch rods from control by removing retaining clips. See figure 34G. 3. Remove remote control by removing its retaining screws. Installation 1. Install remote control. Torque screws to specifications. 2. Reinstall upper and lower latch rods to control. 3. Install trim panel. REAR DOOR UPPER OR LOWER LATCHES AND/OR LATCH RODS Removal 1. Remove trim panel. 2. Disengage rod from remote control assembly. See figure 34G. 3. Remove latch retaining screws and withdraw latch and control rod. 4. Remove spring clip retaining rod to latch. Installation 1. Install latch rod to latch. Fig. 34G—Remote Control and Latch LIGHT DUTY TRUCK SERVICE MANUAL BODY NOTE: When reinstalling the lower latch rod to control, the short straight section attaches to the latch. 2. Install latch and rod assembly into door and connect rod to remote control. 3. Install latch retaining screws and torque to specifications. 4. Adjust latch to strikers. REAR DOOR OUTSIDE HANDLE Removal 1. Remove trim panel. 2. Remove door handle retaining screws, handle and gaskets. See figure 35G. Installation 1. Apply grease to remote control where handle plunger makes contact. 2. Install handle and gaskets. Torque screws to specifications. 3. Install trim panel. REAR DOOR LOCK CYLINDER Removal 1. Remove trim panel. 2. Remove remote control. 3. Remove lock cylinder retainer and lock cylinder. Installation 1. Install lock cylinder and retainer. 2. Install remote control. Torque specifications. 3. Install trim panel. screws Fig. 35G—Outside Handle and Lock Cylinder to 1B-45 REAR DOOR GLASS AND WEATHERSTRIP Removal and installation procedures are the same as for the stationary body side windows. Refer to those procedures for rear door glass and weatherstrip replacement. REAR DOOR ADJUSTMENTS 1. 2. 3. 4. NOTE: Door adjustments are provided by slotted holes, at hinge attachment, in body and door. Remove or loosen door strikers and wedges. Loosen door hinge bolts and adjust door to provide equal clearances between body and door around perimeter of door. Adjust door in and out so that door panel is flush with body. Install door strikers and wedges and adjust as outlined under door striker adjustment. REAR DOOR STRIKER ADJUSTMENT CAUTION: See CAUTION on page 1 of this section regarding Rear Door Strikerfasteners. 1. Adjust striker by adding or deleting shims as necessary to obtain dimension as shown in figure 36G. This dimension can be checked by applying grease to the latch and slowly closing door until striker fully engages latch. Then open door and measure from grease impression to bottom of latch slot. Torque to specifications. 2. Adjust door wedge by adding or deleting shims as necessary so that wedge contacts bumper on door when door is closed. See figure 37G. Fig. 36G—Rear Door Strikers and Wedges LIGHT DUTY TRUCK SERVICE MANUAL I B - 4 6 BODY Fig. 37G—Door Wedge Adjustment SEATS CAUTION: See CAUTION on page 1 of this section regarding fasteners used on seats and seat belts. DRIVERS SEAT Seat Adjuster Installation 1. Install seat riser to floor. Torque bolts to specifications. 2. Install seat and torque bolts to specifications. Removal 1. Remove seat by removing bolts securing seat to seat riser. 2. Remove seat belt from adjuster. 3. Remove adjuster from seat. See figure 38G. Installation 1. Install seat adjuster to seat. Torque bolts to specifications. 2. Install seat belt. Torque retaining nut to specifications. CAUTION: weld nut. Shoulder of bolt must bottom on 3. Install seat onto seat riser, and torque screws to specifications. SEAT RISER Removal 1. Remove seat and adjusters as an assembly by removing bolts securing seat to riser. 2. Remove bolts securing seat riser to floor. LIGHT DUTY TRUCK SERVICE MANUAL BODY PASSENGER SEAT—MOUNTING BRACKETS Removal 1. Remove seat and brackets from seat riser. See figure 39G. 2. Remove brackets from seat. Installation 1. Install brackets to seat. Torque to specifications. 2. Install seat to seat riser. Torque to specifications. SEAT RISER Removal 1. Remove seat and mounting bracket as an assembly. 2. Remove riser from floor. 1 B-47 installation 1. Attach leg and support assembly to seat. Torque to specifications. 2. Attach seat belts. Torque bolts to specifications. CAUTION: weld nut. Shoulder of Bolt must bottom on 3. Attach seat to floor. Torque bolts to specifications. CARE AND CLEANING OF SEATS Instructions on care and cleaning of interior soft trim may be found in "C-K M odels-Seats", earlier in this section. Installation 1. Install riser to floor. Torque bolts to specifications. 2. Install seat to riser. Torque bolts to specifications. BENCH SEATS—FIGS. 40G, 41G Seat and/or Seat Support Removal 1. Remove bolts securing seat legs to floor. 2. Remove seat assembly. NOTE: After removing the rear seat, reinstall the bolts into the anchor nuts to seal the openings from dirt and foreign matter. 3. Remove legs and support assembly. Fig. 40G—Bench Seat 2nd or 3rd Position Fig. 39G—Passenger Seat Fig. 41G—Bench Seat 4th Position LIGHT DUTY TRUCK SERVICE MANUAL 1B-48 BODY SPECIAL TOOLS mmmmmr 12. 3. 4. 5. J-2189 J-22585 J-22577 J-7797 J-23457 Weatherstrip Tool Set Front Door Hinge, Bolt Wrench Windshield Checking Blocks Door Handle Clip Remover Door Striker Bolt Remover and Installer Fig. IT —Special Tools LIGHT DUTY TRUCK SERVICE MANUAL SECTION 2 FRAME INDEX .2-1 .2-1 .2-1 .2-2 .2-2 Description 10-30 Series Truck M aintenance................................... Frame Alignment..................... Horizontal C heck................... Vertical Check......................... Frame Repair......................................................................2-2 W elding...............................................................................2-2 Bolting..................................................................................2-2 Underbody A lignm ent.....................................................2-2 DESCRIPTION Light duty 10-30 Series frames are of the ladder channel section riveted type. Figure 1 illustrates typical light duty frames with crossmembers, body mounts and suspension attaching brackets. This section also included general instructions for checking frame alignment and recommendations on frame repair. The G-Van frame side rails, cross sills and outriggers are part of the underbody assembly which is a welded unit. Misalignment of the underbody can affect door opening fits and also influence the suspension system, causing suspension misalignment. It is essential, therefore, that underbody alignment be exact to within - 1/16" of the specified dimensions. M AINTENANCE UNDERBODY AND FRAME INSPECTION UNDERBODY INSPECTION Raise the vehicle on a hoist (preferably a twin-post type). Check for obvious floor pan deterioration. Check for loose dirt and rust around the inside of the floor pan reinforcement member access holes. This is the first indication that corrosion may exist in hidden areas, and that repairs might be required before the final cleaning and protective treatment is performed. Using a chisel, ensure that the drain provisions in the floor pan reinforcement members are open. There are drain holes in the body side panels also. These holes can be opened by using a punch or drift. The side panel drain holes are in the rear section of the rocker panels, and in the lower rear quarter panels. must be used for vertical checks, opposite and alternate sides for horizontal checks. Vehicle Preparation Points to remember when preparing vehicle for frame checking: 1. Place vehicle on a level surface. 2. Inspect damaged areas for obvious frame misalign­ ment to eliminate unnecessary measuring. 3. Support vehicle so that frame sidemembers are parallel to the ground. Tramming Sequence 1. Dimensions to bolts and/or holes in frame extend to dead center of the hole or bolt. FRAME ALIGNMENT Horizontal frame checking can be made with tramming gauges applied directly to the frame or by transferring selected points of measurement from the frame to the floor by means of a plum bob and using the floor layout for measuring. Figure 2 may be used as a general guide in the selection of checking points; however, selection of these points is arbitrary depending on accessibility and convenience. An important point to remember is that for each point selected on one side of the frame, a corresponding point on the opposite side of the frame Fig. 1 - 1 0 - 3 0 Series Frame—Typical LIGHT DUTY TRUCK SERVICE MANUAL 2-2 FRAME 2. Dimensions must be within 3/16". 3. If a tram bar is used, for horizontal alignment "X " - check from opposite and alternate reference points AA, BB and CC, as illustrated by the lines in Figure 2. Error will result if a tram bar is not level and centered at the reference points. 4. Obtain vertical dimensions and compare the differences between these dimensions with the dimensions as shown in chart. Horizontal Check 1. Measure frame width at front and rear. If widths correspond to specifications, draw centerline full length of vehicle halfway between lines indicating front and rear widths. If frame widths are not correct, layout centerline as shown in Step 4. 2. Measure distance from centerline to corresponding points on each side of frame layout over entire length. Opposite side measurement should corre­ spond within 3/16". 3. Measure diagonals marked A, B and C. If the lengths of intersecting diagonals are equal and these diagonals intersect the centerline, frame area included between these points of measurement may be considered in alignment. 4. If front or rear end of frame is damaged and width is no longer within limits, frame centerline may be drawn through the intersection of any two previously drawn pairs of equal, intersecting diagonals. Vertical Check Vertical dimensions are checked with a tramming bar from indicated points on the frame (figs. 3 and 4). For example, if the tram bar is set at point B with a vertical pointer length of 8-1/4 inches, and at point E with a vertical pointer length of 5-1/4 inches (a height difference of 3 inches), the tram bar should be parallel with the frame. If the area is twisted or misaligned in any way, tram bar will not be parallel. Placing the tram bar vertical pointers on opposite sides of the frame side rail is preferable in that frame twist will show up during this vertical check. Figures 3 and 4 show typical checking points, with dimensions for various frames shown in the chart below. Frame Repair Welding Before welding up a crack in frame, a hole should be drilled at the starting point of the crack to prevent spreading. Widen V groove crack to allow complete weld penetration. NOTE: Do not weld into corners of frame or along edges of side rail flanges. Welding at these points will tend to weaken the frame and encourage new cracks. Bolting Wherever rivets or failed bolts are replaced, bolt hole must be as near the O.D. of the bolt as possible to prevent bolt from working and wearing. Drill out and line ream hole (or holes) to the bolt O.D. UNDERBODY ALIGNMENT One method of determining the alignment of the underbody is with a tram gauge which should be sufficiently felxible to obtain all necessary measurements up to three quarters the length of the vehicle. A good tramming tool is essential for analyzing and determining the extent of collision m isalignm ent present in underbody construction. MEASURING (Fig. 5) To measure the distance accurately between any two reference points on the underbody, two specifications are required. 1. The horizontal dimension between the two points to be trammed. 2. The vertical dimension from the datum line to the points to be trammed. The tram bar should be on a parallel to that of the body plane. The exception to this would be when one of the reference locations is included in the misaligned area; then the parallel plane between the body and the tram bar may not prevail. After completion of the repairs, the tram gauge should be set at the specified dimension to check the accuracy of the repair operation. EXCESSIVE BODY DAMAGE If damage is so extensive that key locations are not suitable as reference points, repair operations should always begin with the underbody area. All other components should be aligned progressively from this area. Unlike the conventional type of frame design, the unitized type of body construction seldom develops the two conditions of "twist" and "diam ond" in the underbody area as a result of front or rear end collisions, therefore, there usually is an undam aged area suitable as a beginning reference point. LIGHT DUTY TRUCK SERVICE MANUAL k LIGHT DUTY FRAME TRUCK SERVICE 2-3 M ANUAL Fig. 2- Frame Horizontal Checking - Typical 2 -4 FRAME Fig 3--KA Frame Model A B C D CA107 9 - 3 /8 1 1 -7 /8 1 3 -3 /8 16 CA109 9 - 3 /8 1 1 -7 /8 1 3 -3 /8 16 CA209 9 - 3 / 8 1 1 -7 /8 1 3 - 3 /8 16 LCA210 310 9 - 3 /8 1 1 -7 /8 1 2 -3 /4 16 CA314 9 - 3 /8 1 1 -7 /8 1 2 -3 /4 16 KA107 9 - 3 /8 1 1 -7 /8 1 3 -1 /8 16 E F G 1 0 -1 /4 7 - 1 /8 10 10 -1 /4 7 - 1 /8 10 1 0 -1 /4 7 -1 /8 10 7 -1 /2 10 H I J 1 3 - 3 /8 1 5 -1 /2 12 1 3 -3 /8 1 5 -1 /2 12 1 3 -3 /8 15 -1 /2 12 L M 11 -3 /8 1 3 - 3 /8 43 11 -3 /8 1 3 -3 /8 43 1 1 -3 /8 1 3 -3 /8 43 N 92 104 104 O P Q R S 1 2 7 -3 /4 14 134 14 134 14 1 6 -7 /8 1 9 -1 /8 1 6 - 7 /8 16 -7 /8 19 -1 /8 1 6 - 7 /8 1 6 -7 /8 1 9 - 1 /8 1 6 - 7 /8 9 0 - 3 /8 1 58-1/4 14 1 6 -7 /8 1 6 -7 /8 1 6 - 7 /8 90 92 1 80-1/2 14 127 -3 /4 14 16 -7 /8 16 -7 /8 1 6 -7 /8 1 6 - 7 /8 1 6 - 7 /8 1 6 -7 /8 104 139 -3 /4 14 1 6 - 7 /8 1 6 -7 /8 1 6 -7 /8 79 114 -5 /8 14 1 6 -7 /8 1 9 -1 /8 1 6 -7 /8 7 -1 /2 6 - 1 /8 10 1 0 - 1 /4 7 - 1 /8 10 1 0 -1 /4 1 3 - 3 /8 49 8 - 3 /8 17 -1 /8 1 4 -1 /4 1 4 -1 /4 1 7 -1 /8 49 1 3 - 3 /8 1 4 -5 /8 12 1 0 -3 /4 1 3 -3 /8 43 KA109 ^ 2 0 9 9 - 3 /8 11 -7 /8 1 3 - 1 /8 16 PA100 9 - 3 /8 1 1 -7 /8 1 3 -3 /8 16 1 0 -1 /4 7 - 1 /8 10 1 3 -3 /8 1 5 -1 /2 12 1 0 -3 /4 1 3 -3 /8 43 1 0 -1 /4 7 - 1 /8 10 1 3 -3 /8 1 5-1/2 12 1 0 -3 /4 1 3 -3 /8 43 PA208 308 9 - 3 /8 1 1 -7 /8 1 2 -3 /4 16 1 3 -1 /2 7 -1 /2 10 10 1 5 -1 /8 1 1 -5 /8 1 1 -1 /4 1 3 - 3 /8 3 1 - 5 /8 9 - 3 /8 1 1 -3 /8 1 2 -3 /4 16 1 3 -1 /2 7 -1 /2 10 10 1 5 -1 /8 1 1 -5 /8 1 1 -1 /4 1 3 -3 /8 3 1 - 1 /2 1 07-3/4 183 -3 /4 1 6 - 7 /8 1 6 -7 /8 1 6 -7 /8 1 6 -7 /8 9 -3 /8 1 1 -7 /8 1 2 -3 /4 16 9 - 3 /8 1 1 -7 /8 1 3 - 3 /8 16 9 - 3 /8 1 1 -7 /8 1 3 -1 /8 16 1 3 -1 /2 7 -1 /2 10 1 0 -1 /4 7 - 1 /8 10 1 0 -1 /4 7 - 1 /8 10 10 1 5 -1 /8 1 1 -5 /8 1 1 -1 /4 1 3 -3 /8 3 1 - 1 /2 1 31-3/4 2 0 7 -3 /4 1 6 - 7 /8 1 6 -7 /8 1 6 -7 /8 1 6 -7 /8 1 3 -3 /8 1 5 -1 /2 12 1 3 -3 /8 43 81 14 1 6 -7 /8 1 9 -1 /8 1 6 -7 /8 1 3 -3 /8 1 4 -5 /8 12 1 0 -3 /4 1 3 -3 /8 43 81 116 -3 /4 14 1 6 -7 /8 1 6 -7 /8 1 6 -7 /8 PA210 310 PA314 CA105 KA105 PE 31132 9 -1 /4 137) i - 10 K 1 5 -1 /8 9 9 - 3 /4 175 -3 /4 1 6 - 7 /8 1 6 -7 /8 1 6 -7 /8 1 6 -7 /8 1 1 -5 /8 12-5/8 15-3/4 1 3 -3 /8 7 - 3 /8 9 -3 /4 9 -3 /4 15 11-1/2 1 1 -1 /8 13-1/8 3 1 - 1 /2 111-3/4 187-3/4 14 1 6 -7/8 1 6-7/8 16-7/8 PE 31432 9 -1 /4 11-5/8 12-5/8 15-3/4 1 3-3/8 7 - 3 /8 (157) 9 -3 /4 9 -3 /4 15 11-1/2 1 1-1/8 1 3 -1 /8 3 1 - 1 /2 131-3/4 2 0 7 -3 /4 14 1 6 -7/8 1 6-7/8 1 6-7/8 A LIGHT DUTY TRUCK SERVICE MANUAL LIGHT DUTY SERVICE FRAME TRUCK 2-5 M ANUAL Fig. 4-10-30 Series Truck Frame Fig. 5--Underbody Reference Points • G-Van 2-6 FRAME LIGHT DUTY TRUCK SERVICE MANUAL SECTION 3 FRONT SUSPENSION The following caution applies to one or more steps in the assembly procedure of components in this portion of the manual as indicated at appropriate locations by the terminology “See Caution on page 1 of this Section” . CAUTION THIS FASTENER IS A N IMPORTANT A TTACHING PART IN THAT IT COULD AFFECT THE P E R F OR MA NC E OF VITAL COMPONENTS A N D SYSTEMS, AND/OR CO ULD RESULT IN MAJOR REPAIR EXPENSE. IT M U S T BE REPLACED WITH ONE OF THE SA ME PART N U M B E R OF WITH A N EQUIVALENT PART IF REPLAC EM EN T B EC O M E S NECESSARY. D O N O T USE A REP LA CE ME NT PART OF LESSER QUALITY OR SUBSTITUTE DESIGN. TORQUE VALUES M U S T BE USED AS SPECIFIED DURING REASSEMBLY TO ASSURE PROPER RETENTION OF THIS PART. CONTENTS OF THIS SECTION Front Suspension - 2 Wheel Drive........................................................ 3-2 Front Suspension - 4 Wheel Drive........................................................ 3-38 INDEX General Description................................................................ Theory of Operation............................................................. K-Series Suspension............................................................. Independent Suspension...................................................... Steering Knuckle and Wheel Spindle.............................. Control Arms..................................................................... Ball Joints........................................................................... Coil Springs......................................................................... Leaf Springs........................................................................ Shock Absorbers................................................................ Wheel Alignment.................................................................... Front Suspension Geometry............................................... Caster.................................................................................. Camber................................................................................ Toe-In.................................................................................. Toe-Out on Turns............................................................... Steering Axis Inclination.................................................. Preliminary Adjustments.................................................. Maintenance and Adjustments.............................................. Wheel Bearing—Check Adjustment.................................... Front Alignment Description............................................. Camber................................................................................. Caster................................................................................... How to Determine Caster................................................. Tow-In................................................................................ Definitions.......................................................................... 3-2 34 3-4 34 3-5 3-5 3-5 3-5 3-5 3-5 3-9 3-9 3-9 3-10 3-10 3-10 3-10 3-10 3-12 3-12 3-12 3-13 3-13 3-13 3-14 3-14 Component Parts Replacement............................................ Wheel Hubs and Bearings..................................................... Removal.............................................................................. Inspection........................................................................... Repairs................................................................................. Bearing Cups—Replace.................................................... Wheel Stud Replacement................................................ Installation............. ............................................................ Shock Absorbers.................................................................. Removal............................................................................... Installation.......................................................................... Stabilizer Bar......................................................................... Coil Spring............................................................................ Leaf Spring - K Series.......................................................... Upper Control Arm Pivot Shaft and Bushings (Steel)........................................................ Lower Control Arm Pivot Shaft and Bushings (Steel)........................................................ Upper Control Arm Assembly............................................ Rubber Bushings................................................................ Lower Control Arm Assembly............................................ Rubber Bushings................................................................ Ball Joint Service.................................................................. Inspection........................................................................... Replacement...................................................................... 3-16 3-16 3-16 3-16 3-17 3-17 3-17 3-17 3-17 3-17 3-17 3-17 3-18 3-19 3-19 3-20 3-21 3-21 3-22 3-22 3-22 3-23 3-24 LIGHT DUTY TRUCK SERVICE MANUAL 3-2 FRONT SU S PEN SIO N Steering Knuckle/Steering Arm......................................... .3-25 Removal...............................................................................3-26 Installation...........................................................................3-26 Crossmember and Suspension Unit.....................................3-26 Removal...............................................................................3-26 Installation...........................................................................3-26 Diagnosis................................................................................. .3-27 Front Suspension..................................................................3-27 Ball Joint............................................................................... .3-30 Shock Absorber.................................................................... .3-31 On Vehicle...........................................................................3-31 Bench....................................................................................3-32 Bearings and Races................................................................3-33 Special Tools............................................................................3-37 GENERAL DESCRIPTION The GM 10-30 series Truck line except K Series incorporates an independent coil spring front suspension system. (Figs. 1 and 2). The control arms are of unequal length (S.L.A. Type) and is used on all 10, 20 and 30 series vehicles without 4 wheel drive. This suspension system consists of upper and lower control arms pivoting on steel threaded or rubber bushings on upper and lower control arm shafts. The lower control arms are attached to the crossmember with U-bolts. The upper control arms are attached to a frame bracket. These control arms are connected to the steering knuckle through pivoting ball joints. A coil spring is located between the lower control arm and a formed seat in the suspension crossmember, thus the lower control arm is the load carrying member. Double acting shock absorbers are also attached to the lower control arms and connect with the frame to the rear on the upper end. The front wheel bearings are tapered roller type and are used on all models. Fig. 1—Front Suspension - G-30—Typical LIGHT DUTY TRUCK SERVICE MANUAL DUTY C 10 TRUCK P 10-30 FRONT SUSPENSION LIGHT G 10-20 MANUAL 3-3 SERVICE Fig. 2—Front Suspension C -P-K Typical 3-4 FRONT SU SPEN SION Fig. 3—Wheel Hubs and Bearings THEORY OF OPERATION The front suspension can be divided into two types, the CONVENTIONAL, such as used on General Motors K Series trucks, or the INDEPENDENT, such as used on all other General Motors light duty trucks. The description of caster, camber, toe-in, toe-out — on turns and steering axis or kingpin inclination is the same for conventional or independent types of suspensions. The description of the control arms and related parts as well as adjustment methods is intended for the independent front suspension only. K-SERIES SUSPENSION The K-Series suspension system, as described here, refers to leaf springs and a tubular axle. The tubular axle attached to the vehicle through the leaf springs that are secured to the axle on a spring pad. The spring ends, called eyes, are attached to the vehicle frame through hangers. The steering knuckle and wheel spindle attach to the axle ends through ball joints. Caster can not be changed on this particular vehicle and is designed and built into the suspension. The camber setting is built into the axle and cannot be changed. Toe-in is changed in a manner similar to all other G.M. vehicles. INDEPENDENT SUSPENSION The independent suspension system, as described here, refers to coil springs and control arms. Control arms and coil springs are covered later in this section. The term “independent suspension” describes a method of supporting the chassis on the wheels without the use of rigid axles. When a pair of wheels are mounted to a LIGHT DUTY TRUCK SERVICE MANUAL FRONT S U S PEN SIO N rigid axle and one of them passes over a bump the axle executes an angular movement in the (front view) vertical plane and both of the wheels perform movements of the same angular magnitude. With independent suspension the movement of the two wheels are not interdependent; one wheel does not force the other wheel to deflect. W ith the independent suspension, the steering knuckle and wheel spindle are connected to the vehicle through ball joints and control arms. Steering Knuckle and Wheel Spindle The wheel spindle is the unit that carries the hub and bearing assembly with the aid of the knuckle assembly. The hub assembly has also become the brake disc assembly. As pointed out under conventional and independent suspensions, the wheel spindle is connected to the vehicle through a steering knuckle and ball joints. The spindle carries the entire wheel load. In order to reduce friction, on the sprindle and wheel hub, wheel bearings are provided. The design and placement of these bearings on the spindle is such that the center plane of the wheel is closer to the center plane of the wheel is closer to the center plane of the inner bearing than the outer bearing. The reason for this is to bring the wheel as close as possible to the knuckle axis. For this same reason the inner bearing will usually be larger than the outer bearing. Wheel bearing service is covered in detail elsewhere in this section. Coil Spring Coil springs are just what their name implies. They are coils of steel wire. A coil spring can be installed on the front suspension or rear suspension of a vehicle with the method of attachment varying to suit the application. On the front suspension the lower control arm provides the seat for the coil spring with the upper end housed within the frame crossmember. The function of the coil spring is the same as the leaf spring, that is, to cushion shock imparted to the wheel by road roughness or obstacles. Since a coil spring provides little directional stability control arms are provided and connect between the vehicles frame and axle assembly. Shock absorbers are used with the springs and are covered elsewhere in this section. 3-5 bolted to the steering knuckle. This arrangement allows the front wheel suspension to move up and down with respect to the vehicle frame (spring action) and swing at various angles for vehicle steering. Control Arm Bushings Two different types of bushings are used in 1973 independent suspension trucks. G-10 and 20 series and C-10 series trucks use new rubber bushings for both upper and lower control arms. All P series, C-20/30 and G-30 use steel bushed upper and lower control arms. The rubber bushings provide a better more enjoyable ride, while the steel bushings are needed for heavy duty applications. BALL JOINTS (Fig. 5) Ball joints are used to connect the control arms to the steering knuckle. The upper ball joint is usually riveted to the control arm and connects to the steering knuckle through a tapered stud that is held in position with a castellated nut and a cotter pin. The lower ball joint is usually pressed into the control arm and connects to the steering knuckle through a tapered stud that is held in position with a castellated nut and a cotter pin. A ball joint stud, nut and rubber seal is about all your eye will see of the ball joint assembly. The function of the rubber seal is to retain the lubricating grease, which it contains, and to protect this grease from contam ina­ tion by water or foreign material (sand, dirt, etc.). If this seal is damaged (torn or pulled off its metal retainer) the ball joint should be replaced. Check the Service procedure for inspection and replacement of a ball joint suspected of being in need of replacement. NOTE: Grease fittings on ball joints should be wiped clean before applying grease to the joint. SHOCK ABSORBERS Shock absorbers are hydraulic devices that help to control the up-and-down and rolling motion of a vehicle SHORT ARM BALL JOINT CONTROL ARMS (Independent Suspension) The front control arms are said to be the SLA type (Short and Long Arm). The control arms attach to the vehicle with bolts at their inner pivot points and to the steering knuckle (which is part of the front wheel spindle) at their outer points. The outer attachment is made through ball joints secured to the control arms and Fig. 4—Control Arms LIGHT DUTY TRUCK SERVICE MANUAL 3-6 FRONT SU SPEN SION BALL JOINT ASSEMBLY UPPER MOUNT SEAL COVER SEAL SEAL SPRING ROD GUIDE CYLINDER TUBE REBOUND SPRING PISTON NUT CYLINDER END BASE CUP Fig. 5—Ball Joints-Typical body while at the same time controlling wheel and axle motions. The vehicle’s springs support the body, but shock absorbers work with the springs to control movements of the body, wheel, and axle for smooth driving. This is accomplished by changing the movements of the spring (kinetic energy) into heat energy. Therefore, a shock absorber may be considered as a damper to control the energy stored up by the springs under load. COMPRESSION VALVE CAGE LOWER MOUNT RELIEF VALVE Fig. 6—Major Components of a Shock Absorber C O M PR ES S IO N FORC E t Operation A shock absorber is sometimes compared to a water pistol. Of course, there are many steps between a water pistol and a shock absorber, but both are damping devices and both use the same principle—they force an incompressible liquid through small openings. There are usually four shock absorbers on a vehicle; one located near each wheel. They are direct-acting because of their direct connection between the vehicle frame (body) and the axle (or wheel mounting member). They are also double-acting because they control motion in both directions of the suspension travel. Up movements of the body are termed rebound and down movements, compression. The compression movement of the shock absorber causes the piston to move downward with respect to the cylinder tube (figure 7), transferring fluid from chamber B to chamber A. This is accomplished by fluid moving through the outer piston holes and unseating the piston intake valve. Since all the fluid in chamber B cannot pass into chamber A due to the volume of the piston rod, the fluid equivalent to the rod volume is discharged out of the compression valve into chamber C of the reservoir with a corresponding compression of the air in chamber D. Compression control is the combination of load due to the compression valve and of load due to the piston intake valve. The rapid movement of the fluid between the chambers during the rebound and compression strokes can cause FLUID (H YD R A U LIC ) A IR OR GAS FILLED CELL PISTON IN TA K E V A LV E B LO W -O FF V A LV E PISTON H OLES FLU ID (H YD R A U LIC ) HIGH VELO C ITY ORIFICE LO W V ELO C ITY ORIFICE BLOW O FF VA LV E B LOW O FF PORT Fig. 7—Shock Absorber Compression Schematic aeration or foaming of the fluid (aeration is the mixing of free air and the shock fluid). W hen aeration occurs, the shock develops lag (piston moving through an air pocket which offers no resistance). Two means of eliminating aeration are utilized. One is a spiral groove reservoir tube, Figure 8, which breaks up the air bubbles in the fluid. The other is a gas filled cell, Figure 9, which replaces the free air in a shock absorber. LIGHT DUTY TRUCK SERVICE MANUAL FRONT S U S P E N S IO N This cell, in the reservoir, acts the same as an air chamber, expanding and contracting to compensate for the volume of the piston rod. But since it is a gas filled cell, there is no free air to mix with the fluid; thus, aeration is eliminated. A rebound or extension stroke, Figure 10, will cause the pressure in chamber B to fall below that in chamber C. As a result, the compression valve will unseat and allow fluid to flow from chamber C into chamber B. Chamber D contains air which expands to compensate for the piston rod volume being removed. Simultaneously, fluid in chamber A will be transferred into chamber B through the inner piston holes and the rebound valve. Rebound control is determined by the piston rebound varying. Sometimes shock absorbers are used to limit the rebound travel of a suspension system. This type of usage is prim arily for front suspension systems and permits the rubber rebound bump stop to be omitted. Shock absorbers used in this manner have a different type of internal construction which controls the rebound stroke. This construction is called "rebound cut-off". On the rebound stroke, all fluid passing from chamber A to chamber B, see Figure 10, through the piston valving parts must first flow through the piston rod. The fluid flows through the piston rod by means of intersecting holes, one along the axis of the piston rod and the other perpendicular to it. As the shock absorber approaches the end of the rebound stroke, the passage in the piston rod enters the rod guide, gradually restricting the flow of the fluid. As the flow is restricted, the control of the shock absorber increases. W hen the passage is completely closed off the by rod guide, see Figure 11, a small amount of fluid is trapped in chamber A creating a hydraulic stop which limits the full rebound travel of the suspension system. As the piston moves, forcing fluid through calibrated orifices, pressure increases within the cylinder. This pressure acting against the effective area of the piston determines the resistance or control provided by the shock absorber. Low piston velocities create low pressures, whereas high piston velocities with the same orifice result in considerably higher pressures. For 3-7 Fig. 9—Gas Filled Cell Shock Absorber EXTEN SIO N FORCE CYLINDER TUBE Fig. 10—Shock Absorber Rebound Schematic SPIR A L-G R O O VE RESERVOIR Fig. 8—Spiral-Groove Shock Absorber example, body lean during a turn will result in low force in the shock absorber due to low piston velocity; while hitting a chuckhole at high speeds will generate high resistance forces. The system of valves and orifices in a shock absorber which is referred to as the “valving,” is composed of three .distinct stages, which generate rebound and compression resistance levels (control) dependent upon LIGHT DUTY TRUCK SERVICE MANUAL 3-8 FRONT SU SPEN SION EXTEN SIO N FORCE INTAKE VALVE SPRING COMPRESSION VALVE ASSY. HIGH SPEED ORIFICE ■*--------- VALVE CAGE VALVE STEM RESERVOIR BLOW OFF VALVE SPRING COM PRESSION LOW SPEED ORIFICE RETAINER WASHER CYLINDER END Fig. 11—Shock Absorber Rebound Cut Off Schematic Fig. 12—Compression Valve Parts shock absorber piston velocity. Figure 13 illustrates rebound valving, and Figure 12 illustrates compression valving. The three stages are described as follows. blow-off valve opens as soon as the pressure is great enough to unseat the valve, after which the low speed orifice ceases to have an appreciable effect. As the pressure of the fluid against the spring increases, the valve continues to open until it reaches its maximum lift. Low Speed Orifice (First Stage) Two low speed orifices control fluid passage during slow body or wheel motions. The low speed orifice for rebound consists of slots in the orifice disc of the rebound valve, Figure 13, whereas the low speed orifice for compression consists of depressions in the cylinder end of the compression valve, Figure 12. This stage has its major effect in controlling low speed body movements. A very small, low speed orifice will cause a harsh ride in which every bump will be felt, similar to driving with over-inflated tires. Blow-Off Valve (Second Stage) Two blow-off valves, Figures 12 and 13, control the fluid motion during intermediate body and/or wheel motion. Depending on direction of stroke, the spring-loaded High Speed Orifice (Third Stage) After the blow-off valve is completely open, further increases in control at even higher piston velocities is caused by restriction due to the high speed orifice. Basically, there are two high speed orifices. The high speed orifice on the rebound stroke is the holes in the inner ring of the piston, Fig. 14. The high speed orifice on the compression stroke is the hole in the compression valve cage, Figure 12, in combination with the slots in the outer ring of the piston. The high speed orifices are large enough not to affect flow through the low speed orifices or during the opening of the blow-off-valves, but will quickly increase the control under conditions such as wheel-hop, where high piston velocities are present. LIGHT DUTY TRUCK SERVICE MANUAL FRONT SU S PEN SIO N COMPRESSION SIDE 3-9 BACK WASHER INTAKE SPRING INTAKE VALVE DISC PISTON-HIGH SPEED ORIFICE TYPICAL REBOUND ORIFICE DISC REBOUND SPRING DISC REBOUND SIDE SPACING SPRING DISC LO W SPEED ORIFICE SPRING SEAT REBOUND SPRING PISTON ASSEMBLY PISTON NUT " ► i — BLOW-OFF VALVE Fig. 13—Piston Valving Parts Fig. 14—High Speed Orifices in Piston WHEEL ALIG NM ENT FRONT SUSPENSION GEOMETRY (FIG. 15) The term “front suspension geometry” refers to the angular relationships between the front wheels, the front suspension attaching parts and the ground. The angle of the knuckle (or steering axis inclination) away from the veritcal, the pointing in or “toe-in” of the front wheels, the tilt of the front wheels from vertical (when viewed from the front of the vehicle) and the tilt of the suspension members from vertical (when viewed from the side of the vehicle), - all these are involved in front suspension geometry. The various factors that enter into front-end geometry are covered here each one under its own heading. CASTER Caster is the tilting of the front steering axis either forward or backward from the vertical (when reviewed from the side of the vehicle). A backward tilt is said to be positive(-F) and a forward tilt is said to be negative (—). On the short and long arm type suspension you cannot see a caster angle without a special instrument, but you can understand that if you look straight down from the top of the upper control arm to the ground you would find that the ball joints do not line up (fore and aft) when a caster angle other than 0° is present. If you had a positive caster angle the lower ball joint would be slightly ahead (toward the front of the vehicle) of the upper ball joint center line. In short then: caster is the forward or backward tilt of the steering axis as viewed from a side elevation. Caster is designed into the front axle assembly on all K series vehicles and is nonadjustable. See caster copy under ADJUSTMENTS. LIGHT DUTY TRUCK SERVICE MANUAL 3 -1 0 FRONT SUSPENSION CAMBER Camber is the tilting of the front wheels from the vertical when viewed from the front of the vehicle. When the wheels tilt outward at the top, the camber is said to be positive ( + ). When the wheels tilt inward at the top, the camber is said to be negative (—). The amount of tilt is measured in degrees from the vertical and this measurement is called the camber angle. Camber is designed into the front axle assembly of all K series vehicles and is non-adjustable. See camber copy under ADJUSTMENTS. TOE-IN Toe-in is the turning in of the front wheels. The actual amount of toe-in is normally only a fraction of an inch. The purpose of a toe specification is to ensure parallel rolling of the front wheels. (Excessive toe-in or toe-out will cause tire wear) Toe-in also serves to offset the small deflections of the wheel support system which occurs when the vehicle is rolling forward. In other words, even when the wheels are set to toe-in slightly when the vehicle is standing still, they tend to roll parallel on the road when the vehicle is moving. See toe-in copy under ADJUSTMENTS. TOE-OUT ON TURNS (Fig. 16) Toe-out on turns refers to the difference in angles between the front wheels and the vehicle frame during turns. Since the inner wheel turns a smaller radius than the outer wheel, when rounding a curve, it must be at a sharper angle with respect to the vehicle frame. That is, the inner wheel must toe-out more than the outside wheel toes-in. This condition is desirable because it allows the front wheels to turn in a concentric circle. Note in fig. 16 that the right front wheel centerline (B) and the left front wheel centerline (C) intersect the centerline of the rear axle (A) at the same point (D). The 20° and 23° angles are not necessarily representative of any vehicle and are used here for theory only. If “Toe-Out on Turns” is found to be other than specified for a specific vehicle it might indicate that some front suspension part is bent and a visual inspection is necessary. The angle of the steering arms is the determining factor of toe-out on turns. If either arm is bent, toe-out on turns will be affected. This steering arm angle is not adjustable, so a bent arm must be replaced. Since it is unlikely that both arms will be bent, follow the procedure below to determine which, if either, arm is bent. Measurement Measure the distance between the suspected bent arm and a stationary point on the brake backing plate or splash shield, comparing it with the same measurement on the other arm. The angle of the steering arms must be the same for both arms. Toe-out on turns is not adjustable. STEERING AXIS INCLINATION (S.A.I.) FIG. 17 Steering axis inclination (form ally called kingpin inclination on conventional suspensions) is the inward slant (at the top) of the steering knuckle from the vertical. This inclination tends to reduce road shock on the steering system by allowing the steering systems centerline to intersect the tire centerline near the point where the tire contacts the road. The inward slant or inclination of the steering knuckle tends to keep the wheels straight ahead. The reason for this is as follows: When the front wheels are straight ahead the steering knuckle spindles are practically horizontal. As the wheels are turned away from the straight ahead the outer ends of the spindle tries to lower or get closer to the ground. However, because the spindles are fixed in the hub assembly they cannot get closer, or lower, to the ground. So the spindles force the steering knuckles to raise the front of the vehicle. After a turn is complete, and force applied to the steering wheel is released, the weight of the vehicle on the spindles tends to help the front wheels return to a straight ahead position. “Steering Axis Inclination” is a designed in angle and is non-adjustable. PRELIMINARY ADJUSTMENTS FIG. 19-21 Before making any adjustment affecting caster, camber or toe-in, the following checks and inspections should be made to insure correctness of alignment readings and alignment adjustments. 1. Check all tires for proper inflation pressures and approximately the same tread wear. 2. Check front wheel bearings for looseness (.001-.008 end play is correct) and adjust if necessary. 3. Check for looseness of ball joints, tie rod ends and steering relay rods, if excessive looseness is noted, it must be corrected before adjusting. 4. Check for run-out of wheels and tires. 5. Check vehicle trim heights; if out of specifications and a correction is to be made, the correction must be made before adjusting caster, camber or toe-in. NOTE: Good judgment should be exercised before replacing a spring when vehicle trim height is somewhat out of limits (± 3 /4 "). 6. Consideration must be given to excess loads, such as tool boxes. If this excess load is normally carried in the vehicle it should remain in the vehicle during alignment checks. 7. Consider the condition of the equipment being used to check alignment and follow the m anufacturer’s instructions. 8. Regardless of equipment used to check alignment the vehicle must be on a level surface both fore and aft and transversely. LIGHT DUTY TRUCK SERVICE MANUAL FR ON T S U S PEN SIO N 3-11 Fig. 16—Toe-out on Turns LIGHT DUTY TRUCK SERVICE MANUAL 3 12 FRONT SU SPEN SION LEFT HAND FRONT VIEW Fig. 17—Steering Axis Inclination MAINTENANCE A N D ADJUSTMENTS CAU TIO N : See CAUTION on page 1 of this section regarding the fasteners referred to in the maintenance and adjustment procedures below. WHEEL BEARINGS—CHECK ADJUSTMENT Tapered roller bearings are used on all series vehicles and they have a slightly loose feel when properly adjusted. This differs from ball bearings which may be pre-loaded without adverse effect. A design feature of front wheel taper roller bearings is that they must NEVER be pre-loaded. Damage can result by the steady thrust on roller ends which comes from preloading. 1. Raise car and support at front lower control arm. 2. Spin wheel to check for unusual noise. 3. If bearings are noisy or excessively loose, they should be cleaned and inspected prior to adjustment. NOTE: To check for loose bearings, grip the tire at the top and bottom and move the wheel assembly in and out on the spindle. CAUTIO N: Movement greater than .008" (.010" on K-Series) indicates a loose bearing. If necessary to inspect bearings, see REPLACE­ MENT OF BEARINGS. ADJUSTMENT 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Raise car and support at front lower control arm. Remove hub cap or wheel disc from wheel. Remove dust cap from hub. Remove cotter pin from spindle and spindle nut. Adjust bearing as shown in Fig. 18. Insert new cotter pin and bend ends against nut. Cut off extra length to ensure ends will not interfere with dust cap. Install dust cap on hub. Install hub cap or wheel disc. Lower vehicle to ground. Repeat this procedure for the other wheel. FRONT ALIGNMENT (Fig. 19) Satisfactory vehicle operation may occur over a wide LIGHT DUTY TRUCK SERVICE MANUAL FRONT SU S PEN SIO N 4. H A N D ' S N U G -U P ' THE NUT 3 -1 3 5. LO O S E N N U T UNTIL EITHER HOLE IN THE SPINDLE LINES UP W ITH A SLOT IN THE N U T -T H E N INSERT COTTER PIN. N O T E : UNDER N O C IR C U M STAN C ES IS THE B EAR IN G TO BE EVEN FINGER TIGHT. 3. BACK OFF N U T UNTIL JUST LO O SE ( 1 / 4 - 1 / 2 TURN) "S N U G -U P THE N UT TO FULLY SEAT BE A R IN G S— THIS O V E R C O M E S A N Y BURRS O N THREADS. 6. W H E N THE BEAR IN G IS PROPERLY ADJUSTED THERE WILL BE FROM . 0 0 1 - . 0 0 8 IN CHES END-PLAY (LO O S E N E S S ). Fig. 18—Wheel Bearing Adjustment range of front end wheel alignment settings. Neverthe­ less, should settings vary beyond certain tolerances, readjustment of alignment is advisable. The specifica­ tions stated in column 1 of the applicable vehicle chart in the specifications section of this manual should be used by owners, dealers and repairmen as guidelines in vehicle diagnosis either for repairs under the new vehicle warranty or for maintenance service at customer’s request. These specifications provide an acceptable allaround operating range in that they prevent abnormal tire wear caused by wheel alignment. Governmental Periodic Motor Vehicle Inspection pro­ grams usually include wheel alignment among items that are inspected. To provide useful information for such inspections, the specifications stated in column 2 of the aforesaid applicable chart are given and these are well within the range of safe vehicle operation. In the event the actual settings are beyond the specifications set forth in column 1 or 2 (whichever is applicable), or whenever for other reasons the alignment is being reset, Chevrolet recommends that the specifica­ tions given in column 3 of the aforesaid applicable chart be used. NOTE: A normal shim pack will leave at least two (2 ) threads of the bolt exposed beyond the nut. If two (2) threads cannot be obtained: Check for damaged control arms and related parts. Difference between front and rear shim packs must not exceed .30 inches. Front shim pack must be at least .24 inches. Caster (Fig. 20) All caster specifications are given assuming a frame angle of zero. Therefore, it will be necessary to know the angle of the frame (whether “up” in rear or “down” in rear) before a corrected caster reading can be determined. Camber and toe can be read “as is” from the alignment equipment. How to Determine Caster 1. With the vehicle on a level surface, determine the frame angle “B” in Fig. 20, using a bubble protractor or clinometer. 2. Draw yourself a graphic as in Fig. 20 that is representative of the frame angle (either “up” in rear or “down” in rear). 3. Determine the caster angle from the alignment equipment and draw a line that is representative of the caster reading. 4. To determine an “actual (corrected) caster reading” with various frame angles and caster readings one of the following rules applys. a. A “ DOWN IN REAR” frame angle must be SUBTRACTED from a POSITIVE caster reading. b. An “ UP IN REAR” frame angle must be ADDED to a POSITIVE caster reading. c. A “ DOWN IN REAR ” frame angle must be ADDED to a NEGATIVE caster reading. d. An “ UP IN REAR” frame angle must be SUBTRACTED from a NEGATIVE caster reading. 5. Add or subtract as necessary to arrive at the corrected caster angle. 6 . Measure dimension “A ” (bump stop bracket to frame) and check the specifications for that dimension. 7. Correct the actual caster angle, as arrived at in Step 4, as necessary to keep within the specifications by adding or subtracting shims from the front or rear bolt on the upper control arm shaft (fig. 21 ). Camber 1. Determine the camber angle from the alignment equipment. LIGHT DUTY TRUCK SERVICE MANUAL 3 -1 4 FRONT SU S PEN SIO N ~V!\ ../0 "0 r 15 16 O "\ i 17 18 o ,, 19 20 21 1 22 23 24 lOW' R.G. AXLE ONLY 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. J-21548 J-23690 J-23689 J-21128 J-21057 J-22804-1 J-5748 J-6627 J-8092 J-5853 J-8614-II J-2619 J-2222 J-24429 J-24433 T ru nnion Seal Installer A xle S haft Bearing Installer A xle S haft Bearing Remover A xle S haft Seal Installer Pinion O il Seal Installer Pinion Seal Gauge Plate Positraction Torque Measuring Adapter Wheel B o lt Remover Driver Handle Torque Wrench - Inch/Pound Companion Flange Holder Slide Hammer Wheel Bearing N ut Wrench A djusting N ut Wrench Pinion Rear Bearing Installer 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. J-24430 J-23322 J-24426 J-24432 J-24427 J-8608 J-24384 J-24428 J-24434 J-870 J-22380 J-22354 J-22281 J-8114 J-8093 D iffe re n tia l Side Bearing Installer Pinion Straddle Bearing Installer O uter Wheel Bearing Cup Tool Pinion Rear Bearing Cup Installer Inner Wheel Bearing Cup Installer Outer Wheel Bearing Cup Installer Pinion O il Seal Installer - Dana Wheel Hub O il Seal Installer Pinion O il Seal Installer - Chevrolet Wheel Bearing N u t Wrench T ru -A rc Pliers Wheel O il Seal Installer Pinion O il Seal Installer Wheel Bearing O uter Cup Installer Wheel Bearing Inner Cup Installer Fig. 83—Special Tools LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-1 SECTION 5 BRAKES The following caution applies to one or more steps in the assembly procedure of components in this portion of the manual as indicated at appropriate locations by the terminology "See Caution on page l of this section.". CAUTION: THIS FASTENER IS A N IMPORTANT ATTACHING PART IN THAT IT COU LD AFFECT THE PE RF O R M A N C E OF VITAL C O M P O N E N T S A N D SYSTEMS, AND/OR C OU LD RESULT IN M A J O R REPAIR EXPENSE. IT M U S T BE REPLACED WITH ON E OF THE S A M E PART N U M B E R OR WITH A N EQUIVALENT PART IF REP LA C E M E N T B E C O M E S NECESSA R Y. D O N O T USE A R E P L A C E M E N T PART OF LESSER QUALITY OR SUBSTITUTE DESIGN. TORQUE VALUES M U S T BE USED AS SPECIFIED DURING REASSE MB LY TO ASSURE PROPER RETENTION OF THIS PART. CONTENTS OF THIS SECTION Standard Brakes................................................................................. 5-1 Power Brakes........................................................................................ 5-60 Special Tools........................................................................................ 5-70 STANDARD BRAKES INDEX General Description............................................................ Master Cylinder.................................................................. Combination Valve........................................................... Disc Brakes Front.............................................................. Drum Brakes R ear............................................................ Theory of Operation.......................................................... Hydraulic System............................................................... Pressure and Force............................................................ Brake System Components............................................. Operation of Brake Mechanism.................................. Front Disc Brakes........................................................... Rear Drum Brakes......................................................... Maintenance and Adjustment.......................................... Brake Inspection................................................................. Hydraulic Brake Fluid..................................................... Bleeding Hydraulic System............................................. Pressure Bleeding............................................................. Manual Bleeding............................................................. Hydraulic Brake Lines and Tubing............................ Drum Brake Adjustment................................................. Brake Pedal Free Travel Adjustment........................ Stoplamp Switch Adjustment........................................ Brake Travel Warning Switch...................................... 5-2 5-2 5-2 5-2 5-2 5-4 5-4 5-5 5-5 5-10 5-11 5-12 5-15 5-15 5-16 5-16 5-16 5-17 5-18 5-21 5-22 5-22 5-22 Parking Brake Adjustment...............................................5-22 Parking Brake (Propeller Shaft) Adjustm ent......... ..5-23 Component Replacement and R ep air......................... ..5-24 Shoes and Linings—Rear Drum Brakes.................... ..5-24 Anchor Pin Replacement..................................................5-27 Wheel Cylinder.....................................................................5-27 Brake Drum Refinishing...................................................5-28 Shoe and Linings—Front Disc Brakes....................... ..5-29 Caliper Overhaul..................................................................5-31 Disc Refinishing...................................................................5-34 Master Cylinder....................................................................5-36 Master Cylinder Overhaul................................................5-36 Master Cylinder (with Frame Mounted Booster)... 5-38 Bench Bleeding Master Cylinder...................................5-39 Brake Combination Valve.................................................5-40 Brake Travel Warning Switch...................................... ..5-41 Brake Pedal-Service Brake..............................................5-42 Parking Brake Pedal........................................................ ..5-42 Parking Brake Cables...................................................... ..5-43 Parking Brake-Propeller S haft.................................... ..5-43 Rear Brakes—R.P.O. H-22................................................5-46 Diagnosis...................................................................................5-48 Inspection................................................................................5-48 Preliminary Checks..............................................................5-49 Road Testing....................................................................... ..5-49 LIGHT DUTY TRUCK SERVICE MANUAL 5-2 BRAKES GENERAL DESCRIPTION All vehicles are equipped with a dual hydraulic brake system. The split system consists basically of two separate brake systems. When a failure is encountered on either, the other is adequate to stop the vehicle. If one system is not functioning, it is normal for the brake pedal lash and pedal effort to substantially increase. This occurs because of the design of the master cylinder which incorporates an actuating piston for each system. When the rear system loses fluid, its piston will bottom against the front piston. When the front system loses fluid, its piston will bottom on the end of the master cylinder body. The pressure differential in one of the systems causes an uneven hydraulic pressure balance between the front and rear systems. The combination valve, near the master cylinder, (except RPO H22 vehicles) detects the loss of pressure and illuminates the brake alarm indicator light on the instrument panel. The pressure loss is felt at the brake pedal by an apparent lack of brakes for most of the brake travel and then, when failed chamber is bottomed, the pedal will harden. RPO H22 vehicles (with frame mounted vacuum over hydraulic boosters) have an electrical switch that senses pedal travel. This switch will illuminate the lamp on the instrument panel whenever the brake pedal travel is in excess of 5.10 inches. If a vehicle displays these symptoms, it is a good indication that one of the systems contains air or has failed, and it is necessary to bleed or repair the brakes. MASTER CYLINDER (Fig. 1) The system is designed with a separate hydraulic system for the front and rear brakes using a dual master cylinder. The cylinder has two separate reservoirs and outlets in a common body casting. On all 10 and G20 series vehicles, the front reservoir controls the front brake system and the rear reservoir controls the rear system. On all other 20-30 series vehicles, the front reservoir controls the rear brake system and the rear reservoir controls the front system (except on CA 30 with vacuum over hydraulic boosters where the front is controlled by the front booster and rear by the rear booster). COMBINATION VALVE All models (except models with vacuum over hydraulic boosters) have a combination valve. The combination valve is located below the master cylinder on P and G models; on the front crossmember on C-K models. The front and rear hydraulic lines are routed through this combination "metering" and "brake failure warning switch" to their appropriate wheel cylinders or caliper. The metering portion of the combination valve tends to "hold off" front hydraulic pressure until the rear brake system overcomes their pull back springs; then pressure is allowed to flow with the result being a good distribution of braking effort. The brake failure warning switch portion of the combination valve "senses" a loss of hydraulic pressure, if a failure should occur and turns "on" a red light in the dash to warn the operator of the failure. DISC BRAKES FRONT—(Fig. 2) All models have disc brakes on the front. The one piece caliper mounts on the steering knuckle/steering arm, which is also a one piece casting, and astride the brake disc. The caliper is the single piston design which is said to be a sliding caliper sliding piston. No front brake adjustment is necessary once the system is in operation and the pedal has been stroked to "seat" the shoes to the caliper. DRUM BRAKES REAR—(Fig. 3) The rear brakes are duo servo and self adjusting (except R.P.O. H-22). Brake adjustment takes place when the brakes are applied with a firm pedal effort while the vehicle is backing up. Applying the brakes moves the actuator which turns the star wheel and lengthens the adjuster screw assembly. This action moves the shoes outward until clearance between the lining and drum is within proper limits. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-3 P105 ( 42) P300 ( 32) C-K MODELS P300 ( 42) WITH RPO H22/H23 G MODELS P MODELS Fig. 1-Master Cylinder Mountings- Typical LIGHT DUTY TRUCK SERVICE MANUAL 5 -4 BRAKES Fig. 3--Rear Drum Brake Fig. 2--Front Disc Brake THEORY OF OPERATION Brakes are simply a means of applying friction to either stop, slow down or hold an element. Brakes accomplish their job by converting motion energy, or kinetic energy, to heat energy, through brake shoes and linings. On the present day vehicle, the brake shoes are metal with heat resistant linings attached. The brake shoes are applied against the brake drum or disc by hydraulic pressure. To perform properly, the brake components must be properly installed and adjusted. First, the drum or disc must be the right size and shape, diameter, width, thickness and contour to provide enough friction area and adequate heat dissipation. Second, the linings must be of the correct material, size and contour to provide the proper amount of friction for: a. Proper performance b. Satisfactory durability c. Freedom from noise and scoring Third, clearances must be correct. Fourth, the operating system must be simple, dependable and easily adjusted. The basic hydraulic brake system consists of (1) a master cylinder, in which the hydraulic pressure is developed, (2 ) a cylinder at each wheel, where hydraulic pressure is utilized to force linings to rub against a brake disc or brake drum, and (3) the necessary tubing and flexible hoses to connect the master cylinder to the wheels. Of course, we need a method of generating this hydraulic pressure so we have a pedal mounted within the vehicle and connected to the master cylinder through a push rod. The principle of hydraulic pressure is put to work through the use of the pedal. When the pedal is depressed the master cylinder piston HYDRAULIC SYSTEM (Fig. 4) When fluid is contained in a closed system and pressure is applied to it, the pressure is exerted equally in all directions (Pascal’s Law). By applying this law, we are able to have a brake system that is easy to maintain and functionally stable. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES is pushed forward. The fluid in the master cylinder, and the entire system, being incompressible, transmits the force exerted by the master cylinder piston to all the inner surfaces of the system. At this point only the pistons in the wheel cylinders or caliper are free to move, and since the hydraulic fluid is not compressible, the pistons move outward to force brake shoes against the brake drums or disc. To work properly a hydraulic brake system must be leakproof, sturdy and filled with the right type of fluid. The right type of fluid is one that has no corrosive effect on the system’s parts, and does not readily freeze, boil or vaporize at the temperature extremes encountered in vehicle use. PRESSURE AND FORCE (Fig. 5) One of the advantages of a hydraulic system is that we have the same pressure inside the system and up to all wheels. This does not mean however that we are applying the same force at each wheel; in fact, it permits us to apply unequal force under certain circumstances. NOTE: Pressure may be different at front or rear wheels due to valving. Valves are covered later in this section. Pressure can be defined as the amount of force applied to a specific area, (measured in square inches). Suppose a hydraulic pressure of 10 psi (pounds square inch) were applied to an object with a surface area of 16 square inches. The total applied force would equal 160 pounds (ten psi pressure times an area of 16 square inches). If the same 10 psi were applied to an object with a surface area of two square inches, a force of 20 pounds would be applied. Reduced to a formula, this means that pressure (in pounds per square inch) times area (in square inches) equals total force applied. 10 psi PRESSURE GAUGE AREA—16 sq. in. AREA—2 sq. in. 5-5 This is the principle that enables us to incorporate a very desirable feature in the brake system - we can vary the braking power to the wheels by changing the wheel cylinder piston area. Some of the vehicle weight is transferred to the front wheels when the brakes are applied. We can balance this weight transfer with different braking force at the front and rear wheels. BRAKE SYSTEM COMPONENTS MASTER CYLINDER (Fig. 6) The master cylinders used today have split reservoirs. This means that the front and rear brakes are separated from each other by the design of the master cylinder. The master cylinder contains two fluid reservoirs and two cylindrical pressure chambers in which force, applied to the brake pedal, is transmitted to the fluid which actuates the brake shoes. Breather ports and compensating ports permit passage of fluid between each pressure chamber and its fluid reservoir during certain operating conditions. A vented cover and flexible rubber diaphragm, at the top of the master cylinder reservoir, seal the hydraulic system from possible entrance of contamination while at the same time permitting expansion or contraction of fluid within the reservoirs without direct venting. In the pressure chambers, coil springs hold rubber primary seals against the end of the pistons. These seals and rubber secondary seals on the opposite end of the pistons, prevent escape of fluid past the pistons. The piston is retained in the cylinder by a push rod retainer. A rubber boot is installed over this end of the cylinder to exclude foreign matter. Stroking or pushing the brake pedal causes the primary piston in the master cylinder to move forward. At the same time, a combination of hydraulic pressure and force of the primary piston spring moves the secondary piston forward. When the pistons have moved forward so that their primary seals cover the compensating ports, hydraulic pressure is built up and transmitted to the front and rear wheels. When the brake pedal is released, the master cylinder pistons move rearward and hydraulic pressure on the brake system is released. Rear Line Failure (Fig. 7) 160 POUNDS 10 x 16 Sq. in. = 160 lbs. (psi) x (AREA)= TOTAL FORCE 10 x 2 sq. in. = 20 lbs. (psi) x (AREA) = TOTAL FORCE Fig. 5 -Pressure and Force In case of a ruptured rear brake line or some other malfunction, the primary piston will move forward when the brakes are applied, but will not generate hydraulic pressure. Only a negligible force is transferred to the secondary piston through the primary piston spring until the primary piston comes in contact with the secondary piston. Then, push rod force is transmitted directly to the secondary piston and sufficient pressure is generated to operate the front brakes. LIGHT DUTY TRUCK SERVICE MANUAL 5-6 BRAKES COVER RETAINING BAIL RUBBER DIAPHRAM RESERVOIR COVER Fig. 6--Master Cylinder u q ljq l: f=£. SECONDARY PISTON PRIMARY PISTON ^vTT Hj®. Jc A frontA V ^ brakesv ^ J Fig. 7- Rear Line Failure Front Line Failure (Fig. 8) If there is a malfunction in the front brake line, both pistons will move forward when the brakes are applied, as under normal conditions. However, due to the front line malfunction, there is nothing to resist piston travel except the secondary piston spring. This permits the primary piston to generate only negligible pressure until the secondary piston bottoms in the cylinder bore. Then, Fig. 8 -Front Line Failure sufficient hydraulic pressure will be generated to operate the rear brakes. It should be noted that if either the front or rear brakes become inoperative, one brake system will remain effective and permit the vehicle to be brought to a controlled stop. Increased pedal travel will be evident as well as increased pedal force since only a part of the normally available braking surface will be used. Both of these effects should be noticeable to the driver but, as an LIGHT DUTY TRUCK SERVICE MANUAL BRAKES added safety feature, a warning light has been incorporated into the brake system. The dash-mounted warning light will come on when the brakes are applied under a condition of partial failure. This is a signal to the driver to have the brakes serviced. WHEEL CYLINDER (Fig. 9) Each wheel cylinder contains two pistons and two rubber cups which are held in contact with the pistons by a central coil spring with cup expanders to provide a fluidtight seal. The wheel cylinder cups are of a special heat resisting rubber. Cups of this material must have an expander to hold the lips of the cup out against the wheel cylinder bore. These cup expanders are crimped on each end of the wheel cylinder spring. The inlet port for brake fluid is located between the pistons so that when fluid pressure is applied, both pistons move outward toward the ends of wheel cylinders. The pistons impart movement to the brake shoes by means of connecting links which seat in the pistons and bear against webs of the shoes. Rubber boots enclose both ends of the cylinder to exclude foreign matter. A valve for bleeding the brake lines and wheel cylinder is located above the inlet port. COMBINATION VALVE (Fig. 10) The combination valve is just what its name implies. The metering valve, failure warning switch and proportioner are "combined" into an assembly which also serves as the front junction block. This valve is used on all disc brake applications. The input-output characteristics of the valve (i.e. split points), vary with vehicle usage. PUSH ROD AN D BOOT PISTON CUP RETURN SPRING WITH EXPANDERS WHEEL CYLINDER HOUSING PISTON CUP PISTON CUP BLEEDER SCREW ' ig F * ------- PISTON & PUSH ROD AND BOOT Fig. 9- Typical Wheel Cylinder 5-7 Metering Valve The Metering Valve "holds-off" front disc braking until the shoes of the rear drum brake contacts the drum. Brakes Not Applied (Fig. 11) The metering valve allows free flow of brake fluid through the valve when the brakes are not applied. This allows the fluid to expand and contract with temperature changes. (The boot is pressed in, to hold the pin down during bleeding operations.) Shut-Off Point-Initial Brake Apply (Fig. 12) The metering valve stem moves to the left, and at 4 to 30 psi, the smooth end of the stem is in a sealing position with the metering valve seal lip and this is the shut-off point. Hold-Off Blend Pressure (Fig. 13) The metering valve stem continues to the left on initial brake apply and stops on the knurl at the metal retainer. The metering valve spring holds the retainer against the seal until a predetermined psi is produced at the inlet of the valve. This pressure overcomes the spring and allows pressure through the valve to the front brakes. The continued increase of pressure into the valve is metered through the metering valve seal, through to the front brakes and produces an increasing force on the diaphragm. The diaphragm pulls the pin and the pin in turn pulls the retainer, thus reducing the spring load on the metering valve seal. Eventually, the pressure reaches the point where the spring is completely pulled away by the diaphragm pin and retainer leaving the metering valve seal free to pass unrestricted pressure through the valve. Failure Warning Switch (Fig. 14) The Failure Warning Switch is activated if either front or rear brake systems fail, and when activated, completes a circuit to the dash warning lamp. If the rear hydraulic system fails, the pressure of the good front system forces the switch position to the right. The switch pin is forced up into the switch by the piston ramp and makes the electrical circuit lighting the dash lamp, and is held in this position by the piston. When repairs are made and pressure is returned to the rear system by bleeding, the piston moves to the left and resets the switch to the off position. The detent on the piston typically requires 100 to 450 psi pressure before allowing full reset (centering) of the piston. The same condition will exist if the front hydraulic system fails except the piston moves to the left. Proportioner The rear brake Proportioner improves front-to-rear brake balance at high deceleration. During high deceleration stops, a percentage of the rear weight is transferred to the front wheels. Compensation must be made for the resultant loss of weight to the rear wheels to avoid early rear wheel skid. The proportioner part of LIGHT DUTY TRUCK SERVICE MANUAL 5 -8 BRAKES SWITCH TERMINAL SWITCH PIN FRONT INLET PORT-^ SWITCH PISTON DETENT ,REAR INLET PORT PROPORTIONER PISTON VALVE STEM FRONT OUTLET PORT STOP PLATE BOOT PROPORTIONING NUT' REAR OUTLET PORT DIAPHRAGM 'METERING VALVE SEAL FRONT OUTLET PORT METERING VALVE STEM Fig. 10--Combination Valve FROM MASTER CYLINDER Fig. 11 -Brakes Not Applied the combination valve reduces the rear brake pressure and delays the rear wheel skid. Normal Brake Stops (Fig. 15) The proportioner does not operate during normal brake stops. Fluid normally flows into the proportioner, through the space between the piston center hole and valve stem, through the stop plate and out to the rear brakes. The spring loads the piston so that it rests against the stop plate for normal brake pressures. Fig. 1 2 -Shut-Off Point Proportioning Action (Fig. 16) Pressure developed within the valve pushes against the large end of the piston and when sufficient to overcome the spring load, moves the piston to the left. The piston "Contacts" the spherical stem seat and starts proportion­ ing by restricting pressure through the valve. Overhaul and Major Service The combination valve is not reparable. If a defect is LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-9 FROM MASTER CYLINDER REAR OUTLET Fig. 13--Hold-Off and Blend Pressure Fig. 14 -Rear System Failure found in any portion of the valve, the complete valve assembly must be replaced. BRAKE TRAVEL WARNING SWITCH (FIG. 17) Vehicles with frame mounted vacuum over hydraulic boosters have an electrical switch that senses pedal travel. This switch will illuminate the lamp on the instrument panel whenever the brake pedal travel is in excess of 5.10 inches. BRAKE STOPLAMP SWITCH The brake stoplamp switch is mounted on a flange protruding from the brake pedal support bracket below the instrument panel (fig. 18). When the brake pedal is depressed, the switch plunger (which is spring loaded), follows the brake pedal arm downward until the switch is in the "O N " position. When the brake is released, the brake pedal arm returns the switch plunger to the "O FF" position. BRAKE PEDAL The brake pedal is a lever, pivoted at one end, with the master cylinder push rod attached to the pedal near the pivot point. By this lever arrangement the force applied to the master cylinder piston through the push rod is multiplied several times over the force applied at the brake pedal (fig. 19). Proper service of the brake pedal is vital to good brake performance, and pedal operation should be checked each time brakes are inspected. Weak or broken return springs or lack of lubrication can cause sluggish release LIGHT DUTY TRUCK SERVICE MANUAL 5 -1 0 BRAKES of the brakes. Wear in the pedal linkage, pivot pins, or bushings, can cause loss of pedal or frequent need for brake adjustment. Pedal free play is the free travel of the pedal before any movement of the master cylinder piston occurs. Too little free play can cause brakes to drag. Too much free play may result in a low pedal. The free play at the brake pedal pad should be l / 16 to 1/4 inch for the standard height pedal. OPERATION OF BRAKE MECHANISM When the brakes are fully released, the master cylinder pistons are held against the push rod retainer, and the primary seals are held just clear of the compensating C O N T A C T IS MADE Fig. 18-Stoplamp Switch (Typical) Fig. 19-Brake Pedal (Typical) ports by the piston springs. The pressure chambers are filled with fluid at atmospheric pressure due to the open compensating ports and the flexible reservoir diaphragm. When the brake pedal is depressed to apply the brakes, the push rod forces the master cylinder pistons and primary seals forward. As this movement starts, the lips of the primary seals cover the compensating ports to prevent escape of fluid into the reservoirs. Continued movement of the pistons builds pressure in the pressure chambers and fluid is then forced through the lines leading to the wheel cylinders. Fluid forced into the wheel cylinders between the cups and pistons causes the pistons and connecting links to move outward and force the brake shoes into contact with the drums. Movement of all brake shoes into contact with drums is accomplished with very light pedal pressure. Since pressure is equal in all parts of the hydraulic system, effective braking pressure cannot be applied to any one drum until all of the shoes are in contact with their respective drums; therefore, the system is self-equalizing. When the brake pedal is released, the master cylinder springs force the pedal back until the push rod contacts the retaining ring in the master cylinder. This spring also forces the pistons and primary seals to follow the push rod. At the start of a fast release, the pistons move faster than the fluid can follow in returning from the lines and wheel cylinders; therefore, a partial vacuum is momentarily created in the pressure chamber. Fluid supplied through the breather ports is then drawn through the bleeder holes in piston heads and past the primary seals to keep the pressure chamber filled. As pressure drops in the master cylinder, the shoe LIGHT DUTY TRUCK SERVICE MANUAL BRAKES springs retract all brake shoes and the connecting links push the wheel cylinder pistons inward, forcing fluid back to the master cylinder. With the piston bearing against the retaining ring and the lips of the primary seals just clear of the compensating ports, excess fluid which entered through the bleeder holes or was created by expansion due to increased temperature, now returns to the reservoirs through the uncovered compensating ports. SINGLE PISTON FRONT DISC BRAKES (Fig. 20) When fluid is contained in a closed system and pressure is applied to it, this pressure is exerted equally in all directions (fig. 4). In the single piston mechanism, hydraulic pressure acts on two surfaces. The first, and most obvious, is the piston. The second is in the opposite direction against the bottom of the bore of the caliper housing. Since the area of the piston and bottom of the caliper bore are equal, equal forces are developed. Hydraulic force in the caliper bore is exerted against the 5-11 piston which is transmitted to the inner brake shoe and lining assembly and the inner surface of the disc. This tends to pull the caliper assembly inboard, sliding on the four rubber bushings. The outer lining, which rests on the caliper housing, then applies a force on the outer surface of the disc and together the two linings brake the car. Since an equal hydraulic force is applied both to the caliper housing and the piston, the force created against the outer surface of the disc is the same as the inner. Since there are equal forces on the linings, no flexing or distortion of the disc occurs regardless of the severity or length of application, and lining wear will tend to be equal. Note the running clearance of the brake shoe and the brake disc in Figures 21 and 22. When the brake pedal is depressed, the piston being in contact with the other side of the brake shoe, applies force to the inner surface of the disc. This force causes the caliper to move inboard until an equal force is applied to the outer disc surface. The movement that takes place is very slight and would have to be observed very closely to be seen. As the brake linings wear, the caliper assembly moves inboard and fluid fills the area behind the piston, so that Fig. 20--Disc Brake Operation LIGHT DUTY TRUCK SERVICE MANUAL 5 -1 2 BRAKES there is not a condition of pedal travel increase with respect to the front brake as the linings wear (fig. 21 ). As the driver releases the brake pedal, it is important that the piston immediately release from the shoe and lining. As pointed out earlier, the movement from no application to full application is very slight, therefore it should be easy to understand that as force is removed, the piston and caliper merely relax into the released position and braking effort is removed. An important thing to remember about disc brakes is that the lining is in constant contact with the disc (fig. 21 ) giving the added advantages of improved brake response, reduced pedal travel and faster generation of line pressure. The shoe, being at zero clearance, also "wipes" the disc free of any foreign matter. Disc brakes also have good fade resistance with fast recovery. The major components of the single piston sliding caliper disc brake are the hub and disc assembly, the shield, the support, the caliper assembly, and the shoe and lining assemblies (fig. 22). The cast iron disc is of the fully ventilated design. Note that between the machined braking surfaces are cooling fins. This design acts to cool the brakes by fanning the air and in addition has many cooling surfaces. Hub and Disc The purpose of the disc is to provide the frictional surfaces required to stop the vehicle. Shield and Support The disc is protected from cross vehicle splash by a shield on the inboard side that is bolted to the steering knuckle. Brake Caliper NEW WORN Fig. 21- New and Worn Linings The caliper provides a means of applying the shoe and lining assemblies to the disc. It is connected to the system by a hydraulic line. It is mounted to the support plate by two housing retainer bolts, two sleeves and four rubber bushings. An inner caliper rubber bushing is installed between each sleeve and groove in the housing, and an outer caliper rubber bushing is installed between each bolt and groove in the housing. Shoe and lining assemblies are positioned on the caliper so they straddle the disc. REAR DRUM BRAKES (Fig. 2 3 ) The entire rear wheel brake mechanism is mounted on the brake flange plate, which is bolted directly to the axle housing (fig. 23). PULL BACK SPRINGS PRIMARY SHOE FWD"*' SECONDARY SHOE ACTUATING LEVER Fig. 22- Disc and Caliper - Single Piston HOLD DO W N SPRING A N D PIN Fig. 23-Rear Drum Brake - Right Side Shown LIGHT DUTY TRUCK SERVICE MANUAL BRAKES The anchor pin is the upper pivot point of the brake shoes. It is located above the wheel cylinder, and is secured to the top of the flange plate. Two brake shoes are used, a primary shoe toward the front of the vehicle, and a secondary shoe toward the rear. Brake shoe linings are secured to the shoes. The primary shoe lining is shorter than the secondary shoe lining. The shoes are fitted to the anchor pin at the top and secured by color-coded retracting springs. At the bottom they fit into grooves at each end of the star wheel adjuster and are retained in position by a primary to secondary connecting spring located above the star wheel adjuster. Each shoe is also attached to the flange plate by means of a hold-down pin, which is retained in position by a hold-down spring and retainer cup. The star wheel assembly is installed under the primary to secondary shoe connecting spring. A self-adjusting brake shoe mechanism consisting of a link, actuating lever, pawl and pawl return spring is also used. The loop end of the link is attached to the shoe guide plate and the hooked end to the actuating lever. Self Energizing Action (Fig. 24) The brakes are self-energizing. This means that the brake unit is designed to assist the driver in forcing the shoes against the drum. To see how this is done, let’s observe a step-by-step sequence of brake action. When pressure is applied to the brake pedal, fluid is delivered under pressure from the master cylinder to each of the wheel cylinders. At each wheel cylinder the fluid forces the two pistons outward in the bore. This motion is transmitted from the piston to the shoes by thrust rods or "struts". This action forces the shoes outward at the top causing the shoes to pivot on the adjusting screw assembly (as the shoes move outward, they also stretch the pull-back 5-13 springs which are used later to return the shoes to the rest position). When the shoes expand outward, they contact the drum and tend to rotate with the drum. It is this principle that allows the self-energizing feature to exist. The primary shoe (the first shoe from the anchor pin in the direction of normal rotation), rotating with the drum, moves away from the anchor pin and exerts a rearward force on the adjusting screw. At the same time this is taking place the secondary shoe is rotating upward until the shoe web contacts the anchor pin. We can then see that the force applied to the secondary shoe is the sum of the apply force on the primary shoe and the force caused by rotation (friction force) of the primary shoe. This combination of force is the selfenergizing feature, and the increased force it applies to the brake shoes results in less physical effort required at the brake pedal. The increased braking force applied to the secondary shoe accounts for the fact that the secondary shoe lining area is usually larger than that of the primary shoe lining. When the brakes are applied with the vehicle moving in reverse, the rear shoe becomes, in effect, the primary shoe. The self-energizing action now would be applied to the front shoe, and the rear shoe would move away from the anchor pin. Self-Adjusting Action With the understanding of the operation of the drum brake system, we can apply the same step-by-step sequence to see how the self-adjusting mechanism operates. In the component description given earlier, we found that the actuating lever assembly of the selfadjusting mechanism is mounted on the secondary or rear shoe. The lever is attached to the web of the secondary shoe by the hold down pin and spring. The deep dished washer, used as the hold down spring seat, passes through the lever and into the shoe web. Thus, the lever is allowed to pivot about this point. Also, this spring type mount keeps the pawl end of the lever in firm contact with the teeth of the adjusting screw star wheel. Forward Stops (Fig. 25) Fig. 24- Brake Operation During a forward stop, the shoes expand outward and contact the drum; they rotate with the drum until the secondary or rear shoe contacts the anchor pin. Thus the pivot point for the secondary shoe moves only far enough to place the lining in contact with the drum. Subsequent motion is then in the direction of the anchor pin. When the brakes are released, the secondary shoe is already in contact with the anchor pin, so its only movement is to pivot on the anchor pin, and follow the primary shoe to the rest position. Now, let’s see what affect the forward stop has on the self-adjusting LIGHT DUTY TRUCK SERVICE MANUAL 5 -1 4 BRAKES slight amount of movement is not enough to cause the actuating lever to advance the star wheel. Over-Ride Mechanism (Fig. 27) PR IM AR Y S H O E MOVES A W A Y FR O M A N C H O R PIN Fig. 25--Reaction During Forward Stop mechanism. First, the small amount of movement from the rest position until the shoes contact the drum, is permitted without activating the adjusting mechanism by the slack inherent to this linkage design. Since the rotation of the secondary or rear shoe is toward the anchor pirr, the effective distance from the pin to the actuating lever is not increased; thus, no adjustment occurs. When the brakes are released, the linkage relaxes with any small degree of motion absorbed by the linkage slack. Reverse Stops (Fig. 26) During a reverse stop, the shoes expand outward to contact the drum, and then rotate with the drum until the primary or front shoe contacts the anchor pin. When there is sufficient clearance between the lining and the drum, this rotation increases the distance from the anchor pin to the secondary or rear shoe hold down pin. Since the wire link between the anchor pin and actuating lever is a fixed length, the movement of the lever pivot point causes the top of the actuating lever to be pulled inward. As the lever pivots on the hold down spring cup, the pawl end rocks down on the adjusting screw star wheel. When the pawl turns the star wheel, it increases the length of the adjusting screw in much the same manner as a service technician using a brake adjusting tool. As the lever rocks down to turn the star wheel, it also moves outboard to follow the contour of the star wheel. At the same time, the downward motion compresses the lever return spring. When the brakes are released, the pull-back springs return the shoes to their normal position, the lever return spring raises the pawl end of the lever back to its normal position. The pawl slips back over the teeth of the star wheel and takes a new "bite" on another notch. When there is only a slight clearance between the shoes and drums, such as the condition when the brakes are near to proper adjustment, the shoes rotate only a small amount before the shoes contact the anchor pin. This All of the standard equipment self-adjusting mechanisms contain a built-in safety device known as the "over-ride pivot plate and spring". This pivot plate and spring are mounted on the upper end of the actuating lever, acting as a semi-rigid connection between the actuating lever and the wire link. The over-ride mechanism has one major function; to prevent damage to the linkage when, for some reason, the linkage cannot move as dictated by shoe rotation. Two common examples of this condition occurs when; the adjusting screw binds, or the brakes are severely out of adjustment. If the adjusting screw threads should bind, the selfadjusting mechanism would attempt to continue operating. This would result in damaged parts, or possible reduced brake application on the affected wheel. When this occurs, the actuating lever remains stationary, and the over-ride pivot plate is pulled by the wire link. This motion is absorbed by stretching the over-ride spring. With the adjusting motion dampened by the spring, the component parts remain undamaged. NOTE: One symptom of a bound adjusting screw is "pulling brakes". Inspect the screw when a complaint of brake pull is reported. The second purpose of the over-ride plate is to prevent excessive actuating lever travel. This condition could occur if the brake adjustment were extremely loose. Should this condition occur, the motion of the actuating lever could allow the pawl end to rock down until it contacted the secondary shoe. Here again, without the over-ride spring, linkage damage or reduced brake efficiency could result. Equally important to proper brake adjustment is the prevention of adjusting screw "back-off". The selfenergizing force transmitted by the adjusting screw tends to compress the screw length. We can thus see the REVERSE S E C O N D A R Y SH O E M OVES A W A Y FR O M A N C H O R PIN FIXED LEN G TH O F W IRE LIN K C AUSES LEVER T O P IV O T Fig. 26--Reaction During Reverse Stop LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-15 STOP TANG SEATED ON SHOE Fig. 27 Override Component Operation necessity of preventing star wheel "back-off" during the maximum self-energizing condition. To do this, a "stop tang" extends down from the under side of the actuating lever to contact the secondary shoe (fig. 28). This limits the actuating lever travel to a maximum of three notches per stroke, which has the effect of maintaining pawl engagement to the star wheel while braking to a stop. Again, as in the case of a bound adjusting screw, any additional shoe motion is absorbed by the over-ride pivot plate and spring. NOTE: The actuating lever stop is also the mount and guide for the lever return spring. The actuating lever is held against the secondary shoe by the hold-down spring and cups. The pawl is connected to the actuating lever and held in position by the pawl return spring. Fig. 28-Actuating Lever Stop Tang Parking Brake Activating Mechanism The activating mechanism for the parking brake consists of an operating lever located in back of the secondary shoe, and attached to the shoe by a pivot at the upper end. A strut rod located a few inches below the pivot point, extends forward from this lever to the primary shoe. The parking brake cable is connected to the lower end of the operating lever. When the parking brake is applied, the cable pulls the lower end of the operating lever forward, causing the strut rod to push the primary shoe forward. At the same time, the upper end of the lever pushes the secondary shoe rearward. The combined action of the lever and the strut rod drives the primary and secondary shoes apart and into contact with the drums. M A IN TEN A N C E A N D ADJUSTMENTS BRAKE INSPECTION Every 12 months or 12,000 miles-whichever occurs first: Inspect drum brake linings or disc brake pads, as well as the other internal brake components at each wheel (drums, rotors, wheel cylinders, etc.). For convenience, it is recommended that disc brake pads be checked whenever tires are rotated (at 6000 mile intervals). More frequent checks should be made if driving conditions and habits result in frequent brake application. Parking brake adjustment should also be checked whenever brake linings are checked. NOTE: During any inspection period, the remaining lining life expectancy should be determined. This determination should dic­ tate the next inspection period. Lining Inspection Drum Brake Replace whenever the thickness of any part of any lining is worn to within 1/32" of the shoe table or rivet head whichever is applicable. Another important point to remember, always replace brake shoes in axle sets (right and left side). Disc Brakes Check both ends of the outboard shoe by looking in at each end of the caliper. These are the points at which the highest rate of wear normally occurs. However, at the same time, check the lining thickness on the inboard shoe to make sure that it. has not worn prematurely. Replace whenever the thickness of any part of any lining LIGHT DUTY TRUCK SERVICE MANUAL 5 -1 6 BRAKES is worn to within 1/32" of the shoe or rivet whichever is applicable. HYDRAULIC BRAKE FLUID Brake fluid is a specially blended liquid which provides a means of transmitting hydraulic pressure between the master cylinder and the brake calipers and wheel cylinders. Brake fluid is one of the most important parts of the hydraulic system. Use GM Hydraulic Brake Fluid Supreme No. 11 or DOT-3, meeting GM Specification GM4653M or equivalent. Brake fluid must have certain specific qualities such as: 1. Viscosity (free flowing at all temperatures). 2. High boiling point (remain liquid at highest operating temperatures). 3. Non-corrosive (must not attack metal or rubber parts). 4. Water tolerance (must be able to absorb and retain moisture). 5. Lubricating ability (must lubricate piston and seals to reduce wear and internal friction). 6 . Low freezing point (must not freeze even at lowest operating temperatures). If brake fluid becomes contaminated, it may lose some of its original qualities. It is good practice to bleed the brake system until all old fluid is removed when performing major brake work. Old fluid should be bled from the system and replaced with clean brake fluid if any of the hydraulic system parts are corroded or the fluid is discolored or dirty. If any of the rubber parts of the hydraulic system are soft or swollen old fluid should be removed and hydraulic system should be flushed with clean brake fluid. Do not reuse old brake fluid at any time. In the event that improper fluid has entered the system, it will be necessary to service the system as follows: 1. Drain the entire system. 2. Thoroughly flush the system clean with brake fluid. CAU TIO N: Use only brake fluid when flushing 3. a system. Replace all rubber parts of the system, brake hoses and combination valve. 4. Refill the system. 5. Bleed the system. Flushing Brake Hydraulic System It is recommended that the entire hydraulic system be thoroughly flushed with clean brake fluid whenever new parts are installed in the hydraulic system. Flushing is also recommended if there is any doubt as to the grade of fluid in the system or if fluid has been used which contains the slightest trace of mineral oil. Flushing is performed at each bleeder valve in turn, and in the same manner as the bleeding operation except that bleeder valve is opened 1- 1/2 turns and the fluid is forced through the lines and bleeder valves until it emerges clear in color. Approximately one quart of fluid is required to flush the hydraulic system thoroughly. When flushing is completed at all bleeder valves, make certain the master cylinder reservoir is filled to proper level. BLEEDING HYDRAULIC SYSTEM The hydraulic brake system must be bled whenever, any line has been disconnected or air has in some way entered the system. Bleeding of brake system may be performed by one of two methods — either pressure or manual. Bleeder valves are provided at the calipers, wheel cylinders and are also located on some master cylinders. Sequence for Bleeding Wheel Cylinders It is advisable to bleed one valve at a time to avoid allowing fluid level in reservoir to become dangerously low. The correct sequence of bleeding is to bleed the valve, either front or rear system, nearest master cylinder first. This sequence expels air from lines and calipers or wheel cylinders nearest the master cylinder first and eliminates the possibility that air in a line close to the master cylinder may enter a line farther away after it has been bled. CAUTIO N: Do not perform bleeding operation while any brake drum is removed or with a caliper removedfrom the disc. Pressure Bleeding (Figs. 29 and 30) NOTE: Pressure bleeding equipment must be of the diaphragm type. That is, it must have a rubber diaphragm between the air supply and the brake fluid to prevent air, moisture, oil and other contaminates from entering the hydraulic system. 1. Clean all dirt from top of master cylinder and remove cylinder cover and rubber diaphragm. NOTE: Make sure brake fluid in bleeder equipment is at operating level and that the equipment is capable of exerting 20 to 30 lbs. hydraulic pressure on the brake system. 2. Install Brake Bleeder Adapter J-23518 (J-23339 for frame mounted boosters) on master cylinder. Connect hose from bleeder equipment to bleeder adapter and open release valve on bleeder equipment. NOTE: The combination valve, located near the master cylinder, must be held in the open position while bleeding. This can be accom­ plished by installing Tool J-23709 with the open slot under the mounting bolt and pushing in on the pin in the end of the valve LIGHT DUTY TRUCK SERVICE MANUAL BRAKES Fig. 29-B rake Bleeder J-23518 and J-23709 G Model Shown (fig. 29). Be sure to retorque the mounting bolt after removing Tool J-23709. Install Brake Bleeder Wrench J-21472 on caliper bleeder valve nearest the master cylinder and install one end of bleeder hose on bleeder valve. NOTE: If the master cylinder is equipped with bleeder valves, bleed these valves first, proceed to the bleeder valve nearest the master cylinder, then the next nearest and so on until all valves have been bled and there is no evidence of air in the system. Pour a sufficient amount of brake fluid into a transparent container to ensure that end of bleeder hose will remain submerged during bleeding. Place the loose end of bleeder hose into the container. Be sure the hose end is submerged in the fluid. Open bleeder valve by turning Tool J-21472 counterclockwise approximately 3/4 of a turn and observe flow of fluid at end of bleeder hose. NOTE: To assist the bleeding operation a rawhide mallet may be used to tap the caliper while fluid is flowing. Close bleeder valve tight as soon as bubbles stop and brake fluid flows in a solid stream from the bleeder hose. Remove brake bleeder wrench and bleeder hose from bleeder valve. Repeat Steps 3 through 7 on the remaining bleeder valves. Disconnect bleeder equipment from brake bleeder adapter. NOTE: The master cylinder on certain models is tilted. When removing the bleeder adapter on these models, place a clean dry 5-17 Fig. 3 0 -Bleeding Brakes with Tool J 21472 cloth below the cylinder to absorb any fluid spillage as the cover is removed. 10. Remove bleeder adapter. Wipe all areas dry if fluid was spilled during adapter removal. 11. Fill master cylinder reservoirs to within 1/4" of reservoir rims as shown in Figure 31. 12. Install master cylinder diaphragm and cover. CAUTION: When installing the master cylinder cover, the retaining bail should be slipped over the lower cover bosses (fig. 32). Incorrect installation could result in bail tension loss and fluid leakage. 13. Test operation of brake pedal before moving the vehicle. Manual Bleeding 1. Clean all dirt from the top of the master cylinder LIGHT DUTY TRUCK SERVICE MANUAL 5 -1 8 BRAKES return slowly to the released position. Repeat Step 5 until expelled brake fluid flows in a solid stream without the presence of air bubbles, then close the bleeder valve tightly. NOTE: To assist the bleeding operation a rawhide mallet may be used to tap the caliper while fluid is flowing. 6 . Remove brake bleeder wrench and hose from the bleeder valve and repeat Steps 2 through 6 on the remaining bleeder valves. 7. Fill the master cylinder to the level shown in Figure 31. 8 . Install the master cylinder diaphragm and cover. CAUTION: When installing the master cylinder and remove the cylinder cover and rubber diaphragm. 2. Fill master cylinder (if necessary) and reinstall the cover. 3. Install Brake Bleeder Wrench J-21472 on caliper bleeder valve nearest the master cylinder and install a bleeder hose on the bleeder valve (fig. 30). NOTE: The combination valve, located near the master cylinder, must be held in the open position while bleeding. This can be accom­ plished by installing Tool J-23709 with the open slot under the mounting bolt and pushing in on the pin in the end of the valve (fig. 29). Be sure to retorque the mounting bolt after removing Tool J-23709. If the master cylinder is equipped with bleeder valves, bleed these valves first, then proceed to the bleeder valve nearest the master cylinder, then the next nearest and so on until all cylinders have been bled and there is no evidence of air. 4. Pour a sufficient amount of brake fluid into a transparent container to ensure that the end of the bleeder hose will remain submerged during bleeding. Place the loose end of the bleeder hose into the container. NOTE: Carefully monitor the fluid level at the master cylinder during bleeding. Do not bleed enough fluid at one time to drain the reservoir. Replenish as needed to ensure a sufficient amount of fluid is in the master cylinder at all times. 5. Open bleeder valve by turning Tool J-21472 counterclockwise approximately 3/4 of a turn. Have helper depress the brake pedal. Just before the brake pedal reaches the end of its travel, close the bleeder valve tightly and allow the brake pedal to cover the retaining bail should be slipped over the lower cover bosses (fig. 32). Incorrect installation could result in bail tension loss and fluid leakage. NOTE: In order to have a good surge of fluid at the bleeder valve, the brake pedal should be pumped up and pressure held before each opening of the valve. HYDRAULIC BRAKE LINES AND TUBING (Figs. 33 and 34) Hydraulic Brake Hose The flexible hoses which carry the hydraulic pressure from the steel lines to the brake calipers are carefully designed and constructed to withstand all conditions of stress and twist which they encounter during normal vehicle usage. These hoses require no service other than periodic inspection for damage from road hazards or other like sources. Should damage occur and replacement become necessary, the following procedure should be followed. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -1 9 BRAKE LINE FUEL LINE TO MASTER CYLINDER FRONT BRAKE HOSE REAR BRAKE HOSE CO M BINATION VALVE AXLE Fig. 34-Brake Line Retainers- Typical Removal 1. Clean all dirt and foreign material away from both hose fitting ends. 2. Separate steel line from flex hose. Use a back up wrench on the hose fitting. 3. Remove clip retainer from frame attachment. 4. Remove hose to caliper bolt and remove hose. Installation (Fig. 33) 1. Install the hose to the caliper using new gaskets. Torque the mounting bolt. CAUTION: See Caution on Page 1 of this section. Hose line must be installed in caliper locating gate (except "K" models); connector arm in caliper locating gate ("K" series). 2. Insert hose into frame bracket or frame. This end of hose will properly mate to the bracket or frame in one direction only. 3. Install the clip retainer. 4. Install the steel line to the flex line using a back up wrench on the hose fitting. CAUTION: See Caution on Page 1 of this section. 5. Bleed brakes as outlined in this section. Hydraulic Brake Tubing (Figs. 35 thru 39) Hydraulic brake tubing used on all trucks is a double wall steel tubing which resists corrosion and has the physical strength to stand up under the pressures which are developed when applying the brakes. In making up hydraulic brake lines, it is important that the ends of the tubing be flared properly for the compression couplings.; CAUTION: When necessary to replace brake tubing, always use double wall steel tubing which is designed to withstand high pressure and resist corrosion. Steel tubing must be equivalent to G M Specification GM123M, be annealed dead soft and super terne coated. ORDINARY COPPER TUBING IS N O T SATISFACTORY A N D S H O U L D N O T BE USED. When replacing brake lines, be sure to install new spring steel shielding material over the replacement line in the same areas as on the line removed. LIGHT DUTY TRUCK SERVICE MANUAl* 5 -2 0 BRAKES Safety steel tubing must be double-lap flared at the ends in order to produce a strong leak-proof joint. Brake Tube Flaring Tool J-2185-45° is used to form the double lap flare. It must be equipped with the proper size die block and upset flare punch for each size tubing to form the double-lap flare (fig. 35). The proper size die blocks and upset flare punches are as follows: Tubing Size 3/16” 1 /4 ” 5/16” Die Block J-2185-27 J-2185-28 J-2185-29 Upset Flare Punch J-2185-3 J-2185-37 J-2185-4 Finish Flare Punch J-2185-26 J-2185-26 J-2185-26 Figure 36 shows two pieces of tubing, one with single-lap flare "A" and the other with double-lap flare "B". It will be noted that the single-lap flare in "A" split the tubing while the one shown in "B" is well-formed and unbroken due to the reinforcement of the double wall. Fig. 35-Flaring Tool J-2185 The following procedure should be followed in making up hydraulic brake lines. Double Lap Flaring 1. Cut the tubing to the desired length, using Tool J-8000. Square off ends of tube and ream sharp edges with reamer tool provided on the tube cutter. 2. Install compression couplings on tubing and dip end of tubing to be flared in hydraulic brake fluid. This lubrication results in better formation of the flare. 3. Place one-half of the die blocks in the tool body with the counterbored ends toward the ram guide. Now lay the tubing in the block with approximately 1/4" protruding beyond the end. Fit the other half of the block into the tool body, close the latch plate and tighten the nuts "finger tight." 4. Select the correct size upset flare punch. One end of this punch is hollowed out to gauge the amount of tubing necessary to form a double-lap flare. 5. Slip the punch into the tool body with the gauge end toward the die blocks, install the ram and tap lightly until the punch meets the die blocks and they are forced securely against the stop plate (fig. 37). 6 . Using the supplied wrench, draw the latch plate nut down tight to prevent the tube from slipping. Tightening the nuts alternately (beginning with the nut at the closed hole in the plate), will prevent distortion of the plate. Remove the punch and the ram. Now reverse the punch and put it back into the tool body. Install the ram and tap it until the upset flare is complete (fig. 38). This completes the first operation. Remove the ram and the punch. 7. To complete the flare, insert the pointed finish flare punch and the ram into the tool body. Tap the ram until a good seat is formed (fig. 39). NOTE: The seat should be inspected at intervals during the finishing operation to avoid over-seating. 8 . Blow tubing out with compressed air to remove any foreign objects. LATCH PLATEDIE BLOCK TUBE UPSET FLARE PUNCH RAM GUIDE RAM STOP PLATE Fig. 3 6 -Single and Double Lap Flare Fig. 3 7 -Positioning Tube LIGHT DUTY TRUCK SERVICE MANUAL BRAKES LATCH PLATE DIE BLOCK\ TUBE T UPSET FLARE PUNCH 5-21 RAM GUIDE r RAM PLATE Fig. 38--Flaring O peration DRUM BRAKE ADJUSTMENT Service Brake Although the brakes are self adjusting a preliminary or initial adjustment may be necessary after the brakes have been relined or replaced, or whenever the length of the adjusting screw has been changed. The final adjustment is make by using the self adjusting feature. 1. With brake drum off, disengage the actuator from the star wheel and rotate the star wheel. Recommended Method of Adjustment (Fig. 40) Fig. 40--Using D rum -to-B rake Gauge J-21177 a. Use Drum to Brake Shoe Clearance Gauge J-21177 to check the diameter of the drum clearance surface (fig. 40). b. Turn the tool to the opposite side and fit over the brake shoes by turning the star wheel until the gauge just slides over the linings (fig. 41). c. Rotate the gauge around the brake shoe lining surface to assure proper clearance. Alternate Method of Adjustment a. Using the brake drum as an adjustment fixture, turn the star wheel until the drum slides over the brake shoes with a slight drag. Fig. 41--Setting Lining Clearance w ith J-21177 b. Turn the star wheel 1-1/4 turns to retract the shoes. This will allow sufficient lining to drum clearance so final adjustment may be made as described in Step 3. 2. Install the drum and wheel and remove the vehicle from the jack stands or hoist. CAUTIO N: If lanced area in drum or flange plate was knocked out, be sure all metal has been removedfrom brake compartment. Install a new metal hole cover to prevent contamina­ tion of the brakes. Make certain when installing drums that drums are installed in the same position as when LIGHT DUTY TRUCK SERVICE MANUAL 5 -2 2 BRAKES removed, with the drun locating tang in line with the locating hole in he axle shaftflange. 3. Make final adjustmei by making numerous forward and reverse stc 3S, applying brakes with a firm pedal effort until a satisfactory brake pedal height results. CAUTION: Frequent u age of an automatic transmission forward mge to halt reverse vehicle motion may P event the automatic adjusters from functior mg, thereby inducing low pedal heights. push rod. Power brake units incorporate a two-piece push rod. Ordinarily there would be no reason to change the push rod dimension; however, if the rod were inadvertently lengthened or shortened, the correct dimension is given in Figure 42. NOTE: To adjust, it would be necessary to remove the unit from the vehicle, loosen the locknut and adjust to the dimension shown, retighten the locknut and reinstall the unit. STOPLAMP SWITCH ADJUSTMENT (Fig. 43) BRAKE PEDAL FREE 1 RAVEL ADJUSTMENT G-P Models A definite pedal push rod to-master cylinder piston clearance must be maintaine 1 on G and P model dash mounted master cylinder ui its (manual brakes). This clearance is adjusted as follov s: 1. After the brake pedal ai d pedal bumper have been assembled, install the f ush rod and its attaching parts. Then to obtain th correct clearance between the push rod and the i aster cylinder, adjust the push rod so that the pedal travel measured at the center of the pedal pad is .06-.25 inches (fig. 42). 2. After tightening the loci nut on the adjustable push rod, recheck free travel. CAUTION: See "Cautio i" on Page 1 of this section. C-K Models Manual brake vehicles do no incorporate an adjustable The stoplamp switch is mounted on a flange protruding from the brake pedal support. Adjustment 1. Release the brake pedal to its normal position. 2 . Adjust the switch by rotating the switch in its bracket. Electrical contact should be made when the pedal travel (measured at the center of the pedal pad) is 3/8-5/8" (C-K models), approximately 5/8" (P-G models). 3. Tighten switch locknut, if so equipped, and connect electrical harness. BRAKE TRAVEL WARNING SWITCH ADJUSTMENT Refer to "Brake Travel Warning Switch" under Component Replacement in this section. PARKING BRAKE-REAR WHEEL The rear brake assemblies (except RPO H22—where Fig. 42- Brake Pedal Adjustment-Typical LIGHT DUTY TRUCK SERVICE MANUAL BRAKES parking brake is mounted on the propeller shaft) serve a dual purpose in that they are utilized both as a hydraulically operated service brake and also as a mechanically operated parking brake. In view of this dual purpose, the service brake must be properly adjusted as a base for parking brake adjustment; conversely the parking brake must be properly adjusted for the service brake to function as intended. Inspection If complete release of the parking brake is not obtained, unless it is forcibly returned to its released position, or if application effort is high, check parking brake assembly for free operation. If operation is sticky or a bind is experienced, correct as follows: 1. Clean and lubricate brake cables and equalizer with Delco Brake Lube #5450032 (or equivalent). 2. Inspect brake assembly for straightness and alignment (replace if necessary). 3. Clean and lubricate parking brake assembly with Delco Brake Lube #5450032 (or equivalent). 4. Checking routing of cables for kinks or binding. Adjustment—Foot Pedal Type 1. 2. 3. 4. NOTE: Before adjusting parking brake, check service brake condition and adjustment. Raise vehicle on hoist. Apply parking brake 1 notch from fully released position. Loosen equalizer check nut and tighten the adjusting nut until a moderate drag is felt when the rear wheels are rotated forward. Tighten the check nut to specifications. CAU TIO N : See Caution on Page 1 of this section. 5. Fully release parking brake and rotate the rear wheels. No drag should be present. 6 . Remove vehicle from hoist. Adjustment—Orscheln Lever Type 1. Turn adjusting knob on parking brake lever counterclockwise to stop. 2. Apply parking brake. 3. Raise vehicle on a hoist. 4. Loosen lock nut at intermediate cable equalizer and adjust front nut to give light drag at rear wheels. Tighten the check nut to specifications. CAUTIO N: See Caution on Page 1 of this section. 5. Readjust parking brake lever knob to give a definite snap-over-center feel. 5 -2 3 6 . Fully release parking brake and rotate rear wheels. No drag should be present. 7. Remove vehicle from hoist. PARKING BRAKE (PROPELLER S H AFT)INTERNAL EXPANDING Adjustment—Drum On 1. Jack up at least one rear wheel. Block wheels and release hand brake. 2. Remove cotter pin and clevis pin connecting pull rod and relay lever. This will assure freedom for full shoe release. CAUTIO N: It may be necessary to knock out lanced area in brake drum with punch and hammer to gain entry into adjusting screw through brake drum. Be sure all metal has been removedfrom parking brake compartment. 3. Rotate brake drum to bring one of access holes into line with adjusting screw at bottom of shoes. 4. Expand shoes by rotating adjusting screws with screwdriver inserted through hole in drum. Move outer end of screwdriver away from drive shaft. Continue adjustment until shoes are tight against drum and drum cannot be rotated by hand. Back off adjustment ten notches and check drum for free rotation. 5. Place parking brake lever in fully released position. Take up slack in brake linkage by pulling back on cable just enough to overcome spring tension. Adjust clevis of pull rod or front cable to line up with hole in relay levers. a. Insert clevis pin and cotter pin, then tighten clevis locknut. b. Install a new metal hole cover in drum to prevent contamination of brake. c. Lower rear wheels. Remove jack and wheel blocks. CAUTIO N: See "Caution" on Page 1 of this section. Adjustment—Drum Off 1. With parking brake drum off, use special Tool J-21177 or J-22364, Drum to Brake Shoe Clearance Gauge, to check diameter of drum clearance surface. 2. Turn the tool to the opposite side and fit over brake shoes by turning the star wheel until the gauge just slides over the linings. 3. Rotate the gauge around the brake shoe lining surface to insure proper clearance. 4. Install propeller shaft flange at mainshaft as outlined in transmission section. 5. Lower rear wheels. Remove jack and wheel blocks. LIGHT DUTY TRUCK SERVICE MANUAL 5 - 2 4 BRAKES C O M P O N E N T REPLACEMENT A N D REPAIRS SHOES AND LININGS—REAR DRUM BRAKES (Fig. 44) NOTE: If brake drums are worn severely, it may be necessary to retract the adjusting screw. To gain access to the adjusting screw star wheel, knock out the lanced area in the brake drum or flange plate using a chisel or similar tool. Release the actuator from the star wheel with a small screwdriver on models with access hole in flange plate or with a wire hook on models with hole in drum. Back off the star wheel with a second screwdriver (as shown in Figures 45 and 46). CAUTIO N: After knocking out the metal, be sure to remove it from the inside of the drum and clean all metal from the brake compart­ ment. A new metal hole cover must be 1. Raise the vehicle on hoist. 2. Loosen check nuts at forward end of parking brake equalizer sufficiently to remove all tension from brake cable. 3. Remove brake drums. CAUTION: The brake pedal must not be depressed while drums are removed. 4. Unhook brake shoe pull back springs from anchor pin and link end, using tool J-8049 (fig. 47). 5. Remove the actuator return spring. 6 . Disengage the link end from the anchor pin and then from the secondary shoe. 7. Remove hold-down pins and springs using any suitable tool (fig. 48). installed when drum is reinstalled. Drum brake lining can be inspected through slots in the flange plate. The portion of lining visible through the slot will not necessarily be the area of maximum wear and extra caution is necessary to make sure lining is replaced prior to the point where the remaining thickness, as viewed through the inspection slot, is as follows: Series 10 (bonded lining), 1/16" Series 20, 30 (riveted lining), 3/16" NOTE: Riveted linings should be replaced when worn within 1/32" of rivet heads. Removal NOTE: See Section 4 (Rear Suspension and Driveline) for non-demountable type hub and drum removal. PULL BACK SPRINGS Fig. 45--Flange Plate Access Hole PRIMARY SHOE Fig. 4 4 -Rear Brakes LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -2 5 2. Carefully pull lower edges of wheel cylinder boots away from cylinders and note whether interior is wet with brake fluid. Excessive fluid at this point indicates leakage past piston cups requiring overhaul of wheel cylinder. NOTE: A slight amount of fluid is nearly always present and acts as lubricant for the piston. 3. Inspect flange plate for oil leakage past axle shaft oil seals. Install new seals if necessary. 4. Check all brake flange plate attaching bolts to make sure they are tight. Clean all rust and dirt from shoe contact faces on flange plate (fig. 49), using fine emery cloth. Fig. 47-Unhooking Pull Back Spring 8 . Remove the actuator assembly. NOTE: The actuator, pivot and override spring are an assembly. It is not recom­ mended that they be disassembled for service purposes, unless they are broken. It is much easier to assemble and disassemble the brakes by leaving them intact. 9. Separate the brake shoes by removing adjusting screw and spring. CAUTIO N: Mark shoe and lining positions if they are to be reinstalled. 10. Remove parking brake lever from secondary brake shoe. Installation CAUTIO N: Make certain to install recom­ mended shoe and lining assemblies. 1. Inspect new linings and make certain there are no nicks or burrs or bonding material on shoe edge where contact is made with brake flange plate or on any of the contact surfaces. CAUTIO N: Keep hands clean while handling brake shoes. Do not permit oil or grease to come in contact with linings. 2. Lubricate parking brake cable with Delco Brake Lube #5450032 (or equivalent). 3. Lubricate fulcrum end of parking brake lever and the bolt with Delco Brake Lube #5450032 (or equivalent), then attach lever to secondary shoe with bolt, spring washer, lock washer and nut. Make sure that lever moves freely. Inspection 1. Clean dirt out of brake drum. Inspect drums for roughness, scoring or out-of-round. Replace or recondition drums as necessary. Fig. 48-Removing Hold Down Spring and Pin Fig. 49- Flange Plate Contact Surfaces LIGHT DUTY TRUCK SERVICE MANUAL 5 -2 6 BRAKES 4. Before installation, make certain the adjusting screw is clean and lubricated properly. CAUTION: Loose adjustment may occur from an adjusting screw that is not properly operating. If the lubrication in the adjusting screw assembly is contaminated or destroyed, the adjusting screw should be thoroughly cleaned and lubricated with Delco Brake Lube #5450032 (or equivalent). 5. Connect brake shoes together with adjusting screw spring, then place adjusting screw, socket and nut in position. CAUTION: Make sure the proper adjusting screw is used (left hand or right hand). The star wheel should only be installed with the star wheel nearest to the secondary shoe and the adjusting screw spring inserted to prevent interference with the star wheel. Make sure right hand thread adjusting screw is on leftside of car and left hand thread adjusting screw is on right side of car. Make certain star wheel lines up with adjusting hole inflange plate. anchor pin stud with the regular spring hook tool. Fasten the wire link to the actuator assembly first, and then place over the anchor pin stud by hand while holding the adjuster assembly infull down position. 11. Install actuator return spring. CAUTION: Do not pry actuator lever to install return spring. Ease it in place using the end of a screwdriver or other suitableflat tool. 12. If old brake pull back (return) springs are nicked, distorted, or if strength is doubtful, install new springs. 13. Hook springs in shoes using Tool J-8049 by installing the primary spring from the shoe over the anchor pin and then the spring from the secondary shoe over the wire link end (fig. 50). 14. Pry shoes away from the flange plate and lubricate shoe contact surfaces with a thin coating of Delco Brake Lube #5450032 (or equivalent). CAUTION: Be careful to keep lubricant off facings. If original shoe and lining assemblies are being reinstalled, they must be installed in original positions (as marked at removal). 6 . Install parking brake cable. 7. Secure the primary brake shoe (short lining faces forward) first with the hold down pin and spring using a pair of needle nose pliers. Engage shoes with the wheel cylinder connecting links. 8 . Install and secure the actuator assembly and secondary brake shoe with the hold down pin and spring using a pair of needle nose pliers. Position parking brake strut and strut spring. 9. Install guide plate over anchor pin. 10. Install the wire link. CAUTION: Do not hook the wire link over the 15. After completing installation, make certain the actuator lever functions easily by hand operating the self-adjusting feature (fig. 51). 16. Follow the above procedure for all brakes. 17. Adjust the service brakes and parking brake as outlined under "Maintenance and Adjustments" in this section. 18. Install drum, wheel and tire and lower the vehicle to floor. Test brake operation. Relining Brake Shoes If old brake shoes are to be relined, inspect shoes for distortion and for looseness between the rim and web; these are causes for discarding any shoe. If shoes are serviceable, be governed by the following points in installing new linings: 1. Remove old linings by drilling out rivets. Punching rivets out will distort shoe rim. Thoroughly clean FWD Fig. 5 0 -Installing Pull Back Spring Fig. 5 1 -Checking Actuating Lever LIGHT DUTY TRUCK SERVICE MANUAL BRAKES surface of shoe rim and file off any burrs or high spots. 2. Use released brake lining (or equivalent) and the rivets included in lining package which are of the correct size. The rivets must fit the holes with the solid body of rivet extending through the shoe rim, but no farther. CAUTION: Keep hands clean while handling brake lining. Do not permit oil or grease to come in contact with lining. 3. Start riveting at center of shoe and lining and work toward the ends. Use a roll set for reveting; a star set might split the tubular end and then the rivet would not fill the hole. The primary lining is shorter than secondary lining, therefore, the rivet holes at each end of the shoe rim are not used. 4. After riveting is completed, lining must seat snugly against shoe with no more than .005" separation midway between rivets. Check with a .004" (Go) and a .006 (No Go) feeler gauge. ANCHOR PIN REPLACEMENT Removal 1. Raise vehicle on a hoist. 2. Remove wheel and drum as outlined in this section. 3. Remove brake shoe pull back springs, link and guide plate. 4. Disengage anchor pin lock and remove pin from flange plate (Threaded type). Installation 1. Position anchor pin to flange plate, install lock washer and torque pin. Lock by peening over washer tabs. CAUTION: See Caution on Page 1 of this section. 2. Install brake shoe guide plate, link and pull back springs. 3. Adjust brakes, install drum and wheel as outlined previously in this section. 4. Lower vehicle and test brake operation. WHEEL CYLINDER CAUTION: Always use clean brake fluid to clean wheel cylinder parts. Never use mineralbase cleaning solvents such as gasoline, kerosene, carbon-tetrachloride, acetone, paint thinner or units of like nature as these solvents deteriorate rubber parts, causing them to become soft and swollen in an extremely short time. The wheel cylinder boots should be removed from a cylinder body only when they are visibly damaged or 5-27 leaking fluid. Wheel cylinders having torn, cut, or heatcracked boots should be completely overhauled. Wheel Cylinder Repair Wheel cylinders should not be disassembled unless they are leaking or unless new cups and boots are to be installed. It is not necessary to remove the wheel cylinder from the flange plate to disassemble, inspect, and overhaul the cylinder. Removal is necessary only when the cylinder is damaged or scored beyond repair. Removal 1. Place vehicle on hoist. 2. Remove wheel and tire assembly. Back off brake adjustment, if necessary, and remove drum. 3. Disconnect brake system hydraulic line from cylinder. 4. Remove brake shoe pull back springs. 5. Remove screws securing wheel cylinder to flange plate. Disengage cylinder push rods from brake shoes and remove cylinder. Disassembly (Fig. 52) 1. Remove boots from cylinder ends. 2. Remove pistons and cups. Inspection and Cleaning NOTE: Staining is not to be confused with corrosion. Corrosion can be identified with pits or excessive bore roughness. 1. Inspect cylinder bore. Check for staining and corrosion. Discard cylinder if corroded. 2. Polish any discolored or stained area with crocus cloth by revolving the cylinder on the cloth supported by a finger. Do not slide the cloth in a lengthwise manner under pressure. CAUTION: Before washing parts, hands must be clean. Do not wash hands in gasoline or oil before cleaning parts. Use soap and water to clean hands. 3. Wash the cylinder and metal parts in clean brake fluid. 4. Remove excess cleaning fluid from the cylinder. Do not use a rag to dry the cylinder as lint from the rag cannot be kept from the cylinder bore surfaces. 5. Check piston for scratches or other visual damage; replace if necessary. Assembly (Fig. 52) 1. Lubricate the cylinder bore with clean brake fluid and insert spring-expander assembly. 2. Install new cups with flat surface toward outer ends of cylinder. Be sure cups are lint and dirt free before insertion. Do not lubricate cups prior to assembly. LIGHT DUTY TRUCK SERVICE MANUAL 5 -2 8 BRAKES WARNING: A cracked drum is unsafe for further service and must be replaced. Do not attempt to weld a cracked drum. PUSH ROD AN D BOOT PISTON CUP RETURN SPRING WITH EXPANDERS WHEEL CYLINDER HOUSING PISTON CUP PISTON CUP BLEEDER SCREW PUSH ROD AN D BOOT Fig. 52 -Wheel Cylinder-Explode 3. Install new pistons into cylinder with flat surfaces toward center of cylinder. Do not lubricate pistons before installation. 4. Press new boots onto cylinder by hand. Do not lubricate boots prior to installation. Installation 1. Position wheel cylinder to brake flange plate. Install screws and tighten securely. CAUTION: See Caution on Page 1 of this section. 2. Install all push rods and pull back springs. 3. Connect hose or line to wheel cylinder. CAUTION: See Caution on Page 1 of this section. Install drum, wheel and tire assembly. 5. Bleed system as outlined in this section. 6 . Remove vehicle from hoist. 4. BRAKE DRUMS A lanced "knock out" area is provided in the brake flange plate or brake drum for servicing purposes in the event retracting of the brake shoes is required in order to remove the drum. A small screwdriver or hooked wire may be inserted to disengage the automatic adjuster actuating lever so the star wheel may be turned. Inspecting and Reconditioning Whenever brake drums are removed, they should be thoroughly cleaned and inspected for cracks, scores, deep grooves and out-of-round. Any of these conditions must be corrected since they can impair the efficiency of brake operation and cause premature failure of other parts. Smooth up any slight scores by polishing with fine emery cloth. Heavy or extensive scoring will cause excessive brake lining wear, and it will probably be necessary to refinish in order to true up the braking surface. If the brake linings are slightly worn and the drum is grooved, the drum should be turned just enough to remove grooves. The ridges in the lining should be lightly removed with a lining grinder. If brake linings are more than half worn but do not need replacement, the drum should be polished with fine emery colth but should not be turned. At this stage, eliminating all grooves in drum and smoothing the ridges on lining would necessitate removal of too much metal and lining, while if let alone, the grooves and ridges match and satisfactory service can be obtained. If drum is to be refinished for use with standard size brake facings which are worn very little, only enough metal should be removed to obtain a true smooth braking surface. A brake drum must not be refinished more than .060" over the maximum standard diameter. Out-Of-Round Or Tapered Drum A drum that is more than .006 out-of-round on the diameter will result in rough brake application and should be refinished. Out-of-round and the diameter can only be accurately measured with an inside micrometer fitted with proper extension rods. An out-of-round drum makes accurate brake shoe adjustment impossible and is likely to cause excessive wear of other parts of brake mechanism due to its eccentric action. An out-of-round drum can also cause severe and irregular tire tread wear as well as a pulsating brake pedal. When the braking surface of a brake drum exceeds the factory specification limits in taper and/or being out-of-round, the drum should be turned to true up the braking surface. Out-of-round as well as taper and wear can be accurately measured with an inside micrometer fitted with proper extension rods. When measuring a drum for out-of-round, taper and wear, take measurements at the open and closed edges of machined surface and at right angles to each other. Micrometer Method (Fig 53) 1. Place the brake drum on a smooth surface. 2. Using micrometers, place the tips at the center of the drum face. 3. While sweeping horizontally and vertically, slowly adjust the micrometer until maximum contact is made. Record this reading. 4. Rotate the drum 45 degrees and repeat Step 3. Continue until 4 readings have been made. The LIGHT DUTY TRUCK SERVICE MANUAL BRAKES difference between these 4 readings must not exceed .006. Cleaning New brake drums are given a light coating of rust proofing oil to prevent the formation of rust on the critical braking surfaces during the time that the drums are in storage. This rust proofing oil must be carefully removed before the drum is placed in service to prevent any of this oil from getting on the brake shoe facings. It is recommended that a suitable volatile, non-toxic, greaseless type solvent be used to clean the oil from the braking surface of the new brake drums before they are placed in service to insure the cleanest possible surface. Gasoline or kerosene should not be used as there is danger that a portion of the diluted oil substance may be left on the braking surface. NOTE: All brake drums have a maximum diameter cast into them. This diameter is the maximum wear diameter and not a refinish diameter. Do not refinish a brake drum that will not meet the specifications as shown below after refinishing. ORIGINAL DIAMETER 11.000 12.000 13.000 MAXIMUM REFINISH DIAMETER 11.060 12.060 13.060 REPLACEMENT (DISCARD) DIAMETER 11.090 12.090 13.090 SHOE AND LININGS—FRONT DISC BRAKE The brake linings should be inspected any time that the 5 -2 9 wheels are removed. Check both ends of the outboard shoe by looking in at each end of the caliper. This is the point at which the highest rate of wear normally occurs. At the same time, check the lining thickness on the inboard shoe by looking down through the inspection hole in the top of the caliper--See "Brake Inspection". The outboard shoes have ears near the outer edge which are bent over at right angles to the shoe. The top ends of the shoe have looped ears with holes in them which the caliper retaining bolts fit through. The large tab at the bottom of the shoe is bent over at a right angle and fits in the cut-out in the outboard section of the caliper. The inboard shoe and lining has ears on the top ends which fit over the caliper retaining bolts. A special spring inside the hollow piston supports the bottom edge of the inboard shoe. NOTE: Outboard shoes (with formed ears) are designed for original installation only and are fitted to the caliper. The shoes should never be relined or reconditioned for reinstallation. Removal 1. Remove master cylinder cover and observe brake fluid level in front reservoir. If reservoir is more than 1/3 full, siphon the necessary amount out to bring the level to 1/3 full; this step is taken to avoid reservoir overflow when the caliper piston is pushed back into its bore.) Discard the brake fluid removed. Never reuse brake fluid. i 2. Raise the vehicle and remove the front wheels. 3. Push the piston back into its bore. This can be accomplished by using a "C" clamp as shown in Figure 54, 4. Remove the two mounting bolts which attach the caliper to the support (fig. 55). 5. Lift the caliper off the disc. 6 . Remove the inboard shoe. Dislodge the outboard shoe and position the caliper on the front suspension arm so that the brake hose will not support the weight of the caliper. CAUTION: Mark shoe positions if they are to be reinstalled. 7. Remove the shoe support spring from the piston. 8 . Remove the two sleeves from the inboard ears of the caliper. 9. Remove the four rubber bushings from the grooves in each of the caliper ears. Cleaning and Inspection Fig. 53-Measuring Drum Diameter NOTE: The shoes should be replaced when the lining is worn to approximately 1/32" over the rivet heads. Replace shoes in axle sets. 1. Thoroughly clean the holes and the bushing grooves LIGHT DUTY TRUCK SERVICE MANUAL 5 -3 0 BRAKES Installation CAUTION: If original shoes are being reinstalled, they must be installed in original positions (as marked at removal). 1. Lubricate new sleeves, new rubber bushings, the bushing grooves and the end of the mounting bolts using Delco Silicone Lube #5459912 or equivalent (fig. 56). CAUTION: It is essential that new sleeves and rubber bushings be used and that lubrication instructions be followed in order to ensure the properfunctioning of the sliding caliper design. Fig. 54-"C " Clamp for Removal Aid in the caliper ears and wipe any dirt from the mounting bolts. CAUTION: Do not use abrasives on the bolts since this may damage the plating. If the bolts are damaged or corroded, they should be replaced. 2. Examine the inside of the caliper for evidence of fluid leakage. If leakage is noted, the caliper should be overhauled. 3. Wipe the inside of the caliper clean, including the exterior of the dust boot. Check the boot for cuts, cracks or other damage. CAUTION: Do not use compressed air to clean the inside of the caliper. This may cause the dust boot to become unseated. 2. Install the new rubber bushings in the caliper ears. 3. Install the new sleeves to the inboard ears of the caliper. NOTE: Position the sleeve so that the end toward the shoe and lining assembly is flush with the machined surface of the ear. 4. Install the}shoe support spring and the "inboard" shoe in the center of the piston cavity as shown in Figure 57. 5. Push down until the shoe lays flat against the caliper (fig. 58). 6 . Position the outboard shoe in the caliper with the ears at the top of the shoe over the caliper ears and the tab at the bottom of the shoe engaged in the caliper cutout. 7. With both shoes installed, lift up the caliper and rest the bottom edge of the outboard lining on the outer edge of the brake disc to make sure there is Fig. 5 6 -Lubrication Points LIGHT DUTY TRUCK SERVICE MANUAL BRAKES no clearance between the tab at the bottom of the outboard shoe and the caliper abutment. 8 . Position the caliper over the brake disc, lining up the hole in the caliper ears with the holes in the mounting bracket. NOTE: Make sure that the brake hose is not twisted or kinked. 9. Start the caliper to mounting bracket bolts through the sleeves in the inboard caliper ears and through the mounting bracket, making sure that the ends of the bolts pass under the retaining ears on the inboard shoe. 10. Push the mounting bolts through to engage the holes in the outboard shoes and the outboard caliper ears, threading the mounting bolts into the mounting bracket. 5-31 11. Torque the mounting bolts to 35 ft. lbs. CAUTION: See "Caution" on Page 1 of this section. 12. Pump the brake pedal to seat the linings against the rotors. 13. Using arc joint pliers, as shown in Figure 59, bend both upper ears of the outboard shoe until no radial clearance exists between the shoe and the caliper housing. Locate pliers on small notch of caliper housing during clinching procedure. CAUTION: If radial clearance exists after initial clinching, repeat Step 13. NOTE: Outboard shoes (with formed ears) are designed for original installation only and are fitted to the caliper. The shoes should never be relined or re-conditioned for reinstallation. 14. Reinstall the front wheel and lower the vehicle. 15. Add brake fluid to the master cylinder reservoir to bring the fluid level up to within 1/4 inch of the top. NOTE: Before moving the vehicle, pump the brake pedal several times to make sure that it is firm. Do not move vehicle until a firm pedal is obtained. Check master cylinder fluid level again after pumping the brake pedal. CALIPER OVERHAUL CAUTION: Always use clean brake fluid to clean any caliperparts. Never use mineral-base cleaning solvents such as gasoline, kerosene, carbon-tetrachloride, acetone, paint thinner or units of like nature as these solvents deteriorate rubber parts, causing them to become soft and swollen in an extremely short time. LIGHT DUTY TRUCK SERVICE MANUAL 5 -3 2 BRAKES Fig. 60--Caliper Explode Removal CAUTION: Clean dirt from hose to caliper connection beforeproceeding with removal. 1. Remove master cylinder cover and observe brake fluid level in front reservoir. If reservoir is more than 1/3 full, siphon the necessary amount out to bring the level to 1/3 full. This step is taken to avoid reservoir overflow when the caliper piston is pushed back into its bore. Discard the brake fluid removed. Never reuse brake fluid. 2. Raise the vehicle and remove the front wheels. 3. Push the piston back into its bore. This can be accomplished by using a "C" clamp as shown in Figure 54. 4. Remove the hose to caliper bolt and cap or tape the open connections to prevent dirt from entering the hose or caliper. Discard the copper gaskets. 5. Remove the caliper assembly and then remove the brake shoes from the caliper. CAUTION: Mark discpad locations ifpads are to be reinstalled. Disassembly 1. Clean the exterior of the caliper using clean brake fluid and place on a clean work surface. 2. Drain the brake fluid from the caliper. WARNING: Do not place the fingers in front of the piston in an attempt to catch or protect it when applying compressed air. 3. Using clean shop towels, pad the interior of the caliper and remove the piston by directing compressed air into the caliper inlet hole (fig. 61). CAUTION: Usejust enough airpressure to ease the piston out of the bore. Do not blow piston out of the bore. NOTE: An alternate method of removing the LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -3 3 primary sealing surface in the caliper assembly. It is manufactured and plated to close tolerances. Refinishing by any means or the use of any abrasive is not an acceptable practice. BRAKE FLUID INLET HOLE 4. Check the bore in the caliper for the same defects as the piston. The piston bore, however, is not plated and stains or minor corrosion can be polished with crocus cloth. AIR HOSE SHOP TOWELS CAUTIO N: Do not use emery cloth or any other form of abrasive. Thoroughly clean the caliper after the use of crocus cloth. If the bore cannot be cleaned up in this manner, replace the caliper. Assembly Fig. 61 -Removing Piston From Caliper piston is to stroke the brake pedal (gently) while the hydraulic lines are still connected. This will push the piston out of the caliper bore. 4. Using a screwdriver and caution so as not to scratch the piston bore, pry the dust boot out of the caliper piston bore. 5. Using a small piece of wood or plastic, remove the piston seal from its groove in the caliper piston bore. CAUTIO N: Do not use a metal tool of any kind for this operation as itmay damage the bore. 6 . Remove the bleeder valve from the caliper. 7. Remove and discard the sleeves and bushings from the caliper ears. Cleaning and Inspection CAU TIO N: The dust boot, piston seal, rubber bushings and sleeves are to be replaced each time that the caliper is overhauled. Discard these parts - do not bother to clean and inspect them. 1. Lubricate the caliper piston bore and the new piston seal with clean brake fluid. Position the seal in the caliper bore groove. 2. Lubricate the piston with clean brake fluid and assemble a new boot into the groove in the piston so that the fold faces the open end of the piston as shown in Figure 62. 3. Insert the piston into the caliper bore using care not to unseat the seal and force (50 to 100 pounds force required) the piston to the bottom of the bore. 4. Position the dust boot in the caliper counterbore and seat using Boot Installer Tool J-22904 as shown in Figure 63. CAUTIO N: Check the boot installation to make sure that the retaining ring moulded into the boot is not bent and that the boot is installed below the caliperface and evenly all around. 5. Install the bleeder screw and specifications. 1. Clean all parts (other than those mentioned above) in clean brake fluid. Use dry, filtered, compressed air to blow out all passages in the caliper and bleeder valve. torque to DU ST B O O T CAUTIO N: The use of lubricated shop air will leave a film of mineral oil on the metal parts. This may damage rubberparts when they come in contact after reassembly. 2. Check the mounting bolts for corrosion or other damage. Do not attempt to clean up the bolts. If they appear corroded - replace them. 3. Carefully examine the outside surface of the piston for scoring, nicks, corrosion and worn or damaged chrome plating. If any surface defects are detected, replace the piston. PISTON END OF GROOVE Fig. 6 2 -Installing Boot to Piston CAUTION: The piston outside diameter is the LIGHT DUTY TRUCK SERVICE MANUAL 5 -3 4 BRAKES Installation NOTE: Installation of the caliper and mounting parts (rubber bushings, sleeves, bolts, and shoe and lining assemblies) is the same as for: Brake Shoes and Linings except for the steps given below. 1. Connect the brake hose to the caliper using new copper gaskets. Torque connector bolt to specifications. CAUTIO N: Hose must be positioned in the caliper locating gate (between locating beads) to assure proper positioning to caliper. variation, flatness and parallelism are out of specifica­ tion. Scoring of the brake disc surfaces not exceeding .015 inch in depth, which may result from normal use, is not detrimental to brake operation. CAUTION: Both sides of the disc must be treated in the same manner. If one side needs resurfacing or reconditioning the opposite side should be treated in the same manner. REPLA C E if the disc cannot be reconditioned to bring it within specifications and meet the minimum thickness specification after reconditioning. CAUTION: All brake disc have a minimum thickness dimension cast into them. This dimension is the minimum wear dimension and not a refinish dimension. Do not refinish a brake disc that will not meet the specifications as shown below after refinishing: See "Caution" on page Iof this section. 2. Bleed the calipers using the method outlined earlier in this section. DISC SERVICING Servicing of the brake disc is extremely critical since accurate control of the disc tolerances is necessary to ensure proper brake operation. Brake discs can be refinished if precision equipment is available and a few simple rules are followed. The first thing to do is to determine which of the following will need to be done. RESURFACE, RECONDITION or REPLACE. R ESU R FA CE with a flat sanding disc (with disc rotating) if scoring is light or if the disc surface has severe rust scale. RECO N D ITIO N if scoring is deep or if runout, thickness MINIMUM THICKNESS AFTER REFINISHING REPLACEMENT (DISCARD) THICKNESS 1.230 .980 1.215 .965 Minimum Requirements The disc brake surfaces must meet the following specifications: 1. BOTH SU R FA C ES M UST BE SQUARE WITH BEARING C U P C E N T E R LIN E W ITH IN .003 T.I.R. To check, mount the hub and disc to the lathe on the bearing cups—Do not mount on hub surface (fig. 64). 2. FIN ISH IS TO BE 20-60 M ICR O -IN CH ES AND B O O T IN S T A L L E R J -2 2 9 0 4 D U ST BOOT Fig. 63 Installing Boot to Caliper Fig. 6 4 -Hub and Disc Mounting LIGHT DUTY TRUCK SERVICE MANUAL BRAKES M U ST NOT (D IR EC TIO N A L) 3. 4. 5. BE 5 -3 5 C IR C U M F E R E N T IA L The disc in Figure 65 has a preferred nondirectional finish that is achieved with a flat sanding disc. BOTH SU RFA CES M UST BE FLAT W ITHIN .002 T.I.R. This specification must be met to prevent surface taper that could wear shoes on an angle (fig. 66 ). M UST BE PA R A LLEL W ITH EACH O THER W ITHIN .003 T.I.R. WHEN C H E C K E D RADIALLY. Disc surfaces, which are not parallel, can cause shoes to wear on an angle (fig. 67). WHEN MOUNTED ON BEA RIN G C U PS, LA TER A L RUN-OUT M UST NOT E X C E ED .005 T.I.R. AND M AXIM UM RATE OF C H A N G E M U ST NOT EX C EED .001 IN 30 4 bearing adjusting nut until all of the play is out of the bearing. It should be just loose enough to allow the wheel to turn. Mark the disc with chalk every 30° (fig. 68 ). Fasten a dial indicator to some portion of the suspension so that the point of the stylus contacts the rotor face approx­ imately one inch from the rotor edge. Set the dial at zero and move the rotor one complete rotation, checking the indicator as the rotor moves. After checking the runout, readjust the wheel bearing (See Section 3). Proper lateral runout will prevent disc "wobble" that could knock the piston back into the caliper bore causing increased pedal travel. To check lateral runout, tighten the wheel 6. Fig. 65 -Disc Non-Directional Finish TO TA L C IR C U M FE R E N T IA L T H IC K N E S S VARIA­ TION AT ANY RAD IUS M UST NOT E X C E ED .0005 IN 360, Excessive disc thickness variation will cause brake pedal pulsation. To check for parallelism, measure the thickness of the rotor at four or more points around the circumference of the rotor. All measurements must be made at the same distance in from the edge of the rotor. Place indicators opposite each other and set to MARK DISC WITH CHALK EVERY 30° MAXIMUM RUN OUT .005 WITH MAXIMUM OF .001 IN 30° Fig. 6 8 -Checking Lateral Run-Out LIGHT DUTY TRUCK SERVICE MANUAL 5 -3 6 BRAKES 4. Connect the brake lines to the master cylinder. CAUTIO N: See "Caution" on page 1 of this section. 5. Fill the master cylinder reservoirs to the levels shown in Figure 31. Bleed the brake system as outlined in this section. 6 . If necessary, adjust the brake pedal free play as outlined in this section. MASTER CYLINDER OVERHAUL (Fig. 70) Disassembly 1. Remove the small secondary piston stop screw from the bottom of the front fluid reservoir of the master cylinder. Fig. 6 9 -Checking Circumferential Thickness Variation zero. As disc is rotated watch each indicator for proper tolerance. A micrometer could be used for this check. MASTER CYLINDER CAUTIO N: Always use clean brake fluid to clean any master cylinder parts. Never use mineral-base cleaning solvents such as gaso­ line, kerosene, carbon-tetrachloridem acetone, paint thinner or units of like nature as these solvents deteriorate rubber parts, causing them to become soft and swollen in an extremely short time. Removal 1. Wipe master cylinder and lines clean with a clean cloth. Place dry cloths below master cylinder areas to absorb any fluid spillage. 2. Disconnect hydraulic lines at master cylinder. Cover line ends with clean lint-free material to prevent foreign matter from entering the system. 3. Disconnect the push rod from the brake pedal. 4. Unbolt and remove the master cylinder from the dash panel (or power brake booster.) CAUTIO N: When placing the master cylinder in a vise, do not tighten too tightly as damage to the cylinder could result. 2. Place the master cylinder in the vise so that the lock ring can be removed from the small groove in the I.D. of the bore. Remove the lock ring and primary piston assembly. Remove the secondary piston, secondary piston spring and retainer by blowing air through the stop screw hole. If air is not available, a piece of wire may be used. Bend approximately 1/4" of one end of the wire into a right angle. Hook this end under the edge of the secondary piston and pull the secondary piston from the bore. NOTE: The brass tube-fitting insert should not be removed unless visual inspection indicates the insert is damaged. 3. To replace a defective insert the following procedure should be practiced: a. Place the master cylinder in a vise, so that the Installation 1. Assemble the push rod through the push rod retainer, if it has been disassembled. 2. Push the retainer over the end of the master cylinder. Assemble new boot over push rod and press it down over the push rod retainer. Slide new mounting gasket into position. Secure the master cylinder to the dash panel with mounting bolts. CAUTIO N : See "Caution" on Page 1 of this section. 3. Connect the push rod clevis to the brake pedal with pin and retainer. Fig. 7 0 -Master Cylinder- Explode LIGHT DUTY TRUCK SERVICE MANUAL BRAKES outlet holes are up. Enlarge the outlet holes in the tube seats using a 13/64" drill. Tape a 1/4" - 20 thread in these holes. Place a heavy washer over the outlet on the master cylinder and thread a 1/4" - 20 x 3/4" hex head bolt into the tube seat. Tighten the bolt until the tube seat is unseated. b. A more preferable way to remove a defective insert involves use of a self-tapping screw and a claw hammer. With a box-end or socket wrench, thread a # 6 - 32 x 5/8" long self- tapping screw into the tube-fitting insert. Using the claw end of the hammer, remove the screw and insert. 4. Remove the casting from the vise and inspect the bore for corrosion, pits and foreign matter. Be sure the outlet ports are clean. Inspect the fluid reservoirs for foreign matter. Check the bypass and compensating ports to the master cylinder bore to determine if they are unrestricted. 5. Remove the primary seal, primary seal protector and secondary seals from the secondary piston. Cleaning Use clean brake fluid to thoroughly clean all reusable brake parts. Immerse in the cleaning fluid and brush metal parts with hair brush to remove foreign matter. Blow out all passages, orifices and valve holes. Place cleaned parts on clean paper or lintfree clean cloth. If slight rust is found inside either the front or rear half housing assemblies, polish clean with crocus cloth or fine emery paper, washing clean afterwards. CAUTION: Be sure to keep parts clean until re­ assembly. Re-wash at re-assembly if there is any occasion to doubt cleanliness - such as parts dropped or left exposedfor eight hours or longer. IF there is any suspicion of contamination or any evidence of corrosion, completely flush the vehicle hydraulic brake system in accordance with this shop manual. Failure to clean the hydraulic brake system can result in early repetition of trouble. Use of gasoline, kerosene, anti-freeze, alcohol or any other cleaner, with even a trace of mineral oil, will damage rubber parts. Rubber Parts Wipe fluid from the rubber parts and carefully inspect each rubber part for cuts, nicks or other damage. These parts are the key to the control of fluid flow. If the unit is in for overhaul, or if there is any question as to the serviceability of rubber parts, REPLACE them. Badly damaged items, or those which would take extensive work or time to repair, should be replaced. In case of doubt, install new parts. Do not rely on the brake unit being overhauled at an early or proper interval. New parts will provide more satisfactory service, even if 5-37 the brake unit is allowed to go beyond the desired overhaul period. Assembly If the brass tube inserts were removed, place the master cylinder in a vise so that the outlet holes are up. Position the new brass tube inserts in the outlet holes, making sure they are not cocked. The recommended method of seating these inserts is to thread a spare brake line tube nut into each outlet and turn the nuts down until the insert bottoms. Remove the tube nut and check the outlet hole for loose brass burrs, which might have been turned up when the insert was pressed into position Each vehicle application of these cylinders is designed to produce the correct displacement of fluid from both the front and rear chambers under normal, failed and partially failed conditions. Cylinders are designed so that this variable displacement requirement is controlled within each bore size by the secondary piston. Because the pistons vary in length, it is necessary to mark them with identification rings. It is imperative that exact replacements be made when servicing the master cylinders. With all of the variables to be found in master cylinders, which look similar externally, it is important that the complete assemblies be properly identified. For this purpose a two-letter metal stamp will be found on the end of each master cylinder. This two-letter stamp indicates the displacement capabilities of that particular master cylinder. It is, therefore, mandatory that when master cylinders are replaced, they are replaced with cylinders bearing the same two-letter stamp. 1. Place new secondary seals in the two grooves in the flat end of the secondary piston assembly. The seal which is nearest the flat end will have its lip facing toward this flat end. On Delco units, the seal in the second groove should have its lips facing toward the end of the secondary piston which contains the small compensating holes. On Bendix units, the seal in the second groove is an "O " ring seal. 2. Assemble a new primary seal and primary seal protector over the end of the secondary piston opposite the secondary seals, so that the flat side of the seal seats against the flange of the piston which contains the small compensating holes. 3. In order to ensure a correct assembly of the primary piston assembly, a complete primary piston assembly is included in the repair kits. 4. Coat the bore of the master cylinder with clean brake fluid. Coat the primary and secondary seals on the secondary piston with clean brake fluid. Insert the secondary piston spring retainer into the secondary piston spring. Place the retainer and spring down over the end of the secondary piston so that the retainer locates inside the lips of the primary seal. 5. Hold the master cylinder with the open end of the LIGHT DUTY TRUCK SERVICE MANUAL 5 -3 8 BRAKES bore so that the spring will seat in against the closed end of the bore. Using a small wooden rod to push the secondary piston to seat. 6 . Place the master cylinder in a vise with the open end of the bore up. Coat the primary and secondary seals on the primary piston with clean brake fluid. Push the primary piston, secondary piston stop first, into the bore of the master cylinder. Hold the piston down and snap the lock ring into position in the small groove in the I.D. of the bore. CAUTION: Do not tighten vise too tightly as damage to the master cylinder could result. 7. Continue to hold the primary piston down. This will also move the secondary piston forward and will ensure that the secondary piston will be forward far enough to clear the stop screw hole, which is in the bottom of the front fluid reservoir. The stop screw is now positioned in its hole and tightened to a torque of 25-40 inch pounds. CAUTION: See "Caution" on Page I of this section. 8 . Install the reservoir diaphragm in the reservoir cover and install the cover on the master cylinder. Assemble the bail wire(s) into position to retain the reservoir cover. The master cylinder is now ready for "Bench Bleeding". MASTER CYLINDER Mounted Booster) (With Frame Removal (Fig. 71) 1. Wipe master cylinder and lines clean with a clean cloth. Place dry cloths below master cylinder to absorb any fluid spillage. 2. Disconnect hydraulic lines at master cylinder. Cover line ends with clean, lint-free material to prevent foreign matter from entering system. 3. Disconnect battery ground strap or stop light wires and brake warning switch wire. 4. Remove nuts, bolts, washers which fasten master cylinder to dash. Pull master cylinder straight off push rod and remove from engine compartment. 5. Remove and discard master cylinder push rod boot. 6 . Remove master cylinder cover and pour out fluid from reservoir. Pump the remaining fluid out by depressing piston. Disassembly 1. Remove cylinder cover bolt and gasket. 2. Lift off reservoir cover and cover seal. Pour out any excess fluid and stroke piston to force fluid through outlet ports. 3. Remove piston stop bolt and gasket from bottom of reservoir housing. 4. Use snap ring pliers and remove retainer ring from groove in end of cylinder bore. 5. Remove stop plate. 6 . All internal parts should slide easily out of cylinder bore. If they do not, apply compressed air carefully at front outlet port. If parts do not remove easily, examine bore carefully for extensive damage which may eliminate the possibility of reconditioning the master cylinder. Cleaning and Inspection Clean all parts in clean brake fluid. Inspect cylinder bore for scratches or corrosion. Minor blemishes can be removed with crocus cloth or a clean-up hone. Check by-pass ports in both reservoirs to make sure they are open and free of burrs. Remove and discard all rubber parts. All rubber parts are included in each repair kit. Assembly 1. Coat all parts with a liberal amount of clean brake fluid. 2. Install rubber seal cup on secondary piston with cup lip facing rear (open end of cylinder). NOTE: All other cup lips face in the opposite direction (closed end of cylinder.) 3. Stack and install secondary piston spring, pressure cup and piston in cylinder bore. 4. Install piston stop bolt and gasket, making sure screw enters cylinder bore behind rear of piston. 5. Assemble and install primary piston parts in cylinder bore. 6 . Install stop plate in cylinder bore. 7. Compress all parts in cylinder bore and install retainer ring in groove. 8 . Install reservoir cover and seal. Installation 1. Assemble new boot on brake pedal push rod. 2. Place master cylinder in position in engine compartment. Make certain that push rod and boot are in proper position. 3. Fasten master cylinder to dash with nuts, bolts, and washers. CAUTION: See " Caution " on Page 1 o f this section. 4. Connect brake lines to master cylinder. CAUTIO N: See " Caution " on Page 1 of this section. 5. Fill the reservoir with recommended brake fluid to level shown in Figure 31. 6 . Follow instructions under heading of "Bleeding Brakes". LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -3 9 4 1 Primary Piston Seal Cup 2 Primary Piston 3 Cover Seal 4 Reservoir Cover 5 Gasket 6 Cover Bolt 7 Intake Port 8 By-Pass Port 9 Reservoir Housing 10 Tube Seat 11 Secondary Piston Return Spring 12 Secondary Piston Pressure Cup 13 Floating Secondary Piston 14 Secondary Piston Seal Cup 15 Gasket 16 Stop Bolt 17 Prim ary Return Spring Retainer 18 Prim ary Return Spring 19 Prim ary Piston Stop Pin 20 Primarv Piston Pressure Cup 21 Stop Plate 22 Retainer Ring Fig. 71--Frame Mounted Booster Master Cylinder 7. If necessary, adjust the brake pedal free play as directed. 8 . Connect battery ground strap or stop light wires and brake warning switch wire (whichever was disconnected at removal). 9. Test brakes and make any necessary adjustments if operation is not satisfactory. Bleeding Tool (Fig. 72) A special tool for bleeding the frame mounted booster master cylinder is shown in Figure 72. It will be necessary for the technician to install his own bleeder adapter fitting to this tool. When bleeding the system, always bleed the frame mounted boosters before bleeding any wheel cylinders. BENCH BLEEDING MASTER CYLINDER 1. Install plugs in both outlet ports. NOTE: Plastic plugs that come with a Fig. 72 -Tool J-23339 Installed LIGHT DUTY TRUCK SERVICE MANUAL / 5 -4 0 BRAKES replacement cylinder are recommended for this operation. 2. Clamp the master cylinder in a bench vise with the front end tilted slightly down. CAUTION: Do not tighten vise too tightly as damage to the master cylinder could result. 3. Fill both reservoirs with clean brake fluid. 4. Insert a rod with a smooth round end to the primary piston and press in to compress the piston return spring. 5. Release pressure on rod. Watch for air bubbles in the reservoir fluid. 6 . Repeat Step 5 as long as bubbles appear. 7. Reposition master cylinder in vise so that the front end is tilted slightly up. 8 . Repeat Steps 4-5-6. 9. Install diaphragm and cover on reservoir. BRAKE COMBINATION VALVE Metering, Warning and Proportioning (Fig. 73) NOTE: The brake combination valve is a non-adjustable, non-serviceable valve. If defective it must be replaced. Function position (not allowed to close). This can be accomplished by installing Tool J-23709 under the mounting bolt and depressing the pin in the end of the valve. Be sure to re­ torque the mounting bolt after removing Tool J-23709 (fig. 29). Warning Switch The warning switch is the pressure differential type. It is wired electrically to the warning lamp on the instrument panel to warn the vehicle operator of a pressure differential between the front and rear hydraulic systems. Once the switch is activated "on", it will not "reset" until the defect in the hydraulic system has been repaired. Hydraulic reset to the "off" position occurs with the application of equal front and rear pressures. Proportioning Valve The function of this valve is prevent premature rear wheel slide. Line pressure is allowed to increase normally up to a certain point (determined by vehicle weight and braking distribution). When the predetermined pressure is reached, the valve begins to function and limit the amount of increase in hydraulic pressure passed to the rear brakes. This prevents the rear brakes from locking up before the full effective braking effort is produced by the front disc brakes. NOTE: In the event of "front hydraulic system failure" the proportioning valve has a "by-pass" feature that assures full system pressure to the rear brakes. Metering Valve Removal This section of the valve operates to "hold-off" hydraulic flow to the front disc brakes until a predetermined pressure is reached. This "hold-off" action allows the rear drum brakes to build up sufficient hydraulic pressure to overcome the force of their retracting springs. This metering or hold-off valve then provides for balanced braking. NOTE: When bleeding the brakes; the pin in the end of the metering portion of the combination valve must be held in the open 1. Disconnect electrical lead. 2. Place dry rags below valve to absorb any fluid spillage. 3. Wipe off any dirt and disconnect hydraulic lines from valve—cover open lines to prevent foreign matter from entering the system. 4. Remove mounting screws and remove valve. Installation 1. Make sure new switch is clean and free of lint. If any doubt exists, wash the switch in clean brake fluid. 2. Place new switch in position and secure with screws. CAUTION: See "Caution" on Page 1 of this SWITCH TERMINAL FROM MASTER CYLINDE FROM MASTER CYLINDER section. TO REAR BRAKES TO FRONT BRAKES 3. Connect hydraulic lines to valve. CAUTION: See "Caution" on Page 1 of this section. 4. Connect switch electrical lead. 5. Bleed the brake system. Fig. 73-Combination Valve LIGHT DUTY TRUCK SERVICE MANUAL BRAKES Brake Warning Light Checking 1. Set parking brake and turn the ignition key to "ON". 2. Warning lamp should light. 3. If lamp does not light, bulb is burned out or electrical circuit is defective. 4. Turn ignition key off. 5. Replace bulb or repair circuit as necessary. Testing Warning Switch 1. Raise vehicle on a hoist and attach a bleeder hose to a rear brake bleed screw and immerse the other end of hose in a container partially filled with clean brake fluid. Be sure master cylinder reservoirs are full. NOTE: When bleeding the brakes; the pin in the end of the metering portion of the combination valve must be held in the open position (not allowed to close). This can be accomplished by installing Tool J-23709 under the mounting bolt and depressing the pin a slight amount. Be sure to re-torque the mounting bolt after removing Tool J-23709 (fig- 29). CAUTIO N: See " Caution" on Page 1 of this section. 2. Turn ignition key "ON". Open bleed screw while helper applies heavy pressure to brake pedal. Warning lamp should light. Close bleed screw before helper releases pedal. NOTE: To "reset" switch, apply heavy pedal force. This force will apply hydraulic pressure which re-centers the switch contact. 3. Attach bleeder hose to front brake bleed screw and repeat Step 2. 4. Turn ignition key off. See Note under Step 2. 5. Lower vehicle to floor. NOTE: If warning lamp does not light during Steps 2 and 3 but does light when the parking brake is set, warning light switch is defective. Do not attempt to repair switch. A defective switch must be replaced with a new combination valve assembly. 5-41 boosters have an electrical switch that senses pedal travel. This switch will illuminate the lamp on the instrument panel whenever the brake pedal is in excess of 5.10 inches. Removal 1. Loosen the nut (at the switch) on the failure warning switch push rod and drop the push rod out of the way. 2. Remove the switch electrical lead. 3. Remove the two switch mounting screws and remove switch. Installation 1. Install the switch to the brake pedal bracket with two screws and install the electrical lead. 2. Check the length of the failed switch push rod to see that it is as described in Figure 74. 3. Adjust the switch so that the warning light will be on after 5.10" pedal pad travel in the following manner. NOTE: The brake pedal to master cylinder push rod will have to be removed to make test to determine if the switch is properly set. Adjust the brake pedal push rod travel as described in this section upon completion of installation. 4. With brake pedal hard against rubber bumper (A), rotate brake failure warning switch lever (B) forward and insert the preassembled push rod (C) in the switch and brake pedal and lock in place. CAUTIO N: Caution should be taken to prevent air from entering system during checks on switch. The recommended checking interval should be 24 months or 24,000 miles, any time major brake work is done or any time a customer complains of excessive pedal travel. BRAKE TRAVEL WARNING SWITCH (Fig. 74) Vehicles with frame mounted vacuum over hydraulic LIGHT DUTY TRUCK SERVICE MANUAL 5 -4 2 BRAKES I f Switch Circuit is Closed a. Rotate switch bracket rearward until switch "just opens" (light off). b. Hold switch bracket in this position and tighten bolt (D). Switch should close (light on) at 5.10" brake pedal pad movement from full back. I f Switch Circuit is Open a. Rotate switch bracket forward until switch "just closes" (light on). b. Hold switch bracket in this position and tighten bolt (D). BRAKE PEDAL—SERVICE BRAKE (Fig. 75) NOTE: The brake pedal is an integral design with the clutch pedal (except automatic transmission), necessitating the removal of the clutch pedal before removing the brake pedal. Removal 1. Remove the pull back spring from the body or brake pedal support bracket. 2. Manual Transm ission Vehicles-Rem ove the clutch pedal as outlined under "Clutch Pedal" in Section 7. Automatic Transm ission Vehicles-Rem ove pedal pivot bolt nut or pivot pin retainer and remove bolt or pin and bushings. 3. P Models-Remove the sleeve assembly screw attachment and remove sleeve. 4. Disengage the push rod from the master cylinder and remove the pedal. Inspection Clean all parts and inspect for wear, cracks or any other damage that might impair operation; replace if required. Installation Reverse the above procedure and make certain the brake pedal is secure and adjusted properly before operating the vehicle. Lubricate pedal pivot bushings and pivot pin, bolt or sleeve with Delco Brake Lube #5450032 (or equivalent). CAUTIO N: See " Caution" on Page 1 of this section. PARKING BRAKE PEDAL OR HANDLE Removal (Fig. 76) 1. Place parking brake pedal or handle in the released position. 2. Remove nuts from the engine compartment on C, K and G models or bolts from mounting bracket on P models. 3. Disconnect the release handle rod at the parking brake assembly end (C-K models). 4. Remove the bolts from the underside of the dash and lower the brake assembly. NOTE: Take notice of the spacers on P models for reinstallation. 5. Remove the clevis pin and disconnect the cable from the brake assembly. Installation Reverse the removal procedure. Torque all bolts and nuts. After installing the clevis pin, use a new cotter pin to secure the clevis pin. Adjust the cable if necessary as outlined under "Maintenance and Adjustments". CAUTIO N: See "Caution" on Page 1 of this section. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -4 3 VIEW C-K MODELS POOO (42) MODELS (v G MODELS iew P300 (32) MODELS Fig. 76-Parking Brake Assembly-Typical PARKING BRAKE CABLES Refer to Figure 77 for routing of cables. i PARKING BRAKE-PROPELLER SHAFT— (Internal Expanding) Removal (Fig. 78) 1. Remove the propeller shaft; see Section 4. 2. Remove the brake drum. NOTE: It may be necessary to back off the shoe adjustment before removing the drum. 3. Remove the two pull back springs. 4. Remove the guide plate from anchor pin. 5. Remove shoe hold down cups, springs, and washers from hold down pins—remove pins. 6 . Pull brake shoe and lining assemblies away from anchor pin and remove the strut and spring. 7. Lift the brake shoes and linings with the adjusting nut and bolt and connecting spring off the flange plate. 8 . Move the shoes toward each other until the adjusting bolt and connecting spring drop off. 9. Remove the clip holding the brake lever to the primary shoe (shoe with short lining). 10. Compress the spring on the brake cable and remove the cable from the lever. 11. If necessary to remove the anchor pin, straighten the washer from pin hex and reinforcement. Remove reinforcement and washer with anchor pin. 12. If necessary to remove the cable, compress tangs on cable and pull assembly out of the hole in the flange plate. 13. If necessary to remove the flange plate, remove the transmission flange nut and transmission output flange. Remove bolts holding the flange plate to bearing retainer and remove the flange plate. LIGHT DUTY TRUCK SERVICE MANUAL 5 -4 4 BRAKES C MODELS G MODELS P MODELS Fig. 77-Parking Brake System LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-45 RETURN SPRINGS WAVE WASHER BRAKE LEVER HOLD DOWN PIN DRUM HOLD D O W N WASHER. SPRING , CUP BACKING PLATE BRAKE CABLE Fig. 7 8 -Internal Expanding Brake Components Inspection Replace any worn or broken parts. Installation 1. Place the flange plate in position on the rear bearing retainer and fasten with four bolts. Torque bolts to 24 foot pounds. CAUTION: See "Caution" on Page I of this section. 2. Install transmission output flange on spline of mainshaft and fasten with flange nut. Torque nut to 100 foot pounds. CAUTION: See " Caution" on Page 1 of this section. 3. Install cable assembly from back of flange plate. Push retainer through hole in flange plate until tangs securely grip the inner side of the plate. 4. Place washer and reinforcement over the threaded end of anchor pin. Hold anchor pin nut (flat side against flange on flange plate) in position behind flange plate and insert threaded end of anchor pin from front side. Thread the anchor pin into nut and tighten securely (140 foot pounds torque). Bend tang of washer over reinforcement and side of washer over hex of anchor pin. CAUTION: See " Caution" on Page 1 of this section. 5. Install lever on cable by compressing spring and inserting cable in channel of lever. Release spring. 6 . Install primary shoe (short lining) to lever as follows: Place pin in lever, place washer on pin and push pin through hole in primary shoe. Fasten parts together by installing the clip in groove of pin. CAUTION: See "Caution" on Page 1 of this section. 7. Fasten two brake shoes and linings together by installing connecting spring. Move the shoes toward each other and install adjusting screw. 8 . Lubricate the flange plate contact surfaces with a very light coat of Delco Brake Lube #5450032 (or equivalent). 9. Place shoe and linings in position on flange plate. NOTE: When facing the brake assembly, the shoe with the short lining should be to the left with the lever assembled to it. 10. Pull brake shoes apart and install strut lever and spring between them. The loop on the strut spring should be in the "up" position. 11. Install hold down pins, washers, springs and cups from flange plate to shoes. LIGHT DUTY TRUCK SERVICE MANUAL 5 -4 6 BRAKES 12. Place guide plate on anchor pin. 13. Install pull back springs. 14. Remove the "knock out" plug (if necessary) and install a new metal plug in the brake drum adjusting hole. 15. Install the brake drum. 16. Install the propeller shaft. REAR BRAKES RPO H-22 (Fig. 79) Brake shoe adjustment takes place when brakes are applied with a firm pedal effort while the vehicle is backing up. Applying the brakes moves actuators which turn the star wheels and rotate the adjusting screws outward from the anchor brackets. This action adjusts the shoe until clearance between the lining and drum is within proper limits. Should low pedal heights be encountered, it is recommended that numerous forward and reverse stops be performed with a firm pedal effort until a satisfactory pedal height results. Retracting Self Adjusters Access holes are located in the flange plate. These holes are for service purposes in the event retracting of the brake shoes is required to remove the drum. In order to back off the adjuster, insert a screwdriver, index a corner of the screwdriver blade with the hole in the actuating lever and hold the lever away from the star wheel. Using a brake adjusting tool, back off the star wheel. Brake Drums, Shoes and Linings 3. Using Tool J-22348, remove the brake shoe pull back springs (fig. 80). 4. Loosen the actuating lever cam cap screw and while holding the star wheel end of the actuating lever past the star wheel, remove the cap screw and cam. 5. Remove the brake shoe hold down springs and pins by compressing the spring with Tool J-22348 and, at the same time, pushing the pin back through the flange plate toward the tool. Then, keeping the spring compressed, remove the lock from the pin with a magnet (fig. 81). 6 . Lift off the brake shoe and self adjuster as an assembly. 7. The self adjuster can now be removed from the brake shoe by removing the hold down spring and pin. NOTE: The actuating lever, override lever and spring are an assembly. It is recom­ mended that they not be disassembled for service purposes unless they are broken. It is much easier to assemble and disassemble the brakes leaving them intact. 8 . Thread the adjusting screw out of the anchor support and remove and discard the friction spring. 9. Clean all dirt out of brake drum. Inspect drums for roughness, scoring or out-of-round. Replace or recondition drums as necessary. NOTE: See Section on "BRAKE DRUMS". 10. Carefully pull lower edges of wheel cylinder boots Removal 1. Raise the vehicle on a hoist. 2. Retract self adjusters if necessary and remove brake drums. ANCHOR SUPPORT x A C T U A T IN G LEVER CAM A C T U A T IN G LEVER LINK FRICTIO N SPRING OVER RIDE ' LEVER OVER RIDE SPRING RETURN SPRING HO LD D O W N PIN STAR W HEEL A C T U A T IN G LEv e r Fig. 79 -Rear Brake-Used with RPO H-22 Fig. 8 0 -Removing Pull Pack Spring with Tool J-22348 LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -4 7 Fig. 81-Removing Hold Down Pins Using J-22348 away from cylinders. If brake fluid flows out, overhaul of the wheel cylinders is necessary. NOTE: A slight amount of fluid is nearly always present and acts as a lubricant for the piston. 11. Inspect flange plate for oil leakage past axle shaft oil seals. Install seals if necessary. 12. Check all flange plate attaching bolts to make sure they are tight (150 ft. lbs. torque). Clean all dirt and rust from shoe contact faces on flange plate using emery cloth. 13. Thoroughly clean adjusting screws and threads in the anchor brackets. Fig. 82-Brake Shoe and Self Adjuster Assembly Installation 1. Put a light film of Delco Brake Lube #5450032 (or equivalent) on shoe bearing surfaces of brake flange plate and on threads of adjusting screw. 2. Thread adjusting screw completely into anchor bracket without friction spring to be sure threads are clean and screw turns easily. Then remove screw, position a new friction spring on screw and reinstall in anchor bracket. CAUTION: section. See "Caution" on Page 1 of this 3. Assemble self adjuster assembly to brake shoe and position actuating lever link on override lever. 4. Position hold down pins in flange plate. 5. Install brake shoe and self adjuster assemblies onto hold down pins, indexing ends of shoes with wheel cylinder push rods and legs of friction springs. NOTE: Make sure the toe of the shoe is against the adjusting screw (fig. 82). 6 . Install cup, spring and retainer on end of hold down pin. Using Tool J-22348, compress the spring. With spring compressed, push the hold down pin Fig. 83 Measuring Points for Shoe Centering back through the flange plate toward the tool and install the lock on the pin. 7. Using Tool J-22348, install brake shoe return springs. 8 . Holding the star wheel end of the actuating lever as far as possible past the star wheel, position the adjusting lever cam into the actuating lever link and assemble with cap screw. 9. Check the brake shoes for being centered by measuring the distance from the lining surface to LIGHT DUTY TRUCK SERVICE MANUAL 5 -4 8 BRAKES ACTUATING LEVER---------► TOP VIEW ACTUATING LEVER END VIEW Fig. 84 -Positioning Actuator Lever the edge of the flange plate at the points shown in Figure 83. To center the shoes, tap the upper or lower end of the shoes with a plastic mallet until the distances at each end become equal. 10. Locate the adjusting lever .020" to .039" above the outside diameter of the adjusting screw thread by loosening the cap screw and turning the adjusting cam. NOTE: To determine .020" to .039", turn the adjusting screw 2 full turns out from the fully retracted position. Hold a .060" plug gauge (from J-9789-01 Universal Carburetor Gauge Set) at a 90° angle with the star wheel edge of the actuating lever. Turn the adjusting cam until the actuating lever and threaded area on the adjusting screw just touch the gauge (figs. 84 and 85). Fig. 85-Pull Gauge Positioning for Correct Actuator Lever Adjustment 11. Secure the adjusting cam cap screw and retract the adjusting screw. 12. Install brake drums and wheels and remove vehicle from jack stands. 13. Adjust the brakes by making several forward and reverse stops until a satisfactory brake pedal height results. D IA G N O S IS INSPECTION At a reasonably frequent interval, the brake system should be inspected for pedal reserve, which is the clearance between the pedal pad and the fioorpan. Inspection should be made with the brake pedal firmly depressed while the brakes are cold. Pedal reserve on manual brake vehicles is usually not less than 2-1/4". On power brake-equipped vehicles, the pedal reserve is usually not less than 1- 1/ 2 ". NOTE: Heat generated by high speed stops will expand brake drums and increase shoe clearance, thereby permitting the pedal pad to go closer to the fioorpan than when the brakes are cold. Brake shoe linings should not be permitted to wear down until rivets or shoes contact drums because the drums could be scored. As the vehicle mileage approaches the point where relining may be required it is advisable to remove one or more drums for inspection of linings in order to avoid the possibility of damaging brake drums. LIGHT DUTY TRUCK SERVICE MAmJAL BRAKES PRELIMINARY CHECKS External Conditions That Affect Performance In addition to previously mentioned conditions, the following external conditions may affect brake perform­ ance and should be corrected before work is done on the brake mechanism. Tires Tires having unequal contact and grip on the road could cause unequal braking. Tires should be equally inflated and tread pattern of right and left tires should be approximately equal. Loading When the vehicle has unequal loading, the most heavily loaded wheels require more braking power than others. Shock Absorbers Faulty shock absorbers that permit bouncing of the vehicle on quick stops may give the erroneous impression that brakes are too severe. General Checks NOTE: If a damaged component or malfunc­ tion is discovered while making any of the following brake system checks, repairs must be made before attempting to continue with additional diagnosis. 1. Inspect for excessive tire tread wear and indications of front suspension misalignment. Check tire pressures and for improperly adjusted or worn wheel bearings. Any of these conditions can result in an improper diagnosis. 2. Check master cylinder fluid level. If low, refill to the proper level, pressurize the system, and make an inspection of the entire brake system for leakage. Wheel cylinder leakage can frequently be detected by the presence of brake fluid on the inboard side of the wheel and tire. 3. Power Brake: a. With transmission in Park, stop the engine, and exhaust all vacuum in the system by depressing the pedal several times. b. Depress the brake pedal and hold it in the apply position for one minute with approximately 20 lbs. pedal force. If the pedal gradually falls away or the brake warning light comes on, it is an indication that the hydraulic system is leaking or that there is a malfunction in the master cylinder. Check all tubing, hoses, wheel cylinders, calipers and connections for leakage before replacing the master cylinder. c. If the brake pedal feels spongy, it is an indication of air in the hydraulic system. Bleed the air from the system and recheck the pedal feel. NOTE: Steps (b) and (c) may also be used to 5 -4 9 check for leakage or the presence of air in a non-vacuum powered brake system. d. Depress the brake pedal and start the engine. If the vacuum system is operating, the brake pedal will tend to fall away when the engine starts and less pedal pressure will be needed to hold it in the applied position. If no action is felt when the engine starts, the vacuum system is inoperative. ROAD TESTING CAUTION: A road test should be made only when the operator is sure that the brakes will stop the vehicle. Road tests are necessary to check brakes for safe, quiet performance. Preliminary inspection should be made in the shop as outlined in the preceding paragraphs. The following tests will aid in the evaluation of brake performance and the need for service. They should be conducted on dry, clean, reasonably smooth and level roadway. Use care not to induce fade unintentionally with continuous applications during test. Refer to the Troubleshooting Chart for causes and remedies for trouble which may be discovered during testing. WARNING: Before driving any vehicle, push the brake pedal to make sure it will not bottom. Next, make a series of slow speed stops to determine if the brakes are safe for driving. Low Speed Test for Effectiveness, Pulls and Noise fkS . Make light and medium stops at from 10 to 15 MPH. Bring the vehicle to a complete stop each time. Observe the effort required to make each stop. Is it too light (grabby) satisfactory or too hard? Check for pulls. Unequal front brakes will cause pulls in the direction of the brake doing the most work. Unequal rear brakes may not cause noticeable pulling during low speed stops. Check for noise. Open the windows and turn off all accessories and listen to determine the type of noise and the wheel from which it is coming. NOTE: Driving along a wall when applying brakes will make noises more audible. High Speed Test for Roughness or Pulsations Make light stops from 60 MPH or maximum legal speed. Check for roughness or pulsations by pedal feel and vehicle vibration. High Speed Test for Effectiveness, Pulls and Noise Make hard stops (just short of skid) from 60 MPH. Bring LIGHT DUTY TRUCK SERVICE MANUAL 5 -5 0 BRAKES the vehicle to a complete stop each time. Do not repeat stops within two miles of each other to avoid high brake temperatures. Observe the effort required to make each stop. Is it too light (grabby), satisfactory or too hard? Check for pulls. Unequal brakes will cause pulls in the direction of the brake doing the most work. Check for noise to determine the type and the wheel from which it is coming. High Speed Test for Fade NOTE: Fade is a temporary reduction of brake effectiveness resulting from heat. Make three hard stops (just short of skid) from 60 MPH at 1/2 mile increments or just as fast as possible. Check for pulls and observe the effort required to make the stops. These should be made without strenuous effort. Check pedal reserve after each stop. High Speed Test for Delayed Fade After making previous fade test, let the vehicle stand for 10 minutes. Then, accelerate quickly to 60 MPH and make one hard stop, just short of a skid. Check for pulls and observe the effort required to make the stop. Check pedal reserve. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5-51 DIAGNOSIS—DRUM BRAKES LOW PEDAL OR PEDAL GOES TO TOE BOARD Probable Cause Remedy 1 . Excessive clearance between l i n i n g s and drum. 1 . A djust brakes. 2. Automatic a d ju s te rs not working. 2. Make forward and reverse stops; i f pedal stays low, r e p a i r f a u l t y a d ju s te r s . 3. . Leaking conduits. 3. Repair or repla ce f a u l t y p a rts . 4. Leaking wheel c y l i n d e r . 4. Overhaul wheel c y l i n d e r , as o u t lin e d p re v io u s ly in t h i s s e c tio n . 5. Leaking master c y l i n d e r . 5. Overhaul master c y l i n d e r as o u t lin e d p re v io u s ly in t h i s s e c tio n . 6. A i r in system. 6. Bleed system. 7. Plugged master c y li n d e r f i l l e r cap. 7. Clean f i l l e r cap vent hole s; bleed system. 8. Improper brake f l u i d . 8. Flush system and r e f i l l w ith GM Hydraulic Brake F lu id Supreme No. 11 (o r e q u i v a le n t ) . 9. Low f l u i d l e v e l . 9. F i l l r e s e r v o ir w ith GM Hydraulic Brake F lu id Supreme No. 11 (o r e q u i v a le n t ) ; bleed system. SPRINGY, SPONGY PEDAL Probable Cause Remedy 1 . A i r trapped in h y d ra u lic system. 1 . Remove a i r by ble e din g. 2. Improper brake f l u i d . 2. Flush and bleed system using GM Hydra ulic Brake F lu id Supreme No. 11 (o r e q u iv a le n t ) . 3. Improper l i n i n g thickness or lo c a t io n . 3. I n s t a l l new l i n i n g o r replace shoe and l i n i n g . 4. Drums worn too t h i n . 4. Replace drums. 5. Master c y li n d e r f i l l e r vent clogged. 5. Clean vent or repla ce cap; bleed brakes. E X C E SSIV E PED A L PRESSU RE REQ U IRED TO STOP V E H IC LE Probable Cause Remedy 1 . Brake adjustment not c o r r e c t . l 2. I n c o r r e c t l i n i n g . 2. I n s t a l l new l i n i n g s . 3. Grease or f l u i d soaked l i n i n g . 3. Repair grease seal or wheel c y l i n d e r . 1in in g s . 4. Improper f l u i d . . 4. A djust the brakes. In s ta ll new Flush out system; f i l l w ith GM Hydraulic Brake F lu id Supreme No. 11 (o r e q u i v a le n t ) ; bleed system. 5. Frozen master or wheel c y li n d e r p is to n s . 5. Overhaul master or wheel c y li n d e r s as o u t lin e d p r e v io u s ly in t h i s s e c tio n . 6. Brake pedal bindin g on s h a f t . 6. L u b rica te w ith Delco Brake Lube #5450032 (or e q u iv a le n t). LIGHT DUTY TRUCK SERVICE MANUAL 5 -5 2 BRAKES DIAGNOSIS—DRUM BRAKES EXCESSIVE PEDAL PRESSURE REQUIRED TO STOP VEHICLE (CONT.) Remedy Probable Cause 7. Glazed 1in in g s. 7. Sand surface o f l i n i n g s . 8. Bellmouthed, barrel-shaped or scored drums. 8. Replace or resu rfa ce drums in l e f t and r i g h t hand p a ir s . LIGHT PEDAL PRESSURE-BRAKES TOO SEVERE Probable Cause Remedy 1. Brake adjustment not c o r r e c t. 1. A djust the brakes. 2. Loose fla n ge p la te on f r o n t axle . 2. Tighten p la te s . 3. A small amount o f grease or f l u i d on l i n i n g s . 3. Replace the l i n i n g s . 4. Charred l i n i n g s . 4. Replace the 1in in g s . 5. In c o r r e c t 1 in i r i g . 5. I n s t a l l new l i n i n g s . 6. Wheel bearings loose. 6. Adjust wheel bearings. 7. Linin g loose on shoe. 7. Replace l i n i n g o r shoe and l i n i n g . 8. Excessive dust and d i r t in drums. 8. Clean and sand drums and l i n i n g s . 9. Bellmouthed, barrel-shaped or scored drums. 9. Turn drums in p a irs or repla ce. BRAKE PEDAL TRAVEL DECREASING Probable Cause Remedy 1. Master c y li n d e r compensating p o rt plugged. 1. Open, use a i r or .015 w ir e . 2. Swollen cup in master c y li n d e r . 2. Replace rubber p a r ts . Flush system. R e f i l l w ith GM Hydraulic Brake F lu id Supreme No. 11 (or e q u iv a le n t ) . 3. Master c y li n d e r p isto n not re tu r n in g . 3. Overhaul master c y li n d e r as o u t lin e d p re v io u s ly in t h i s s e c tio n . 4. Weak shoe r e t r a c t i n g s pring s. 4. Replace spring s. 5. Wheel c y li n d e r pistons s t i c k i n g . 5. Overhaul wheel c y li n d e r as o u t lin e d p r e v io u s ly in t h is s e c tio n . Remove any b u rr in bore. PULSATING BRAKE PEDAL Remedy Probable Cause 1. Drums o u t-o f-ro u n d . 1. Re finis h drums. 2. Loose brake drum on hub. 2. Tighten. 3. Worn or loose wheel bearings. 3. Replace or a d ju s t. 4. Bent rear axle . 4. Replace axle. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -5 3 DIAGNOSIS—DRUM BRAKES ‘ BRAKES FADE Probable Cause Remedy 1. I n c o r r e c t l i n i n g . 1. Replace w ith new l i n i n g . 2. Thin drum. 2. Replace drums. 3. Dragging brakes. 3. A djus t or c o r r e c t cause. *Fade is a temporary re d u c tio n o f brake e ffe c tiv e n e s s r e s u l t i n g from heat. ALL BRAKES DRAG WHEN ADJUSTMENT IS KNOWN TO BE CORRECT Probable Cause Remedy 1. Pedal does not r e t u r n to s top. 1. Lu brica te the pedal w ith Delco Brake Lube #5450032 (or e q u i v a l e n t ) . 2. 2. Replace rubber pa rts and f i l l w ith GM Hydra ulic Brake F lu id Supreme No. 11 (or e q u iv a le n t ) . Improper f l u i d . 3. Compensating or bypass p o r t o f master c y l i n d e r closed. 3. Open w ith compressed a i r . 4. Use o f i n f e r i o r rubber p a r ts . 4. Overhaul wheel and/or master c y li n d e r using new Delco k i t s (or e q u i v a l e n t ) . ONE WHEEL DRAGS Probable Cause 1 . Weak or broken shoe r e t r a c t i n g s pring s. 2. Brake shoe to drum clearance too small or the brake shoe e cc e n tric is not adjusted p ro p e rly . Remedy 1 . Replace the d e f e c t iv e brake shoe springs and l u b r i c a t e the brake shoe ledges w ith Delco Brake Lube #5450032 (or e q u iv a le n t ) . 2. A d ju st. 3. Loose wheel be arings. 3. A djus t wheel bearings. 4. Wheel c y li n d e r pisto ns cups swollen and d i s t o r t e d or the pistons stu ck. 4. Overhaul c y lin d e r s as o u t lin e d p re v io u s ly in t h is s e c tio n . 5. Pistons s t i c k i n g in wheel c y l i n d e r . 5. Clean or repla ce p is to n s ; clean c y li n d e r bore. 6. Drum o u t - o f - r o u n d . 6. Grind or t u rn both rea r drums. 7. O bstructio n in l i n e . 7. Clean ou t or rep la ce. 8. Loose anchor pin . 8. A djust and t ig h t e n lo ck nut. 9. D is to rte d shoe. 10. Defe ctiv e 1in in g . 9. Replace 10. Replace w ith new l i n i n g . LIGHT DUTY TRUCK SERVICE MANUAL 5 -5 4 BRAKES DIAGNOSIS—DRUM BRAKES REAR BRAKES DRAG Remedy Probable Cause 1. Maladjustment. 1. Adjust brake shoes and parking brake mechanism. 2. Parking brake cables frozen . 2. Lu bricate w ith Delco Brake Lube #5450032 (or e q u i v a le n t ) . V E H IC LE P U LLS TO ONE SID E Probable Cause Remedy 1. Grease or f l u i d soaked l i n i n g . 1. Replace w ith new l i n i n g s . 2. Adjustment not c o r r e c t . 2. Adjust the brakes. 3. Loose wheel bearings, loose fla n g e p la te on rear axle or f r o n t axle or loose sp ring b o lt 6 . 3. A djus t the wheel bearing, tig h t e n the fla nge p la t e on the re a r and f r o n t axles and t ig h t e n spring b o lt s . 4. Linings not o f s p e c ifie d kind or primary and secondary shoes reversed. 4. I n s t a l l new 1in in g s . 5. T ires not p ro pe rly i n f l a t e d or unequal wear o f tread . D i f f e r e n t tread non-skid design. 5. I n f l a t e the t i r e s to recommended pressures. Rearrange the t i r e s so t h a t a p a ir o f nonskid tread surfaces o f s i m i l a r design and equal wear w i l l be i n s t a l l e d on the f r o n t wheels, and another p a ir w ith l i k e tread w i l l be i n s t a l l e d on the rea r wheels. 6. Linin gs charred. 6. Replace w ith new l i n i n g . 7. Water, mud, e t c . , in brakes. 7. Remove any f o r e ig n m aterial from a l l o f the brake parts and the in s id e o f the drums. L u bricate the shoe ledges and the re a r brake cable ramps w ith Delco Brake Lube #5450032 (o r e q u i v a l e n t ) . 8. Wheel c y li n d e r s t i c k i n g . 8. Overhaul or repla ce wheel c y l i n d e r . 9. Weak or broken r e t r a c t i n g s pring s. 9. Check s p r in g s -re p la c e bent, open-coiled or cracked s pring s. 10. Out-of-round drums. 10. Resurface or replace drums in l e f t and r i g h t hand p a irs (both f r o n t and both r e a r ) . 11. Brake dragging. 11. Check f o r loose l i n i n g . 12. Weak chassis springs or loose "U" b o lt s . 12. Replace springs or t ig h t e n "U" b o l t s . 13. Loose s t e e rin g . 13. Repair and a d ju s t. 14. Unequal camber. 14. A djus t to s p e c if ic a t i o n s . 15. Clogged or crimped h y d r a u lic l i n e . 15. Repair or replace l i n e . 16. Wheel c y li n d e r s ize d i f f e r e n t on opposite sid es. 16. Replace w ith c o r r e c t c y li n d e r s . 17. Loose king pin or bushings. 17. Replace king pins or bushings. 18. Bad drum. 18. R e finis h drums in p a ir s . A d ju st. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -5 5 DIAGNOSIS—DRUM BRAKES ONE WHEEL LOCKS Probable Cause Remedy 1. Gummy 1in in g . 1. Replace the l i n i n g s . 2. T ir e tread s l i c k . 2. Match up t i r e treads from side to sid e. WET WEATHER: BRAKES GRAB OR W O N T HOLD Probable Cause Remedy 1. Linin gs too s e n s it iv e to water. 1. Replace the 1in in g s . 2. D i r t y brakes. 2. Clean. 3. Bent fla n g e p la te - opening. 3. S tra ig h te n . 4. Scored drums. 4. Grind or tu rn in pa irs, BRAKES SQUEAK Probable Cause Rem edy 1. Flange p la te bent or shoes tw is te d . 1. Stra ig h te n or replace damaged p a rts . 2. M e t a l lic p a r t i c le s or dust imbedded in l i n i n g . 2. Sand the surfaces o f the l i n i n g s and drums. Remove a l l p a r t i c le s o f metal t h a t may be found in the surface o f the 1i ni ngs. 3. L inin g r i v e t s loose or l i n i n g not held t i g h t l y a g ainst the shoe a t the ends. 3. Replace r i v e t s an d/or tig h t e n l i n i n g by r e - r i v e t i n g . 4. Drums not square or d i s t o r t e d . 5. Shoes scraping on fla n g e p la te ledges. 6. Weak or broken hold down s pring s . Turn or grin d or replace drums. 5 . Apply Delco Brake Lube #5450032 (or e q u iv a le n t) to ledges. Replace w ith new shoe and l i n i n g s , i f d i s t o r t e d . Replace d e f e c t iv e p a rts . 7. Loose wheel be arings. 8. Loose fla n ge p la t e , anchor, drum wheel c y li n d e r . 9. Loose shoe 1 in k s . 10. Linin gs located wrong on shoes. 11. Brake drum s il e n c e r spring missing or too weak. Tighten to proper s e t t i n g . g T ighten. 9 T ighten. 11. In s ta ll lin in g s c o rre c tly . I n s t a l l new s pring . LIGHT DUTY TRUCK SERVICE MANUAL 5 -5 6 BRAKES DIAGNOSIS—DRUM BRAKES BRAKES CHATTER Probable Cause Remedy 1. I n c o rr e c t l i n i n g to drum cle arance. 1,. Readjust to recommended cle arances. 2. Loose fla n g e p la t e . 2,. Tighten s e cu re ly. 3. Grease, f l u i d , road dust on l i n i n g . 3.. Clean ou t d u st; repla ce grease and f l u i d soaked l i n i n g s . 4. Weak or broken r e t r a c t o r s p rin g . 4,. Replace. 5. Loose wheel bearings. 5,. Readjust. 6. Drums o u t-o f-ro u n d . 6,. Grind or tu rn drums in p a ir s . 7. Cocked or d i s t o r t e d shoes. 7,. S tra ig h te n or rep la c e. 8. Tapered or barrel-shaped drums. 8,. Grind or tu rn in p a ir s . SHOE CLICK Remedy Probable Cause 1. Shoes l i f t o f f fla n g e p l a t e and snap back. 1. Change drums sid e to sid e or g rin d drums ( i n p a i r s ) . 2. Hold down springs weak. 2., Replace s pring s. 3. Shoe bent. 3., S tra ig h te n . 4. Grooves in fla n g e p l a t e pads. 4. Grind - lu b r i c a t e w ith Delco Brake Lube #5450032 (or e q u iv a le n t). SNAPPIN G NOISE IN FRONT END Probable Cause Remedy 1. Grooved fla n g e p la t e pads. 1 . Grind pads or repla ce fla n g e p l a t e . 2. Lack o f l u b r i c a t i o n on moving p a r ts . 2.. Lu brica te a l l rubbing po in ts w ith Delco Brake Lube #5450032 (or e q u iv a le n t ) . 3. Loose drums or fla n g e p la t e s . 3.. Tig hte n. 4. Loose or worn f r o n t end p a rts . 4., Tighten or repla ce d e f e c t iv e p a r ts . TH U M PIN G NOISE W HEN BRAKES ARE APPLIED Probable Cause Remedy 1. Too much clearance between shoes and anchors. 1 . A d ju st. 2. R e tra c to r springs unequal - weak. 2. Replace sp rin g s. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -5 7 DIAGNOSIS—DRUM BRAKES G R IN D IN G NOISE Probable Cause Rem edy 1. Shoe h i t s drum. 1 . Switch drums or grin d drums. 2. Bent shoe web. 2. S tra ig h te n . 3. Foreign m aterial in l i n i n g . 3. Remove. 4. Rivets or shoe rubbing drum. 4. Reline - r e f i n i s h drums, i f scored. 5. L inin g charred. 5. Replace the 1in in g s . 6. Rough drum surface. 6. R e finis h drums. DIAGNOSIS—DISC BRAKES PULLS Probable Cause 1. I n c o r r e c t t i r e pressures. Rem edy 1 . I n f l a t e evenly on both sides to the recommended pressures. (See owner's manual.) 2. Front end out o f 1ine. 2. Check and a l i g n to m an ufac ture r's s p e c i f i c a t i o n s . 3. Unmatched t i r e s on same a x le . 3. T ires w ith approxim ately the same amount o f tread should be used on the same a x le . 4. R e stric te d brake tubes or hoses. 4. Check f o r s o f t hoses and damaged l i n e s . Replace w ith new hoses and new double -w alled stee l brake tu b in g . 5. M a lfu nc tio nin g c a l i p e r assembly. 5. Check f o r stuck or slu gg is h p is to n s . 6. D e fe ctiv e or damaged shoe & l i n i n g (grease or brake f l u i d on l i n i n g or bent shoe). 6. I n s t a l l new shoe and l i n i n g on complete a x le . 7. M alfu n ctio n in g rea r brakes. 7. Check f o r in o p e r a t iv e automatic a d ju s tin g mechanism, d e f e c t iv e l i n i n g (grease o r brake f l u i d on l i n i n g ) or d e f e c t iv e wheel c y l i n d e r s . Repair as necessary. 8. Loose suspension p a rts . 8. Check a l l suspension mountings. 9. Loose c a l ip e r s . 9. Check and torque a l l b o lt s to s p e c i f i c a t i o n s . BRAKE ROUGHNESS OR CHATTER (PEDAL PULSATES) Probable Cause Rem edy 1. Excessive l a t e r i a l runout. 1 . Check per i n s t r u c t i o n s and resurfa ce the r o t o r , i f not w ith in s p e c ific a tio n s . 2. P a ra lle lis m not w i t h i n s p e c if ic a t i o n s 2. Check per i n s t r u c t i o n s and res u rfa ce the r o t o r , i f not w ith in s p e c ific a tio n s . 3. Wheel bearings not adjusted c o r r e c t l y 3. A d ju st wheel bearings to c o r r e c t s p e c i f i c a t i o n s . LIGHT DUTY TRUCK SERVICE MANUAL 5 -5 8 BRAKES DIAGNOSIS—DISC BRAKES BRAKE ROUGHNESS, ETC. (C O N T .) Probable Cause Remedy 4. Rear drums o u t-o f- ro u n d . 4. Check runout and i f not w i t h i n s p e c i f i c a t i o n s , t u r n the drums. (Not over maximum o f .060 on the d ia m e te r.) 5. Shoe reversed (s te e l ag a in s t ir o n ) . 5. Replace r o t o r and shoe and l i n i n g . EXCESSIVE PEDAL EFFORT Probable Cause Remedy . 1. M alfu nctio nin g power brake. 1 2. P a r t ia l system f a i l u r e (dual master c y l i n d e r ) . 2. Check f r o n t and rea r brake system and r e p a i r i f necessary. Also check brake warning l i g h t i f a f a i l e d system is found and l i g h t did not f u n c t i o n . Check power brake and r e p a i r i f necessary. 3. Excessively worn shoe and l i n i n g . 3. Check and replace in axle sets. 4. Pistons in c a lip e r s stuck or slu g g is h . 4. Remove c a lip e r s and r e b u i ld . 5. Fading brakes due to i n c o r r e c t l i n i n g . 5. Remove and repla ce w ith o r i g i n a l equipment. EXCESSIVE PEDAL TRAVEL Probable Cause Remedy . 1. P a r t ia l brake system f a i l u r e (w ith dual system master c y lin d e rs ). 1 Check both f r o n t and rea r systems f o r a f a i l u r e and r e p a i r . Also check warning l i g h t , i f v e h ic le is so equipped. I t should have in d ica te d a f a i l u r e . 2. I n s u f f i c i e n t f l u i d due to leak in system. 2. F i l l r e s e rv o ir s w ith GM Hydraulic Brake F lu id Supreme No. 11 (or e q u i v a l e n t ) . 3. In c o rr e c t master c y li n d e r push rod adjustment. 3. Adjust c le v is where po ssib le . 4. A i r trapped in system. 4. Bleed system. 5. Rear brake not a d ju s tin g p ro p e rly . 5. Adjust re a r brakes and r e p a i r auto a d ju s te r s . 6. Bent shoe and l i n i n g . 6. Replace axle set o f shoe and l i n i n g . D R A G G IN G BRAKES (A very l i g h t drag is present in a l l disc brakes immediately a f t e r pedal is released) Remedy Probable Cause . 1. Master c y li n d e r pisto ns not r e tu r n in g c o r r e c t l y . 1 With r e s e r v o ir cover o f f , check f o r f l u i d s p u r t a t bypass holes as pedal is depressed. A d ju s t push rod, i f necessary or r e b u ild master c y l i n d e r . 2. R e s tricte d brake tubes or hoses. 2. Check f o r s o f t hoses or damaged tubes and repla ce w ith new hoses and new doub le-walled stee l brake tu b in g . LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -5 9 DIAGNOSIS—DISC BRAKES DRAGGING BRAKES (CONT.) Probable Cause Remedy 3. I n c o rr e c t parking brake adjustment on rea r brakes. 3. Check and r e a d ju s t to c o r r e c t s p e c i f i c a t i o n s . 4. Metering valve i n s t a l l e d i n c o r r e c t l y . 4. Port marked " i n l e t " goes to master c y l i n d e r , Port marked " o u t l e t " goes to dis c c a l i p e r s . 5. Check valve i n s t a l l e d in o u t l e t to f r o n t disc brakes. 5. Check o u t l e t hole and remove check va lve , i f l i n e is connected to dis c brake c a l i p e r s . G RABBING OR UNEVEN BRAKING A C TIO N Probable Cause 1. A l l c o n d itio n s l i s t e d under "PULLS". Rem edy 1. See "PULLS". 2. M alfu nctio n o f metering valve or p ro p o rtio n in g valve. 2. Replace and bleed system. 3. M alfu nctio n o f power brake u n i t . 3. Check o p era tion and r e p a i r , i f necessary. 4. Binding brake pedal mechanism. 4. Check and lu b r i c a t e w ith Delco Brake Lube #5450032 (or e q u iv a le n t) i f necessary. 5. Metering valve not hold in g o f f f r o n t brake a p p l ic a t io n . 5. Replace metering valve and bleed system. I f v e h ic le is not equipped w ith metering va lv e , check o th er causes. REAR DRUM BRAKES SKIDDING PREMATURELY UNDER HARD BRAKE APPLICATION Probable Cause 1. P rop o rtio n in g valve not c o n t r o l l i n g rea r l i n e pressure to prevent rea r wheel lockup on hard brake a p p lic a t io n s Remedy 1. Replace p r o p o r tio n in g valve and bleed system. If v e h ic le is not equipped w ith p r o p o r tio n in g v a lv e , check o th e r causes l i s t e d under "PULLS" or "GRABBING OR UNEVEN BRAKING ACTION". LIGHT DUTY TRUCK SERVICE MANUAL 5 -6 0 BRAKES POWER BRAKES INDEX General Description.......................................................................... Theory of Operation......................................................................... Maintenance and Adjustments...................................................... Inspection............................................................................................ Lubrication.......................................................................................... Bleeding............................................................................................... Air Cleaner Service......................................................................... Component Part Replacement....................................................... Power Brake U nit............................................................................ Diagnosis............................................................................................... 5-60 5-60 5-66 5-66 5-66 5-66 5-66 5-66 5-66 5-67 GENERAL DESCRIPTION The Power brake Unit is a self-contained hydraulic and vacuum unit, utilizing manifold vacuum and atmospheric pressure for its power. This unit permits the use of a low brake pedal as well as less pedal effort than is required with the conventional (nonpower) hydraulic brake system. The unit is mounted on the engine side of the dash panel and directly connected to the brake pedal. THEORY OF OPERATION A power brake is used with the brake system to reduce the braking effort required by the driver. A combined vacuum and hydraulic unit, which utilizes engine manifold vacuum and atmospheric pressure, is used to provide power assisted application of vehicle brakes. The unit is used in conjunction with a conventional brake system. From the master cylinder connection outward to the wheel units, there is no other change in the brake system. In addition to the master cylinder connections, the unit requires a vacuum connection to the engine intake manifold (through a vacuum check valve) and a mechanical connection to the brake pedal. The unit is self-contained. The vacuum power unit contains the power piston assembly, which houses the control valve and reaction mechanism, and the power piston return spring. The control valve is composed of the air valve (valve plunger), the floating control valve assembly, and the push rod. The reaction mechanism consists of a hydraulic piston reaction plate and a series of levers. An air filter, air silencer, and filter retainer are assembled around the valve operating rod filling the cavity inside the hub of the power piston. The push rod or valve operating rod, which operates the air valve, projects out of the end of the power unit housing through a rubber dust guard. A vacuum check valve assembly is mounted in the front housing assembly for connection to the vacuum source. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES RESERVOIR COVER 5-61 FRONT SHELL REAR SHELL POWER PISTON DIAPHRAGM FLUID RESERVOIRS REACTION RETAINER POWER PISTON INSERT REACTION LEVER REACTION SPRING FLOATING CONTROL VALVE PUSH ROD AIR FILTER FLOATING PISTON STOP BOLT FLOATING PISTON ASSEMBLY SILENCER AIR VALVE REACTION PLATE POWER PISTON RETURN SPRING MASTER CYLINDER PUSH ROD COMPENSATING PORT SUPPORT PLATE AIR FILTER PRIMARY PISTON ASSEMBLY Fig. 86--Typical Power Unit RELEASED (Figs. 86 and 87) At the released position the air valve is seated on the floating control valve. Air at atmospheric pressure, which enters through the filter element in the tube extension of the power piston, is shut off at the air valve. The floating control valve is held away from the valve seat in the power piston insert. Vacuum is present in the space on Released both sides of the power piston. Any air in the system is drawn through a small passage in the power piston, over the valve seat in the power piston insert, and then through a passage in the power piston insert. From here it travels through a hole in the power piston support plate into the space in front of the power piston. It is then drawn through the check valve and into the engine intake manifold. LIGHT DUTY TRUCK SERVICE MANUAL 5 -6 2 BRAKES Fig. 8 7 -Typical Circuit - Released In this position there is vacuum on both sides of the power piston, and the power piston is held against the rear of the housing by the power piston return spring. At rest, the hydraulic reaction plate is held against the reaction retainer. The air valve spring holds the reaction levers against the hydraulic reaction plate and also holds the air valve against its stop in the tube of the power piston. The floating control valve assembly is held against the air valve seat by the floating control valve spring. With the power brake at released position, the master cylinder primary seals on both the rear (primary) piston and the floating (secondary) piston are back past the two compensating ports in the bore. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -6 3 VACUUM REACTION PLATE FLOATING CONTROL VALVE AIR VALVE UNSEATED AIR VALVE REACTION LEVERS ATMOSPHERIC PRESSURE Fig. 88-Typical Power Unit - Applying APPLYING (Figs. 88 and 89) As the pedal is depressed, the valve operating rod (push rod) carries the air valve away from the floating control valve. The floating control valve will follow until it is in contact with the raised seat in the power piston insert. When this occurs, vacuum is shut off to the rear of the power piston, and air under atmospheric pressure enters through the air filter and travels past the seat of the air valve and through a passage into the housing at the rear of the power piston. Since there is still vacuum on the front side of the power piston, the atmospheric air pressure at the rear of the piston will force the power piston to travel forward. LIGHT DUTY TRUCK SERVICE MANUAL 5 -6 4 BRAKES Fig. 8 9 -Typical Circuit - Applying As the power piston travels forward, the master cylinder piston rod carries the master cylinder primary piston further into the bore of the master cylinder. The force on the master cylinder primary piston spring forces the secondary piston to move forward. As the primary seal, on both the master cylinder primary and the secondary pistons pass the compensating ports in the bore, hydraulic pressure will build up in the lines to the front and rear brakes. As the pressure builds up on the end of the master cylinder piston, the hydraulic reaction plate is moved off its seat on the power piston and presses against the reaction levers. The levers, in turn, swing about their pivots and bear against the end of the air valve operating rod assembly. In this manner approx­ imately 30% of the load on the hydraulic master cylinder piston is transferred back through the reaction system to the brake pedal. This gives the operator a feel, which is proportional to the degree of brake application. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -6 5 VACUUM REACTION PLATE FLOATING CONTROL VALVE AIR VALVE SEATED AIR VALVE REACTION LEVERS ATMOSPHERIC PRESSURE Fig. 90--Typical Power Unit - Holding HOLDING (Figs. 90 and 91) When the desired pedal pressure is reached, the power piston moves forward until the floating control valve, which is still seated on the power piston, again seats on the air valve. The power piston will now remain stationary, until either pressure is applied or released at the brake pedal. As the pressure at the pedal is released, the air valve spring forces the air valve back to its stop on the power piston. As it returns, the air valve pushes the floating control valve off its seat on the power piston insert. The air valve seating on the floating control valve has shut off the outside air source. When it lifts the floating control valve from its seat on the power piston insert, it opens the space at the rear of the power piston to the vacuum source. Since both sides of the power piston are now under vacuum, the power piston return spring will return the piston to its released position against the rear housing. As the power piston is returned, the master cylinder primary and secondary pistons move back, and the fluid from the wheel cylinders flows back into the master cylinder. If the brake pedal is released quickly, the master cylinder primary and secondary pistons immedi­ ately return to the released position. If the fluid in the lines cannot return as quickly as the pistons, this is compensated for by the flow of fluid from the space between the primary and secondary seals through the compensating holes in the pistons. The excess fluid in the system can flow back to the fluid reservoirs through the small compensating ports in the master cylinder bore. LIGHT DUTY TRUCK SERVICE MANUAL 5 66 BRAKES Fig. 91--Typical Circuit • Holding VACUUM FAILURE In case of vacuum source interruption, the brake unit operates in the following manner: As the pedal is pushed down, the end of the air valve contacts the reaction levers and pushes, in turn, against the hydraulic reaction plate. Since the hydraulic reaction plate is fastened to the master cylinder piston rod, it forces the piston rod against the master cylinder primary piston, which builds up the hydraulic line pressure. With this condition you have, in effect, a standard brake unit. M A IN TEN A N C E A N D ADJUSTMENTS INSPECTIONS 1. Check vacuum line and vacuum line connections as well as vacuum check valve in front housing of power unit for possible vacuum loss. 2. Inspect all hydraulic lines and connections at the wheel cylinders and master cylinder for possible hydraulic leaks. 3. Check brake assemblies for scored drums, grease or brake fluid on linings, worn or glazed linings, and make necessary adjustments. 4. Check brake fluid level in the hydraulic reservoirs. The reservoirs should be filled to the levels shown in Figure 31. 5. Check for loose mounting bolts at master cylinder and at power section. 6 . Check air cleaner filter in power piston extension and replace filter if necessary. 7. Check brake pedal for binding and misalignment between pedal and push rod. LIGHT DUTY TRUCK SERVICE MANUAL BRAKES LUBRICATION The power brake unit is lubricated at assembly and needs no further lubrication other than maintaining normal reservoir fluid level. The reservoir should be filled as described in this section. BLEEDING The power system may be bled manually or with a pressure bleeder as outlined in this section. Use only GM Supreme 11 Brake Fluid or equivalent. Do not use the power assist while bleeding. The engine should not be 5 -6 7 running and the vacuum reserve should be reduced to zero by applying the brake several times before starting the bleeding procedure. AIR CLEANER SERVICE Servicing of the air cleaner is recommended and the element replaced when restriction becomes severe enough to affect power brake response. At any other time, if cleaning of the filter is felt necessary, it should be shaken free of dirt or washed in soap and water and thoroughly dried. C O M P O N E N T PART REPLACEMENT POWER BRAKE UNIT Removal 1. Remove all dirt from the exterior of the master cylinder. Disconnect the brake lines from the two master cylinder hydraulic outlets. Cover brake line fittings to prevent dust and dirt from entering brake lines. 2. Disconnect the vacuum hose from the vacuum check valve on the front housing of the power head. Plug vacuum hose to prevent dust and dirt from entering hose. 3. Disconnect the power brake push rod from the brake pedal. 4. Remove the four nuts (inside vehicle) from the mounting studs which hold the power brake to the dash panel. 5. Carry the power brake to a clean work area and clean the exterior of the power brake prior to disassembly (see the applicable portion of the "Overhaul" manual for disassembly at the power unit). Installation 1. Mount power brake assembly to dash. CAUTIO N: See "Caution" on Page 1 of this section. 2. Connect power brake push rod to brake pedal. 3. Connect vacuum hose to vacuum check valve. 4. Connect brake lines to master cylinder outlets. CAUTIO N: See " Caution" on Page 1 of this section. 5. Bleed brakes as necessary and fill fluid reservoirs to within 1/4" of top of the reservoirs. LIGHT DUTY TRUCK SERVICE MANUAL 5 -6 8 BRAKES DIAGNOSIS NOTE The same types o f brake troub le s are encountered w ith power brakes as w ith standard brakes. Before check­ ing the power brake system f o r source o f t r o u b le , r e f e r to tro u b le diagnosis o f standard h y d ra u lic brakes in t h is manual. A f t e r these p o ssib le causes have been e lim in a te d , check f o r cause as o u t lin e d below. BRAKE SYSTEM LOSES FLUID Probable Cause Remedy 1. External le ak: 1eakin g-pipe connections, hose, wheel c y li n d e r s , stop l i g h t s w itc h , master c y li n d e r head nut, e tc. 1. Clean p a rts . Tig hte n. Replace d e f e c t iv e parts, 2. In te rn a l le aks: past secondary seals in to power u n i t . Check vacuum hose f o r f l u i d . 2. Rebuild master c y l i n d e r . NOTE: Make the f o llo w in g t e s t before checking hard pedal f o r the cause. With the, engine stopped, depress the brake pedal several times to e lim in a te a l l vacuum from the system. Apply the brakes, and w h ile holding the f o o t pressure on the brake pedal, s t a r t the engine. I f the u n i t is operating c o r r e c t l y , the brake pedal w i l l move forward when the engine vacuum power is added to the pedal pressure. I f th is te s t shows t h a t the power u n i t is not o p e ra tin g , the t r o u b le may be one o f the f o ll o w i n g : N O B O O S T -H A R D PEDAL Probable Cause 1 . Bent, broken, obstru cted tube. Collapsed hose. Remedy 1 . Replace d e f e c t iv e p a r ts . 2. Stuck check valve. 2. Replace valve. 3. A i r i n l e t blocked. 3. Replace f i l t e r . 4. A i r valve stuck. 4. Disassemble u n i t - clean - replace d e f e c t iv e 5. F aulty diaphragm. 5. Replace diaphragm. 6. F aulty p is to n s e a l . 7. Leaks i n t e r n a l l y . Open passages. 6. Replace s e a l . 7. Rebuild as o u t lin e d in the "Overhaul" Manual. Tighten b o l t s . LIGHT DUTY TRUCK SERVICE MANUAL BRAKES 5 -6 9 DIAGNOSIS—POWER HYDRAULIC BRAKES SLOW BRAKE PEDAL RETURN Probable Cause Remedy 1. Excessive seal f r i c t i o n in power u n i t . 1. Overhaul u n i t as o u t lin e d in the "Overhaul" Manual. 2. F aulty valve a c t io n . 2. Overhaul u n i t . 3. Broken r e tu r n s p rin g . 3. Replace s p rin g . BRAKES GRABBY Probable Cause Remedy 1. Broken valve s p rin g . 1. Overhaul u n i t . 2. S t ic k in g vacuum valve. 2. Clean and lu b r i c a t e w ith Delco S ilic o n e Lube #5459912 (or e q u i v a l e n t ) . 3. Reaction diaphragm leakage. 3. Overhaul u n i t . BRAKES CHATTER: PEDAL VIBRATES (BELLOWS TYPE) Probable Cause Remedy 1. Brake pedal fre e play not adjusted p ro p e rly . 1. A djust brake pedal f r e e play. BRAKE PEDAL CHATTER (BELLOWS TYPE) Probable Cause Remedy 1. Power brake t r i g g e r is out o f adjustment or bent. 1. Replace t r i g g e r and a d ju s t li n k a g e . 2. Master c y li n d e r push rod is improperly adju ste d. 2. Adjust push rod. 3. Power brake t r i g g e r rubber c o l l a r is missing or damaged. 3. Replace w ith new c o l l a r . 4. Binding in s id e power u n i t . 4. Overhaul u n i t . NOTE: I f tr o u b le is determined as being caused by the power bo oster, r e f e r to the a p p lic a b le Service or Overhaul Manual f o r service procedures. LIGHT DUTY TRUCK SERVICE MANUAL 5 -7 0 BRAKES SPECIAL TOOLS GUU 1. 2. 3. 4. J-2185 Flaring Tool J-8000 Tubing Cutter J-8049 or J-22348 Spring Remover J-21177 Drum/Shoe Gage 5. 6. 7. 8. J-21472 J-22904 J-23518 J-23709 Bleeder Wrench Dust Boot Installer Bleeder Adapter Combination Valve Pin Retainer Fig. 9 2 -Special Tools LIGHT DUTY TRUCK SERVICE MANUAL SECTION 6 ENGINE CONTENTS OF THIS SECTION Engine Tune-Up................................................................... 6-1 Theory of Operation.......................................................... 6-14 Engine Mechanical (In Line)......................................... 6-19 Engine Mechanical (V8 ).................................................... 6-44 Diagnosis................................................................................. 6-68 Special Tools......................................................................... 6-73 ENGINE TUNE-UP INDEX General Description................................................ ........... Mechanical Checks and Adjustments............... ........... Spark Plug Removal............................................ .......... Test Compression................................................... ........... Service and Install Spark Plugs....................... .......... Service Ignition System....................................... ........... Service Battery and Battery Cables................ ........... Service Delcotron and Regulator..................... ........... Service Belts............................................................ .......... Service Manifold Heat Valve............................ .......... Tighten Manifold................................................... .......... Service Fuel Lines and Fuel Filter................ .......... Service Cooling System....................................... ........... Service Crankcase Ventilation...................................... Service Air Injection Reactor System............. .......... 6-1 6-1 6-1 6-2 6-2 6-2 6-3 6-4 6-5 6-5 6-5 6-5 6-5 6-6 6-6 Choke Adjustment.......................................................... ... Instrument Check-Out..................................................... ... Instrument Hook-Up..................................................... ... Check and Adjust Dwell.............................................. ... Check Dwell Variation................................................. ... Check and Adjust Timing........................................ ... Adjust Idle Speed.......................................................... ... Additional Checks and Adjustments......................... ... Cylinder Balance Test................................................... ... Battery................................................................................ ... Ignition.............................................................................. ... Carburetor......................................................................... ... Fuel Pum p........................................................................ ... Cooling System........................................................ ....... ... Cylinder Head Torque and Valve Adjustment ... 6-7 6-8 6-8 6-8 6-8 6-8 6-9 6-11 6-11 6-11 6-11 6-13 6-13 6-13 6-13 GENERAL DESCRIPTION The engine tune-up is important to the modern automotive engine with its vastly improved power and performance. Emission system requirements, interrelated system functions, improved electrical systems and other advances in design, make today’s engines more sensitive and have a decided effect on power, performance and fuel consumption. It is seldom advisable to attempt a tune up by correction of one or two items only. Time will normally be saved and more lasting results assured if the technician will follow a definite and thorough procedure of analysis and correction of all items affecting power, performance and economy. The tune-up will be performed in two parts. The first part will consist of mechanical checks and adjustments; the second part will consist of an instrument checkout that can be performed with any one of the units of service equipment available for this purpose. Always follow the instructions provided by the manufacturer of the particular equipment to be used. Additional checks and adjustments are included in the latter part of this section for use as required. Many of these operations can be used to isolate and correct trouble located during the tune-up. Where conditions are uncovered requiring major corrective action, refer to the appropriate section of this manual or the Overhaul Manual for detailed service information. Typical illustrations and procedures are used except where specific illustrations or procedures are necessary to clarify the operation. Illustrations showing bench operations are used for clarification, however, all operations can be performed on the vehicle. MECHANICAL CHECKS A N D ADJUSTMENTS SPARK PLUG REMOVAL Remove any foreign matter from around spark plugs by blowing out with compressed air, then disconnect wires and remove plugs. To disconnect wire at spark plug, grasp the boot portion of the wire and apply only LIGHT DUTY TRUCK SERVICE MANUAL 6-2 ENGINE enough force to remove the boot. Do not pull on plug wire. TEST COMPRESSION (FIG. 1) The compression check is important because an engine with low or uneven compression cannot be tuned successfully. It is essential that improper compression be corrected before proceeding with the engine tune up. 1. Remove air cleaner and block throttle and choke in wide open position. 2. Hook up starter remote control cable and insert compression gauge firmly in spark plug port. CAUTION: Whenever the engine is cranked remotely at the starter, with a special jumper cable or other means, the distributor primary lead must be disconnected from the negative post on the coil. 3. Crank engine through at least four compression strokes to obtain highest possible reading. 4. Check and record compression of each cylinder. 5. If one or more cylinders read low or uneven, inject about a tablespoon of engine oil on top of pistons in low reading cylinders (through spark plug port). Crank engine several times and recheck compression. • If compression comes up but does not necessarily reach normal, rings are worn. • If compression does not improve, valves are burned, sticking or not seating properly. • If two adjacent cylinders indicate low compres­ sion and injecting oil does not increase compression, the cause may be a head gasket leak between the cylinders. Engine coolant and/ or oil in cylinders could result from this defect. NOTE: If a weak cylinder cannot be located with the compression check, see “Cylinder Balance Test” under “Additional Checks and Adjustments” in this section. SERVICE AND INSTALL SPARK PLUGS (FIG. 2 ) 1. Inspect each plug individually for badly worn electrodes, glazed, broken or blistered porcelains and replace plugs where necessary. 2. Clean serviceable spark plugs thoroughly, using an abrasive-type cleaner such as sand blast. File the center electrode flat. 3. Inspect each spark plug for make and heat range. All plugs must be of the same make and number. 4. Adjust spark plug gaps to specifications using a round feeler gauge. CAUTIO N: Never bend the center electrode to adjust gap. Always adjust by bending ground or side electrode. 5. If available, test plugs with a spark plug tester. 6 . Inspect spark plug hole threads and clean before installing plugs. Corrosion deposits can be removed with a 14 m m .x 1.25 SAE spark plug tap (available through local jobbers) or by using a small wire brush in an electric drill. (Use grease on tap to catch chips.) CAUTIO N: Use extreme care when using tap to prevent cross threading. Also crank engine several times to blow out any material dislodged during cleaning operation. 7. Install spark plugs and torque to specifications. NOTE: The following are some of the greatest causes of unsatisfactory spark plug performance. • Installation of plugs with insufficient torque to fully seat. • Installation of the plugs using excessive torque which changes gap settings. • Installation of plugs on dirty seat. • Installation of plugs to corroded spark plug hole threads. 8 . Connect spark plug wiring. SERVICE IG N ITIO N SYSTEM Fig. 1—Checking Compression 1. Remove distributor cap, clean cap and inspect for cracks, carbon tracks and burned or corroded terminals. Replace cap where necessary (fig. 3). 2. Clean rotor and inspect for damage or deteriora­ tion. Replace rotor where necessary. 3. Replace brittle, oil soaked or damaged spark plug wires. Install all wires to proper spark plug. Proper positioning of spark plug wires in supports is important to prevent cross-firing. LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E Fig. 2—Spark Plug Detail 4. Tighten all ignition system connections. 5. Replace or repair any wires that are frayed, loose or damaged. Distributor (Figs. 4 or 5) 1. Check the distributor centrifugal advance mecha­ nism by turning the distributor rotor in a clockwise direction as far as possible, then releasing the rotor to see if the springs return it to their retarded position. If the rotor does not return readily, the distributor must be disassembled and the cause of the trouble corrected. 2. Check to see that the vacuum control operates freely by turning the movable breaker plate counterclockwise to see if the spring returns to its retarded position. Any stiffness in the operation of the vacuum control will affect the ignition timing. Correct any interference or binding condition noted. 3. Examine distributor points and clean or replace if necessary. • Contact points with an overall gray color and only slight roughness or pitting need not be replaced. • Dirty points should be cleaned with a clean point file. Use only a few strokes of a clean, fine-cut contact file. The file should not be used on other metals and should not be allowed to become greasy or dirty. Never use emery cloth or sandpaper to clean contact points since particles will embed and cause arcing and rapid burning of points. Do not attempt to 6-3 remove all roughness nor dress the point surfaces down smooth. Merely remove scale or dirt. • Clean cam lobe with cleaning solvent and rotate cam lubricator wick 180°. NOTE: Where prematurely burned or badly pitted points are encountered, the ignition system and engine should be checked to determine the cause of trouble so that it can be eliminated. Unless the condition causing point burning or pitting is corrected, new points will provide no better service than the old points. Refer to Section 6 Y for an analysis of point burning or pitting. • Check point alignment (fig. 6 ) then, adjust distributor contact point gap to .019" (new points) or .016" (used points). Breaker arm rubbing block must be on high point of lobe during adjustment. NOTE: If contact points have been in service, they should be cleaned with a point file before adjusting with a feeler gauge. • Check distributor point spring tension (contact point pressure) with a spring gauge hooked to breaker lever at the contact and pull exerted at 90 degrees to the breaker lever. The points should be closed (cam follower between lobes) and the reading taken just as the points separate. If not within limits, replace. Excessive point pressure will cause excessive wear on the points, cam and rubbing block. Weak point pressure permits bouncing or clattering, resulting in arcing and burning of the points and an ignition miss at high speed. 4. Install rotor and distributor cap. Press all wires firmly into cap towers. SERVICE BATTERY AND BATTERY CABLES 1. Measure the specific gravity of the electrolyte in each cell (fig. 7). If it is below 1.230 (corrected to 80°F.) recharge with a slow rate charger, or if desired, further check battery. 2. Connect a voltmeter across the battery terminals and measure the terminal voltage of the battery during cranking (disconnect the coil primary lead at the negative terminal during this check to prevent engine from firing). If the terminal voltage is less than 9.0 volts at room temperature, approximately 80° ± 20°F., the battery should be further checked. See Section 6 Y for further tests. 3. Inspect for signs of corrosion on battery, cables and surrounding area, loose or broken carriers, cracked or bulged cases, dirt and acid, electrolyte leakage and low electrolyte level. Fill cells to proper level With colorless, odorless, drinking water. The top of the battery should be clean and the LIGHT DUTY TRUCK SERVICE MANUAL 6 -4 ENGINE CARBON L PATH CRACK CARBON PATH ERODED TOWER INSPECTION OF DISTRIBUTOR CAP TOWERS CLEANING & INSPECTION OF OUTSIDE OF DISTRIBUTOR CAP ROTOR TIP CORRODED BURNED OR ERODED INSERT TERMINALS/ CLEANING & INSPECTION OF INSIDE OF DISTRIBUTOR CAP REPLACING DISTRIBUTOR CAP INSUFFICIENT ROTOR CONTACT SPRING TENSION ROTOR INSPECTION BLOWING OUT INSIDE OF DISTRIBUTOR CAP & INSPECTION OF INSERT _____________ TERMINALS_____________ CLEANING TOWER INSERT CLEANING IGNITION COIL INSPECTION OF CARBON ROTOR BUTTON Fig. 3—Cleaning and Inspecting Distributor Cap, Rotor and Coil CAM LUBRICATOR CONTACT SET ATTACHING SCREW QUICK DISCONNECT TERMINAL BREAKER PLATE ATTACHING SCREWS Fig. 4-D istributor (In Line) battery hold-down bolts properly tightened. Particu­ lar care should be taken to see that the top of the battery is kept clean of acid film and dirt. When cleaning batteries, wash first with a dilute ammonia or soda solution to neutralize any acid present and then flush off with clean water. Keep vent plugs tight so that the neutralizing solution does not enter the cell. The hold down bolts should be kept tight enough to prevent the battery from shaking around in its holder, but they should not be tightened to the point where the battery case will be placed under a severe strain. To insure good contact, the battery cables should be tight on the battery. If the battery cable terminals are corroded, the cables should be cleaned separately with a soda solution and wire brush. If the battery has remained undercharged, check for loose or defective fan belt, defective Delcotron, high resistance in the charging circuit, oxidized regulator contact points, or a low voltage setting. If the battery has been using too much water, the voltage output is too high. SERVICE DELCOTRON AND REGULATOR y^e Delcotron and regulator tests during tune up consist of the above battery tests; the condition of the battery LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E LATERAL MISALIGNMENT WEIGHT ASSEMBLY 6-5 PROPER LATERAL ALIGNMENT ROTOR II' If R.F.I. SHIELD Li CIRCUIT BREAKER PLATE ASSEMBLY ACCESS PASSAGE FOR ENGINE OIL FUMES DISTRIBUTOR HOUSING GEAR SHAFT BUSHING '"J CORRECT LATERAL MISALIGNMENT BY BENDING FIXED CONTACT SUPPORT NEVER BEND BREAKER LEVER PERMANENT LUBRICATION RESERVOIR VACUUM ASSEMBLY -'1 .11 Fig. 6—Point Alignment DO NOT SUCK IN TOO MUCH ELECTROLYTE HOLD TUBE VERTICAL FLOAT MUST----BE Fig. 5—Distributor (V8) will indicate the need for further tests and adjustments as outlined in Section 6 Y. SERVICE BELTS (FIG. 8 ) Inspect belt condition. Check and adjust if necessary for correct tension of belt, as follows: • Using a strand tension gauge, check the belt tension. • If belt is below the minimum, adjust until the specified tension, is reached. (See Tune Up Chart in Specification section.) SERVICE MANIFOLD HEAT VALVE (FIG. 9 or 1 0 ) Check manifold heat control valve for freedom of operation. If shaft is sticking, free it up with GM Manifold Heat Control Solvent or its equivalent. NOTE: Tap shaft end to end to help free it up. TIGHTEN MANIFOLD Tighten intake manifold bolts to specifications in the sequence outlined on Torque Sequence Chart located at end of Engine Mechanical section. A slight leak at the intake manifold destroys engine performance and economy. TAKE READING AT EYE LEVEL Fig. 7—Testing Specific Gravity of Battery SERVICE FUEL LINES AND FUEL FILTER 1. Inspect fuel lines for kinks, bends or leaks and correct any defects found. Refer to Section 8 for the correct fabrication and replacement procedures for fuel lines. 2. Inspect filter and replace if plugged. NOTE: If a complaint of poor high speed performance exists on the vehicle, fuel pump tests described in Section 6 M should be performed. SERVICE COOLING SYSTEM 1. Inspect cooling system for leaks, weak hoses, loose hose clamps and correct coolant level, and service as required. NOTE: A cooling system pressure test, as described in “Additional Checks and Adjust­ ments” in this section, may be performed to LIGHT DUTY TRUCK SERVICE MANUAL 6 -6 ENGINE Fig. 9—Manifold Heat Control Valve (L6) Fig. 8—Checking Fan Belt Tension detect internal or external leaks within the cooling system. SERVICE CRANKCASE VENTILATION (FIG. 1 1 ) All engines have a “Closed Positive” ventilation system utilizing manifold vacuum to draw fumes and contami­ nating vapors into the combustion chamber where they are burned. Since it affects every part of the engine, crankcase ventilation is an important function and should be understood and serviced properly. In a “Closed Positive” ventilation system, air is drawn through the engine crankcase (through a regulating valve) (fig. 12) into the manifold, drawing crankcase vapors and fumes with it to be burned. The “Closed Positive” ventilation system draws clean air from the carburetor air cleaner and has a nonvented oil filler cap. 1. Ventilation valve should be replaced at intervals specified in Section 0. 2. Inspect for deteriorated or plugged hoses. 3. Inspect all hose connections. 4. Remove flame arrestor and wash in solvent, then dry with compressed air. 5. Inspect ventilation filter (fig. 13) and replace if necessary. SERVICE AIR INJECTION REACTOR SYSTEM Inspect air injection reactor system for evidence of leaks, deteriorated hoses, cracked air manifolds or tubes and loose hose clamps. Inspect air injection pump belt Fig. 10—Manifold Heat Control Valve (Typical V8) condition and tension. Make all necessary repairs as outlined in “Section 6 T ” . Because of the relationship between “Engine Tune U p” and “Unburned Exhaust Gases”, the condition of Engine Tune Up should be checked whenever the Air Injection Reactor System seems to be malfunctioning. Particular care should be taken in checking items that affect fuelair ration such as the crankcase ventilation system, the carburetor and the carburetor air cleaner. Carburetors and distributors for engines with the Air Injection Reactor System and Controlled Combustion System are designed, particularly, for these engines; therefore, they must not be interchanged with or replaced by a LIGHT DUTY TRUCK SERVICE MANUAL ENGINE 6-7 carburetor or distributor designed for different applications. CHOKE ADJUSTMENT Inspect choke valve, choke rod, choke coil and housing for proper alignment, bends and binding — make necessary corrections to assure proper choke operation; then adjust choke as outlined in Section 6 M. Fig. 11—Crankcase Ventilation Systems LIGHT DUTY TRUCK SERVICE MANUAL 6-8 ENGINE C R A N K C A S E V E N T IL A T IO N FILTER Fig. 13—Crankcase Ventilation Filter INSTRUMENT CHECK-OUT INSTRUMENT HOOK-UP Connect vacuum gauge, dwell meter, tachometer and timing light as recommended by the manufacturer of the equipment being used. CHECK AND ADJUST DWELL 1. Start engine then check ignition dwell. 2. If dwell is not within specifications, adjust dwell as follows: V8 Engine • With engine running at idle, raise the adjustment screw window and insert an Allen wrench in the socket of the adjusting screw (fig. 14). • Turn the adjusting screw as required until the specified dwell reading is obtained. •Close access cover fully to prevent the entry of dirt into the distributor. In Line Engines • Remove distributor cap and recheck point setting. If dwell is still not within specifications check the distributor as outlined in Section 6Y. CHECK DWELL VARIATION Slowly accelerate engine to 1750 rpm reading. Return engine to idle and note dwell variation exceeds specifications, distributor shaft, worn distributor shaft breaker plate. and note dwell dwell reading. If check for worn bushing or loose CHECK AND ADJUST IG NITIO N TIM ING (FIG. 1 5 ) 1. Disconnect the distributor spark advance hose and plug the vacuum source opening. 2. Start engine and run at idle speed. (See tune up chart in Specification section.) 3. Aim timing light at timing tab. NOTE: The markings on the tabs are in 2° increments (the greatest number of markings on the “ Before” side of the “O ” ). The “O” marking is TDC and all BTDC settings fall on the “Before” (advance) side of “O ” . 4. Adjust the timing by loosening the distributor clamp and rotating the distributor body as required, then tighten the clamp and recheck timing. 5. Stop engine and remove timing light and reconnect the spark advance hose. LIGHT DUTY TRUCK SERVICE MANUAL ENGINE 6-9 W INDOW "H E X ” TYPE W RENCH SCREW Fig. 14—Setting Point Dwell (Typical V8) ADJUST IDLE SPEED (FIG. 16) Emission system requirements necessitate the division of the Series 10-30 trucks into two groups as follows: a. Light Duty Emission Vehicles - Includes all 10 Series; C-K20 Suburban Models; All G20 Series and G30 Passenger Models. b. Heavy Duty Emission Vehicles - Includes all C-KP20 Series (Except C-K20 Suburban Models); all C-P30 Series and all G30 Series (Except Passenger Models). NOTE: Idle speed will increase as new engines loosen up during the first few hundred miles of operation. Idle speed should be reset during tune-up as specified in the following procedures. With engine running at operating temperature, air cleaner installed, choke valve in fully open position, air conditioning “off”, parking brake on and drive wheels blocked - adjust idle speed as follows (See “Tune-up” Decal Figure 17.): NOTE: All carburetors are equipped with idle mixture limiter caps (fig. 16), the idle mixture is preset and “locked in” by these caps - no attempt should be made to adjust mixture. Do not remove mixture screw caps. • 250 Cu. In. (Single-Barrel Carburetor) On 250 cu. in. Light-Duty vehicles, disconnect “Fuel Tank” line from Evaporation Emission vapor canister. Disconnect the distributor spark advance hose and plug the vacuum source opening. Adjust Idle Stop Solenoid (turn solenoid body, using hex nut) to obtain: 700 rpm on all Heavy-Duty Vehicles and all LightDuty vehicles equipped with manual transmission (in neutral). Fig. 15—Ignition Timing Marks 600 rpm on Light-Duty vehicles equipped with automatic transmissions (in “Park”). NOTE: Light-Duty vehicles are equipped with the carburetor mounted CEC solenoid (fig. 16). DO NOT ADJUST THE CEC SOLENOID SCREW. CAUTIO N: If the CEC solenoid screw (fig. 16) is used to set engine idle or if the solenoid is adjusted out of limits as specified in Section 6M, a decrease in engine braking may result. Place transmission in “park” or netural and adjust carburetor fast idle speed to obtain 1800 rpm with cam follower on top step of cam. Reconnect “Fuel Tank” line to vapor canister and reconnect distributor spark advance hose. • 292 Cu. In. (Single-Barrel Carburetor) Disconnect the distributor spark advance hose and plug the vacuum source opening. Adjust Idle Stop Solenoid (turn solenoid body, using hex nut) to obtain: 600 rpm on vehicles equipped with Air Injection Reactor System (State of California Vehicles). 700 rpm on vehicles not equipped with Air Injection Reactor System. Reconnect distributor spark advance hose. • 307 Cu. In. (Two-Barrel Carburetor) On Light-Duty vehicles, disconnect "Fuel Tank" line from Evaporation Emission vapor canister. Disconnect the distributor spark advance hose and plug the vacuum source opening. LIGHT DUTY TRUCK SERVICE MANUAL 6 -1 0 ENGINE SINGLE-BARREL TW O -B AR REL IDLE M IXTURE SC REW IDLE MIXTURE SC REW S FOUR-BARREL IDLE M IXTURE SC RE W S CEC S O L E N O ID IDLE SPEED (S O L E N O ID ) SC REW IDLE SPEED (S O L E N O ID ) SC R E W Fig. 16—Idle Speed and Mixture Screws HICLE EMISSION CONTROL INFORMATION G EN ER A L MOTORS CORPORATION 2. 3. 4. 5. 6 7. 8 [ qm ] DWELL fcNTS WITH ENGINE AT NORMAL OPERATING TEM P, TIMING ( BTDC@RPM) : INSTALLED. AND DISTR VACUUM LINE DISCONNECT SPARK PLUG GAP UM LINE WHEN ADJUSTMENTS ARE COMPLETED BLOCK DRIVE WHEELS SOLENOID SCREW (RPM) f'FUOM VAPOR CANISTER. FAST IDLE SCREW (RPM) S fT DWELL AND TIMING’ AT SPECIFIED RPM IDLE MIXTURE SETTING ADJUST CARBURETOR SOLENOID SCREW TO SPECIFIED RPM WITH TRANSMISSION IN PARK OR NEUTRAL. ADJUST FAST IDLE SCREW TO SPECIFIED SPEED ON TOP STEP OF CAM. VAC. SPARK CONN. FOR AUTO TRANS RECONNECT FUEL TANK HOSE TO VAPOR CANISTER IDLE MIXTURE PRESET AT FACTORY DO NOT REMOVE CAPS IF CARBURETOR IS REPAIRED OR IDLE MIXTURE SCREW CAPS HAVE BEEN REMOVED. RESET IDLE MIXTURE BY USING */4 TURN RICH FROM LEAN ROLL METHOD. INSTALL REPLACEMENT IDLE MIXTURE SCREW CAPS PROCURED FROM DEALER. REMOVAL OF MIXTURE SCREW CAPS AND ALTERING TO OTHER THAN SPECIFIED IDLE MIXTURE SETTING MAY VIOLATE FEDERAL AND/OR CALIFORNIA AND OTHER STATE LAWS. .( CONFORMS II /^W R •/« TURN RICH FROM LEAN ROLL CALIFORNIA III ENGINE EXHAUST EMISSION CONTROL INFORMATION G EN ER A L MOTORS CORPORATION MAKE IDLE SPEED (CARBURETOR SCREW OR SOLENOID SCREW) AND TIMING ADJUSTMENTS AT SPECIFIED RPM WITH ENGINE AT NORMAL OPERATING TEMP, CHOKE OPEN. AIR COND OFF. AIR CLEANER INSTALLED. DISTR. VACUUM LINE DISCONNECTED AND PLUGGED RECONNECT ALL FITTINGS WHEN SETTINGS ARE COMPLETED. SET PARKING BRAKE AND BLOCK DRIVE WHEELS. PUT TRANS IN PARK OR NEUT. FOR ALL SETTINGS. LEAN DROP IDLE MIXTURE IDLE MIXTURE PRESET AT FACTORY DO NOT REMOVE CAPS. REMOVAL OF MIXTURE SCREW CAPS AND ALTERING TO OTHER THAN SPECIFIED IDLE MIXTURE SETTING MAY VIOLATE FEDERAL AND/OR SOME STATE LAWS. IF CARBURETOR IS REPAIRED OR IDLE MIXTURE SCREW CAPS HAVE BEEN REMOVED, RESET IDLE MIXTURE BY LEAN DROP METHOD. IN STALL REPLACEMENT IDLE MIXTURE SCREW CAPS PROCURED FROM DEALER. f»» GASOLINE WHO MW PUTT ENGINES_ _ _ _ _ _ _ _ _ _ _ PT NO. 330S64 J 7 I REGULATIONS APPLICAIIE Tl Fig. 17—Tune-Up Decal On Heavy-Duty vehicles - C-K-P20 (except C-K20 suburban) and C-P30 - adjust carburetor Idle Speed Screw to obtain 600 rpm with automatic transmission in “Park” and manual transmission in neutral. On Light-Duty Vehicles - C-G-K10 and C20 Suburban adjust Idle Stop Solenoid (turn solenoid body, using hex nut) to obtain 600 rpm with automatic transmission in Drive - 900 rpm with manual transmission in neutral. On Light-Duty vehicles, disconnect the Idle Stop Solenoid electrical lead. Adjust low idle screw (located inside the solenoid hex nut) with screw on low step of cam, to obtain rpm - automatic transmission in Drive and manual transmission in neutral - reconnect Idle Stop Solenoid electrical lead. .Reconnect “Fuel Tank” line to v va^$^ canister and reconnect distributor spark advanceHfegase^ • 350 Cu. In. (Four-Barrel Carburetor) On Light-Duty vehicles, disconnect “Fuel Tank” line from Evaporation Emission vapor canister. Disconnect the distributor spark advance hose and plug the vacuum source opening. On Heavy-Duty vehicles, adjust carburetor Idle Speed Screw to obtain 600 rpm with automatic transmission in “Park” and manual transmission in neutral. On Light Duty vehicles, adjust Idle Stop Solenoid (turn solenoid body, using hex nut) to obtain 600 rpm with automatic transmission in Drive; 900 rpm with manual transmission in neutral. On Light-Duty vehicles with automatic transmission, reconnect distributor spark advance hose. Adjust fast idle LIGHT DUTY T R q p ^ E t & IC E MANUAL EN G IN E * 6-11 screw to obtain 1600 rpm with screw on top step of fast idle cam. On Light-Duty vehicles with manual transmission, adjust fast idle screw to obtain 1300 rpm with screw on top step of fast idle cam and distributor spark advance hose disconnected. Reconnect “Fuel Tank” line to vapor canister and reconnect distributor spark advance hose. • 454 Cu. In. (Four-Barrel Carburetor) On Light-Duty vehicles, disconnect “Fuel Tank” line from Evaporation Emission vapor canister. Disconnect the distributor spark advance hose and plug the vacuum source opening. Adjust Idle Stop Solenoid (turn solenoid body, using hex nut) to obtain: 700 rpm on all Heavy Duty vehicles - automatic transmission in “Park” ; manuaPMransmission in neutral. 6V00 rpm on Light-Duty vehicles with automatic transmission (in Drive). 900 rpm on Light-Duty vehicles with manual transmission (in neutral). On Light Duty vehicles with automatic transmission, _ig£onnect distributor spark advance hose. Adjust fast idle screw to obtain 1600 rpm with screw on top step of fast idle cam. ^ On Light-Duty vehicles with manual transmission, adjust fast idle screw to obtain 1600 rpm with screw on top step of fast idle cam and distributor spark advaii%" hos£ disconnected. : v*8"' Reconnect “Fuel Tank” line to vapor^anister and reconnect distributor spark advance hose. C A D D ITIO N A L CHECKS A N D ADJUSTMENTS CYLINDER BALANCE TEST (FIG. 1 8 ) It is often difficult to locate a weak cylinder. A compression test, for example, will not locate a leaky intake manifold, a valve not opening properly due to a worn camshaft, or a defective spark plug. With the cylinder balance test, the power output of one cylinder may be checked against another, using a set of grounding leads. When the power output of each cylinder is pot equal, the engine will lose power and run roughly. Perform a cylinder balance test as follows: 1. Connect the tachometer and vacuum gauge. 2. Start engine and run at 1500 rpm. 3. Ground large clip of grounding leads and connect individual leads to all spark plugs except the pair being tested. Divide the firing order in half and arrange one half over the other. The cylinders to be tested together appear one over the other. L6 Firing Order 1-5-3-6-2-4 = 1-5-3 = 1-6, 5-2, 3-4 BATTERY The battery should be checked with special testing equipment and to the equipment manufacturers specifications. See Section 6 Y for complete information on battery tests. IG N ITIO N The following additional ignition checks may be made with any of several pieces of equipment available for uncovering the source of engine difficulties. The specific operating instructions of the equipment manufacturer should be followed. • Cranking voltage • Ignition switch • Distributor resistance V 8 Fifing Order 1-8-4-3-6-5-7-2 = 1-84-3 = 1-6, 8-5, 4-7,3-2 6-5-7-2 4. Operate engine on each pair of cylinders in turn and note engine rpm and manifold vacuum for each pair. A variation of more than 1 inch of vacuum or 40 rpm between pairs of cylinders being tested indicates that the cylinders are off balance. LIGHT DUTY TRUCK SERVICE MAfUAL ■V 6 -1 2 ENQINE • Secondary Resistance • Ignitioft’oulput and secondary leakage Cranking Voltage (Fig. 19) 1. Disconnect coil .primary lead at the coil negative terminal , to prevent engine from firing during cranking. \ 2. Connect voltmeter between primary terminal of coil (resistance wire side) and ground. 3. Operate starting mbtor. a. If voltage is 9 volts or more and cranking speed is satisfactory, the battery, starter, cables, starter switch and ignition circuit to coil (by-passing resistance wire) are in good condition. \ b. If below 9 volts, check circuit until difficulty is located. Meter reading below specification-W eak battery; defective cables^ connections, switch or starter; defective ignition circuit to coil. Cranking speed below norm al-Excessive resistance in cables or starting motor; excessive mechanical drag in engine. Uneven cranking sp«ec£-Uneven compression, defective starter to starter drive. Fig. 19-Testing Cranking Voltage Ignition Switch With voltmeter connected as described for the Cranking Voltage Test, turn ignition switch to ON. Voltage should drop to 5 to 7 volts as current is now passing through high resistance wire connected between ignition switch and ( + ) positive terminal of coil. If battery voltage of 12 volts is obtained, the starter solenoid is by-passing the high resistance wire connected between ignition switch and ( + ) positive terminal of coil, thus the starter solenoid is not functioning properly to by-pass the ignition resistance wire or the ignition circuit is incorrectly wired. NOTE: The voltage drop (12 to 5-7 volts) will only take place when the points are closed. If the points are open, the path through the resistance wire will not be completed. Distributor Resistance Use equipment as directed by manufacturer. Excessive resistance in primary circuit must be eliminated before continuing with test procedure. Secondary Resistance Use equipment as directed by manufacturer. • Uniform “normal readings” as specified by manufacturer indicate all secondary circuit compo­ nents are in good condition. • If all readings are “below normal”, check for corroded coil tower terminal, poorly connected or broken coil wire, center cap electrode or rotor tip burned, or an open secondary in coil. • If readings are “higher than normal” at two or more plugs adjacent in firing order, cross firing is Fig. 20—Cooling System Pressure Check LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E occurring in distributor cap or between spark plug cables concerned. • If meter reads off scale to left, the coil polarity is reversed. Check for reversed coil primary wires, wrong coil or reversed vehicle battery connections. Ignition Output and Secondary Leakage Use equipment as directed by manufacturer. • GOOD readings indicate both ignition output and secondary insulation are good. • If all readings are BAD or if ignition test calibrator cannot be adjusted to Set Line, check for high resistance in primary circuit, defective distributor points, coil or condenser. • If readings are BAD when certain plug wires are lifted off, check for cracks or carbon tracks in distributor cap or defective insulation on those plug wires being lifted off. CARBURETOR Refer to Section 6 M to perform adjustments such as float level, pump rod and vacuum break. FUEL PUMP If the owner has complained of poor high speed performance, the fuel pump may be at fault. Too low a pump pressure or volume will cause a high speed “miss” because of lack of fuel delivered to the carburetor, while too high a pressure will cause carburetor flooding. Check fuel pump as outlined in Section 6 M. COOLING SYSTEM The following test may be performed with pressure testing equipment available commercially for this purpose. This test provides an excellent means of detecting internal or external leaks within the cooling system. 1. Remove radiator cap. 2. Apply a test pressure of 3 pounds higher than the radiator cap (fig. 20), i.e. 18 pounds for a 15 pound cap. 3. If the pressure will not hold, there is either an internal or external leak in the system. CYLINDER HEAD TORQUE AND VALVE ADJUSTMENT Retorquing the cylinder head bolts is not necessary unless a gasket has been replaced, or a leak is suspected. Valve lash must always be adjusted after the head has been torqued. Valve Adjustment 1. Remove rocker arm cover(s) and gasket(s). CAUTION: Do not pry rocker arm cover loose. Gaskets adhering to cylinder head and rocker arm cover may be sheared by bumping end of 6 -1 3 rocker arm cover rearward with palm of hand or a rubber mallet. 2. Adjust valves on L -6 engines as follows: a. Mark distributor housing, with chalk, at number one and number six positions (plug wire) then disconnect plug wires at spark plugs and coil and remove distributor cap and plug wire assembly (if not previously done). b. Crank engine until distributor rotor points to number one cylinder position and breaker points are open. The following valves can be adjusted with engine in number one firing position: Number one cylinder-Exhaust and Intake Number two cylinder-Intake Number three cylinder-Exhaust Number four cylinder-Intake Number five cylinder-Exhaust c. Back out adjusting nut until lash is felt at the push rod then turn in adjusting nut until all lash is removed. This can be determined by checking push rod end play while turning adjusting nut (fig. 21 ). When play Has been removed, turn adjusting nut in one full additional turn (to center lifter plunger). d. Crank engine until distributor rotor points to number six position and breaker points are open. The following valves can be adjusted with engine in number six firing position: Number two cylinder-Exhaust Number three cylinder-Intake ' Number four cylinder-Exhaust Number five cylinder-Intake Number six cylinder-Intake and Exhaust 3. Adjust valves on V -8 engines using the following procedures: a. Crank engine until mark on torsional damper lines up with center or “ 0 ” mark on the timing tab and the engine is in the number 1 firing position. This may be determined by placing fingers on the number 1 cylinder valve as the mark on the damper comes near the “ 0 ” mark on the front cover. If the valves are not moving, the engine is in the number 1 firing position. If the valves move as the mark comes up to the timing tab, the engine is in number 6 firing position and crankshaft should be rotated one more revolution to reach the number 1 position. b. Valve adjustment is made by backing off the adjusting nut (rocker arm stud nut) until there is play in the push rod and then tighten nut to just remove all push rod to rocker arm clearance. This may be determined by rotating push rod LIGHT DUTY TRUCK SERVICE MANUAL 6 -1 4 ENGINE Fig. 22—Valve Adjustment (V8 Engine) Fig. 21—Valve Adjustment (L6 Engine) with fingers as the nut is tightened (fig. 22 ). When push rod does not readily move in relation to the rocker arm, the clearance has been eliminated. The adjusting nut should then be tightened an additional 1 turn to place the hydraulic lifter plunger in the center of its travel. No other adjustment is required. c. With the engine in the number 1 firing position as determined above, the following valves may be adjusted. Exhaust - 1, 3, 4, 8 Intake - 1, 2, 5, 7 d. Crank the engine one revolution until the pointer “0 ” mark and torsional damper mark 4. 5. 6. 7. are again in alignment. This is number 6 firing position. With the engine in this position the following valve may be adjusted. Exhaust - 2, 5, 6 , 7 Intake - 3, 4, 6 , 8 Clean gasket surfaces on cylinder head(s) and rocker arm cover(s) with degreaser, then install rocker arm cover(s), using new gasket(s), and torque bolts to specifications. Install distributor cap and spark plug wire assembly. Install rocker arm cover as outlined. Adjust carburetor idle speed. THEORY OF OPERATION All engines operate on the 4-stroke cycle principle (Fig. ID and 2D). During this cycle the piston travels the length of its stroke four times. As the piston travels the length of its stroke (up or down) the crankshaft is rotated halfway (180 degrees). To accomplish one cycle of the 4 -stroke cycle, the crankshaft rotates two complete turns; the camshaft, which controls the valves, is driven by the crankshaft at half crankshaft speed. Valve action, intake and exhaust, occurs once in each 4-stroke cycle and the piston acts as an air pump during the two remaining strokes. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6 -1 5 Fig. ID —Sectional View of Eight-Cylinder Engine LIGHT DUTY TRUCK SERVICE MANUAL 6-16 ENGINE Fig. 2D—Sectional View of Six-Cylinder Engine Intake Stroke The intake valve is opened as the piston moves down in the cylinder (Fig. 3D). The piston traveling downward in the cylinder creates an area of pressure lower than that of the atmosphere surrounding the engine. Atmospheric pressure will cause air to flow into this low pressure area. By directing the air flow through the carburetor, a measured amount of vaporized fuel is added. When the piston reaches the bottom of the intake stroke, the cylinder is filled with air and vaporized fuel. The exhaust valve is closed during the intake stroke. down. This downward motion of the piston is transmitted through the connecting rod and is converted to rotary motion by the crankshaft. Both the intake and exhaust valve are closed during the power stroke (Fig. 5D). Exhaust Stroke When the piston starts to move upward, the compression stroke begins (Fig. 4D). The intake valve closes, trapping the air-fuel mixture in the cylinder. The upward movement of the piston compresses the mixture to a fraction of its original volume; exact pressure depends principally on the compression ratio of the engine. The exhaust valve opens just before the piston completes the power stroke (Fig. 6 D). Pressure in the cylinder at this time causes the exhaust gas to rush into the exhaust manifold. The upward movement of the piston on its exhaust stroke expels most of the remaining exhaust gas. As the piston pauses momentarily at the top of the exhaust stroke, the inertia of the exhaust gas tends to remove any remaining gas in the combustion chamber; however, a small amount of exhaust gas always remains to be mixed with the incoming mixture - this unexpelled gas is captured in the clearance area between the piston and the cylinder head. Power Stroke Combustion The power stroke is produced by igniting the compressed air-fuel mixture. When the spark plug arcs, an explosion does not occur. Instead, the mixture ignites and burns very rapidly during the power stroke. The extremely high temperature expands the gases, creating a very high pressure on the top of the piston which drives the piston The power delivered from the piston to the crankshaft is the result of a pressure increase in the gas mixture above the piston. This pressure increase occurs as the mixture is heated, first by compression, and then — on the down stroke — by burning. The burning fuel supplies heat that raises temperature and at the same time also raises Compression Stroke LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E 6 -1 7 Fig. 4D—Piston Compression Stroke Fig. 3D—Piston Intake Stroke pressure. Actually, about 75 per cent of the mixture in the cylinder is composed of nitrogen gas that does not burn but expands when heated by the burning of the combustible elements, and this expanding nitrogen supplies most of the pressure on the piston. The fuel and oxygen must burn smoothly within the combustion chamber to take full advantage of this heating effect. Maximum power would not be delivered to the piston if an explosion took place, because the entire force would be spent in one sharp hammer-like blow, occurring too fast for the piston to follow. Instead, burning must take place evenly as the flame moves across the combustion chamber. Burning must be completed by the time the piston is about half-way down so that maximum pressure will be developed in the cylinder at the time the piston sends its greatest force to the crankshaft. This will be when the mechanical advantage of the connecting rod and crankshaft is at a maximum. At the beginning of the power stroke, as the piston is driven downward by this pressure the volume above the piston increases, which would normally allow the pressure in the cylinder to drop. However, the combustion process is still occurring and this continues to raise the temperature of the gases, expanding them and maintaining a continuous pressure on the piston as it travels downward. This provides a smooth application of power throughout the effective part of the power stroke to make the most efficient use of the energy released by the burning fuel. An internal combustion engine actually runs on heated air, the air being composed mainly of inert nitrogen. The fuel is used, not to cause explosions, but to cause high pressure within the cylinder to push the piston down smoothly during the power stroke. Compression Ratio The compression ratio is a comparison of the volume of the cylinder and combustion chamber when the piston is all the way down, to the volume remaining when the piston is all the way up. The main advantage of a high compression ratio is that it enables the engine to develop more power from a given charge of fuel. The combustion pressure exerted downward on the piston is always 3 or 4 times as great as the compression pressure. Consequently, an increase in LIGHT DUTY TRUCK SERVICE MANUAL 6 -1 8 ENGINE Fig. 6D—Piston Exhaust Stroke Fig. 5D—Piston Power Stroke compression pressure (input) means at least three times as great an increase in combustion pressure (output). Valve Timing As in most 4-stroke cycle engines, the intake valve begins to open before the piston reaches the top, and the exhaust valve remains open until after top dead center. This means that both valves are open for a short period of time. This condition is called valve overlap (Fig. 7D). The valve timing is arranged this way to use the inertia of the gas in evacuating and in filling the cylinders. When the air-fuel mixture and exhaust gases move in or out of the cylinder, its weight gives it momentum in the established direction. When a valve opens, the initial air flow is slow. Valve timing allows for this lag in starting and stopping in the flow. In order to pack the maximum air-fuel mixture into the cylinder, each valve opens earlier and closes later than would be necessary if the mixture were weightless. On the intake stroke, the exhaust valve stays open a little after top center to take advantage of the momentum of the exhaust gases rushing out through the valve, even though the piston has started down. With the exhaust TOP DEAD CENTER INTAKE VALVEOPENS INTAKE VALVE CLOSES EXHAUST VALVE CLOSES EXHAUST VALVE OPENS BOTTOM DEAD CENTER Fig. 7D—Typical Valve Overlap (720-degree spiral) LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E 6 -1 9 valve still open, the cylinder continues to empty itself because of this momentum. On the compression stroke, the intake valve stays open past bottom center because incoming gases will continue to pack their way in for a short time after the piston reverses direction, due to their momentum. On the power stroke, the exhaust valve opens before bottom center to get the exhaust gases started out of the cylinder. On the exhaust stroke, the intake valve opens before top center to start the air fuel mixture moving into the cylinder. Valve timing is not variable with speed and load as is ignition timing. Except for very small variations due to the stack of tolerances in the valve train (Fig. 8 D), valves always open and close at the same time in the cycle. There is, however, one particular speed for a given engine at which the air-fuel mixture will pack itself into the cylinders most effectively. This is the speed at which the engine puts out its peak torque. At low engine speeds, compression is somewhat suppressed due to the slight reverse flow through the valves just as they open or close, when the mixture is not moving fast enough to take advantage of the time lag. At very high speeds, the valve timing does not allow quite enough time during the opening and closing periods for effective packing of the air-fuel mixture into the cylinders. Fig. 8D—Valve System Components ENGINE MECHANICAL IN-LINE ENGINES INDEX General Description............................................................ Component Replacement and Adjustment................. Engine Assembly................................................................ Removal (C, K and P Series).................................... Removal (G Series)........................................................ Installation (C, K and P Series)............................... Installation (G Series)................................................... Manifold Assembly........................................................... Removal.............................................................................. Installation......................................................................... Rocker Arm Cover............................................................ Removal.............................................................................. Installation......................................................................... Valve Mechanism............................................................... Removal.............................................................................. Installation and Adjustment........................................ Valve Lifters........................................................................ Locating Noisy Lifters.................................................. Removal.............................................................................. Installation......................................................................... Valve Stem Oil Seal and/or Valve Spring.............. 6-20 6-20 6-20 6-20 6-22 6-23 6-24 6-25 6-25 6-25 6-26 6-26 6-26 6-26 6-26 6-26 6-26 6-27 6-27 6-27 6-27 Replacement...................................................................... Cylinder Head Assemblies.............................................. Removal............................................................................... Installation......................................................................... Oil P an .................................................................................. Removal............................................................................... Installation......................................................................... Oil Pump............................................................................... Removal............................................................................... Installation......................................................................... Oil Seal (Rear M ain)...................................................... Replacement...................................................................... Torsional Damper.............................................................. Removal.............................................................................. Installation......................................................................... Crankcase Front Cover................................................... Removal.............................................................................. Installation......................................................................... Oil Seal (Front Cover).................................................... Replacement...................................................................... Camshaft............................................................................... 6-27 6-28 6-28 6-28 6-28 6-28 6-28 6-29 6-29 6-29 6-29 6-29 6-30 6-30 6-30 6-31 6-31 6-31 6-32 6-32 6-33 LIGHT DUTY TRUCK SERVICE MANUAL 6 - 2 0 ENGINE Measuring Lobe Lift ......................................................... Removal .................................................. ........................... Installation .......................................................................... Timing Gears ...................................................................... Replacement ...................................................................... Flywheel ............................................................................... 6-33 6-34 6-34 6-35 6-35 6-35 Removal .............................................................................. 6-35 Installation .......................................................................... 6-35 Engine Mounts...................................................................... .6-36 Checking Engine Mounts ................................................ 6-36 Replacement (Front) ........................................................6-36 Replacement (Rear) ......................................................... 6-36 GENERAL DESCRIPTION The In-Line engines covered in this section are the 250 and 292 cu. in. L6 engines used in 10-30 Series truck vehicles (fig. 1L). This section covers the removal and installation of engine assemblies, the removal, installation and adjustment of some sub-assemblies and replacement of some components. For service to all components and sub-assemblies (after removal) and removal of some sub-assemblies, refer to Section 6 of the Overhaul Manual. Because of the interchangeability and similarity of many engine sub-assemblies and parts, regardless of which truck vehicle they are used in, typical illustrations and procedures are used (except where specific illustrations or procedures are necessary to clarify the operation). Although illustrations showing bench operations are used, most single operations, when not part of a general overhaul, should be performed (if practical) with the engine in the vehicle. C O M PO N EN T REPLACEMENT A N D ADJUSTMENT Engine Assembly Removal (C, K and P Series) 1. Disconnect battery cables and drain cooling system. 2. Remove the air cleaner. 3. Perform the following preliminary operations. ON CS 10-20-30, KS 10-20 SERIES: Remove the hood as outlined in Section 11. Remove the radiator and shroud as outlined in Section 13. ON PS 10-20-30 SERIES: Remove the engine box and hood as outlined in Section 11. Remove the battery. Remove the radiator and shroud as outlined in Section 13. 4. Disconnect wires at: Starter Solenoid. Delcotron. Temperature Switch. Oil Pressure Switch. Coil. CEC Solenoid. 5. Disconnect: Accelerator linkage at manifold bellcrank. Fuel line (from tank) at fuel pump. Heater hoses at engine connection. Oil pressure gauge line (if so equipped). Vacuum lines at engine (as required). • Evaporation Emission System lines at carburetor. • Power steering pump at engine bracket and lay aside (if so equipped). • Ground straps at engine. • Exhaust pipe at manifold. NOTE: Hang exhaust pipe at frame with wire. 6 . Remove fan and pulley as outlined in Section 6 K. 7. Remove clutch cross-shaft (if so equipped). 8 . Perform the following operations: • Remove the rocker arm cover as outlined. • Attach lifting device or chain to engine lifting brackets and take engine weight off mounts. ON ALL SERIES EXCEPT CS 10-20-30: • Support transmission and disconnect from engine. Refer to Section 7. • Remove engine mount bolts. ON CS 10-20-30: • Remove propeller shaft as outlined in Section 4. NOTE: If plug for propeller shaft opening in transmission is not available, drain transmission. Disconnect TCS switch at transmission. Disconnect speedometer cable at transmission. Disconnect shift linkage at transmission. Disconnect clutch linkage (as required). Remove engine mount bolts. Transmission cooler lines (if so equipped). E N G IN E 6-21 Fig. 1 L —Six-C ylinder Engine 9. Remove engine from vehicle as follows: CAUTION: Check often during engine removal to be sure all necessary disconnects have been made. ON CS 10-20-30 SERIES: • On vehicles with automatic or four speed transmission, remove rear mount crossmember. • Raise engine and transmission assembly and pull forward until removed. ON KS 10-20 SERIES: • Raise engine and pull forward until disconnected from transmission. • Continue to raise engine until removed from vehicle. ON PS 10-20-30 SERIES: • Raise engine and push forward to clear cross­ member and disconnect from transmission. • Remove engine from vehicle. 10. If engine is to be mounted in an engine stand perform the following: ON CS 10-20-30: • Remove synchromesh transmission and clutch (if so equipped). a. Remove clutch housing rear cover bolts. b. Remove bolts attaching the clutch housing to engine block then remove transmission and clutch housing as a unit. NOTE: Support the transmission as the last mounting bolt is removed and as it is being pulled away from the engine, to prevent damage to clutch disc. c. Remove starter and clutch housing rear cover. d. Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. • Remove automatic transmission (if so equipped). a. Lower engine, secured by the hoist, and support engine on blocks. b. Remove starter and converter housing under pan. c. Remove flywheel-to-converter attaching bolts. d. Support transmission on blocks. e. Disconnect throttle linkage and vacuum modula­ tor line. f. Remove transmission-to-engine mounting bolts. g. With the hoist attached, remove blocks from the engine only and slowly guide the engine from the transmission. LIGHT DUTY TRUCK SERVICE MANUAL 6 -2 2 ENGINE ON ALL SERIES EXCEPT CS 10-20-30: • Remove clutch housing. • Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. 11. Mount engine in engine stand and remove lifting device and lifting adapter. Removal (G Series) 1. Remove engine cover and position it out of way. 2. Disconnect battery ground cable at engine block and at battery. 3. Drain cooling system and disconnect heater hoses at engine; disconnect radiator hoses at radiator. 4. Disconnect automatic transmission cooler lines at radiator. 5. Remove fan guard and radiator. 6 . Disconnect oil pressure gauge, if so equipped. 7. Disconnect engine wiring harness at dash panel junction block. 8 . Disconnect Delcotron wires at rear of Delcotron. 9. Disconnect TCS system electrical leads at car­ buretor mounted CEC valve and at temperature switch - remove harness from clips and position it to one side. 10. Disconnect Evaporation Control System lines at air cleaner and at carburetor - position lines to one side. 11. Disconnect accelerator linkage at dash panel mounted bell crank. 12. Disconnect power brake vacuum line at inlet manifold. 13. Raise vehicle on a hoist and disconnect: Fig. 2L—Brake Line Disconnects • • • • Fuel line (from tank) at fuel pump. Engine ground strap(s). Steering idler arm at frame. Steering pitman arm at steering gear as outlined in Section 9. • Battery positive cable at starter. • Speedometer cable at transmission. • TCS switch at transmission - remove bell housing mounted clip and position wiring to one side. • Exhaust pipe at manifold and at pipe hangers then remove exhaust system from vehicle. • Transmission at crossmember. • Stabilizer shaft at frame brackets. 14. Disconnect clutch linkage and/or transmission linkage and remove cross shaft as outlined in Section 7. Fig. 4L-Suspension-to-Frame Attaching Bolts LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E 15. Disconnect shock absorbers at frame or at lower control arm attachment and position shocks up and rearward. 16. Remove propeller shaft as outlined in Section 4 install plug in transmission extension. 17. Disconnect front brake pipe at equalizer tee and disconnect rear brake pipe at connector at left frame rail (Fig. 2L). 18. Disconnect rear brake pipe at right frame rail connector (Fig. 3L). 19. Remove transmission support frame-to-crossmember attaching nuts - do not remove bolts at this time. 20. Remove the six (3 on each side) vertically driven front crossmember-to-frame attaching bolts (Fig. 3L). 21. Remove the four (2 on each side) frame-to-upper control arm (inside) attaching bolts (Fig. 4L). 22. Lower the vehicle on hoist so that weight of vehicle is on hoist but with wheels touching floor and suspension at curb height. 23. Install wood blocks between oil pan and crossmem­ ber to stabilize engine assembly (Fig. 5L). 24. Position floor jack under vehicle so that jack pad is aligned under transmission and, using a block of wood to protect transmission, support transmission with jack. 25. Remove transmission support crossmember. 26. Remove the four (2 on each side) remaining suspension-to-frame (outside) retaining bolts (Fig. 4L). 27. Raise vehicle slowly, leaving suspension and power train on the floor until sufficient clearance is obtained for removing engine. CAU TIO N: Check often when raising the vehicle to make sure that all disconnects have been made and that vehicle is positioned properly on hoist. 28. Roll the power train and suspension assembly to the work area and position jack stand under transmission extension - remove floor jack. 29. Place floor jack under suspension crossmember and raise jack so that weight of assembly is supported on jack pad. 30. Attach lifting adapter at engine lifting brackets. 31. Attach lifting device to support engine, remove engine mount through bolts and remove engine assembly from crossmember. 32 Remove synchromesh transmission and clutch (if so equipped). a. Remove clutch housing rear cover bolts. b. Remove bolts attaching the clutch housing to 6 -2 3 Fig. 5 L —F loor Jack Location Under Transmission (L-6) engine block, then remove transmission and clutch housing as a unit. NOTE: Support the transmission as the last mounting bolt is removed and as it is being pulled away from the engine, to prevent damage to clutch disc. c. Remove starter and clutch housing rear cover. d. Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. 33. Remove automatic transmission (if so equipped). a. Lower engine, secured by the hoist, and support engine on blocks. b. Remove starter and converter housing underpan. c. Remove flywheel-to-converter attaching bolts. d. Support transmission on blocks. e. Disconnect detent cable on Turbo Hydra-Matic. f. Remove transmission-to-engine mounting bolts. g. With the hoist attached, remove blocks from the engine only and slowly guide the engine away from the transmission. 34. Mount engine in engine stand and remove lifting device and lifting adapter. Installation (C, K and P Series) 1. If engine was mounted in an engine stand, attach lifting adapter to engine lift brackets then using lifting device, remove engine from stand and perform the following: ON CS 10-20-30: LIGHT DUTY TRUCK SERVICE MANUAL 6 -2 4 ENGINE 2. 3. 4. 5. 6. • Install synchromesh transmission and clutch (if so equipped). a. Install the clutch assembly on flywheel as outlined in Section 7. b. Install clutch housing rear cover and starter. c. Install the transmission and clutch housing as outlined in Section 7. d. Install clutch housing rear cover bolts and torque to specifications. • Install automatic transmission (if so equipped). a. Position engine adjacent to the transmission and align the convertor with the flywheel. b. Bolt transmission to engine then raise engine and transmission assembly and install flywheel to convertor bolts. c. Install convertor housing underpan and starter. d. Connect throttle linkage and vacuum modulator line. ON ALL SERIES EXCEPT CS 10-20-30: • Install clutch assembly and clutch housing as outlined in Section 7. Install engine in vehicle as follows: ON ALL SERIES EXCEPT CS 10-20-30: • Install engine, and lower until transmission shaft lines up with clutch. • Push engine rearward and rotate crankshaft until transmission shaft and clutch engage. • Install the engine mount bolts and torque to specifications. • Connect transmission to engine. ON CS 10-20-30 SERIES: • Lower engine and transmission assembly and push rearward until engine mounts line up. • On vehicles with automatic or four speed transmissions, install rear mount crossmember. •Install the engine mount bolts and torque to specifications. •Install the propeller shaft as outlined in Section 4. ON ALL SERIES: • Remove the lifting device and lifting adapter from engine lift brackets. Connect transmission linkage (as required). Install clutch cross-shaft (as required). Install fan and pulley as outlined in Section 6 K. Connect: • Transmission cooler lines (if so equipped). • Exhaust pipe at manifold. • Power steering pump (as required). • Vacuum lines at engine (as required). • Oil pressure gauge line (as required). • Heater hoses at engine connection. • Fuel line at fuel pump. • Accelerator linkage at manifold bellcrank. • TCS switch at transmission. • Evaporation Emission System hoses at canister. 7. Connect wires at: • Coil • Oil Pressure Switch • Temperature Switch • Delcotron • Starter Solenoid • CEC Solenoid 8 . Complete installation as follows: ON PS 10-20-30 SERIES: • Install the radiator and shroud as outlined in Section 13. • Install the battery. • Install the floor panel and engine box as outlined in Section 1B. ON CS 10-20-30, KS 10-20 SERIES: • Install the radiator and shroud as outlined in Section 13. • Install the hood as outlined in Section 11. 9. Install the air cleaner, connect battery cables, fill cooling system and crankcase then start engine and check for leaks. Installation (G Series) 1. If engine was mounted in an engine stand, attach lifting adapter-to-engine, then using lifting device, remove engine from stand and perform the following: • Install synchromesh transmission and clutch (if so equipped). a. Install the clutch assembly on flywheel as outlined in Section 7. b. Install clutch housing rear cover and starter. c. Install the transmission and clutch housing as outlined in Section 7. d. Install clutch housing bolts and torque to specifications. • Install automatic transmission (if so equipped). a. Position engine adjacent to the transmission and align the converter with the flywheel. b. Bolt transmission to engine and then raise LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. engine and transmission assembly and install flywheel to converter bolts. c. Install converter housing underpan and starter. d. Connect throttle linkage and detent cable on Turbo Hydra-Matic. Raise engine and align mounts on engine with brackets on crossmember - install engine mount through bolts. Place wood block between oil pan and crossmember to stabilize power train. Remove floor jack from under crossmember and position jack pad under transmission assembly, using wood blocks at jack pad to protect transmission. Remove the lifting device from engine brackets. Roll the power train and suspension assembly under vehicle so that crossmember is aligned with frame. Slowly lower the vehicle, checking often to assure that engine components do not interfere with vehicle as it is being lowered, until suspension to frame attaching bolt holes are aligned. Install and securely tighten suspension to-frame attaching bolts. Install transmission support crossmember, and remove floor jack from beneath the transmission. Raise vehicle on the hoist and install the remaining suspension-to-frame attaching bolts - torque boltsto-specifications. Torque transmission-to-crossmember and crossmember to frame bolts to specifications. Install propeller shaft as outlined in Section 4. Connect rear brake pipe at right fram e-rail connector; connect front brake pipe at equalizer tee and connect rear brake pipe at left frame rail connector. Install and torque shock absorber attaching bolts to specifications. Connect stabilizer shaft to frame. Install cross shaft and connect clutch linkage and/ or transmission linkage as outlined in Section 7. Connect the following items: • Fuel line (from tank) at fuel pump. • Engine ground strap(s). • Steering idler arm at frame; then steering pitman arm at steering gear and torque nut to specifications. • Battery positive cable at starter. • Speedometer cable at transmission. • TCS switch at transmission - install TCS wire to clip at transmission/clutch housing. • Install exhaust system. 6-25 16. Remove wood block placed between crossmember and oil pan. 17. Lower vehicle on hoist. 18. Connect accelerator linkage at dash panel mounted bell crank. 19. Connect Evaporation Control System lines at air cleaner and at carburetor. 20. Connect TCS system electrical leads at carburetor mounted CEC valve and at temperature switch position harness in rocker arm cover clips. 21. Connect electrical leads at rear of Delcotron. 22. Connect engine wiring harness at dash panel junction block. 23. Connect oil pressure gauge line if so equipped. 24. Install radiator and fan guard, connect radiator and heater hoses, install automatic transmission cooler lines and fill cooling system. 25. Connect battery ground cable at engine block and at battery. 26. Connect power brake vacuum hose at inlet manifold fitting. 27. Install engine cover. 28. Bleed front and rear brakes as outlined in Section 5. 29. Start engine, check and add engine coolant as required and check engine for proper operation. Manifold Assembly Removal 1. Remove air cleaner. 2. Disconnect both throttle rods at bellcrank and remove throttle return spring. 3. Disconnect fuel and vacuum lines and choke cable at carburetor. 4. Disconnect crankcase ventilation hose at rocker arm cover. 5. Disconnect exhaust pipe at manifold flange and discard packing. 6 . Remove manifold attaching bolts and clamps then remove manifold assembly and discard gaskets. 7. Check for cracks in manifold castings. 8 . Separate manifolds by removing one bolt and two nuts at center of assembly. 9. Disconnect exhaust gas recirculation valve hose. Installation 1. Clean gasket surfaces on cylinder head and manifolds. 2. Lay a straight edge along the full length of the exhaust port faces and measure any gaps between the straight edge and the port faces. If at any point a gap of .015 or more exists, it is likely the LIGHT DUTY TRUCK SERVICE MANUAL 6 -2 6 ENGINE 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. manifold has distorted to a point where it will not seat properly. If a good exhaust seal is to be expected, the exhaust manifold must be replaced. Reinstall the one bolt and two nuts at the center of the manifold to finger tight. Position new gasket over manifold end studs on the cylinder head. Install manifold assembly bolts and clamps while holding manifold assembly in place by hand. Clean, oil and torque all manifold assembly-tocylinder head bolts and nuts to specifications. Complete torqueing the inlet to exhaust manifold bolt and two nuts at the center of the manifold to specifications. Connect exhaust pipe to manifold using a new packing. Connect crankcase ventilation hose at rocker arm cover. Connect exhaust gas recirculation valve hose. Connect fuel and vacuum lines at carburetor. Connect throttle rods at bellcrank and install throttle return spring. Install air cleaner, start engine, check for leaks and adjust carburetor idle speed. and push rods in a rack so that they may be reinstalled in the same location. Installation and Adjustment 1. 2. 3. Rocker Arm Cover Removal 1. Disconnect crankcase ventilation hose(s) at rocker arm cover. 2. Remove air cleaner. 3. Disconnect temperature wire from rocker arm cover clips. 4. Remove air injection pipe support bracket. 5. Remove rocker arm cover. Installation 1. Clean gasket surfaces on cylinder head and rocker gasket, install rocker arm cover and torque to specifications. 2. Connect temperature wire at rocker arm cover clips. 3. Install air cleaner. 4. Connect crankcase ventilation hoses. 5. Install air injection pipe support bracket. Valve Mechanism Removal 1. Remove rocker arm cover as outlined. 2. Remove rocker arm nuts, rocker arm balls, rocker arms and push rods. NOTE: Place rocker arms, rocker arm balls 4. 5. 6. NOTE: Whenever new rocker arms and/or rocker arm balls are being installed, coat bearing surfaces of rocker arms and rocker arm balls with “Molykote” or its equivalent. Install push rods. Be sure push rods seat in lifter socket. Install rocker arms, rocker arm balls and rocker arm nuts. Tighten rocker arm nuts until all lash is eliminated. Adjust valves when lifter is on base circle of camshaft lobe as follows: a. Mark distributor housing, with chalk, at number one and number six cylinder positions (plug wire) then disconnect plug wires at spark plugs and coil and remove distributor cap and plug wire assembly (if not previously done). b. Crank engine until distributor rotor points to number one cylinder position and breaker points are open. The following valves can be adjusted with engine in number one firing position. Number one cylinder-Exhaust and Intake Number two cylinder-Intake Number three cylinder-Exhaust Number four cylinder-Intake Number five cylinder-Exhaust c. Back out adjusting nut until lash is felt at the push rod then turn in adjusting nut until all lash is removed. This can be determined by checking push rod side play while turning adjusting nut (fig. 6 L). When play has been removed, turn adjusting nut in one full additional turn (to center lifter plunger). d. Crank engine until distributor rotor points to number six position and breaker points are open. The following valves can be adjusted with engine in number six firing position: Number two cylinder-Exhaust Number three cylinder-Intake Number four cylinder-Exhaust Number five cylinder-Intake Number six cylinder-Intake and Exhaust Install distributor cap and spark plug wire assembly. Install rocker arm cover as outlined. Adjust carburetor idle speed. Valve Lifters Hydraulic valve lifters very seldom require attention. LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E 6-27 c. Improper adjustment. 3. General Noise Throughout the Valve Train — This will, in most cases, be caused by either insufficient oil supply or improper adjustment. 4. Intermittent Clicking — Probable causes are: a. A microscopic piece of dirt momentarily caught between ball seat and check valve ball. b. In rare cases, the ball itself may be out-of-round or have a flat spot. c. Improper adjustment. In most cases, where noise exists in one or more lifters, all lifter units should be removed, disassembled, cleaned in a solvent, reassembled, and reinstalled in the engine. If dirt, varnish, carbon, etc. is shown to exist in one unit, it more than likely exists in all the units, thus it would only be a matter of time before all lifters caused trouble. Removal Fig. 6L—Valve Adjustment The lifters are extremely simple in design. Readjust­ ments are not necessary, and servicing of the lifters requires only that care and cleanliness be exercised in the handling of parts. Locating Noisy Lifters Locate a noisy valve lifter by using a piece of garden hose approximately four feet in length. Place one end of the hose near the end of each intake and exhaust valve with the other end of the hose to the ear. In this manner, the sound is localized making it easy to determine which lifter is at fault. Another method is to place a finger on the face of the valve spring retainer. If the lifter is not functioning properly, a distinct shock will be felt when the valve returns to its seat. The general types of valve lifter noise are as follows: 1. Hard Rapping Noise — Usually caused by the plunger becoming tight in the bore of the lifter body to such an extent that the return spring can no longer push the plunger back up to working position. Probable causes are: a. Excessive varnish or carbon deposit causing abnormal stickiness. b. Galling or “pickup” between plunger and bore of lifter body, usually caused by an abrasive piece of dirt or metal wedging between plunger and lifter body. 2. Moderate Rapping Noise — Probable causes are: a. Excessively high leakdown rate. b. Leaky check valve seat. 1. Remove valve mechanism as outlined. 2. Mark distributor housing, with chalk, at number one and number six cylinder position (plug wire) then disconnect plug wires at spark plugs and coil and remove distributor cap and plug wire assembly. 3. Crank engine until distributor rotor points to number one position, then disconnect distributor primary lead at coil and remove distributor. 4. Remove push rod covers (discard gaskets). 5. Remove valve lifters. NOTE: Place valve lifters in a rack so that they may be reinstalled in the same location. Installation 1. Install valve lifters. NOTE: Whenever new valve lifters are being installed, coat foot of valve lifters with “Molykote” or its equivalent. 2. Install push rod covers, using new gaskets, and torque to specifications. 3. Install distributor, positioning rotor to number one cylinder position, then connect primary lead at coil. 4. Install and adjust valve mechanism as outlined. 5. Adjust ignition timing and carburetor idle speed. Valve Stem Oil Seal and/or Valve Spring Replacement 1. Remove rocker arm cover as outlined. 2. Remove spark plug, rocker arm and push rod on the cylinder(s) to be serviced. 3. Install air line adapter Tool J-23590 to spark plug port and apply compressed air to hold the valves in place. 4. Using Tool J-5892 to compress the valve spring, LIGHT DUTY TRUCK SERVICE MANUAL 6 -2 8 ENGINE 5. 6. 7. 8. 9. remove the valve locks, valve cap, valve shield and valve spring and damper (fig. 7L). Remove the valve stem oil seal. To replace, set the valve spring and damper, valve shield and valve cap in place. Compress the spring with Tool J-5892 and install oil seal in the lower groove of the stem, making sure the seal is flat and not twisted. NOTE: A light coat of oil on the seal will help prevent twisting. Install the valve locks and release the compressor tool, making sure the locks seat properly in the upper groove of the valve stem. NOTE: Grease may be used to hold the locks in place while releasing the compressor tool. Install spark plug and torque to specifications. Install and adjust valve mechanism as outlined. Cylinder Head Assemblies Removal 1. 2. 3. 4. 5. 6. 7. 8. Remove manifold assembly as outlined. Remove valve mechanism as outlined. Drain cooling system (block). Remove fuel and vacuum line from retaining clip at water outlet then disconnect wires from temperature sending units. Disconnect air injection hose at check valve. Disconnect radiator upper hose at water outlet housing and battery ground strap at cylinder head. Remove coil. Remove cylinder head bolts, cylinder head and gasket. Place cylinder head on two blocks of wood to prevent damage. Installation CAUTIO N: The gasket surfaces on both the head and the block must be clean of any foreign matter and free of nicks or heavy scratches. Cylinder bolt threads in the block and threads on the cylinder head bolt must be cleaned. (Dirt will affect bolt torque). Do not use gasket sealer on composition steel asbestos gaskets. 1. Place the gasket in position over the dowel pins with the bead up. 2. Carefully guide cylinder head into place over dowel pins and gasket. 3. Coat threads of cylinder head bolts with sealing compound and install finger tight. 4. Tighten cylinder head bolts a little at a time in the sequence shown on the torque sequence chart until the specified torque is reached. 5. Connect air injection hose at check valve. 6 . Install coil. 7. Connect radiator upper hose and engine ground strap. 8 . Connect temperature sending unit wires and install fuel and vacuum lines in clip at water outlet. 9. Fill cooling system. 10. Install manifold assembly as outlined. 11. Install and adjust valve mechanism as outlined. 12. Install and torque rocker arm cover. Oil Pan Removal 1. Disconnect battery ground cable. 2. Raise vehicle on a hoist and disconnect starter at engine block - leave electrical connections intact and position starter out of way. 3. On G Series vehicles, remove bolts securing engine mounts to crossmember brackets - then, using a suitable jack with a flat piece of wood to protect oil pan, raise engine sufficiently to insert 2” x 4” wood block between engine mounts and crossmember brackets (fig. 8 L). 4. Drain engine oil and remove flywheel (convertor) cover. 5. Remove oil pan bolts and withdraw oil pan from engine. Installation Fig. 7L—Compressing Valve Spring 1. Discard old gaskets and seals, thoroughly clean all gasket sealing surfaces. 2. Install new rear seal in rear main bearing cap. LIGHT DUTY TRUCK SERVICE MANUAL EN GINE 6-29 Fig. 8L—Engine Blocked for Oil Pan Removal 3. Install new front seal on crankcase front cover pressing, tips into holes provided in cover. 4. Install new side gaskets on cylinder block (fig. 9L). NOTE: DO NOT USE SEALER. 5. Position oil pan to block, making sure that seals and gaskets remain in place, install and torque pan screws to specifications. 6 . On G Series vehicles, raise engine as outlined above and remove blocks used to support engine. 7. On G Series vehicles, lower engine, install and torque mount-to-crossmember bracket bolts. 8 . Install starter and flywheel (convertor) cover. 9. Fill engine with specified quantity of oil, then start engine and check for leaks. Oil Pump Removal 1. Remove oil pan as outlined. 2. Remove two flange mounting bolts, pickup pipe bolt, then remove pump and screen as an assembly. Installation 1. Align oil pump drive shafts to match with distributor tang, then install oil pump to block positioning flange over distributor lower bushing. Use no gasket. NOTE: Oil pump should slide easily into place, if not, remove and reposition slot to align with distributor tang. 2. Install oil pan as outlined. Fig. 9L—Oil Pan Gasket and Seal Location Oil Seal (Rear Main) Replacement NOTE: Always replace the upper and lower seal as a unit. Install seal with lip facing front of engine. The rear main bearing oil seal can be replaced (both halves) without removal of the crankshaft. Extreme care should be exercised when installing this seal to protect the sealing bead located in the channel on the outside diameter of the seal. An installation tool (fig. 10L) can be used to protect the seal bead when positioning seal as follows: 1. With the oil pan and oil pump removed, remove the rear main bearing cap. 2. Remove oil seal from the bearing cap by prying from the bottom with a small screw driver (fig. 1 1 L). 3. To remove the upper half of the seal, use a small hammer to tap a brass pin punch on one end of seal until it protrudes far enough to be removed with pliers (fig. 12L). 4. Clean all sealant and foreign material from cylinder case bearing cap and crankshaft, using a non-abrasive cleaner. 5. Inspect components for nicks, scratches, burrs and machining defects at all sealing surfaces, case assembly and crankshaft. LIGHT DUTY TRUCK SERVICE MANUAL 6 30 ENGINE 6 . Coat seal lips and seal bead with light engine oil — keep oil off seal mating ends. 7. Position tip of tool between crankshaft and seal seat in cylinder case. 8 . Position seal between crankshaft and tip of tool so that seal bead contacts tip of tool. NOTE: Make sure that oil-seal lip is positioned toward front of engine (fig. 13L). 9. Roll seal around crankshaft using tool as a “shoe-horn” to protect seal bead from sharp corner of seal seat surface in cylinder case. CAU TIO N: Installation tool must remain in position until seal is properly positioned with both endsflush with block. 10. Remove tool, being careful not to withdraw seal. 11. Install seal half in bearing cap, again using tool as a “shoe-horn”, feeding seal into cap using light pressure with thumb and finger. 12. Install bearing cap to case with sealant applied to the cap-to-case interface, being careful to keep sealant off the seal split line (fig. 14L). Fig. 11L—Removing Oil Seal (Lower Half) Typical 13. Install the rear main bearing cap (with new seal) and torque to specifications. Torsional Damper Removal 1. Drain radiator and disconnect radiator hoses at radiator. 2. Remove radiator core, as outlined in Section 13. 3. Remove fan belt and (if so equipped) accessory drive pulley and belt. If so equipped, remove retaining bolt. 4. Install Tool J-23523 to damper and turn puller screw to remove damper (fig. 15L). Remove tool from damper. Installation CAUTIO N: The inertia weight section of the torsional damper is assembled to the hub with a rubber type material. The installation proce­ dures (with proper tool) must be followed or movement of the inertial weight section on the hub will destroy the tuning of the torsional damper. 1. Coat front seal contact area (on damper) with engine oil. 2. Install torsional damper as follows: DRIVE ON TYPE (Without retaining bolt) a. Attach damper installer Tool J-22197 to damper. Tighten fingers of tool to prevent inertia weight from moving (fig. 16L). b. Position damper on crankshaft and drive into position, using J-5590, until it bottoms against crankshaft gear (fig. 16L). Remove installer tool. PULL ON TYPE (With retaining bolt) a. Install 7/16 threaded end of Tool J-23523 into crankshaft. Fig. 12L—Removing Oil Seal (Upper Half) Typical LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-31 Fig. 15L—Removing Torsional Damper Fig. 13L—Crankshaft Oil Seal (Rear Main) CAUTION: Install tool in crankshaft so that at least 1/2" of thread engagement is obtained. 3. 4. 5. 6. 7. b. Position damper on crankshaft, aligning damper with key on crankshaft. c. Install plate, thrust bearing and nut to complete tool installation. d. Pull damper into position as shown in Figure 11L. e. Remove tool from crankshaft. Install fan belt and adjust, using strand tension gauge. If so equipped, install accessory drive pulley and belt. Install radiator core as outlined in Section 13. Connect radiator hoses. Fill cooling system and check for leaks. APPLY SEALANT TO SHADED AREAS ONLY Fig. 14L—Sealing Bearing Cap Fig. 16L—Installing Torsional Damper (Drive on Type) Crankcase Front Cover Removal 1. Remove torsional damper as outlined. 2. Remove the two, oil pan-to-front cover attaching screws. 3. Remove the front cover-to-block attaching screws. 4. Pull the cover slightly forward only enough to permit cutting of oil pan front seal. 5. Using a sharp knife or other suitable cutting tool, cut oil pan front seal flush with cylinder block at both sides of cover (fig. 18L). 6 . Remove front cover and attached portion of oil pan front seal. Remove front cover gasket. Installation 1. Clean gasket surfaces on block and crankcase front cover. LIGHT DUTY TRUCK SERVICE MANUAL 6 -3 2 ENGINE Fig. 18L—Cutting Tabs on Oil Pan Front Seal Fig. 17L—installing Torsional Damper (Pull on Type) 2. Cut tabs from the new oil pan front seal (fig. 19L) use a sharp instrument to ensure a clean cut. 3. Install seal to front cover, pressing tips into holes provided in cover. 4. Coat the gasket with gasket sealer and place in position on cover. 5. Apply a 1/8 inch bead of silicone rubber sealer part #1051435 (or equivalent) to the joint formed at the oil pan and cylinder block (fig. 20L). 6 . Install centering tool J-23042 in crankcase front cover seal (fig. 21 L). NOTE: It is important that centering tool be used to align crankcase front cover so that torsional damper installation will not damage seal and so that seal is positioned evenly around balancer. 7. Install crankcase front cover to block. Install and paratially tighten the two, oil pan-to-front cover screws. 8 Install the front cover-to-block attaching screws. 9. Remove centering Tool J-23042 and torque all cover attaching screws to specifications. 10. Install torsional damper as outlined. Fig. 20L—Applying Front Cover Sealer Oil Seal (Front Cover) Replacement With Cover Removed 1. With cover removed, pry seal out of cover from the front with a large screw driver being careful not to distort cover. . CUT THIS PORTION FROM NEW SEAL Fig. 19L—Oil Pan Front Seal Modification Fig. 21L—Centering Tool (J-23042) In Cover LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E 2. Install new seal so that open end of the seal is toward the inside of cover, and drive it into position with Tool J-23042 (fig. 22L). Camshaft Measuring Lobe Lift CAU TIO N: Support cover at sealing area. (Tool J-971 may be used as support). Without Cover Removed 1. With crankshaft pulley and hub or damper removed, pry old seal out of cover from the front with a large screw driver, being careful not to damage the seal surface on the crankshaft. 2. Install new seal so that open end of seal is toward the inside of cover and drive it into position with Tool J-23042 (fig. 23L). 6-33 1. 2. 3. 4. NOTE: Procedure is similar to that used for checking valve timing. If improper valve operation is indicated, measure the lift of each push rod in consecutive order and record the readings. Remove valve mechanism as outlined. Position indicator with ball socket adapter (Tool J-8520) on push rod (fig. 24L). Rotate the crankshaft slowly in the direction of rotation until the lifter is on the heel of the cam lobe. At this point, the push rod will be in its lowest position. Set dial indicator on zero, then rotate the Fig. 22L— -Installing Oil Seal (Cover Removed) Fig. 24L—Measuring Camshaft Lobe Lift Fig. 23L—installing Oil Seal (Cover Installed) (Typical) Fig. 25L—Timing Gear Alignment Marks LIGHT DUTY TRUCK SERVICE MANUAL 6 -3 4 ENGINE crankshaft slowly, or attach an auxiliary starter switch and “bump” the engine over, until the push rod is in the fully raised position. CAUTIO N: Whenever the engine is cranked remotely at the starter, with a special jumper cable or other means, the distributor primary lead must be disconnected from the negative post on the coil. 5. Compare the total lift recorded from the dial indicator with specifications. 6 . Continue to rotate the crankshaft until the indicator reads zero. This will be a check on the accuracy of the original indicator reading. 7. If camshaft readings for all lobes are within specifications, remove dial indicator assembly. 8 . Install and adjust valve mechanism as outlined. Removal 1. 2. 3. 4. 5. Remove valve lifters as outlined. Remove crankcase front cover as outlined. Remove grille as outlined in Section 13. Remove fuel pump as outlined in Section 6 M. Align timing gear marks then remove the two camshaft thrust plates screws by working through holes in the camshaft gear (fig. 25L). 6 . Remove the camshaft and gear assembly by pulling it out through the front of the block. NOTE: Support camshaft carefully when removing so as not to damage camshaft bearings. Fig. 26L—Checking Camshaft Gear Runout Fig. 27L—Checking Timing Gear Backlash Installation 1. Install the camshaft and gear assembly in the engine block, being careful not to damage camshaft bearings or camshaft. 2. Turn crankshaft and camshaft so that the valve timing marks on the gear teeth will line up (fig. 25L). Push camshaft into position. Install camshaft thrust plate to block screws and torque to specifications. 3. Check camshaft and crankshaft gear runout with a dial indicator (fig. 26L). The camshaft gear run out should not exceed .004" and the crankshaft gear run out should not exceed .003". 4. If gear run out is excessive, the gear will have to be removed and any burrs cleaned from the shaft or the gear will have to be replaced. 5. Check the backlash between the timing gear teeth with a dial indicator (fig. 27L). The backlash should be not less than .004" nor more than .006". 6 . Install fuel pump as outlined in Section 6 M. 7. Install grille as outlined in Section 13. Fig. 28L—Removing Crankshaft Gear LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-35 Fig. 29L—Installing Crankshaft Gear 8. Install crankcase front cover as outlined. 9. Install valve lifters as outlined. Timing Gears Replacement With camshaft removed, crankshaft gear may be removed using Tool J-8105 (fig. 28L). To install crankshaft gear use Tool J-5590 (fig. 29L). For camshaft gear replacement, refer to “Camshaft Disassembly” in the Overhaul Manual. Flywheel Removal (All Except 2 9 2 cu. in. Engines) 1. Remove transmission and/or clutch housing and clutch from engine. 2. Remove flywheel retaining bolts and remove flywheel. (2 9 2 cu. in. Engines) 1. Remove transmission and/or clutch housing and clutch from engine. 2. Mark relationship of flywheel and crankshaft so that dowel holes can be aligned in their original positions on assembly. CONVERTER BOLT AREA - J | DEPRESSED GEAR WELDS TRANS.^ SYNCHROMESH AUTOMATIC Fig. 30L—Flywheel Installation (Typical) Fig. 31L—Reaming Flywheel Dowel Pin Holes 3. Remove engine oil pan and rear main bearing cap. 4. Remove flywheel retaining bolts and drive crank­ shaft dowels out of flywheel and crankshaft. Rotate crankshaft as necessary so dowels clear cylinder block. 5. Remove flywheel and discard used dowel pins. Installation (All Except 2 9 2 cu. in. Engines) 1. Clean the mating surfaces of flywheel and crankshaft to make certain there are no burrs. 2. Install flywheel on crankshaft and position to align dowel hole of crankshaft flange and flywheel (fig. 30L). 3. Install flywheel retaining bolts and torque to specifications. (292 cu. in. Engine) 1. Clean the mating surfaces of flywheel and crankshaft to make certain there are no burrs. 2. Install flywheel on crankshaft and position to align dowel holes of crankshaft flange and flywheel. 3. Install flywheel retaining bolts and torque to specifications. NOTE: The interference fit dowel pins used on 292 cu. in. engines must be replaced with an oversize dowel pin when installing the flywheel. 4. When installing the original flywheel, ream the dowel pin holes with Tool J-22808-2. When installing a new flywheel, first ream the dowel pin LIGHT DUTY TRUCK SERVICE MANUAL 6 3 6 E N G IN E holes with Tool J-22808-2 and then finish reaming them with Tool J-22808-1 (fig. 31L). 5. Install oversize dowel pins flush with flywheel retaining bolt surface. 6. Install rear main bearing cap and torque bolts to specifications. Install oil pan with new gaskets and seals. Torque oil pan retaining screws to specifications. Engine Mounts Engine mounts (fig. 32L-38L) are the non-adjustable type and seldom require service. Broken or deteriorated mounts should be replaced immediately, because of the added strain placed on other mounts and drive line components. 3. 4. 5. 6. 7. Checking Engine Mounts Front Mount Raise the engine to remove weight from the mounts and to place a slight tension in the rubber. Observe both mounts while raising engine. If an engine mount exhibits: a. Hard rubber surface covered with heat check cracks; b. Rubber separated from a metal plate of the mount; or c. Rubber split through center. Replace the mount, if there is relative movement between a metal plate of the mount and its attaching points, lower the engine on the mounts and tighten the screws or nuts attaching the mount to the engine, frame, or bracket. Rear Mount Raise the vehicle on a hoist. Push up and pull down on the transmission tailshaft while observing the transmis­ sion mount. If the rubber separates from the metal plate of the mount or if the tailshaft moves up but not down (mount bottomed out) replace the mount. If there is relative movement betwen a metal plate of the mount and its attaching point, tighten the screws or nuts attaching the mount to the transmission or crossmember. Front Mount Replacement C, K and P Series 1. 2. 3. 4. 5. Remove frame bracket to mount bolt. Raise engine enough to clear mount. Remove mount and install new mount. Install new mount and torque bolts to specifications. Lower engine then install frame bracket to mount bolt and torque to specifications. G Series 1. Raise vehicle on hoist. 2. On manual transmission equipped vehicles. 8. a. Disconnect clutch rod at outboard lever on clutch cross shaft. b. Remove the two bolts securing clutch cross shaft bracket to frame side rail, and position clutch linkage away from engine mount. Remove mount-to-bracket through-bolt. Raise engine sufficiently to clear mount. Remove bolts securing mount to frame bracket. Install new mount to frame bracket, and torque bolts to specifications. Lower engine to align mount with engine bracket. Install through bolt and torque to specifications. On manual transmission equipped vehicles. a. Position clutch cross shaft between frame side rail and ball stud on engine bracket. Install and torque frame bolts. b. Connect clutch rod at outboard lever on clutch cross shaft. Lower vehicle on hoist and check operation of clutch. Rear Mount Replacement C, K and P Series 1. Raise and support vehicle. 2. Bend mount bolt french lock tabs away from bolt head, then remove mount bolts, lower mount and spacer. 3. Raise engine enough to clear upper mount assembly and remove upper mount from frame member. NOTE: On models using a propeller shaft brake of any type, it is necessary to remove screws from transmission hole cover to allow the engine to raise because of the limited clearance between the brake and transmis­ sion hole cover. 4. Place new upper mount in place on frame member, then lower engine to within 1 /4 inch of mount. 5. Align mount so that guide dowel enters hole in mount, install bolt through french lock, lower mount and spacer, then install bolt up through frame, upper mount and thread into engine bell housing loosely. 6. Lower engine completely and tighten mount bolt, then bend tabs of french lock to lock the bolt in place. G Series 1. Raise vehicle on hoist and support transmission so as not to interfere with support crossmember removal. 2. Remove bolts securing rear mount to support crossmember. 3. Remove support crossmember retaining bolts from LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E underbody cross rail and withdraw support from vehicle. 4. Remove bolts securing mount to transmission extension. 5. Install new rear mount and torque bolts to specifications. 6-37 6. Position support crossmember to cross rail, install bolts then loosely install crossmember-to-mount retaining bolts. 7. Remove support from rear of transmission, torque remaining bolts to specifications and lower vehicle on hoist. LIGHT DUTY TRUCK SERVICE MANUAL 6 3 8 E N G IN E 250 CU. IN. ENGINE 4 i LEFT & RIGHT MOUNT & FRAME BRACKET 292 CU. IN. ENGINE LEFT MOUNT & FRAME BRACKEET 0 ENGINE BRACKET ALL P SERIES WITH L-6 ENGINE 292 CU. IN. ENGINE RIGHT FRAME BRACKET & MOUNT Fig. 33L—P Series Engine Front Mount LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-39 LIGHT DUTY TRUCK SERVICE MANUAL 6 - 4 0 E N G IN E LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-41 LIGHT DUTY TRUCK SERVICE MANUAL 6-42 ENG INE LIGHT DUTY TRUCK SERVICE MANUAL Fig. 37L—K Series Engine Front Mount E N G IN E 6-43 REAR MOUNT FRONT MOUNT Fig. 38L—G Series Engine Mounts LIGHT DUTY TRUCK SERVICE MANUAL ENGINE 6-44 ENGINE MECHANICAL V-8 ENGINES INDEX General Description........................................................... Component Replacement and Adjustment................. Engine Assembly................................................................ Removal.............................................................................. Installation......................................................................... Intake M anifold................................................................. Removal.............................................................................. Installation......................................................................... Exhaust Manifold............................................................... Removal.............................................................................. Installation......................................................................... Rocker Arm Cover........................................................... Removal............................................................ ................. Installation......................................................................... Valve Mechanism.............................................................. Removal.............................................................................. Installation and Adjustment........................................ Valve Lifters....................................................................... Locating Noisy Lifters................................................. Removal.............................................................................. Installation......................................................................... Valve Stem Oil Seal and/or Valve Spring.............. Replacement...................................................................... Cylinder Head Assembly................................................ Removal.............................................................................. Installation......................................................................... Oil P an ................................................................................. 6-44 6-44 6-44 6-44 6-47 6-49 6-49 6-50 6-50 6-50 6-50 6-50 6-50 6-51 6-51 6-51 6-51 6-51 6-51 6-52 6-52 6-52 6-52 6-52 6-52 6-53 6-53 Removal.............................................................................. Installation......................................................................... Oil Pump.............................................................................. Removal.............................................................................. Installation......................................................................... Oil Seal (Rear M ain)...................................................... Replacement...................................................................... Torsional Damper............................................................. Removal.............................................................................. Installation......................................................................... Crankcase Front Cover................................................... Removal.............................................................................. Installation......................................................................... Oil Seal (Front Cover).................................................... Replacement...................................................................... Timing Chain and/or Sprockets.................................. Replacement...................................................................... Camshaft.............................................................................. Measuring Lobe L ift..................................................... Removal.............................................................................. Installation......................................................................... Flywheel................................................................................ Removal.............................................................................. Installation......................................................................... Engine M ounts................................................................... Checking Engine Mounts.............................................. Replacement (Front)...................................................... Replacement (Rear)........................................................ 6-53 6-53 6-54 6-54 6-54 6-54 6-54 6-55 6-55 6-55 6-55 6-55 6-56 6-57 6-57 6-57 6-57 6-58 6-58 6-59 6-59 6-60 6-60 6-60 6-60 6-60 6-60 6-61 GENERAL DESCRIPTION The V8 engines covered in this section are the 307, 350, and 454 cu. in. engines used in 10-30 Series truck vehicles. In order to avoid repetition and to identify the engines involved in a particular procedure, the 307 and 350 cu. in. V8 engines are identified as “Small V8’s” . The 454 cu. in. engine is identified as “Mark IV V8” . This section covers the removal and installation of engine assemblies; the removal, installation and adjustment of some sub-assemblies and replacement of some components. For service to all components and sub-assemblies (after removal) and removal of some sub-assemblies, refer to Section 6 of the Overhaul Manual. Because of the interchangeability and similarity of many engines, engine sub-assemblies and parts regardless of which truck vehicle they are used in, typical illustrations and procedures are used (except where specific illustrations or procedures are necessary to clarify the operation). Although illustrations showing bench opera­ tions are used, most single operations, when not part of a general overhaul, should be performed (if practical) with the engine in the vehicle. C O M P O N E N T REPLACEMENT A N D ADJUSTMENT Engine Assembly 3. Perform the following preliminary operations: Removal • Remove the hood as outlined in Section 11. C, K and P Series • Remove the radiator and shroud as outlined in 1. Disconnect battery cables and drain cooling system. Section 13. 2. Remove the air cleaner. LIGHT DUTY TRUCK SERVICE MANUAL ENGIN E 4. Disconnect wires at: • TCS Solenoid • Starter Solenoid • Delcotron • Temperature Switch • Oil Pressure Switch • Coil 5. Disconnect: • Accelerator linkage at manifold bellcrank • Fuel line (from tank) at fuel pump. • Heater hoses at engine connection. • Oil pressure gauge line (if so equipped). • Vacuum or air lines at engine (as required). • Power steering pump with hoses attached and lay aside (if so equipped). • Ground straps at engine. • Exhaust pipe at manifold. • TCS switch at transmission. NOTE: Hang exhaust pipe at frame with wire. 6. 7. 8. 9. Remove fan and pulley as outlined in Section 6K. Remove clutch cross-shaft. Perform the following operations: Attach lifting device to engine lift brackets ana take weight off engine mounts. ON ALL SERIES EXCEPT CE 10-20-30: • Support transmission and disconnect from engine. • Disconnect speedometer cable at transmission. • Disconnect shift linkage at transmission. • Disconnect clutch linkage (as required). • Remove engine mount bolts. 10. Remove engine from vehicle as follows: CAUTION: Check often during engine removal to be sure all necessary disconnects have been made. ON CE 10-20-30 SERIES: 6-45 • On vehicles with automatic or four speed transmissions, remove rear mount crossmember. • Raise engine and transmission assembly and pul! forward until removed. ON KE 10-20 SERIES: • Raise engine and pull forward until disconnected from tranmission. • Continue to raise engine until removed from vehicle. 11. If engine is to be mounted in an engine stand perform the following: ON CE 10-20-30 SERIES: • Remove synchromesh tranmission and clutch (if so equipped). a. Remove clutch housing rear cover bolts. b. Remove bolts attaching the clutch housing to engine block then remove transmission and clutch housing as a unit. NOTE: Support the transmission as the last mounting bolt is removed and as it is being pulled away from the engine, to prevent damage to clutch disc. c. Remove starter and clutch housing rear cover. d. Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. • Remove automatic transmission (if so equipped). a. Lower engine, secured by the hoist, and support engine on blocks. b. Remove starter and converter housing under pan. c. Remove flywheel-to-converter attaching bolts. d. Support transmission on blocks. e. Disconnect throttle linkage and vacuum modulator line. f. Remove tranmission-to-engine mounting bolts. g. With the hoist attached, remove blocks from the engine only and glowly guide the engine from the transmission. ON ALL SERIES EXCEPT CE 10-20-30: • Remove clutch housing. • Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. 12. Mount engine in engine stand and remove lifting device and lifting adapter. LIGHT DUTY TRUCK SERVICE MANUAL 6 - 4 6 E N G IN E G Series 1. Remove engine cover and position it out of way. 2. Disconnect battery ground cable at engine block and at battery. 3. Drain cooling system and disconnect heater hoses at engine; disconnect radiator hoses at radiator. 4. Disconnect automatic transmission cooler lines at radiator; remove radiator shroud and radiator. 5. Remove carburetor air cleaner and remove engine oil filler tube. 6 . Remove Delcotron and support bracket - position assembly out of way on left frame rail. 7. Disconnect oil pressure gauge if so equipped. 8. Disconnect engine wiring harness at dash panel junction block. 9. Disconnect accelerator linkage at dash panel mounted bell crank. Disconnect TCS system electrical leads - remove harness from clips and position it to one side. 11. Disconnect Evaporation Control System lines at rocker arm cover and at carburetor - position lines to one side. 12. Disconnect power brake vacuum hose at rocker arm tube-to-hose junction. 13. Raise vehicle on a hoist and disconnect: Fuel line (from tank) at fuel pump. Engine ground strap(s). Steering idler arm at frame. Steering pitman arm at steering gear as outlined in Section 9. Stabilizer shaft at frame brackets. Battery positive cable at starter. Shock absorbers at lower control arm. Speedometer cable at transmission. TCS switch at transmission-remove bell housing mounted clip and position wiring to one side. Transmission at crossmember. Exhaust crossover at manifolds and at muffler. 14. Remove propeller shaft as outlined in Section 4 install plug in transmission extension. 15. Disconnect clutch linkage and/or transmission linkage and remove cross shaft as outlined in Section 7. 16. Disconnect front brake pipe at equalizer tee, disconnect rear brake pipe at left frame rail mounted connector and at right frame rail mounted connector (Fig. IV). 17. Remove transmission support frame-to-crossmember attaching nuts - do not remove bolts at this time. 18. Remove the six (3 on each side) vertically driven 19. 20. 21. 22. 23. front crossmember-to-frame attaching bolts (Fig. 2V). Remove the four (2 on each side) frame-to-upper control arm (inside) attaching bolts (Fig. 3V). Lower the vehicle on hoist so that weight of vehicle is on hoist but with wheels touching floor and suspension at curb height. Install wood block between oil pan and crossmem­ ber to stabilize engine assembly (Fig. 4V). Position floor jack under vehicle so that jack pad is aligned under transmission and, using a block of wood to protect transmission, support transmission with jack (Fig. 5V). Remove transmission support crossmember. Fig. 2V—Crossmember-to-Frame Attaching Bolts LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 24. Remove the four (2 on each side) remaining suspension-to-frame (outside) retaining bolts (Fig. 3V). 25. Raise vehicle slowly, leaving suspension and power train on the floor, until sufficient clearance is obtained for removing engine. CAUTION: Check often when raising the vehicle to make sure that all disconnects have been made and that vehicle is positioned properly on hoist. 26. Roll the power train and suspension assembly to the work area and position jack stand under transmis­ sion extension (Fig. 6V)-remove floor jack. 27. Place floor jack under suspension crossmember and raise jack so that weight of assembly is supported on jack pad, (Fig. 4V). 28. Attach lifting device to support engine, remove engine mount through bolts and remove engine assembly from crossmember. 647 29. Remove synchromesh transmission and clutch (if so equipped). a. Remove clutch housing rear cover bolts. b. Remove bolts attaching the clutch housing to engine block, then remove transmission clutch housing as a unit. NOTE: Support the transmission as the last mounting bolt is removed and as it is being pulled away from the engine, to prevent damage to clutch disc. c. Remove starter and clutch housing rear cover. d. Loosen clutch mounting bolts a turn at a time (to prevent distortion of clutch cover) until the spring pressure is released. Remove all bolts, clutch disc and pressure plate assembly. 30. Remove automatic transmission (if so equipped). a. Lower engine secured by the hoist, and support engine on blocks. b. Remove starter and converter housing underpan. c. Remove flywheel-to-converter attaching bolts. d. Support transmission on blocks. e. Disconnect throttle linkage and detent cable on Turbo Hydra-Matic. f. Remove transmission-to-engine mounting bolts. g. With the hoist attached, remove blocks from the engine only and slowly guide the engine away from the transmission. Installation 1. If engine was mounted in an engine stand, attach lifting adapter to engine then using lifting device, remove engine from stand and perform the following: Fig. 4V—Stabilizing Power Train Fig. 5V—Floor Jack Location Under Transmission LIGHT DUTY TRUCK SERVICE MANUAL 6 - 4 8 E N G IN E 3. 4. 5. 6. Fig. 6V—Supporting Power Train ON CE 10-20-30: • Install synchromesh tranmission and clutch (if so equipped). a. Install the clutch assembly on flywheel as outlined in Section 7. b. Install clutch housing rear cover and starter. c. Install the tranmission and clutch housing as outlined in Section 7. d. Install clutch housing rear cover bolts and torque to specifications. • Install automatic tranmission (if so equipped). a. Position engine adjacent to the transmission and align the converter with the flywheel. b. Bolt transmission to engine then raise engine and transmission assembly and install flywheel to converter bolts. c. Install converter housing underpan and starter. d. Connect throttle linkage and vacuum modu­ lator line. ON ALL SERIES EXCEPT CE 10-20-30: • Install clutch assembly and clutch housing as outlined in Section 7. 2. Install engine in vehicle as follows: ON ALL SERIES EXCEPT CE 10-20-30: • Install engine and lower until transmission lines up with clutch. • Push engine rearward and rotate crankshaft until transmission shaft and clutch engage. • Install the engine mount bolts and torque to specifications. • Connect transmission to engine. 7. 8. 9. ON CE 10-20-30 SERIES: • Lower engine and transmission assembly and push rearward until engine mounts line up. • On vehicles with automatic or four speed transmissions, install rear mount crossmember. • Install the engine mount bolts and torque to specifications. • Install the propeller shaft as outlined in Section 4. ON ALL SERIES: • Remove the lifting device from engine lift brackets. Connect transmission linkage (as required). Install clutch cross-shaft. Install fan and pulley as outlined in Section 6K. Connect: • Exhaust pipe at manifold. • Power steering pump (as required). • Vacuum lines at engine (as required). • Oil pressure gauge line (as required). • Heater hoses at engine connection. • Fuel line at fuel pump. • Choke cable at carburetor. • Accelerator linkage at manifold bellcrank. • TCS switch at transmission. Connect wires at: • Coil • Oil Pressure Switch • Temperature Switch • Delcotron • Starter Solenoid • CEC Solenoid Complete installations as follows: • Install the radiator and shroud as outlined in Section 13. • Install the hood as outlined in Section 11. Install the air cleaner, connect battery cables, fill cooling system and crankcase then start engine and check for leaks. G Series 1. If engine was mounted in an engine stand, attach lifting adapter to engine, then, using lifting device, remove engine from stand and perform the following: • Install manual transmission and clutch (if so equipped). a. Install the clutch assembly on flywheel as outlined in Section 7. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. b. Install clutch housing rear cover and starter. c. Install the transmission and clutch housing as outlined in Section 7. d. Install clutch housing rear cover bolts and torque to specifications. • Install automatic transmission (if so equipped). a. Position engine adjacent to the transmission and align converter with the flywheel. b. Bolt transmission to engine then raise engine and transmission assembly and install flywheel to converter bolts. c. Install converter housing underpan and starter. d. Connect throttle valve linkage and vacuum modulator. Connect detent cable on Turbo Hydra-Matic. Raise engine and align mounts on engine with brackets on crossmember - install engine mount through bolts. Place wood block between oil pan and crossmember to stabilize power train. Remove floor jack from under crossmember and position jack pad under transmission assembly, using wood block at jack pad to protect transmission. Remove the engine lifting device and roll power train and suspension assembly under vehicle so that crossmember is aligned with frame. Slowly lower the vehicle, checking often to assure that engine components do not interfere with vehicle as it is being lowered, until suspension-toframe attaching bolt holes are aligned. Install and securely tighten suspension-to-frame attaching bolts. Install transmission support crossmember and remove floor jack from beneath the transmission. Remove block of wood from between oil pan and crossmember. Raise vehicle on the hoist and install the remaining suspension-to-frame attaching bolts - torque bolts to specifications. Torque transmission to-crossmember and crossmember-to- frame bolts to specifications. Install propeller shaft as outlined in Section 4. Connect rear brake pipe at right frame rail connector; connect front brake pipe at equalizer tee and connect rear brake pipe at left frame rail connector. Install cross shaft and connect clutch linkage and/ or transmission linkage as outlined in Section 7. Connect the following items: • Fuel line (from tank) at fuel pump. • Engine ground strap(s). 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 6-49 • Steering idler arm at frame. • Steering pitman arm at steering gear - torque nut to specifications. • Stabilizer shaft at frame brackets. • Battery positive cable at starter. • Shock absorbers at lower control arm. • Speedometer cable at transmission. • TCS switch at transmission - install TCS wire to clip at transmission/clutch housing. • Exhaust crossover at muffler and at manifolds. Lower vehicle on hoist. Connect power brake vacuum hose at tube-to-hose junction. Connect Evaporation Control System lines at rocker arm cover and carburetor. Connect TCS system electrical leads at valve and at temperature switch - position harness in rocker arm cover clips. Install Delcotron and support assembly. Connect accelerator linkage at dash mounted bell crank. Install carburetor air cleaner and oil filler tube connect oil pressure gauge line if so equpped. Connect engine wiring harness at dash panel junction block. Install radiator and fan shroud, connect radiator and heater hoses, install automatic transmission cooler lines and fill cooling system. Install engine cover. Connect battery ground cable at engine block and at battery. Bleed front and rear brakes as outlined in Section 5. Start engine, check and add engine coolant as required and check engine for proper operation. Intake Manifold Removal 1. Drain radiator and remove air cleaner. 2. Disconnect: • Battery cables at battery. • Radiator upper hose and heater hose at manifold. • Water pump by-pass at water pump. • Accelerator linkage at pedal lever. • Fuel line and choke cable at carburetor. • Crankcase ventilation lines (as required). • Spark advance hose and governor line (if so equipped) at distributor. LIGHT DUTY TRUCK SERVICE MANUAL 6 - 5 0 E N G IN E 3. Remove distributor cap and mark rotor position with chalk, then remove distributor. 4. Remove (as required) oil filler bracket, air cleaner bracket, air compressor and bracket, coil, accelera­ tor return spring and bracket, and accelerator bellcrank. 5. Remove manifold attaching bolts, then remove manifold and carburetor as an assembly. Discard gaskets and seals. 6. If manifold is to be replaced, transfer: • Carburetor and carburetor mounting studs. • Temperature sending unit. • Water outlet and thermostat (use new gasket). • Heater hose and water pump by-pass adapters. • EGR Valve (use new gasket). Installation 1. Clean gasket and seal surfaces on manifold, block, and cylinder heads. 2. Install manifold seals on block and gaskets on cylinder heads (fig. 7V). Use sealer at water passages and where seals butt to gaskets. 3. Install manifold and torque bolts to specifications in the sequence outlined on the torque sequence chart. 4. Install (if removed) oil filler bracket, air cleaner bracket, air compressor and bracket, coil, accelera­ tor return spring and bracket and accelerator bellcrank. 5. Install distributor, positioning rotor at chalk mark, then install distributor cap. 6. Connect: REAR SEAL GASKETS • Spark advance hose and governor line (if so equipped) at distributor. • Crankcase ventilation lines (as required). • Fuel line and choke cable at carburetor. • Accelerator linkage at pedal lever. • Water pump by-pass at water pump (use new gasket). • Battery cables at battery. 7. Adjust choke cable and accelerator linkage as outlined. 8. Install air cleaner. 9. Fill with coolant, start engine, adjust ignition timing and carburetor idle speed and check for leaks. Exhaust Manifold Removal 1. On vehicles so equipped, remove carburetor heater. 2. On right exhaust manifold, disconnect and remove Delcotron. 3. On “Mark IV V8” engines, remove spark plugs. 4. Disconnect exhaust pipe from manifold and hang exhaust pipe from frame with wire. 5. Remove end bolts then remove center bolts and remove manifold. Installation 1. Clean mating surfaces on manifold and head, then install manifold in position and install bolts (fingertight). 2. Torque manifold bolts to specifications in the sequence shown on torque chart at end of section. 3. Connect exhaust pipe to manifold. Use new gasket or packing. 4. On “Mark IV V8” engines, install spark plugs. Torque plugs to specifications. 5. On right exhaust manifold, install and connect Delcotron. Adjust belt as outlined in Engine Tune Up. 6. On vehicles so equipped, install carburetor heater. 7. Start engine and check for leaks. Rocker Arm Cover Removal FRONT SEAL Fig. 7V—Intake Manifold Gasket and Seal Location 1. Remove air cleaner. 2. Disconnect crankcase ventilation hoses at rocker arm covers. 3. Disconnect temperature wire from left rocker arm clips. 4. On vehicles so equipped, remove carburetor heater from right exhaust manifold. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 5. Remove rocker arm cover. CAUTION: Do not pry rocker arm cover loose. Gaskets adhering to cylinder head and rocker arm cover may be sheared by bumping end of rocker arm cover rearward with palm o f hand or a rubber mallet. Installation 1. Clean gasket surfaces on cylinder head and rocker arm cover with degreaser then, using a new gasket, install rocker arm cover and torque to specifications. 2. Install carburetor heater (if removed). 3. Connect temperature wire at clips on left rocker arm cover. 4. Connect crankcase ventilation hoses (as required). 5. Install air cleaner, start engine and check for leaks. Valve Mechanism Removal 1. Remove rocker arm covers as outlined. 2. Remove rocker arm nuts, rocker arm balls, rocker arms and push rods. NOTE: Place rocker arms, rocker arm balls and push rods in a rack so they may be reinstalled in the same locations. Installation and Adjustment NOTE: Whenever new rocker arms and/or rocker arm balls are being installed, coat bearing surfaces of rocker arms and rocker arm balls with “Molykote” or its equivalent. 1. Install push rods. Be sure push rods seat in lifter socket. 2. Install rocker arms, rocker arm balls and rocker arm nuts. Tighten rocker arm nuts until all lash is eliminated. 3. Adjust valves when lifter is on base circle of camshaft lobe as follows: a. Crank engine until mark on torsional damper lines up with center or “O ” mark on the timing tab fastened to the crankcase front cover and the engine is in the number 1 firing position. This may be determined by placing fingers on the number 1 valve as the mark on the damper comes near the “O ” mark on the crankcase front cover. If the valves are not moving, the engine is in the number 1 firing position. If the valves move as the mark comes up to the timing tab, the engine is in number 6 firing position and should be turned over one more time to reach the number 1 position. b. With the engine in the number 1 firing position as determined above, the following valves may be adjusted. 6-51 Exhaust — 1, 3, 4, 8 Intake — 1, 2, 5, 7 c. Back out adjusting nut until lash is felt at the push rod then turn in adjusting nut until all lash is removed. This can be determined by checking push rod side play while turning adjusting nut (fig. 8V). When play has been removed, turn adjusting nut in one full additional turn (to center lifter plunger). d. Crank the engine one revolution until the pointer “O” mark and torsional damper mark are again in alignment. This is number 6 firing position. With the engine in this position the following valves may be adjusted. Exhaust — 2, 5, 6, 7 Intake — 3, 4, 6, 8 4. Install rocker arm covers as outlined. 5. Adjust carburetor idle speed. Valve Lifters Hydraulic valve lifters very seldom require attention. The lifters are extremely simple in design, readjustments are not necessary, and servicing of the lifters requires only that care and cleanliness be exercised in the handling of parts. Locating Noisy Lifters Locate a noisy valve lifter by using a piece of garden hose approximately four feet in length. Place one end of the hose near the end of each intake and exhaust valve with the other end of the hose to the ear. In this manner, the sound is localized making it easy to determine which lifter is at fault. Another method is to place a finger on the face of the valve spring retainer. If the lifter is not functioning properly, a distinct shock will be felt when the valve returns to its seat. The general types of valve lifter noise are as follows: 1. Hard Rapping Noise—Usually caused by the plunger becoming tight in the bore of the lifter body to such an extent that the return spring can no longer push the plunger back up to working position. Probable causes are: a. Excessive varnish or carbon deposit causing abnormal stickiness. b. Galling or “pick-up” between plunger and bore of lifter body, usually caused by an abrasive piece of dirt or metal wedging between plunger and lifter body. 2. Moderate Rapping Noise—Probable causes are: a. Excessively high leakdown rate. b. Leaky check valve seat. c. Improper adjustment. 3. General Noise Throughout the Valve Train—This LIGHT DUTY TRUCK SERVICE MANUAL 6 - 5 2 E N G IN E will, in most cases, be caused by either insufficient oil supply or improper adjustment. 4. Intermittent Clicking—Probable causes are: a. A microscopic piece of dirt momentarily caught between ball seat and check valve ball. b. In rare cases, the ball itself may be out-of-round or have a flat spot. c. Improper adjustment. In most cases where noise exists in one or more lifters all lifter units should be removed, disassembled, cleaned in a solvent, reassembled, and reinstalled in the engine. If dirt, corrosion, carbon, etc. is shown to exist in one unit, it more likely exists in all the units, thus it would only be a matter of time before all lifters caused trouble. Removal 1. Remove intake manifold as outlined. 2. Remove valve mechanism as outlined. 3. Remove valve lifters. NOTE: Place valve lifters in a rack so that they may be reinstalled in the same location. Installation 1. Install valve lifters. NOTE: Whenever new valve lifters are being installed, coat foot of valve lifters with “Molykote” or its equivalent. 2. Install intake manifold as outlined. 3. Install and adjust valve mechanism as outlined. Valve Stem Oil Seal and/or Valve Spring Replacement 1. Remove rocker arm cover as outlined. 2. Remove spark plug, rocker arm and push rod on the cylinder(s) to be serviced. 3. Install air line adapter Tool J-23590 to spark plug port and apply compressed air to hold the valves in place. 4. Using Tool J-5892 to compress the valve spring, remove the valve locks, valve cap and valve spring and damper (fig. 9V). 5. Remove the valve stem oil seal. 6. Assemble as follows: SMALL V8 ENGINES a. Set the valve spring and damper, valve shield and valve cap in place. Compress the spring with Tool J-5892 and install oil seal in the lower groove of the stem, making sure the seal is flat and not twisted. NOTE: A light coat of oil on the seal will help prevent twisting. Fig. 8V—Valve Adjustment b. Install the valve locks and release the compres­ sor tool making sure the locks seat properly in the upper groove of the valve stem. NOTE: Grease may be used to hold the locks in place while releasing the compressor tool. MARK IV V8 ENGINES a. Install new valve stem oil seal (coated with oil) in position over valve guide. NOTE: Seal installation instructions are supplied with each service kit. Install seal following procedures outlined on the supplied instruction sheet. b. Set the valve spring and damper and valve cap in place. c. Compress the spring with Tool J-5892 and install the valve locks then release the compressor tool, making sure the locks seat properly in the groove of the valve stem. NOTE: Grease may be used to hold the locks in place while releasing the compressor tool. 7. Install spark plug and torque to specifications. 8. Install and adjust valve mechanism as outlined. Cylinder Head Assembly Removal 1. 2. 3. 4. Remove intake manifold as outlined. Remove exhaust manifolds as outlined. Remove valve mechanism as outlined. Drain cylinder block of coolant. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-53 J -2 3 5 9 0 FRONT SEAL Fig. 9V—Compressing Valve Spring 5. Remove cylinder head bolts, cylinder head and gasket. Place cylinder head on two blocks of wood to prevent damage. Installation CAUTION: The gasket surfaces on both the head and the block must be clean of any foreign matter and free of nicks or heavy scratches. Cylinder bolt threads in the block and threads on the cylinder head bolts must be clean. (Dirt will affect bolt torque). 1. On engines using a STEEL gasket, coat both sides of a new gasket with a good sealer. Spread the sealer thin and even. One method of applying the sealer that will assure the proper coat is with the use of a paint roller. Too much sealer may hold the gasket away from the head or block. CAUTION: Use no sealer on engines using a composition STEEL ASBESTOS gasket. 2. 3. 4. 5. 6. 7. Place the gasket in position over the dowel pins with the bead up. Carefully guide the cylinder head into place over the dowel pins and gasket. Coat threads of cylinder head bolts with sealing compound and install bolts finger tight. Tighten each cylinder head bolt a little at a time in the sequence shown in the torque sequence chart until the specified torque is reached. Install exhaust manifolds as outlined. Install intake manifold as outlined. Fig. 10V—Oil Pan Gasket and Seal Location 8. Install and adjust valve mechanism as outlined. Oil Pan Removal 1. Drain engine oil. 2. Remove oil dip stick and tube. 3. On vehicles so equipped remove exhaust crossover pipe. 4. On vehicles equipped with automatic transmission remove converter housing under pan. 5. Remove starter brace and inboard bolt, -swing starter as^de. a. Remove engine front mount bolts (frame bracket-to-mount). 6. Remove oil pan and discard gaskets and seals. Installation 1. Thoroughly clean all gasket and seal surfaces on oil pan, cylinder block, crankcase front cover and rear main bearing cap. 2. Install new oil pan side gaskets on cylinder block using gasket sealer as a retainer. Install new oil pan LIGHT DUTY TRUCK SERVICE MANUAL 6 - 5 4 E N G IN E 3. 4. 5. 6. 7. 8. rear seal in rear main bearing cap groove, with ends butting side gaskets. Install new oil pan front seal in groove in crankcase front cover with ends butting side gaskets (fig. 10V). Install oil pan and torque bolts to specifications. Install starter brace and attaching bolts. Torque bolts to specifications. Install converter housing under pan (if removed). Install exhaust crossover pipe (if removed). Install oil dip stick tube and dip stick. Fill with oil, start engine and check for leaks. Oil Pump Removal 1. Remove oil pan as outlined. 2. Remove pump to rear main bearing cap bolt and remove pump and extension shaft. 1. With the oil pan and oil pump removed, remove the rear main bearing cap. 2. Remove oil seal from the bearing cap by prying from the bottom with a small screw driver (fig. 12V). 3. To remove the upper half of the seal, use a small hammer to tap a brass pin punch on one end of seal until it protrudes far enough to be removed with pliers (fig. 13V). 4. Clean all sealant and foreign material from cylinder case bearing cap and crankshaft, using a non-abrasive cleaner. 5. Inspect components for nicks, scratches, burrs and machining defects at all sealing surfaces, case assembly and crankshaft. 6. Coat seal lips and seal bead with light engine oil keep oil off seal mating ends. Installation 1. Assemble pump and extension shaft to rear main bearing cap, aligning slot on top end of extension shaft with drive tang on lower end of distributor drive shaft. 2. Install pump to rear bearing cap bolt and torque to specifications. NOTE: Installed position of oil pump screen is with bottom edge parallel to oil pan rails. 3. Install oil pan as outlined. Oil Seal (Rear Main) Replacement NOTE: Always replace the upper and lower seal as a unit. Install seal with lip facing front of engine. The rear main bearing oil seal can be replaced (both halves) without removal of the crankshaft. Extreme care should be exercised when installing this seal to protect the sealing bead located in the channel on the outside diameter of the seal. An installation tool (fig. 1IV) can be used to protect the seal bead when positioning seal as follows: Fig. 1IV—Oil Seal Installation Tool Fig. 12V—Removing Oil Seal (Lower Half) Fig. 13V—Removing Oil Seal (Upper Half) LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 7. Position tip of tool between crankshaft and seal seat in cylinder case. 8. Position seal between crankshaft and tip of tool so that seal bead contacts tip of tool. NOTE: Make sure that oil-seal lip is positioned toward front of engine (fig. 14V). 9. Roll seal around crankshaft using tool as a “shoehorn” to protect seal bead from sharp corner of seal seat surface in cylinder case. CAUTION: Installation tool must remain in position until seal is properly positioned with both ends flush with block. 10. Remove tool, being careful not to withdraw seal. 11. Install seal half in bearing cap, again using tool as a “shoehorn”, feeding seal into cap using light pressure with thumb and finger. 12. Install bearing cap to case with sealant applied to the cap-to-case interface being careful to keep sealant off the seal split line (fig. 15V). 13. Install the rear main bearing cap (with new seal) and torque to specifications. NOTE: Tool J-23523 has holes forming two patterns. A two bolt and a three bolt pattern. The holes for the two bolt pattern must be elongated for use on the Mark IV V8 engines. Installation CAUTION: The inertial weight section o f the 1. 2. 3. Torsional Damper Removal 1. Remove fan belt, fan and pulley. 2. Remove the radiator shroud assembly as outlined in Section 13. NOTE: If additional operations (such as camshaft removal) are not being performed, the radiator removal will not be necessary. 3. Remove accessory drive pulley then remove damper retaining bolt. 4. Install Tool J-23523 on damper then, turning puller screw, remove damper (fig. 16V). 6 -5 5 4. 5. 6. 7. 8. torsional damper is assembled to the hub with a rubber type material. The installation proce­ dures (with proper tool) must be followed or movement of the inertia weight section on the hub will destroy the tuning o f the torsional damper. Coat front cover seal contact area (on damper) with engine oil. Place damper in position over key on crankshaft. Pull damper onto crankshaft as follows: a. Install appropriate threaded end of Tool J-23523 into crankshaft. CAUTION: Install tool in crankshaft so that at least 1/2" o f thread engagement is obtained. b. Install plate, thrust bearing and nut to complete tool installation. c. Pull damper into position as shown in Figure 17 V. d. Remove tool from crankshaft then install damper retaining bolt and torque to specifications. Install accessory drive pulley. Install radiator shroud as outlined in Section 13. Install fan and pulley to water pump hub and tighten securely. Install fan belt and adjust to specifications using strand tension gauge. Fill cooling system, start engine and check for leaks. Crankcase Front Cover Removal DUST SEAL Small V8 Engine OIL SEAL 1. 2. 3. 4. Remove oil pan as outlined. Remove torsional damper as outlined. Remove water pump as outlined in Section 6K. Remove crankcase front cover attaching screws and remove front cover and gasket, then discard gasket. M ark IV V8 Engine Fig. 14V—Crankshaft Oil Seal (Rear Main) 1. Remove torsional damper and water pump as outlined. 2. Remove the two, oil pan-to-front cover attaching screws. 3. Remove the front cover-to-block attaching screws. LIGHT DUTY TRUCK SERVICE MANUAL 6 - 5 6 E N G IN E APPLY SEALANT TO SHADED AREAS ONLY Fig. 15V—Sealing Bearing Cap Fig. 16V—Removing Torsional Damper Fig. 17V—Installing Torsional Damper 4. Puil the cover slightly forward only enough to permit cutting of oil pan front seal. 5. Using a sharp knife or other suitable cutting tool, cut oil pan front seal flush with cylinder block at both sides of cover (fig. 18V). 6. Remove front cover and attaching portion of oil pan front seal. Remove front cover gasket. Installation Small V8 Engine 1. Make certain that cover mounting face and cylinder block front end face are clean and flat. 2. Coat the oil seal with engine oil and using a new cover gasket, coated with gasket sealer install cover and gasket over dowel pins and cylinder block. 3. Install cover screws and torque to specifications. 4. Install water pump as outlined in Section 6K. 5. Install torsional damper as outlined. 6. Install oil pan as outlined. Fig. 18V—Cutting Tabs on Oil Pan Front Seal Mark IV V8 Engine 1. Clean gasket surface on block and crankcase front cover. 2. Cut tabs from the new oil pan front seal (fig. 19V), use a sharp instrument to ensure a clean cut. 3. Install seal to front cover, pressing tips into holes provided in cover. 4. Coat the gasket with gasket sealer and place in position on cover. 5. Apply a 1/8 inch bead of silicone rubber sealer, part 1051435 (or equivalent) to the joint formed at the oil pan and cylinder block (fig. 20V). 6. Position crankcase front cover over crankshaft. 7. Press cover downward against oil pan until cover is aligned and installed over dowel pins on block. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-57 Fig. 19V—Oil Pan Front Seal Modification 8. Install and partially tighten the two, oil pan-to-front cover attaching screws. 9. Install the front cover-to-block attaching screws. 10. Torque all screws to specifications. 11. Install torsional damper and water pump as outlined. Oil Seal (Front Cover) Replacement With Cover Removed 1. With cover removed, pry oil seal out of cover from the front with a large screw driver. 2. Install new seal so that open end of the seal is toward the inside of cover and drive it into position with Tool J-23042 on Small V8 engines or Tool J-22102 on Mark IV V8 engines (fig. 21V). CAUTION: Support cover at seal area. (Tool J-971 may be used as support). Fig. 20V—Applying Front Cover Sealer Fig. 21V—Installing Oil Seal (Cover Removed) Without Cover Removed 1. With torsional damper removed, pry seal out of cover from the front with a large screw driver, being careful not to damage the surface on the crankshaft. 2. Install new seal so that open end of seal is toward the inside of cover and drive it into position with Tool J-23042 on Small V8 engines or Tool J-22102 on Mark IV V8 engines (fig. 22V). Timing Chain and/or Sprockets Replacement 1. Remove torsional damper and crankcase front cover as outlined. 2. Crank engine until marks on camshaft and crankshaft sprockets are in alignment (fig. 23V). 3. Remove camshaft sprocket to camshaft bolts. 4. Remove camshaft sprocket and timing chain together. Sprocket is a light press fit on camshaft. If sprocket does not come off easily, a light blow on the lower edge of the sprocket (with a plastic mallet) should dislodge the sprocket. 5. If crankshaft sprocket is to be replaced on Small V8 engines remove sprocket using Tool J-5825 (fig. 24V). Install new sprocket using bolt and nut from J-23523 (fig. 25V). On Mark IV V8 engines remove sprocket using Tool J-1619 (fig. 26V). Install new sprocket using bolt and nut from Tool J-23523 (fig. 25V). 6. Install timing chain on camshaft sprocket. Hold the sprocket vertically with the chain hanging down and align marks on camshaft and crankshaft sprockets (fig. 27V). NOTE: Do not attempt to drive sprocket on camshaft as welsh plug at rear of engine can be dislodged. LIGHT DUTY TRUCK SERVICE MANUAL 6 5 8 E N G IN E J-23042 Fig. 22V—Installing Oil Seal (Cover Installed) 7. Draw camshaft sprocket onto camshaft, using the three mounting bolts. Torque to specifications. Fig. 23V—Timing Sprocket Alignment Marks 8. Lubricate timing chain with engine oil. 9. Install crankcase front cover and torsional damper as outlined. Camshaft Measuring Lobe Lift 1. 2. Fig. 2 4 V — R em o v in g C ra n k s h a ft S p ro c k e t (S m a ll V 8 ) 3. 4. 5. Fig. 25V—Installing Crankshaft Sprocket 6. NOTE: Procedure is similar to that used for checking valve timing. If improper valve operation is indicated, measure the lift of each push rod in consecutive order and record the readings. Remove the valve mechanism as outlined. Position indicator with ball socket adapter (Tool J-8520) on push rod (fig. 28V). NOTE: Make sure push rod is in the lifter socket. Rotate the crankshaft slowly in the direction of rotation until the lifter is on the heel of the cam lobe. At this point, the push rod will be in its lowest position. Set dial indicator on zero, then rotate the crankshaft slowly, or attach an auxiliary starter switch and “bump” the engine over, until the push rod is in fully raised position. CAUTION: Whenever the engine is cranked remotely at the starter, with a special jumper cable or other means, the distributor primary lead must be disconnected from the negative post on the coil. Compare the total lift recorded from the dial indicator with specifications. Continue to rotate the engine until the indicator LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-59 w asher (TORSIONAL DAMPER) Fig. 2 6 V —Removing Crankshaft Sprocket (Mark ! V V8) reads zero. This will be a check on the accuracy of the original indicator reading. 7. If camshaft readings for all lobes are within specifications, remove dial indicator assembly. 8. Install and adjust valve mechanism as outlined. Removal 1. Remove valve lifters as outlined. 2. Remove crankcase front cover as outlined. 3. Remove grille (if necessary) as outlined in Section 13. 4. Remove fuel pump push rod as outlined in Section 6M. 5. Complete camshaft removal as follows: NOTE: Sprocket is a light fit on camshaft. If sprocket does not come off easily a light blow on the lower edge of the sprocket (with a plastic mallet) should dislodge the sprocket. 6. Install two 5/16" x 18 x 4" bolts in camshaft bolt holes then remove camshaft (fig. 29V). C A U T IO N :^ // camshaft journals are the same diameter and care must be used in removing camshaft to avoid damage to bearings. Fig. 27V—Installing Timing Chain Installation NOTE: Whenever a new camshaft is installed coat camshaft lobes with “ Molykote” or its equivalent. 1. Lubricate camshaft journals with engine oil and install camshaft. 2. Install timing chain on camshaft sprocket. Hold the sprocket vertically with the chain hanging down, Fig. 28V—Measuring Camshaft Lobe Lift and align marks on camshaft and crankshaft sprockets. (Refer to fig. 23V and 27V). 3. Align dowel in camshaft with dowel hole in LIGHT DUTY TRUCK SERVICE MANUAL 6 6 0 E N G IN E Checking Engine Mounts Front Mount Raise the engine to remove weight from the mounts and to place a slight tension in the rubber. Observe both mounts while raising engine. If an engine mount exhibits: a. Hard rubber surface covered with heat check cracks; b. Rubber separated from a metal plate of the mount; or c. Rubber split through center. Replace the mount. If there is relative movement between a metal plate of the mount and its attaching points, lower the engine on the mounts and tighten the screws or nuts attaching the mount to the engine, frame, or bracket. Fig. 29V—Removing Camshaft 4. 5. 6. 7. 8. 9. camshaft sprocket then install sprocket on camshaft. Draw the camshaft sprocket onto camshaft using the mounting bolts. Torque to specifications. Lubricate timing chain with engine oil. Install fuel pump push rod as outlined in Section 6M. Install grille as outlined in Section 13. Install crankcase front cover as outlined. Install valve lifters as outlined. Flywheel Removal With transmission and/or clutch housing and clutch removed from engine, remove the flywheel. Rear Mount Raise the vehicle on a hoist. Push up and pull down on the transmission tailshaft while observing the transmis­ sion mount. If the rubber separates from the metal plate of the mount or if the tailshaft moves up but not down (mount bottomed out) replace the mount. If there is relative movement between a metal plate of the mount and its attaching point, tighten the screws or nuts attaching the mount to the transmission or crossmember. Front Mount Replacement 1. Remove distributor cap. 2. Remove mount retaining bolt from below frame mounting bracket. 3. Raise front of engine and remove mount-to-engine bolts and remove mount. CAUTION: Raise engine only enough for Installation 1. Clean the mating surfaces of flywheel and crankshaft to make certain there are no burrs. 2. Install flywheel on crankshaft and position to align dowel hole of crankshaft flange and flywheel (fig. 30V). NOTE: On Automatic Transmission equipped engines, the flywheel must be installed with the flange collar to transmis­ sion side (fig. 30V). 3. Coat thread end of bolts with sealer then install bolts and torque to specifications. CONVERTER |"^ R IN G BOLT AREA ^ GEAR DEPRESSED I WELDS ^ENGINE Engine Mounts Engine mounts (fig. 31V - 36V) are the non-adjustable type and seldom require service. Broken or deteriorated mounts should be replaced immediately, because of the added strain placed on other mounts and drive line components. SYNCHROMESH TRANS. AUTOMATIC Fig. 30V—Flywheel Installation (Typical) LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E sufficient clearance. Check for interference between rear of engine and cowl panel. 4. Replace mount to engine and lower engine into place. 5. Install retaining bolt and torque all bolts to specifications. Rear Mount Replacement 1. Support engine weight to relieve rear mounts. 2. Remove crossmember-to-mount bolts. 3. On P Series with manual transmission and propeller shaft parking brake, remove mount 4. 5. 6. 7. 8. 6-61 attaching bolts from frame outrigger and clutch housing and remove rear mounting cushions. Remove mount-to-tfansmission bolts, then remove mount. On P Series with manual transmission and propeller shaft parking brake, install new mounting cushions and bolts. Install new mount on transmission. While lowering transmission, align and start crossmember-to-mount bolts. Torque bolts to specifications then bend lock tabs to bolt head as applicable. LIGHT DUTY TRUCK SERVICE MANUAL 6 - 6 2 E N G IN E M A N U A L TR A N SM ISSIO N W ITH PROPELLER SHAFT PAR KING BRAKE ALL TURBO H Y D R A -M A T IC 4 0 0 (EXCEPT MOBILE H O M E CHASSIS) W ITH O U T PROPELLER SHAFT PARKING BRAKE ALL M A N U A L TRAN SM ISSIO N ALL TURBO H Y D R A -M A T IC 3 5 0 A U T O M A T IC TR A N SM ISSIO N ALL MOBILE H O M E CHASSIS W ITHO UT PROPELLER SHAFT PARKING BRAKE W ITH PROPELLER SHAFT PA R K IN G BRAKE Fig. 31V—P Series Engine Rear Mount LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-63 VIEW A A 3 5 0 CU. IN . / M O TO R H O M E CHASSIS 454 cu |N VIEW FWD 4 5 4 CU VIEW ALL EXCEPT M O TO R H O M E CHASSIS FWD 307 & Fig. 32V—P Series Engine Front Mount LIGHT DUTY TRUCK SERVICE MANUAL 6 - 6 4 E N G IN E LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6-65 LIGHT DUTY TRUCK SERVICE MANUAL 6 - 6 6 E N G IN E LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E 6 -6 7 Fig. 36V—C Series Engine Mounts LIGHT DUTY TRUCK SERVICE MANUAL 6-68 ENGINE DIAGNOSIS ENGINE FAILS TO START CAUSE a. Corroded or loose battery terminal connections and/or weak battery. Broken or loose ignition wires and/or faulty ignition switch. c. Excessive moisture on plugs, caps or ignition system. d. Damaged distributor rotor, cracked distributor cap and/or corroded distributor contact points. e. Fouled spark plugs and/or improper spark plug gaP- f. Weak or faulty coil. Carburetor flooded and/or fuel level in carburetor bowl not correct. h. Dirt and water in gas line or carburetor. i. Sticking choke. j- Faulty fuel pump. k. Faulty solenoid or starting motor. Park or neutral switch inoperative. ENGINE LOPES WHILE IDLING a. b. c. d. CAUSE Air leaks between intake manifold and head. Blown head gasket. Worn timing chain or sprockets. Worn camshaft lobes. e. f. g. h. Overheated engine. Plugged crankcase vent valve. Faulty fuel pump. Leaky exhaust gas recirculation valve. ENGINE MISSES WHILE IDLING CAUSE a. b. c. d. e. f. g. h. i. Spark plugs damp or gap incorrectly set. Excessive moisture on ignition wires and caps. Leaks in ignition wiring. Ignition wires making poor contact. Uneven compression. Burned, pitted or incorrectly set contact points. Faulty coil or condenser. Worn distributor cam or cracked distributor cap. Incorrect carburetor idle adjustment and/or dirty jets or plugged passages in carburetor. j. Foreign matter, such as dirt or water, in gas line or carburetor. k. Air leak at carburetor mounting gasket. 1. Choke inoperative. m. Faulty spark advance mechanism. Burned, warped, pitted, or sticking valves. Incorrect valve lifter clearance. Low compression. Leak in exhaust gas recirculation valve. ENGINE MISSES AT VARIOUS SPEEDS a. b. c. d. e. f. CAUSE Dirt and water in gas line or carburetor. Fouled carburetor jets. Incorrect ignition timing. Points dirty, pitted or incorrectly spaced. Excessive play in distributor shaft. Insufficient spring tension on points. g- Distributor cam lobe worn. h. Weak coil or condenser. i. Spark plugs dirty or damp and/or gaps set too wide. j- k. 1. m. n. o. Pq- Insufficient point dwell. Detonation or pre-ignition. Excessively worn fuel pump diaphragm. Weak valve spring. Worn camshaft lobes. Engine overheating. Sub-standard fuel. Leak in exhaust gas recirculation valve. ENGINE 6-69 ENGINE STALLS CAUSE a. Carburetor idle speed set too low and/or idle mixture too rich or too lean. b. Carburetor needle valve and seat inoperative. c. Incorrect carburetor float level and/or carburetor flooding. d. Dirt or water in gasoline or carburetor. e. Choke improperly adjusted or sticking. f. Faulty ignition system. g- Spark plugs damp or dirty and/or gaps incorrectly set. h. Faulty coil or condenser. i. Distributor points burned, pitted, dirty, or incor­ rectly set. j- Distributor advance inoperative. k. Exhaust system restricted. 1 Leaks in carburetor mounting gasket or intake manifold. m. Incorrect valve lifter clearance. n. Burned, warped, or sticking valves. Low compression. 0 P- Engine overheating. q- Loose, corroded, or leaking wiring connections (bulkhead connector, etc.) Leak in exhaust gas recirculation valve. r. . . ENGINE HAS NO POWER CAUSE a. Weak coil or condenser. b. Incorrect ignition timing. c. Excessive play in distributor shaft or distributor cam worn. d. Insufficient point dwell. e. Spark plugs dirty or gaps incorrectly set. f. Carburetor not functioning properly. g- Improper carburetor float level. h. Carburetor fuel mixture too rich or too lean. i. Foreign matter, such as dirt or water, in gas line or carburetor. J- Faulty fuel pump. k. Valve spring weak and/or valves sticking when hot. l. Valve timing incorrect. m. Incorrect valve lifter clearance. n. Worn camshaft lobes. Pistons incorrectly fitted in block. 0 P- Blown cylinder head gasket. q- Low compression. r. Flow control valve inoperative (Power Steering). s. Clutch slipping. t. Brakes dragging. u. Engine overheating. Transmission regulator valve sticking (HydraMatic). w. Sub-standard fuel. . V. EXTERNAL ENGINE OIL LEAKAGE CAUSE a. b. c. d. e. f. Improperly seated or broken fuel pump gasket. Improperly seated or broken push rod cover gasket. Improperly seated or broken oil filter gasket. Broken or improperly seated oil pan gasket. Gasket surface of oil pan bent or distorted. Improperly seated or broken timing chain cover gasket. g- Worn timing chain cover oil seal. h. Worn or improperly seated rear main bearing oil seal. Loose oil line plugs. j- Engine oil pan drain plug improperly seated. k. Rear camshaft bearing drain hole plugged. Loose rocker arm cover, gasket broken, or cover distorted or bent. LIGHT DUTY TRUCK SERVICE MANUAL 6-70 ENGINE EXCESSIVE OIL CONSUMPTION DUE TO OIL ENTERING COMBUSTION CHAMBER THROUGH HEAD AREA CAUSE a. Intake valve seals damaged or missing. b. Worn valve stems or guides. c. Plugged drain back holes in head. d. Intake manifold gasket leak in conjunction with rocker cover gasket leak. EXCESSIVE OIL CONSUMPTION DUE TO OIL ENTERING COMBUSTION CHAMBER BY PASSING PISTON RINGS CAUSE a. Oil level too high. b. Excessive main or connecting rod bearing clearance c. Piston ring° gaps not staggered. OD d. Incorrect size rings installed. e. Piston rings ° out of round, broken or scored. f. Insufficient piston ring tension due to engine overheating. g. h. i. J>k. 1., Ring grooves or oil return slots clogged. Rings sticking in ring grooves of piston, Ring grooves worn excessively in piston. ^Compression • rings • installed • ,, , upside . . .down. • , worn or scored .cylinder .. Excessively walls. ~Oil, too thin. .. NO OIL PRESSURE WHILE IDLING CAUSE a. Faulty oil gauge sending unit. b. Oil pump not functioning properly. (Regulator ball stuck in position by foreign material). c. Excessive clearance at main and connecting rod bearings. d. Loose camshaft bearings. e. Leakage at internal oil passages. NO OIL PRESSURE WHILE ACCELERATING a. Low oil level in oil pan. CAUSE b- Leakage at internal oil passages. BURNED, STICKING OR BROKEN VALVES CAUSE a. Weak valve springs. b. Improper valve lifter clearance. c. Improper valve guide clearance and/or worn valve guides. d. Out-of-round valve seats or incorrect valve seat width. e. Deposits on valve seats and/or gum formation on stems or guides. f Wart'ed valves or faul|y valve forSinSsg. Exhaust back pressure. h. Improper spark timing, LIGHT DUTY TRUCK SERVICE MANUAL ENGINE 6-71 NOISY VALVES CAUSE a. b. c. d. Incorrect valve lifter clearance. Excessively worn, dirty or faulty valve lifters. Worn valve guides. Excessive run-out of valve seat or valve face. e. f. g. h. Worn camshaft lobes. Pulled or loose rocker arm studs. Bent push rods. Broken valve spring. NOISY PISTONS AND RINGS CAUSE a. Excessive clearance between piston and bore. b. Improper fit of piston pin. c. Excessive accumulation of carbon in heads. d. Connecting rods improperly aligned. e. Excessive clearance between rings and grooves. f. Rings broken. BROKEN PISTONS AND/OR RINGS CAUSE a. b. c. d. Undersize pistons installed. Wrong type and/or size rings installed. Cylinder bores tapered or eccentric. Connecting rods improperly aligned. e. f. g. h. i. Excessively worn ring grooves. Pins improperly assembled. Insufficient ring gap clearance. Engine overheating. Fuel of too low octane rating. NOISY CONNECTING RODS a. Connecting rods improperly aligned. b. Excessive bearing clearance. c. Eccentric or out-of-round crankshaft journals. CAUSE d. Insufficient oil supply. e. Low oil pressure. f. Connecting rod bolts not tightened correctly. NOISY MAIN BEARINGS a. b. c. d. Low oil pressure and/or insufficient oil supply. Excessive bearing clearance. Excessive crankshaft end play. Eccentric or out-of-round crankshaft journals. CAUSE e. Sprung crankshaft. f. Excessive belt tension. g. Loose torsional damper. NOISY VALVE LIFTERS a. b. c. d. e. f. Broken valve springs. Worn or sticking rocker arms. Worn or bent push rods. Valve lifters incorrectly fitted to bore size. Faulty valve lifter plunger or push rod seat. Plungers excessively worn causing fast leakdown under pressure. g. Excessively worn camshaft lobes. h. Valve lifter oil feed holes plugged causing internal breakdown. i. Faulty valve lifter check ball. (Nicked, flat spot, or out of round). >■ Rocker a™ retaining nut installed upside down. k. End of push rod excessively worn or flaked. LIGHT DUTY TRUCK SERVICE MANUAL 6-72 ENGINE TORQUE SPECIFICATIONS CYLIND ER HEAD TORQUE SEQUENCE L6 S M A L L V8' ' M A R K IV V 8 ' IN TA K E MANIFOLD TORQUE SEQ UEN CE FRONT “ SMALL V 8 “ " MA RK I V V 8 ” Fig. IT —Torque Sequence LIGHT DUTY TRUCK SERVICE MANUAL ENGINE 6-73 SPECIAL TOOLS 1. 2. 11. 12. 13. J-4536 J-1264 J-8058 J-5853 J-8087 J-8001 J-23600 J-8037 J-8020 J-8021 J-8032 J-22249 J-22147 J-22250 J-6994 J-9510 J-5239 J-6305 J-8062 J-8101 J-5830 14. 15. J-7049 J-8089 J-5860 3. 4. 5. 6. 7. 8. 9. 10. Engine L if t K it (0-200 F t. Lb.) Torque Wrench (0-50 Ft. Lb.) (0-100 in lb.) In d ica to r Set (C ylin d e r Bore) In d ica to r Set (Universal) Belt Tension Gauge Piston Ring Compressor (3 -9 /1 6 ” ) Piston Ring Expander (3 -7 /8 ” ) (4 ” ) (3 -1 5 /1 6 ” ) (4 -3 /3 2 ” ) (4 -1 /4 ” ) Piston Pin Assembly Tool Piston Pin Assembly Tool (3 /8 ” ) Connecting Rod Guide Set (1 1 /3 2 ” ) Valve Spring Compressor Valve Guide Cleaner (1 1 /3 2 ” ) Valve Guide Reamer Set (3 /8 ” ) Carbon Removing Brush C ylinder Head B o lt Wrench 16. J-5715 17. 18. 19. J-6036 J-6880 J-5802 J-9534 20 J-9535 21 22 23 24. 25 26 27. 28 29. 30 J-22 144 J-8369 J-6098 J-097 1 J-23523 J-22 197 J-1619 J-5825 J-8 105 J-5590 31 J-23042 32 J-22102 (.0 0 3 ” ) Rocker A rm Stud Reamer (.0 1 3 ” ) Rocker A rm Stud Installer Rocker A rm Stud Remover D is trib u to r Low er Bushing Remover D istributor Lower Bushing Installer Oil Pick-up Screen Installer Oil Pick-up Screen Installer Cam Bearing Tool Camshaft Gear Support Torsional Damper Puller Torsional Damper Installer Crankshaft Sprocket Puller Crankshaft Sprocket Puller Crankshaft Gear Puller Crankshaft Sprocket or Gear Installer Crankcase Cover Centering Gauge and Seal Installer Crankcase Cover Seal Installer TOOLS NOT ILLUSTRATED Valve Seal Leak Detector J-23994 Fig. 2T—Special Tools LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L IN G 6K-1 SECTION 6K ENGINE COOLING INDEX General Description........................................................ Theory of Operation....................................................... Maintenance and Adjustments.................................... Coolant Level................................................................... Coolant System Checks................................................ Periodic Maintenance................................................... Cleaning.......................................................................... Reverse Flushing.......................................................... Radiator........................................................................ Cylinder Block and Cylinder H ead.................... 6K-1 6K-2 6K-7 6K-7 6K-7 6K-8 6K-8 6K-8 6K-8 6K-8 Heater Core.................................................................. Fan Belt Adjustment..................................................... Radiator C ap ................................................................... Thermostat........................................................................ Replacement................................................................... Thermostatic Fan Clutch Replacement.................. Water Pum p..................................................................... Removal.......................................................................... Installation...................................................................... Diagnosis.............................................................................. 6K-9 6K-9 6K-9 6K-9 6K-9 6K-9 6K-10 6K-10 6K-11 6K-11 GENERAL DESCRIPTION Fig. 1—Radiator Pressure Cap All trucks have pressure type engine cooling sys­ tems with thermostatic control of coolant circulation. The cooling system is sealed by a pressure type radiator filler cap. The pressure type radiator filler cap (fig. 1) is designed to operate the cooling system at higher than atmospheric pressure. The higher pressure raises the boiling point of the coolant which increases the efficiency of the radiator. The radiator filler cap contains a pressure relief valve and a vacuum relief valve. The pressure relief valve is held against its seat by a spring which when compressed, allows excessive pressure to be relieved out the radiator overflow. The vacuum valve is also held against its seat by a spring which when compressed, opens the valve relieving the vacuum created when the system cools. The cooling system’s water pump is of the centrifugal vane impeller type (figs. 2 and 3). The bearings are permanently lubricated during manufacture and are sealed to prevent the loss of lubricant or the entry of dirt and water. The pump requires no care other than to make certain the air vent at the top of the housing and Fig. 2—Water Pump—Typical L-6 the drain holes in the bottom do not become plugged with dirt or grease. Water pump components are not serviced separately; therefore, in the event of water pump failure, it will be necessary to replace the complete assembly — removal and installation procedures are covered in this section. For radiator service refer to Section 13 of this manual. Radiator fan shroud replacement is covered in Section 11 of this manual. LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 2 E N G IN E C O O L IN G Fig. 3—Water Pump—Typical V-8 THEORY OF OPERATION The engine cooling system is designed to maintain the tfngine at its most efficient operating temperature at all engine speeds and all driving conditions. During combustion of the air-fuel mixture, combustion gas temperatures may be as high as 4500 degrees. The cylinder walls, cylinder heads and pistons absorb some but not all of the heat. They, in turn, must be provided with some means of cooling to prevent permanent damage. Temperatures higher than the limit imposed by the oil properties will destroy the lubricating characteris­ tics of the oil and lead to subsequent engine failure. It is desirable to operate the engine at a temperature as close as possible to the limit imposed by the oil properties. Removing too much heat would lower the thermal efficiency; therefore, the cooling system functions to remove approximately 35 percent of the heat produced during combustion. COOLING SYSTEM CIRCULATION Six-Cylinder Engine The water pump discharges coolant into the water jacket chamber between the front face of the block and the number one cylinder (Fig. 4). Coolant then flows through the block, toward the rear, passing through two large cast openings into the cylinder head, to cool the valve seats, and forward to the water outlet at the front of the head. Some coolant is directed through a small hole in the cylinder head gasket to an area around each spark plug. During engine warm-up, when the thermostat is closed, coolant is redirected to the water pump through a coolant by-pass in the cylinder head and block. Coolant circulation, after normal operating temperatures are reached (thermostat open), flows through the coolant outlet and the pellet-type thermostat to the radiator. Eight-Cylinder Engine The water pump discharges coolant to each bank of cylinders. The coolant flow is from the front of each bank around each cylinder and toward the rear of the block. Large passages connecting the block to cylinder head directs coolant over and around the alternately spaced inlet and exhaust ports, as well as around the exposed exhaust valve guide inserts. Smaller circular holes permit metered amounts of coolant to pass from the cylinder block to cored passages surrounding the spark plugs. On “Small V8” engines during warm up (thermostat closed), coolant is redirected, through a small passage located in the front of the right cylinder head and block to a mating hole in the extreme lower portion of the water pump runner. On “Mark IV” engines during warm up (thermostat closed), coolant is redirected to the water pump by way of a recirculating passage in the intake manifold which is connected externally to the pump body. Coolant circulation after normal operating temperatures are obtained (thermostat open), is directed from the intake manifold through the coolant outlet and thermostat to the radiator. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L IN G 6 K -3 Fig. 4—Engine Coolant Circulation (Six-Cylinder) COMPONENTS Water Pump The cooling system water pump is of the centrifugal vane impeller type. The impeller turns on a steel shaft that rotates on a double row of permanently lubricated ball bearings, which are sealed during manufacture to prevent loss of lubricant and to prevent entry of dirt and water. The pump inlet is connected to the bottom of the radiator by means of a rubber hose. Pump outlet is separate from the pump and is located in the thermostat housing which is connected to the top of the radiator by a rubber hose. Radiator Radiators are designed to hold a large volume of coolant so that the coolant is also exposed to a large volume of air. The object being to transfer heat produced during combustion to the coolant and then to transfer heat in the coolant to air flowing passed the radiator. Radiators are of the cross-flow type (Fig. 5). The water flows horizontally from the input (left) tank through the individual cores to the output (right) tank. Radiators used on vehicles equipped with automatic transmission may, in some instances, have oil coolers into the right (output) tank. Inlet and outlet fittings for transmission fluid circulation are positioned vertically on the tank. Radiator Cap The pressure type radiator filler cap is designed to operate the cooling system at higher than atmospheric pressure. The higher pressure raises the boiling point of the coolant, which increases the efficiency of the radiator. The radiator filler cap contains a pressure relief valve and a vacuum relief valve. The pressure relief valve is LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 4 E N G IN E C O O L IN G WARM WATER FROM ENGINE COLD RADIATOR TRANSMISSION FILL LEVEL OIL COOLER LINES RADIATOR CODE' COOLED WATER TO ENGINE LOCATION Fig. 5—Typical Cross-Flow Radiator held against its seat by a spring, which, when compressed, allows excessive pressure to be relieved out the radiator overflow. The vacuum valve is also held against its seat by a spring which, when compressed, opens the valve to relieve the vacuum created when the system cools. Fan The cooling fan is located on the end of the water pump shaft and is driven by the same belt that drives the pump. In some instances a fan shroud surrounds the fan. This shroud increases the cooling system efficiency by ensuring that all air pulled in by the fan passes through the radiator. Basically there are two types of fans: a fixed drive fan (which rotates at water pump - engine rpm speed) and the automatic fan clutch. Automatic fan clutches, Figure 6, are hydraulic devices used to vary the speed in relation to the engine temperature. Automatic fan clutches are used with many engines, especially those equipped with factory installed air conditioning units. Automatic fan clutches permit the use of a high delivery fan to insure adequate cooling at reduced engine speeds while eliminating overcooling, excessive noise, and power loss at high speeds. The automatic fan clutch has two modes of operation, the engaged mode and the disengaged mode. The disengaged mode (engine cold or high speed driving) occurs when the silicone fluid is contained in the reservoir area of the fan clutch. As the temperature of the engine rises so does the temperature of the bimetallic coil. This bimetallic coil is connected to the arm shaft in such a way that as the temperature rises the shaft moves the arm exposing an opening in the pump plate. This opening allows the silicone fluid to flow from the reservoir into the working chamber of the automatic fan clutch. The silicone fluid is kept circulating through the fan clutch by wipers located on the pump plate. A hole is located in front of each wiper, Figure 7. The speed differential between the clutch plate and the pump plate develops high pressure areas in front of the wipers, thus the fluid is forced back into the reservoir. But as the temperature rises the arm uncovers more of the large opening and allows more of the silicone fluid to re-enter the working chamber. The automatic fan clutch becomes fully engaged when the silicone fluid, circulating between the working chamber and the reservoir, reaches a sufficient level in the working chamber to completely fill the grooves in the clutch body and clutch plate. The resistance of the silicone fluid to the shearing action caused by the speed differential between the grooves transmits torque to the clutch body. The reverse situation occurs when the temperature drops. The arm slowly closes off the return hole thus blocking the fluid flow from the reservoir into the working chamber. The continuous action of the wipers removes the silicone fluid from the grooves in the working chamber and reduces the shearing action. Thus, less torque is transmitted to the clutch body and the speed of the fan decreases. The temperature at which the automatic fan clutch engages and disengages is controlled by the setting of the bimetallic coil. This setting is tailored to satisfy the cooling requirements of each model. FAN CLUTCH DIAGNOSTIC PROCEDURE 1. NOISE Fan noise is sometimes evident under the following normal conditions: a. when clutch is engaged for maximum cooling, and b. during first few minutes after start-up until the clutch can re-distribute the silicone fluid back to its normal disengaged operating condition after overnight settling. However, fan noise or an excessive roar will generally occur continuously under all high engine speed conditions (2500 r.p.m. and up) if the clutch assembly is locked up due to an internal failure. If the fan cannot be roated by hand or there is a rough grating feel as the fan is turned, the clutch should be replaced. 2. LOOSENESS Under various temperature conditions, there is a visible lateral movement that can be observed at the tip of the fan blade. This is a normal condition due to the type of bearing used. Approximately 1/4" maximum lateral movement measured at the fan tip is allowable. This is not cause for replacement. 3. SILICONE FLUID LEAK The operation of the unit is generally not affected by small fluid leaks which may occur in the area around the bearing assembly. However, if the degree of leakage appears excessive, proceed to item 4. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L IN G - F------ / WORKING CHAMBER v A .BALL BEARING i| S _ 6 K -5 _ CLUTCH PLATE W II B 1 'W ^ ARM FLUID RESERVOIR CHAMBER PUMP PLATE BIMETALLIC COIL Fig. 6—Automatic Fan Clutch 4. CIRCULATING HOLES ENGINE OVERHEATING A. Start with a cool engine to ensure complete fan clutch disengagement. Refer to Item b, paragraph 1. WIPER Fig. 7—Fan Clutch Pump Plate B. If the fan and clutch assembly free-wheels with no drag (revolves over 5 times when spun by hand), the clutch should be replaced. If clutch performs properly with a slight drag go to step C. NOTE: Testing a fan clutch by holding the small hub with one hand and rotating the aluminum housing in a clockwise/counter­ clockwise motion will cause the clutch to free­ wheel, which is a normal condition when operated in this manner. This should not be considered a test by which replacement is determined. C. Use dial type thermometer, J6742-01, or similar type. NOTE: J6742-01 reads to 180 degrees F, therefore, allow approximately 3/16" pointer movement for each 10 degrees over 180 degrees CAUTION: Check for adequate clearance LIGHT DUTY TRUCK SERVICE MANUAL r 6 K - 6 E N G IN E C O O L IN G D. E. F. G. between fan blades and thermometer sensor before starting engine. Position thermometer so that the thermometer sensor is centered in the space between the fan blades and radiator. This can be achieved by inserting the sensor through one of the existing holes in the fan shroud or fan guard, or by placing between the radiator and the shroud. On some models, it may be necessary to drill a 3/16" hole in the fan shroud to insert J6742-01. Cover radiator grille sufficiently to induce a high engine temperature. Start engine and turn on air conditioning if equipped. Maintain a position in front of the vehicle to observe the thermometer reading. With a rod, broom handle, or etc., push on the accelerator linkage to maintain approx­ imately 3000 r.p.m. Use tachometer if available. Observe thermometer reading when clutch engages. It will take approximately 5 to 10 minutes for the temperature to become high enough to allow engagement of the fan clutch. This will be indicated by an increase or roar in fan air noise and by a drop in the thermometer reading of approximately 5-15 degrees F. If the clutch did not engage between 165-190 degrees F., the unit should be replaced. NOTE: Be sure fan clutch was disengaged at beginning of test. CAUTION: Do not continue test past a thermometer reading o f 190 degrees F to prevent engine overheating. If no sharp increase in fan noise or temperature drop was observed and the fan noise level was constantly high from start of test to 190 degrees F, the unit should be replaced. As soon as the clutch engages, remove the radiator grille cover and turn off the air conditioning to assist in engine cooling. The engine should be run at approximately 1500 r.p.m. After several minutes the fan clutch should disengage, as indicated by a reduction in fan speed and roar. Fig. 8—Sectional View of Thermostat As the engine becomes warm, the pellet expands and the thermostat valve opens, permitting the coolant to flow through the radiator where heat is passed through the radiator walls. This opening and closing of the thermostat valve permits enough coolant to enter the radiator to keep the engine within operating temperature limits. Coolant Regardless of whether freezing temperatures are or are not expected, cooling system protection should be maintained at least to -20°F. to provide adequate corrosion protection and proper temperature indicating light operation. With glycol content less than require- Thermostat A pellet-type thermostat is used in the coolant outlet passage to control the flow of engine coolant, to provide fast engine warm-up and to regulate coolant tempera­ tures. A wax pellet or powder element in the thermostat expands when heated and contracts when cooled (Fig. 8). The pellet is connected through a piston to a valve. When the pellet is heated, pressure is exerted against a rubber diaphragm which forces the valve to open. As the pellet is cooled, the contraction allows a spring to close the valve. Thus, the valve remains closed while the coolant is cold, preventing circulation of coolant through the radiator, but allowing the coolant to circulate throughout the engine to warm it quickly and evenly. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L IN G ment for -20°F. protection, coolant boiling point is less than the temperature indicating light setting. When adding solution due to loss of coolant for any reason or in areas where temperatures lower than -20°F. may occur, a sufficient amount of an ethylene glycol base coolant that meets GM Specification 1899-M should be used. Every two years the cooling system should be serviced by flushing with plain water, than completely refilled with a fresh solution of water and a high-quality, inhibited (permanent-type) glycol base coolant meeting GM Specification 1899-M and providing freezing protection at least to -20°F. At this time, also add GM Cooling 6 K -7 System Inhibitor and Sealer or equivalent. In addition, Cooling System Inhibitor and Sealer should be added every fall thereafter. GM Cooling System Inhibitor retards the formation of rust or scale and is compatible with aluminum components. NOTE: Alcohol or methanol base coolants or plain water are not recommended for engine coolant at any time. Coolant Recovery System The coolant recovery system supplements the standard cooling system in that additional coolant is available from a translucent plastic reservoir (Fig. 9). M A IN TEN A N C E A N D ADJUSTMENTS Coolant Level NOTE: On vehicles equipped with the coolant recovery system, the coolant level is checked by observing the liquid level in the reservoir. The radiator cap need not be removed. The coolant level should be at the “Cold Full” mark when cooling system cools and coolant is at ambient temperature. After the vehicle has been driven sufficiently to obtain normal operating temperature, the level should be at the “Hot Full” mark. The radiator coolant level should only be checked when the engine is cool, particularly on trucks equipped with air conditioning. If the radiator cap is removed from a hot cooling system, serious personal injury may result. The cooling system fluid level in downflow radiators should be maintained one inch below the bottom of the filler neck of the radiator when cooling system is cold. Coolant level in crossflow radiators should be main­ tained three inches below the bottom of the filler neck when the system is cold to allow for expansion of coolant when heated. (Note coolant level arrow on rear of radiator outlet tank.) It is very important that the correct fluid level be maintained, as too high a level will overflow from expansion and too low a level will reduce cooling performance. All truck cooling systems are pressurized with a 15 lb. pressure cap which permits safe engine operation at cooling temperatures of up to 256°F. with a 33% glycol solution. When the radiator cap is removed or loosened, the system pressure drops to atmospheric, and the heat which had caused water temperature to be higher than 212°F, will be dissipated by conversion of water to steam. Inasmuch as the steam may form in the engine water passages, it will blow coolant out of the radiator upper hose and top tank, necessitating coolant replacement. Engine operating temperatures higher than the normal boiling point of water are in no way objectionable so long as the coolant level is satisfactory when the engine is cool. Upon repeated coolant loss, the pressure radiator cap and seat should be checked for sealing ability. Also, the cooling system should be checked for loose hose connections, defective hoses, gasket leaks, etc. Coolant System Checks 1. Test for restriction in the radiator, by warming the engine up and then turning the engine off and feeling the radiator. The radiator should be hot at the top (along the left side on crossflow radiators) and warm at the bottom (along the right side on crossflow radiators), with an even temperature rise from bottom to top (right to left on crossflow radiators). Cold spots in the radiator indicate clogged sections. 2. Water pump operation may be checked by running the engine while squeezing the upper radiator hose. A pressure surge should be felt. Check for a plugged vent-hole in pump. NOTE: A defective head gasket may allow exhaust gases to leak into the cooling system. This is particularly damaging to the cooling system as the gases combine with the water to form acids which are harmful to both the radiator and engine. WARNING: If you siphon coolant from the radiator, do not use mouth to start siphoning action. The coolant solution is POISONOUS and can cause death or serious illness if swallowed. 3. To check for exhaust leaks into the cooling system, siphon coolant from the system until the coolant level stands just above the top of the cylinder head, then disconnect the upper radiator hose and remove the thermostat and fan belt. Start the engine and quickly accelerate several times. At the same time note any appreciable water rise or the appearance of bubbles which are indicative of exhaust gases leaking into the cooling system. LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 8 E N G IN E C O O L IN G Periodic Maintenance It is the owner’s responsibility to keep the freeze protection at a level commensurate with the area in which the vehicle will be operated. Regardless of climate, system protection should be maintained at least to -20°F., to provide adequate corrosion protection. When adding solution due to loss of coolant for any reason or in areas where temperatures lower than -20°F. may occur, a sufficient amount of an ethylene glycol base coolant that meets GM Specification 1899-M should be used. Every two years the cooling system should be serviced by flushing with plain water, then completely refilled with a fresh solution of water and high-quality inhibited (permanent-type) glycol base coolant meeting GM Specification 1899-M, and providing freezing protection at least to -20°F. At this time, also add GM Cooling System Inhibitor and Sealer or equivalent. In Addition, Cooling System Inhibitor and Sealer should be added every fall thereafter. GM Cooling System Inhibitor retards the formation of rust or scale and is compatible with aluminum components. NOTE: Alcohol or methanol base coolants or plain water are not recommended for your cooling system at any time. Two common causes of corrosion are: (1) air suction—Air may be drawn into the system due to low liquid level in the radiator, leaky water pump or loose hose connec­ tions; (2) exhaust gas leakage— Exhaust gas may be blown into the cooling system past the cylinder head gasket or through cracks in the cylinder head and block. Cleaning A good cleaning solution should be used to loosen the rust and scale before reverse flushing the cooling system. There are a number of cleaning solutions available and the manufacturer’s instructions with the particular cleaner being used should always be followed. An excellent preparation to use for this purpose is GM Cooling System Cleaner or its equivalent. The following directions for cleaning the system applies only when this type cleaner is used. WARNING: If you siphon coolant from the radiator, do not use mouth to start siphoning action. The coolant solution is POISONOUS and can cause death or serious illness if swallowed. 1. Siphon coolant from the cooling system, including the cylinder block. 2. Remove thermostat and replace thermostat housing. 3. Add the liquid portion (No. 1) of the cooling system cleaner. 4. Fill the cooling system with water to a level of about 3 inches below the top of the overflow pipe. 5. Cover the radiator and run the engine at moderate speed until engine coolant temperature reaches 180 degrees. 6. Remove cover from radiator and continue to run the engine for 20 minutes. Avoid boiling. 7. While the engine is still running, add the powder portion (No. 2) of the cooling system cleaner and continue to run the engine for 10 minutes. WARNING: BE CAREFUL NOT TO SCALD YOUR HANDS. 8. At the end of this time, stop the engine, wait a few minutes and then open the engine block drain cocks. Also, remove lower hose connection. NOTE: Dirt and bugs may be cleaned out of the radiator air passages by blowing out with air pressure from the back of the core. Do not bend radiator fins. Reverse Flushing Reverse flushing should always be accomplished after the system is thoroughly cleaned as outlined above. Flushing is accomplished through the system in a direction opposite to the normal flow. This action causes the water to get behind the corrosion deposits and force them out. Radiator 1. Remove the radiator upper and lower hoses and replace the radiator cap. 2. Attach a lead-away hose at the top of the radiator. 3. Attach a new piece of hose to the radiator outlet connection and insert the flushing gun in this hose. 4. Connect the water hose of the flushing gun to a water outlet and the air hose to an air line. 5. Turn on the water and when the radiator is full, turn on the air in short blasts, allowing the radiator to fill between blasts of air. CAUTION: Apply air gradually as a clogged radiator will stand only a limited pressure. 6. Continue this flushing until the water from the lead-away hose runs clear. Cylinder Block and Cylinder Head 1. With the thermostat removed, attach a lead-away hose to the water pump inlet and a length of new hose to the water outlet connection at the top of the engine. NOTE: Disconnect the heater hose and cap connections at engine when reverse flushing engine. 2. Insert the flushing gun in the new hose. 3. Turn on the water and when the engine water jacket is full, turn on the air in short blasts. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L IN G 4. Continue this flushing until the water from the lead-away hose runs clear. Heater Core 1. Remove water outlet hose from heater core pipe. 2. Remove inlet hose from engine connection. 3. Insert flushing gun and flush heater core. Care must be taken when applying air pressure to prevent damage to the core. Fan Belt Adjustment 1. Loosen bolts at Delcotron mounting. 2. Pull Decotron away from engine until desired tension reading is obtained with a strand tension gauge. Refer to “Engine Tune Up Specifications” . 3. Tighten all Delcotron bolts securely. Radiator Cap The radiator cap should be washed with clean water and pressure checked at regular tune-up intervals. Inspect rubber seal on cap for tears or cracks. Install radiator cap on tester (fig. 4). If the pressure cap will not hold pressure or does not release at the proper pressure, replace the cap. Thermostat The thermostat consists of a restriction valve actuated by a thermostatic element. This is mounted in the housing at the cylinder head water outlet above the water pump. Thermostats are designed to open and close at predetermined temperatures and if not operating properly should be removed and tested as follows: Replacement 6 K -9 3. Inspect thermostat valve to make sure it is in good condition. 4. Place thermostat in a 33% glycol solution 25° above the temperature stamped on the thermostat valve. 5. Submerge the valve completely and agitate the water thoroughly. Under this condition the valve should open fully. 6. Remove the thermostat and place in a 33% glycol solution 10° below temperature indicated on the valve. 7. With valve completely submerged and water agitated thoroughly, the valve should close completely. 8. If thermostat checks satisfactorily, re-install, using a new housing gasket. 9. Refill cooling system. Thermostatic Fan Clutch Replacement All mating surfaces (water pump hub and fan clutch hub) should be inspected for smooth mating surfaces and reworked as necessary to eliminate burrs or other imperfections. Except for the fan belt, components should be assembled to the engine (See Water Pump Removal and Installation Procedures). Radial run-out should be checked as follows: 1. Secure the fan blade to prevent rotation. (See Figure 12.) 2. Mount a dial indicator (.001 graduations) to the engine and place the indicator pointer on the fan blade spider. Preferably on the longest band or space on the spider. (See Figure 13.) 3. Rotate the water pump pulley in one direction and note the total amount of indicator needle 1. Remove radiator to water outlet hose. 2. Remove thermostat housing bolts and remove water outlet and gasket from thermostat housing (fig. 11). Fig. 10—Pressure Checking Radiator Cap Fig. 11—Replacing Thermostat LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 1 0 E N G IN E C O O L IN G Fig. 13 —Checking Run-Out Fig. 12—Securing Fan Blade movement. This represents the total radial run-out. Mark the point on the pulley at which the highest reading is obtained. 4. If the total indicator reading is less than .006 inch, the assembly is within specification. Install fan belt and adjust. If the total indicator run-out exceeds .006 inch, proceed to Step 5. 5. Divide the total indicator reading in half and obtain this thickness from shim stock (1/2 x 3/4) and resork per Figure 8. Place this shim pack between the water pump pulley and fan clutch hub at the bolt closest to the point marked on the pulley in Step 3. If the mark on the pulley is between two bolts so that it is difficult to determine which bolt is closest, place two shim packs; one under each bolt on either side of the mark. (See Figure 15.) B o lt Torque S equ en ce a. When one shim pack is used, first, torque the bolt over which the shim pack has been placed; second, the bolt opposite the first; and finally, the other two. Recommended torque is 25 lbs. ft. b. When two shim packs are used, each bolt must be torqued partially; then to full torque alternating between opposite bolts; then the other two bolts in the same manner. Recom­ mended torque is 25 lbs. ft. NOTE: Excessive run-out may result if the above sequence and recommended torque is not used. 6. Recheck total indicator run-out to verify that run­ out is within .006 inch. Install fan belt and adjust. Water Pump Removal WARNING: If you siphon coolant from the radiator, do not use mouth to start siphoning action. The coolant solution is POISONOUS and can cause death or serious illness if swallowed. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L I N G 1. Siphon coolant from the radiator and break loose the fan pulley bolts. 2. Disconnect heater hose, radiator lower hose and by­ pass hose (as required) at water pump. 3. Loosen Delcotron and remove fan belt then remove fan bolts, fan and pulley. CAUTION: I f a fan blade is bent or damaged in any way, no attempt should be made to repair and reuse the damaged part. A bent or damaged fan assembly should always be replaced with a new fan assembly. It is essential that fan assemblies remain in proper balance and proper balance cannot be assured once a fan assembly has been bent or damaged. A fan assembly that is not in proper balance could fail and fly apart during subsequent use creating an extremely dangerous condition. NOTE: Thermostatic fan clutches must be kept in an “in-car” position. When removed from the car the assembly should be supported so that the clutch disc remains in a 6K -1 1 vertical plane to prevent silicone fluid leakage. 4. Remove pump to cylinder block bolts and remove pump and old gasket from engine. NOTE: On in line engines, pull the pump straight out of the block first, to avoid damage to impeller. Installation 1. Install pump assembly on cylinder block then, using a new, sealer coated, pump-to-block gasket tighten bolts securely. 2. Install pump pulley and fan on pump hub and tighten bolts securely. NOTE: A guide stud (5/16"-24 x 1" bolt with the head removed) installed in one hole of the fan will aid in aligning hub, pulley and fan. Remove stud after starting the remain­ ing three bolts. 3. Connect hoses and fill cooling system. 4. Install fan belt and adjust as previously outlined. 5. Start engine and check for leaks. D IA G N O S IS If the radiator is filled too full when cold, expansion when hot will overfill the radiator and coolant will be lost through the overflow pipe. Adding unnecessary water will weaken the anti-freeze solution and raise the temperature at which freezing may occur. If the cooling system requires frequent addition of water in order to maintain the proper level in the radiator, check all units and connections in the cooling system for evidence of leakage. Inspection should be made with cooling system cold. Small leaks which may show dampness or dripping can easily escape detection when the engine is hot, due to the rapid evaporation of coolant. Tell-tale stains of grayish white or rusty color, or dye stains from anti-freeze, at joints in cooling system are almost always sure signs of small leaks even though there appears to be no damage. Air or gas entrained in the cooling system may raise the level in radiator and cause loss of coolant through the overflow pipe. Air may be drawn into the cooling system through leakage at the water pump seal. Gas may be forced into the cooling system through leakage at the cylinder head gasket even though the leakage is not sufficient to allow water to enter the combustion chamber. COOLING SYSTEM CHECKS To check for exhaust leaks into the cooling system, drain the system until the water level stands just above the top of the cylinder head, then disconnect the radiator upper hose and remove the thermostat and fan belt. Start the engine and quickly accelerate several times. At the same time note any appreciable water rise or the appearance of bubbles which are indicative of exhaust gases leaking into the cooling system. Water pump operation may be checked by running the engine while squeezing the radiator upper hose. A pressure surge should be felt. Check for a plugged vent­ hole in pump. Test for restriction in the radiator, by warming the engine up and then turning the engine off and feeling the radiator. The radiator should be hot along the left side and warm along the right side, with an even temperature rise from right to left. Cold spots in the radiator indicate clogged sections. An operational check of the thermostat can be made by hanging thermostat on a hook in a 33% glycol solution 25° above the temperature stamped on the thermostat valve. Submerge the valve completely and igitate the solution thoroughly. Under this condition the valve should open. Remove the thermostat and place in a 33% glycol solution 10° below temperature indicated on the valve. With valve completely submerged and water agitated thoroughly, the valve should close completely. Coolant Loss 1. Make sure owner is not trying to keep radiator filled to top, and is not filling while cold. The expansion and contraction of water during opera­ tion will cause level to drop below top of filler neck. LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 1 2 E N G IN E C O O L IN G Once level becomes stabilized, it will not change appreciable during operation. 2. Check for crack in block. Pull engine oil dip-stick to check for water in crankcase. 3. Remove rocker arm covers and check for cracked cylinder head. 4. Remove cylinder heads and check gaskets. While heads are off, check for cracks in heads or block. Overheating 1. Check to see that the radiator cap seats in radiator filler neck and releases at specified pressure (15 lb.). 2. Check coolant level. 3. Check temperature sending unit and/or gauge. 4. Check engine thermostat. 5. Check fan belt for excessive looseness. 6. Check for punctures in radiator, ruptured or disconnected hoses, loose pressure cap or use of low boiling point antifreeze. These conditions prevent cooling system from maintaining proper pressure. 7. Clean debris from radiator and/or condenser. 8. Check engine operation to make sure tune-up is not needed. Improper timing may cause overheating. 9. Check for driving conditions which may cause overheating. Prolonged idling, start and stop driving in long lines of traffic on hot days, climbing steep grades on hot days, etc. will occasionally cause coolant to boil. 10. Clean cooling system. 11. Remove cylinder heads and check water passages in heads and block for obstructions. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E C O O L I N G 6K -13 Fig. 16—Overheating Chart LIGHT DUTY TRUCK SERVICE MANUAL 6 K - 1 4 E N G IN E C O O L IN G Fig. 17—Coolant Loss Chart LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL 6M -1 SECTION 6M ENGINE FUEL CONTENTS OF THIS SECTION Description......................................................................... 6M-1 Theory of Operation...................................................... 6M-3 Maintenance and Adjustments................................... 6M-16 Service Operations........................................................... 6M-23 Diagnosis............................................................................ 6M-42 Special Tools..................................................................... 6M-67 DESCRIPTION This Section of the 1973 Truck Service Manual covers the above "Contents" items as they relate to carburetors and the engine fuel system. This service section also includes, carburetor removal and installation and external adjustments for all 10-30 series trucks, in addition to, maintenance procedures for choke coils, throttle linkage, accelerator and choke controls, air cleaners and fuel filters. For carburetor identification, overhaul procedures, assembly and disassembly of components, and internal carburetor adjustments, refer to Section 6M, of the Overhaul Manual, under the carburetor being serviced. In addition to carburetor adjustment specifications, also refer to Specifications at the end of the manual for carburetor application and type. Carburetors used with 10-30 Trucks are designed to meet the particular requirements of engine, transmission and vehicles. Carburetors that look alike are not always interchangeable. (Refer to carburetor part number and/ or specifications). Service procedures for the various carburetors are similar, therefore, typical illustrations and procedures are used except where specific illustra­ tions or procedures are necessary to clarify the operation. MODEL MV (lbbl.) CARBURETOR The Model MV carburetor is a single bore down-draft carburetor using a triple venturi in conjunction with a plain tube nozzle. Fuel flow through the main metering system is controlled by a main well air bleed and fixed orifice jet. The power enrichment system is used to provide good performance during moderate to heavy accelerations. The idle system on automatic transmission models incorporate a hot idle compensator to maintain smooth engine idle during periods of extreme hot engine operation. The Model MV carburetor has an automatic choke system. The vacuum diaphragm unit is mounted externally on the air horn. The choke coil is mounted on the manifold and is connected to the choke valve shaft by a rod. An integral fuel inlet filter is mounted in the fuel bowl behind the fuel inlet nut to give maximum filtration of incoming fuel. Other features of the Model MV include an aluminum throttle body, and a thick throttle body to bowl insulator gasket. The carburetor has internally balanced venting through a vent hole in the air horn, which leads from the bowl into the bore beneath the air cleaner. The carburetor model identification is stamped on a vertical portion of the float bowl adjacent to the fuel inlet nut. If replacing the float bowl, follow the instructions contained in the service package to transfer the identification. An electrically operated idle stop solenoid is used on all MV models. The solenoid mounts on the carburetor float bowl and replaces the normal carburetor idle stop screw. The curb idle speed setting is made by turning the electrically operated idle stop solenoid in the boss located on the carburetor bowl. See "Idle Stop Solenoid Adjustment". In the manual transmission models, the idle stop solenoid is used along with a Combination Emission Control (C.E.C.) valve. The C.E.C. valve, when energized through the transmission, acts as a throttle stop by increasing idle speed during high gear deceleration and helps in controlling overrun hydrocarbons. The C.E.C. valve also provides full spark vacuum advance to the distributor during high gear operation and is de­ energized in lower gears and at idle for retarded spark timing during this period. The idle mixture screw has a limiter cap installed and no adjustment will be provided on the vehicle. The mixture screw is pre-set at factory and capped and no further adjustment is required. An Exhaust Gas Recirculation system (E.G.R.) is used on all applications for 1973 to control oxides of nitrogen. The vacuum supply port necessary to operate the recirculation valve is located in the throttle body and connects through a channel to a tube which is located at the top of the air horn casting. See Idle System for port location and operation. LIGHT DUTY TRUCK SERVICE MANUAL I 6 M - 2 E N G IN E FUEL MODEL 2GV (2 bbl.) SAE 1-1/4" CARBURETOR The Rochester Model 2GV 1-1/4 (small bore 2 bbl.) carburetor includes some of the following features. 1. A plastic float is the same as is used in the Model 2GV large bore (1 1/2") 2 barrel. Along with the plastic float the float needle and seat assembly is longer which improves fuel level control in the float bowl. A float bowl dam has been added to the float bowl adjacent to the pump well area. The purpose of the float bowl dam is to prevent fuel slosh and help maintain improved fuel supply to the main metering jets under all types of vehicle operation. 2. The pump system on the Model 2GV 1-1/4" carburetor incorporates an expander spring beneath the pump plunger cup to maintain constant pump cup to pump well contact. In addition to the garter spring, a fuel inlet channel in the bottom of the pump well maintains sufficient fuel supply to the pump circuit at all times. A small aluminum inlet check ball seats in the bottom of the well so that as the pump plunger moves downward, the fuel will be forced out through the pump jets. 3. The hot idle compensator will not be used on the Model 2GV 1-1/4" carburetors. Leaner fuel mixtures and changes in idle speed have made the compensator unnecessary. 4. The fast idle cam steps have improved fast idle speed control during the warm-up period. 5. An exhaust gas recirculation system (E.G.R.) is used on all applications, to control oxides of nitrogen. The exhaust gas recirculation valve is operated by a vacuum signal taken from the carburetor. A vacuum supply tube, installed in the float bowl beneath the spark tube, connects by a channel to two timed vacuum ports located just above the throttle valve in the throttle body bore. As the throttle valve is opened beyond the idle position, the first E.G.R. port is exposed to manifold vacuum to supply a signal to the E.G.R. valve located on the intake manifold. The second port in the throttle body is located mid-way between the top of the throttle valve and the throttle body casting and is positioned higher to act as an air bleed for the lower port, thereby, modulating the amount of vacuum signal supplied by it. As the throttle valve is opened further in the part throttle range, at higher air flows, the vacuum signal decreases at the lower port. The upper port then ceases to function as an air bleed and is gradually exposed to manifold vacuum to supplement the signal at the lower port. In this way the E.G.R. valve operation is timed for precise metering of exhaust gases to the intake manifold, so that just the right amount of exhaust gases can be added to the inlet mixtures for proper control of the oxides of nitrogen. The exhaust gas recirculation system does not operate during engine idle. MODEL 2GV (2 bbl.) SAE 1-1/2 CARBURETOR The Model 2G, 2GV (large bore 1-1/2”) carburetors include the features: 1. The carburetors are calibrated to meet current engine requirements. 2. The internal float bowl vent hole located in the air horn is enlarged for improved float bowl venting and vapor handling. As there are no external vents, the carburetor is completely internally balanced. 3. Plastic main well inserts in the main fuel wells provide improved fuel metering for the main metering system. The use of the plastic main well inserts provide improved fuel control in the off-idle, transfer and part throttle ranges of operation. The plastic main well inserts surround the main fuel discharge nozzles and are removable for carburetor disassembly and cleaning purposes. 4. An exhaust gas recirculation system (E.G.R.) is used on all applications to control oxides of nitrogen emissions. The vacuum supply necessary to operate the exhaust gas recirculation valve is obtained through timed vacuum ports in the throttle body which connects through a channel to a tube which is located beneath the spark tube at the side of the float bowl. As the throttle valve is opened beyond the idle position, the first E.G.R. port is exposed to manifold vacuum, to supply a signal to the E.G.R. valve located on the engine manifold. The second port in the throttle body is located mid-way between the top of the valve and the throttle body casting and is positioned higher to act as an air bleed for the lower port, thereby, modulating the amount of vacuum signal supplied by it. As the throttle valve is opened further in the part throttle range, at higher air flows, the vacuum signal decreases at the lower port. The upper port then ceases to function as an air bleed and is gradually exposed to manifold vacuum to supplement the signal at the lower port. In this way, the E.G.R. valve operation is timed for precise metering of exhaust gases to the intake manifold, so that the right amount can be added to the inlet mixtures, for proper control of the oxides of nitrogen. The exhaust gas recirculation system does not operate during the normal curb engine idle. 5. The steps on the fast idle cam have been revised to improve engine performance during the warm-up period. 6. A pump fill trough in the pump system is located just beneath the venturi cluster gasket. The fill trough is only used on passenger car models and gives added capacity to the pump system above the pump discharge ball for improved operation of the pump system. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL MODEL 4MV (4 bbl.) QUADRAJET CARBURETOR The Model 4MV carburetor has many features including the following: 1. All models are calibrated to assist in meeting emission requirements. 2. The highest step on the fast idle cam length improves choke engine operation during the warm­ up period. 3. An exhaust gas recirculation system is used to control oxides of nitrogen emissions. Dual punched ports are located in the carburetor throttle body bore to supply a vacuum signal for operation of the exhaust gas recirculation valve. Two punched ports, one just above the throttle valve and one mid-way between the throttle valve and upper surface of the throttle body are located in the primary bore. As the primary throttle valve is opened beyond the idle position, the first vacuum port for the E.G.R. system is exposed to manifold vacuum to supply a vacuum signal to the E.G.R. valve. To control the vacuum signal at the 6M -3 lower port, the upper port bleeds air into the vacuum channel and modulates the amount of vacuum signal supplied by the lower E.G.R. port. In this manner, the E.G.R. valve can be timed for precise metering of exhaust gases to the intake manifold dependent upon location of the ports in the carburetor bore and by the degree of throttle valve opening. As the primary throttle valve is opened further in the port throttle range at higher air flows the vacuum signal decreases at the lower ports. At this time the upper port ceases to function as an air bleed and is gradually exposed to manifold vacuum to supplement the vacuum signal at the lower port and help maintain correct E.G.R. valve position. The upper and lower vacuum ports connect to a cavity in the throttle body which, in turn, through a passage supply the vacuum signal to the E.G.R. tube pressed into the front corner of the throttle body. The tube in the throttle body is connected by a hose to the E.G.R. valve located on the engine manifold. The E.G.R. valve remains closed during periods of engine idle and deceleration to prevent rough idle from excessive exhaust gas contamination in the idle air/fuel mixtures. THEORY OF OPERATION INDEX Theory of Operation...................................................... 6M-3 What is a Carburetor................................................ 6M-3 Purpose of a Carburetor........................................... 6M-3 Atomization................................................................. 6M-4 Metering....................................................................... 6M-5 Air Measurement.................................................... .6M-5 Fuel Metering.......................................................... .6M-6 Venturi Principle......................................................6M-7 Distribution...................................................................6M-7 WHAT IS A CARBURETOR A carburetor is a metering device which mixes fuel with air in the correct proportion and delivers them to the engine cylinders as a combustible mixture. The design of a carburetor is based on the application of natural principles to the job of providing compatible air-fuel mixtures to meet exhaust emission standards and driveability for the varying engine requirements. Just as it is necessary to understand the range of fuel mixtures required for each operational phase, so must the serviceman basically understand the natural forces applied by the design for delivery of these mixtures. PURPOSE OF A CARBURETOR The purpose of a carburetor on a gasoline engine is to meter, atomize, and distribute the fuel throughout the air Fuel-Air Requirements.............................................. 6M-8 Power vs. Economy.................................................. 6M-8 Cold Starts................................................................... 6M-9 Basic Carburetor Systems........................................ 6M-9 Float System................................................................ 6M-10 Idle System.................................................................. 6M-10 Main Metering System............................................ 6M-11 Power System.............................................................. 6M-12 Pump System.............................................................. 6M-12 Choke System............................................................. 6M-12 flowing into the engine (Fig. 1). These functions are designed into the carburetor and are carried out by the carburetor automatically over a wide range of engine operating conditions, such as varying engine speeds, load, and operating temperature. The carburetor also regulates the amount of air-fuel mixture which flows to the engine. It is this mixture flow regulation which gives the driver control of the engine speed. Regardless of engine speed or load, the carburetor must automatically perform its three basic functions. The automotive carburetor is an intricate device; however, when studied one phase at a time, the functions of the carburetor are easily understood. As mentioned above, the three main functions of the carburetor are to meter, atomize and distribute the fuel. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 E N G IN E FUEL METERING CORRECT PR O P O R TIO N S O F FUEL A N D AIR A T O M IZ A T IO N SPRAY O F FINE PARTICLES GREAT AIR C O N T A C T DISTRIBUTION U N IF O R M MIXTURE DELIVERED T O M A N IF O L D Fig. 1 -Basic Functions ATOMIZATION The engine’s source of fuel for power is gasoline. Before gasoline can be used as fuel for an engine, it must be atomized which means breaking the fuel into fine particles so that it can be mixed with air to form a combustible mixture. Contrary to popular belief, gasoline in its liquid state is not combustible; only gasoline vapor will burn. A common example of this is a cigarette lighter which works fine indoors but then can’t be lit after you’ve been outdoors in the cold for awhile. At warmer temperatures, fuels vaporize quickly and so can be ignited easily but at lower temperatures, evaporation is slower and accordingly ignition is impossible or, at least, difficult because of insufficient vapor. While this analogy is quite simple, it is an illustration of the basic problems of carburetor design; that is, the provision of combustible fuel mixtures over a broad range of temperature and operating conditions. The complexity of design problems continues to mount each year due to a constant effort to reduce exhaust emissions and at the same time improve operating conditions. To be combustible, gasoline must vaporize. Vaporization is the act of changing from a liquid to a gas and this change of state occurs only when the liquid absorbs enough heat to boil. This is what happens in a tea kettle to change water to water vapor, or steam. Heat is transferred to the water, raising its temperature until it finally reaches the boiling point, at which time the water changes to steam and is carried off to atmosphere in this gaseous form. At seal level, the water will oil at 212°F but at high altitudes, less heat is required for water to boil due to lower atmospheric pressure. This is known as the temperature-pressure relationship; that is, as the pressure is reduced, the boiling point is reduced. This law, combined with a process known as atomization, has important applications in the transformation of liquid gasoline to a capor for use in combustion. In a carburetor (Fig. 2), gasoline is discharged into the incoming air stream as a spray and the spray is then atomized, or torn into fine droplets to form a mist. The resulting air-fuel mixture is drawn into the intake manifold. At this point, the change of state occurs and the fuel "mist" vaporizes as the result of several factors. Since the pressure in the intake manifold is far less than atmosphere, the boiling point of the gasoline is lowered considerably. At this reduced pressure, latent heat absorbed from the many air particles surrounding each fuel particle causes some vaporization, which is further aided by heat on the intake manifold floor. Because complete fuel vaporization is the result of many factors (ambient temperature, fuel temperature, mani­ fold vacuum, and intake manifold temperature), it is easy to see that anything which reduces any one of these factors will adversely effect vaporization and thus reduce fuel economy and increase exhaust emissions. Some examples would be cold weather, an inoperative exhaust heat control valve, and high overlap camshafts and/or heavy throttle demands. While the effects from lower temperatures are obvious, reduction of manifold vacuum either by valve timing or heavy throttle operation are highly detrimental to fuel economy due to the higher pressures (and boiling points) resulting in the intake manifold which reduces the amount of fuel vaporization which will occur by the time the charge enters the combustion chamber. Fuel not vaporized at the time of induction is, to a large extent, exhausted unburned from the combustion chamber and can cause high hydro­ carbon exhaust emissions. We know that gasoline, for combustion, must be vaporized or as the change of state can be loosely considered, absorbed by air. However, this requirement LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL 6M -5 is further limited by the amount of air that the fuel vapor is absorbed by. Combustible mixtures in an engine are limited by the following proportions, or ratios, of air to gasoline: eight parts air to one part gasoline is the richest mixture that will fire regularly and a mixture of 18 1/2 parts air to one part gasoline is the leanest mixture that will fire without missing in an engine. Mixtures leaner than 18.5:1 tend to cause misfire. From an automotive standpoint these ratios represent the mixture extremes that an engine can tolerate, but these limits do not provide the two conditions most sought. The most desired ratios are a mixture that will produce the most power per pound of gasoline and a mixture that will provide the best economy or most miles per pound of fuel with the least exhaust emissions. For those who may be wondering why we are speaking in terms of "pounds" of fuel instead of our more usual gallon measure, let’s take a moment for clarification. Actually the reason we speak in terms of pounds rather than gallons is so that the ratio, or air-fuel mixture proportion, terms can be smaller numbers. For example, for most efficient (and economical) combustion, 9000 gallons of air are required to burn one gallon of gasoline, hence an air-fuel ratio of 9000:1 by volume. Obviously, proportions with such numerical differences would be difficult to comprehend and extremely awkward to work with for experimentation and design. By using weight as the base, let’s make the same comparison (Fig. 3). A gallon of gasoline weighs about six pounds whereas 100 gallons of air are needed to produce one pound of air. Converting our volume airfuel ratio to weight, we find that 9000 gallons of air weighs 90 pounds (100 gals, equals 1 lb., therefore 9000 divided by 10090 lbs.) and one gallon of gasoline weighs 6 pounds. 90 divided by 6 equals 15 therefore we arrive at an air-fuel ratio of 15:1 by weight. METERING Good combustion demands a correct mixture ratio between fuel and air. To release all possible energy by combustion, the right amount of fuel must be mixed with a given amount of air. The metering job of the carburetor is to furnish the proper air-fuel ratio for all conditions, so that the engine operation will neither be too lean for power requirements nor too rich for economy (Fig. 4), while still meeting prime requirements of low emissions. AIR MEASUREMENT Air flow through a pipe will create a pressure drop within the pipe proportional to the speed of the air. Thus, for a given pipe size, the pressure difference between the outside air and the pressure within the pipe provides a direct means of measuring the amount of air flowing through the pipe. The simplest means of measuring the pressure difference between atmosphere and the pressure inside the pipe, is to insert a U-tube partially filled with water into the pipe as illustrated (Fig. 5). Since one end is open to atmosphere, the water level will rise on the low pressure (or pipe side) because water will flow toward an area of lower pressure. Actually, the water is being pushed into a state of balance by the weight of the air at the end of the U-tube open to atmosphere vacuum. A common example of the force exerted by the weight of air is a drinking straw (Fig. 6). As you suck on a straw, the air within the straw is removed, thus creating a low pressure or vacuum. The weight, or pressure, of the air on the surface of the liquid in the glass then forces the liquid up the straw to fill the void. The important thing to LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 6 E N G IN E FUEL more convenient valve for measuring the larger pressure differences. FUEL METERING DEPRESSION (LOWER PRESSURE) WATER Fig. 5 -Air Flow Measurement understand is that fluid is not pulled by the vacuum but is rather pushed into the vacuum or low pressure area by the weight of the air pressing on the surface of the liquid. The difference in pressure, or vacuum, is expressed by measuring the distance between the two heads of water in the U-tube, or inches of water. Low vacuum is generally expressed in inches of water but higher vacuum, such as manifold vacuum, is usually measured in inches of mercury because mercury is approximately 13 1/2 times heavier than water and thus provides a As shown in measurement of air flow with the U-tube, fluids flow when there is a difference in pressure and will always flow toward the lower pressure. If the fluid level in the U-tube were higher, the reduced pressure within the pipe would cause the fluid to flow into the pipe. Further, if a means were provided to maintain the fluid level at a desired height in the U-tube, the amount of fluid flow would be proportional to the pressure difference caused by the air flow through the pipe. Carburetors operate on the basic principle of pressure difference. A basic carburetor is an adaptation of the U-tube (Fig. 7). The fuel side, open to atmospheric pressure, inside of air cleaner (internal venting), is enlarged to create a reservoir and fitted with a float valve to maintain a constant level of fuel. To control the quantity of fuel delivered, a jet or metering orifice is screwed into the base of the main nozzle. A streamlined restriction, known as a venturi, is added to the air intake side to create an additional pressure drop for a given rate of air flow, dictated by upper diameter of the pipe. Finally, a throttle valve is added to control the volume of air-fuel mixture admitted. Applying the basic carburetor to an engine, air flow is initiated by the pumping action of the pistons and the intake and exhaust valve action. As the piston moves downward during the admission or intake stroke, the inlet valve is open causing air to rush in through the carburetor and manifold to fill the space left by the downward piston travel. At engine operating speeds, especially with multi-cylinder engines, the air flow through the carburetor is nearly constant. The amount of air flow, and accordingly the fuel picked up, is controlled by the opening allowed by the throttle valve. VENTURI P y /.. ii LOW PRESSURE (VACUUM) DEVELOPED INSIDE MOUTH j! THROTTLE Fig. 6 -Vacuum Principle Fig. 7 -Basic Carburetor LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL VENTURI PRINCIPLE (FIG. 8) To obtain a greater pressure drop at the tip of the nozzle to cause the fuel to flow, the principle of increasing the air velocity to create a low pressure area is used. A device called the "venturi" is used to increase the air velocity and lower the pressure at the discharge nozzle. The increased pressure differential between that of the fuel bowl and at the carburetor throat increases fuel flow sufficiently, at a given air flow, so that the resulting airfuel proportions result in a combustible mixture. For example, a carburetor with a 1 1/2" pipe will supply the volume of air required for a given displacement engine. However, the pressure drop within the carburetor throat is insufficient to cause enough fuel to flow into the carburetor at the desired speed to create a combustible fuel mixture due to the large weight difference between air and gasoline. By necking down the inner diameter of the carburetor throat into a venturi, the air flow is forced to speed up at the restriction area, thus further reducing air pressure and increasing fuel flow proportionately to achieve the desired mixture. To be most effective, the venturi must be designed for a certain curvature and length. The venturi design can be tailored to provide fuel flow under any condition of air flow. However, a small venturi may restrict high speed engine operation and a large venturi will not provide enough pressure differential for low speed operation. The production venturi size is usually a compromise to provide adequate low and high speed operation. The carburetor discharge nozzle is located in the center of the venturi throat to take advantage of the maximum ATMOSPHERIC 6 M -7 pressure drop and promote atomization of the fuel. The large venturi, cast in the carburetor bore, is called the primary or main venturi. Most carburetors use a primary and one or most boost venturis. The boost venturi is usually located over the primary with its discharge end in the low pressure area of the primary. The purpose of the boost venturi is to further lower the pressure at the nozzle. Additional boost venturis may be used for finer control of pressure drop but at high speed they tend to restrict air flow to the engine. Because actual venturi size is a compromise, two- and four-barrel carburetors are used where requirements are extreme. A two-barrel carburetor allows use of smaller venturi for improved low speed operation yet gives relatively good high speed operation due to the larger throttle area provided by the two throttle valves. The primary side of a four-barrel carburetor is designed much the same as the two-barrel carburetor with small venturi for low speed economy. The secondary side of a four-barrel carburetor uses large bores and venturi for extremely good high speed breathing. The secondary side of the four-barrel carburetor operates only at high degree primary throttle openings or when performance is required. DISTRIBUTION For good combustion and smooth engine operation, the air and fuel must be thoroughly and uniformly mixed, delivered in equal quantities to each cylinder and evenly distributed within the combustion chamber. Good distribution requires good vaporization. A gaseous mixture will travel much more easily around corners in the manifold and engine, while liquid particles, being relatively heavy, will try to continue in one direction and will hit the walls of the manifold or travel on to another cylinder. As an example, consider a six cylinder engine with the carburetor mounted at the center of the manifold. The INTAKE STROKE 'Low Pressure) Fig. 8 -Venturi Principle DISTRIBUTIO N Fig. 9-Distribution LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 8 E N G IN E FUEL mixture for cylinder 4, 5, and 6 will initially travel towards the rear of the engine. If 5 is on the intake stroke, the mixture will be drawn sharply around the corner to 5 at right angles to the original direction (Fig. 9). The large drops of gasoline won’t make such a sharp turn and will continue in their path to the rear of the manifold, where they will probably be drawn into 6 on its intake stroke. Thus, 5 receives a leaner mixture and 6 receives a richer mixture than originally entered the manifold. To compensate for these problems, manifolds are tailored to the engines to minimize the sharp corners and provide as smooth a flow as possible. The carburetor’s principal job in distribution is to break up the fuel as finely as possible and furnish a uniformly vaporized mixture to the manifold. FUEL-AIR REQUIREMENTS (Fig. 10) As previously mentioned, we know that without regard for efficiency, an air-fuel mixture within the range of 8-to-l and 18 1/2-to-l must be provided for an automobile engine to run. More practically the air-fuel ratio should be utilized which would allow peak power output, minimum emissions, and peak fuel economy. Unfortunately, no single air-fuel ratio can provide both the above peak conditions. Tests prove the best power output is obtained using a 12.5-13.5:1 mixture whereas best fuel economy results using a 15.0-16.0:1 mixture. Since an automobile engine must be able to provide both requirements, obviously no compromise fuel ratio would be satisfactory. Therefore a carburetor must be able to quickly match varying engine requirements with the best possible fuel mixture to meet the demand. This means that fuel ratios must be provided not only for the demand but caused by light speed variations and changing engine load conditions such as a moderate grade. One of the reasons that the air-fuel ratio must be varied is because of imperfect conditions within the combustion chamber. Exhaust gases remaining in the cylinder dilute the fresh charge. The fuel and air are not perfectly mixed, miniature droplets of unvaporized fuel being carried along by the mixture of air and evaporated fuel. The intake manifold itself does not deliver exactly equal air-fuel mixtures to all cylinders. The air-fuel ratio must therefore be adjusted, depending on such factors as engine speed and whether power or economy is desired. POWER VS. ECONOMY If maximum power is desired, it is necessary to burn all the oxygen in the air, since the power-production ability of an engine is limited by the amount of air it can take in. Additional fuel must therefore be added to insure that each molecule of oxygen combined with the necessary fuel. Thus, the mixture required for maximum power usually falls in the range from 12 to 13.5-to-l, being "richer" in gasoline than the theoretical ratio. On the other hand, for maximum economy and least emissions, it is desirable to burn all of the fuel, in order to extract as much energy as possible with minimum residual. Because of the imperfect combustion condi­ tions, additional air is required to insure that each molecule of fuel can be combined with the necessary oxygen. As a result, the actual air-fuel ratio for maximum economy tends to be somewhat "leaner" in gasoline than that calculated for chemically perfect combustion. The best air-fuel ratio for any given operating condition varies from engine to engine due to differences in manifolding, combustion chamber design, valve timing, P( DW ER-W IDE -— Fig. 10-Air-Fuel Flow IDLE O P E N THRO TTI F E N G IN E SPEED H IG H — Fig. 11 -Air-Fuel Flow -Full Throttle LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL ignition timing, and other engine design factors. The optimum mixture can best be determined by operating an engine on a dynamometer where power, speed, and fuel consumption may be measured over a wide range of conditions. Tests made at speeds throughout the engine’s operating range reveal that the air-fuel ratio for maximum power remains nearly constant at all except low speeds (Fig. 11). Here, some slight enrichment is necessary due to the effect of exhaust-gas dilution in the cylinder and the poor mixing and distribution from the lower velocity air flow into the engine. Similarly, the leaner air-fuel ratios for maximum economy at part throttle (Fig. 12) are found to be essentially equal throughout most of the operating range. Again, enrichment is necessary at low speeds and during idling; for the latter, the air-fuel ratio usually falls in the range from 11 -to-1 to 12.5-to-l. Richer mixtures are also used at high operating speeds and loads, where more power is required. It is usually desirable to operate the engine so that the best fuel mileage can be secured during normal cruising, while maximum power should be available when the throttle is opened for acceleration or top speed (Fig. 13). Through this point, we have covered the engine’s general requirements insofar as the need for both a vaporized mixture and the proportions, or ratio, of the air-fuel vapor for efficient combustion. This leaves only one question which needs clarification before we end this discussion of air-fuel requirements, that is, "W hy are richer fuel mixtures needed for cold starts " COLD STARTS Recall for a moment that the cigarette lighter could be ignited easily indoors but after exposure to colder air, the lighter failed to light. It was concluded that the 6M -9 Fig. 13- Air-Fuel Flow- Complete Air lighter failed to light because there was too little fuel vapor or actually the air-fuel ratio was too lean to burn. Preheating to increase fuel vaporization to correct the air-fuel ratio is the answer in the case of the cigarette lighter but this would be impractical from a time and cost standpoint for automotive use. We are all aware that a choke is used on carburetors to restrict the air flow and thereby enrich the fuel mixture. Because of this, many assume that a richer mixture is actually burned during cold engine operation but this is definitely not the case. Although the air-fuel ratio may vary fuel is always burned at a 15:1 ratio. While this may seem contrary to actual conditions, the key is the term "vaporize." Since only vaporized fuel burns and the vaporization rate is sharply reduced at lower temperatures, a rich fuel charge must be admitted so that the total resultant fuel vapor reaching the cylinders will be rich enough to create a combustible mixture. The extra fuel (that which did not vaporize) is minimized, or in some engines is discharged from the port unburned as waste during the exhaust cycle and burned in the exhaust system. While this represents a considerable waste of fuel, it is necessary to provide combustible fuel mixtures until the engine is warmed up. While the discussion of engine air-fuel requirements has been brief, the following points should be remembered: • Only vaporized gasoline will burn • Air-Fuel ratios are referenced in terms of weight • Vaporization rates reduce as temperature declines • Gasoline always burns at a 15-to-l ratio; extra fuel is not burned but lost as waste. BASIC CARBURETOR SYSTEMS The carburetor performs a comparatively simple job but LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 1 0 ENGINE FUEL it does so under such varied conditions that it is necessary to have several systems to alter its functions so that it can adjust to various situations. Most carburetors contain the following six basic systems: • Float System • Idle System • Main Metering System • Power System • Pump System • Choke System Float System (Fig. 14) Fuel in the carburetor float bowl must be maintained at a specified level for correct fuel metering under all driving conditions. The float system accomplishes this by using a float pontoon and attached leverage arm which exerts force against a needle valve, shutting off fuel flow when the specified level is reached in the carburetor bowl. Fuel enters the inlet and fills the carburetor bowl through the valve orifice (needle seat). As the level in the bowl rises, the buoyant action of the float seats the needle valve. When fuel is being used from the bowl, the float drops sufficiently to allow the needle to unseat and fuel to enter past the needle to maintain,the specified level in the float bowl. The liquid level controlled by the float setting is an im portant part of the calibration of the carburetor. The effects of a low liquid level causes poor performance in the main metering system and could cause loss of power. High liquid level can result in premature main metering delivery and fuel spillage during normal car maneuver­ ing, each of which causes excessive fuel consumption and an over-rich condition. The fuel level is controlled by a float and adjusted by bending a tab on the float arm. Accuracy of this adjustment may be measured by checking the physical relationship of the float to a particular area on the fuel bowl. The float system is perhaps one of the most important systems in the carburetor, as the correct operation of all other systems depends on the proper level of fuel in the float bowl. Idle System (Fig. 15) During engine idle and low speed operation, air flow through the carburetor is very slight due to the throttle blade being nearly closed and is insufficient to meter fuel properly from the main discharge nozzle. To offset this condition, the idle system is used to provide the proper mixture ratios required during engine idle and low speed operation. The idle system consists of an idle tube, idle passages, idle air bleeds, off-idle discharge ports, idle mixture adjusting needle and the idle mixture needle discharge port. In the idle speed position, the throttle valve is slightly open, allowing a small amount of air to pass between the wall of the carburetor bore and the edge of the throttle valve. Since there is not enough air flow for venturi action, the fuel is made to flow by the application of manifold vacuum directly through the idle system to the fuel in the carburetor bowl. The low pressure below the throttle valve (manifold vacuum) will cause the fuel to flow through the idle tube, into the idle passage, where it is mixed with air from the air bleed. This is the first stage of atomizing the fuel. The mixture continues down the passage, past the off-idle ports. At this point these ports act as air bleeds to further break up the mixture. The mixture flows past the mixture screw into the carburetor bore and into the engine intake manifold. The mixture screw controls the idle mixture and is turned in to lean the mixture and out to richen it. Mixture screws are now locked after flow test at the manufacturing plant by means of limiter caps which attach over the mixture screws. These caps must not be tampered with in the field due to the effect on exhaust emissions. As the throttle valve is opened, additional air flows through the carburetor. Since air flow is still insufficient to draw fuel from the main nozzle, the increased air flow results in excessively lean mixtures. To compensate for this problem off-idle ports are added to the carburetor (inset Fig. 15) just above the closed throttle position. When the throttle is opened during slow speed or off-idle operation (Fig. 15), the off-idle ports are exposed to manifold vacuum and begin discharging extra fuel mixture for off-idle requirements. Thus, the off-idle ports have a dual purpose. At idle they act as air bleeds but LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL during the off-idle range they change to fuel mixture feeds. Both the idle and off-idle ports are designed to provide a smooth transition between idling and cruising speeds of 25 to 40 mph for passenger cars, depending on carburetor design. At these speeds, the throttle opening and air low are sufficient to perm it the main metering system to begin to supply fuel. The point at which fuel flow starts from the main nozzle is the transfer point (Fig. 16). This means that the carburetor is passing from idle to main metering system. The idle port discharge however, does not cease at this point but rather diminishes as main nozzle discharge increases. Thus, the two systems interact and produce a smooth fuel-air flow at all engine speeds. Main Metering System (Fig. 17) The main metering system controls the economy range of the carburetor. It consists of a main jet, main well and 6 M -1 1 main nozzle with air bleeds in it. The main jet is a very accurately machined orifice, which controls the fuel flow through the main well in which the nozzle is located. An air bleed in the main well and the air bleeds in the main nozzle keep the mixture constant throughout the operating range of the main metering system. As the throttle valve is opened, air velocity through the venturi system increases which in turn decreases the pressure in the venturi at the main fuel nozzle. This action causes the fuel to pass through the main metering jet into the main well where it rises in the main well passage and idle pickup tube. As the fuel enters the nozzle, it is mixed with air through calibrated holes in the nozzle. Air is bled into the main well by the air bleeds. This air aids in breaking up the fuel for improved distribution. The mixture continues through the main discharge nozzle and enters the air stream at the boost venturi. At this point it is mixed with the incoming air and is carried past the throttle valve and into the manifold for distribution to the engine cylinders. TOP AIR BLEED E.G.R. (EXHAUST GAS RECIRCULATION) TUBE TO E.G.R * VALVE IDLE CHANNEL RESTRICTION AIR INLET Bl— METAL STRIP IDLE TUBE VALVE M AIN METERING JET HOT IDLE COMPENSATOR TIMED VACUUM PORT FOR E.G.R. * OFF— IDLE PORT GASKET THROTTLE VALVE IDLE MIXTURE NEEDLE IDLE DISCHARGE HOLE IDLE S Y S T EM OFF— IDLE OPERATION Fig. 15—Idle System LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 1 2 ENGINE FUEL Pump System TYPICAL FLOW CURVE SHOW ING SYSTEMS OPERATION VS. M.P.H. k 15=1 V " TRANSFER 1 IDLE& 1 MAIN METERING SYSTEMS M IL E S PER HOUR 0 -2 5 2 5 -4 0 . MAIN METERING SYSTEM 4 0 -6 0 7 POWER SYSTEM & MAIN MET’RNG. 6 0 -M A X Fig. 16-Typical Systems Operation The main metering jet and the air bleeds are pre­ calibrated to maintain the desired air-fuel ratios throughout the main metering range. Therefore, no adjustments are necessary in the main metering system. Power System (Fig. 18) As discussed previously, richer fuel mixtures are needed for high speed operation since maximum engine power requires the use of all available air for combustion. The power system is used to supplement the main metering system and provide the power enrichment according to the amount of throttle opening and engine load. The power system consists of: a power valve, power piston and spring, and power restriction. The power valve controls a fuel passage which bypasses the main metering jet from the bowl to the main well. The power piston is located above the valve and determines when the valve will open. The power piston is spring loaded and normally held in the closed position by high manifold vacuum conditions. Under conditions of power, manifold vacuum will be low which means vacuum will decrease on top of the piston allowing the spring to corce the power piston down, opening the valve to increase the fuel flow to the main nozzle. This has the same effect as enlarging the main jet. A calibrated power restriction is used in the passage between the power valve and the main well to control the amount of enrichment. While this system is constantly operative only at speeds approaching wide open throttle and above, sudden throttle openings at slow and mid-range speeds will cause momentary opening of the power valve, due to resultant manifold vacuum decreases. Power valve springs generally are calibrated to allow opening to begin at 8 " to 9" average and full opening when manifold vacuum falls below 4" to 6 " average. There is no adjustment required for the power system. (Fig. 19) When the throttle is opened rapidly, the air flow and manifold vacuum change almost instantly. Because of the great difference in weight between air and fuel, any sudden change in throttle opening results in an immediate increase in air intake but the fuel, having greater weight tends to lag behind. The result of this is momentary leanness. The accelerator pump provides the extra fuel necessary to overcome this leanness and give smooth operation during transient operations. This is accomplished by discharging extra fuel into the venturi air stream whenever the throttle valve is opened. The pump system utilizes a pump plunger that is linked to the throttle lever by mechanical linkage. When the pump plunger moves upward in the pump well, as happens during throttle closing, fuel from the float bowl enters the pump well through a slot in the top of the pump well, or through an inlet check valve in earlier design carburetors. It flows past the pump cup seal into the bottom of the pump well. The pump plunger is the floating type of which the cup moves up and down on the pump plunger head. Some models may use the fixed cup, ball vapor vent design. When the pump plunger is moved upward, the flat on the top of the cup unseats from the flat on the plunger head and allows free movement of fuel through the inside of the cup into the bottom of the pump well. During a shut down soak period this also vents any vapors which may be in the bottom of the pump well so that a solid charge of fuel can be maintained in the fuel well beneath the plunger head. At the same time, the discharge check valve seats to prevent air from leaking into the discharge passage. When the throttle valves are opened, the connecting linkage forces the pump plunger downward. The pump cup seats instantly and fuel is forced through the pump discharge passage, where it unseats the pump discharge check valve and passes on through the passage to the pump jets where it sprays into the venturi area of each bore. The accelerator pump system is an accessory device which has no function other than momentary operation at the time of throttle position changes. The pump is purely mechanical and not affected by air flow. Choke System (Fig. 20) The necessary requirements for good fuel vaporization are missing or are inadequate when starting a cold engine. To overcome this condition, plus condensation of the fuel on the cold manifold, it is necessary to meter extremely rich mixtures from the carburetor (2:1 to 1:1 air-fuel ratios) in order to provide sufficient combustible mixtures to the cylinders for quick starting. This enrichment is obtained by the addition of a choke valve in the air horn above the main m etering system; starting fuel to flow through these systems. The choke system consists of a choke valve located in the LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -13 M A IN W ELL A IR BLEED POWER PISTON M E T E R IN G ROD M A IN D ISC HA R G E NO ZZLE POWER PISTON SPRING BOOST V E N T U R I M A IN V E N T U R I M A IN M E T E R IN G JET C A L IB R A T IO N SCREW POWER PISTON A C T U A T IN G L IN K A G E LOWER ID LE A IR BLEED POWER PISTON V A C U U M THRO TTLE VALVE MAIN METERING SYSTEM Fig. 1 7 -Main Metering System primary air horn, a vacuum break diaphragm unit, fast idle cam, choke linkage and a thermostatic coil which is located on the engine manifold. The coil is connected to the choke valve by a rod. The choke operation is controlled by a combination of intake manifold vacuum, the off-set choke valve, thermostatic coil characteristics, atmospheric tmeperature, and exhaust manifold heat. The remote thermostatic coil located on the engine manifold is calibrated to hold the choke valve closed when starting a cold engine, air velocity against the off­ set choke valve causes the valve to open slightly, against the torque of the thermostatic coil. When the engine is started, manifold vacuum applied to the vacuum diaphragm unit mounted on the carburetor air horn will open the choke valve to a point where the engine will operate without loading (rich) or stalling (lean). The choke valve will remain in this position until the engine begins to warm up. Through application of exhaust manifold heat, the thermostatic coil relaxes gradually until the choke valve is fully open. Opening of the choke valve is controlled by air flow through the carburetor air horn, past the off-set choke valve and manifold heat acting upon the thermostatic coil. As the engine is accelerated during warm-up, the corresponding drop in manifold vacuum and low air flow against the off-set choke valve, allows the thermostatic coil to momentarily close the choke, providing a richer mixture. During warm-up it is necessary to provide a faster idle to prevent engine stalling. This is accomplished by a fast idle cam which is connected by a rod to a lever on the choke shaft. The idle screw on the throttle lever contacts graduated steps on the fast idle cam to provide a faster idle than normal, to prevent engine stalling during the warm-up period. When the engine is fully warm and the choke valve is wide open, the fast idle cam rotates so that the idle screw rests on the low step on the fast idle cam where normal curb idle is obtained. Some carubretors have separate fast and curb idle air adjustment screws. If the engine becomes flooded during the starting period, LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 1 4 ENGINE FUEL MAIN WE LL AIR BLEED POWER PISTON M A IN D ISC H A R G E NOZZLE D R IV E RO D BOOST V E N T U R I M E T E R IN G ROD M A IN V E N T U R I POWER PISTON SPRING M A IN M E T E R IN G JET POWER PIS TO N A C T U A T IN G L IN K A G E THROTTLE VALVE POWER PISTON V A C U U M LOWER ID LE A IR BLEED POWER ENRICHMENT SYSTEM Fig. 18- Power System the choke valve can be partially opened manually to allow increased air flow through the carburetor. This is accomplished by depressing the accelerator pedal to the floor. The unloader projection on the throttle lever contacts the edge of the fast idle cam and, in turn, partially opens the choke valve. The extra air leans out the fuel mixture enough so the engine will start. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -15 " T " D IS C H A R G E SPR IN G R E T A IN E R PUMP L E V E R PUMP P L U N G E R & D U R A T IO N SPR IN G PUMP D IS C H A R G E SPR IN G & B A LL PUMP F IL L S LO T CUP S EA L PUMP R E T U R N SPR IN G PUMP A C T U A T IN G L IN K PUMP SYSTEM PUMP CUP O P E R A T IO N Fig. 19-Pump System LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 1 6 ENGINE FUEL Fig. 20--Choke System M AINTEN A NC E A N D ADJUSTMENTS NOTE: Also refer to the "Emission Control Systems" Booklet for required maintenance and warranty information. Timing Points (Dwell), Idle Speed - These adjustments must be performed accurately, following the specifica­ tions shown on the label under the hood. Adjustments must be made with test equipment known to be accurate. Proper functioning of the carburetor is particularly essential to control of emissions. Correct mixtures for emission compliance and idle quality have been preset. Plastic idle mixture limiters have been installed on the idle mixture screws to preclude unauthorized adjustment. These idle limiters are not to be removed unless made necessary by some major carburetor repair or replacement which affects the idle screw adjustment. CHOKE-Choke mechanism should be checked for free operation. A binding condition may have developed from petroleum gum formation on the choke shaft or from damage. Choke shafts can usually be cleaned without disassembly by using United Delco X -66 Carburetor and Combustion Cham ber Conditioner or equivalent. BOLTS, CARBURETOR TO M ANIFOLD-Carburetor attaching bolts and/or nuts should be carefully adjusted to correct torque to compensate for compression of gasket at first 4 months or 6,000 miles of vehicle operation only. FILTER-CARBURETOR A N D /O R FUEL PUMP-A LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL clogged carburetor or fuel pump filter may restrict fuel flow or bypass foreign m aterial into carburetor depending upon type used. Replace clogged filters. Also replace filters each 12,000 miles or 12 months, whichever occurs first. CEC VALVE, OR VACUUM ADVANCE SOLE­ NOID, AND HOSES-The vacuum portion of either of these valves should be checked, with the transmission in neutral, by using a vacuum gauge attached to the valve (or solenoid) distributor connector. With the engine at fast idle, the vacuum gauge should read zero. The electrical portion of the solenoid or valve may be checked by applying 12 volts across its electrical terminals, which should result in a vacuum reading on the gauge — a vacuum reading should be obtained only while the solenoid or valve is not energized. An inoperative or leaking solenoid or valve should be replaced. All hoses and wires should be carefully inspected for correct routing and to make certain that they are intact. 6M -17 IDLE STOP SOLENOID-The idle stop solenoid should be checked to assure that it permits the throttle plate to close further when the ignition switch is turned "off." An inoperative solenoid should be replaced. PRELIMINARY CHECKS (ALL CARBURETORS) 1. Thoroughly warm-up engine. If the engine is cold, allow to run for at least 15 minutes. 2. Inspect torque of carburetor to intake manifold bolts and intake manifold to cylinder head bolts to exclude the possibility of air leaks. 3. Inspect manifold heat control valve (if used) for freedom of action and correct spring tension. 4. Check and adjust choke as required, using procedures specified in this section. 5. Adjust idle speed and idle mixture as outlined in Section 6 , "Engine Tune-up" and at the end of the carburetor group in this section under, "Additional External Settings and Adjustments." EXTERNAL ADJUSTMENTS (ALL CARBURETORS) INDEX Adjustments........................................................................ Removal .............................................................................. Test Before Installation ..................................................... Installation ........................................................................... 6M-17 6M-23 6M-24 6M-24 Fuel Filter M aintenance........................................... Automatic Choke Coil Assemblies....................... Choke Coil R eplacem ent.......................................... Additional External Settings and Adjustments. Throttle Linkage Adjustm ent.................................. 6M-25 6M-25 6M-25 6M-26 6M-27 ROCHESTER MV, 2GV AND 4 M V ADJUSTMENTS FAST IDLE ADJUSTMENTS (Figs. 1C, 2C and 3C) ROCHESTER MV AND 4MV NOTE: The fast idle adjustment must be set with transmission in "N eutral." 1. Position fast idle lever on high step of fast idle cam. 2. Be sure choke is properly adjusted and in wide open position - engine warm. 3. Set fast idle to specified rpm as follows: a. Adjust fast idle screw on Rochester 4MV (Fig. 2C). b. Bend fast idle lever as required on Rochester MV to specified speed (Fig. 1C). FAST IDLE ADJUSTMENT-ALL 2 BBL. NOTE: The two barrel carburetors are preset to the approximate fast idle RPM noted in specifications, listed under "Fast Idle (Run­ ning) RPM adjustment", when low step idle is set. (Also note Low Idle RPM in specifications). CHOKE ROD (FAST IDLE CAM) ADJUSTMENTS MV (Fig. 4C) NOTE: Make sure that the fast idle adjustment is made previous to choke rod adjustment. Automatic choke models with steps on fast idle cam. W ith fast idle adjustment made: 1. Place fast idle cam follower on second step of the fast idle cam and hold firmly against the rise to the high step. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 1 8 ENGINE FUEL 2. Rotate choke valve toward direction of closed choke by applying force to choke coil lever. Fig. 2C~Fast Idle Adjustment (Rochester 4MV) 3. Bend choke rod at point shown to give specified opening between the lower edge of choke valve (at center of valve) and inside air horn wall. 2GV (Fig. 5C) Turn stop screw in until it just contacts bottom step of fast idle cam. Then turn screw in one full turn. Place idle screw on second step of fast idle cam against shoulder of high step. With screw in this position, hold choke valve toward closed position with a rubber band and check clearance between upper edge of choke valve and air horn wall. Adjust to specified dimension by bending tang on choke lever and collar assembly. H O LD DOWN ON CHOKE VALVE GAUGE BETWEEN CHOKE VALVE AND AIR HORN WALL BEND ROD TO ADJUST CAM FOLLOW ER MUST BE HELD FIRM LY ON SECOND STEP O F FAST IDLE CAM AGAINST HIGH STEP 4MV (Fig. 6C) With the cam follower on second step of fast idle cam and against the high step, rotate the choke valve toward Fig. 4C-Choke Rod (Fast Idle Cam) Adjustment (MV) the closed position by turning the external choke lever counterclockwise. Dimension between the lower edge of choke valve, at choke lever end, should be as specified. Bend choke rod to adjust (Fig. 6 C). CHOKE VACUUM BREAK ADJUSTMENTS MV (Fig. 7C) Fig. 3C~Fast Idle Adjustment (Manual Choke) The following procedure for adjusting the vacuum break diaphragm unit is used to insure correct initial choke valve opening after engine starting: 1. Remove air cleaner assembly from vehicle. On vehicles with "Therm AC" air cleaner, plug the sensor’s vacuum take-off port. 2. Using an outside vacuum source, apply vacuum to the vacuum break diaphragm until the plunger is fully seated. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -19 (4MV) (2GV) 3. With the vacuum break diaphragm in the fully seated position, push the choke valve toward the closed position. 4. With the choke valve held in this position, place specified gauge between the lower edge of the choke valve and air horn wall. 5. Dimension should be as specified; if not, bend the vacuum break rod at point shown, to adjust. 2GV (Fig. 8C) Refer to Figure 8 C and follow steps under MV. 4MV (Fig. 9C) Fig. 8C-Vacuum Break Adjustment (2GV) 1. Seat choke vacuum break diaphragm using outside vacuum source. 2. Open throttle valve slightly so cam follower will clear steps of fast idle cam. Then rotate vacuum break lever counterclockwise (towards direction of closed choke). A rubber band may be used to hold in place. The end of vacuum break rod should also be in outer end of slot in vacuum break diaphragm plunger. 3. Measure the distance between lower edge of choke valve and inside air horn wall. 4. To adjust to specified dimension, bend vacuum break link at point shown. CHOKE UNLOADER ADJUSTMENT 1. Hold choke valve in closed position by applying a light force to the choke operating lever. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 2 0 ENGINE FUEL GAUGE BETWEEN A IR HORN WALL AN D LOWER EDGE OF CHOKE VALVE VACUUM PLUNGER M U S T BE FULLY SEATED USE OUTSID E V A C U U M SOURCE r-? LIGHTLY ROTATE CHOKE COIL LEVER COUNTERCLOCK W ISE UN TIL END OF ROD IS IN END OF SLOT IN LEVER BEND ROD TO A D JU S T OPEN P R IM A R Y THROTTLE VALVES SO TH A T FAST IDLE C A M FOLLOWER CLEARS FAST IDLE CA M Fig. 9C~Vacuum Break Adjustment (4MV) 2. Rotate throttle lever to wide open throttle valve position. 3. Bend unloader tang on throttle lever to obtain specified dimension between lower edge of choke plate (at center) and air horn wall. 2GV (Fig. 11C) With the throttle valves held wide open and the choke valve held toward the closed position with a rubber band, bend the unloader tang on the throttle lever to obtain specified clearance between the upper edge of the choke valve and air horn wall. CHOKE COIL ROD ADJUSTMENT MV (Fig. 12C) 1. Disconnect thermostatic coil rod from upper choke lever and hold choke valve completely closed. 2. W ith thermostatic coil rod disconnected, push downward on rod to end of travel. 3. With rod held in this position, the top of rod should be even with bottom of hole in choke lever. 4. To adjust, bend rod at point shown. 2GV (Fig. 13C) 1. Hold choke valve completely open. 2. With the thermostatic coil rod disconnected from upper lever, push downward on rod to end of travel. 3. W ith the rod in the fully downward position, bottom of rod should be even with the bottom of slotted hole in lever as shown. 4. To adjust, bend lever at point shown with screwdriver end. 4MV (Fig. 14C) 1. Hold choke valve completely closed by rotating choke coil lever counterclockwise. 2. With the thermostatic coil rod disconnected, with cover removed, push downward on coil rod so that the rod contacts bracket surface. 3. The coil rod must fit in choke lever notch, as shown. 4. Bend choke coil rod at point shown to adjust. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6 M -2 1 5. Install choke coil spring cover. 6 . Insert coil rod into choke coil lever slot and install retaining clip. 7. Make sure that the choke valve operates freely and coil rod does not bind on choke cover from the full open to full closed position. C.E.C. VALVE ADJUSTMENT (L-6 ENGINES-EXCEPT H /D VEHICLES) IM PORTANT: Do not set CEC Valve adjust­ ment to idle R.P.M. The CEC (Solenoid) Valve has a specified R.P.M. See Section 6 M, Specifications, under "O ther Adjustments." CAUTIO N: I f the CEC solenoid on the carburetor is used to set the engine idle or is adjusted out of limits specified in the Service Manual, decrease in engine braking may result. This adjustment is to be made only after, (1) replacement of the solenoid, (2 ) major overhaul of the carburetor is performed, or (3) after the throttle body is removed and replaced. The C.E.C. valve setting is made only after completing instruction on tune-up sticker. With engine running and transmission in "N eutral" for manual, and "Drive" for automatics, with air condition­ ing off, distributor vacuum hose removed and plugged, and fuel tank hose from vapor canister disconnected, perform the following: 1. Manually extend the C.E.C. valve plunger to contact throttle lever. 2. Adjust plunger length to obtain C.E.C. valve R.P.M. (see "Other Adjustments" in Specifications at end of this manual — Column No. 3). 3. Reconnect fuel tank vapor hoses to the canister and distributor vacuum hoses. AIR VALVE DASHPOT ADJUSTMENT 4MV (Fig. 16C) 1. Completely seat choke vacuum break diaphragm using an outside vacuum source. 2. With choke diaphragm seated and air valve fully closed, measure the distance between the end of slot in vacuum break plunger lever and air valve. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 2 2 E N G IN E FUEL A IR V A LV E C O M PLETELY C LO SED PULL OUTWARD ON PLUNGER STEM TO END OF TRAVEL DISCONNECT AND PLUG DISTRIBUTOR VACUUM HOSE NOTE: THROTTLE LEVER SHOULD CONTACT PLUNGER 1/8" HEX SCREW TO ADJUST LOW IDLE (SOLENOID NOT ENERGIZED) TURN SCREW TO ADJUST B EN D R O D H E R E TO O B T A IN S P E C IF IE D C L E A R A N C E B ET W E E N R O D A N D EN D O F S L O T IN LE V E R SET IDLE R.P.M. TO SPECIFICATIONS (TURN ASSEMBLY IN OR OUT TO ADJUST, SOLENOID ENERGIZED) C.E.C. VALVE ADJUSTMENT Models M-MV D IA P H R A G M U S E O U T S ID E VACU U M SO U R CE P L A C E G A U G E B ETW EEN R O D A N D E N D OF S L O T IN L E V E R AIR VALVE DASHPOT ADJUSTMENT Fig. 1 6 C --A ir V alve D a s h p o t A d ju s tm e n t ( 4 M V ) 3. Adjust to specifications by bending rod as shown. Fig. 15C --C .E .C . V a lv e A d ju s tm e n t (M V ) Ty p ica l ACCELERATOR PUMP ROD ADJUSTMENT 2GV (Fig. 17C) Back out idle stop screw and completely close throttle valves in bore. Place gauge on top of air horn ring. Bend the pump rod at lower angle to obtain specified dimension to top of pump rod. Fig. 17C-Accelerator Pump Rod Adjustment (2GV) LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL 6M -23 SERVICE OPERATIONS (INCLUDING ADDITIONAL EXTERNAL SETTINGS AND ADJUSTMENTS) INDEX Carburetor Removal........................................................... 6M-23 Accelerators and Choke Controls.......................................6M-27 Air Cleaners......................................................................6M-33 ALL CARBURETORS REMOVAL (Figs. Kl, K2 and K3) Flooding, stumble on acceleration and other perform ­ ance complaints are, in many instances, caused by the presence of dirt, water, gum and varnish caused by stale fuel from prolonged vehicle storage, or other foreign matter in the carburetor. To aid in diagnosing the cause of the complaint, the carburetor should be carefully removed from the engine without draining the fuel from the bowl. The contents of the fuel bowl may then be examined for contamination as the carburetor is disassembled. Check filter. 1. Remove air cleaner and gasket. Fuel Pumps........................................................................6M-40 Special Tools.....................................................................6M-67 2. 3. 4. 5. Disconnect fuel and vacuum lines from carburetor. Disconnect choke coil rod. Disconnect accelerator linkage. If equipped with automatic transmission, disconnect TV linkage. 6 . Remove C.E.C. valve (if so equipped) vacuum hose and electrical connector. 7. Remove idle stop electrical wiring from solenoid (if so equipped). 8 . Remove carburetor attaching nut and/or bolts, gasket or insulator and remove carburetor. Fig. Kl-Choke Coil Rod, L-6 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 2 4 E N G IN E FUEL TORQUE BOLTS (4) TO 14 FT. LBS. INSULATOR Fig. K 3 -C h o k e Coil R od, 4 M V R o c h e s te r Fig. K 2 -C h o k e C oil R od, 2 B b l. C a rb . V -8 TEST BEFORE INSTALLATION It is good shop practice to fill the carburetor bowl before installing the carburetor. This reduces the strain on the starting motor and battery and reduces the possibility of backfiring while attempting to start the engine. A fuel pump clamped to the vench, a small supply of fuel and the necessary fittings enable the carburetor to be filled and the operation of the float and intake needle and seat to be checked. Operate the throttle lever several times and check the discharge from the pum p jets before installing the carburetor. INSTALLATION 1. Be certain throttle body and intake manifold sealing surfaces are clean. 2. Install new carburetor to m anifold flange gasket or insulator (as required). LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL 6M -25 Fig. K 4--F uel F ilte r (P a p e r-T y p e ) (T y p ic a l) 3. Install carburetor over manifold studs or holes. 4. Start vacuum and fuel lines at carburetor. 5. Install attaching nuts and/or bolts and tighten to specified torque shown. 6 . Tighten fuel lines and install vacuum lines securely. 7. Connect and adjust accelerator and TV linkage. 8 . Connect C.E.C. Valve (L- 6 ) electrical wiring and attach vacuum lines. 9. Connect idle stop wiring connector to solenoid. 10. Connect choke coil rod. 11. Install air cleaner, adjust curb idle and low idle speeds per decal. (See specifications for C.E.C. valve adjustment, idle stop solenoid adjustment and idle mixture adjustment; also, "Additional external settings and adjustments".) FUEL FILTER MAINTENANCE 1. Disconnect fuel line connection at inlet fuel filter nut. 2. Remove inlet fuel filter nut from carburetor with a box wrench or socket. 3. Remove filter element and spring (fig. K4). 4. Check paper element by blowing on fuel inlet end. If filter does not allow air to pass freely, replace element. No attempt should be made to clean filters. NOTE: Element should be replaced if plugged or if flooding occurs. A plugged filter will result in a loss of engine power or rough (pulsating) engine feel, especially at high engine speeds. 5. Install element spring, and install element in carburetor. Bronze filters must have small section of cone facing out. 6 . Install new gasket on inlet fitting nut and install nut in carburetor and tighten securely. 7. Install fuel line and tighten connector. AUTOMATIC CHOKE COIL ASSEMBLIES Refer to "External A djustm ents" for choke coil adjustment procedures and typical installed views. Choke Coil Replacement In-Line Engines (Fig. K l) 1. 2. 3. 4. NOTE: The following procedures refer to all IN-LINE engines. Remove air cleaner and disconnect choke rod upper clip. Remove bolt attaching choke coil to manifold, and remove choke coil and choke rod as an assembly. Disconnect choke rod from choke coil. Connect choke rod to new choke coil and install assembly on manifold. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 2 6 E N G IN E FUEL 5. Install bolt and tighten securely. 6 . Adjust and connect choke rod as outlined. 7. Start and warm-up the engine then check operation of choke and install air cleaner. V8 Engines (Figs. K2-K3) 1. Remove air cleaner and disconnect choke rod upper clip. 2. Remove choke coil as follows: WITH ROCHESTER 4MV AND 2GV CARBURETORS Remove the choke coil shield by prying with a screw driver on the small tangs at base of shield, then lift shield carefully over rod. Remove choke rod, bracket screw and choke coil assembly. 3. Install a new choke coil assembly being sure the locator is in the hole of the intake manifold and install mounting screw. 4. Complete installation as follows: WITH ROCHESTER 4MV AND 2GV CARBURETORS Install the choke rod and adjust as necessary (without choke coil shield installed). Disconnect choke rod upper end and lower choke coil shield over choke rod and install over choke coil. 5. Be sure choke valve moves freely from full open to full closed position. 6 . Start and warm up the engine and check operation of the choke. 7. Install the air cleaner. ON-THE-VEHICLE ADJUSTMENTS Final curb idle and fast idle settings should be made on the vehicle using a tachometer. All idle speeds in 1973 are to be set with the air conditioning in the OFF position unless otherwise indicated. Idle speed and mixture settings must be made with the air cleaner installed. Warm engine to normal operating tem pera­ ture, choke valve and thermostatic air cleaner valve must be in full open positions. Idle settings must follow procedure shown on the, "Vehicle Emission Control Inform ation" sticker, sometimes referred to as tuneup sticker. ADDITIONAL EXTERNAL SETTINGS AND ADJUSTMENTS All Vehicles After carburetor overhaul, throttle body part replace­ ment, mixture needle part replacement, or limiter cap and needle removal for any reason, the below procedures must be followed: 1. Refer to Vehicle Emission Control Information Sticker, sometimes referred to as tuneup sticker, (also see Section 6 , Tuneup) before proceeding: CAUTION: After following the below proce­ dure, always double check and set specifications which agree with latest certified information on Vehicle Emission Control (tuneup) Information sticker. 2. Turn mixture screw in until it lightly contacts seat, then back screws out four (4) full turns. 3. Adjust idle stop solenoid or carburetor speed screw to obtain, "initial curb idle speed", see "Other Adjustments" Speci­ fications chart in back of this M anual Column No. 1. 4. Adjust mixture screw as follows: a. Adjust mixture screws equally (in) to idle speed specified by specifications in Column No. 2. b. When 1/4 turn rich from lean roll is specified, turn mixture screw equally (in) leaner to a drop of 20 RPM then turn mixture screw 1/4 turn rich (out). Set final idle speed to RMP under "Other Adjustments" in Specifications chart in back of this Section - Column No. 2. 5. Install service "M ixture Needle Limiter Caps" on mixture screws. 6 . Reconnect distributor vacuum hose and fuel tank vapor hose. IDLE STOP SOLENOID (CURB IDLE-LOW IDLE) ADJUSTMENT With engine at normal operating temperature, air cleaner installed, choke open, and air conditioning off, if so equipped. CAUTION: Set parking brakes and block the drive wheels. 1. Disconnect fuel tank hose vapor canister. 2. Disconnect distributor vacuum hose at the distrib­ utor. Plug hose lead-to carburetor. 3. With engine running; ONE BARREL CARBURETORS CAUTION: During adjustment, do not turn the solenoid more than one complete turn without first disconnecting the electrical wiring. a. Turn the solenoid clockwise to increase RPM, counterclockwise to decrease RPM. Refer to Specifications, Section 6 M, under "O ther Ad­ justments", column No. 2, for curb idle speed (Idle Stop Solenoid-Energized). b. Set low idle speed (with solenoid de-energized) to 450 RPM by using an alien head wrench (located at the end of this solenoid). Turn to adjust. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL TWO BARREL AND FOUR BARREL CAR­ BURETORS a. Disconnect electrical connection at the end of the idle stop solenoid. b. Adjust carburetors low idle (Adjustment screw on low step of cam) to Specifications in Column No. 2, Note (3). 6M -27 c. Set dwell and timing and recheck low idle speed. d. Reconnect electrical connector to the solenoid. Open the throttle momentarily and adjust the solenoid plunger screw to the specified curb idle speed (RPM). See Specifications, Section 6 M, under "Other Adjustments". ACCELERATOR AND CHOKE CONTROLS THROTTLE LINKAGE (Fig. K5 thru K18) The throttle control system is of the cable type. There are no throttle linkage adjustments, a reference between the bottom of the accelerator pedal roller and floor pan should be used only as a check for bent bracket assemblies. Check torque references in Figures K5 thru K18. Check for correct opening and closing positions by operating accelerator pedal in car. Cable routing attachment, carburetor positioning for proper assembly should be noted by some of the following illustrations. NOTE: If any binding is present, check for correct routing of cable or pedal interference with carpets. THROTTLE ROD KICKDOWN LINKAGE ADJUSTMENT 1. Disconnect throttle rod swivel at throttle lever on carburetor or at dash lever. NOTE: Cable controls do not require adjustment. 2. On automatic transm ission equipped vehicles disconnect TV rod at throttle lever. 3. Hold carburetor throttle in wide open position, push throttle rod rearward (to position accelerator pedal at the floor mat) and adjust swivel to just enter hole in throttle lever. 4. Connect swivel to throttle lever and install accelerator return spring. 5. On vehicles equipped with automatic transmission hold throttle lever in full open position, pull TV rod to full detent position and adjust TV rod to just enter hole on throttle lever, and connect TV rod at throttle lever. Fig. K 5 -A c c e le r a to r C o n tro ls , C S a n d KS 1 0 th ru 3 0 S e rie s LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 2 8 E N G IN E FUEL SUPPORT STUD—TORQUE^ DETENT CABLE Fig. K 6 --A c c e le ra to r C o n tro ls a n d C ab le , CS a n d KS LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E FUEL 6M -29 CARBURETOR LEVER COTTER P IN - LOCK WASHER TORQUE AT 120 IN. LBS. CABLE ASSEMBLY PLAIN LEVER WASHER ASSEMBLY ROD ASSEMBLY LEVER ASSEMBLY PLAIN WASHER COTTER pIN | \ CARBURETOR LEVER TORQUE AT 65 IN. LBS. LOCK WASHER p in 1v i e w | A Fig. K 9 -A c c e le r a to r C o n tro ls P 1 0 ( 4 2 ) S e rie s w / 3 0 7 e n g in e LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 3 0 ENGINE FUEL SUPPORT CABLE ASSEMBLY TORQUE AT 65 IN. LBS. CARBURETOR LEVER SPRING (T V IE W LEVER ASSEMBLY ^ X CABLE ASSEMBLY J p ^ If) n f l 1 r_, t in n r*£ l O ^ I^ C A R B U R E T O R BRACKET ASSEMBLY1 / (v ie w \ B O y CARBURETOR LEVER .SUPPORT CABLE ASSEMBLY Fig. K1 l--Accelerator Controls - P30(32) Models Fig. K12—Accelerator Controls, P20-30 (42) 350 Engine LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6 M -31 Fig. K13—Accelerator Controls, P30 (42) 454 Engine LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 3 2 ENGINE FUEL Fig. K15—Accelerator Controls - G-Van (L-6) LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -33 CAUTION Care must be taken during installation of Retainer onto Accelerator Cable and the proper attention must be made to press the Retainer into hole on Rod to assure the Cable is not "KINKED" or "DAMAGED" in any way. VIEW A > FWD Fig. K17—Accelerator Pedal and Controls, C, K P10 thru 30 Series Fig. K18—Accelerator Controls (Manual Throttle) C-K AIR CLEANERS INDEX General Description.......................................................... 6M-33 Maintenance and Service Procedures........................ 6M-34 Element Replacement ....................................................6M-36 Part Replacement.............................................................6M-37 GENERAL DESCRIPTION Air cleaners on all models operate primarily to remove dust and dirt from air before it is drawn into the carburetor and engine. The air cleaner also helps to reduce engine noist and quenches any flame that my be caused by engine backfiring through the carburetors. Two types or air cleaners are used on trucks. They are the oil wetted paper element air cleaner, and the poly­ wrap element air cleaner. The oil wetted paper element air cleaner (fig. 1A) consists of an accordian pleated oiled paper filter supported by wire mesh with a plastisol seal on both top and bottom The polywrap element air cleaner consists of a paper element in addition to a polyurethane band. Air temperature is automatically controlled by a thermostatic valve which selects warmed air from the heat stove and /o r cooler air from the engine compartment or from outside the vehicle. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 3 4 ENGINE FUEL AIR CLEANER B O TTO M ARRESTOR ASSEMBLY ■ ■- r f1 W lE W A Fig. 2A -Engine Ventilation, (L-6) ELEMENT C O VE R Fig. 1A -Paper Element Air Cleaner M AINTENA N CE A N D SERVICE CARBURETOR AIR CLEANER ELEMENT-Under normal operating conditions, the carburetor air cleaner should be replaced every 24.000 rmles on V -8 engines and 12.000 miles on L-6 engines. Operation of vehicle in dusty areas will cause rapid clogging or element and enrichment of carburetor mixture. Under these condtions, the element must be replaced more frequently. THERMOSTATICALLY CONTROLLED AIR CLEANER-The air cleaner should be inspected to make certain that all hoses and ducts are intact and correctly AIR CLEANER W IN G N U T ----------TO RQ UE AT 2 0 IN . LBS. AIR L CLEANER CHAMFER END RETAINER \ GaSKET STUD TO RQ UE AT (1 7 IN . LBS.) EXTENSIO N ' SUPPORT , GASKET TO RQ UE AT 25 IN . LBS. STUD OIL LEVEL G A G E TUBE GASKET SUPPORT NOTE Colored adhesive TU B E "'"'^ ASSEMBLY S T U D -T O R Q U E AT 2 0 IN . LBS. TORQUE SEQUENCE FOR L-6 AIR CLEANER AND SUPPORT. AIR CLEANER HOSE 1. Secure W in g N u t to required to rq ue (1 7 IN . LBS.) 2 . Secure W in g N u t [2 ] to required to rque (1 7 IN . LBS.) 3. Secure Bolts [ 3 ] (a ttac h in g A ir C leaner Support) to required to rque (2 5 FT. LBS.) surface to carburetor, CH O K E ASSEMBLY 1 NOTE 1 Boss on choke into inboard hole. . r. PLATE ' ASSEMBLY TO AIR CLEANER L-6 Fig. 3A-Air Cleaner and Heat Stove, Truck (Base L6 and V8) except P and G Series LIGHT DUTY TRUCK SERVICE MANUAL W IN G NUT TO R Q U E AT 2 0 IN. LBS. AIR C LEA N ER G A S K E T IN O TEI Colored adhesive surface to carburetor STUD TO R Q U E AT 2 0 IN. LBS. TO RQ U E AT 75 IN. LBS. TO R Q U E AT 7 5 IN. LBS. TO R Q U E AT 75 IN. LBS. T O R Q U E AT 75 IN. LBS. CARBU RETO R A SSEM B LY CARBURETO R A SSEM B LY IN SU LA TO R M 49 3 SPEED A / T R A N S M 38 3 SPEED A / T R A N S C B C LS9 V 8 E N G IN E 3 5 0 C ID M 4 9 3 SPEED A / T R A N S . LF8 V 8 E N G IN E 4 5 4 C ID TO R Q U E AT 25 IN. LBS. TO RQ U E AT 25 IN. LBS. AIR C LE A N E R H O S E N O TE Choke cover screw to be tightened Jn^place prior to carburetor installation AIR C LE A N E R H O S E # CHOKE A SSEM B LY C H O K E A SSEM B LY N O TE Boss on choke into inboard hole. Lx— 1& ^ \ ^ V IE W V IE W Fig. 4A--Carburetor, Air Cleaner and Choke, C-K Series RETAINER N O TE Boss on choke into outboard hole. 6 M - 3 6 ENGINE FUEL -t o air ^ 17 IN. LBS. TORQUE END u A.W3SjV STUD (17 IN. LBS.) V y« CARBURETOR SUPPORT OIL LEVEL GAGE TUBE V VIEW A VIEW B 10-15__________> STUD EXTENSION GASKET AIR CLEANER __J COIL EXTENSION GASKET TUBE ASSEMBLY I NOTE I Position red (adhesive) surface dow n. g STUD A STUD C SUPPORT TORQUE SEQUENCE FOR L-6 AIR CLEANER AND SUPPORT. TO AIR CLEANER 1. Secure W in g N ut Q ] to required torque (17 IN. LBS.) \ LOCK WASHER 2. Secure W in g N u t [ T |t o required torque (17 IN. LBS.) 3. Secure Bolts (atta ch in g A ir Cleaner Support) to required torque (25 FT. LBS.) PLATE ASSEMBLY / CAP CARBURETOR TO AIR CLEANER L-6 V VIEW C GE 20-30 Fig. 5A Air Cleaner and Heat Stove G-Van L-6 and V-8 installed. Operational function should be checked by inspecting position of valve in air intake. With engine stopped, valve should be open. At underhood tem pera­ ture below 100 degrees F, with engine running, valve should be partially or fully closed. As engine underhood temperature rises, the valve should open. PAPER ELEMENT REPLACEMENT (PAPER FILTER ONLY) 1. 2. 3. 4. NOTE: See below part replacement. Remove air cleaner cover. Remove element. Disconnect vacuum signal hose and CCV hose. Discard air cleaner element and gasket. Clean bottom section of air cleaner, gasket surfaces and air cleaner cover thoroughly. NOTE: Check air cleaner cover seal for tears or cracks. 5. Install bottom section of air cleaner with a new air cleaner gasket. Align heat stove tube. 6 . Install new paper element in bottom section of air cleaner with either end up. 7. Install air cleaner cover. (Do not over-torque wing nut). LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -37 AIR CLEANER STUD OIL GAGE TUBE ASM OIL GAGE TUBE SUPPORT — PS100-150(35) PS200-250 NOTE Stud must ASM UPC 6Y V be installed with chamber end up. EXTENSION VIEW A NOTE Position red adhesive surface down when installing gaskets. ^ FWD /O U R CLEANER PS100-150 PS MODELS Fig. 7A~Air Cleaner and Heat Stove, P Series POLYWRAP ELEMENT REPLACEMENT (PAPER FILTER WITH POLYURETHANE BAND) NOTE: See below part replacement. The replacement period for the polywrap paper element is the same as for the above "paper element only". However, each time the polywrap paper element is replaced, also, the polyurethane band should be cleaned, as outlined below, inspect and reoil or replace. 5. Install the polyurethane band around the outer surface of the paper filter (Fig. 9A). PART REPLACEMENT It should be noted that different type paper elements are used; one with the polyurethane band and another type used for paper element replacement without a polyure­ thane band. Cleaning the Polyurethane Band 1. Remove the polyurethane band from the paper filter. 2. If not torn, wash the polyirethane band in kerosene or mineral spirits then squeeze out excess solvent (as dry as possible) (Fig. 8 A). NOTE: Never use a hot degreaser or any solvent containing acetone or similar solvent; also, never shake, swing or wring the element to remove excess solvent as this may tear the polyirethane material. Instead, "squeeze" the excess solvent from the element. 3. Inspect the polywrap band for tears and replace if necessary. 4. Dip the band into light engine oil and squeeze out excess oil. Fig. 8A—Cleaning the Polyurethane Band LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 3 8 ENGINE FUEL W IN G J s lU T T O R Q U E A T 2 0 LBS. IN I NOTE I Polyurethane Band must wrap over both end seals of paper element as shown. POLYW RApZjL^^. AIR C LE AN ER ELEM ENT completely cover the outer screen surface of paper element as shown. BAND S H O W N ). PAPER FILTER P O R T IO N O F P O L Y W R A P AIR C LE A N E R ELEM ENT Fig. 9A—Installing the Polyurethane Band THERMOSTATICALLY CONTROLLED AIR CLEANER This system (fig. 10A and 11 A) is designed to improve carburetor operation and engine warm-up characteristics. It achieves this by keeping the air entering the carburetor at a temperature of at least 100 degrees F or more. The thermostatic air cleaner system includes a temperature sensor, a vacuum motor, and control damper assembly mounted in the air cleaner, vacuum control hoses, manifold heat stove and connecting pipes. The vacuum motor is controlled by the temperature sensor. The vacuum motor operated the air control damper assembly to regulate the flow of hot air and underhood air to carburetor. The hot air is obtained from the heat stove on the exhaust manifold. Inspecti on-Visual 1. Check for proper and secure connections of heat pipe and hoses. 2. Check for kinked or deteriorated hoses. Repair or replace as required. Operational 1. Remove air cleaner cover and install temperature gauge (Tool J-22973) as close as possible to sensor ( % 12A). Reinstall cover without wing nut. (Temperature must be below 85 degrees F before proceeding). 2. With the engine "O FF", observe damper door position through snorkel opening. Snorkel passage should be open. Fig. 11 A, View A. If not, check for binds in linkage. 3. Start and idle engine. W ith air temperature below 85 degrees F, snorkel passage should be closed. Fig. 11 A,View B. When dam per door begins to open snorkel passage, remove air cleaner cover and observe thermometer reading. It should be between 85 degrees F and 115 degrees F. 4. If damper door does not close completely or does not open at correct temperature, continue with the following vacuum motor check: a. Turn off engine. Disconnect diaphragm assem­ bly vacuum hose at sensor unit. b. Apply at least 9 in. Hg. of vacuum to diaphragm assembly through the hose. This can be done by mouth. Damper door should completely close snorkel passage when vacuum is applied. If not check to see if linkage is hooked up coorectly and for a vacuum lean. c. With vacuum applied, bend or clamp hose to trap vacuum in diaphragm assembly (fig. 13A). Damper door should remain in position (closed snorkel passage). If it does not, there is a vacuum leak in daiphragm assembly. Replace diaphragm assembly. 5. If vacuum motor check is found satisfactory, replace sensor unit. VACUUM MOTOR REPLACEMENT Removal 1. Remove air cleaner from engine. 2. Drill out spot welds fastening vacuum motor retaining strap to snorkel tube. 3. Remove vacuum motor by lifting and unhooking linkage rod from damper door. Replacement 1. Drill 7/64" hole in snorkel tube at center of vacuum motor retaining strap (fig. 14A). 2. Connect vacuum motor linkage to dam per door. Fasten retaining strap to air cleaner with sheet metal screw. 3. Replace air cleaner on engine and check operation of vacuum motor and control dam per assembly. TEMPERATURE SENSOR REPLACEMENT Removal 1. Remove air cleaner from engine and disconnect vacuum hose at sensor. 2. Pry up tabs of sensor retaining clip (fig. 15A). NOTE: Observe position of sensor, new sensor must be installed in this same position. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -39 Fig. lOA-Thermostatically Controlled Air Cleaner VIEW B -U N D E R H O O D TEMPERATURE BELOW 85°F VIEW A —ENGINE OFF AIR BLEED VALVE . CLOSED DIAPHRAGM SPRING DIAPHRAGM SPRING SNORKEL TUBE VACUUM CHAMBER SNORKEL TUBE ■^1 LINKAGE r DIAPHRAGM DIAPHRAGM HL. \ CONTROL DAMPER ASSM. CONTROL DAMPER ASSM. 1 | j VIEW D -U N D E R H O O D TEMPERATURE BETWEEN 85°F AND 128°F AIR BLEED VALVE OPEN DIAPHRAGM SPRING VACUUM CHAMBER LINKAGE AIR INLET AIR BLEED VALVE DIAPHRAGM SPRING VACUUM CHAMBER TEMP. SENSING SPRING SNORKEL TUBE DIAPHRAGM AIR INLET S' CONTROL DAMPER ASSM. HOT AIR PIPE HOT AIR PIPE VIEW C— UNDERHOOD TEMPERATURE ABOVE 128°F SNORKEL TUBE TEMP. SENSING SPRING VACUUM CHAMBER ■HOT AIR PIPE CONTROL DAMPER ASSM HOT AIR PIPE Fig. 11A--Air Cleaner Operation TOOL J-22973 Fig. 12A--Temperature Gauge Installation Fig. 13A -Checking Vacuum Diaphragm LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 0 ENGINE FUEL 3. Remove clip and sensor from air cleaner. Replacement 1. Install sensor and gasket assembly in air cleaner in position as noted above. 2. Press retaining clip on sensor. Support the sensor on its side to prevent damage to the control mechanism in the center. 3. Install air cleaner on engine and connect vacuum hoses. DRILL 7 /6 4 " HOLE IN CENTER POSITION OF STRAP SPOTWELDS VACUUM DIAPHRAGM RETAINING STRAP INSTALL REPLACEMENT SENSOR ASSM. IN SAME POSITION AS ORIGINAL ASSM. Fig. 14A-Vacuum Diaphragm Replacement Fig. 15A--Removing Sensor Unit FUEL PUMP INDEX General Description..........................................................6M-40 Test..................................................................................6M-40 Service Procedures............................................................. 6M-40 Removal........................................................................ 6M-41 Inspection.........................................................................6M-40 Installation.................................................................... 6M-41 GENERAL DESCRIPTION The fuel pump (fig. IP and 2P) used on all vehicles covered in this manual is the diaphragm type. The pump is actuated by an eccentric located on the engine camshaft. On in-line engine, the eccentric actuates the rocker arm. On V-8 engines, a push rod (located between the camshaft eccentric and fuel pump) actuates the pump rocker arm. Because of design, this pump is serviced as an assembly only. INSPECTION The fuel pump (fig. 3P) should be checked to make sure the mounting bolts and inlet and outlet connections are tight. TEST Always test pump while it is mounted on the engine and be sure there is gasoline in the tank. The larger line from the tank to the pump is the suction side of the system and the line from the pump to the carburetor is the pressure side of the system. A leak on the pressure side, therefore, would be made apparent by dripping fuel, but a leak on the suction would not be apparent except for its effect of reducing volume of fuel on the pressure side. 1. Tighten any loose line connections and look for bends or kinks in lines. 2. Disconnect fuel pipe at carburetor. Disconnect distributor to coil primary wire so that engine can be cranked without firing. Place suitable container at end of pipe and crank engine a few revolutions. If little or no gasoline flows from open end of pipe then fuel pipe is clogged or pump is inoperative. Before removing pump disconnect fuel pipe at gas tank and outlet pipe and blow through them with an air hose to make sure they are clear. Reconnect pipes and retest while cranking engine. CAUTION: Whenever the engine is cranked re­ motely at the starter, with a specialjumper cable or other means the distributor primary lead must be disconnected from the negativepost on the coil and the ignition switch must be in the “O N ”posi­ tion. Failure to do this will result in a damaged grounding circuitin the ignition switch. 3. If fuel flows from pump in good volume from pipe at carburetor, check fuel delivery pressure to be certain that pump is operating within specified limits as follows: LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6 M -41 Fig. 2P--Fuel Pump and Pipe, V-8 a. Attach a fuel pump pressure test gauge to disconnect end of pipe. b. Run engine at approximately 450-1,000 rpm .(on gasoline in carburetor bowl) and note reading on pressure gauge. c. If pump is operating properly the pressure will be within specifications and will remain constant at speeds between 450-1,000 rpm. If pressure is too low, too high, or varies significantly at different speeds, the pump should be replaced. REMOVAL NOTE: When connecting fuel pump outlet pipe fitting always double wrench to avoid possible damage of pump. 1. Disconnect fuel inlet and outlet pipes at fuel pump. 2. Remove fuel pump mounting bolts and remove pump and gasket. 3 . On V8 engines if push rod is to be removed, remove pipe plug and push rod (454 cu. in. engines), and fuel pump adapter and gasket and push rod (307, 350 and 400 cu. in. engines). Fig. 3P--Fuel Pump (Non-Serviceable) INSTALLATION 1. On V 8 engines, if fuel pump push rod has been removed, install push rod and pipe fitting or fuel pump adapter using gasket sealer on gasket or pipe fitting. 2. Install fuel pump using a new gasket and tighten securely. Use sealer on fuel pump mounting bolt threads. NOTE: On V 8 engines, a pair of mechanical fingers or heavy grease may be used to hold fuel pump push rod while installing fuel pump (fig. 4P). 3. Connect fuel pipes to pump. 4. Start engine and check for leaks. LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 2 ENGINE FUEL Fig. 4P--lnstalling V-8 Engine Fuel Pump CARBURETOR DIAGNOSIS MODELS M , M V -2 G , 2 G V -4 M , 4M V . INDEX Rochester Monojet (1 bbl.) C arburetor.................. 6M-43 Rochester 2GV (2 bbl.) C arburetor......................... 6M-51 Rochester 4MV (4 bbl.) Carburetor......................... 6M-58 Fuel Pum p......................................................................... 6 M-66 PROPER CARBURETOR OPERATION IS DEPENDENT UPON THE FOLLOWING 1. 2. 3. 4. 5. 6. 7. 8. Fuel Supply Linkage and emission control systems. Engine compression. Ignition system firing voltage Ignition spark timing Secure intake manifold Engine temperature Carburetor adjustments ANY PROBLEMS IN THE ABOVE AREAS CAN CAUSE THE FOLLOWING 1. 2. 3. 4. 5. 6. 7. No start or hard starting - (hot or cold) Rough engine idle and stalling Hesitation on acceleration Loss of power on acceleration and top speed Engine to run uneven or surge Poor fuel economy Excessive emissions BEFORE PROCEEDING WITH CARBURETOR DIAGNOSIS, CHECK THE PRECEDING ITEMS FIRST. 1 LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -43 ROCHESTER CARBURETOR DIAGNOSIS MODELS M , M V - 2 G , 2 G V - 4 M , 4 M V . NOTE: These problems can be caused by many things other than carburetor. Check the following engine tune-up items before proceeding w ith carburetor items. Engine compression, spark plugs, ignition point gap and condition, ignition timing, fuel pump pressure and volume, plugged fuel filters or fuel lines and intake manifold for vacumn ieaks. Make sure all emission control parts are installed and operating properly. This includes all emission systems solenoids and hoses where used. Problems o f roughness slight hesitation, surge or poor fuel economy should not be diagnosed before an allowable engine break in period. Problem: _____________________________________________________________________________ ALL MODELS M , M V - SINGLE BARREL E N G IN E C R A N K S (T U R N S O V E R ) W IL L N O T S T A R T OR S T A R T S H A R D W H E N C O L D . POSSIBLE CAUSE Improper starting procedure used. Check w ith the customer to determine if proper starting procedure is used, as outlined in the owner's manual. No fuel in gas tank Add fuel. Check fuel gauge for prosper operation. Choke valve not closing sufficiently when cold. Adjust the choke thermostatic coil. Use procedure H or I. Choke valve or linkage binding or sticking. Realign the choke valve or linkage as necessary. If caused by d irt and gum, clean w ith automatic choke cleaner. Do not oil choke linkage. If parts are replaced, check adjustments using procedure D, E or F. No fuel in carburetor. 1. Remove fuel line at carburetor. Connect hose to fuel line and run into metal container. Remove the high tension coil wire from center tower on distributor cap and ground. Crank over engine — if there is no fuel discharge from the fuel line, check fo r kinked or bent lines. Disconnect fuel line at tank and blow out w ith air hose, reconnect line and check again for fuel dis­ charge. If none, replace fuel pump. Check pump for adequate flow, as outlined in service manual. 2. If fuel supply is o.k., check the following: a. Inspect fuel filters. If plugged replace. b. If filters are o.k., remove air horn and check fo r a bind in the float mechanism or a sticking float needle. If o.k., adjust float as specified. Use proce­ dure A. Check to determine if customer is using proper carbu­ retor unloading procedure. Depress the accelerator to the floor and check the carburetor to determine if the choke valve is opening. If not, adjust the th ro ttle link­ age and unloader, as specified. Use procedure G. Engine Flooded. NOTE: To check for flooding, remove the air cleaner, with the engine off, and look into the carburetor bores. Fuel w ill be dripping o ff nozzles and/or the carburetor w ill be very wet. NOTE: Before removing the carburetor air horn, use the following procedure which may eliminate the flooding. Carburetor flooding 1. Remove the fuel line at the carburetor and plug. Crank and run the engine until the fuel bowl runs dry. Turn o ff the engine and connect fuel line. Then re-start and run engine. This w ill usually flush d irt past the carbu­ retor float needle and seat. 2. If d irt is in fuel system, clean the system and replace fuel filters as necessary. If excessive d irt is found, re­ move the carburetor unit. Disassemble and clean. 1 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 4 ENGINE FUEL ROCHESTER CARBURETOR DIAGNOSIS - MODELS M, MV POSSIBLE CAUSE CORRECTIVE ACTION Carburetor flooding (continued) 3. Check float needle and seat for proper seal. If a needle and seat tester is not available, apply mouth suction to the needle seat w ith needle installed. If the needle is defective, replace w ith a factory matched set. 4. Check float for being loaded w ith fuel, bent float hanger or binds in the float arm. NOTE: A solid float can be checked fo r fuel absorption by lightly squeezing between fingers. If wetness appears on surface or float feels heavy (Check w ith known good float), replace the float assembly. 5. Adjust float. Problem: e n g in e starts a n d Use procedure A. stalls Engine does not have enough fast idle speed when cold. Check and re-set the fast idle setting and fast idle cam. Use procedure C and D. Choke vacuum break unit is not adjusted to specification or unit is defective. 1. Adjust vacuum break to specification. Use procedure E or F. 2. If adjusted O.K., check the vacuum break fo r proper operation as follows: On the externally mounted vacuum break unit, connect a piece o f hose to the nipple on the vacuum break unit and apply suction by mouth or use tool J-23417 to appiy vacuum. Plunger should move inward and hold vacuum. If not, replace the unit. On the integral vacuum break unit remove cover and visual­ ly check diaphragm and vacuum channel. If diaphragm is leaking, replace. NOTE: Always check the fast idle cam adjustment before adjusting vacuum break unit. Use procedure D. Choke coil rod out of adjustment. Adjust choke coil rod. Use procedure H or I. Choke valve and/or linkage sticking or binding. 1. Clean and align choke valve and linkage. necessary. Replace if 2. Re-adjust if part replacement is necessary. Use procedure D, E or F. Idle speed setting Adjust idle speed to specifications on decal in engine com­ partment. Not enough fuel in carburetor. 1. Check fuel pump pressure and volume. 2. Check for partially plugged fuel inlet filter. dirty. Replace if 3. Remove air horn and check float adjustments. procedure A. Carburetor flooding. Use 1. Check float needle and seat fo r proper seal. If a needle and seat tester is not available, mouth suction can be applied to the needle seat w ith needle installed. If needle is defective, replace w ith a factory matched set. NOTE: Check by using procedure outlined under carbu­ retor flooding. Page 1. 2. Check float fo r being loaded w ith fuel, bent float hanger or binds in the float arm. 2 LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL ROCHESTER CARBURETOR DIAGNOSIS - 6M -45 MODELS M, MV CORRECTIVE ACTION POSSIBLE CAUSE Carburetor flooding (continued) NOTE: A solid float can be checked fo r fuel absorption by lightly squeezing between fingers. If wetness appears on surface or float feels heavy (check w ith known good float, replace the float assembly. 3. Check float adjustments. Use procedure A. 4. If excessive d irt is found in the carburetor, clean the fuel system and carburetor. Replace fuel filters as necessary. P roblem : E N G IN E ID L E S R O U G H A N D S T A L L S Idle speed setting. Re-set idle speed per instructions on decal in engine compartment. Manifold vacuum hoses disconnected or improperly in­ stalled. Check all vacuum hoses leading into the manifold or carburetor base fo r leaks or being disconnected. Install or replace as necessary. Carburetor loose on intake manifold. Torque Intake manifold is loose or gaskets are defective. Using a pressure oil can, spray light oil or kerosene around manifold legs and carburetor base. If engine RPM changes, tighten or replace the manifold gaskets or carburetor base gaskets as necessary. Hot idle compensator not operating (where used.) Normally the hot idle compensator should be closed when engine is running cold and open when engine is hot (approx. 140°F at comp.) replace if defective. Carburetor flooding. NOTE: Check by using procedure outlined under "carbu­ retor flooding” , page 1. 1. Remove air horn and check float adjustment. procedure A. carburetor to manifold bolts (10-14 ft. lbs.). Use 2. Check float needle and seat for proper seal. If a needle and seat tester is not available, mouth suction can be applied to the needle seat w ith needle installed. If the needle is defective, replace w ith a factory matched set. 3. Check float for being loaded w ith fuel, bent float hanger or binds in the float arm. NOTE: lightly surface replace A solid float can be checked fo r fuel absorption by squeezing between fingers. If wetness appears on or float feels heavy (check w ith known good float), the float assembly. 4. If excessive d irt is found in the carburetor, clean the fuel system and carburetor. Replace fuel filters as necessary. Problem: E N G IN E H E S IT A T E S O N A C C E L E R A T IO N 1. Remove air horn and check pump cup. If cracked, scored or distorted, replace the pump plunger. Defective accelerator pump system NOTE: A quick check of the pump system can be made as follows. With the engine o ff, remove air cleaner and look into the carburetor bores and observe pump stream, while briskly opening throttle valve. A full stream of fuel should emit from pump jet and strike near the center o f the venturi area. 2. Check the pump discharge ball fo r proper seating and location. The pump discharge ball is located in a cavity next to the pump well. To check fo r proper seating, remove air horn and gasket and fill cavity w ith fuel. No "leak dow n" should occur. Restake and replace check ball if leaking. Make sure discharge ball, spring, and re­ tainer are properly installed. 3 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 6 ENGINE FUEL MODELS M, MV ROCHESTER CARBURETOR DIAGNOSIS PO SSIBLE CAUSE C O R R E C T IV E ACTION D irt in pump passages or pump jet. Clean and Blow out with compressed air. Fuel level. Check fo r sticking float needle or binding float. Free up or replace parts as necessary. Check and reset float level to specification. Use procedure A. Leaking air horn to float bowl gasket. Torque air horn to float bowl using proper tightening procedure. Use procedure J. Carburetor loose on manifold. Torque carburetor to manifold bolts. (10-14 ft. lbs.). Problem: NO POWER ON H E A V Y A C C E L E R A T IO N O R A T H IG H SP EE D Carburetor th ro ttle valve not going wide open. by pushing accelerator pedal to floor). (Check Adjust th ro ttle linkage to obtain wide open throttle in carburetor. D irty or plugged fuel filters. Replace w ith a new filte r element. Power system not operating. Check power piston fo r free up and down movement. If power piston is sticking check power piston and cavity for dirt, or scores. Check power piston spring for dis­ tortion. Clean or replace as necessary. Metering rod not adjusted to specification. Adjust metering rod. Use procedure B. Float level too low. 1. Check and reset float level to specification. procedure A. Float not dropping far enough into float bowl. Check fo r binding float hanger and fo r proper float align­ ment in float bowl. Main metering jet or metering rod d irty, plugged or in­ correct part. 1. If the main metering jets are plugged or d irty and exces­ sive d irt is in the fuel bowl. The carburetor should be completely disassembled and cleaned. Use 2. Check the jet or rod for being the correct part. Consult the parts list for proper usage. The last two digits stamped on the jet face are the same as the last two digits of the part number. The metering jet and rod can be identified using chart. Use procedure K. Problem: e n g in e starts ha r d w hen hot 1. Check for binding choke valve and/or linkage. and free-up or replace parts as necessary. Do not oil choke linkage. Choke valve not opening completely. Clean 2. Check and adjust choke thermostatic coil. Use procedure FI or I. Engine flooded - Carburetor flooding. See procedure under "Engine cranks, w ill not start” . Pg. 1 No fuel in carburetor. 1. Check fuel pump. Run pressure and volume test. 2. Check float needle fo r sticking in seat, or binding float. Fill bowl w ith fuel and look for leaks. Leaking float bowl. 4 LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL ROCHESTER CARBURETOR DIAGNOSIS Problem : e n g in e runs - u n even 6M -47 MODELS M, MV or PO SSIBLE CAUSE surges C O R R E C T IV E ACTION Fuel Restriction Check all hoses and fuel lines for bends, kinks or leaks. Straighten and secure in position. Check all fuel filters. If plugged or d irty - replace. D irt or water in fuel system. Clean fuel tank and lines. Fuel level Adjust float. Use procedure A. Check for free float and float needle valve operation. Main metering rod not adjusted to specification. Remove carburetor air horn and gasket. rod. Use procedure B. Metering rod bent or incorrect part. defective, loose or incorrect part. Replace as necessary. See identification chart. Use procedure B and K. Main metering jet Remove and clean carburetor. Adjust metering Power system in carburetor not functioning properly. Power valve or piston sticking in down position. Free up or replace as necessary. Vacuum leakage It is absolutely necessary that all vacuum hoses and gaskets are properly installed, w ith no air leaks. The carburetor and manifold should be evenly tightened to specified torque. Problem: poor fuel eco no m y Engine needs complete tune-up. Check engine compression. Examine spark plugs, (if d irty or improperly gapped, clean and re-gap or replace). Check ignition point dwell, condition, readjust ignition points if necessary and check and reset ignition timing. Clean or replace air cleaner element if d irty. Check fo r restricted exhaust system and intake manifold fo r leakage, make sure all vacuum hoses are connected correctly. Make sure T.C.S. and C.E.C. valves are operating properly. Choke valve not fu lly opening. 1. Clean choke and free up linkage. 2. Check choke coil for proper adjustment. Reset to speci­ fications. Use procedure H or I. Fuel leaks. Check fuel tank, fuel lines and fuel pump for any fuel leakage. Main metering rod not adjusted to specification. Remove carburetor air horn and gasket. Adjust metering rod. Use procedure B. Metering rod bent or incorrect part. defective, loose or incorrect part. Replace as necessary. procedure B and K. Main metering jet See identification chart. Use Power system in carburetor not functioning properly. Power valve or piston sticking in up position. Free up or replace as necessary. High fuel level in carburetor or carburetor flooding. 1. Check for d irt in the needle and seat. Test using suction by mouth or needle seat tester. If defective, replace needle and seat assembly w ith factory matched set. 2. Check fo r loaded float. 3. Re-set carburetor float to specifications. Use procedure A. 4. If excessive d irt is present in the carburetor bowl, the carburetor should be cleaned. 5 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 4 8 ENGINE FUEL ROCHESTER CARBURETOR DIAGNOSIS - MODELS M, MV POSSIBLE CAUSE CORRECTIVE ACTION Fuel being pulled from accelerator system into venturi through pump jet. Run engine at RPM where nozzle is feeding fuel. Observe pump jet. If fuel is feeding from jet, check pump discharge ball fo r proper seating by fillin g cavity above ball with fuel to level of casting. No "leak dow n" should occur w ith discharge ball in place. Re-stake or replace leaking check ball, defective spring, or retainer. A ir bleeds or fuel passages in carburetor d irty or plugged. Clean carburetor or overhaul as necessary. LIGHT DUTY TRUCK SERVICE MANUAL 6 SERVICE PROCEDURES - EN G IN E FUEL MODELS M, MV D W ITH G A S K E T R E M O V E D , G A U G E FR O M TOP OF C A S T IN G TO TOP OF IN D E X P O IN T A T TOE OF F L O A T © (3 ) BEND H ERE TO A D JU ST FL O A T UP OR DOWN 6M -49 G A U G E BETW EEN LOW ER EDGE OF C HO KE V A L V E A N D " IN S ID E A IR H O R N W A L L H O L D DOWN ON C HO KE VALVE W ITH R O D IN E N D OF SLO T H O LD F L O A T R E T A IN IN G PIN F IR M L Y IN PLACE PUSH DOWN ON E N D OF F L O A T A R M , A G A IN S T TOP OF F L O A T N E ED LE W ITH FA ST ID LE A D J U S T M E N T M A D E , CAM FO LLO W ER M U S T BE H E L D F IR M L Y ON SECOND STEP OF FA ST ID L E CAM A G A IN S T H IG H STEP FLOAT LEVEL ADJUSTMENT B ( 3) H O L D POWER W PISTON DOWN A N D SWING M E T E R IN G RO D H O L D E R O V E R F L A T SU R FA C E (G A SK ET R E M O V E D ) OF BOWL C A S T IN G N E X T TO C A R B U R E TO R BORE BEND HERE TO A DJU ST BENDING TOOL @ N O TE : SP E C IFIE D PLUG GA U G E - S L ID E F IT USE TH E SAM E P R O C E D U R E AS A BO VE EXC E PT FOR STEP (1). AS T H E R E ARE NO STEPS ON M A N U A L C H O K E CAM , TH E IN D E X L IN E ON SIDE OF CAM S H O U L D BE L IN E D UP W IT H C O N T A C T P O IN T OF TH E FA S T ID L E CAM FO LLO W E R T A N G . © REM O VE (2 ) M E T E R IN G R OD BY H O L D IN G T H R O T T L E V A L V E W ID E OPEN. PUSH D O W N W A R D ON M E T E R IN G ROD A G A IN S T SPR IN G TE N S IO N , TH EN SL ID E M E T E R IN G RO D O U T OF SLO T IN H O L D E R A N D R E M O V E FR O M M A IN M E T E R IN G JET. M A N U A L C H O K E M O D E LS W IT H SM O O TH C O N TO U R CAM . BACK O U T ID LE SPEED SCREW A N D ID L E STOP S O L E N O ID - H O LD TH R O TTLE VA LVE C O M P L E T E L Y CLOSED FAST ID L E CA M A D J U S T M E N T (C H O K E ROD) M E T E R IN G ROD A D JU S T M E N T © PLACE G A U G E B ETW EEN LOW ER EDGE OF C HO KE V A L V E A N D R H O R N W A LL ® IN S E R T S C R E W D R IV E R IN SLO T IN CAM FO LLO W ER . BEND FO LLO W E R IN OR O U T TO ADJU! M A N U A L C HO KE M O D E L R O TA TE SM O O TH CAM TO H IG H E S T PO SITIO N PLACE CAM FO LLO W ER ON H IG H STEP OF CAM USE O U T S ID E V A C U U M SOURCE TO S E A T D IA P H R A G M c D IA P H R A G M P LU N G ER IN U N T IL IT SEATS L A D JU S T C UR B ID L E SPEED W IT H ID L E SPEED SCREW OR ID LE STOP S O L E N O ID (SEE D E C A L) VACUUM BREAK ADJUSTM ENT FAST ID L E A D J U S T M E N T STANDARD - 7 6 CYL. LIGHT DUTY TRUCK SERVICE MANUAL 6M -50 E N G IN E FU E L - S E R V IC E P R O C E D U R E S MODELS M, MV © J j © GAUGE BETWEEN LOWER EDGE OF C HO KE V A L V E A ND A IR H O R N W A LL BEND TA N G TO ADJU ST © H O LD CHOKE VALVE W IDE OPEN TOP EDGE OF ROD S H O U L D BE E V E N W ITH B O TT O M OF H O LE © PUSH DOWN ON ROD A G A IN S T STOP R O TA TE C HO KE V A L V E TO W A R D S C LO SED PO S ITIO N (USE RUBBER B A N D OR SPR IN G TO KEEP CHO KE V A L V E TO W A R D CLO SED P O S IT IO N ) N O T E . ON 1972 C A L IF O R N IA A P P L IC A T IO N S , A SW IV E L IS USED ON E N D OF C H O K E C O IL ROD. T U R N S W IV E L UP OR DOWN ON R O D U N T IL TOP OF P IN ON S W IV E L IS E V E N W IT H BOTTOM OF H O LE IN L E V E R . © BEND RO D TO A D JU S T (SEE N O TE FOR C A L IF . A P P L IC A T IO N S ) C H O K E C O IL R O D A D J U S T M E N T OPEN T H R O T T L E V A L V E SO CAM FO LLO W ER ON T H R O T T L E L E V E R C LE A R S FAST ID L E CAM 4 CYL. ( D SEA T D IA P H R A G M BY P U S H IN G P LU N G ER IN W ITH N E E D L E NOSED PLIERS iJ VA C U UM BREAK ADJUSTM ENT 4 CYL. jlJ © H O L D DOW N ON CHO KE , V A L V E W IT H ROD IN EN D OF SLO T „ A IR H O R N T IG H T E N IN G SEQUENCE G A U G E B ETW EEN LOWER EDGE OF C HO KE V A L V E A N D A IR H O R N W A LL J lj MAIN METERING JETS The main metering jet used in the single bore Mono­ jet differs from other models and should not be inter­ changed. It can be identified by 5 radial lines which are stamped opposite the identification number on the jet face. Example: H O LD T H R O T T L E LV A L V E W ID E OPEN The number stamped on the jet face indicates the orifice size. It can be two or three digits dependent upon the size of the orifice. The jet size can be determined by subtracting 100 from the last three digits of the part number. UNLOADER ( D H O L D C HO KE VALVE COM PLETELY CLOSED PUSH DOW N ON ROD TO STOP (EN D OF TRAVEL) Part No. Stamped On Jet Part No. On Jet 7034192 92 7034204 104 7034195 95 7034205 105 7034198 98 7034206 106 Stamped MAIN METERING RODS The metering rod used in the Monojet carburetor can be identified as follows. A three digit number is stamped on the shank of the metering rod in the area shown. The number denotes the diameter of the rod at Point " A " . ® B END ROD TO A D JU S T Example: CHOKE COIL ROD ADJUSTMENT -jflffllD DIAMETER “ A" Stamped No. Diameter “ A” .060" 060 C H O K E C O IL R O D A D J U S T M E N T STANDARD - oso~ D I A M E T E R "A" 6 CYL. 8 LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E F U E L 6M -51 ROCHESTER CARBURETOR D IA G N O S IS MODELS 2 G , 2 G V - T W O BARREL E N G IN E C R A N K S (T U R N O V E R ) W IL L N O T S T A R T OR S TA R TS H A R D W HEN CO LD CORRECTIVE ACTION POSSIBLE CAUSE Improper starting procedure used. Check w ith the customer to determine if proper starting procedure is used, as outlined in the owner's manual. No fuel in gas tank. Add fuel. Check fuel gauge fo r proper operation. Choke valve not closing sufficiently when cold. Adjust the choke thermostatic coil. Choke valve or linkage binding or sticking. Realign the choke valve or linkage as necessary. If caused by d irt and gum, clean w ith automatic choke cleaner. Do not oil choke linkage. If parts are replaced, check adjustments using procedure D, E or F. No fuel in carburetor. 1. Remove fuel line at carburetor. Connect hose to fuel line and run into metal container. Remove the high tension coil wire from center tower on distributor cap and ground. Crank over engine - if there is no fuel dis­ charge from the fuel line, check for kinked or bent lines. Disconnect fuel line at tank and blow out w ith air hose, reconnect line and check again for fuel discharge. If none, replace fuel pump. Check pump fo r adequate flow as outlined in service manual. 2. If fuel supply is o.k., check the following. a. Inspect fuel filters. If plugged, replace. b. If filters are o.k., remove air horn and check for a bind in the float mechanism or a sticking float needle. If o.k., adjust float as-specified. Use procedure A and B or C and D. Engine flooded. Check to determine if customer is using proper carburetor unloading procedure. Depress the accelerator to the floor and check the carburetor to determine if the choke valve is opening. If not, adjust the th ro ttle linkage and unloader, as specified. Use procedure I. NOTE: To check for flooding, remove the air cleaner, with the engine off, and look into the carburetor bores. Fuel w ill be dripping o ff nozzles and the carburetor bores w ill be very wet. Use procedure J or K. If choke unloader is operating properly, check fo r carbu­ retor flooding. NOTE: Before removing the carburetor air horn use the following procedure which may eliminate the flooding. Remove the fuel line at the carburetor and plug. Crank and run the engine until the fuel bowl runs dry. Turn o ff the engine and connect fuel line. Then re-start and run engine. This w ill usually flush d irt past the carburetor float needle and seat. If d irt is in fuel system, clean the system and replace fuel filters as necessary. If excessive d irt is found, remove the carburetor unit, disassemble and clean. Check float needle and seat fo r proper seal. If a needle and seat tester is not available, apply mouth suction to the needle seat with needle installed. If the needle or seat is defective, replace w ith a factory matched set. Check float for being loaded w ith fuel, bent float hanger or binds in the float arm. NOTE: A solid float can be checked fo r fuel absorption by lightly squeezing between fingers. If wetness appears on surface or float feels heavy (check w ith known good float), replace the float assembly. Check metal float for leakage bv shakinq. Adjust float. Use procedure A and B or C and D. 1 6 M - 5 2 ENGINE FUEL ROCHESTER CARBURETOR DIAGNOSIS - MODELS 2G, 2GV - TWO BARREL Problem: e n g in e starts a n d stalls POSSIBLE CAUSE CORRECTIVE ACTION Engine does not have enough fast idle speed when cold. Check and re-set the idle stop screw and fast idle cam. Use procedure F. Choke vacuum break unit is not adjusted to specification or is defective. Adjust vacuum break assembly to specification. procedure G or Ft. Use If adjusted O.K., check the vacuum break unit for proper operation as follows: Connect a piece of hose to the nipple on the vacuum break unit and apply suction by mouth or use vacuum source to apply vacuum. Plunger should move inward and hold vacuum. If not, replace the unit. Choke coil rod out of adjustment. Adjust choke coil rod. Use procedure J or K. Choke valve and/or sticking or binding. Clean and align choke valve and linkage. Replace if neces­ sary. Re-adjust if part replacement is necessary. Use procedures F, G and H. Idle speed setting Adjust idle speed to specifications on decal in engine compartment. Not enough fuel in carburetor. Check Check dirty. Check drop. Carburetor flooding. fuel pump pressure and volume. for partially plugged fuel inlet filter. Replace if the float mechanism for binds or not enough float Adjust as specified. Use procedure B or D. 1. Check float needle and seat for proper seal. If a needle and seat tester is not available, mouth suction can be applied to the needle seat w ith needle installed. If needle is defective, replace w ith a factory matched set. NOTE: Check by using procedure outlined under carbu­ retor flooding. Page 1. 2. Check float for being loaded w ith fuel, bent float hanger or binds in the float arm. NOTE: A solid float can be checked for fuel absorption by lightly squeezing between fingers. If wetness appears on surface or float feels heavy (check w ith known good float, replace the float assembly). 3. Check float adjustments. Use orocedure A and B or C and D. 4. If excessive d irt is found in the carburetor, clean the fuel system and carburetor. Replace fuel filters as necessary. Problem: E N G IN E ID L E S R O U G H A N D STALLS Idle speed setting Re-set idle speed per instructions on decal in engine com­ partment. Manifold vacuum hoses disconnected or improperly in­ stalled. Check all vacuum hoses leading into the manifold or carburetor base for leaks or being disconnected. Install or replace as necessary. Carburetor loose on intake manifold. Torque carburetor to manifold bolts Intake manifold is loose or gaskets are defective. Using a pressure oil can, spray light oil or kerosene around manifold legs and carburetor base. If engine RPM changes, tighten or replace the manifold gaskets or carburetor base gaskets as necessary. 2 (10-14 ft. lbs.). LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -53 ROCHESTER CARBURETOR DIAGNOSIS - MODELS 2G, 2GV - TWO BARREL Problem: E N G I N E ID L E S R O U G H AND STALLS (C O N T IN U E D ) POSSIBLE CAUSE CORRECTIVE ACTION Carburetor flooding. NOTE: Check by using procedure outlined under engine flooded. See page 1. Problem: e n g in e h e s it a t e s o n Remove air horn and check float adjustments. Use pro­ cedure A and B or C and D. If excessive d irt is found in the carburetor, clean the fuel system and carburetor. Replace fuel filters as necessary. Check float needle and seat for proper seal. If a needle and seat tester is not available, mouth suction can be applied to the needle seat w ith needle installed. If the needle is defective, replace w ith a factory matched set. Check float for being loaded w ith fuel, bent float hanger or binds in the float arm. NOTE: A solid float can be checked for fuel absorption by lightly squeezing between fingers. If wetness appears on surface or float feels heavy (check w ith known good float, replace the float assembly. Check metal float for leakage by shaking. a c c e l e r a t io n Accelerator pump not adjusted to specification. Adjust accelerator pump. Use procedure E. Defective accelerator pump system. Note: A quick check of the pump system can be made as follows. With the engine o ff, look into the carburetor bores, and observe pump shooters, while briskly opening throttle valves. A full stream of fuel should emit from each pump jet and squirt into the venturi area. Remove air horn and check pump cup. If cracked, scored or distorted, remove the pump plunger. Check the pump discharge ball for proper seating and location. The pump discharge ball is 3/16” steel and is located beneath the venturi cluster assembly. Check pump discharge ball for proper seating by filling cavity above ball w ith fuel to level of casting. No "leak down” should occur w ith discharge ball, spring and retainer in place. Re-stake or replace check ball if leaking D irt in pump passages. Clean and blow out w ith compressed air. Float level. Check for sticking float needle or binding float. Free up or replace parts as necessary. Check and reset float level and drop to specification. Use procedure A and B or C and D. Carburetor loose on manifold. Torque carburetor to manifold bolts (10-14 ft. lbs.). Problem : N O PO W ER O N H E A V Y A C C E L E R A T I O N O R A T H IG H SP EE D Carburetor th ro ttle valves not going wide open. (Check by pushing accelerator pedal- to floor). Adjust throttle linkage to obtain wide open throttle in carburetor. D irty or plugged fuel filters. Replace w ith a new filte r element. 3 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 5 4 ENGINE FUEL ROCHESTER CARBURETOR DIAGNOSIS - MODELS 2G, 2GV - TWO BARREL N O PO W E R O N H E A V Y A C C E L E R A T I O N Problem: O R A T H IG H SP EE D (C O N T IN U E D ) POSSIBLE CAUSE CORRECTIVE ACTION Float level too low. Check and reset float level to specification. Use procedure A or C. Float not dropping far enough into float bowl. Check and adjust float drop to specification. Use procedure B or D. Main metering jets or venturi cluster dirty, plugged or in­ correct part. If the main metering jets are plugged or d irty and excessive d irt is in the fuel bowl, the carburetor should be completely disassembled and cleaned. If the jets are incorrect size consult the parts list for proper usage. The last two digits stamped on the jet face are the same as the last two digits of the part number. See Chart M. Problem: E N G IN E S T A R T S H A R D WHEN HOT Choke valve not opening completely. Check for binding choke valve and linkage. place as necessary. Do not oil choke linkage. Check and adjust choke thermostatic coil. Use procedure J or K. Engine flooded. - Carburetor flooding. See procedure under "Engine cranks, w ill not start - Engine flooded." Page 1. No fuel in carburetor. Check fuel pump. Run pressure and volume test. Check for plugged inlet filter. Clean or replace as necessary. Check float needle for sticking in seat, or binding float. Leaking float bowl. Fill bowl w ith fuel and look for leaks. Problem: Clean or re­ E N G IN E R U N S U N E V E N OR SURGES. Fuel restriction. Check all hoses and fuel lines for bends, kinks or leaks. Straighten and secure in position. Check all fuel filters. If plugged or d irty - replace. D irt or water in fuel system. Clean fuel tank, lines and filters. carburetor. Fuel level. Adjust float. Use procedure A and B, or D and C. Check for free float and float needle valve operation. Free up or replace as necessary. A ir bleeds or fuel passages in carburetor, d irty or plugged. Clean carburetor or overhaul as necessary. Main metering jet defective, loose or incorrect part. Replace as necessary. Power system in carburetor not functioning properly. Power valve or piston sticking. Free up or replace as necessary. Vacuum Leakage. It is absolutely necessary that all vacuum hoses and gaskets are properly installed w ith no air leaks. The carburetor and manifold should be evenly tightened to specified torque. 4 Remove and clean See identification chart M. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6M -55 ROCHESTER CARBURETOR DIAGNOSIS - MODELS 2G, 2GV - TWO BARREL P ro b le m : E N G IN E RU NS U N E V E N OR SURGES (C O N T IN U E D ) POSSIBLE CAUSE CORRECTIVE ACTION Engine needs complete tune up. Check engine compression, examine spark plugs, (if d irty or improperly gapped, clean and re-gap or replace), ignition point dwell, condition, re-adjust ignition points if necessary and check and reset ignition timing. Clean or replace air cleaner element if dirty. Check for restricted exhaust system and intake manifold for leakage. Make sure all vacuum hoses are connected. Choke valve staying partially closed when engine is warm. Clean choke and free up linkage. Check choke coil for proper adjustment. Reset to specifications. Use procedure J or K. Fuel leaks. Check fuel tank, fuel lines and fuel pump fo r any fuel leakage. High fuel level in carburetor. Check for d irt in the needle and seat. Test using suction by mouth or needle seat tester. Check for loaded or leaking float. Re-set carburetor float to specifications. Use procedure A or C. If excessive d irt is present in the carburetor bowl, the carburetor should be cleaned. Power system in carburetor not functioning properly. A. Power piston sticking. B. Power valve leaking, loose, or stuck open. A. Free up or replace as necessary. B. Tighten, free up or replace as necessary. Wrong main metering jets installed. Consult parts list for proper jet. The last two digits of the part number appear on the jet face. See chart M. Fuel being pulled from accelerator system into venturi through pump jets. Run engine at RPM where nozzles are feeding fuel. Ob­ serve pump jets. If fuel is feeding from jets, check the pump discharge ball, spring and retainer. Check pump discharge ball for proper seating by filling cavity above ball w ith fuel to level of casting. No "leak dow n" should occur w ith discharge ball, spring and retainer in place. Re-stake or replace leaking check ball. A ir bleeds or fuel passages in carburetor d irty or plugged. Clean carburetor or overhaul as necessary. 5 LIGHT DUTY TRUCK SERVICE MANUAL 6M -56 E N G IN E FU E L S E R V IC E P R O C E D U R E S © M O D E L S 2G, 2 G V - TWO B A RR EL IN V E R T A IR H O R N W IT H G A S K E T IN PLACE. © (D BEND H ERE TO A D JU ST Jj V IS U A L L Y CHECK F L O A T A L IG N M E N T © G AUGE FRO M END OF F L O A T A T LO W ER EDGE O F S E A M T O A IR H O R N GASKET M E A S U R E FR O M TOP OF A IR H O R N R IN G T O TOP OF PUMP RO D BEND PUMP R O D TO A D JU S T - Q ^ "rJ =^ } W © FLOAT LEVEL ADJUSTM ENT ±1 © B A C K O U T ID L E SCREW TH R O T T L E V A L V E S M UST BE F U L L Y C LO S E D A IR H O R N R IG H T S ID E UP T O A L L O W F L O A T TO H A N G FR EE PUMP R O D A D J U S T M E N T © © B EN D S P E C IF IE D G A U G E B E T W E E N UPPER E D G E O F C H O K E V A L V E A N D W A L L O F A IR L HORN M E A S U R E S P E C IF IE D D IS T A N C E F R O M G ASKET SURFAC E TO FLO AT TANG BOTTOM OF FL O A T T O A D JU S T FO R © P R O P E R S E T T IN G BEND TA N G TO ADJU ST N EEDLE M UST NOT W EDGE A T M A X IM U M D R O P FLOAT DROP ADJUSTM ENT © H IG H E S T S T E P 2 N D STEP IN V E R T A IR H O R N W IT H G A S K E T IN PLACE © (4 ) V IS U A L L Y C HECK F L O A T A L IG N M E N T F O L L O W E R C L E A R S STEPS ON F A S T ID L E CAM V A CU U M B R E A K A D JU S T M E N T © P U S H UP L IG H T L Y ON V A C U U M BREAK LEVER TO CLOSE C H O K E (H O L D IN P O S IT IO N W IT H R U B B ER B A N D ) GAUGE BETWEEN AIR HORN WALL AND LOWER EDGE OF CHOKE VALVE G A U G E B E TW E E N A IR H O R N W A LL A N D LO W ER ED GE OF CHOKE V A L V E BEND ROD TO ADJUST CAM FOLLOWER ON SECOND STEP OF FAST IDLE CAM AGAINST HIGHEST STEP HOLD P R IM A R Y TH ROTTLE VALVES W ID E OPEN B END T A N G ON L E V E R TO A D JU S T F A S T ID L E CAM A D JU S T M E N T U N L O A D E R A D JU S T M E N T 7 LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL S E R V IC E P R O C E D U R E S - ALL MODELS 4M, 4M V - ±l (2 ) C H O K E V A L V E COM PLETELY C LO SED QUADRAJET MAIN METERING JETS The primary main metering jets used in the Quadrajet carburetor differ from other models and should not be interchanged. They can be identified by two curved lines stamped opposite the identification number on the jet face. The identification number stamped on the jet face indicates the orifice size. © R O T A T E C O IL L E V E R C O U N T E R C L O C K W IS E ^ U N T IL C HO KE VA LVE^ IS CLOSED 6 M 65 FOUR B A RR EL R E M O V E T H E R M O S T A T IC C O IL R O D FR O M L E V E R R O D S H O U L D F IT IN N O TC H IN L E V E R B END R OD TO A D J U S T - Example: H O L D DOWN ON R O D i A G A IN S T STOP C H O K E C O IL R O D PR IM A R Y JETS ADJUSTM ENT Part Number 7031972 70 31974 7 0 3 19 77 H Stamped 72 74 77 MAIN METERING RODS-Primary The number indicates the diameter of the metering rod at point " A " and is the last two digits of the part number. The 1968 and later models w ith the double taper w ill have " B " stamped on the rod after the two digit number. © ^ Example: H O L D C HO KE V A L V E W ID E OPEN BY R O T A T IN G V A C U U M BR EA K L E V E R TO W A R D S OPEN C H O K E IC LOCKW ISE ) £ <$) MEASURE .015 H BEND LEVER CLEARANCE I TO ADJUST SE C O N D A R Y L O C K O U T O P E N IN G C L E A R A N C E 3tT D O U BLE TAPER PR IM A R Y RODS HO LD SECONDARY TH R O TTLE VALVES S L IG H T L Y OPEN CD D IA M E T E R A H O L D C HO KE VALVE & SECONDARY TH ROTTLE V A L V E S C LO S ED Part Number 7034843 7034845 7034849 .015 M A X ( 7 ) / CLEARANCE B END PIN TO ADJUST Stamped 43 B 45 B 49 B SECONDARY LOCKOUT LEVER CLEARAN CE Q U ADRAJET S E C O N D A R Y SECONDARY LOCKOUT ADJUSTM ENT METERING RODS The secondary rods are identified w ith a two letter code. Example: g =czzzzzA ^ ID E N T IF IC A T IO N L E T T E R S S EC O N D A R Y RODS Code Letter CM DA Part Number 7045840 7046010 A IR H O R N T IG H T E N IN G SE Q U E N C E 8 LIGHT DUTY TRUCK SERVICE MANUAL 6 M - 6 6 ENGINE FUEL FUEL PUMP DIAGNOSIS CAMSHAFT DRIVEN FUEL PUMP Complete diagnosis of all possible causes of the trouble prior to replacement of the fuel pump will save time, expense and possibly prevent a repeat complaint. When a fuel pump is suspected of not performing properly, the following tests must be made: NOTE: Do not remove the pump for any of these inspec­ tions or tests. Be certain sufficient gasoline is in the tank. 3. With engine idling (using fuel in the carburetor float bowl), the vacuum should be at least 12” Hg. 4. If the vacuum is less than 12" Hg., replace pump. If the vacuum is okay, proceed to the next test. NOTE: Do not be concerned if vacuum drops off after the engine is stopped. Many pumps have valves with a bleed hole that allows vapors to bleed back to the gasoline tank. PRESSURE TEST: IN IT IA L INSPECTION 1. Be certain all fittings and connections are tight and cannot leak fuel between the pump and the carburetor or air between the gas tank and the pump. 2. Look for kinks in the fuel lines. 3. With engine idling, look for leaks: a. In the line between the pump and the carburetor. b. At the diaphragm flange on the pump. c. At the breather holes in the pump casting. d. At the sheet metal cover (pump) and its fittings. If leaks are evident in the lines or fittings, tighten or replace as necessary. If the fuel pump leaks (diaphragm flange, sheet metal cover, or pump casting breather holes), replace the pump. If the above steps do not cure the problem, proceed to the next test. VACUUM TEST: This will determine if the pump has the ability to pump fuel: 1. Disconnect the fuel line at the carburetor. Install a rubber hose on to the fuel line and run it back into the gas tank. 2. Disconnect the inlet fuel line at the pump. Fasten the inlet line in an up position so fuel will not run out. Install a vacuum gage on to the inlet of the pump. This will determine if the pump can deliver fuel at the proper pressure to the carburetor: 1. Reconnect the inlet fuel line to the pump. 2. Reconnect the fuel line at the carburetor. Idle engine for two minutes so the carburetor float bowl can be refilled. (This step may be omitted if enough fuel remains in the carburetor after vacuum test.) 3. Disconnect fuel line at the carburetor and install a pressure gage into the end of this fuel line. If the pump has a vapor return line, pinch the line closed. 4. With the engine idling (using fuel in the carburetor float bowl), the pressure gage when held at the level of the purnp outlet should read at least V-h psi. 5. If the pressure is less than this value, determine if the line from the pump to the carburetor is restricted. If this line is restricted, replace or clean it. If the line is not restricted, remove the pump and install a new one. 6 . If the pressure is okay, determine if fuel can be pulled up to the pump. Disconnect the fuel line at both the fuel pump inlet and the gas tank outlet. Blow air into the fuel pump end of the line to determine if fuel can flow through this line. NOTE: Failure to disconnect the fuel line at the gasoline tank prior to blowing air, can damage the tank strainer. If the line is restricted, replace or clean it. If the line was not restricted, proceed to other areas such as gas tank or car­ buretor. The fuel pump is not at fault. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E FUEL 6 M 67 SPECIAL TOOLS 22973 J—9789 J— 1137 J—5 1 9 7 J—4552 BENDING TOOLS J 1137 Choke Rod Bending J-4552 Choke Rod Bending (1 2 bbl.) J-5197 Unloader Bending J-8328 Carburetor Holding Tool Fig. 5P--Engine Fuel - Special Tools LIGHT DUTY TRUCK SERVICE MANUAL SECTION 6T EMISSION CONTROL SYSTEMS CONTENTS OF THIS SECTION Positive Crankcase Ventilation..................................... 6T-1 Controlled Combustion System.................................... 6T-3 Evaporation Emission C ontrol..................................... 6T -6 Exhaust Gas Recirculation System............................. 6T-7 Transmission Controlled Spark System.................... 6T-9 Air Injection Reactor System....................................... 6T-22 POSITIVE CRANKCASE VENTILATION THEORY OF OPERATION During the combustion process in a gasoline engine, a highly corrosive gas is produced. Also, for every gallon of gasoline burned, more than a gallon of water is formed. During the last part of the combustion stroke, some of the unburned fuel and products of combustion leak past the piston rings into the crankcase. This leakage is a result of four factors (Fig. la): 1. High combustion chamber pressures. 2. Necessary working clearance of piston rings in their grooves. 3. Normal ring shifting that sometimes lines up clearance gaps of two or more rings. 4. Reduction in ring sealing contact area with change in direction of piston travel. This blow-by must be removed before it condenses in the crankcase and reacts with the oil to form sludge which, if circulated with the oil, will cause corrosive and accelerated wear of pistons, rings, valves, bearings, etc. Because this blow-by also carries with it a certain quantity of unburned fuel, oil dilution will take place if it is not removed. These harmful gases are removed from the crankcase through a system utilizing engine vacuum to draw fresh air through the crankcase (Fig. 2a). Fresh air enters the Positive Crankcase Ventilation (PCV) system from the clean air side of the air cleaner or through a separate breather filter on the periphery of the air cleaner. Since the vacuum supply for the PCV system is from the intake manifold, the flow through this system into the manifold must be controlled in such a m anner that it varies in proportion to the regular air-fuel ratio being drawn into the intake manifold through the carburetor. The flow through the PCV system into the intake manifold is regulated by a PCV valve on all engines (Fig. 3a). The PCV valve varies the amount of flow through the system according to the various modes of operation (i.e. idle, cruise, acceleration etc.). The valve itself consists of a coil spring, valve, and a two-piece outer body which is crimped together. The valve dimensions, spring, and AIR IN T A K E PCV C O N TR O L VALVE K EY TO PCV SYSTEM CRANKCASE BLOW BY GASES F = F ILTER ED AIR B = BLOW BY G A S ES f + b m nnxnO CO M B U STIB LE M IXTU RE Fig. la —Engine Blow-By Fig. 2a—Schematic of PCV System LIGHT DUTY TRUCK SERVICE MANUAL 6T-2 EM IS S IO N CONTROL SYSTEMS Fig. 3a—PCV Valve Cross Section internal dimensions are such to produce the desired air flow requirements. During periods of deceleration and idle, manifold vacuum is high. The high vacuum overcomes the force of the valve spring, and the valve bottoms in the manifold end of the valve housing. This does not completely stop the flow but it does restrict the flow of crankcase vapors to the intake manifold (Fig. 4a). When the engine is accelerated or operated at constant speed, intake manifold vacuum is less than at idle or during deceleration. The spring force is stronger than the vacuum pull during this mode so the valve is forced toward the crankcase end of the valve housing. With the valve in this position, more crankcase vapors flow into the intake manifold (Fig. 5a). In the event of a backfire, the valve plunger is forced back and seated against the inlet of the valve body. This prevents the backfire from traveling through the valve and connecting hose into the crankcase (Fig. 6 a). If the backfire was allowed to enter the crankcase, it would ignite the volatile crankcase blow-by gases and result in a sizable explosion. It should be noted that additional air is permitted to enter the intake manifold when positive crankcase ventilation is used. However, the carburetor used with this system is calibrated to compensate for the air plus blow-by gas that enters the intake manifold from the crankcase. As can be seen from the foregoing discussion, the Positive Crankcase Ventilation system provides for proper air flow through it during all operating conditions. In addition, the crankcase vapors are reburned rather than exhausted to the atmosphere - thus helping reduce our air pollution problem. So far, we have discussed the two major benefits of the PCV system - namely, venting of detrimental crankcase vapors and air pollution reduction. There is a third benefit of this system that is equally as im portant to an owner; that is - Better Gas Economy. The recirculated vapor returned to the intake manifold is a combustible mixture. It, in effect, becomes fuel for operation when mixed with the air fuel ratio from the carburetor. In summary then, the PCV system provides: Fig. 4a—PCV Valve Position • Idle or Low Speed HIGH SPEED LOW MANIFOLD VACUUM MAXIMUM FLOW <0 PLUNGER IN OPEN POSITION Fig. 5a—PCV Valve Position High Speed or Cruise Operation Fig. 6a—PCV Valve Position • Engine “ OFF” or “ Backfire" Condition • Longer Engine Life - Draws harm ful blow-by gases out of the crankcase. • Reduction of Air Pollution - Reburns crankcase LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YS TE M S vapors rather than exhausting them into the atmosphere. • Increases Gasoline Economy - Reclaims unburned 6 T -3 blow-by gases by returning them to the intake manifold. DIAGNOSIS Engine operating conditions indicative of improper Positive Crankcase Ventilation System operation usually are accompanied by one or more of the following conditions: 1. Rough Idle 2. Oil Present in Air Cleaner 3. Oil Leaks 4. Excessive Oil Sludging or Diluting If any of the above conditions are observed, corrective action; such as: PCV valve replacement, hose replace­ ment flame arrestor cleaning or replacement or PCV breather (located in the air cleaner) replacement, should be accomplished as required to elim inate the malfunction. Proper operation of the PCV system is dependent upon a sealed engine. If oil sludging or dilution is noted, and the PCV system is functioning properly, check engine for possible cause and correct to ensure that system will function as intended. CONTROLLED COMBUSTION SYSTEM THEORY OF OPERATION In essence the Controlled Combustion System (CCS) increases combustion efficiency through carburetor and distributor calibrations and by increasing engine operating temperature (Fig. lb). Although the CCS system imposes no additional components, other than a special air cleaner assembly that is used in conjunction with it, an understanding of how exhaust emissions are reduced would be beneficial. In general it can be said that CCS carburetors are calibrated leaner and timing is retarded during low speed or deceleration operations as compared to systems used in prior years. However, this does not always hold true. The system was individually developed on each engine-transmission combination. Various adjustments were made to reduce the hydrocarbon and carbon monoxide emissions. The exact provision or adjustment made was not the same for each engine-transmission combination. The following provisions have been made on all CCS systems. Exceptions to these providions will be noted. than a fixed orifice at the base of the idle mixture screw. This insures that even if the idle mixture screw is turned out too far, the fuel enrichment will not greatly affect exhaust emission reduction. NOTE: All carburetors are equipped with idle mixture limiter caps; no attempt should be made to adjust mixture - do not remove mixture screw caps. Distributors and Timing As mentioned initial ignition timing is slightly retarded over previous years. If you took two equal engines of which one had its timing retarded with respect to the other, a wider throttle plate opening would be required to obtain the same RPM on the engine with retarded spark. With a wider throttle plate opening, more air can NEW CARBURETOR LE A N M IXTURES. ENGINE IDLE INCREASED CO N TR O LLED IN TA K E AIR Carburetors Most carburetors used with CCS system are the same as carburetors used in prior years but specially calibrated throughout their driving ranges for optimum emission control as well as the usual parameters of vehicle performance, economy and driving feel. All CCS carburetors have an internal provision that allows production to refine part throttle calibration to meet very accurate air/fuel ratios and thus reduce emissions in this sensitive area. Another feature incorporated in the CCS carburetors is an “Idle Fuel Limiting” feature. This is nothing more HIGH TEM P ER A TU R E TH ER M OSTAT FOR ENGINE CO O LAN T K EY TO C.C.S. S YS TEM HEdTEO UNDERHOOD M l UH0ERH00D MR C6®E! H EA T EXCH AN GED FROM EXH A U ST M AN IFO LD TO UNDERHOOD AIR FLOW HOT EXHAUST Fig. lb —Schematic of Controlled Combustion System LIGHT DUTY TRUCK SERVICE MANUAL 6 T -4 E M IS S IO N C ONTROL SYS TE M S be drawn into the intake manifold and thus less fuel enrichment during idle or deceleration conditions (Fig. 2 b). Vacuum for the spark advance is taken from a point above the carburetor’s throttle plate (throttle in closed position). At engine idle, this port is above the throttle blade and no vacuum is available. Without vacuum, the timing is retarded. As the throttle is opened, the port is uncovered providing vacuum spark advance for normal operation (Fig. 3b). ADVANCED RETARDED OFF-IDLE CARBURETOR IDLE POSITION INTAKE MANIFOLD VACUUM Cooling System With the introduction CCS, higher engine coolant temperatures were necessary; therefore, a 195°F coolant thermostat was employed - previous thermostat were rated at 180°F. Hotter running engines help reduce hydrocarbon emissions by providing more complete vaporization and also by reducing quench area. Quench area is the area of each cylinder that is near the cylinder wall. The cylinder walls are relatively cold in comparison to the center of the cylinder bore. As the air fuel ratio enters the chamber in its vaporous state, the mixture that expands against the relatively cool cylinder walls condenses to a certain extent. As the ignition flame travels from the spark plug. It fails to ignite these condenseed vapors near the cylinder walls. By increasing the coolant temperature the size of the quench area is reduced and thus the ignition flame can consume more of the fuel thus reducing emission content (Fig. 4b). DISTRIBUTOR VACUUM ADVANCE Fig. 3b—Schematic of "Ported" Spark Advance WATER JACKET! QUENCH FLAME TRAVEL QUENCH ARE. Thermostatically Controlled Air Cleaners All CCS systems incorporate a “ therm ostatically controlled air cleaner” . The thermostatic air cleaner system (referred to as ThermAC System) is designed to keep air entering the carburetor at approximately 100°F. when underhood temperatures are less than 100°F. By keeping the air at 100°F. or more, the carburetor can be “leanly” calibrated to reduce hydrocarbon emission, minimize carburetor icing, and improve engine warm-up characteristics. The thermostatically controlled air cleaner system is composed of a special air cleaner and a heat stove. The heat stove is nothing more than a sheet metal case IDENTICAL ENGINES IDLING AT 700 RPM INITIAL TIMING 8° B.T.D.C. Relatively little air flow past carburetor throttle plate which is in nearly closed position. INITIAL TIMING 4° B.T.D.C. Larger throttle plate opening is needed to allow more air into the fuel to achieve 700 R.P.M. Fig. 2b—Relation of Tinning to Exhaust Emission WATER Fig. 4b—Cylinder Quench Area surrounding the exhaust manifold that traps the heat generated from the manifold and uses it to heat the air going to the carburetor. The air cleaner primarily consists of a body, filter element, sensor unit, vacuum diaphragm assembly, damper door, and connecting vacuum hoses and links (Fig. 5b). The body and filter element resemble a conventional snorkel type air cleaner. The sensor unit is mounted in the body on the clean air side of the filter. The sensor unit regulates (depending upon the temperature of the air passing by it) the amount of vacuum supplied to the vacuum diaphragm. The vacuum diaphragm (depending on the amount of vacuum supplied to it by the sensing unit) opens the damper door allowing heated air from the heat stove to enter the cleaner and shuts off the passage for ambient air. The dam per door is fully open (all warm air) at 8 inches of mercury and fully closed (ambient air only) at 6 inches of mercury or less. The vacuum signal measured at the diaphragm assembly will not be the same as actual engine vacuum as the thermostatic control valve in the sensor unit provides a controlled vacuum leak for regulation of the supply LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L SYS TE M S TEMP. SENSING SPRING AIR CLEANER ASSY. VACUUM DIAPHRAGM DAMPER DOOR FROM BASE OF CARBURETOR (SOURCE OF INTAKE MANIFOLD VACUUM) Fig. 5b—Thermostatically Controlled Air Cleaner signal. A bi-metal strip in combination with a needle valve type operation accomplishes the temperature sensitive controlled vacuum leak. The thermostatically controlled air cleaner functions as follows (Fig. 6 b): When the engine is “off” (View A), no vacuum is present at the sensor unit nor at the vacuum diaphragm. The force of the vacuum diaphragm spring closes off the “heated air” passage (snorkel passage open). When the engine is initially started (View B), the sensor unit’s bimetal strip senses cool air temperature (below 85°F). The thermostat control valve of the sensor unit closes its air bleed passage allowing maximum vacuum to the vacuum diaphragm. Maximum vacuum at the vacuum diaphragm completely opens the damper door, closing off the ambient air passage through the snorkel and opening the air passage feed by the air heat stove. Should the engine be heavily accelerated while in this mode, the vacuum level in the system will drop to a low enough level so that the diaphragm spring will overcome the vacuum and push the dam per door closed permitting ambient air passage through the snorkel. As the engine heats up and air passage past the sensor reaches approximately 128° F (View C), the sensor’s thermostatic control valve bleed passage is completely opened by the bimetal spring acting upon the needle. Air bleeding into the vacuum acting on the diaphragm assembly lowers the vacuum level enough so that the diaphragm spring closes the dam per door, thus opening the cold air passage (abmient air through snorkel) and closing the hot air passage (heat stove passage). At temperatures between 85° and 128°F (View D), varying amounts of air is bled into the system, depending on the exact temperature at the sensor unit. This results in a vacuum level and dam per position required to maintain carburetor air temperature at from 85° to 128°F when underhood temperatures are below this range. VIEW B -U N D E R H O O D TEMPERATURE BELOW 85°F VIEW A —ENGINE OFF AIR BLEED VALVE , CLOSED DIAPHRAGM SPRING TEMP. SENSING SPRING VACUUM CHAMBER SNORKEL TUBE 6 T -5 SNORKEL TUBE "•n DIAPHRAGM CONTROL DAMPER ASSM. HOT AIR PIPE \ O " AIR PIPE CONTROL DAMPER ASSM. 11 |i i F -HHOT VIEW D - UNDERHOOD TEMPERATURE BETWEEN 85°F A N D 128°F VIEW C - UNDERHOOD TEMPERATURE ABOVE 128°F AIR BLEED VALVE OPEN SNORKEL TUBE DIAPHRAGM SPRING .VACUUM CHAMBER CONTROL DAMPER ASSM. DIAPHRAGM SPRING VACUUM CHAMBER HOT AIR PIPE TEMP. SENSING SPRING SNORKEL TUBE AIR INLET AIR INLET AIR BLEED VALVE DIAPHRAGM CONTROL DAMPER ASSMH f f S h o t a ir pipe Fig. 6b—Thermostatically Controlled Air Cleaner Operation LIGHT DUTY TRUCK SERVICE MANUAL 6 T -6 E M IS S IO N C O N TR O L SYS TE M S DIAGNOSIS Proper system function relies upon component perform ­ ance as outlined under system operation and description. Only the air cleaner is discussed in the following checks, refer to applicable section for other system components. Operation Check 1. Remove air cleaner cover and install temperature gauge (Tool J-22973) as close as possible to sensor (Fig. 7b). Reinstall cover without wing nut. If vehicle has been in recent operation and tempera­ ture at sensor unit is above 85°F, remove air cleaner assembly and let it cool to below 85°F. Reinstall air cleaner assembly and cover. Do not install wing nut. 2. Observe damper door position through snorkel opening. If position of snorkel makes observation difficult use the aid of a mirror. At this point the damper door should be in such a position that the heat stove passage is covered (snorkel passage open). If not, check for binds in linkage. 3. Start and idle engine. Observe damper door position through snorkel. It should initially be in a position that closes off the snorkel passage if ambient temperatures are below 85°F. When damper door beings to open remove air cleaner cover and observe thermometer reading. It should be between 85°F and 115°F. 4. If damper door opens before 85°F, replace sensor unit (do not try to adjust). 5. If dam per door does not open at correct temperature continue with the following vacuum diaphragm check: a. Turn off engine. Disconnect diaphragm assem­ bly vacuum hose at sensor unit. Damper door should completely close heat stove passage at this point. If not, check linkage for a binding condition. b. Apply at least 9 In. Hg. of vacuum to diaphragm assembly through hose disconnected at sensor unit. This can be done by mouth. Damper door should completely close snorkel passage when vacuum is applied. If not check to see if linkage is hooked up correctly and for a vacuum leak. c. With vacuum applied, bend or clamp hose to trap vacuum in diaphragm assembly (Fig. 8 b). Damper door should remain in position (closed snorkel passage). If it does not, there is a vacuum leak in diaphragm assembly. Replace diaphragm assembly. 6 . If vacuum diaphragm check is found satisfactory, replace sensor unit. Do not try to adjust. TOOL J-22973 Fig. 7b—Checking Sensor Unit Fig. 8b—Checking Vacuum Diaphragm EVAPORATION EMISSION CONTROL This system is designed to reduce fuel vapor emission that normally vents to the atmosphere from the gasoline tank and carburetor fuel bowl. The air cleaner filter mounted at the bottom of the canister requires replacement at intervals specified in Section 0. All other parts are serviced as a complete replacement as outlined in Section 8 . LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YS TE M S 6 T -7 EXHAUST GAS RECIRCULATION SYSTEM DESCRIPTION A N D OPERATION The Exhaust Gas Recirculation (EGR) system is used to reduce oxides of nitrogen (NOx) emitted from the engine exhaust (fig. lc). Formation of NOx takes place at very high temperatures, consequently, it occurs during the peak temperature period of the combustion process. To reduce and control NOx formation only a slight reduction in peak temperatures is required. This reduction can be accomplished by introducing small amounts of an inert gas into the combustion process. The end products of combustion provide a continuous supply of relatively inert gases, therefore, it becomes a matter of utilizing those gases in the correct proportion. The EGR valve is positioned in the left front corner of the inlet manifold in front of the carburetor on all Mark IV engines. The internally cast passages permit exhaust gases to flow to the combustion area through the inlet manifold (fig. 5c). Not all engine operational modes are critical as far as NOx emissions are concerned, the EGR valve and vacuum source is designed to vary the amount of exhaust gases recirculated. At idle, no recirculation is needed, consequently, the opening, or vacuum source, for the tube that connects the EGR valve is placed just above the throttle blade. Therefore, at idle (throttle blade closed) the EGR valve is closed. When the throttle is opened to accelerate, the EGR valve begins opening at approximately three inches of mercury pressure drop in the throttle body. Valve metering is constant above five inches of mercury pressure differential. The valve is quickly brought to full open when accelerating from the throttle closed condition. Approaching full throttle, when manifold vacuum is below three inches of mercury the EGR valve closes. Only a very small portion of the exhaust gases is used with maximum flow occuring during the 30 to 70 miles per hour cruise condition. Fig. lc —Exhaust Gas Reciculation System Schematic To tap this continuous supply of inert gases, without external pipes or connection to the exhaust system, additional exhaust gas passages are cast into the complex runner system of the inlet manifold. Separating the two EGR passages is a vacuum modulated shut-off and metering valve, referred to as the “EGR valve” (fig. 2c). The EGR valve contains a vacuum diaphragm, which is operated by intake manifold vacuum. The diaphragm vacuum signal supply port is located in the carburetor throttle body, and is exposed to engine manifold vacuum in the off-idle and part throttle to wide open throttle operation. A .030 orifice in the valve vacuum tube serves to modulate flow. On In-Line engines the EGR valve is located on the inlet manifold adjacent to the carburetor. Exhaust gases are diverted from the manifold heat box through the EGR valve and into the inlet manifold through a drilled hole (fig. 3c). Small V 8 engines have the EGR valve located externally on the right rear side of the inlet manifold adjacent to the rocker arm cover. Internally cast passages direct the exhaust gases to the area just below the carburetor throttle plates (fig. 4c). VACUUM TUBE CONNECTED V A LV E O PEN V A LV E SEA T. V A L V E C H A M B E R .. EXH AU ST GAS IN L E T P O R T T O IN T A K E m a n if o l d \ J ___________ m Fig. 2c—EGR Valve-Sectional View LIGHT DUTY TRUCK SERVICE MANUAL 6 T -8 E M I S S I O N C O N T R O L S Y S T E M S Fig. 4c—EGR Valve and Manifold (Small V8) Fig. 3c—EGR Valve and Manifold (L-6) Fig. 5c—EGR Valve and Manifold (Mark IV V8) SERVICE OPERATIONS EGR Valve Replacement 1. Disconnect EGR valve vacuum line at top of valve. 2. Remove clamp bolt securing valve to manifold. 3. Remove EGR valve and clamp from manifold. 4. Reassemble valve to manifold, using a new gasket. 5. Torque clamp bolt to 25 lb. ft., and bend lock tab over bolt head. LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YS T E M S 6 . Connect vacuum line to tube at top of valve. EGR Valve Functional Check NOTE: A rough idling engine may be caused by a malfunction of the EGR valve; such as, exhaust deposits holding valve open, broken EGR valve spring, vacuum hose disconnected or a ruptured valve diaphragm. On Vehicle Check 1. Connect tachometer to engine. 2. With engine running at normal operating tem pera­ ture and choke valve is fully open position, set engine speed at 2000 rpm - transmission in Park or neutral, parking brake on and drive wheels blocked. 3. Disconnect vacuum hose at EGR valve and check to make sure that vacuum is available at valve reconnect hose. 4. Observe tachometer to make sure that engine speed is at 2000 rpm. Disconnect vacuum hose at EGR valve and observe tachometer reading. Valve is functioning properly if a minimum increase of 100 rpm is noted with vacuum hose disconnected. Off Vehicle Check 1. Manually depress the EGR valve diaphragm to make sure valve is free - if diaphragm cannot be 6 T -9 moved manually valve should be cleaned before proceeding with check. 2. Apply approximately 9 inches of vacuum to the vacuum tube on top of EGR valve. The valve should move to the fully open position, and should remain open - no leak down - with vacuum applied. 3. Replace valve if diaphragm is defective. EGR Valve Cleaning CAUTION: Do not wash valve assembly in solvents or degreaser-permanent damage to valve diaphragm may result. 1. Clean base of valve with a wire brush or wheel to remove exhaust deposits from mounting surface. 2. Valve seat and pintle should be cleaned in a standard abrasive-type spark plug cleaning machine. 3. Insert valve and pintle into opening in cleaning machine, and blast for approximately 30 seconds. 4. Compress diaphragm spring so that valve is fully unseated, repeat cleaning for approximately 30 seconds. 5. Inspect valve to ensure that exhaust deposits have been removed - repeat cleaning procedure as required to remove all deposits. 6 . Air blast valve seat and pintle area to ensure that abrasive material is thoroughly removed from valve. TRANSMISSION CONTROLLED SPARK SYSTEM SIX-CYLINDER ENGINE The Transmission Controlled Spark System is used on all 10 Series vehicles, C-K20 Suburban, G20 Series and G30 passenger vans. DESCRIPTION Control of exhaust emitted by vehicles using the sixcylinder engine, is accomplished by preventing ignition vacuum advance when the vehicle is operating in low forward gears. Vacuum advance is controlled by a solenoid-operated valve, which is energized by grounding a normally open switch at the transmission. W hen the solenoid is in the non-energized position, vacuum to the distributor advance unit is shut off and the distributor is vented to atmosphere through a filter at the opposite end of the solenoid — venting the distributor advance unit prevents it from becoming locked at an advanced position. When the solenoid is energized, the vacuum port is uncovered and the plunger is seated at the opposite end, shutting off the clean air vent. High gear deceleration throttle blade setting is performed with the solenoid de-energized. The CEC solenoid is controlled by two switches and a time relay. The solenoid is energized in the high forward gear and in reverse on Hydra-matic by a transmission operated switch. A thermostatic coolant temperature switch is used to provide thermal override below 93°F. The time relay is incorporated in the circuit to energize the CEC valve for approximately 20 seconds after the ignition key is turned on. The relay’s 20 second delay begins when the ignition key is turned on, but the solenoid will remain energized as long as coolant temperature is below 93°F. Wider throttle blade openings at idle are required to compensate for the retarded spark condition produced by the design of the emission reduction system. To prevent engine dieseling at engine shut down, an idle stop solenoid is provided. The ignition activated idle stop solenoid eliminates dieseling tendencies by allowing the throttle valve to close beyond the normal idle position when the ignition is turned off. SYSTEM THEORY The TCS system components are shown in their normal at rest position with the engine off and cold (fig. Id). The temperature switch points are closed, making contact with the cold terminal; the time relay points are closed, LIGHT DUTY TRUCK SERVICE MANUAL 6 T -1 0 E M IS S IO N C O N TR O L SYS TE M S Fig. Id —L-6 TCS System (Engine Off) transmission switch points are open; CEC solenoid is de­ energized, plunger retracted and blocking distributor vacuum advance and opening the distributor vacuum advance unit to atmosphere; idle stop solenoid is de­ energized with plunger retracted. When the ignition switch is turned on the idle stop solenoid is energized, extending the plunger to contact the throttle lever. A circuit is completed from the ignition switch through the CEC solenoid and through the temperature switch cold terminal to ground. At the same time another circuit is energized — this is from the ignition switch through the time relay coil and to ground, also as long as the relay points are closed it provides a path to ground for the CEC solenoid (fig. 2d). With either one or both of the above circuits complete, the CEC solenoid is energized; permitting vacuum advance to distributor and, additionally, the CEC solenoid plunger extends, contacting the throttle lever to provide deceleration control at a preset value. In low gear operation, with engine temperature above 93 degrees, the temperature switch cold override points open (fig. 3d). If 20 seconds have elapsed the time relay points are open also. This breaks the circuit(s) de­ energizing the CEC solenoid, allowing the plunger to block vacuum and open advance unit to atmosphere — deceleration control is no longer effective, leaving throttle control to be performed by the idle stop solenoid. When the transmission is shifted into high forward gear, the transmission switch points are closed by shift action or by oil pressure as applicable (fig. 4d). This completes the circuit from the ignition switch through the CEC solenoid and through the closed transmission switch points to ground. The CEC solenoid plunger is extended to provide deceleration control and to open the vacuum port to the advance unit. IGN. SWITCH COLD OVERRIDE SWITCH Fig. 2d—L-6 TCS System (Cold Override & Time Relay Energized) TRANSMISSION SWITCH (N.O.) Energized = V. A. De-energized = Atm. 20 SECOND TIME RELAY (N.C.) Fig. 4d—L-6 TCS System (High Gear Operation) LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YS T E M S 6 T -1 1 CEC SO LENO ID TCS TEMPERATURE SWITCH IDLE STOP SO LENO ID Fig. 6d—L-6 Temperature Cold Override Switch Time Relay Fig. 5d—L-6 Idle Stop and CEC Solenoids COMPONENT DESCRIPTION Idle Stop Solenoid The idle stop solenoid is a two position electrically operated control, used to provide a predetermined throttle setting (fig. 5d). In the energized position (plunger extended) the plunger contacts the carburetor throttle lever and prevents full closing of the carburetor throttle plates. This fast idle control when de-energized (plunger retracted) allows throttle plates to close beyond the normal idle position; thereby shutting off air supply and in essence starving the engine so that it will shut down without dieseling. The idle stop solenoid is attached to the carburetor so that the plunger, when extended, contacts the throttle lever. The time relay is an electrically operated on-off type switch. When the coil is energized it begins to heat the bi-metal strip to open the normally closed relay points in approximately 20 seconds. A ground path is provided for through the relay housing and mounting bracket. Two self-tapping screws attach the relay to the upper portion of the vertical wall of the cowl near the vehicle centerline. Temperature Cold Override Switch The cold override switch, located in the thermostat housing (fig. 6 d) serves to activate the CEC solenoid. At coolant temperatures below 93 (± 7 ) degrees, the cold terminal is contacted by the bi-metallic strip to ground and completes the circuit to the CEC solenoid. In the neutral position, no contact is made; therefore the circuit is broken. CEC SOLENOID The CEC solenoid (fig. 5d) is a two-position electrically operated control, which serves a dual function in the TCS system. In the de-energized position the spring loaded plunger closes the vacuum supply port to the distributor advance unit and opens the air vent to the advance unit. In the energized position the plunger is extended to contact the carburetor throttle lever and to open the vacuum port to the distributor and to shut off the air vent. The solenoid is bracket-attached to the carburetor so that the plunger, when extended, contacts the throttle lever to maintain a predetermined throttle opening. Fig. 7d—Transmission Switch Location (Manual) LIGHT DUTY TRUCK SERVICE MANUAL 6 T -1 2 E M IS S IO N C O N TR O L S YS TE M S Transmission Switch On manual shift synchromesh transmissions, both 3-and 4-speed, the switch is located on the outside of the transmission case in an area adjacent to the 2-3 or 3-4 shifter shaft, as applicable (fig. 7d). The mechanically operated switch is spring loaded to provide continuity between the switch terminal and the switch housing When installed in the transmission, the plunger contacts the shifter shaft, which causes the plunger to retract in low forward gears, thereby opening the circuit to ground. When the transmission is shifted into high forward gear, the plunger drops into a recess or flat on the shifter shaft, causing the plunger to rest internally on the switch housing. A circuit is completed to ground, from the transmission through the switch housing to the cup contact and through the spring to the electrical terminal. The Turbo Hydra-matic 350 transmission uses a pressure sensitive switch, which is activated by transmission fluid pressure. The Turbo Hydra-matic 350 switch (fig. 8 d) is located externally in the 2-3 direct clutch pressure tap. At rest, in or out of the installed position, the switch is in a normally open position (fig. 9d). Construction of the switch is such that a spring loaded diaphragm that contains a metallic contact, is held away from a cup contact, which in turn, is in contact with the switch housing. Transmission fluid pressure, against the insulated plug, forces the diaphragm upward so that the diaphragm contact closes the circuit through the spring to the electrical terminal. EIGHT-CYLINDER ENGINES The Transmission Controlled Spark System is used on all 10 Series vehicles, C-K20 suburban, G20 Series and G30 passenger vans when equipped with manual transmission. In addition, the above vehicles also use the TCS system when equipped with 307 cu. in. engine and automatic transmission. DESCRIPTION Control of exhaust emitted by vehicles using the eightcylinder engines, is accomplished by eliminating ignition Fig. 9d—Turbo Hydra-Matic 350 Transmission Switch (Sectional View) vacuum advance when the vehicle is operating in low forward gears. Vacuum advance is controlled by a solenoid-operated switch, which is energized by grounding a normally open switch at the transmission. When the solenoid is in the non-energized position, vacuum to the distributor advance unit is denied and the distributor is vented to atmosphere through a filter at the opposite end of the solenoid — venting the distributor advance unit prevents it from becoming locked at an advanced position. When the solenoid is energized, the vacuum port is uncovered and the plunger is seated at the opposite end, shutting off the clean air vent. The vacuum advance solenoid is controlled by two switches and a time relay. The solenoid is energized in the high forward gear (and in reverse on Hydra-matic) by a transmission operated switch. A thermostatic coolant temperature switch is used to provide thermal override below 93°F. W ider throttle blade openings at idle are required to compensate for the retarded spark condition produced by the design of the emission reduction system. To prevent engine dieseling at engine shut down, an idle stop solenoid is provided. The ignition switch activated idle stop solenoid eliminates dieseling tendencies by allowing the throttle valve to close beyond the normal idle position when the ignition is turned off. SYSTEM THEORY Fig. 8d—Turbo Hydra-Matic 350 Transmission Switch Location The system components are shown in their normal at rest position with the engine off and cold (fig. le). The temperature switch points are closed, making contact LIGHT DUTY TRUCK SERVICE MANUAL COMPLAINT COMPLAINT Excessive Creep at Idle High Idle Speeds Dieseling Poor High Gear Performance Stum ble Stall Cold or Hot Start Excessive Fuel Consum ption Deceleration Exhaust “ P op” CAUSE M a lfu n c tio n in T C S S y s te m C o m p o n e n t . C h e c k for: B lo w n fuse L o o se c o n n e c tio n s B ro k e n Wire B ro k e n or D is c o n n e c te d hoses P r o p e r g r o u n d at all c o m p o n e n t s P r o p e r r o u tin g o f hoses. C AU SE C AU SE CAUSE Idle S t o p S o le n o id In o p e r a tiv e C E C S o le n o id E n e rg iz e d at all T im e s In o p e r a tiv e C E C S o le n o id _________________________________ Step 1 Inoperative Idle Stop 1 I ................- .............. ................... Step 3 Step 4 Inoperative Tim e Relay Inoperative Transmission Switch M alfunction Solenoid DUTY TRUCK 1. R e m o v e te m p e r a t u r e sw itc h c o n n e c to r . 2. C h e c k relay to m a k e sure th a t it is c o o l, th e n tu r n igni­ tion on. 3. S o le n o id s h o u ld e n e rg iz e for 2 0 s e c o n d s a n d th e n d e ­ ene rgiz e . If it d o e s not d e ­ en e rg iz e , r e m o v e b lu e lead fr o m tim e relay. S o le n o id will de-e n e rg ize if relay is at fault. P r o c e e d to S t e p 4 if relay is n o t at fault. 1. S ta r t e ngine a n d p u t tr a n s ­ m ission in reverse o n H y d ra m a tic or high o n m a n u a ls 2. W he n tr a n s m is s io n is pla c e d in p o s itio n r e q u i r e d fo r test, th e C E C S o le n o id s h o u ld e n ergize. If it d o e s n o t e n e r ­ gize, re m o v e c o n n e c t o r at s w itc h a n d g r o u n d th e t e r ­ m in al if s o le n o id e n ergizes th e s w itc h is fa u lty . 3. If th e s w itc h is n o t at fault p ro c e e d to S t e p 5. 1. C o ld e n g i n e - T u r n t h e ig n i­ tion s w itc h o n . If th e C E C S o le n o id p lu n g e r d o e s n o t e ne rgiz e o r if it e n e rg iz e s a n d r e tr a c ts a f te r 2 0 s e c o n d s , re m o v e th e s w itc h c o n n e c t o r a n d g r o u n d th e c o ld te rm jn a l lead. T h is will a c tiv a te th e s o le n o id p lu n g e r, in d ic a tin g a d e fe c tiv e s w itc h . 2. W a rm e n g in e - A llo w t e m p e r ­ a tu re s w itc h to c o o l. T h e n w ith th e w ires c o n n e c t e d a n d s w itc h g r o u n d e d , t h e so le n o id s h o u ld e n e rg iz e a n d re m a in e n e rg iz e d . If it d o e s n o t th e s w itc h is d e fe c tiv e . SYSTEMS LIGHT 1. C h e c k for free m o v e m e n t o f plunger. 2. C h e c k for in c o r re c tly a d ­ ju s te d plunger. 3. R e m o v e c o n n e c t o r fr o m solenoid a n d a p p ly 12 volts across te rm in a ls. I f s o le n o id does not e n e rg iz e it is d e f e c ­ tive. 4. T u rn ignition o n a n d re m o v e b la c k lead f r o m c o n n e c t o r , solenoid s h o u ld d e -energize. 5. If solenoid was n o t at fault pro ce e d to S t e p 3. CONTROL 1. C h e c k fo r free m o v e m e n t o f p lun ger. 2. C h e c k f o r in c o r re c tly a d ­ j u s te d p lu n g e r ( o u t to o far). 3. W i t h ig n itio n off-so le n o id s h o u ld de-energize. 4. If s o l e n o i d de-energizes p ro c e e d to S t e p 2. Step 5 Tem perature Switch EMISSION Step 2 Inoperative C E C Solenoid 6 T -1 3 SERVICE MANUAL Fig. lOd—Trouble Shooting Guide (Six-Cylinder Engine) 6T-14 EMISSION CONTROL SYSTEMS (CEC PLUNGER IS EXTENDED) Fig. l i d —Vacuum Advance Diagram (Six-Cylinder Engine) E M IS S IO N C O N TR O L S YSTEM S with the cold terminal; the time relay points are closed; transmission switch points are open; idle stop solenoid is de-energized and plunger retracted; vacuum advance solenoid is de-energized with plunger shutting off the port to vacuum advance unit. When the ignition switch is turned on, the idle stop solenoid is energized, extending the plunger to contact the throttle lever. A circuit is completed from the ignition switch through the vacuum advance solenoid and to ground through the temperature switch. At the same time another circuit is energized - this is from the ignition switch through the time relay coil and to ground, also as long as the relay points are closed, it provides a path to ground for the vacuum solenoid (fig. 2 e). With either one or both of the above circuits complete, the vacuum solenoid is energized permitting vacuum advance to the distributor. In low gear operation, with engine temperature above 93 degrees, the temperature switch cold override points open (fig. 3e). If 20 seconds have elapsed, the time relay points are open also. This breaks the circuit(s) de­ energizing the vacuum advance solenoid, allowing the plunger to block vacuum and open the advance unit to atmosphere. When the transmission is shifted into high forward gear, the transmission switch points are closed by shift action or by oil pressure as applicable. This completes the circuit from the ignition switch through the transmission switch to ground (fig. 4e). Vacuum advance solenoid is energized. 6 T -1 5 Fig. 2e—V8 TCS System (Cold Override Energized) COMPONENT DESCRIPTION Idle Stop Solenoid The idle stop solenoid (fig. 5e and 6 e) is a two position electrically operated control, used to provide a predetermined throttle setting. In the energized position (plunger extended) the plunger contacts the carburetor Fig. 3e—V8 TCS System (Low Gear Operation) r BATTERY IGN. SWITCH IDLE STOP SOLENOID DIST. VACUUM ADVANCE UNIT COLD ^ 1 COLD OVERRIDE SWITCH TRANSMISSION SWITCH (N.O.) Energized = V.A. De-energized = Atm. 9999^ 1 20 SECOND TIME RELAY (N.C.) Fig. 4e—V8 TCS System (High Gear Operation) LIGHT DUTY TRUCK SERVICE MANUAL 6 T -1 6 E M IS S IO N C O N TR O L SYS TE M S throttle lever and prevents full closing of the carburetor throttle plates. This fast idle control when de-energized (plunger retracted) allows throttle plates to close beyond the normal idle position; thereby shutting off air supply and in essence starving the engine so that it will shut down without dieseling. The idle stop solenoid is bracketattached to the carburetor so that the plunger, when extended, contacts the throttle lever. Vacuum Advance Solenoid The vacuum advance solenoid is located on the right front portion of the inlet manifold on small V 8 engines Fig. 7e—Small V8 Vacuum Advance Solenoid Fig. 5e—Idle Stop Solenoid (2-Barrel Carburetor) Fig. 8e—Mark IV V8 Vacuum Advance Solenoid Fig. 6e—Idle Stop Solenoid (4-Barrel Carburetor) and at rear center of the inlet manifold on Mark IV V 8 (fig. 7e and 8e). This electrically operated two-position plunger controlled valve serves to supply or deny vacuum to the distributor vacuum advance unit. In the energized position, the plunger opens the vacuum port from the carburetor to the vacuum advance unit. In opening the vacuum port the plunger simultaneously closes the clean air port at the opposite end. In the de-energized position the spring loaded plunger seats against the vacuum inlet LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YSTEM S 6 T -17 Fig. 1le —Transmission Switch Location (Manual) and opens the distributor advance unit to the clean air vent. Time Relay The time relay is an electrically operated on-off type switch. When the coil is energized, it begins to heat the bi-metal strip to open the normally closed relay points in approximately 20 seconds after the ignition switch is turned on. If the vehicle is not started within 20 seconds and the time relay has completed its “countdown”, it denies vacuum advance until the relay has cooled. Once the relay has run one cycle after the ignition has been turned on, it must cool before it will reactivate even if the ignition is switched off and turned on. A ground path is provided for through the relay housing and mounting bracket. Two self-tapping screws attach Fig. 12e—Turbo Hydra-matic 350 Transmission Switch Location the relay to the upper vertical wall of the cowl at or near centerline of the vehicle (fig. 9e). Temperature Switch The TCS system temperature switch is located in the right cylinder head between the num ber 6 and number 8 exhaust port (fig. lOe). The switch is a two-position single terminal control which provides a path to ground, for the cold override feature, when engine coolant temperatures are below 93 degrees. The “off” or “neutral” position is maintained at engine coolant temperatures above 93 degrees. Transmission Switch Fig. lOe—Small V8 Temperature Switch (Right Head) On manual shift synchromesh transmissions, both 3-and 4-speed, the switch is located on the outside of the transmission case in an area adjacent to the 2-3 or 3-4 shifter shaft, as applicable (fig. lie). The mechanically operated switch is spring loaded to provide continuity between the switch terminal and the switch housing. When installed in the transmission, the' plunger contacts the shifter shaft, which causes the plunger to retract in low forward gears, thereby opening the circuit to ground. LIGHT DUTY TRUCK SERVICE MANUAL 6 T -1 8 E M IS S IO N C O N TR O L S YS TE M S Fig. 15e—Turbo Hydra-matic 400 TCS Connection Fig. 13e—Turbo Hydra-Matic 350 Transmission Switch (Sectional View) When the transmission is shifted into high forward gear, the plunger drops into a recess or flat on the shifter shaft, causing the plunger to extend and allow the cup contact to rest internally on the switch housing. A circuit is completed to ground, from the transmission through the switch housing to the cup contact and through the spring to the electrical terminal. The Turbo Hydra-matic 350 transmissions use a pressure sensitive switch, which is activated by transmission fluid pressure. The switch for Turbo Hydra-matic is installed externally in the 2-3 direct clutch pressure tap (fig. 12e). At rest, in or out of the installed position, the switch is in a normally open position. Construction of the switch is such that a spring loaded diaphragm that contains a metallic contact, is held away from a cup contact, which Fig. 16e—Turbo Hydra-matic 400 TCS Connection Terminal Identification T.C.S. SWITCH VALVE BODY (Sectional View) Fig. 14e—Turbo Hydra-matic 400 TCS Switch Location in turn, is in contact with the switch housing (fig. I 3 e). Transmission fluid pressure, against the insulated plug, forces the diaphragm upward so that the diaphragm contact closes the circuit through the spring to the electrical terminal. The Turbo Hydra-matic 400 transmission also uses a LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YSTEM S pressure sensitive switch which is activated by transmis­ sion fluid pressure. However, the TCS switch is located internally in the transmission (fig. 14e). From its location in the valve body the switch is connected to the externally located, combination detent solenoid and TCS connector (figs. I5e and I 6 e). The normally open switch 6T -19 is constructed so that a spring loaded metallic diaphragm is held away from the terminal in the switch. Transmission fluid pressure forces the diaphragm upward so that the spring seat contacts the electrical terminal to provide continuity through the grounded housing (fig. I7e). LIGHT DUTY TRUCK SERVICE MANUAL Fig. 18e—Vacuum Advance Diagram (V8 Engine) COMPLAINT COMPLAINT COMPLAINT Engine Stalls at Idle Excessive Creep at Idle High Idle Speed Dieseling Vacuum at all Times Poor High Gear Performance S tu m b le -S ta ll on Cold Start Excessive Fuel Consum ption Deceleration Exhaust “ P op ” CAU SE: Transmission Switch M alfunction C A U SE : M a lfu n c tio n in Idle S t o p S o le n o id W ith e n g in e w a r m a n d r u n n in g , put tr a n s m iss io n in lo w fo r w a rd g e a r , t h e a d v a n c e s o le n o id should be d e -e n e rg ize d . If s o le ­ noid energizes, r e m o v e sw itc h c o n n e c tio n re p la c e tra n s m iss io n sw itch if s o le n o id de-energizes. TRUCK Step 3 Step 4 Inoperative Tem perature Inoperative Transmission Advance Solenoid 1. R e m o v e te m p e r a t u r e s w itc h c o n n e c to r . 2. C h e c k relay to m a k e sure t h a t it is c o o l, th e n tu r n igni­ tio n on. 3. S o le n o id s h o u ld en e rg iz e for 2 0 s e c o n d s a n d th e n d e ­ e n e rg iz e . If it d o e s n o t d e ­ ene rgiz e , r e m o v e b lu e lead f r o m tim e relay. S o le n o id will de -e n e rg ize if relay is at fault. P r o c e e d to S t e p 3 if relay is n o t at fa u lt. Switch S witch O n a c o ld e n g in e th e v a c u u m a d v a n c e s o le n o id s h o u ld be e n e r ­ gized, if n o t - g r o u n d th e wire f r o m th e c o ld te rm in a l o f th e te m p e r a t u r e s w itc h . I f s o le n o id e ne rgiz e s, re p la c e th e t e m p e r a ­ tu r e s e n d in g u n it. P r o c e e d to S t e p 4 if u n it is n o t a t fault. W ith e n g in e w a r m a n d ru n n in g , p u t tr a n s m is s io n in reverse o n H y d r a - m a tic o r h igh o n m a n u a ls , s o le n o id s h o u ld b e e n e rg iz e d . If n o t re m o v e a n d g r o u n d c o n n e c t o r at s w i t c h - re p la c e s w itc h if s o le n o id e n e rg iz e s . C heck v a c u u m at s o u rc e , th e n c o n n e c t v a c u u m gauge to a d ­ vance u n it p o r t. W ith 12 volts a pplied to s o le n o id , s o le n o id should be e n e rg iz e d ( v a c u u m to d is trib u to r). P r o c e e d to S t e p 2 if solenoid is n o t at fault. SYSTEMS DUTY Step 2 Inoperative Tim e Relay CONTROL LIGHT Step 1 Inoperative Vacuum EMISSION C h e c k fo r free m o v e m e n t o f plu n g er. C h e c k fo r in c o r r e c tly ad ju ste d p lu n g e r ( o u t t o o far). S o le n o id s h o u ld de -e n e rg ize w ith ig n itio n off. M a lfu n c tio n in T C S S y s te m C o m p o n e n t C h e c k for: B lo w n fuse L o o se c o n n e c t i o n s B ro k e n w ire B ro k e n o r d is c o n n e c te d h o se s P r o p e r g r o u n d at all c o m p o n e n t s P r o p e r ro u tin g o f h oses. M ANUAL 6T 21 SERVICE Fig. 19e—Trouble Shooting Guide (V8 Engine) 6T-22 EMISSION CONTROL SYSTEMS 1 AIR INJECTION REACTOR SYSTEM INDEX General Description......................................................... Theory of Operation....................................................... Maintenance Procedures................................................. Drive Belt........................................................................ Inspection................................................................... Adjustment................................................................. Replacement............................................................... Pump Pulley.................................................................. Replacement............................................................... Air Manifold Hose and T ube................................. Inspection................................................................... Replacement............................................................... 6T-22 6T-26 6T-30 6T-30 6T-30 6T-30 6T-30 6T-30 6T-30 6T-31 6T-31 6T-31 Check Valve(s).............................................................. ..6T-32 Inspection......................................................................6T-32 Replacement............................................................... ..6T-32 Diverter Valve..................................................................6T-32 Inspection......................................................................6T-32 Replacement............................................................... ..6T-32 Air Injection T ube.........................................................6T-32 Inspection......................................................................6T-32 Replacement............................................................... ..6T-33 Air Injection Pum p........................................................6T-33 Inspection......................................................................6T-33 Pressure Relief Valve................................................6T-34 Diagnosis...............................................................................6T-34 GENERAL DESCRIPTION The Air Injection Reactor (A.I.R.) System (figs. If, 2f and 3f), consists of: the air injection pump (with necessary brackets and drive attachments), air injection tubes (one for each cylinder), an air diverter valve, check valves (one for in-line engines, two for V 8 engines) and air manifold assemblies, and hoses necessary to connect the various components. NOTE: A diverter valve vent valve is used with 292 cu. in. engines and 454 cu. in. engines in C20 (except suburban) C30 and P30 Series vehicles originally sold in the state of California. This diverter valve vent valve is employed to shut off the air injection at manifold vacuums above 18" Hg, in order to prevent excessive charge dilution and in­ creased emissions at high inlet manifold vacuums. The vent valve functions by venting the diverter valve diaphragm to atmosphere at vacuums above 18" Hg. (fig. 4f). Carburetors and distributors for engines with the A.I.R. System are designed, particularly, for these engines; therefore they should not be interchanged with or replaced by a carburetor or distributor designed for engines without the A.I.R. System. When properly installed and maintained, the A.I.R. System will effectively reduce exhaust emissions. However, if any A.I.R. component or any engine component that operates in conjunction with the A.I.R. System should malfunction, the exhaust emissions might be increased. Because of the relationship between “Engine Tune U p” and “Unburned Exhaust Gases”, the condition of the Engine Tune Up should be checked whenever the A.I.R. System seems to be malfunctioning. Particular care should be taken in checking items that affect fuel-air ratio such as the crankcase ventilation system, the carburetor and the carburetor air cleaner. Because of the similarity of many parts, typical illustrations and procedures are used except where specific illustrations or procedures are necessary to clarify the operation. LIGHT DUTY TRUCK SERVICE MANUAL EMISSION C ONTROL SYSTEMS 6T-23 Fig. I f —Six-Cylinder A.I.R. System LIGHT DUTY TRUCK SERVICE MANUAL 6 T -2 4 E M IS S IO N C O N TR O L SYS TE M S LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S YS T E M S 6T -25 Fig. 4f—Diverter Valve Vent Valve LIGHT DUTY TRUCK SERVICE MANUAL 6 T -2 6 E M IS S IO N C O N TR O L S YS TE M S THEORY OF OPERATION The Air Injector Reactor (A.I.R.) system (Fig. 5f) is an exhaust emission system that is used to actually burn the unburned portion of the exhaust gases to reduce it’s hydrocarbon and carbon monoxide content. The system is primarily composed of an air pump, diverter valve, check valve(s), combustion pipe assemblies and connect­ ing hoses and fittings. Air is drawn into the air pump, where it is compressed. The compressed air is fed out of the pump through the diverter valve and check valve (operation of these valves will be discussed in later paragraphs) into the combustion pipe assemblies (Fig. 6 f). The combustion pipes route the compressed air into the exhaust manifolds (V-8 engines) or cylinder head exhaust ports (L -6 engines). When this compressed air mixes with the hot exhaust gases in the cylinder head or exhaust manifold, combustion results. This combustion process burns most of the un burned hydrocarbon and carbon monoxide in the exhaust before it leaves the vehicle through the exhaust system. Thus, the exhaust emitted at the tail pipe is low in hydrocarbon and carbon monoxide content. Burning the unburned portion of the exhaust gases is much like fanning dying embers. When the gases leave the cylinders, they are extremely hot and still inflammable if supplied with the other element of combustion - namely oxygen. This oxygen is supplied in the air being supplied by the pump (Fig. 7f). If oxygen is not supplied to this mixture when it first leaves the cylinders, the gases cool down to a non-inflammable mixture by the time they enter the exhaust system. One problem with such a system, however, is that during engine overrun or deceleration, the exhaust gases in the exhaust valve area are overly rich with fuel vapors. If this system was allowed to operate under this condition, a sizable backfire would result as soon as the fresh air from the pump mixed with the overly rich vapor. To eliminate this possibility, a diverter valve has been incorporated into the system. The diverter valve is triggered by sharp rises in vacuum the vacuum signal is taken from just beneath the carburetor throttle plate. When a sharp rise in vacuum is sensed, as during engine overrun, the diverter valve exhausts the air pump out-put into the atmosphere (Fig. 8 f). Since the compressed air from air pump never reaches the air manifolds - no backfire occurs. REAR COVER DRIVE HUB Fig. 5f—Schematic of A.I.R. System ROTOR SHAFT Fig. 7f—Air Injection Pump LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L SYS TE M S COMBUSTION PIPE ASSEMBLY PUMP USING AXIS OF ROTOR ROTATION 6 T -27 VANE ROTOR OUTLET PUMP HOUSING CENTRIFUGAL FILTER INLET VANE SEALS CENTERLINE OF PUMP BORE AND AXIS OF VANE ROTATION VIEW Fig. 9f—Air Injection Pump Components Fig. 8f—Diverter Valve Operation The check valves used in this system are nothing more than one-way valves which prevent exhaust gases from entering and damaging the air injection pump, if for any reason (such as drive-belt failure) the pump becomes inoperative. Under normal operating conditions, air pressure from the pump is sufficient to prevent exhaust gases from entering the pump. One (1) check valve is used per combustion pipe assembly. L -6 engines use one combustion pipe assembly and thus one check valve. V -8 engines use two combustion pipe assemblies (one per bank) and thus two (2 ) check valves. AIR PUMP The 2-vane pump is used in all applications to compress the fresh filtered air and inject it into the exhaust manifold or cylinder head. Pump components and operation are described in the following text. Pump Components (Fig. 9f) 1. Pump housing. 2. Centrifugal filter. 3. Set (2) of vanes which rotate about the centerline of pump housing bore. 4. Rotor which rotates on axis that is different than the centerline of the pump bore or the axis of vane rotation. The rotor drives the vanes and is driven by the pump pulley. 5. Set of seals (two per vane) which provide sealing between the vanes and rotor. The pump vanes are located 180° apart and are in constant contact (or rather near contact) with the pump housing bore. The vanes are driven by the rotor and slide through the slits in the rotor. As the vane rotates past the inlet port, it provides an increasing volume which has the effect of producing a vacuum which draws air into the pump (Fig. lOf). As the vane continues to rotate the other vane has also passed the inlet port. At this point, the air that was drawn into the pump is entrapped between these two vanes. As the vanes continue to rotate the entrapped air is carrier into a smaller volume and thus compressed. Continuing rotation takes the vane past the outlet port. Once the vane is past the outlet port, the compressed air is exhausted out the port into the remainder of the system. Although the discussion has been concentrated on only one cycle, it should be noted that actually two cycles are made with every complete revolution. As mentioned, the two-vane pump uses a centrigugal filter to clean the air as it enters the inlet port of the pump. This centrifugal filter actually opposes air entry into the pump but is not efficient enough to hamper it. This opposing force does, however, discharge any foreign particles in the air from entering the pump. The air enters the pump by passing past the vanes of the centrifugal filter. The vanes of the filter are being rotated at a relatively high r.p.m. These rotating vanes hit any foreign particles in the air trying to enter the pump and rebound them out and away from the pump (Fig. Ilf). DIVERTER VALVE The purpose of the dirverter valve in the system is to momentarily exhaust (divert) the air pumps output so that it does not reach the exhaust valve area during the initial stages of engine overrun (Fig. 12f). During engine overrun; there is a high vacuum state just beneath the carburetors throttle plate drawing rich mixtures of fuel into the cylinders. This rich mixture cannot be completely burned in the power stroke so much of it is exhausted out the exhaust valves. If air from the pump was allowed to combine with this mixture, a backfire would occur. The diverter valve diverts the air pump output at this time as follows: LIGHT DUTY TRUCK SERVICE MANUAL 6 T -2 8 E M IS S IO N C O N TR O L SYS TE M S During normal operation, the diverter valve is in the open position. In this position, air pump output is simply routed through the valve into the remainder of the system. However, during engine overrun, a strong vacuum signal (taken from just below the carburetor’s throttle plate) is sent to the diverter valve’s diaphragm. This vacuum signal is strong enough at this point to overcome the spring force opposing the diaphragm action. Conse­ quently, the diaphragm is pulled up against the spring. The spool valve of the diverter valve is connected directly to the diaphragm so it too moves up and seats in the upper seat. This, then, shuts off the passage into the remainder of the system while at the same time opens a path that exhausts the air pump output through the muffler to the atmosphere. A pressure relief valve is incorporated in the diverter valve to relieve excessive pump pressure. The valve body encloses a preload spring, valve and valve seat. When air The vane is travelling from a small area into a larger area—consequently a vacuum is formed that draws fresh air into the pump. pressure in the pump builds up to a predetermined value, it forces the valve off its seat compressing the spring and dumps pump pressure to atmosphere. The pressure at which the valve opens is determined by the resistance (preload) of the spring. Check Valves and Combustion Pipe Assemblies One check valve is used on each combustion pipe assembly. The combustion pipe assembly(s) route the air pump output to each cylinder in the area of the exhaust valves. L -6 engines used one (1) combustion pipe assembly and one (1) check valve. V -8 engines use two combustion pipe assemblies (one per bank) and two check valves (fig. 13f). The check valve(s) are nothing more than one way valve(s) that allow air flow through them in the direction of the exhaust valves but stop flow through them in the direction of the air pump. This keeps any of the exhaust gases from entering the pump. As the vane continues to rotate, the other vane has rotated past the inlet opening. Now the air that has just been drawn in is entrapped between the vanes. This entrapped air is then transferred into a smaller area and thus compressed. As the vane continues to rotate it passes the outlet cavity in the pump housing bore and exhausts the compressed air into the remainder of the system. Fig. lOf—Air Injection Pump Operation LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N T R O L S YS T E M S EXHAUST OUTLETS PRESSURE RELIEF VALVE OUTLET A MANIFOLD ■METERING VALVE INLET INLET 6T 29 RELIEF VALVE PUMP AIR INLET INTERNAL SILENCER VACUUM SIGNAL TUBE VENT DIVERTED AIR OUTLET (MUFFLER) SIGNAL' LINE CONNECTION DIAPHRAGM TIMING VALVE DIAPHRAGM ASSEMBLY INTERNAL MUFFLER TYPE EXTERNAL MUFFLER TYPE Fig. 12f—Diverter Valve Components AIR ENTERING PUMP AT CENTRIFUGAL • FILTER FOREIGN PARTICLES BEING BOUNCED OFF THE VANES Fig. I l f —Centrifugal Filter Operation Fig. 13f—Air Injection Tubes (Mark IV V8) LIGHT DUTY TRUCK SERVICE MANUAL 6 T -3 0 E M IS S IO N C O N TR O L S Y S TE M S M AIN TENA NCE PROCEDURES Drive Belt drive belt then torque pump pulley bolts to 25 ft. lbs. (fig. 15f). Inspection • Inspect drive belt for wear, cracks or deterioration • Recheck drive belt tension and adjust if required. and replace if required. Pump Filter • Inspect belt tension and adjust if below 50 lbs. using Replacement a strand tension gauge. • Remove drive belt and pump pulley as previously Adjustment outlined. • Loosen pump mounting bolt and pump adjustment bracket bolt or Delcotron mounting bolt and adjustment bracket as applicable. • Move pump or Delcotron until belt is properly tensioned then tighten adjustment bracket bolt and mounting bolt. Use a strand tension gauge to check adjustment (fig. 14f). CAUTION: Do not pry on the pump housing. Distortion of the housing will result in extensive damage to the Air Injection Pump. Replacement • Loosen pump mounting bolt and pump adjustment bracket bolt or Delcotron as applicable, then swing pump until drive belt may be removed. • Install a new drive belt and adjust as outlined above. Pump Pulley Replacement • Hold pump pulley from turning by compressing drive belt then loosen pump pulley bolts. • Remove drive belt as outlined above then remove pump pulley. • Install pump pulley with retaining bolts hand tight. • Install and adjust drive belt as outlined above. • Hold pump pulley from turning by compressing Fig. 14f—Checking A.I.R. Pump Belt Tension Fig. 15f—Tightening Pump Pulley Bolts Fig. 16f—Removing Centrifugal Filter LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L SYS TE M S 6 T -3 1 • Pry loose outer disc of filter fan. • Pull filter off with pliers (fig. I 6 f). NOTE: Care should be taken to prevent fragments from entering the air intake hole. • Install the new filter by drawing it on with the pulley and pulley bolts (fig. I7f). Do not attempt to install a filter by hammering it on or pressing it on. • Draw the filter down evenly by alternately torquing the bolts. Make certain that the outer edge of the filter slips into the housing. The slight amount of interference with the housing bore is normal. NOTE: A new filter may squeal upon initial operation until its O.D. sealing lip has worn in. Air Manifold, Hose and Tube Inspection • • • • Inspect all hoses for deterioration or holes. Inspect all tubes for cracks or holes. Check all hose and tube connections. Check all tube and hose routing (fig. I 8 f and 19f). Interference may cause wear. • If leak is suspected on the pressure side of the system or any tubes and/or hoses have been disconnected on the pressure side, the connections should be checked for leaks with a soapy water solution. • With the pump running, bubbles will form if a leak exists (fig. 20 f). Replacement • To replace any hose and/or tube, note routing then Fig. 19f—Small V8 A.I.R. Hoses Fig. 17t—Installing Centrifugal Filter CAUTION: The 1/4" pipe threads at the cylinder head on L-6 or the exhaust manifolds on V8 are a straight pipe thread. Do not use a 1/4" tapered pipe tap. The hoses of the A.I.R. System are a special material to withstand high temperature. No other type hose should be substituted. Install new hose(s) and/or tube(s), routing them as when removed. • Tighten all connections. NOTE: Use anti seize compound on threads • Fig. 18f—Mark IV V8 A.I.R. Hoses LIGHT DUTY TRUCK SERVICE MANUAL 6 T -3 2 E M IS S IO N C O N TR O L S YS TE M S AIR SHOULD FLOW IN THIS DIRECTION O NLY____________ Fig. 2 I f —Air Flow Through Check Valve Fig. 20f—Checking for Leaks With a Soapy Water Solution of the air manifold to exhaust manifold or cylinder connections. CAUTION: Diverter valves although sometimes similar in appearance are designed to meet particular requirements of various engines, therefore, be sure to install the correct valve. Replacement Check Valve Inspection • The check valve should be inspected whenever the hose is disconnected from the check valve or whenever check valve failure is suspected. (A pump that had become inoperative and had shown indications of having exhaust gases in the pump would indicate check valve failure.) • Orally blow through the check valve (toward air manifold) then attempt to suck back through check valve. Flow should only be in one direction (toward the air manifold) (fig. 2 If). • Disconnect vacuum signal line. Disconnect valve exhaust hose(s). • Remove diverter valve from pump or elbow. • Install diverter valve to pump or elbow with new gasket. Torque valve attaching screws to 85 in. lbs. • Install outlet and vacuum signal lines and check system for leaks. Air Injection Tube Inspection (Fig. 25f) • There is no periodic service or inspection for the air Replacement • Disconnect pump outlet hose at check valve. Remove check valve from air manifold, being careful not to bend or twist air manifold (fig. 22 f). Diverter Valve Inspection • Check condition and routing of all lines especially the signal line. All lines must be secure, without crimps and not leaking. • Disconnect signal line at valve. A vacuum signal must be available with engine running (fig. 23f). • With engine stabilized at idle speed, no air should be escaping through the muffler. Manually open and quickly close the throttle, a momentary blast of air should discharge through muffler for at least one second (fig. 24f). • Defective valves should be replaced. Fig. 22f—Removing Check Valve LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L S Y S T E M S injection tubes, yet on in-line engines whenever the cylinder head is removed or on V 8 engines whenever the exhaust manifolds are removed, inspect the air injection tubes for carbon build up and warped or burned tubes. • Remove any carbon build up with a wire brush. • Warped or burned tubes must be replaced. Replacement • On in-line engines remove carbon from tubes and using penetrating oil, work tubes out of cylinder head. • On V 8 engines clamp exhaust manifold in a vise, 6T -33 remove carbon from tubes and using penetrating oil, work tubes out of manifold. Air Injection Pump Inspection Accelerate engine to approximately 1500 RPM and observe air flow from hose(s). If air flow increases as engine is accelerated, pump is operating satisfactorily. If air flow does not increase or is not present, proceed as follows: • Check for proper drive belt tension. • Check for a leaky pressure relief valve. Air may be heard leaking with the pump running. NOTE: The A.I.R. System is not completely noiseless. Under normal conditions noise rises in pitch as engine speed increases. To determine if excessive noise is the fault of the Air Injection Reactor System, operate the engine with the pump drive belt removed. If excessive noise does not exist with the belt removed proceed as follows: • Check for a seized Air Injection Pump. • Check hoses, tubes, air manifolds and all connec­ tions for leaks and proper routing. • Check air injection pump for proper mounting. • If none of the above conditions exist and the air injection pump has excessive noise remove and replace pump runit. Replacement Fig. 23f—Checking for Vacuum Signal at Diverter Valve Fig. 24f—Momentary Blast of Air Through Diverter Valve During Engine Over Run • • • • • • Disconnect the hoses at the pump. Remove pump pulley as outlined. Remove pump mounting bolts and remove pump. Install pump with mounting bolts loose. Install pump pulley as outlined. Install and adjust belt as outlined. Fig. 25f—Air Injection Tubes (In-Line Engine) LIGHT DUTY TRUCK SERVICE MANUAL 6 T -3 4 E M IS S IO N C O N TR O L SYS TE M S • Connect the hoses at the pump. • Tighten mounting bolts securely. Pressure Relief Valve NOTE: The pressure relief valve is incorpo­ rated in the diverter valve. The complete unit must be replaced to correct a malfunction of the relief valve. DIAGNOSIS While the A.I.R. system will result in exhaust emissions below the requirements when it is properly installed and maintained, it will not provide the desired reduction in exhaust emissions if some of the engine components malfunction. Because of the relationship between “Engine Tune U p” and “Unburned Exhaust Gases”, the condition of Engine Tune Up should be checked whenever the Air Injection Reactor System seems to be malfunctioning. Particular care should be taken in checking items that affect the fuel-air ratio such as the crankcase ventilation system, the carburetor and the carburetor air cleaner. If all other components seem to be operating satisfactorily, visually inspect A.I.R. system for loose drive belts, loose or deteriorated hoses and missing or broken components. If after completion of tune-up and visual inspection, malfunction still exists, refer to the diagnosis chart for symptons, probable cause, and remedy. NOTE: The A.I.R. system is not completely noiseless. Under normal conditions, noise rises in pitch as engine speed increases. To determine if excessive noise is the fault of the air injection system, disconnect the drive belt and operate the engine. If noise now does not exist, proceed with diagnosis. LIGHT DUTY TRUCK SERVICE MANUAL E M IS S IO N C O N TR O L SYS TE M S C O N D IT IO N No air supply — accelerate engine to 1 5 0 0 rpm and observe air flo w fro m hoses. If the flo w increases as the rpm's increase, the pum p is functioning norm ally. If not, check possible cause. Excessive pump noise, chirping, rum bling, or knocking 6 T -35 C O R R E C T IO N P O SSIB LE C A U S E 1. Loose drive belt 1. Tighten to specs. 2. Leaks in supply hose 2. Locate leak and repair 3. Leak at fitting(s) 3. Tighten or replace clamps. 4. D iverter valve leaking 4. If air is expelled through diverter m u ffle r w ith vehicle at idle, replace diverter valve. 5. D iverter valve inoperative 5. Usually accompanied by backfire during deceleration. Replace diverter valve. 6. Check valve inoperative 6. Blow through hose tow ard air m anifold, if air passes, function is norm al. If air can be sucked from m an ifo ld , replace check valve. 1. Leak in hose 1. Locate source o f leak using soap solution and correct. 2. Loose hose 2. Reassemble and replace or tighten hose clamp. 3. Hose touching other engine parts 3. A djust hose position. 4. D iverter valve inoperative 4. Replace diverter valve. 5. Check valve inoperative 5. Replace check valve. 6. Pump m ounting fasteners loose 6. Tighten m ounting screws as specified. 7. 7. Pump failure Replace pump. 1. Loose belt 1. Tighten to spec. 2. Seized pump 2. Replace pum p Excessive pump noise. Chirping 1. Insufficient break-in 1. Run vehicle 10-15 miles at turnp ike speeds—recheck. Centrifugal filte r fan damaged o r broken. 1. Mechanical damage 1. Replace centrifugal filte r fan. Exhaust tube bent or damaged. 1. Mechanical damage 1. Replace exhaust tube. Poor idle or driveability. 1. A defective A .I.R . pum p cannot cause poor idle or driveability. 1. Do not replace A .I.R . pum p. Excessive belt noise Fig. 26F—A.I.R. System Diagnosis' Chart LIGHT DUTY TRUCK SERVICE MANUAL SECTION 6Y ENGINE ELECTRICAL CONTENTS OF THIS SECTION Energizer/Battery........................................................... 6Y-1 Charging System............................................................ 6Y-17 Ignition System.................................................................. 6Y-24 Starting System.................................................................. 6Y-50 Special Tools...................................................................... 6Y-61 ENERGIZER/BATTERY INDEX General Description........................................................ Theory of Operation....................................................... General Inform ation....................................................... Common Causes of Failure....................................... Care of Energizer....................................... ................... Energizer Storage...................................... ................... Electrolyte Freezing..................................................... Electrolyte Level Indicator.................... ................... Electrolyte Level........................................ ................... W ater Usage............................................. ................... 6Y-1 6 Y -2 6Y-4 6Y-4 6Y4 6Y-4 6Y4 6Y-5 6Y-5 6 Y -6 Carrier and Hold-Down......................................... .......... 6Y -6 C leaning................................................................ ......... 6Y -6 Energizer R ating.................................................. ......... 6 Y -6 Selecting and Replacement Energizer.......... ......... 6 Y -6 Safety Precautions.......................................................... 6Y-7 Charging Procedures........................................... ......... 6Y-7 Charging G uide.............................................................. 6Y -8 Test Procedures............................................................... 6Y -8 Installing Battery.................................................. ......... 6Y-10 Diagnosis.............................................................................. 6Y-15 GENERAL DESCRIPTION The energizer (fig. lb) is made up of a number of separate elements, each located in an individual cell in a hard rubber case. Each element consists of an assembly of positive plates and negative plates containing dissimilar active materials and kept apart by separators. The elements are immersed in an electrolyte composed of dilute sulfuric acid. Plate straps located on the top of each element connect all the positive plates and all the PARTITION ON E PIECE COVER LEVEL INDICATOR VENT PLUGS CONNECTOR ^sr ^ ^ Fig. lb —Energizer ^ ^ - ^ n. ^ ^ = -«=N ■ ^ ^ ^ ^ Fig. 2b—Internal View of Energizer LIGHT DUTY TRUCK SERVICE MANUAL I 6 Y - 2 E N G IN E ELE C TR IC A L negative plates into groups. The elements are connected in series electrically by connectors that pass directly through the case partitions between cells. The energizer top is a one piece cover. The cell connectors, by passing through the cell partitions, connect the elements along the shortest practical path (fig. 2b). With the length of the electrical circuit inside the Energizer reduced to a minimum, the internal voltage drop is decreased resulting in improved performance, particuarly during engine cranking at low temperatures. The terminals of this type Energizer, passing through the side of the case, are positioned out of the "wet" area surrounding the vent wells. Normal spillage, spewing, condensation, and road splash are not as likely to reach or remain on the vertical sides where the terminals are located. This greatly decreases the cause of terminal corrosion. Also, construction of the terminals is such that the mating cable connector seals the junction and provides a permanently tight and clean connection. Power robbing resistance in the form of corrosion is thereby eliminated at these m aintenance-free connections. The hard, smooth, one piece cover greatly reduces the tendency for corrosion to form on the top of the Energizer. The cover is bonded to the case forming an air-tight seal between the cover and case. Electrical energy is released by chemical reactions between the active materials in the two dissimilar plates and the electrolyte whenever the Energizer is being "discharged." Maximum electrical energy is released only when the cells are being discharged from a state of full charge. As •the cells discharge, chemical changes in the active materials in the plates gradually reduce the potential electrical energy available. "R echarging" the Energizer with a flow of direct current opposite to that during discharge reverses the chemical changes within the cells and restores them to their active condition and a state of full charge. There are two types of Energizers, the "dry charge" type and the "wet charge" type. The difference in types depends on the method of manufacture. A "dry charge" Energizer contains fully charged elements which have VENT WELL SEAL SPLIT VENT Fig. 3b—Typical Vent Well Construction W/Seal been thoroughly washed and dried. This type of Energizer contains no electrolyte until it is activated for service in the field and, therefore, leaves the factory in a dry state. Consequently, it is called a "dry charge" Energizer. Each vent well in a "dry charge" Energizer has a hard rubber seal to prevent the entrance of air and moisture which would oxidize the negative active materials and reduce the freshness of the Energizer (Fig. 3b). The hard rubber seals and the bonding between the case and onepiece cell cover make possible a vacuum sealed assembly which can be stored for very long periods of time without detrimental effects. Before activating the "dry charge" Energizer, the hard rubber seals are broken simply by pushing the special vent plug down into each vent well. The seals drop into the cells, and can remain there since they are not chemically active and will cause no harm. A wet charged Energizer contains fully charged elements which are filled with electrolyte before being shipped from the factory. THEORY OF OPERATION The lead-acid Energizer or storage battery (Fig. lb) is an electrochemical device for converting chemical energy into electrical energy. It is not a storage tank for electricity as is often believed, but instead, stores electrical energy in chemical form. Active materials within the battery react chemically to produce a flow of direct current whenever lights, radio, cranking motor, or other current consuming devices are connected to the battery terminal posts. This current is produced by chemical reaction between the active materials of the PLATES and the sulfuric acid of the ELECTROLYTE. The battery performs three functions in automotive applications: 1. It supplies electrical energy for the cranking motor and for the ignition system as the engine is started. 2. It supplies current for the lights, radio, heater, and other accessories when the electrical demands of these devices exceed the output of the generator. 3. The battery acts as a voltage stabilizer in the LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L 6 Y -3 2 VOLT BATTERY CELL Fig. 4b—Battery Element (Simple) Fig. 5b—Two Volt Battery Cell Fig. 6b—Battery Element (Compound) electrical system. Satisfactory operation of the vehicle is impossible unless the battery performs each of these functions. The simplest unit of a lead-acid storage battery is made up of two unlike materials, a positive plate and a negative plate, kept apart by a porous separator. This assembly is called an "ELEM ENT" (Fig. 4b). When this simple element is put in a container filled with a sulphuric acid and water solution called "electrolyte", a two-volt "cell" is formed. Electricity will flow when the plates are connected to an electrical load (Fig. 5b). An element made by grouping several positive plates together and several negative plates together with separators between them also generates two-volts but can produce more total electrical energy than a simple cell (Fig. 6 b). When six cells are connected in series, a "battery" of cells is formed which produces six times as much electrical pressure as a simple cell, or a total of 12 volts (Fig. 7b). If the battery continuously supplies current, it becomes run-down or discharged. This is where the generator gets into the act. The generator restores the chemical energy to the battery. This is done by sending current through the battery in a direction opposite to that during discharge. The generator current reverses the chemical actions in the battery and restores it to a charged condition. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 4 E N G IN E ELE C TR IC A L GENERAL IN FO R M A TIO N COMMON CAUSES OF FAILURE Since the Energizer is a perishable item which requires periodic servicing, a good maintenance program will insure the longest possible Battery life. If the Energizer tests good but fails to perform satisfactorily in service for no apparent reason, the following are some of the more important factors that may point to the cause of the trouble. 1. Vehicle accessories inadvertently left on overnight to cause a discharge condition. 2. Slow speed driving of short duration, to cause an undercharged condition. 3. A vehicle electrical load exceeding the generator capacity. 4. Defect in the charging system such as high resistance, slipping fan belt, faulty generator or voltage regulator. 5. Battery abuse, including failure to keep the Battery top clean, cable attaching bolts clean and tight, and improper addition of water to the cells. CARE OF ENERGIZER Energizer Storage Since the "dry charge" Energizer is vacuum sealed against the entrance of moisture, it may be stored for very long periods of time without detrimental effects so long as the seals remain unbroken. When storing a "dry charge" Energizer, the following procedures should be followed: 1. Keep the Energizer in its shipping carton until activated. 2. Do not stack the "dry charge" Energizer in cartons more than four high. 3. Rotate stocks regularly. 4. M aintain the storage area at 60°F or higher to aid activation. A wet charged Energizer will not m aintain its charged condition during storage, and must be recharged periodically. During storage, even though the Energizer is not in use, a slow reaction takes place between the chemicals inside the Energizer which causes the Energizer to lose charge and "wear out" slowly. This reaction is called "self-discharge." The rate at which self-discharge occurs varies directly with temperature of the electrolyte. Note from Figure 8 b that an Energizer stored in an area at 100°F for 60 days has a much lower specific gravity and consequently a lower state of charge than one stored in an area at 60°F for the same length of time. To minimize self-discharge, a wet Energizer should be stored in as cool a place as possible, provided the electrolyte does not freeze. A wet Energizer which has been allowed to stand idle for a long period of time without recharging may become so badly damaged by the growth of lead sulfate crystals (sulfation) in the plates that it can never be restored to a norm al charged condition. An Energizer in this condition not only loses its capacity but also is subject to changes in its charging characteristics. These changes, due to self-discharge, are often serious enough to prevent satisfactory performance in a vehicle. Periodic recharging, therefore, is necessary to maintain a wet charged Energizer in a satisfactory condition while in storage. See paragraph "Charging Wet Energizer in Storage." Charging Wet Energizer in Storage Before placing an Energizer on charge, always check the electrolyte level and add water, as necessary, to bring the electrolyte up to the bottom of the split vent. The Energizer should be brought to a fully charged condition every 30 days by charging as covered under heading of "Energizer Charging." Trickle charging should not be used to m aintain an Energizer in a charged condition when in storage. The low charge rate method applied every 30 days is the best method of maintaining a wet charged Energizer in a fully charged condition without damage. Electrolyte Freezing The freezing point of electrolyte depends on its specific 1.160 1.140 0 10 20 30 40 50 60 70 80 90 DAYS STANDING Fig. 8b— Rate of Self-Discharge LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L gravity. The following table gives the freezing temperatures of electrolyte at various specific gravities. Since freezing may ruin a wet Energizer, it should be protected against freezing by keeping it in a charged condition. This is true whether the wet Energizer is in storage or in service. Antifreeze should never be added to the Energizer to prevent it from freezing as this practice is very harmful. Electrolyte Level Indicator The Energizer features an electrolyte level indicator, which is a specially designed vent plug with a transparent rod extending through the center. When the electrolyte is at the proper level, the lower tip of the rod is immersed, and the exposed top of the rod will appear very dark (fig. 9b); when the level falls below the tip of the rod, the top will glow (fig. 10b). Value of Specific Gravity Corrected to 80°F. Freezing Temp. Deg. F. 1.100 1.120 18 13 1.140 1.160 1.180 1.200 8 1 - 6 -17 Value of Specific Gravity Corrected to 80°F. 1.220 1.240 1.260 1.280 1.300 6 Y -5 The indicator reveals at a glance if water is needed, without the necessity of removing the vent plugs. The Level Indicator is used in only one cell (second cell cap from positive terminal) because when the electrolyte level is low in one cell, it is normally low in all cells. Thus when the indicator shows water is needed, check the level in all six cells. An alternate method of checking the electrolyte level is to remove the vent plug and visually observe the electrolyte level in the vent well. The bottom of the vent well features a split vent which will cause the surface of the electrolyte to appear distorted when it makes contact. The electrolyte level is correct when the distortion first appears at the bottom of the split vent (fig. lib). Electrolyte Level The electrolyte level in the Energizer should be checked regularly. In hot weather, particularly during trip Freezing Temp. Deg. F. -13 -50 -75 -92 -95 Fig. 1Ob—Electrolyte at Low Level Fig. 9b—Electrolyte at Proper Level Fig. l i b —View Inside Vent Well LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 6 E N G IN E E LE C TR IC A L driving, checking should be more frequent because of more rapid loss of water. If the electrolyte level is found to be low, then colorless, odorless, drinking water should be added to each cell until the liquid level rises to the split vent located in the bottom of the vent well. DO NOT OVERFILL because this will cause loss of electrolyte resulting in poor performance, short life, and excessive corrosion. CAUTION: During service only water should be added to the Battery, not electrolyte. The liquid level in the cells should never be allowed to drop below the top of the plates, as the portion of the plates exposed to air may be permanently damaged with a resulting loss in performance. Water Usage Excessive usage of water indicates the Battery is being overcharged. The most common causes of overcharge are high Battery operating temperatures, too high a voltage regulator setting, poor regulator ground wire connection. Normal Battery water usage is approximately one to two ounces per month per battery. Carrier and Hold-Down The Energizer carrier and hold-down should be clean and free from corrosion before installing the Battery. The carrier should be in sound mechanical condition so that it will support the Battery securely and keep it level. To prevent the Battery from shaking in its carrier, the hold-down bolts should be tight (60-80 in. lbs.). However, the bolts should not be tightened to the point where the Battery case or cover will be placed under a severe strain. Cleaning The external condition of the Energizer should be checked periodically for damage such as cracked cover, case and vent plugs or for the presence of dirt and corrosion. The Energizer should be kept clean. An accumulation of acid film and dirt may permit current to flow between the terminals, which will slowly discharge the Battery. For best results when cleaning Energizers, wash first with a diluted ammonia or a soda solution to neutralize any acid present; then flush with clean water. Care must be taken to keep vent plugs tight, so that the neutralizing solution does not enter the cells. the Energizer. This value is determined by multiplying the max. current by the max. voltage. The PWR should not be confused with the ampere hour rating since two batteries with the same ampere hour rating can have quite different watt ratings. For battery replacement, a unit of at least equal power rating must be selected. SELECTING A REPLACEMENT ENERGIZER Long and troublefree service can be more assured when the capacity or wattage rating of the replacement Energizer is at least equal to the wattage rating of the Energizer originally engineered for the application by the manufacturer. The use of an undersize Energizer may result in poor performance and early failure. Figure 12b shows how Energizer power shrinks while the need for engine cranking power increases with falling temperatures. Sub­ zero temperatures reduce capacity of a fully charged Energizer to 45% of its normal power and at the same time increase cranking load to 3-1/2 times the normal warm weather load. Hot weather can also place excessive electrical loads on the Energizer. Difficulty in starting may occur when cranking is attempted shortly after a hot engine has been turned off or stalls. In fact, modern high compression engines can be as difficult to start under such conditions as on the coldest winter day. Consequently, good performance can be obtained only if the Energizer has ample capacity to cope with these conditions. An Energizer of greater capacity should be considered if the electrical load has been increased through the addition of accessories or if driving conditions are such that the generator cannot keep the Energizer in a charged condition. On applications where heavy electrical loads are encountered, a higher output generator that will supply a charge during low speed operation may be required to increase Energizer life and improve Energizer performance. ENERGIZER RATING battery generally has two classifications of ratings: ( 1) a 20 hour rating at 80 F and, (2) a cold rating at 0 F which indicates the cranking load capacity. The Am pere/Hour rating found on batteries was based on the 20 hour rating. That is, a battery capable of furnishing three (3) amperes for 20 hours while m aintaining a specified average individual cell voltage would be classified as a 60 ampere hour battery (e.g. 3 amperes X 20 hours = 60 A.H.) a PWR (Peak Watt Rating) has been developed as a measure of the Energizer’s cold cranking ability. The numerical rating is embossed on each case at the base of LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E E L E C T R IC A L Fig. 13b—Sparks or Flames SAFETY PRECAUTIONS When Energizers are being charged, an explosive gas mixture forms in each cell. Part of this gas escapes through the holes in the vent plugs and may form an explosive atmosphere around the energizer itself if ventilation is poor. This explosive gas may remain in or around the energizer for several hours after it has been charged. Sparks or flames can ignite this gas causing an internal explosion which may shatter the energizer (Fig. 13b). The following precautions should be observed to prevent an explosion: 1. Do not smoke near energizers being charged or which have been very recently charged. 2. Do not break live circuits at the terminals of energizers because a spark usually occurs at the point where a live circuit is broken. Care must always be taken when connecting or disconnecting booster leads or cable clamps on fast chargers. Poor connections are a common cause of electrical arcs which cause explosions. CHARGING PROCEDURES Before charging an energizer the electrolyte level must be checked and adjusted if needed. Energizer charging consists of applying a charge rate in amperes for a period of time in hours. Thus, a 10-ampere charge rate for seven hours would be a 70 ampere-hour (A.H.) charging input to the battery. Charging rates in the three to 50 ampere range are generally satisfactory. No particular charge rate or time can be specified for.an energizer due to the following factors: 1. The size, or electrical capacity in ampere-hours (A.H.), of the Energizer. EXAMPLE: A completely discharged 70 A.H. energizer requires almost twice the recharging as a 40 A.H. energizer. 2. Temperature of the energizer electrolyte. 6Y -7 EXAMPLE About two hours longer will be needed to charge a 0°F. energizer than a 80°F. energizer. 3. Energizer state-of-charge at the start of the charging period. EXAMPLE: A completely discharged energizer requires twice as much charge in ampere-hours as a one-half charged energizer. Energizer age and condition. EXAMPLE: An energizer that has been subjected to severe service will require up to 50% more amperehour charging input than a relatively new energizer. The following basic rule applies to any energizer charging situation: “Any energizer may be charged at any rate in amperes for as long as spewing of electrolyte due to violent gassing does not occur, and for as long as electrolyte temperature does not exceed 125°F. If spewing of electrolyte occurs, or if electrolyte temperature exceeds 120°F., the charging rate in amperes must be reduced or temporarily halted to avoid damage to the Energizer. The energizer is fully charged when over a two-hour period at a low charging rate in amperes all cells are gassing freely (not spewing liquid electrolyte), and no change in specific gravity occurs. The full charge specific gravity is 1.260-1.280, corrected for electrolyte tempera­ ture with the electrolyte level at the split ring, unless electrolyte loss has occuried due to age or overfilling in which case the specific gravity reading will be lower. For the most satisfactory charging, the lower charging rates in amperes are recommended. If after prolonged charging a specific gravity of at least 1.230 on all cells cannot be reached, the battery is not in an optimum condition and will not provide optimum performance; however, it may continue to provide additional service if it has performed satisfactorily in the past. An “emergency boost charge”, consisting of a high charging rate for a short period of time, may be applied as a temporary expedient in order to crank an engine. However, this procedure usually supplies insufficient energizer reserve to crank a second and third time. Therefore, the “emergency boost charge” must be followed by a subsequent charging period of sufficient duration to restore the battery to a satisfactory state of charge. Refer to the charging guide in this section. When out of the vehicle, the sealed side terminal battery will require adapters (Fig. 14b) for the terminals to provide a place for attachment of the charging leads. Adapters are available through local parts service. When the side terminal battery is in the vehicle, the studs provided in the wiring harness are suitable for attachment of the charger’s leads. CAUTION: Exercise care when attaching charger leads to side terminal studs to avoid contact with vehicle metal components which would result in damage to the energizer. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -8 E N G IN E E LE C TR IC A L CHARGING GUIDE RECOMMENDED RATE* AND TIME FOR FULLY DISCHARGED CONDITION CAUTION: EXERCISE CARE WHEN ATTACHING CHARGER LEADS TO SIDE TERMINAL STUDS TO AVOID CONTACT WITH VEHICLE METAL COMPONENTS WHICH COULD RESULT IN DAMAGE TO THE ENERGIZER. 30 Amperes 40 Amperes 50 Amperes 20 Amperes 10 Amperes 5 Amperes Watt Rating 2 Hours 5 Hours 2-1 /2 Hours 10 Hours Below 2450 2 Hours 1-1/2 Hours 3 Hours 6 Hours 12 Hours 2450-2950 2 Hours 1 -3/4 Hours 3-1/4 Hours 1-1/2 Hours 15 Hours 7-1/2 Hours Above 2950 *Initial rate for constant voltage taper rate charger. To avoid damage, charging rate must be reduced or temporarily halted if: 1. Electrolyte temperature exceeds 125°F. 2. Violent gassing or spewing of electrolyte occurs. Battery is fully charged when over a two hour period at a low charging rate in amperes all cells are gassing freely and no change in specific gravity occurs. For the most satisfactory charging, the lower charging rates in amperes are recommended. Full charge specific gravity is 1.260-1.280 corrected for temperature with electrolyte level at split ring. Fig. 14b—Charging Lead Adapters TESTING PROCEDURES Visual Inspection Testing procedures are used to determine whether the battery is ( 1) good and usable, (2 ) requires recharging or (3) should be replaced. Analysis of battery conditions can be accomplished by perform ing a visual inspection, instrument test and the full charge hydrometer test. Refer to test procedure chart in this section. The first step in testing the battery should be a visual inspection, which very often will save time and expense in determining battery condition. • Check the outside of the battery for a broken or cracked case or a broken or cracked cover. If any damage is evident, the battery should be replaced. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L • Note the electrolyte level. Levels that are too low or too high may cause poor performance, as covered in the section entitled “General Inform ation” . • Check for loose cable connections. Correct as required before proceeding with tests. Instrument Test A number of suppliers have approved testing equipment available. These testers have a programmed test procedure consisting of a series of timed discharge and charge events, requiring approximately 2 to 3 minutes, that will determine the condition of the battery with a high degree of accuracy. When using these testers, the procedure recommended by the tester m anufacturer should be followed. Batteries should not be charged prior to testing as doing so may alter the test results. If a tester is not available for testing, the “Specific Gravity Cell Comparison Test” may be used or an alternate method, but with a sacrifice in testing accuracy. NOTE: New energizers which have become completely discharged over a relatively long period of time, such as during vehicle storage, should be tested by the hydrometer method. Energizers discharged to this degree cannot be accurately tested using equipment requiring load capability comparison tests. 6 Y -9 To begin, charge the battery, if necessary, until all cells are at least 1.200 specific gravity. 1. If unable to obtain specific gravity 1.200 @ 80°F. in all cells, replace battery. 2. If able to obtain a specific gravity of 1.200 or more @ 80°F. in all cells, remove the vent caps and connect a 300 amp. load for 15 seconds. a. If smoke occurs in one or more cells, replace the battery. b. If smoke does not occur proceed to step 3. 3. Place a thermometer in one cell and apply a specified load from chart No. 1. Read the voltage at 15 seconds with load connected, then remove load and read electrolyte temperature. Compare temper­ ature and voltage readings with chart No. 2. a. If reading is less than voltage on chart No. 2, replace battery. b. If reading is same as or greater than voltage on chart No. 2, fully charge, clean and return battery to service. Full Charge Hydrometer Test This test should be used only on Energizers which test good with testing equipment or “Specific Gravity Cell Comparison Test” but which subsequently fail in service. • Remove the Energizer from the vehicle, and adjust the electrolyte level as necessary, by adding colorless, odorless, drinking water. • Fully charge the Energizer at the Slow Charging rate as covered in the section entitled “Charging Procedures”. • Measure the specific gravity of the electrolyte in each cell and interpret as follows: Hydrometer Reading Less Than 1.230—Full charge hydrometer readings less than 1.230 corrected for temperature indicate the Battery is defective and should be replaced. Hydrometer Readings Above 1.310—Full charge hydrometer readings above 1.310 corrected for temperature indicate that the cells have been improperly filled (activation) or improperly serviced. Poor service and short Battery life will result. In addition to the instrument test and full charge hydrometer test, the following load test may also be performed to check the condition of the battery. NOTE: Equipment to perform this test may be procured from local suppliers of testing equipment. MODEL NO. Y86 R88 R88 W AMP LOAD 130 180 230 CHART NO. 2 VOLTAGE AND TEMPERATURE CHART Electrolyte Temperature Down to 80° 70° 60° 50° o 0 o O O O ■'t co Load Test CHART NO . 1 ENERGIZER LOAD TEST VALUES 10° 0 Minimum Voltages* 9.6 9.6 9.5 9.4 9.3 9.1 8.9 8.7 8.5 ♦Voltage must not drop below minimum listed at given temperature when battery is subjected to the proper load for 15 seconds and is 1.200 specific gravity @ 80° F. or more. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 1 0 E N G IN E ELE C TR IC A L Specific Gravity Readings (Fig. 15b) A hydrometer can be used to measure the specific gravity of the electrolyte in each cell. The hydrometer measures the percentage of sulphuric acid in the battery electrolyte in terms of specific gravity. As a battery drops from a charged to a discharged condition, the acid leaves the solution and enters the plates, causing a decrease in specific gravity of electrolyte. An indication of the concentration of the electrolyte is obtained with a hydrometer. When using a hydrometer, observe the following points: 1. Hydrometer must be clean, inside and out, to insure an accurate reading. 2. Hydrometer readings must never be taken immedi­ ately after water has been added. The water must be thoroughly mixed with the electrolyte by charging for at least 15 minutes at a rate high enough to cause vigorous gassing. 3. If hydrometer has built-in thermometer, draw liquid into it several times to insure correct temperature before taking reading. 4. Hold hydrometer vertically and draw in just enough liquid from batttery cell so that float is free floating. Hold hydrometer at eye level so that float is vertical and free of outer tube, then take reading at surface of liquid. Disregard the curvature where the liquid rises against float stem due to surface tension. 5. Avoid dropping battery fluid on car or clothing as it is extremely corrosive. Any fluid that drops should be washed off immediately with baking soda solution. The specific gravity of the electrolyte varies not only with the percentage of acid in the liquid but also with temperature. As temperature increases, the electrolyte expands so that the specific gravity is reduced. As temperature drops, the electrolyte contracts so that the specific gravity increases. Unless these variations in specific gravity are taken into account, the specific gravity obtained by the hydrometer may not give a true indication of the concentration of acid in the electrolyte. A fully charged Battery will have a specific gravity reading of approximately 1.270 at an electrolyte temperature of 80°F. If the electrolyte temperature is above or below 80°F, additions or subtractions must be made in order to obtain a hydrometer reading corrected to the 80°F standard. For every 10° above 80°F, add four specific gravity points (.004) to the hydrometer reading. Example: A hydrometer reading of 1.260 at 110°F would be 1.272 corrected to 80°F, indicating a fully charged Battery. For every 10° below 80°F, subtract four points (.004) from the reading. Example: A hydrometer reading of 1.272 at 0°F would be 1.240 corrected to 80°F, indicating a partially charged Battery. Specific Gravity Cell Comparison Test This test may be used when an instrument tester is not DO NOT SUCK | f ^ \ H O L D IN TOO MUCH ---- N TUBE ELECTROLYTE / \ VERTICAL FLOAT MUST BE FREE TAKE READING AT EYE LEVEL Fig. 15b—Checking Specific Gravity available. To perform this test measure the specific gravity of each cell, regardless of state of charge, and interpret the results as follows: • If specific gravity readings show a difference between the highest and lowest cell of .050 (50 points) or more, the Battery is defective and should be replaced. INSTALLING BATTERIES To install a Battery properly, it is im portant to observe the following precautions: • Connect grounded terminal of Battery last to avoid short circuits which may damage the electrical system. Do not connect prim ary lead until secondary negative cable wire has been grounded to sheet metal. • Be sure there are no foreign objects in the carrier, so that the new Battery will rest properly in the bottom of the carrier. • Tighten the hold-down evenly until snug (60-80 in. lbs.). Do not draw down tight enough to distort or crack the case or cover. • Be sure the cables are in good condition and the terminal bolts are clean and tight. Make sure the ground cable is clean and tight at engine block or frame. • Check polarity to be sure the Battery is not reversed with respect to the charging system. Do not over torque cable term inal studs. REPLACEMENT (Fig. 16b, 17b and 18b) 1. Disconnect battery negative cable and then the positive cable. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L 2. Disconnect battery vent covers from vent plugs if so equipped. 3. Remove battery hold-down clamp bolt and clamp. 4. Remove battery from tray and transfer vent cover to replacement battery, if so equipped. 5. Position new battery, which has been properly activated, in the battery tray. 6 Y -1 1 6 . Install battery hold down clamp and bolt. NOTE: Recommended hold-down bolt torque is 70 in. lbs. 7. Connect battery vent covers to vent plugs, if so equipped. 8 . Install battery positive and negative cables and tighten terminal bolts to 70 in. lbs. torque. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 1 2 E N G IN E ELE C TR IC A L Fig. 16b—Battery Installation (C-K Series) LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E E L E C T R IC A L 6Y -13 RADIATOR UPPER TIE BAR STARTER M O TO R SO LENO ID (< *V R A D IA TO R * BAFFLE R.H EN G IN E ^ W IR IN G HARNESS V-8 ENGINES TO JU N C T IO N BLOCK . STARTER M O TO R SO LENO ID EN G IN E M O U N T IN G A T T A C H IN G BOLT BRACKET L-6 ENGINES V -8 ENG INE RO UTING EN G IN E W IR IN G HARNESS STARTER M O TO R SO LENOID Fig. 17b—Battery Installation (G-Series) LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 1 4 E N G IN E E LE C TR IC A L FUEL PUMP CABLE VIEW B 30 SERIES MODEL 32 ENGINE •A.I.RJ_PUMP BRACKET 307 & 350 CID V-8 ENGINE CABLE' VIEW C GENERATOR BRACE 30 SERIES MODEL 42 454 CID V-8 ENGINE ALL EXCEPT P30 MODEL 32 CABLE L-6 ENGINE P30 MODEL 32 Fig. 18b—Battery Installation (P Series) LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E E L E C T R IC A L 6Y -1 5 ENERGIZER/BATTERY TEST PROCEDURE To determine the ability of an Energizer or battery to function properly requires testing. The accuracy of the testing changes with temperature, specific gravity, age of the battery, etc. Therefore, an accurate test has more than one step: Step 1. Visual Inspection. Step 2. Specific gravity check (hydrometer). Step 3. Programmed Instrument Test. Step 4. Load Test. CAUTION: Wear safety galsses. Do not break live circuits at energizer/battery terminals. When testing be certain to remove gases at Energizer/battery cover caused by charging. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 1 6 E N G IN E E LE C TR IC A L IF U N A B L E TO O B T A I N S P E C IF IC G R A V I T Y OF 1,200 @ 80 IN A L L CEL LS SP EC IF IC G R A V I T Y OF 1,200 OR M O R E @ 80° IN A L L CEL LS RE PL AC E E N E R G I Z E R / B A T T E R Y R E M O V E V E N T CAPS C O N N E C T 30 0 A M P LO A D FO R 15 SEC. _JT "NO SMOK E" " S M O K E " IN ON E OR M O R E C ELL S R EP L A C E E N E R G I Z E R / B A T T E R Y 1. 2. 3. 4. PL AC E T H E R M O M E T E R IN O N E C EL L AP P L Y S P E C IF IE D LO A D F R O M C H A R T 1 RE A D V O L T A G E A T 15 S EC O ND S W I T H L O A D C O N N E C T E D R E M O V E L O A D A N D RE A D E L E C T R O L Y T E T E M P E R A T U R E , T H E N COMPARE TE M P E R A T U R E AND V O L T A G E REA D IN G S W ITH C HART 2 X LESS T H A N V O L T A G E ON C H A R T 2 SA M E AS OR G R E A T E R T H A N V O L T A G E ON CHART 2 F U L L Y CHARGE, CLEAN AND RETURN ENER G IZER /B A T TER Y T O S E R V IC E R EP L AC E E N E R G I Z E R / B A T T E R Y LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L 6 Y -17 THE CHARGING SYSTEM 10-SI SERIES DELCOTRON SYSTEM INDEX General Description........................................................ Theory of Operation....................................................... Service Operations........................................................... Delcotron Replacement................................................. Pulley Replacement....................................................... Diagnosis............................................................................. 6Y-17 6Y-17 6Y -19 6Y -19 6Y-19 6Y-21 Static Checks.....................................................................6Y-21 Indicator Lamp Circuit Check...................................6Y-21 Undercharged Energizer C ondition..........................6Y-22 Overcharged Energizer C ondition.............................6Y-23 Generator Output T est..................................................6Y-23 Other Harness Checks....................................................6Y-24 GENERAL DESCRIPTION The 10-SI series Delcotron generator shown in Figure 1C is typical of a variety of models. A solid state regulator having an integrated circuit is built into the end frame. Although models are available with different outputs at idle and different maximum outputs, their basic operating principles are the same. The Delcotron generator consists primarily of two end frame assemblies, a rotor assembly and a stator assembly. A typical cross-sectional view is shown in Figure 1C. The rotor assembly is supported in the drive end frame by a ball bearing and in the slip ring end frame by a roller bearing. These rotor bearings contain a supply of lubricant sufficiently adequate to eliminate the need for periodic lubrication. Two brushes carry current through the two slip rings to the field coil mounted on the rotor and under normal conditions will provide long periods of attention - free service. No periodic adjustments or maintenance are required on the generator assembly. The stator windings are assembled on the inside of a laminated core that forms part of the generator frame. A rectifier bridge connected to the stator windings contains six diodes, (three positive and three negative) molded into an assembly which is connected to the stator windings. This rectifier bridge changes the stator a.c. voltages to d.c. voltage which appears at the output terminal. The blocking action of the diodes prevent battery discharge back through the Delcotron generator. Fig. 1C—10-SI Series Delcotron LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 1 8 E N G IN E E LE C TR IC A L Because of this blocking action, the need for a cutout relay in the circuit is eliminated. Generator field current is supplied through a diode trio which is also connected to the stator windings. A capacitor, or condenser, mounted in the end frame protects the rectifier bridge and diode from high voltages, and suppresses radio noise. THEORY OF OPERATION The typical passenger car integral charging system is made up of two components—a Delcotron generator with a built-in solid state voltage regulator and an Energizer (battery). These components work together to supply electrical power for ignition, lights, radio, cranking motor, etc. A typical wiring diagram is illustrated in Figure 2C. The basic operating principles are explained as follows. When the switch is closed, current from the energizer flows to the generator No. 1 terminal, through resistor R l, diode D l, and the base-emitter of transistor TR1 to ground, and then back to the battery. This turns on transistor TR1, and current flows through the generator field coil and TR1 back to the energizer. The indicator lamp then turns on. The resistor in parallel with the indicator lamp reduces total circuit resistance to provide higher field current for initial voltage build-up when the engine starts. With the generator operating, a.c. voltage is generated in the stator windings, and the stator supplies d.c. field current through the diode trio, the field, TR1, and then through the grounded diodes in the rectifier bridge back to the stator. Also, the six diodes in the rectifier bridge change the stator a.c. voltages to a d.c. voltage which appears between ground and the generator “BAT” terminal. As generator speed increases, current is provided for charging the energizer and operating electrical accessories. Also, with the generator operating, the same voltage appears at the "BAT" and No. 1 terminals, and the indicator lamp goes out to indicate the generator is producing voltage. The No. 2 terminal on the generator is always connected to the energizer, but the discharge current is limited to a negligible value by the high resistances of R2 and R3. As the generator speed and voltage increase, the voltage between R2 and R3 increases to the point where zener diode D2 conducts. Transistor TR2 then turns on and TR1 turns off. With TR1 off, the field current and system voltage decrease, and D2 then blocks current flow, causing TR1 to turn back on. The field current and system voltage increase, and this cycle then repeats many times per second to limit the generator voltage to a pre­ set value. Capacitor Cl smooths out the voltage across R3, resistor R4 prevents excessive current through TR1 at high temperatures, and diode D3 prevents high-induced voltages in the field windings when TR1 turns off. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L S O L E N O ID RESISTOR — vw v^- ENERGIZER DIODE 6 Y -1 9 SOLENOID RESISTOR — w w — TRIO DIODE REGULATOR REGULATOR FIELD (ROTOR) FIELD (ROTOR) TRIO STATOR STATOR RECTIFIER BRIDGE RECTIFIER BRIDGE INTEGRAL SYSTEMWITH AMMETER INTEGRAL SYSTEM WITH INDICATOR LAMP Fig. 2C—Integral Charging System Circuitry SERVICE OPERATIONS DELCOTRON ASSEMBLY DELCOTRON PULLEY Replacement (Fig. 3C) Replacement 1. Disconnect the battery cables at battery. 2. Disconnect wiring leads at Delcotron. 3. Remove generator brace bolt, then detach drive belt (belts). 4. Support the generator and remove generator mount bolt and remove from vehicle. 5. Reverse the removal procedure to install then adjust drive belt(s) as outlined under tune-up, Section 6 of this manual. Single Groove Pulley 1. Place 15/16" box wrench on retaining nut and insert a 5/16" alien wrench into shaft to hold shaft while removing nut (fig. 4C). 2. Remove washer and slide pulley, fan and spacer from shaft. 3. Reverse Steps 1 and 2 to install, use a torque wrench with a crow-foot adapter (instead of box wrench) and torque the nut to 50 ft. lbs. (fig. 5C). LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 2 0 E N G IN E E LE C TR IC A L V IE W A L-6 ENGINE V IE W B 3 0 7 & 3 5 0 C.l. V -8 ENGINES 4 5 4 C.l. V -8 ENG INE Fig. 3C—Delcotron Installation LIGHT DUTY TRUCK SERVICE MANUAL’ E N G I N E E L E C T R IC A L 6 Y -2 1 1 5 /1 6 ” SOCKET Fig. 4C—Pulley Removal Fig. 5C—Torquing Pulley Nut Double Groove Pulley 1. Place a 15/16" socket (with wrench flats on the drive end or use Adapter J-21501 and a box wrench) on retaining nut, insert a 5/16" alien wrench through socket and adapter into hex on shaft to hold the shaft while removing the nut. 2. Remove washer and slide pulley, fan and spacer from shaft. 3. To install, slide spacer, fan, pulley and washer on shaft and start the nut. 4. Use the socket and adapter with a torque wrench and tighten nut to 50 ft. lbs. torque. D IA G N O S IS Most charging system troubles show up as a faulty indicator lamp, an undercharged or an overcharged battery. Since the battery itself may be defective, it should be checked first to determine its condition. Also, in the case of an undercharged battery, check for battery drain caused by grounds or by accessories being left on. A basic wiring diagram showing lead connections is presented in Figure 6 C. The following precautions must be observed when working on the charging circuit. Failure to observe these precautions will result in serious damage to the electrical equipment. • Do not polarize the generator. • Do not short across or ground any of the terminals in the charging circuit except as specifically instructed in these procedures. • Never operate the generator with the output terminal open circuited. • Make sure the generator and Energizer are of the same ground polarity. • When connecting a charger or a booster Energizer to the vehicle Energizer, connect negative terminal to negative terminal and positive terminal to positive terminal. STATIC CHECK Before making any electrical checks, visually inspect all connections, including slip-on connectors, to make sure they are clean and tight. Inspect all wiring for cracked, frayed or broken insulation. Be sure generator mounting bolts are tight and unit is properly grounded. Check for loose fan belt. NOTE: In some circuits an ammeter may be used instead of an indicator lamp. In this case, the section pertaining to faulty indicator lamp operation may be omitted from the trouble shooting procedure. INDICATOR LAMP CIRCUIT CHECK Check the indicator lamp for normal operation as shown below. If the indicator lamp operates normally, proceed to "Undercharged Energizer" or "Overcharged Energizer" section. Otherwise, proceed to either one of the following three abnormal conditions. 1. Switch Off, Lamp On— In this case, disconnect the two leads from the generator No. 1 and No. 2 terminals. If the lamp stays on, there is a short between these two leads. If the lamp goes out, replace the rectifier bridge as covered in the Overhaul Manual. This condition will cause an under­ charged Energizer. 2. Switch On, Lamp Off, Engine Stopped—This condition can be caused by the defects listed in step 1 above, by reversal of the No. 1 and No. 2 leads at LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 2 2 E N G IN E E LE C TR IC A L Fig. 6C—Basic Wiring Diagram Switch OFF ON ON Lamp OFF ON OFF Engine STOPPED STOPPED RUNNING these two terminals, or by an open in the circuit. This condition can cause an undercharged Ener­ gizer. To determine where an open exists, proceed as follows: a. Connect voltmeter from No. 2 generator terminal to ground. If reading is obtained, go to step b. If reading is zero, repair open circuit between No. 2 terminal and Energizer. If lamp now comes on, no further checks need be made. b. With ignition switch on and with No. 1 and No. 2 terminal leads disconnected, at generator, momentarily ground No. 1 terminal lead. CAUTION: Do not ground No. 2 lead. c. If lamp does not light, check for a blown fuse, or fusible link, a burned out bulb, defective bulb socket, or an open in No. 1 lead circuit between generator and ignition switch. d. If lamp lights, remove ground at No. 1 terminal and with No. 1 and No. 2 terminal leads connected at generator, insert screwdriver into test hold (fig. 7C) to ground winding. e. If lamp does not light, check connection between wiring harness and No. 1 terminal of generator, and check brushes, slip rings, and field winding as covered in Overhual Manual. f. If lamp lights and voltmeter reading is obtained in step a, replace regulator as covered in the Overhaul Manual. 3. Switch On, Lamp On, Engine Running—The possible causes of this condition are covered in the "UNDERCHARGED ENERGIZER" section. UNDERCHARGED ENERGIZER CONDITION CHECK This condition, as evidenced by slow cranking and low specific gravity readings, can be caused by one or more of the following conditions even though the ammeter may be operating normally. 1. Insure that the undercharged condition has not been caused by accessories having been left on for extended periods. 2. Check the drive belt for proper tension. INSERT SCREWDRIVER GROUND TAB TO END FRAME END FRAME HOLE Fig. 7C—Delcotron End View LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L Check energizer. Test is not valid unless energizer is good and fully charged. Inspect the wiring for defects. Check all connections for tightness and cleanliness, including the slip connectors at the generator and firewall, and the cable clamps and battery posts. With ignition switch “on” connect a voltmeter from generator “BAT” terminal to ground, generator No. 1 terminal to ground and generator No. 2 terminal to ground. A zero reading indicates an open between voltmeter connection and Energizer. NOTE: An open No. 2 lead circuit on generators will cause uncontrolled voltage, Energizer overcharge and possible damage to Energizer and accessories. Generators sup­ plied for current applications have a built-in feature which avoids overcharge and acces­ sory damage by preventing the generator from turning on if there is an open in the wiring harness connected to the No. 2 generator terminal. Opens in the wiring harness connected between the No. 2 generator terminal and Energizer may be between the terminals, at the crimp between the harness wire and terminal, or in the wire. If previous Steps 1 through 5 check satisfactorily, check Delcotron generator as follows: a. Disconnect Battery ground cable. b. Connect an ammeter in the circuit at the “BAT” terminal of the generator. c. Reconnect Battery ground cable. d. Turn on radio, windshield wipers, lights high beam and blower motor high speed. Connect a carbon pile across the Battery. e. Operate engine at moderate speed as required, and adjust carbon pile as required, to obtain maximum current output. f. If ampere output is within 10 percent of rated output as stamped on generator frame, genera­ tor is not defective; recheck Steps 1 through 5. g. If ampere output is not within 10 percent of rated output, ground the field winding by inserting a screwdriver into the test hole (Fig. 1C). CAUTION: Tab is within 3/4 inch of casting surface. Do not force screwdriver deeper than one inch into endframe. h. Operate engine at moderate speed as required, and adjust carbon pile as required to obtain maximum current output. i. If output is within 10 percent of rated output, replace regulator as covered in the Overhaul Manual and check field winding. j. If output is not within 10 percent of rated output, check the field winding, diode trio, 6 Y -23 rectifier bridge, and stator as covered in the Chassis Overhaul Manual. k. Remove ammeter from generator and turn accessories off. OVERCHARGED ENERGIZER CONDITION CHECK 1. Determine Energizer condition. Test is not valid if Energizer is not good and fully charged. 2. Connect a voltmeter from generator No. 2 terminal to ground. If reading is zero, No. 2 lead circuit is open. 3. If Energizer and No. 2 lead circuit check good, but an obvious overcharge condition exists as evidenced by excessive Energizer water usage, proceed as follows: a. Separate end frames as covered in Delcotron “Disassembly” section in the Overhaul Manual. Check field winding for shorts. If shorted replace rotor and regulator. b. Connect ohmmeter using lowest range scale from brush lead clip to end frame as shown in Step 1, Figure 8 C, then reverse lead connections. c. If both readings are zero, either the brush lead clip is grounded, or regulator is defective. d. A grounded brush lead clip can result from omission of insulating washer (Fig. 8 C), omission of insulating sleeve over screw, or damaged insulating sleeve. Remove screw to inspect sleeve. If satisfactory, replace regulator as covered in the Overhaul Manual. GENERATOR OUTPUT TEST To check the generator in a test stand, proceed as follows: 1. Make connections as shown in Figure 9C, except leave the carbon pile disconnected. Use a fully charged Energizer or battery, and a 10 ohm resistor rated at six watts or more between the generator No. 1 terminal and the Energizer. 2. Slowly increase the generator speed and observe the voltage. 3. If the voltage is uncontrolled with speed and increases above 16 volts, check for a grounded brush lead clip as covered under heading of “OVERCHARGED ENERG IZER”, Step 3. If not grounded, replace the regulator. NOTE: The Energizer must be fully charged when making this check. 4. Connect the carbon pile as shown. 5. Operate the generator at moderate speed as required and adjust the carbon pile as required to obtain maximum current output. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 2 4 E N G IN E ELE C TR IC A L INSULATING WASHERS OHMMETER 1 cr3 OHMMETER 2 CARBON PILE VOLTMETER ENERGIZER RESISTOR TEST AM M ETER CAPACITOR RECTIFIER BRIDGE ATTACHING NUTS DIODE TRIO GENERATOR Fig. 8C—Slip Ring End Frame Fig. 9C—Generator Output Test 6. If output is within ten percent of rated output as stamped on generator frame, generator is good. 7. If output is not within ten percent of rated output, ground generator field (Fig. 7C). 8. Operate generator at moderate speed and adjust carbon pile as required to obtain maximum output. 9. If output is within ten percent of rated output, replace regulator as covered in “ Regulator Replace­ m ent” section. 10. If output is not within ten percent of rated output, check the field winding, diode trio, rectifier bridge and stator as previously covered. OTHER HARNESS CHECKS Wires in the charging system may be checked for continuity by us of an ohmmeter or a test light (12 volt). Connect the test so the wire in question is in series in in the test circuit. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L 6Y -25 IGNITION SYSTEMS INDEX General Description........................................................ 6Y-25 Theory of Operation....................................................... 6Y-27 Components...................................................................... 6Y-28 D istributors..................................................................... 6Y-28 Spark Advance Systems............................................. 6Y-28 Cam A ngle..................................................................... 6Y- 31 Ignition Condenser (Capacitor)............................... 6Y-31 Ignition Coil................................................................... 6Y -32 Spark Plugs..................................................................... 6Y -32 Secondary Ignition Cables......................................... 6Y-33 Ignition Switch.............................................................. 6Y- 33 Adjustments and Repairs............................................... 6Y-35 Distributor Contact Points........................................... 6Y-35 C leaning.......................................................................... 6Y- 35 Replacement................................................................... 6Y -35 Setting Dwell Angle.................................................... 6Y -37 Distributor Condenser................................................... 6Y- 38 Performance Diagnosis............................................... 6Y- 38 Replacem ent.....................................................................6Y- 38 Distributor......................................................................... 6Y- 39 Removal........................................................................... 6 Y -39 Disassembly.................................................................... 6Y-39 Cleaning and Inspection............................................ 6Y- 40 Assembly......................................................................... 6Y-40 Installation...................................................................... 6Y-41 Off-Engine T est............................................................... 6Y-42 Coil Replacement.............................................................. 6Y-42 Spark Plug and Wire Service...................................... 6Y-42 Removal and Inspection.................................................6Y-42 Spark Plug Cleaning..................................................... 6Y-43 Adjust Plug G ap ............................................................. 6Y-43 Installation of Plugs...................................................... 6Y-43 Installation of Plug W ires........................................... 6Y-43 Diagnosis.............................................................................. 6Y-44 Ignition System................................................................ 6Y-44 Ignition Coil T est........................................................... 6Y-45 Distributor Condenser Test........................................ 6Y-46 Ignition System Resistance T est............................... 6Y-47 Spark Plugs....................................................................... 6Y-47 GENERAL DESCRIPTION The ignition system used on all models is the standard breaker point type consisting of a coil, condenser, distributor, switch, wiring, spark plugs and a source of electrical energy. The distributor contact points set, condenser, cam lubricator and spark plugs are the only system components that require periodic service. The remainder of the ignition system requires only periodic inspection to check the operation of the components, tightness of electrical connections, and condition of the wiring. Two types of distributors are used: an internal adjustment distributor on 6 cylinder engines (fig. li) and an external adjustment distributor on 8 cylinder engines (fig. 2i). Both function in much the same manner to - (1) cause a higher voltage surge from coil, (2) time these surges with regard to engine requirements through use of centrifugal and vacuum advance mechanisms, and (3) direct high voltage surges through distributor rotor, cap, and high tension wiring to the spark plugs. The distributor houses the contact points that make and break the primary circuit, and also directs high voltage and current in proper sequence to the spark plugs. The contact point set is replaced as a complete assembly. The breaker lever spring tension and point alignment on the replacement set are factory adjusted, leaving only the dwell angle to be adjusted after installation. The distributors are equipped with a cam lubricator, which should be rotated 180 degrees every 12,000 miles and replaced every 24,000 miles. Do not attempt to lubricate the element, but replace when necessary. Distributor shaft lubrication is accomplished by a reservoir of lube around the mainshaft in the distributor bowl. The rotor located above the breaker plate assembly serves as a cover for the centrifugal advance mechanism, and distributes high voltage and current to fire the spark plugs. When the rotor is removed, the centrifugal advance mechanism should be inspected for lubricant. If necessary, a small amount of cam and bearing lubricant should be applied to the advance weights. The ignition coil (fig. 3i) is an oil filled, hermetically sealed unit designed specifically for use with an external resistance. The number of turns in the primary winding results in a high inductance in this winding, which makes it possible for the coil to provide a higher secondary voltage output throughout the speed range. The primary current from the ignition switch passes through a resistance wire which lowers the voltage to approx­ imately 8 volts. This lower voltage provides for longer contact life. For optimum starting performance, the resistance is bypassed during cranking, thereby connecting the ignition coil directly to the battery. This provides full battery voltage at the coil and keeps ignition voltage as LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 2 6 E N G IN E E LE C TR IC A L ROTOR CAM LUBRICATOR CONTACT SET ATTACHING EW CIRCUIT BREAKER PLATE ASSEMBLY CENTRIFUGAL WEIGHT BASE ASSEMBLY PERMANENT LUBRICATION RESERVOIR HOUSING QUICK DISCONNECT TERMINAL GEAR BREAKER PLATE ATTACHING SCREWS Fig l i —6 Cylinder Distributor high as possible during cranking. The resistance is bypassed automatically through the ignition and starting switch when the switch is in the "Start" position. The secondary ignition cables in the secondary or high tension system (coil to distributor and distributor to plugs) are resistant to grease, battery acid and road salt, and offers resistance to corona breakdown. Ignition cables have a multiple cloth thread core impregnated with a graphite solution to give the correct conductivity. The spark plugs used are a resistor type, tapered seat plug. The plugs have a type num ber on the insulator which designates thread size as well as relative position of the plug in the heat range. Type numbers (First Digit) starting with 4 are 14 mm, thread size. The last digit of the type number indicates the heat range position of the plug. The higher the number the hotter the plug. Spark plugs should be checked, cleaned, regapped or replaced at least every 12 months or 12,000 miles depending on driving conditions. LIGHT DUTY TRUCK SERVICE MANUAL E N G I N E E L E C T R IC A L S E A LIN G NIPPLE H IG H VO LTAG E TERMINAL WEIGHT ASSEMBLY" 6Y -27 ROTOR R.F.I. SHIELD PRIMARY TERMINALS CIRCUIT BREAKER PLATE ASSEMBLY C O IL CAP PERMANENT LUBRICATION RESERVOIR VAC U U M ASSEMBLY L A M IN A T IO N ACCESS PASSAGE FOR ENGINE OIL FUMES PRIMARY TERMINAL DISTRIBUTOR H O U S IN G SEC O N D A R Y W IN D IN G SHAFT BUSHING PRIMARY W IN D IN G Fig. 2i—8 Cylinder Distributor COIL CASE GLASS IN S U LA TIO N Fig. 3i—Ignition Coil THEORY OF OPERATION The basic ignition system (Fig. 4i) consists of the ignition coil, condenser, ignition distributor, ignition switch, low and high tension wiring, spark plugs, and a source of electrical energy (battery or generator). The ignition system has the function of producing high voltage surges and directing them to the spark plugs in the engine cylinders. The sparks must be timed to appear at the plugs at the correct instant near the end of the compression stroke with relation to piston position. The spark ignites the fuel-air mixture under compression so that the power stroke follows in the engine. There are two separate circuits through the ignition system. One of these is the prim ary circuit which includes the ignition switch, prim ary winding of the ignition coil, distributor contact points and condenser. The other is the secondary or high tension circuit which includes the secondary winding of the ignition coil, the high tension lead, distributor cap, rotor and spark plugs. The basic operation is described as follows: With the switch closed, current flows through the prim ary circuit; that is from the battery through the prim ary winding of the ignition coil and closed distributor contacts to ground, and then back to the battery. A cam mounted on the rotating distributor shaft causes the distributor contacts to open and close. W hen the contacts open, the current decreases very rapidly in the ignition coil prim ary winding, and a high voltage is induced in the coil secondary winding. This high voltage is impressed through the distributor cap and rotor across one of the spark plugs. As the voltage establishes an arc across the spark plug LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 2 8 E N G IN E ELE C TR IC A L electrodes, the air-fuel mixture in the cylinder is ignited to provide the power stroke. The secondary electrons flow from the coil secondary winding, across the distributor rotor gap and spark plug gap, and then back to the secondary winding through ground, the battery and switch. The distributor contacts then reclose, and the cycle repeats. The next-firing spark plug then will be the one connected to the distributor cap insert that is aligned with the rotor when the contacts separate. With the engine running, current flows through the coil primary calibrated resistance wire; the other lead connected between the coil and solenoid terminal is a by­ pass feature that will be covered in the section entitled "Ignition Coils". When the contacts separate, a high voltage is induced in the coil primary winding. This voltage may be as high as 250 volts, which causes an arc to form across the distributor contacts. To bring the prim ary current to a quick controlled stop, and in order to greatly reduce the size of the arc and thereby insure prolonged contact point life, a capacitor (condenser) is connected across the distributor contacts. iron. Centrifugal advance weights are pivoted on studs in the weight base, and are free to move against calibrated weight springs which connect them to the breaker cam assembly. The breaker cam assembly fits on the top of the shaft (slip fit) and rotates with the shaft, being driven by the weight springs actuated by the advance weights. Outward movement of the weights advances the cam assembly in relation to the shaft as engine speed is increased, providing an earlier spark. Each engine model requires an individual spark advance curve to insure delivery of the spark at the right instant for maximum power at all speeds. Because of this, very lettle standardization of complete distributors can be made. It is possible to improve fuel economy on engines operating under part-throttle conditions by supplying additional spark advance. Vacuum advance mechanisms are provided on some distributors for this purpose. The mechanism used rotates either the complete distributor or the breaker plate in order to time the spark earlier when the engine is operating at part throttle. COMPONENTS Centrifugal Advance Distributor The distributor has three jobs. First, it opens and closes the low tension circuit between the source of electrical energy and the ignition coil so that the prim ary winding is supplied with intermittent surges of current. Each surge of current builds up a magnetic field in the coil. The distributor then opens its circuit so that the magnetic field will collapse and cause the coil to produce a high voltage surge. The second job that the distributor has is to time these surges with regard to the engine requirements. This accomplished by the centrifugal and vacuum advance mechanisms. Third, the distributor directs the high voltage surge through the distributor rotor, cap and high tension wiring to spark plug which is ready to fire. The typical contact point type ignition distributor (Figs. li and 2i), consists of a housing, shaft, centrifugal advance assembly, vacuum advance assembly, breaker plate assembly, capacitor or condenser, and rotor. The cap, rotor, and high voltage leads in a distributor form a distribution system that conveys the high voltage surges to the spark plugs in correct sequence. The breaker plate contains the breaker lever, contact support, and capacitor. When the breaker cam rotates, each cam lobe passes by and contacts the breaker lever rubbing block, separating the contact points and producing a high voltage surge in the ignition system. With every breaker cam revolution, one spark will be produced for each engine cylinder. Since each cylinder fires every other revolution in a four-cycle engine, the distributor rotates at one-half engine speed. The shaft and weight base assembly is fitted in suitable bearings made of such materials as cast iron, bronze, or Spark Advance Systems The centrifugal advance mechanism times the high voltage surge produced by the ignition coil so that it is delivered to the engine at the correct instant, as determined by engine speed. When the engine is idling, the spark is timed to occur in the cylinder just before the piston reaches top dead center. At higher engine speeds, however, there is a shorter interval of time available for the fuel-air mixture to ignite, burn, and give up its power to the piston. Consequently, in order to obtain the maximum amount of power from the mixture, it is necessary at higher engine speeds for the ignition system to deliver the high voltage surge to the cylinder earlier in the cycle. To illustrate this principle, assume that the burning time of a given gas mixture in an automotive engine is .003 of a second. To obtain full power from combustion, maximum pressure must be reached while the piston is between 10 degrees and 20 degrees past top dead center. At 1,000 engine r.p.m., the crankshaft travels through 18 degrees in .003 of a second, at 2,000 r.p.m., the crankshaft travels through 36 degrees. See Fig. 5i. Since maximum pressure point is fixed, it is easy to see why the spark must be delivered into the cylinder earlier in the cycle in order to deliver full power, as engine speed increases. As previously mentioned, the timing of the spark to engine speed is accomplished by the centrifugal advance mechanism, which is assembled on the distributor shaft. The mechanism consists prim arily of two weights and a cam assembly. The weights throw out against spring tension as engine speed increases. This motion of the weights turns the cam assembly so that the breaker cam is rotated in the direction of shaft rotation to advanced position with respect to the distributor drive shaft. The LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL DISTRIBUTOR 6 Y -29 IGNITION COIL SECONDARY WINDING PRIMARY WINDING MAGNETIC FIELD LOW TENSION LEAD CALIBRATED RESISTANCE WIRE HIGH TENSION LEAD ENERGIZER STARTER MOTOR Fig. 4i—Typical Ignition System LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -30 ENGINE ELECTRICAL 1,000 ENG. RPM 2,000 ENG. RPM Fig. 5 i— Ig n itio n S p a rk vs E n g in e S peed higher the engine speed, the more the weights throw out and the further the breaker cam is advanced. See Fig. 6i. The centrifugal advance required varies considerably between various engine models. In order to determine the advance for a given engine, the engine is operated on a dynamometer at various speeds with a wide-open throttle. Spark advance is varied at each speed until the range of advance that gives maximum power is found. The cam assembly, weights and springs are then selected to give this advance. Timing, consequently, varies from no advance at idle to full advance at high engine speed where the weights reach the outer limits of their travel. Vacuum Advance Under part-throttle operation a high vacuum develops in the intake manifold and a smaller amount of air and gasoline enters the cylinder. Under these conditions, additional spark advance (over and above advance provided by the centrifugal advance mechanism) will Fig. 6i—Centrifugal Advance Mechanism increase fuel economy. In order to realize maximum power, ignition must take place still earlier in the cycle. To provide a spark advance based on intake manifold vacuum conditions, many distributors are equipped with a vacuum advance mechanism. The mechanism has a spring-loaded diaphragm connected by linkage to the distributor. The spring-loaded side of the diaphragm is air-tight, and is connected in many cases by a vacuum passage to an opening in the carburetor. See Fig. l i . This opening is on the atmospheric side of the throttle when the throttle is in the idling position. In this position, there is no vacuum in the passage. When the throttle is partly opened, it swings past the opening of the vacuum passage. Intake manifold vacuum then can draw air from the air-tight chamber in the vacuum advance mechanism and this causes the diaphragm to be moved against the spring. This motion is transmitted by linkage to the distributor breaker assembly rotation is governed by the amount of vacuum in the intake manifold up to the limit imposed by the design of the vacuum advance mechanism. When the distributor breaker plate assembly is rotated, the contact points are carried around the breaker cam to an advanced position, so that the breaker cam contacts the rubbing block and closes and opens the points earlier in the cycle. This provides a spark advance based on the amount of vacuum in the intake manifold. Thus, for varying compressions in the cylinder the spark advance will vary, permitting greater economy of engine operation. It should be recognized that the additional advance provided by vacuum control is effective in providing additional economy only on PART-THROTTLE operation. At any particular engine speed there will be a certain definite advance resulting from operation of the LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL 6Y-31 and less as the engine speed increases. At higher engine speeds, the ignition coil primary current does not reach its maximum value in the short length of time the contacts are closed. In order to store the maximum amount of energy obtainable on the coil, and consequently obtain sufficient energy to fire the plug, it is necessary to design a breaker lever assembly that will operate properly at high speeds. The distributor is equipped with a special-high rate-of-break cam and a special high speed breaker lever which is capable of following the cam shape at high speeds without bouncing. The high rate-of-break cam separates the contact points faster for each degree of rotation and permits closing earlier, thus increasing cam angle. With the speical cam and breaker lever combination, it is possible to obtain the maximum cam angle and consequently optimum ignition performance at high speeds. The point opening is the maximum distance that occurs between the separated contacts as the cam rotates. If the cam angle is properly set, the point opening most likely will also be according to specifications. In some cases, it may be necessary to measure point opening in addition to cam angle to insure that the contacts are properly set. A feeler gauge on new contacts, or a dial indicator on used contacts may be used to measure point opening. centrifugal advance mechanism, plus a possible addi­ tional advance resulting from operation of the vacuum advance mechanism. For example, an initial timing advance of 5 degrees, plus a centrifugal advance of 10 degrees, makes a total of 15 degrees advance at 40 miles an hour. If the throttle is only partly opened, an additional vacuum advance of up to 15 degrees more may be obtained, making a total of 30 degrees. When the throttle is wide open there is no appreciable vacuum in the intake manifold, so this additional advance will not be obtained. All advance then is based on engine speed alone and is supplied by the centrifugal advance mechanism. The vacuum advance mechanism is an economy device which will increase fuel economy when properly used. The driver who drives with wide-open throttle whether in low or high gear will not obtain this additional advance with its resulting increased fuel economy. Ignition Condenser (Capacitor) The capacitor consists of a roll of two layers of thin metal foil separated by a thin sheet or sheets of insulating material. (Fig. 9i). This assembly is sealed in a metal can with a flat spring washer providing a tight seal. The high voltage induced in the coil primary causes the capacitor plates to charge when the contacts first Cam Angle The cam angle, often referred to as contact angle or dwell angle, is the number of degrees of cam rotation during which the distributor contact points remain closed. See Fig. 8i. It is during this period of cam rotation that the current in the primary winding increases. Although the cam angle may not change, the length of time the contacts remain closed becomes less LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -32 ENGINE ELECTRICAL performance results. In other words, a 12-volt coil without the resistor is not necessarily a 6-volt coil. During cranking, the external resistance on most applications is by-passed to provide full battery voltage to the coil for improved performance and easier starting. The by-pass wire may be connected to an "R " terminal on the cranking motor solenoid which contacts the contact disk during cranking, or to a separate terminal on the ignition switch, as shown in the previous section. The higher currents during cranking are not sufficient to cause distributor contact deterioration because of the short periods of time in the life of contacts spent during cranking. Also, the lowered battery voltage during cranking causes a lower primary current, so the resistor by-pass feature is an offsetting factor. By-passing the resistor with the engine operating will cause very rapid failure of the distributor contacts. Fig. 9 i— Ig n itio n C o n d e n s e r separate; the capacitor acts initially like a short circuit and current flows into the capacitor to minimize arching at the contacts. Ignition Coil An ignition coil is a pulse transformer that steps up the low voltage from the battery or generator to a voltage high enough to ionize the spark plug gap and ignite the air-fuel mixture in the cylinder. A typical coil is made up of a primary winding, consisting of a few hundred turns of relatively large wire, and a secondary winding, consisting of many thousand turns of very small wire (Fig. 3i). These windings are assembled over a soft iron core and are enclosed by a sofe iron shell. This assembly is inserted into a one-piece, steel or diecast aluminum coil case, which is filled with oil and hermetically sealed by a coil cap made of molded insulating material. The cap contains the primary and secondary high voltage terminals. The ignition coils are hermetically sealed to prevent the entrance of moisture, which would cause coil failure. During manufacture, the coil case also is filled with oil at a high temperature. As the oil temperature decreases to more nearly match the temperature of the surrounding air, the oil contracts to occupy less volume thus allowing room for expansion when the coil heats up during normal operation. The oil acts as an insulator to prevent high voltage arc-over within the coil. In the design of an ignition system, sufficient primary circuit resistance must be present to protect the distributor contacts from excessive arcing and burning. In some ignition systems, part of this resistance may take the form of a separate resistor or a calibrated resistance wire connected between the ignition switch and the coil primary terminal. Since the value of this resistor along with the resistances of the other components in the entire primary circuit affects the coil performance at higher engine speeds, a 12-volt coil used on a 6-volt system without the external resistor, will not provide equal Spark Plugs The spark plug (Fig. lOi) consists of a metal shell in which is fastened a porcelain insulator and an electrode extending through the center of the insulator. The metal shell has a short electrode attached to one side and bent in toward the center electrode. There are threads on the metal shell that allow it to be screwed into a tapped hole in the cylinder head. The two electrodes are of special heavy wire, and there is a specified gap between them. The electric spark jumps this gap to ignite the air-fuel mixture in the combustion chamber, passing from the center, or insulated, electrode. The seals between the metal base, porcelain, and center electrode, as well as the porcelain itself, must be able to withstand the high pressure and temperature created in the combustion chamber during the power stroke. Some spark plugs have been supplied with a built-in resistor which forms part of the center electrode. The purpose of this resistor is to reduce radio and television interference from the ignition system as well as to reduce spark-plug-electrode erosion caused by excessively long sparking. We have been talking of the high-voltage surge from the ignition-coil secondary as though it were a single powerful surge that almost instantly caused the spark to jump across the spark plug gap. Actually, the action is more complex than that. There may be a whole series of preliminary surges before a full-fledged spark forms. At the end of the sparking cycle the spark may be quenched and may reform several times. All this takes place in only a few ten-thousandths of a second. The effect is that the ignition wiring acts like a radio transmitting antenna; the surges of high voltage send out impulses that causes radio and television interference. However, the resistors in the spark plugs tend to concentrate the surges in each sparking cycle, reduce their number, and thus reduce the interference and also the erosive effect on the plug electrodes. Heat Range System The "heat range" of a spark plug is determined primarily by the length of the lower insulator. The LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL ------- COLDER Fig. 6Y-33 HOTTER -------► l l i — S p a rk P lu g H e a t R a n g e S y s te m experienced, a type with one number lower (a "cooler" type) will generally be found satisfactory. The last digit of the type number indicates the heat range position of the plug in the heat range system. Read the numbers as you would a thermometer-the higher the last digit, the "hotter" the spark plug will operate in the engine; the lower the last digit, the "cooler" the spark plug will operate. Spark Plug Reach and Threads Fig. lO i—C ro ss -S e c tio n of S p a rk Plug longer this is, the hotter the plug will operate; the shorter it is, the cooler the plug will operate (Fig. 1li). Spark plugs, to give good performance in a particular engine, must operate within a certain temperature range (neither too hot nor too cool). If the spark plug remains too cool: oil, soot, and carbon compounds will deposit on the insulator causing fouling and missing. If the plug runs too hot, electrodes will wear rapidly, and under extreme conditions, premature ignition (pre-ignition) of the fuel mixture may result. Frequently, the wrong type of spark plugs, one with an improper heat range for the engine, may have been installed when replacing spark plugs originally fitted by the engine manufacturer and such misapplication may lead to poor performance. The heat range system makes it possible to select the type of spark plug that will operate within the correct temperature range for each specific engine. Where abnormal operating conditions cause chronic carbon or oil fouling of the plugs, the use of a type one number higher (a "hotter" type) than recommended will generally remedy the trouble; and by the same formula, where chronic pre-ignition or rapid electrode wear is Spark plugs are manufactured in a number of thread sizes and "reaches." Reach is the distance from the gasket seat to the end of the shell. Spark Plugs have a type number on the insulator which designates plug thread size as well as the relative position in the heat range system as previously explained. Secondary Ignition Cables The secondary wiring consists of the high tension cables connected between the distributor cap, the spark plugs, and the high tension terminal of the ignition coil. These cables carry the high voltage surges to the spark plugs and are heavilty insulated to contain the high voltages. The cables are neoprene jacketed and have a multiple cloth thread core impregnated with a graphite solution to give the correct conductivity and proper resistance for suppression of radio and television interference. Ignition Switch The electrical switching portion of the assembly is separate from the key and lock cylinder. However, both are synchronized and work in conjunction with each other through the action of the actuator rod assembly. For a complete explanation of the key and lock cylinder, and the actuator rod assembly, refer to the Steering section of this manual. The ignition switch is key operated through the actu­ ator rod assembly to close the ignition primary circuit and to energize the starting motor solenoid for crank­ ing. The ignition switch has five positions: OFF, LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -3 4 ENGINE ELECTRICAL LOCK, ACCESSORY, RUN and START. OFF is the center position of the key-lock cylinder, and LOCK is the next position to the left. ACCESSORY is located one more detent to the left of LOCK. Turning the key to the right of the OFF position until spring pressure is felt will put the ignition switch in the RUN position, and when turned fully to the right against spring pressure, the switch will be in the START position. In the RUN position, the ignition primary circuit is activated through a resistance wire. The ignition resistor wire is used in the ignition running circuit to reduce the voltage to the ignition coil. The resistor wire is bypassed when the engine is being started. The purpose of this is to compensate for the drop in voltage which occurs as the result of the heavy drain on the battery during starting, and to provide a hotter spark for starting. All ignition switches have five terminals which are connected in different combinations for each of the three operating positions. A brass plate, inside the switch, has three contacts which connect these terminals. Figure 12i shows the positions of the contacts in all positions as viewed from the key side of the switch. There is also a ground pin in the switch which contacts the "ground" terminal when the ignition switch is in the START position. This pin contacts the IGN. terminal when in the OFF position. Ignition Start and Run Circuit The ignition switch is fed from a junction at the horn relay to the BAT. terminal of the switch. When the ignition switch is in the OFF position, no current flows through the switch. When the ignition switch is turned to the ACC. position, the BAT. terminal is connected to the ACC. terminal. This permits operation of accessories when the engine is not running. When the ignition switch is turned to the START position, the BAT. terminal is connected to the SOL. and IGN. terminals. When the clutch or automatic transmis­ sion neutral start switches are closed, current flows to the starter solenoid. This energizes the solenoid windings. The solenoid has two sets of windings: a "pull-in" winding and a "hold-in" winding. Both windings are used to create the magnetic field to actuate the the solenoid plunger and move the starter pinion into engagement with the flywheel. As the solenoid plunger reaches the end of its travel, it closes a switch which connects battery voltage to the starter motor. With battery voltage applied to both terminals of the "pull-in" windings, the "pull-in" winding is no longer energized, so that only the "hold-in" winding keeps the starter solenoid engaged. During cranking, current is directed from the battery through the brass disc in the starter solenoid housing to the "B" terminal on the solenoid and then to the ignition coil, bypassing the ignition resistor wire. NOTE: The instrument panel warning lights are fed from the ignition terminal of the ignition switch and have battery voltage applied to them when the ignition switch is in the START and RUN position. These circuits are explained in the Chassis Electrical Section. When the ignition switch is released from the START to the RUN position, the IGN. terminal is still connected to the BAT. terminal, but the solenoid is no longer energized and so the feed for the coil from the IGN. terminal on the ignition switch, through the ignition resistor wire and to the coil, dropping the battery voltage at the coil to approximately nine volts. With the ignition switch in the RUN position, the BAT. terminal is connected to the IGN. terminal and the ACC. terminal. This permits operation of all accessories and the ignition system. i LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL 6Y-35 12 R 12 ORN (VIEW IG NITIO N SWITCH FROM TERMINAL POSITIONS— SIDE OF SWITCH) IG N -3 G R D -2 BAT-1 ________ . M g n -H I----1 ™ 'S_ START POSITION [G R D -2 \ ^ B A T -_2 . □ LOCK IG N -3 POSITION 1 L 'G N - 1J ACC IG N -3 SOL Q B A T -2 Fig. j BAT-1 ] 1 2 i— Ig n itio n S w itch C irc u it ADJUSTMENTS AND REPAIRS Distributor Contact Points Cleaning Dirty contact points should be dressed with a few strokes of a clean, fine-cut contact file. The file should not be used for other metals and should not be allowed to become greasy or dirty. Never use emery cloth to clean contact points. Contact surfaces, after considerable use, may not appear bright and smooth, but this is not necessarily an indication that they are not functioning satisfactorily. Do not attempt to remove all roughness nor dress the point surfaces down smooth; merely remove scale or dirt. Badly burned or pitted contact points should be replaced and the cause of trouble determined so it can be eliminated. High resistance or loose connections in the condenser circuit, oil or foreign materials on the contact surfaces, improper point adjustment or high voltages may cause oxidized contact points. Check for these conditions where burned contacts are experienced. An out-of-balance condition in the ignition system, often the result of too much or too little condenser capacity, is indicated where point pitting is encountered. Replacement Six Cylinder Engine D istributor 1. Release distributor cap hold-down screws, remove cap and place it out of work area. 2. Remove rotor. On Van models, also remove dust shield. LIGHT DUTY TRUCK SERVICE MANUAL 6Y -36 ENGINE ELECTRICAL 3. Pull primary and condenser lead wires from contact point quick disconnect terminal (fig. 13i). 4. Remove contact set attaching screw, lift contact point set from breaker plate. 5. Clean breaker plate of oil smudge and dirt. 6. Place new contact point assembly in position on breaker plate, install attaching screw. NOTE: Pilot on contact set must engage matching hole in breaker plate. 7. Connect primary and condenser lead wires to quick disconnect terminal on contact point set. NOTE: The contact point pressure must fall within specified limits. Weak tension will cause chatter resulting in arcing and burning of the points and an ignition miss at high speed, while excessive tension will cause undue wear of the contact points, cam and rubbing block. Breaker arm spring tension should be 19-23 ounces. The contact point pressure can be checked with a spring gauge. 8. Set point opening (.019" for new points). 9. Rotate cam lubricator 180 degrees at 12,000 mile intervals. Replace every 24,000 miles. 10. On Van models, install dust shield. Reinstall rotor, position and lock distributor cap to housing. 11. Start engine and test dwell and ignition timing. Eight Cylinder Engine D istributor 1. 2. 3. 4. 5. 6. 7. CAM LUBRICATOR CONTACT SET ATTACHING SCREW 8. NOTE: Contact points utilizing the push-in type terminal for the condenser and primary leads are recommended when contact point replacement is required on distributors containing the radio frequency inference shield. Point sets utilizing a lock screw at the condenser and primary lead terminal, if not carefully installed, may short out due to the head of the lock screw or lead clips contacting the shield. The contact point set is replaced as one complete assembly and only dwell angle requires adjustment after replace­ ment. Breaker lever spring tension and point alignment are factory set. Remove the distributor cap by placing a screw­ driver in the slot head of the latch, press down and rotate 1/4 turn in either direction. Remove attaching screws and rotor. Remove R.F.I. shield attaching screws and shield. Loosen the two attaching screws which hold the base of the contact set assembly in place and slide set from breakerplate. Remove the primary and condenser leads from their nylon insulated connection (fig. 14i) in contact set. Reverse Steps 2, 3 and 4 to install new contact set. CAUTIO N: Install the primary and condenser leads as shown in Figure 14i. Improper installation will cause lead interference between the cap, weight base and breaker advance plate. The cam lubricator should be rotated at 12,000 mile intervals and replaced at 24,000 mile intervals. Start engine and check point dwell and ignition timing. PRIMARY LEAD QUICK DISCONNECT TERMINAL BREAKER PLATE ATTACHING SCREWS Fig. 13i—Breaker Plate and Attaching Parts Fig. 14i—Distributor Lead Arrangements LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL C E N T R IFU G A L A D V A N C E M E C H A N IS M R A D IO F R E Q U E N C Y INTERFERENCE SHIELD r ^ IN S U L A T IN G C A U T IO N ! N EVER OIL CAM LU B RICA TO R — REPLACE W IC K W HEN N EC ESSA R Y Fig. 1 5 i—T o p V ie w of D is trib u to r Setting Dwell Angle Six Cylinder Engine D istributor The point opening of new points can be checked with a feeler gauge, but the use of a feeler gauge on rough or uncleaned used points is not recommended since accurate mechanical gauging cannot be done on such points (fig. 17i). Contact points must be set to the proper opening. Points set too close may tend to burn and pit rapidly. Points with excessive separation tend to cause a weak spark at high speed. Proper point setting for all models are: .019" for new points ACTUAL POINT OPENING .021 ---1 I----- I] 6Y-37 .016" for used points New points must be set to the larger opening as the rubbing block will wear down slightly while seating to the cam. Contact points should be cleaned before adjusting if they have been in service. To adjust contact point opening: 1. If necessary, align points (fig. I7i) by bending the fixed contact support. Do not bend the breaker lever. Do not attempt to align used points; replace them where serious misalignment is observed. Use an aligning tool if available. 2. Turn or crank the distributor shaft until the breaker arm rubbing block is on the high point of the cam lobe. This will provide maximum point opening. 3. Loosen the contact support lock screw. 4. Use a screw driver (fig. 18i) to move the point support to obtain .019" opening for new points and a .016" opening for used points. 5. Tighten the contact support lock screw and recheck the point opening. 6. After checking and adjusting the contact point opening to specifications, the cam angle or dwell should be checked with a dwell angle meter if such equipment is available (see Specifications for proper dwell angle). If the cam angle is less than the specified minimum, check for defective or misaligned contact points or worn distributor cam lobes. The variation in cam angle readings between idle speed and 1750 engine rpm should not exceed 3°. Excessive variation in this speed range indicates wear in the distributor. NOTE: Cam angle readings taken at speeds above 1750 engine rpm may prove unreliable on some cam angle meters. Eight Cylinder Engine D istributor On the Vehicle With the engine running at idle and operating temperatures normalized, the dwell is adjusted by first raising the window provided in the cap and inserting a LATERAL MISALIGNMENT PROPER LATERAL ALIGNMENT .016 FEELER GAUGE CO RRECT L A T E R A L M IS A L IG N M E N T BY BEND IN G F IX E D C O N T A C T S U P P O R T NEVER BEND BREAKER LEVER Fig. 16i—Inaccurate Gauging of Rough Points Fig. 17i—Alignment of Points LIGHT DUTY TRUCK SERVICE MANUAL 6Y -38 ENGINE ELECTRICAL Fig. Fig. 1 8 i— S e ttin g P o in t O p e n in g “ HEX” type wrench into the adjusting screw head. (fig. 19i). 1. Preferred Method - Turn the adjusting screw until the specified dwell angle is obtained as measured in degrees (29° to 31°, 30° preferred) by a dwell angle meter. 2. Alternate Method - Turn adjusting screw in (clockwise) until the engine begins to misfire, then turn screw 1/2 turn in the opposite direction (counterclockwise). This will give the approximate dwell angle required. (Use only when meter is not avaiable.) O ff the Vehicle 1. Distributor Test Method: a. With the distributor mounted on a distributor testing machine, connect the dwell meter to the distributor primary lead. b. Turn the adjusting screw (fig. 19i) to set the dwell angle to 30 degrees. 2. Test Light Method: a. With the distributor mounted in a vise, connect a testing lamp to the primary lead. b. Rotate the shaft until one of the circuit breaker cam lobes is under the center of the rubbing block of the breaker lever. c. Turn the adjusting screw clockwise (fig. 19i) until the lamp lights, then give the wrench 1/2 turn in the opposite direction (counter-clockwise) to obtain the proper dwell angle. Distributor Condenser Performance Diagnosis 19 i—A d ju s tin g D w e ll A n g le The following four factors affect condenser performance and, each factor must be considered in making any condenser test. 1. Breakdown - A failure of the insulating material. A direct short between the metallic elements of the condenser. This prevents any condenser action. 2. Low Insulating Resistance (Leakage) - Low insulation resistance prevents the condenser from holding a charge. All condensers are subject to leakage which, up to a certain limit, is not objectionable. 3. High Series Resistance - Excessive resistance in the condenser circuit due to broken strands in the condenser leak or to a defective connection. This will cause burned points and ignition failure upon initial starts and at high speeds. 4. Capacity - Capacity is determined by the area of the metallic elements and the insulating and impregnating materials. For a complete check of the condenser, use a tester which will check for all of the above conditions. Follow the instructions given by the manufacturer of the test equipment. Condenser capacity should be 18-: 23 microfarads. Replacement Six Cylinder Engine D istributor (Fig. 13i) 1. Release distributor cap hold-down screws, remove cap and place it out of the work area. 2. Remove rotor. On Van models, also remove dust shield. 3. Disconnect condenser lead wire from contact point quick-disconnect terminal. 4. Remove condenser attaching screw, lift condenser from breaker plate and wipe breaker plate clean. 5. Install new condenser using reverse of procedure outlined above. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL 6Y-39 Eight Cylinder Engine D istributor 1. Remove distributor cap, rotor and R.F.I. shield. 2. Disconnect condenser lead (fig. 14i) from terminal. 3. Remove screw holding condenser bracket to breaker plate and slide condenser from bracket. 4. To replace condenser reverse the above procedure. NOTE: Make sure that new condenser lead is installed in proper position (fig. 14i). Distributor Removal 1. Release the distributor cap hold-down screws, remove the cap and place it clear of the work area. NOTE: If necessary, remove secondary leads from the distributor cap after first marking the cap tower for the lead to No. 1 cylinder. This will aid in the reinstallation of leads in the cap. 2. Disconnect the distributor primary lead from the coil terminal. 3. Scribe a realignment mark on the distributor bowl and engine in line with the rotor segment. 4. Disconnect vacuum line to distributor. Remove the distributor holddown bolt and clamp and remove the distributor from the engine. Note position of vacuum advance mechanism relative to the engine. CAUTION: Avoid rotating the engine with the distributor removed as the ignition timing will be upset. Disassembly It is advisable to place the distributor in a distributor testing machine or synchroscope prior to disassembly. When mounting distributors for tests, first secure the gear in the test drive mechanism, then push the distributor housing downward toward the gear to take up any end play between the gear and the housing. Test the distributor for variation of spark, correct centrifugal and vacuum advance and condition of contacts. This test will give valuable information on distributor condition and indicate parts replacement which may be necessary. Check the area on the breaker plate just beneath the contact points. A smudgy line indicates that oil or crankcase vapors have been present between the points. Six Cylinder Engines (Fig. 2 0 i) 1. Remove the rotor on Van models, also remove dust shield. 2. Remove the vacuum control assembly retaining screws, detach the unit from the distributor housing. 3. Disconnect the primary and condenser leads from the contact point quick disconnect terminal, remove the contact point set attaching screw, condenser 1. B re a k e r P la te A t t a c h in g S crew s C o n d e n s e r A t ta c h in g Screw s 3. C ondenser 4 . B re a k e r P la te A s s e m b ly 4 a . C a m L u b r ic a to r 5 . V a c u u m C o n tr o l A s s e m b ly 6 . V a c u u m C o n tr o l A t t a c h in g S crew s 7 . H o u s in g 8. Cap 9 . R o tor 2. 10. C o n ta c t P o in t A t t a c h in g S c re w 11. C o n ta c t P o in t A s s e m b ly 12. W e ig h t C o v e r A t t a c h in g S crew s 13. W e ig h t C o v e r 14. W e ig h t S p rin g s 15. A d v a n c e W e ig h ts 16. C a m A s s e m b ly 17. M a in S h a ft A s s e m b ly 18. R o ll P in 19. D r iv e G e a r Fig. 2 0 i— L-6 D is trib u to r - E xp lo d e d V ie w attaching screw. Remove the point set and condenser from the breaker plate. 4. Remove the breaker plate attaching screws, remove the breaker plate from the distributor housing. NOTE: Do not disassemble breaker plate any further. 5. Remove the roll pin retaining the driven gear to the mainshaft, slide the gear from the shaft. 6. Slide the cam and mainshaft from the distributor housing. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -4 0 ENGINE ELECTRICAL 7. Remove the weight cover and stop plate screws, remove the cover, weight springs, weights and slide cam assembly from the mainshaft. V-8 Engines (Fig. 2 1i) 1. Remove the rotor. 2. Remove attaching screws and R.F.I. shield. 3. Remove both weight springs and advance weights. 4 . Remove roll pin retaining driven gear to distributor shaft, slide the gear and spacers from the shaft. 5. Before sliding the distributor shaft from the housing, check for and remove any burrs on the shaft. This will prevent damage to the seals and bushing still positioned in the housing. 6. Slide the distributor mainshaft and cam-weight base assembly from the housing. 7. Remove vacuum advance mechanism retaining screws, remove the vacuum advance assembly. 8. Remove the spring retainer, remove the breaker plate assembly f'om the distributor housing. Remove the contac points and condenser from the breaker plate. Renove the felt washer and plastic seal located beneath the breaker plate. Cleaning and Inspection 1. Wash all parts in cleaning solvent except cap, rotor, condenser, breaker plate assembly and vacuum control unit. Degreasing compounds may damage insulation of these parts or saturate the lubricating felt in the case of the breaker plate assembly. 2. Inspect the breaker plate assembly for damage or wear and replace if necessary. 3. Inspect the shaft for wear and check its fit in the bushings in the distributor body. If the shaft or bushings are worn, he parts should be replaced. 4 . Mount the shaft in “ V ” blocks and check the shaft alignment with a dial gauge. The run-out should not exceed .002". 5. Inspect the advance weights for wear or burrs and free fit on their pivot pins. 6. Inspect the cam for wear or roughness. Then check its fit on the end of the shaft. It should be absolutely free without any roughness. 7. Inspect the condition of the distributor points. Points should be cleaned and badly pitted points should be replaced. (See Distributor Contact Points.) 8. Test the condenser for series resistance, microfarad capacity (.18 to .23) and leakage or breakdown, following the instructions given by the manufac­ turer of the test equipment used. 9. Inspect the distributor cap and spark plug wires for damage and replace if necessary. Assembly Six Cylinder Engine (Fig. 2 0 i) 1. Replace cam assembly to mainshaft. NOTE: Lubricate top end of shaft with Delco cam and ball bearing grease or equivalent prior to replacing. 2. Install governor weights on their pivot pins, replace weight springs. Install weight cover and stop plate. 3. Lubricate mainshaft and install it in distributor housing. 4. Install distributor driven gear to main­ shaft and insert attaching roll pin. Check to see that shaft turns freely. 5. Install breaker plate assembly in the distributor body and attach retaining screws. 6. Attach condenser and contact point set. NOTE: Contact point set pilot must engage matching hole in breaker plate. Connect primary and condenser leads (as applicable) to contact set quick-disconnect terminal. 7. Attach vacuum control assembly to distributor housing. 8. Check and adjust contact point opening. 9. On Van models, install dust shield, then install rotor. V-8 Engine—(Fig. 21i) 1. Fill housing lubricating cavity, press in new plastic seal and install felt washer. 2. Replace the vacuum advance unit, install the breaker plate in housing and install the spring retainer on the upper bushing. 3. Lubricate and slide weight cam over mainshaft and install weights and spring (fig. 22i). 4. Insert mainshaft into housing, indexing it with drive gear and washers. 5. Slide distributor drive gear shims and gear over shaft and install new pin. Tap new pin through gear and mainshaft. Check shaft for free rotation. 6. Install contact point set and condenser to breaker plate. Connect leads as shown in Figure 14i. NOTE: Contact point spring tension is factory set above specifications to assure ease of final adjustment. Correct tension is 19-23 oz. Hi Performance is 28-32 oz. 7. Position R.F.I. shield and install attaching screws. 8. Install rotor to cam assembly, indexing round and square pilot holes. LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL 1. 2. 3. Condenser Contact Point Assembly Retaining Ring 4. 5. 5a. 6. Breaker Plate Felt Washer Plastic Seal Vacuum Advance Unit 7. 7a. 8. 9. 10. Housing Tanged Washer Shim Washer Drive Gear Pin Drive Gear 11. 12. 13. 14. Cap Rotor Radio Frequency Interference Shield Weight Springs 15. 16. 17. 6Y-41 Mainshaft Advance Weights Cam Weight Base Assembly Fig. 21 i— V -8 D is trib u to r (T y p ic a l) - E xploded V iew Installation—Engine Not Disturbed 1. Turn the rotor about 1/8 turn in a clockwise direction past the mark previously placed on the distributor housing to locate rotor. 2. Push the distributor down into position in the block with the housing in a normal “installed” position (fig. 23i). NOTE: It may be necessary to move rotor slightly to start gear into mesh with camshaft gear, but rotor should line up with the mark when distributor is down in place. 3. Tighten the distributor clamp bolt snugly and connect vacuum line. Connect primary wire to coil terminal and install cap. Also install spark plug and high tension wires if removed. NOTE: It is important that the spark plug wires be installed in their proper location in the supports and also in the cap. 4. Time ignition as previously described under Tune Up in Section 6. Installation—Engine Disturbed 1. Locate No. 1 piston in firing position by either of two methods described below. a. Remove No. 1 spark plug and, with finger on plug hole, crank engine until compression is felt in the No. 1 cylinder. Continue cranking until timing mark on crankshaft pulley lines up with timing tab attached to engine front cover. b. Remove rocker cover (left bank on V-8 engines) LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -42 ENGINE ELECTRICAL Fig. 2 3 i— Six C y lin d e r E n g in e D is tr ib u to r In s ta lla tio n Fig. 2 2 i—A d v a n c e W e ig h ts In s ta lle d 2. 3. 4. 5. 6. 7. and crank engine until No. 1 intake valve closes and continue to crank slowly about 1/3 turn until timing mark on pulley lines up with timing tab. Position distributor to opening in block in normal installed attitude, noting position of vacuum control unit. NOTE: On Mark IV engines the distributor may be installed with the distributor cap in place by using the punch mark on the distributor drive gear for alignment instead of the rotor as follows: Align the punch mark on the gear, which represents the centerline of the rotor, approximately 2° clockwise from the distributor cap # 1 terminal, then rotate the distributor body counterclockwise slightly (1/8 turn) so that the distributor points just break open (.002 maximum). Secure the distributor clamp and proceed with steps 3 thru 7 as required. Position rotor to point toward front of engine (with distributor housing held in installed attitude), then turn rotor counter-clockwise approximately 1/8 turn more toward left cylinder bank and push distributor down to engine camshaft. It may be necessary to rotate rotor slightly until camshaft engagement is felt. While pressing firmly down on distributor housing, kick starter over a few times to make sure oil pump shaft is engaged. Install hold-down clamp and bolt and snug up bolt. Turn distributor body slightly until points just open and tighten distributor clamp bolt. Place distributor cap in position and check to see that rotor lines up with terminal for No. 1 spark plug. Install cap, check all high tension wire connections and connect spark plug wires if they have been removed. 8. Connect vacuum line to distributor and distributor primary wire to coil terminal. 9. Start engine and set timing as described under Tune Up in Section 6. Distributor Off-Engine Test The distributor’s centrifugal and vacuum advance can be checked in a distributor testing machine or synchroscope designed to accommodate the distributor. However, since this involves removing the distributor from the engine, this test may be postponed until other system checks have been made. Coil Replacement 1. Disconnect ignition switch and distributor leads from terminals on coil. 2. Pull high tension wire from center terminal of coil. 3. Remove the two coil support mounting bolts or loosen friction clamp screw and remove coil. 4. Place new coil in position and install attaching bolts or tighten clamp screw. 5. Place high tension lead securely in center terminal of coil and connect ignition switch and distributor primary leads to terminals on coil. 6. Start engine and check coil operation. Spark Plug and Wire Service Removal and Inspection 1. To disconnect wires, pull only on the boot. Pulling on the wire might cause separation of the core of the wire. Remove spark plugs and gaskets using a 5 /8 " deep socket on the 5 / 8 " hex tapered plugs. Use care in this operation to avoid cracking spark plug insulators. 2. Carefully inspect the insulator and electrodes of all LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL spark plugs. Replace any spark plug which has a cracked or broken insulator. If the insulator is worn away around the center electrode, or the electrodes are burned or worn, the spark plug is worn out and should be discarded. Spark plugs which are in good condition except for carbon or oxide deposits should be thoroughly cleaned and adjusted. 3. The spark plug wires are of a special resistance type. The core is carbon-impregnated linen. This wire is designed to eliminate radio and television interference radiation, but is also superior in resistance to cross fire. The resistance type wire, however, is more easily damaged than copper core wire. For this reason care must be taken that the spark plug wires are removed by pulling on the spark plug boots rather than on the wire insulation. Also, when it is necessary to replace a spark plug boot, the old boot should be carefully cut from the wire and a small amount of silicone lubricant used to aid in installing the new boot. If the wire is stretched, the core may be broken with no evidence of damage on the outer insulation. The terminal may also pull off the wire. If the core is broken, it will cause missing. In the case of wire damage, it is necessary to replace the complete wire assembly as a satisfactory repair cannot be made. 4. Wipe ignition wires with cloth moistened with kerosene, and wipe dry. Carefully bend wires to check for brittle, cracked, or loose insulation. Defective insulation will permit missing or cross­ firing of engine, therefore defective wires should be replaced. 5. If the wires are in good condition, clean any terminals that are corroded and replace any terminals that are broken or distorted. Replace any broken or deteriorated cable nipples or spark plug boots. Spark Plug Cleaning Spark plugs which have carbon or oxide deposits should be cleaned in a blast type spark plug cleaner. Scraping with a pointed tool will not properly remove the deposits and may damage the insulator. If spark plugs have a wet or oily deposit dip them in a degreasing solvent and then dry thoroughly with dry compressed air. Oily plugs will cause the cleaning compound to pack in the shell. Carefully follow the instructions of the manufacturer of the cleaner being used, cleaning each plug until the interior of shell and the entire insulator are clean; however, avoid excessive blasting. Examine interior of plug in good light. Remove any cleaning compound with compressed air. If traces of carbon oxide remain in plug, finish the cleaning with a Fig. 2 4 i— C h e c k in g S p a rk 6Y-43 Plug G ap light blasting operation. Clean firing surfaces of center and side electrodes with several strokes of a fine file. When spark plugs have been thoroughly cleaned, carefully inspect for cracks or other defects which may not have been visible before cleaning. Adjusting Spark Plug Gap (Fig. 24i) Use round wire feeler gages to check the gap between spark plug electrodes of used plugs. Flat feeler gages will not give a correct measurement if the electrodes are worn. Adjust gap by bending the side electrodes only Adjust gaps to specifications. Setting spark plug gap to other than specification to effect changes in engine performance is not recommended. Installation of Spark Plugs When installing spark plugs, make sure that all surfaces on plugs and in cylinder heads are clean. When installing the 5/8" hex tapered seat spark plugs, tighten to 15 lb. ft., using a 5/8" deep socket, an extension and a torque wrench. CAUTION: I f tapered seat spark plugs are over-tightened, there is a possibility they can crack and be more difficult to remove at the next tune-up. Installation of Spark Plug Wires No. 1 spark plug wire is installed in the first distributor cap tower after the adjusting window, moving in the direction of rotation (V-8), or in the foremost tower (L6). The other wires are then installed in a clockwise direction according to the firing order (figs. 25i). LIGHT DUTY TRUCK SERVICE MANUAL 6 Y - 4 4 ENGINE ELECTRICAL Fig. 25i—V-8 Spark Plug Wire Installation LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL 6Y-45 DIAGNOSIS IGNITION SYSTEM A. Engine Will Not Start But Cranks O.K. 1. Disconnect a spark plug wire and hold 1/4" away from the engine block, then crank engine. a. If strong spark is seen, check timing. Adjust as necessary. If timing is correct, trouble is not in ignition system. b. If no spark or an intermittent spark is seen, reconnect plug wire and proceed to step 2. 2. Disconnect distributor cap-to-coil lead from coil and place screwdriver blade across coil tower to engine block and crank engine. a. If strong spark is seen between coil tower and metal bar, check distributor cap and rotor for cracks or carbon tracking. Check lead between distributor and coil for broken or burned terminals or cracks in insulation. Replace defective parts. b. If no spark or intermittent spark is seen, proceed to step 3. 3. Connect jumper wire from battery plus ( + ) terminal to coil plus ( + ) • terminal. Place a screwdriver blade across coil tower to engine block and crank engine. a. If strong spark is seen, remove jumper wire and check wiring connections and switches between battery plus ( + ) terminal and coil ( + ) terminal. Opens, high resistance or intermittent contact will require repair or replacement. b. If no spark or intermittent spark is seen, remove jumper wire and proceed to step 4. 4. Disconnect distributor lead from coil minus (—) terminal and connect test light from coil minus (—) terminal to engine block. Turn ignition switch to crank position. a. If lamp does not light, replace coil. b. If lamp lights proceed to step 5. 5. Connect test light from battery plus ( + ) terminal to distributor lead which is still detached from the coil. If necessary, rotate distributor until points close. a. If lamp lights, check condenser and points. Replace defective parts. b. If lamp does not light, proceed to step 6. 6. Connect test lamp from battery plus ( + ) terminal to connection of distributor lead and contact points. Make sure points are closed. a. If lamp lights, replace distributor lead to coil. b. If lamp does not light, proceed to step 7. 7. Connect test lamp from battery plus ( + ) terminal to screw holding points in place. a. If lamp lights, replace points and check capacitor. b. If lamp does not light, breaker plate or distributor is not grounded. Check plate-todistributor ground wire or distributor-to-engine block connector. B. Engine Starts But Will Not Continue to Run 1. Connect jumper wire from battery plus ( + ) terminal to ignition coil plus ( + ) terminal and start engine. a. If engine does not continue to run, problem is not ignition. b. If engine runs, proceed to step 2. 2. Remove jumper and disconnect leads from battery plus ( + ) terminal and coil ( + ) terminal. Connect ohmmeter and measure resistance between the ends of the leads just detached. Ignition switch should be in the run position. a. If resistance exceeds 2.5 ohms, check wires and connections for loose or intermittent contact. Check by-pass resistor and ignition switch for opens. b. If resistance is 1.0 to 2.5 ohms, check the output of the ignition coil. c. If resistance is less than 1.0 ohm, replace shorted by-pass resistor and replace contact points. C. Engine Runs Rough, Poor Power or Gas Mileage 1. Check all tune-up specifications (timing, dwell, carburetion, fouled plugs, etc.) If settings are improper, correct as required. 2. If settings are O.K. check both centrifugal and vacuum advance of distributor and correct with replacement parts, if necessary. 3. If distributor advance mechanisms are within specifications, check coil available voltage and plug required voltage. a. High requirements or low availability of voltage will require a replacement of parts. b. If coil and plugs are O.K., the problem is not in the ignition system. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -4 6 ENGINE ELECTRICAL IGNITION COIL TEST A. Weak Coils Most ignition coils that are replaced are classified as weak. Many coils rejected as weak actually test up to specifications and give normal performance. A coil that actually is weak will first effect engine performance when the ignition reserve is at a minimum. This may be in starting, low speed acceleration or top speed. Eventually the engine will fail to start. High resistance connections in either the primary or secondary circuit wiring will react the same as a weak coil. Wide spark plug gaps, which require higher voltage than the coil can produce, put the coil under suspicion. High compression and lean carburetion increase the voltage requirements and lead to many needless coil changes. Leakage of high tension current through moisture on an unprotected coil terminal may produce carbon tracks which weaken the coil output voltage. For this reason the nipple on coil high tension terminal must be properly installed and in good condition. When an ignition coil is suspected of being defective it should be tested as described below before being replaced. B. Testing Coil for Open and Grounded Circuits Before using a coil test instrument, the coil should be tested for open and grounded circuits, using a 110-volt test lamp and test points. 1. Apply test points to both primary terminals of coil. If test lamp does not light, the primary circuit is open. 2. Apply one test point to the high tension terminal, and the other test point to one of the primary terminals. If secondary circuit is not open, the lamp will not light but tiny sparks will appear at test points when they are rubbed over terminals. If secondary circuit is open, no sparks will occur. 3. Apply one test point to a clean spot on the metal coil case and touch the other point to the primary and high tension terminals. If the lamp lights, or tiny sparks appear at the points of contact, the coil windings are grounded. 4. A coil with open or grounded windings must be replaced since internal repairs cannot be made. It is unnecessary to test such a coil with instruments. If windings are not open or grounded, a test for short circuits and other internal defects should be made with a reliable coil test instrument. C. Coil Test Instruments Two general type of instruments are used in testing ignition coils. One type makes use of an open or protected spark gap, while the other reports the condition of the coil on a meter. The spark gap type of tester should always be used comparatively, that is, the questionable coil should be compared with a coil of same model that is known to be good. Both coils must be at the same temperature and identical test leads must be used. Certain variables caused by altitude, atmosphere or spark gap electrode conditions are usually present in the spark gap type of test. The meter type testers are usually designed to permit testing the coil without making any connection to the secondary terminal. This eliminates the variables usually present in the spark type of test and avoids the necessity for comparison with a good coil. Some different makes and models of coil testers differ in their methods of use, as well as in the markings on meters, the instructions of the manufacturer must be carefully followed when using any coil tester. The instrument must be frequently checked to make certain that it is accurately calibrated. Regardless of instrument or method used, the coil must be tested at normal operating temperature because internal defects often fail to show up on a cold test. DISTRIBUTOR CONDENSER TEST When a condenser is suspected of being faulty it should be tested with a reliable condenser tester to determine whether it is actually the cause of ignition trouble. The condenser should be tested for (a) high series resistance (b) insufficient or excessive capacity (c) low insulation resistance. A special condenser tester is required to make these tests. When using a condenser tester the instructions of the manufacturer must be carefully followed. NOTE: The condenser must be at normal operating temperature when it is being tested. A. High Series Resistance High series resistance in the condenser causes the condenser to be slow in taking the charge and, consequently, a higher than normal voltage is developed across the contact points when they first start to open. The higher voltage causes more distrubance at the contact points, which in turn causes more rapid wear and more tendency toward oxidized surfaces. The condition can become severe enough to cause complete failure of the ignition system. It would first show up during starting and low speed operation. High series resistance may be caused by internal resistance in condenser or by resistance in the connections. Any defect caused by internal resistance should show up at low mileage since this does not change very much with time or use. The damaging changes are in the connections, in which looseness, corrosion, or broken strands may develop. New condensers may have a series resistance as low as .05 ohm. Some condenser testers are set to reject condensers which have a resistance of .3 ohm; however, LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL test show that the resistance can go to .5 ohm before ignition performance is affected. B. Insufficient or Excessive Capacity The condenser specified for use in the ignition system has a capacity of .18 to .23 microfarads. If a condenser is used which does not have the specified capacity of .18 to .23 microfarads, excessive pitting of one contact point and a corresponding buildup of metal on the other contact point will result. A condenser having insufficient capacity will cause build-up of metal on the breaker arm (positive) point. A condenser having excessive capacity will cause build-up of metal on the contact support (negative) point. In exceptional cases, pitting and metal buildup on contact points may be experienced even when condenser capacity is within the specified limits. In such cases the life of contact points will be improved by installing a condenser of high-limit capacity if metal build-up is on breaker arm point, or a condenser of low-limit capacity if metal build-up is on contact support point. There is usually sufficient variation in the capacities of stock condensers to permit selection of a high or low limit condenser by testing the available stock. C. Low Insulation Resistance A weak or leaking condenser is usually one that has absorbed water so that the insulation resistance of the winding is lowered to the extent that the condenser will not hold a charge satisfactorily. A condenser with low insulation resistance will drain sufficient energy from the ignition system to lower the secondary voltage seriously. The condenser specified for use in the ignition system is sealed to prevent absorption of water, and no other type should be used. A leaky condenser usually does not affect engine performance except when hot. It is unlikely that a condenser with low insulation resistance would cause missing at low or medium speeds under conditions where the condenser does not get hot. A condenser that has low enough resistance to affect engine performance when cold would probably be indicated as broken down on most condenser testers. Condenser testers equipped to check condensers for low insulation resistance usually give a reading megohms, a megohm being one million ohms. The scale is marked to indicate whether the condenser is good or bad. When testing a condenser for low insulation resistance the lead should always be disconnected from the distributor. Since the distributor terminals and the connected circuit have much lower insulation resistance than the condenser, failure to disconnect the condenser lead will give a reading much too low. IGNITION SYSTEM RESISTANCE TEST Check for proper functioning of the resistance in the primary ignition circuit by turning on the ignition. With the engine not running, a voltmeter connected from the battery side of the coil to ground should read 6Y -47 approximately 5 to 5.5 volts. If the reading is a full 12 volts, the ignition points may be open; "bump" the starter a few times until the engine comes to rest with the ignition points closed and again check for a 5.5 volt reading. A reading of 12 volts or over for all engine positions would indicate that the shorting switch is making contact all the time; this condition must be corrected immediately or ignition point life will be very short. Check for proper closing of the shorting switch and also for proper functioning of the complete starting circuit by grounding the secondary coil wire so the engine won’t start. With the engine cranking, a voltmeter connected from the battery side of the coil to ground should read at least 9 volts. A reading of under 5 bolts would indicate that the shorting switch is not closing; this condition would result in hard cold starting. Briefly, the advantages of our resistance with shorting switch system are: it sends full battery voltage to the coil for good cold weather starting, and it cuts down the voltage to the coil with the engine running for long ignition point life. NOTE: Discourage any attempts to measure voltage at the coil with the engine running; because of variations in current flow at high speeds and in regulated voltage, this check would be meaningless. Voltage readings on a perfectly-functioning ignition system may go over 11 volts. SPARK PLUGS Under normal operating conditions, spark plugs wear out due to the destructive action, under intense heat, of sulphur and lead compounds in the fuel and the bombardment of the electric spark on the electrodes. It is reasonable to expect 12,000 miles of useful life from a spark plug which has been cleaned and regapped at regular intervals. However, operating conditions are an important factor and life expectany of the spark plug will vary with the type of service in which the engine is used. The same type of spark plug used in two different engines of the same make and model may frequently show wide variation in appearance. The cause of such differences lies in the condition of the engine, its piston rings, carburetor setting, kind of fuel used, and under what conditions the engine is operated, namely, sustained high speeds or heavy loads; or continual low speed, stop-and-go driving or light loads. Spark Plugs are frequently blamed for faulty engine operation which they do not cause. Replacement of old spark plugs by new may temporarily improve poor engine performance because of the lessened demand new plugs make on the ignition system. This cannot permanently cure poor engine performance caused by worn rings or cylinders, weak coil, worn contact points, faulty carburetion or other engine ills. On the following pages are pictures of some commonly encountered appearances and causes • of spark plug problems. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -48 ENGINE ELECTRICAL NORMAL OPERATION Brown to grayish-tan deposits and slight electrode wear indicate correct spark plug heat range and mixed periods of high and low speed driving. SPARK PLUGS HAVING THIS APPEARANCE MAY BE CLEANED, REGAPPED AND REIN­ STALLED. When reinstalling spark plugs that have been cleaned and regapped, be sure to use new gaskets on spark plugs that utilize engine seat gaskets. Normal Operation DEPOSIT FOULING—"A ” Red, brown, yellow and white colored coatings which accumulate on the insula­ tor are by-products of combustion and come from the fuel and lubricating oil, both of which today generally contain additives. Most powdery deposits have no 'adverse effect on spark plug operation; however, they may cause intermittent missing under severe operating conditions, especially at high speeds and heavy load. IF THE INSULATOR IS NOT TOO HEAVILY COATED, THE SPARK PLUGS MAY BE CLEANED, REGAPPED AND REINSTALLED. Sometimes, even after cleaning, an invisible shunt path remains. The only remedy under such circumstances is to replace the plug. Deposit Fouling " A ” DEPOSIT FOULING—"B" Most powdery deposits, as shown in “A”, have no adverse effect on the operation of the spark plug as long as they remain in the powdery state. However, under certain conditions of operation, these deposits melt and form a shiny yellow glaze coating on the insulator which, when hot, acts as a good electrical conductor. This allows the current to follow the deposits instead of jumping the gap, thus shorting out the spark plug. Glazed deposits can be avoided by not applying sudden load, such as wide open throttle acceleration, after sustained periods of low speed and idle operation. IT IS ALMOST IMPOSSIBLE TO EFFECTIVELY REMOVE GLAZED DEPOSITS, SO WHEN THEY OCCUR THE PLUG SHOULD BE REPLACED. CARBON FOULING Deposit Fouling " B ” Dry, fluffy black carbon deposits may result from overrich carburetion, excessive hand choking, a faulty automatic choke, or a sticking manifold heat valve. A clogged air cleaner can restrict air flow to the carburetor causing rich mixtures. Poor ignition output (faulty breaker points, weak coil or condenser, worn ignition cables) can reduce voltage and cause misfiring. Fouled spark plugs are the result-not the cause-of this problem. AFTER THE CAUSE HAS BEEN ELIMINATED, SPARK PLUGS HAVING THIS APPEARANCE CAN BE CLEANED, REGAPPED AND REINSTALLED. Excessive idling, slow speeds under light load also can keep spark plug tempera­ tures so low that normal combustion deposits are not burned off. In such a case a hotter type spark plug will better resist carbon deposits. Carbon Fouling LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL 6Y -49 DETONATION Overadvanced ignition timing, or the use of low octane fuel will result in detona­ tion commonly referred to as engine knock. This causes severe shock inside the combustion chamber resulting in damage to the adjacent parts which include spark plugs. A common result of detonation is to have the sidewire of a spark plug torn off. INSTALL A NEW PLUG OF THE RECOMMENDED HEAT RANGE AFTER PROBLEM HAS BEEN CORRECTED. Detonation INSUFFICIENT INSTALLATION TORQUE Failure to install a spark plug with sufficient torque results in poor contact between the spark plug and the engine seat. The lack of proper heat transfer, resulting from poor seat contact, causes excessive overheating of the spark plug and, in many cases, severe damage as shown. A NEW SPARK PLUG OF THE RECOMMENDED HEAT RANGE SHOULD BE INSTALLED IN ACCORDANCE WITH AC INSTALLATION INSTRUCTIONS. Insufficient Installation Torque PR E -IG N ITIO N Pre-ignition, causing burned or blistered insulator tip and badly eroded elec­ trodes, indicates excessive overheating. Cooling system stoppages or sticking valves can also result in pre-ignition. Lean fuel-air mixtures are an additional cause. INSTALL A NEW PLUG OF THE RECOMMENDED HEAT RANGE AFTER PROBLEM HAS BEEN CORRECTED. Sustained high speed, heavy load service can produce high temperatures which will cause pre-ignition and, in this instance a colder spark plug should be used. Pre-ignition IMPROPER INSTALLATION Dirty threads in an engine head will result in the plug seizing before it is actually seated. This results in poor heat transfer and causes the spark plug to overheat. To insure proper seating of a new spark plug in the head, dirty cylinder head threads should be cleaned with a greased thread chaser of the proper size. ELIMINATE THE CAUSE AND INSTALL A NEW PLUG OF THE RECOM­ MENDED HEAT RANGE. Improper Installation LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -50 ENGINE ELECTRICAL OIL FOULING Wet, oily deposits with a minor degree of electrode wear may be caused by oil pumping past worn rings. “Break-in” of a new or recently overhauled engine before rings are fully seated may also result in this condition. Other possibilities of intro­ duction of oil into the combustion chamber are a porous vacuum booster pump diaphragm or excessive valve stem guide clearances. Usually, these spark plugs can be degreased, cleaned and reinstalled. A HOTTER TYPE SPARK PLUG WILL REDUCE OIL DEPOSITS, but too hot a spark plug can cause pre-ignition and, consequently, severe engine damage. An engine overhaul may be necessary in severe cases to obtain satisfactory service. Oil Fouling HEAT SHOCK FAILURE Heat shock is a common cause of broken and cracked insulator tips. Over­ advanced ignition timing and low grade fuel are usually responsible for heat shock failures. Rapid increase in tip temperature under severe operating conditions causes the heat shock and fracture results. Another common cause of chipped or broken insulator tips is carelessness in regapping by either bending the centerwire to adjust the gap, or allowing the gapping tool to exert pressure against the tip of the center electrode or insulator when bending the side electrode to adjust the gap. ELIMINATE THE CAUSE AND INSTALL A NEW PLUG OF THE RECOM­ MENDED HEAT RANGE. Heat Shock Failure STARTER SYSTEM INDEX General Description.................................... ................... Theory of Operation................................... ................... Starter M otor.............................................. ................... Solenoid......................................................... ................... Service Operation......................................... ................... Lubrication................................................... ................... Starter Motor Replacement.................... ................... Diagnosis......................................................... ................... 6Y-50 6Y-51 6Y-51 6Y-53 6Y-55 6Y-55 6Y-55 6Y-57 No Cranking Action.................................................... . Cranking Speed Abnormally Low........................... . Voltage Test of Starting System and Solenoid Switch................................................................................... . Amperage Test of Solenoid Switch Windings.... . Checking Pinion Clearance........................................ . Bench Test of Starting Motor.................................. . Diagnosis Chart.............................................................. . 6Y-57 6Y-57 6Y-57 6Y-58 6Y-58 6Y-59 6Y-60 GENERAL DESCRIPTION The function of the starting system, composed of the starting motor, solenoid and battery, is to crank the engine. The battery supplies the electrical energy, the solenoid completes the circuit to the starting motor, and the motor then does the actual work of cranking the engine. The starting motor (fig. Is) consists primarily of the drive mechanism, frame, armature, brushes, and field windings. The starting motor is a pad mounted 12-volt extruded frame type, having four pole shoes and four fields, connected with the armature. The aluminum drive end housing is extended to enclose the entire shift lever LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL 6Y-51 SOLENOID CONTACT FINGER TURN SPRING SHIFT LEVER P IN IO N STOP BRUSH INSULATED BRUSH HOLDER BRUSH SPRING \ FIELD COIL ARMATURE ASSIST O V ER R U N N IN G CLUTCH SPRING GROUNDED BRUSH HOLDER Fig. I s — S ta rtin g M o to r Cross S ection (T y p ic a l) and plunger mechanism, protecting them from dirt, splash, and icing. The drive end frame also includes a grease reservoir to provide improved lubrication of the drive end bearing. The flange mounted solenoid switch operates the overrunning clutch drive by means of a linkage to the shaft lever. THEORY OF OPERATION The starting system is made up of the cranking motor with its drive mechanism, the starter motor solenoid and the Energizer, (often referred to as the Battery). These units are connected together and work as a team to crank the engine. The simplified diagram (Fig. 2s) shows the electrical components in a typical starting system. Although modern day applications use more circuitry and controls than shown in Figure Is, the function of the components is always the same—to convert electrical energy from the Energizer into mechanical energy at the starter motor to crank the engine. STARTER MOTOR To understand the operating principles of a starter motor, think of a straight wire conductor located in the magnetic field of a horseshoe-shaped magnet. Current is flowing through the wire as shown in Figure 3s. There will be two separate magnetic fields—the one produced by the horseshoe magnet and the one produced by the current flow through the conductor. Since magnetic lines always leave a North pole and enter a South pole, the direction of the magnetic lines between the two poles of the horseshoe magnet will be upward as shown. The current-carrying conductor will produce a magnet field shown as circles around the wire. The net result is more magnetic lines on the left hand side of the wire than on the right (Fig. 4s). With a strong field on one side of the conductor and a weak field on the other side, the conductor will move from the strong to the weak field, or from left to right. This magnetic force makes the cranking motor operate. A basic motor is shown in Figure 5s. A loop of wire is placed between two iron pole pieces and is connected to two separate commutator bars. Riding on the commuta­ tor bars are two brushes, which are connected to the battery and to the windings located over the pole pieces. Current flow can be traced from the battery through the pole piece windings, to a brush and commutator bar, through the loop of wire to the other commutator bar and brush, and then back to the battery. The magnetic fields create a turning or rotational effect in the same clockwire direction as shown in Figure 6s. The basic motor we have used in our illustrations has no LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -5 2 ENGINE ELECTRICAL Fig. 2 s — T y p ica l C ra n k in g S ystem MAGNETIC FIELD DIRECTION OF CURRENT FLOW Fig. 4 s — M a g n e tic Fo rce Fig. 3 s — M a g n e tic Field o f a H o rse s h o e M a g n e t practical value. It would produce very little torque to crank an engine. It has served, however, to show the fundamental principles that operate a starter motor. In the simplest terms, the armature is rotated by a concentration of magentic lines on one side of the armature conductor and a lack of magnetic lines on the other side of the conductor. Construction A cross-sectional view of a typical passenger car starter motor with a solenoid is shown in figure Is. The starting motor assembly is made up of field coils placed over pole pieces which are attached to the inside of a heavy iron frame, an armature, an overrunning clutch-type drive mechanism, and a solenoid. The iron frame and pole shoes not only provide a place for the field coils, but also provide a path for the magnetic lines produced by the field coil windings. Armature The armature assembly (Fig. 7s), consists of a stack of iron laminations placed over a steel shaft, a commutator assembly and the armature winding. The windings are heavy copper ribbon that are assembled into slots in the LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL 6Y -53 W INDING COMMUTATOR Fig. 7 s —A r m a t u r e A ss e m b ly CLUTCH SPRIMrl COLLA PINION AND COLLAR ASSEMBL iron laminations. The winding ends are soldered or welded to the commutator bars which are electrically insulated from each other and from the iron shaft. The armature is supported by bushings in the end frames. Brushes are supported on the field frame and ride on the commutator bars. Drive Mechanism The vehicle starting motor drive mechanism (Fig. 8s) is a roll-type overrunning clutch that is assembled onto the armature shaft. Through this drive component power is transmitted from the armature to the engine during the starting cycle. The overrunning clutch drive contains a pinion which is made to move along the shaft by means of a shift lever to engage the engine ring gear for cranking. A gear reduction is provided between the pinion and ring gear to meet the cranking requirements of the engine. With this gear reduction, the motor operates to crank the engine at speeds required for starting. The overrunning clutch drive has a shell and sleeve Fig. 6s—Magnetic Field Rotational Effect BUSHINGS SHELL AND SLEEVE ASSEMBLY LOCK WIRE Fig. 8 s — O v e r ru n n in g C lu tc h A s s e m b ly assembly which is splined internally to match the spiral splines on the armature shaft. The pinion is located inside the shell along with spring-loaded rollers that are wedged against the pinion and a taper inside the shell. The springs may be either a helical or accordion type. Four rolls are used. A collar and spring, located over the sleeve, are the other major clutch components. When the shift lever is operated by the solenoid, it moves the collar endwise along the shaft. The spring pushes the pinion into mesh with the ring gear. If a tooth abutment occurs, the spring compresses until the switch is closed, at which time the armature rotates and the tooth abutment is cleared. The compressed spring then pushes the pinion into mesh and cranking begins. Torque is transmitted from the shell to the pinion by the rolls which are wedged tightly between the pinion and taper cut into the shell. When the engine starts, the ring gear drives the pinion faster than the armature and the rolls move away from the taper, allowing the pinion to overrun the shell. The start switch should be opened immediately when the engine starts to avoid prolonged overrun. When the shift lever is moved back by the return spring, the pinion moves out of mesh and the cranking cycle is completed. SOLENOID A sectional view of a typical solenoid is shown in Figure LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -5 4 ENGINE ELECTRICAL 9s. It performs two functions in the starting system. First, it is used to provide a circuit of short length and low resistance between the battery and motor. Since the motor amy draw several hundred amperes during operation, heavy cables of short length are needed to reduce the voltage drop in the circuit. If a solenoid switch were not used and the high motor currents were carried directly through the start switch, cables of excessive size would be required to limit the voltage drop to an acceptable value. Since the start switch is usually some distance from the battery and solenoid switch, the long leads connected to the switch can be of reasonable size since they conduct only the small current drawn by the solenoid switch winding (Fig. 10s). HOLD-IN WINDING CONTACTS PULL-IN WINDING SHIFT LEVER (NOT A PART OF SOLENOID) Second, when the start switch is closed, the solenoid moves the pinion into mesh, and the cranking cycle begins. When the start switch is opened, the cranking cycle ends. The neutral safety switch in this type of circuit is closed only when the transmission shift lever is in the proper position, thereby preventing cranking of the engine with the transmission in gear. The solenoid switch consists basically of two windings mounted around a hollow cylinder containing a moveable core or plunger (Fig. 9s). A shift lever is connected to the plunger. When the push rod and contact disc is pushed into firm contact with the battery and motor terminals of the solenoid, with the motor windings connected directly to the battery, cranking takes place. The two windings in the solenoid are called the hold-in winding and the pull-in winding (Fig. 1 Is). The hold-in winding contains many turns of fine wire and the pull-in winding the same number of turns of larger wire. When the start switch is closed, current flows from the battery to the solenoid (S) terminals, through the hold-in winding to ground, and then back to the battery. Current also flows through the solenoid (M) terminal and then through the motor windings to the ground. The magnetism created by each winding adds together to form a strong magnetic field that attracts the plunger into the core. Plunger movement shifts the pinion into mesh with the ring gear and also moves the contact disc to close the circuit between the solenoid battery (B) and Motor (M) terminals. With the motor windings connected directly to the battery through the contact disc, cranking takes place. The pull-in winding operates to assist the hold-in winding in pulling the plunger into the core. Once the Fig. 9 s — S o len o id Cross S ection Fig. 10s—Start Switch Circuit (Typical) Fig. 11s—Solenoid Windings LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL IGNITION COIL TERMINAL CONTACT FINGER BATTERY TERMINAL SOLENOID WINDING TERMINAL MOTOR TERMINAL Fig. 12s—S o len o id C o n ta c t F in g e r 6Y-55 plunger movement has been completed, much less magnetism is needed to hold the plunger in the cranking position. With the contact disc contacting the battery and motor terminals of the solenoid, the pull-in winding is shorted and no current flows through it. This design feature reduces current draw on the battery and also reduces the amount of heat created in the solenoid. When the start switch is opened, current flows for a very brief instant through the contact disc to the solenoid motor (M) terminal, through the pull-in winding in a reverse direction to the solenoid (S) terminal and then through the hold-in winding in a normal direction back to the battery. The magnetisms created by each winding oppose and cancel out each other and the return spring moves the entire shifting mechanism to the at-rest position, to complete the cranking cycle. On most vehicle starting motors, a contact finger (Fig. 12s) touches the contact disc when the solenoid is in the cranking mode of operation. The contact finger is connected to the ignition coil terminal or (R) terminal on the solenoid, which in turn is connected directly to the ignition coil. This feature by-passes the ignition resistor and provides more available ignition voltage during cranking. SERVICE OPERATIONS STARTER MOTOR Lubrication No periodic lubrication of the starting motor or solenoid is required. Since the starting motor and brushes cannot be inspected without disassembling the unit, no service is required on these units between overhaul periods. Starting Motor Replacement (Fig. 13s) The following procedure is a general guide for all vehicles and will vary slightly depending on series and model. 1. Disconnect battery ground cable at battery. 2. Raise vehicle to a good working height. 3. Disconnect all wires at solenoid terminals. 4. 5. 6. 7. NOTE: Reinstall the nuts as each wire is disconnected as thread size is different but may be mixed and stripped. Loosen starter front bracket (nut on V-8 and bolt on L-6) then remove two mount bolts. NOTE: On V-8 Engines incorporating sole­ noid heat shield, remove front bracket upper bolt and detach bracket from starter motor. Remove the front bracket bolt or nut and rotate bracket clear of work area then lower starter from vehicle by lowering front end first -- (hold starter against bell housing and sort of roll end-over-end). Reverse the removal procedure to install. Torque the mount bolts to 25-35 ft. lbs. first, then torque brace bolt. Check operation of starter on vehicle. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -5 6 ENGINE ELECTRICAL 2 5 0 CID L-6 E N G IN E 3 0 7 CID V - 8 E N G IN E 3 5 0 CID V -8 E N G IN E 4 5 4 CID V -8 E N G IN E Fig. 13s—Starter Mounting Installation LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL 6Y-57 DIAGNOSIS NO CRANKING ACTION 1. Make sure that control lever is neutral (N) or park (P) position or that clutch pedal is depressed on manual transmission. 2. Make quick check of battery and cables. If battery is low, the solenoid usually will produce a clattering noise, because a nearly discharged battery will not sustain the voltage required to hold solenoid plunger in after solenoid switch as been closed. 3. If starter motor spins and drive pinion engages ring gear but does not drive it, overrunning clutch is slipping. Remove motor to replace drive assembly. 4. If starter motor does not operate, note whether solenoid plunger is pulled into solenoid when solenoid curcuit is closed. Ordinarily the plunger makes a loud click when it is pulled in. If plunger is pulled in, solenoid circuit is okay and trouble is in solenoid switch, cranking motor, or cranking motor circuit. The starter motor must be removed for repairs to switch or motor. 5. If plunger does not pull into solenoid when ignition switch is turned to "START", the solenoid circuit is open, or solenoid is at fault. 6. To find reason why plunger does not pull into solenoid, connect jumper between solenoid battery terminal and terminal on solenoid switch to which purple wire is connected. If cranking motor operates, solenoid is okay; trouble is in ignition switch, neutral start switch, or in wires and connections between these units. 7. If starter motor still does not operate, remove motor for inspection and test of solenoid switch. CRANKING SPEED ABNORMALLY LOW Abnormally low cranking speed may be caused by low battery or defective cables, defective solenoid switch, defective cranking motor, or an internal condition of engine. 1. Make quick check of battery. If low battery is indicated, test battery. If defective cables are indicated, test cables. NOTE: Check generator belt tension for cause of low battery. 2. If battery and cables are okay, test cranking motor and solenoid switch. 3. If starter motor and solenoid switch test okay, the trouble is due to an internal condition of engine. This may be due to use of engine oil which is too heavy for prevailing temperatures. VOLTAGE TEST OF STARTING SYSTEM AND SOLENOID SWITCH The voltage across the starter motor and switch while cranking the engine gives a good indication of any excessive resistance. NOTE: Engine must be at normal operating temperature when test is made. 1. Inspect battery and cables to make certain that battery has ample capacity for cranking and ignition. 2. Connect jumper wire to distributor terminal of coil and to ground on engine, so that engine can be cranked without firing. 3. Connect voltmeter positive lead to the motor terminal on solenoid switch; connect voltmeter negative lead to ground (Fig. 14s). 4. Turn ignition switch on, crank engine and take voltmeter reading as quickly as possible. If cranking motor turns engine at normal cranking speed with voltmeter reading 9 or more volts, the motor and switch are satisfactory. If cranking speed is below normal and voltmeter reading is 9 volts or greater, the cranking motor is defective. CAUTIO N: Do not operate starter motor more than 30 seconds at a time without pausing to allow motor to cool for at least two minutes; otherwise, overheating and damage to motor may result. 5. If starter motor turns engine at low rate of speed with voltmeter reading less than 9 volts, test solenoid switch contacts as follows: 6. With voltmeter switch turned to any scale above 12 volts, connect voltmeter negative lead to the motor Fig. 1 4 s —C ra n k in g V o lta g e T e s t C o n n e c tio n s LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -58 ENGINE ELECTRICAL terminal of solenoid switch, and connect positive lead to battery terminal of switch (Fig. 15s). 7. Turn ignition switch on and crank engine. Immediately turn voltmeter switch to low scale and take reading as quickly as possible, then turn switch back to higher scale and stop engine. The voltmeter will read not more than 2/10 volt if switch contacts are satisfactory. If voltmeter reads more than 2/10 volt, switch should be repaired or replaced. AMPERAGE TEST OF SOLENOID SWITCH WINDINGS (1) Current draw of both windings in parallel. (2) Current draw of hold-in winding alone. 1. Remove screw from solenoid motor terminal and bend field leads slightly until clear of terminal. Then ground solenoid motor terminal with a heavy jumper wire (Fig. 16s). 2. Connect a 12-volt battery, a variable resistance, and an ammeter of 100 amperes capacity in series with solenoid "S" terminal. Connect a heavy jumper wire from solenoid base to ground post of battery. 3. Connect a voltmeter between base of solenoid and small solenoid "S" terminal. 4. Slowly adjust resistance until voltmeter reads 10 volts and note ammeter reading. This shows current draw of both windings in parallel. Refer to DelcoRemy bulletin for specifications on the starter being tested. 5. Remove jumper wire from solenoid motor terminal and re-adjust resistance until voltmeter reads 10 volts, then note ammeter reading. This shows current draw of hold-in winding alone. Refer to Delco-Remy bulletin for specifications. 6. If solenoid windings do not test within specifica­ tions given, solenoid switch assembly should be replaced. CHECKING PINION CLEARANCE Whenever the starter motor is disassembled and reassembled, the pinion clearance should be checked. This is to make sure that proper clearance exists between the pinion and pinion stop retainer when pinion is in cranking position. Lack of clearance would prevent solenoid starter switch from closing properly; too much clearance would cause improper pinion engagement in ring gear. 1. Connect a source of approximately 6 volts (3 battery cells or a 6 volt battery) between the solenoid "S" terminal and ground. CAUTIO N: Do not use more than 6 volts or the motor will operate. As a further precaution to prevent motoring, connect a heavy jumper wire from the solenoid motor terminal to ground. 2. After energizing the solenoid, push the pinion away from the stop retainer as far as possible and use Fig. 1 5s — Solen oid S w itch C o n ta c t T e s t C o n n e c tio n s Fig. 17s—Checking Pinion Clearance LIGHT DUTY TRUCK SERVICE MANUAL E N G IN E ELECTRICAL feeler gauge to check clearance between pinion and retainer (Fig. 17s). 3. If clearance is not between .010" and .140" it indicates excessive wear of solenoid linkage, shift lever mechanism, or improper assembly of these parts. NOTE: Pinion clearance cannot be adjusted. If clearance is not correct, motor must be disassembled and checked for the above mentioned defects. Any defective parts must be replaced. BENCH TEST OF STARTING MOTOR To obtain full performance data on a cranking motor, or to determine the cause of abnormal operation, the motor should be removed from the engine and be submitted to a no-load test with equipment designed for such tests. A high current carrying variable resistance should be connected into the circuit so that the specified voltage at the starter motor may be obtained, since a small variation in the voltage will produce a marked difference in the current draw. (a) No-Load Test. Connect the starter motor in series with a 12 volt-battery and an ammeter capable of indicating several hundred amperes. If an RPM indicator is available, set it up to read armature RPM. Check current draw and armature RPM at the specified voltage. 1. Low no-load speed and high current draw may result from: (a) Tight, dirty, or worn bearings, bent armature shaft or loose field pole screws which would allow the armature to drag. (b) Shorted armature. Check armature further on growler. (c) A grounded armature or field. Check for grounds by raising the grounded brushes and insulating them from the commutator. If the starter 6Y -59 motor has shunt field coils which are grounded to the field frame, disconnect these fields from gound. Then check with a test lamp between the insulated terminal and the frame. If lamp lights, raise other brushes from commutator and check fields separately to determine whether it is the fields or armature that is grounded: 2. Failure to operate with high current draw may result from: (a) A direct ground in the terminal or fields. (b) Frozen shaft bearings which prevent the armature from turning. 3. Failure to operate with no current draw may result from: (a) Open field circuit. Inspect internal connec­ tions and trace circuits with test lamp. (b) Open armature coils. Inspect the commuta­ tor for badly burned bars. (c) Broken or weakened brush springs, worn brushes, high mica on the commutator, or other causes which would prevent good contact between the brushes and commuta­ tor. Any of these conditions will cause burned commutator bars. 4. Low no-load speed with low current draw indicates: (a) An open field winding. Raise and insulate ungrounded brushes from commutator and check fields with test lamp. (b) High internal resistance due to poor connections, defective leads, dirty commu­ tator and causes listed under item 3 (c). 5. High no-load speed with high current draw indicates shorted fields. There is no easy way to detect shorted fields, since the field resistance is already low. If shorted fields are suspected, replace the fields and check for improvement in performance. LIGHT DUTY TRUCK SERVICE MANUAL 6 Y -6 0 ENGINE ELECTRICAL D IA G N O S IS C H A R T N O T H IN G HAPPENS W HEN S T A R T A T T E M P T PROBABLE CAUSE 1. 2. 3. 4. 5. Undercharged or defective energizer. Loose energizer cables. Burned fusible link in starting circuit. Incorrectly positioned or defective neutral start switch. Loose or defective wiring between neutral start switch and ignition switch. 6. Defective starter motor. IS M A D E REMEDY Check condition of energizer and recharge or replace as re­ quired. Clean and tighten cable connections. Check for burned fusible link. Correct wiring problem. Check neutral start switch adjustment. If O.K., replace switch. Check for loose connections and opens between energizer, horn relay, ignition switch, and solenoid “S” terminal. Check energizer ground cable. Replace or repair defective item. Repair or replace starter motor. S O L E N O ID S W IT C H C L IC K S B U T S T A R T E R D O ES N O T C R A N K 1. 2. 3. 4. 5. 6. PROBABLE CAUSE Undercharged or defective energizer. Loose energizer cables. Loose or defective wiring at starter. Defective solenoid. “Hot stall” condition. Excessive engine rotational torque caused by mechanical problem within engine. 7. Defective starter motor. REM EDY Test energizer. Recharge or replace energizer. Check and tighten energizer connections. Tighten connections or repair wiring as required Replace solenoid. Check engine cooling system. Check engine torque for excessive friction. Repair or replace starter motor. S O L E N O ID S W IT C H PUM PS IN PROBABLE CAUSE Undercharged or defective energizer. 2 . Loose connections or opens between energizer, horn relay, ignition switch, neutral start switch, and solenoid “S” ter­ minal, plus energizer ground cable. 3. Defective solenoid 1. AND OUT REMEDY Test energizer. Recharge or replace energizer. Replace or repair wiring or switches. Replace solenoid. S T A R T E R KEEPS R U N N IN G A F T E R IG N IT IO N S W IT C H IS R E L E A S E D - F R O M " S T A R T " T O " R U N " P O S IT IO N _______________ P R O B A B L E C A U S E ______ __________________________________ R E M E D Y 1. Defective ignition switch. 2. Defective solenoid Replace ignition switch. Replace solenoid. S T A R T E R SPINS A N D /O R M A K E S L O U D G R IN D IN G N O IS E B U T D O ES N O T T U R N E N G IN E _______________ P R O B A B L E C A U S E __________________________________________ R E M E D Y 1. Defective starter motor. Repair or replace starter motor. LIGHT DUTY TRUCK SERVICE MANUAL EN G IN E ELECTRICAL 6Y-61 SLO W C R A N K IN G PROBABLE CAUSE Vehicle is overheating. 2. Undercharged or defective energizer. 3. Loose or defective wiring between energizer and engine block. Loose or defective wiring between energizer and solenoid “Bat.” terminal. 5. Defective starter motor. 1. REMEDY Check engine cooling system and repair as required. Recharge or replace energizer. Repair or replace wiring. Repair or replace wiring. Repair or replace starter. S T A R T E R E N G A G E S (" C L U N K S ” ) B U T E N G IN E D O ES N O T C R A N K PROBABLE CAUSE REMEDY 1. Open circuit in solenoid armature or field coils. 2. Short or ground in field coil or armature. Repair or replace solenoid or starter motor. Repair or replace starter motor. Special Tools J 21501 puiir ADAPTER Fig. 18s—Special Tools LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7M-1 SECTION 7M CLUTCHES & MANUAL TRANSMISSIONS CONTENTS OF THIS SECTION Clutch Controls Clutches.............. 7M-1 7M-10 Manual Transmissions................................................... 7M-17 Special Tools..................................................................... 7M-46 CLUTCH CONTROLS INDEX General Description....................................................... 7M-1 Maintenance and Adjustments................................... 7M-5 Clutch Linkage Inspection......................................... 7M-5 Clutch Free Pedal Travel Adjustment.....................7M-5 Insufficient Clutch Release......................................... ..7M-5 Clutch Pedal Arm Assembly Replacement......... ..7M-6 Clutch Cross Shaft Replacement............................ ..7M-7 GENERAL DESCRIPTION The clutch operating controls for C-K trucks (fig. la) are a mechanical type consisting of a pendant type pedal, return spring, pedal push rod. cross-shaft, fork push rod, clutch fork and throwout bearing. The pedal push rod is routed vertically, inside the cab, from the pedal lever down through two boots on the toe pan. to the cross­ shaft lever. When the clutch pedal is depressed, the pedal push rod moves rotating the cross-shaft, pushing the fork push rod rearward, and pivoting the clutch fork to move the throwout bearing against the clutch release fingers and releasing the clutch. The clutch operating controls for "G " and "P" models are a mechanical type similar to the C-K models. On "G " models (fig. lb), a pedal pull rod is routed vertically from the clutch pedal lever down through the toe panel to the cross shaft. When the pedal is depressed, the pedal pull rod moves rotating the cross shaft, pushing the clutch fork rod rearward and pivoting the clutch fork. This action moves the throwout bearing against the clutch release fingers, releasing the clutch. "P" model controls (fig. lc) have an upper pull rod connected from the clutch pedal shaft to a bell crank and a lower pull rod from the bell crank to the cross shaft. When the pedal is depressed, the pull rods are moved rotating the cross shaft and pushing the clutch fork rearward, thus subsequently activating the clutch release mechanism. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 CLUTCHES & M A N U A L T R A N S M IS S IO N S VIEW B Fig. la —Clutch Linkage Assy. (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7M -3 LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 4 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. lc —Clutch Linkage Assy. (P Models) LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7 M -5 MAINTENANCE AND ADJUSTMENTS CLUTCH LINKAGE INSPECTION There are several things which affect good clutch operations. Therefore, it is necessary, before performing any major clutch operations, to make preliminary inspections to determine whether trouble is actually in the clutch. Check the clutch linkage to be sure the clutch releases fully as follows: 1. With engine running, hold the clutch pedal approximately 1/2" from floor mat and move shift lever between first and reverse several times. If this can be done smoothly, the clutch is fully releasing. If shift is not smooth, clutch is not fully releasing and adjustment is necessary. 2. Check clutch pedal bushings for sticking or excessive wear. 3. Check fork for proper installation on ball stud. Lack of lubrication on fork can cause fork to be pulled off the ball. 4. Check for bent, cracked or damaged cross shaft levers or support bracket. 5. Loose or damaged engine mounts may allow the engine to shift its position causing a bind on clutch linkage at the cross shaft. Check to be sure there is some clearance between cross shaft, both mount brackets, and ball studs. 6. Check throw out bearing end clearance between spring fingers and front bearing retainer on the transmission. If no clearance exists, fork may be improperly installed on ball stud or clutch disc may be worn out. CLUTCH FREE PEDAL TRAVEL ADJUSTMENT Only one adjustment is necessary to compensate for all normal clutch wear. The clutch pedal should have free travel (measured at clutch pedal pad) before the throwout bearing engages the clutch diaphragm spring levers. Lash is required to prevent clutch slippage which would occur if the bearing was held against the fingers or to prevent the bearing from running continually until failure. A clutch that has been slipping prior to free play adjustment may still slip right after the new adjustment due to previous heat damage. C, K and P Models Except P30 W/H22-23 1. Disconnect return spring at clutch fork. 2. Rotate clutch lever and shaft assembly until clutch pedal is firmly against rubber bumper on brake pedal bracket. 3. Push outer end of clutch fork rearward until throwout bearing lightly contacts pressure plate fingers. 4. Loosen lock nut and adjust rod length so that swivel slips freely into gauge hole. Install push rod in gauge hole and increase length until all lash is removed from system. 5. Remove swivel or rod from gauge hole and insert into lower hole on lever. Install two washers and cotter pin. Tighten lock nut being careful not change rod length. 6. Reinstall return spring and check pedal free travel. Pedal travel should be 1 3/8" to 1 5/8" on "C-K" models and 1 1/4" to 1 1/2" on "P" models. P-30 Models W/H22-23 (Fig. 2) 1. Disconnect clutch fork return spring. 2. Loosen nut "G " at swivel. 3. Move the clutch fork rod against fork to eliminate all clearance between throwout bearing and clutch fingers. 4. Rotate shaft lever until clutch pedal contacts the bumper mounted on the brake pedal bracket. 5. Rotate the fork rod until a clearance of approx­ imately 1/4" to 5/16" (.29) is obtained between the shoulder on the fork rod and the adjustment nut. 6. Tighten nut "G " against swivel and install clutch return spring. 7. Check free pedal clearance at pedal. Pedal clearance should be 1 3/8" to 1 5/8". Readjust as required. G-Models (Fig. 3) 1. Disconnect clutch fork return spring at fork. 2. Loosen nut "A " and back off from swivel approximately 1/2 inch. 3. Hold clutch fork push rod against fork to move throwout bearing against clutch fingers (push rod will slide through swivel at cross-shaft). 4. Adjust nut "B" to obtain approximately 1/4" clearance between nut "B" and swivel. 5. Release push rod, connect return spring and tighten nut "A" to lock swivel against nut "B". 6. Check free pedal clearance at pedal (3/4" to 1" is proper clearance). Readjust if necessary. INSUFFICIENT CLUTCH RELEASE Where complaints of first or reverse gear clash due to insufficient clutch release are encountered, the following may be helpful. Cut off the existing clutch pedal stop bumper to a height of 3/8". Since shortening the bumper increases the lash and not the usable stroke, the lash must be reduced to specifications in order to gain the additional stroke benefit. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 6 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. 3 — Free T ra v e l A d ju s tm e n t (G M o d e ls ) CLUTCH PEDAL ARM, PUSH ROD OR BUSHING REPLACEMENT (Fig. 4) C-K Models Removal Fig. 2—Clutch Pedal Free Travel Adjustment 1. Disconnect battery negative ground cable at the battery terminal. 2. Disconnect clutch push rod at the cross shaft under the vehicle. 3. Remove steering column covers. Remove screws retaining push rod boots to bulkhead. 4. Disconnect parking brake release from the instrument cluster. 5. Remove air conditioning duct from lower left side of instrument cluster if so equipped. (Refer to Section 1A, Truck Service Manual for A /C Service Information). CAUTIO N : Maintain pressure on lower arm. When lower attaching bolt is removed upper section will snap upward. 6. Remove bolts attaching lower section of clutch pedal arm to the upper arm. 7. Remove lower arm and push rod from vehicle. 8. Remove pedal return spring. 9. Remove pedal pivot shaft retaining nut and pivot shaft. Insert a dummy shaft or rod through the support to hold the brake pedal components in place. 10. Remove the clutch pedal assembly from the support assembly. 11. Remove pedal bushings and spacer from pedal LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S arm. Check pedal bumper for wear and replace as required. Installation 1. Install new bushings and spacer in pedal arm. Components should be lubricated prior to assembly. 2. Position clutch pedal upper arm in support bracket and install pivot bolt through support and pedal arms. 3. Install pivot bolt retaining nut and torque to specifications. 4. Install pull back spring to support and pedal arm. NOTE: If previously removed, connect pedal push rod to clutch pedal arm. 5. Position lower pedal arm to upper arm and install upper attaching bolt. Push down on pedal and install lower bolt. Torque to specifications. 6. Install air conditioning duct. 7. Install steering column covers. Install screws retaining push rod boots to bulk head. 8. Position parking brake release to instrument panel and install attaching bolts. 9. Check operation of clutch assembly and adjust clutch as required. G and P Models (Fig. 4) Removal 1. Apply parking brake firmly. 2. Remove bolt at clutch pedal push rod lever, then remove lever from pedal shaft. 3. Hold pedal pad with one hand and slide clutch pedal and shaft assembly outboard enough to clear pedal stop. Insert a dummy shaft or rod through support and brake pedal assembly to hold components in place while removing clutch pedal shaft. Allow return spring (or center spring) to pull pedal up high enough to unhook spring from pedal arm. 7 M -7 4. Remove pedal and shaft assembly from support bracket. Inspection 1. Check clutch pedal bushings for excessive wear and replace is necessary. 2. Check clutch pedal shaft for wear and alignment and straighten or replace if necessary. Installation 1. 2. 3. 4. NOTE: Use new shaft bushing if needed. Lubricate with Lubriplate or petrolatum. Slide one pedal shaft bushing over shaft, install shaft in support enough to still clear pedal bumper stop, hook pedal return (or overcenter) spring to pedal, then rotate pedal forward of bumper stop; slide shaft into position in support and release pedal against bumper stop. Install clutch pedal shaft bushing over pedal shaft end and into place in sleeve. Assemble pedal push rod lever over pedal shaft and install bolts, washers, and nut. Adjust clutch pedal free travel as needed. CLUTCH CROSS-SHAFT REPLACEMENT (Fig. i) Removal 1. Disconnect clutch fork return spring at fork. 2. Disconnect pedal push rod at cross-shaft lever and allow clutch fork push rod to hang free from lower lever. 3. On C-K models, remove ball stud retaining nut, at frame end and slide shaft toward engine. Then lift cross-shaft up to clear bracket and remove shaft from the engine ball stud. On panel G models, remove frame bracket retaining bolts, then remove shaft from engine ball stud. 4. Remove clutch fork push rod from cross-shaft lever. 5. Reverse removal procedure to install. LIGHT DUTY TRUCK SERVICE MANUAL 7M-8 CLUTCHES & MANUAL TRANSMISSIONS LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & MANUAL TRANSMISSIONS 7M-9 CLUTCHES DIAPHRAGM SPRING CLUTCH INDEX Theory of Operation...................................................... Clutch................................................................................ Clutch Components....................................................... Clutch Operation........................................................... 7M-9 7M-9 7M-9 7M-12 Service Operations........................................................... Preliminary Inspection................................................. Clutch Replacement...................................................... Diagnosis............................................................................. 7M-13 7M-13 7M-13 7M-16 THEORY OF OPERATION CLUTCH Automotive clutches depend on friction for their operation, whether it be solid friction as in the conventional clutch, or fluid friction and inertia as utilized in the fluid coupling and torque converter. The fluid coupling serves the same purpose as the conventional clutch, but the difference in the principle of operation makes it necessary to discuss the two mechanisms separately. Conventional clutches will be discussed in this section. A clutch in an automotive vehicle (Fig. 5) provides a means of connecting and disconnecting the engine from the power transmission system. Since the internal combustion engine does not develop a high starting torque, it must be disconnected from the power train and allowed to operate without load until it develops enough torque to overcome the inertial of the vehicle when starting from rest. The application of the engine power to the load must be gradual to provide smooth engagement and to lessen the shock on the driving parts. After engagement, the clutch must transmit all the engine power to the transmission without slipping. Further, it is desirable to disconnect the engine from the power train during the time the gears in the transmission are being shifted from one gear ration to another. The transmission of power through the clutch is accomplished by bringing one or more rotating drive members secured to the crankshaft into gradual contact with one or more driven members secured to the unit being driven. These members are either stationary or rotating at different speeds. Contact is established and maintained by strong spring pressure controlled by the driver through the clutch pedal and suitable linkage.- As spring pressure increases, the friction increases: therefore, when the pressure is light, the comparatively small amount of friction between the members permits a great deal of slippage. As the spring pressure increases, less slippage occurs until, when the full spring pressure is applied, the speed of the driving and driven members is the same. All slipping has stopped and there is, in effect, a direct connection between the driving and driven parts. CLUTCH COMPONENTS The principal parts of a clutch are: the driving members, attached to the engine and turning with it; the driven members attached to the transmission and turning with it; the operating members which include the spring or springs and the linkage required to apply and release the pressure which holds the driving and driven members in contact with each other. Figure 6 shows a clutch cutaway so operating members can be seen. Driving Members The driving members of a clutch usually consist of two nodular iron plates or flat surfaces machined and ground to a smooth finish. Nodular iron is desirable because it contains enough graphite to provide some lubrication when the driving member is slipping during engage­ ment. One of these surfaces is usually the rear face of the engine flywheel, and the other is a comparatively heavy flat ring with one side machined and surface. This part is known as the pressure plate. It is fitted into a steel cover, which also contains some of the operating members, and is bolted to the flywheel. Driven Members The driven member is a disc with a splined hub which is free to slide lengthwise along the splines of the clutch shaft, but which drives the shaft through these same splines.,Grooves on both sides of the clutch driven plate lining prevent sticking of the plate to the flywheel and pressure plate due to vacuum between the members on disengaging. The clutch driven plate (Fig. 7) is usually made of spring steel in the shape of a single flat disc consisting of a number of flat segments. Suitable frictional facings are attached to each side of the plate by means of brass rivets. These facings must be heat resistant since friction produces heat. The most commonly used facings are made of cotton and asbestos fibers woven or molded together and impregnated with resins or similar binding agents. Very often, copper wires are woven or pressed into material to give it additional strength. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 1 0 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. 5 — E xp lo d e d V ie w of C lu tc h a n d Flyw heel A s s e m b ly In order to make clutch engagement as smooth as possible and eliminate chatter, the steel segments attached to the splined hub are slightly waved, which also causes the facings to make gradual contact as the waved springs flatten out. The driven member of the clutch (fig. 7) is usually provided with a flexible center to absorb the torsional vibration of the crankshaft which would be transmitted to the power train unless it were eliminated. The flexible center usually takes the form of steel compression springs placed between the hub and the steel plate. The springs permit the plate to rotate slightly with relation to its hub until, under extreme conditions, the springs are fully compressed and relative motion stops. Then the plate can rotate slightly backward as the springs decompress. This slight backward and forward rotation permitted by the springs allows the clutch shaft to rotate at a more uniform rate than the crankshaft, thereby eliminating some of the torsionaly vibration from the crankshaft and preventing the vibration from being carried back through the transmission. Operating Members The driving and driven members are held in contact by spring pressure. This pressure may be exerted by a onepiece conical or diaphragm spring (fig. 6) or; a number of small helical springs located circumferentially around the outer portion of the pressure plate (fig. 8). In the diaphragm design clutch, the throwout bearing moves forward against the spring fingers forcing the diaphragm spring to pivot around the inner pivot ring, dishing the fingers toward the flywheel. The outer circumference of the spring now lifts the pressure plate away from the driven disc, through a series of retracting springs placed around the outer circumference of the pressure plate. In the helical-spring clutch a system of levers pivoted on the cover forces the pressure plate away from the driven disc and against the pressure of the springs thus performing the same function as the dish-shaped diaphragm spring. NOTE: Two variations of the diaphragm spring design are the flat finger type and the bent finger type (fig. 6). The integral release fingers in the bent finger design are bent back to gain a centrifugal boost to aid quick re-engagement at high engine speeds. This design is used primarily with high perform­ ance V-8 engines and heavy duty clutch assemblies. The clutch release or (throw-out) bearing is a ball-thrust bearing contained in the clutch housing, mounted on a sleeve attached to the front of the transmission case. The release bearing is connected through linkage to the clutch, and is moved by the release fork to engage the release levers and move the pressure plate to the rear, LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7 M -1 1 FLAT FINGER BENT FINGER 1. 2. Flywheel Dowel-hole 3. 4. Pilot Bushing Driven Disc 5. 6. Pressure Plate Diaphragm Spring 7. Cover 8. Throwout Bearing 9. 10. Fork Retracting Spring Fig. 6—Diaphragm Spring Clutch Cross-section (Typical) LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 1 2 CLUTCHES & M A N U A L T R A N S M IS S IO N S FRICTION RING DRIVE WASHER FLANGE FACINGS STOP PIN CUSHION SPRINGS Fig. 7 —C lu tc h D riv e n TORSIONAL COIL SPRINGS P la te A s s e m b ly thus separating the clutch driving members from the driven member when the clutch pedal is depress by the driver. A return spring preloads clutch linkage, removing looseness due to wear. The clutch free pedal travel, therefore, will increase with linkage wear and decrease with driven disc wear and the free travel felt at the clutch pedal is throwout bearing lash. NOTE: The clutch release bearing used with the bent finger design is of shorter length than the release bearing used with the flat finger design clutch. Do not interchange the two bearings. The longer bearing, if used with the bent finger spring clutch, will cause inability to obtain free pedal travel, resulting in slippage and rapid wear. CLUTCH OPERATION Diaphragm Clutch In diaphragm spring type clutches, a diaphragm is used instead of coil springs. It is a conical piece of spring steel punched to give it greater flexibility. The diaphragm is positioned between the cover and the pressure plate so that the diaphragm spring is nearly flat when the clutch is in the engaged position. The action of this type of spring is similar to that of the bottom of an ordinary oil can. The pressure of the outer rim of the spring on the pressure plate increases until it reaches the flat position and decreases as this position is passed. The outer rim of the diaphragm is secured to the pressure plate and is pivoted on rings approximately 1 inch in from the outer edge so that the application of the pressure at the inner section will cause the outer rim to move away from the flywheel and draw the pressure plate away from the clutch disc, releasing or disengaging the clutch. When the pressure is released from the inner section, the oil­ can action of the diaphragm causes the inner section to move out, and the movement of the outer rim forces the pressure plate against the clutch disc, thus engaging the clutch. 1. 2. 3. 4. 5. 6. Release Lever Eyebolt Strut Cover Adjustment Nut Coil Spring 7. 8. 9. 10. 11. Drive Disc Pressure Plate Anti-Rattle Spring Throwout Bearing Flywheel Fig. 8 —C oil S p rin g C lu tc h C ro ss -s e ctio n Coil Spring Clutch In some clutches, coil springs are used instead of a diaphragm spring. This type of clutch (fig. 8) operates as follows: When the clutch is fully engaged, the driven disc is firmly clamped between the flywheel and the pressure plate by the pressure of the springs. When the driver disengages the clutch by depressing the pedal, the release fork is moved on its pivot, and the pressure is applied to the release bearing. The rotating race of the release bearing presses against the clutch release levers and moves them on their pivot pins. The outer ends of the release levers, being fastened to the cover, move the pressure plate to the rear, compressing the clutch springs and allowing driving members to rotate independently of the driven member. The release fork moves only on LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S its pivot, which is attached to the clutch fork ball stud. All parts of the clutch, except the release bearing and collar, rotate with the flywheel when the clutch is 7M -13 engaged. When the clutch is disengaged, the release bearing rotates with the flywheel, but the driven plate and the clutch shaft come to rest. SERVICE OPERATIONS PRELIMINARY INSPECTION There are many things which affect good clutch operation. Therefore, it is necessary, before performing any major clutch operations, to make a preliminary inspection to determine whether or not the trouble is actually in the clutch. 1. Check the clutch pedal and make sure that the pedal has at least 3 /4 "-l" free travel. 2. Check the clutch pedal bushing for wear and for sticking on the shaft or loose mountings. 3. Lubricate the pedal linkage. 4. Tighten all front and rear engine mounting bolts. Should the mountings be oil soaked, it will be necessary to replace them. CLUTCH REPLACEMENT Removal From Vehicle 1. Remove transmission as outlined in “Transmission Section.” 2. Disconnect clutch fork push rod and pull back spring. 3. Remove clutch and flywheel housing. 4. Remove clutch fork by pressing it away from its ball mounting with a screwdriver, until the fork snaps loose from the ball or remove ball stud from rear of clutch housing. Remove throwout bearing from clutch fork. NOTE: The retainer may be removed from the fork by prying out with a small screwdriver. 5. Install Tool J-5824 or a used clutch drive gear to support the clutch assembly during removal. 6. Loosen the clutch attaching bolts one turn at a time to prevent distortion of clutch cover until diaphragm spring is released. 7. Remove clutch pilot tool and remove clutch assembly from vehicle. NOTE: The flywheel should be inspected for cracks, heat checking and other defects. Installation to Vehicle l. Install the pressure plate in the cover assembly 2. 3. 4. 5. 6. 7. lining up the notch mark on pressure plate with notch mark on flange of cover. Install pressure plate retracting springs, lockwashers and drive strap to pressure plate bolts. Tighten to 11 ft. lbs. torque. The clutch is now ready to be installed. Hand crank the engine until “X” mark on flywheel is at the bottom. Install clutch disc, pressure plate and cover assembly and support them with Tool J-5824 or a used clutch drive gear. Turn clutch assembly until “X” mark or painted white letter on clutch cover flange lines up with “X” mark on flywheel. Install attaching bolts and tighten each one a turn at a time to prevent distorting the cover as the spring pressure is taken up. Remove clutch pilot Tool. Fig. 9—Lubrication Points on Clutch Throwout Bearing LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 1 4 CLUTCHES & M A N U A L T R A N S M IS S IO N S 8. Pack dutch fork ball seat with a small amount of high melting point grease and install a new retainer in the groove of the clutch fork if the old retainer is worn or damaged. NOTE: Install retainer with high side up, away from bottom of the ball socket and with open end of retainer on the horizontal. CAUTION: Be careful not to use too much lubricant. Excessive lubricant may get on clutch fingers and cause slippage. 9. Replace clutch fork ball if removed from the clutch housing and snap clutch fork onto the ball. 10. Pack lubricant in the recess on the inside of the throwout bearing collar and coat the throwout fork groove with a small amount of graphite grease (fig. 9). Install throwout bearing assembly to the throwout fork. Install clutch and flywheel housing to engine. 12. Assemble transmission as outlined in Transmission Section, 13. Align push rod to clutch fork and attach return spring to clutch fork. 14. Adjust clutch linkage (See adjustments in this section). COIL SPRING CLUTCH INDEX General Description....................................................... 7M-14 Theory of Operation (Refer to Diaphragm Clutch)................................................................................. 7M-9 Service Operations.......................................................... 7M-14 Clutch Assembly Replacement.................................. 7M-14 GENERAL DESCRIPTION The coil spring single plate clutch (Fig. 8) is a dry disc type and no adjustment for wear is provided in the clutch itself. An individual adjustment is provided for locating each lever in manufacturing but the adjusting nut is locked in place and should never be disturbed, unless the clutch is dismantled for replacement of parts. When the clutch pedal is depressed the release bearing is moved toward the flywheel and contacts the inner ends of the release levers, (1) (fig. 10). Each release lever is pivoted on a floating pin which remains stationary in the lever and rolls across a short flat portion of the enlarged hole in the eyebolt (2). The outer end of each release lever engages the pressure plate lug by means of a strut (3), which provides knife-edge contact between the outer end of the lever and the lug. The outer ends of the eyebolts extend through holes in the stamped cover (4), and are fitted with adjusting nuts (5) to correctly position the levers. Fig. 10—Release Lever SERVICE OPERATIONS CLUTCH ASSEMBLY REPLACEMENT 2. Disconnect clutch fork push rod and pull back Removal From Vehicle spring. .. , . 3. Remove clutch and flywheel housing. 1. Remove transmission as outlined in Transmission Section.” 4. Remove clutch fork by pressing it away from its LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S ball mounting with a screwdriver, until the fork snaps loose from the ball or remove ball stud from rear of clutch housing. Remove throwout bearing from clutch fork. NOTE: The retainer may be removed from the fork by prying out with a small screwdriver. 5. Install Tool J-5824 or a used clutch drive gear to support the clutch assembly during removal. NOTE: Before removing clutch from fly­ wheel, mark the flywheel, clutch cover and one pressure plate lug, so that these parts may be assembled in their same relative positions, as they were balanced as an assembly. 6. Loosen the holding screws a turn or two at a time to avoid bending rim of cover. It is advantageous to place wood or metal spacers (approximately 3/8 thick) between the clutch levers and the cover to hold the levers down as the holding screws are removed or when clutch is removed from engine. When removing driven plate be sure to mark flywheel side. 7. Remove clutch pilot tool and remove clutch assembly from vehicle. NOTE: Inspect flywheel for heat defects, cracks or other defects. Installation To Vehicle 1. Assemble driven plate and clutch cover assembly to flywheel in accordance with marking on driven plate for flywheel side. Use Tool J-5824 or a dummy shaft to support assembly. 7M -15 2. Line up the clutch assembly with "X " mark or painted white letter with "X " mark on flywheel, before tightening cover holding screws. 3. Tighten holding screws, a turn at a time, before re­ moving dummy shaft. 4. 5. Remove clutch pilot tool. Pack clutch fork ball seat with a small amount of high melting point grease and install a new retainer in the groove of the clutch fork if the old retainer is worn or damaged. NOTE: Install retainer with high side up, away from bottom of the ball socket and with open end of retainer oon the horizontal. CAUTIO N: Be careful not to use too much lubricant. Excessive lubricant may get on clutch fingers and cause slippage. 6. Replace clutch fork ball if removed from the clutch housing and snap clutch fork onto the ball. 7. Pack lubricant in the recess on the inside of the throwout bearing collar and coat the throwout fork groove with a small amount of graphite grease (fig. 9). 8. Install throwout bearing assembly to the throwout fork. Install clutch and flywheel housing to engine. 9. Assemble transmission as outlined in Transmission Section, 10. Align push rod to clutch fork and attach return spring to clutch fork. 11. Adjust clutch linkage (See adjustments in this section). LIGHT DUTY TRUCK SERVICE MANUAL 7M-16 CLUTCHES & MANUAL TRANSMISSION C L U T C H T R O U B L E D IA G N O S IS CONDITION Fails to Release (Pedal pressed to floor-shift lever does not move freely in and out of reverse gear a. b. c. d. e. f. PROBABLE CAUSE Improper linkage Adjustment Improper pedal travel Loose linkage Faulty pilot bearing Faulty driven disc Fork off ball stud g. Clutch disc hub binding on clutch gear spline h. Clutch disc warped or bent Slipping a. Improper Adjustment (no lash) b. Oil Soaked driven disc c. Worn facing or facing torn from disc. d. Warped pressure plate or flywheel e. Weak diaphragm spring Grabbing (Chattering) Rattling-Transmission Click Throw-Out Bearing Noise with Clutch Fully Engaged Noisy Pedal Stays on Floor When Disengaged Hard Pedal Effort f. Driven plate not seated in g. Driven plate overheated a. Oil on facing. Burned or glazed facings. b. Worn splines on clutch gear. c. Loose engine mountings. d. Warped pressure plate or flywheel. e. Burned or smeared resin on flywheel or pressure plate. a. Weak retracting springs. b. Throw-out fork loose on ball stud or in bearing groove. c. Oil in driven plate damper. d. Driven plate damper spring failure. a. Improper adjustment. No Lash. b. Throw-out bearing binding on trans­ mission bearing retainer. c. Insufficient tension between clutch fork spring and ball stud. d. Fork improperly installed. e. Weak linkage return spring. a. Worn throw-out bearing. b. Fork off ball stud (heavy clicking). CORRECTION a. Adjust Linkage b. Trim bumper stop and adjust linkage c. Replace as necessary d. Replace bearing e. Replace disc f. Install properly and* lubricate fingers at throw-out bearing with wheel bearing grease. g. Repair or replace clutch gear and/or disc. h. Replace disc (run-out should not exceed .020”). *Very lightly lubricate fingers a. Adjust linkage to spec. b. Install new disc and correct leak at its source c. Replace disc d. Replace pressure plate or flywheel e. Replace pressure plate (Be sure lash is checked before replacing plate.) f. Make 30 to 40 normal starts CAUTION: Do Not Overheat g. Allow to cool - check lash a. Install new disc and correct leak. b. c. d. e. a. b. c. d. a. b. c. d. e. a. b. c. Pilot Bearing loose in crankshaft. a. Bind in linkage or release bearing. c. a. b. Springs weak in pressure plate. c. Springs being over traveled. b. c. a. Bind in linkage. b. Driven plate worn. a. b. Replace transmission clutch gear. Tighten or replace mountings. Replace pressure plate or flywheel. Sand off if superficial, replace burned or heat checked parts. Replace pressure plate. Check ball stud and retaining. Replace driven disc. Replace driven disc. Adjust linkage. Clean, relubricate, check for burrs, nicks, etc. Replace fork. Install properly. Replace spring. Replace bearing. Install properly and lubricate fork fingers at bearing. See Section 6 for bearing fits. Lubricate and free up linkage and release bearing. Replace pressure plate. Adjust linkage to get proper lash, be sure proper pedal stop (bumper) is installed. Lubricate and free up linkage. Replace driven plate. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & MANUAL TRANSMISSION 7M-17 MANUAL TRANSMISSIONS INDEX General Description....................................................... Theory of Operation...................................................... Synchronizing Mechanism......................................... Synchronizing Operation............................................. Power Flow...................................................................... Service Operations.......................................................... Linkage Adjustment..................................................... 7M-17 7M-21 7M-21 7M-22 7M-24 7M-29 7M-29 Floor Shift Control Lever Replacement............... 7M-29 Transmission Replacement.......................................... 7M-29 Transmission Alignment...............................................7M-33 Rear Oil Seal Replacement........................................ 7M-34 Speedometer Driven Gear Replacement................7M-35 Side Cover Replacement/Repair...............................7M-35 Transfer Case Replacement...................................... .7M-35 Diagnosis............................................................................ .7M-41 GENERAL DESCRIPTION The three speed synchromesh transmissions used by GM (Fig. II and 12) are representative of a constant-mesh transmission design. Fundamental components of these units are the case, which houses the gears and shaft; the control cover, which houses the shifter mechanism; and the various shafts and gears. The input shaft has an integral main drive gear and rotates with the clutch driven plate; that is, the shaft rotates all the time the clutch is engaged and the engine is running. The input shaft is supported in the case by a ball bearing and at the front end by an oil impregnated bushing mounted in the engine crankshaft. The drive gear is in constant mesh with the countershaft drive gear. Since all gears in the coutershaft cluster are integral to the shaft, they also rotate at the time the clutch is engaged. The countergear is carried on roller bearings at both ends and thrust is absorbed by thrust washers located between the countergear and thrust bosses in the case. An anti-lash plate assembly at the front face of the countergear provides a constant spring tension between the countergear and the main drive gear to reduce torsional vibrations. The transmission mainshaft is held in line with the input shaft by a pilot bearing at its front end, which allows it to rotate or come to rest independently of the input shaft. Its carried at the rear by a ball bearing mounted in the front face of the extension housing. Helical gears are incorporated throughout, including reverse gear. The mainshaft gears are free to rotate independently on the mainshaft and are in constant mesh with the countershaft gears. The reverse idler gear is carried on a bushing; finish bored in place, and thrust is taken on the thrust bosses of the case. The transmissions are fully synchronized in all forward speeds, however, reverse gear is not. The synchronizer assemblies consist of a hub, sleeve, two key springs and three synchronizer keys. The snychronizer hubs are splined to the mainshaft and retained by snap rings. These assemblies permit gears to be selected without clashing, by synchronizing the speeds of mating parts before they engage. Synchronizer assemblies are discussed separately later in this section. Four of the transmission gears are rididly connected to the countergear. These are the driven gear, second-speed gear, first-speed gear and reverse gear. The engine driven clutch gear drives the countergear through a constant mesh countershaft driven gear. The countergear rotates in a direction opposite, or counter, to the rotation of the clutch gear. Forward speed gears on the countergear remain in constant mesh with two non­ sliding mainshaft gears giving first and second speed. Third speed is a direct drive with the clutch gear engaged directly to the mainshaft. Forward gears are engaged through two sliding synchronizer sleeves mounted on the mainshaft. Engagement of the constant mesh mainshaft gears to the mainshaft is accomplished through blocker ring-type synchronizers. NOTE: The Muncie unit is similar to the Saginaw design but differs in that it has a 3-1/4 inch center distance between the mainshaft and countershaft instead of 3 inches, and has larger bearings, gears, input shaft and mainshaft. Power flow is essentially the same for both the Saginaw and Muncie transmissions. The Muncie Model CH 465 truck transmission (fig. 13) uses a constant mesh first gear that engages with the second spped synchronizer sleeve. Second, third and fourth gears are synchronized. Clutch gears with two different splines are used, the larger size for 40-60 series trucks. The clutch gear is supported by a heavy duty ball bearing. The forward end of the mainshaft is supported by a loose collar-type bearing inside the clutch gear, while the rear is carried on a ball bearing in the case. End play is taken up by the rear flange retaining nut. The countergear is supported at the rear by a single row ball bearing which takes the thrust load, and by a roller bearing at the front. Incorporated in the cover is a ball pin type interlock which prevents simultaneous engage­ ment of two gears. As one rod is moved, it pushes a ball out that engages the other two rods to prevent their movement. Gearshift levers on manual transmissions are located LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 1 8 CLUTCHES & M A N U A L T R A N S M IS S IO N S 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Clutch Gear Clutch Gear Bearing Retainer 3rd Speed Synchronizer Ring 2nd-3rd Speed Clutch Assy. 2nd Speed Synchronizer Ring 2nd Speed Gear 1st Speed Gear 1st Speed Synchronizer Ring 1st—Reverse Clutch Assy. Reverse Gear 11. 12. 13. 14. 15. 16. 17. 18. 19. 20 . Vent Speedometer Gear and Clip Rear Extension Seal Rear Extension Rear Bearing-to-Shaft Snap Ring Rear Bearing-to-extension Snap Ring Countergear Woodruff Key Thrust Washer Reverse Idler Shaft Woodruff Key Reverse Idler Gear 21. 22. 23. 24. 25. 26. 27. 28. 29. Reverse Idler Shaft Countergear Bearings Countergear Case Magnet Anti-Lash Plate Assy. Thrust Washer Clutch Gear Bearing Snap Ring Clutch Gear Retainer Lip Seal Fig. 1 1 — M u n c ie 3 -S p e e d T ra n s m is s io n Cross S ec tio n either on the steering column or on the floorboard. Regardless of location, the lever performs two opera­ tions: It selects the gear assembly to be moved, and moves it either forward or backward into the desired gear position. The transmission action is the same whether a floor-type shift lever or a steering column shift lever is used. When the shift lever is moved, the movement is carried by linkage to the transmission. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 1 2 30 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 3 31 4 5 6 7 8 9 32 Clutch Gear Bearing Retainer Pilot Bearings Case 3rd Speed Blocker Ring 2-3 Synch. Snap Ring 2-3 Synch. Hub 2nd Speed Blocker Ring 2nd Speed Gear 1st Speed Gear 1st Speed Blocker Ring 1st Speed Synch. Hub 1st Speed Synch. Snap Ring Reverse Gear 33 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 34 35 10111213141516 36 37 38 39 17 18 19 7M -19 20 40 Reverse Gear Thrust and Spring Washers Snap Ring—Bearing to Mainshaft Extension Vent Speedometer Drive Gear and Clip Mainshaft Rear Oil Seal Retainer Oil Seal Snap Ring—Bearing to Gear Clutch Gear Bearing Snap Ring—Bearing to Case Thrust Washer—Front Thrust Washer—Rear 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. Snap Ring—Bearing to Extension Rear Bearing Countegear Roller Bearings Anti-Lash Plate Assembly Magnet 2-3 Synch. Sleeve Countergear Counter Shaft Reverse Idler Shaft 1st Speed Synch. Sleeve "E ” Ring Reverse Idler Gear Woodruff Key Fig. 1 2 — S a g in a w 3 -S p e e d T ra n s m is s io n Cross S ection LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 0 CLUTCHES & M A N U A L T R A N S M IS S IO N S 1. M a in D riv e G e a r 1 1. R e v e r s e D riv e n G e a 2. D riv e G e a r B e a r in g 12. P o p p e t S p r in g R e t a in e r 13. P o p p e t B a ll 3. S n a p R in g -O u te r 14. S h if t R a il 4. 3 r d a n d 4 th 15. S y n c h r o n iz e r R in g 25. M a in s h a f t R e a r 37. T h ru s t W a s h e r B e a r in g 38. S n a p R in g R e a r B e a r in g S n a p 39 1 s t a n d 2 n d S h ift 26. S n a p R in g 27. C o u n te rs h a ft 16. 1st S p e e d G e a r S y n c h r o n iz e r C o lla r 17. T h ru s t W a s h e r 6. 3 r d a n d 4 t h S h if t 18. B e a r in g S n a p R in g F o rk 19. 7. 3 r d a n d 4 th S p e e d 28. 29 40. C o u n te rs h a ft R ea r 41. B e a r in g 42. S p e e d o m e t e r D riv e 30. R e v e r s e Id le r G e a r 43. G ear 31. R e v e r s e Id le r S h a f t 44. C ase M a g n e t 32. 8. 3 rd S p e e d G ear 21 F la n g e N u t 33. S n a p R in g 45. 9. 2nd Speed G ear 22 R e a r B e a r in g 34. S n a p R in g 46 R e t a in e r O il S e a l 35. Spacer R e a r B e a r in g 36. C o u n te rg e a r S y n c h r o n iz e r 23. R e ta in e r C lu t c h G e a r O il S n a p R in g 3 rd S p e e d G e a r B u s h in g O u tp u t Y o k e A s s e m b ly P ilo t B e a r in g R o lle r s S lin g e r B e a r in g S n a p R in g 20. 1st a n d 2 n d C o u n te r g e a r F ro n t C over S y n c h r o n iz e r R in g 10. F ro n t C o u n te rs h a ft B e a r in g R in g F o rk 3 r d a n d 4 th 5. 24. T h ru s t W a s h e r 2nd Speed G ear B u s h in g 47. 1st S p e e d G ear B u s h in g Fig. 13—Muncie 4-Speed Transmission Cross Section LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7 M -2 1 THEORY OF OPERATION An internal combustion engine cannot develop apprecia­ ble torque at low speeds, and it develops maximum torque only at one speed. Also, the crankshaft of an engine must always rotate in the same direction. The transmission which provides a means of varying the gear ratio between the engine and rear wheels, then becomes necessary in automotive vehicles. The transmission provides the mechanical advantage that enables the engine to propel the vehicle under adverse conditions of load. It also furnishes the driver with a selection of vehicle speeds while the engine is held at speeds within the effective torque range; and allows disengaging and reversing the power flow from the engine to the wheels. In summary, the purpose of the transmission is to provide the operator with a selection of gear ratios between engine and wheels so that the vehicle can operate at best efficiency under a variety of driving conditions and loads. SYNCHRONIZING MECHANISM The entire synchronizing mechanism is installed on the mainshaft and the main drive gear. First, second, third speed are all synchronized by synchronizing clutches, which act as friction clutches. Each of the gears to be synchronized - main drive gear, second speed gear, and in this example, the first speed gear (5, Fig. 14) - has a cone surface (6, Fig. 14). Only the hub and the gear carrier (3, Fig. 14), are tightly splined to the mainshaft, while the main drive gear, 1st, and 2nd speed mainshaft gears, can revolve on the mainshaft. Three keys (2, Fig. 15) slide in slots of the hub (3, Fig. 14), and these keys are spring-loaded by two synchronizer springs; one of which is shown in Figure 15. Between the hub and the mainshaft 1st speed gear a synchronizer ring (7, Fig. 14) is installed which, together with the cone surface, acts as a friction clutch. The synchronizer ring (3, Fig. 14) has three slots (3, Fig. 16) in which the keys (4, Fig. 16) engage, and is thereby moved along with the guide unit (1, Fig. 16). The slots in the synchronizer cover are wider than the keys, so that Fig. 1 5 — S y n c h ro n iz e r H u b a n d S leeve Fig. 14—Synchronizing Mechanism LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 2 CLUTCHES & M A N U A L T R A N S M IS S IO N S the synchronizer ring can rotate a small amount relative to the hub. The internally splined mainshaft 1st and reverse synchronizer sleeve (1, Fig. 14) slides along the external splines of the hub (9, Fig. 14). The 1st speed gear clutch sleeve splines are recessed to form a shallow annular groove (2, Fig. 14) in which rest the raised portion of the keys (8, Fig. 14), when in neutral position. Each spline of the 1st and reverse speed gear clutch sleeve and each tooth of the synchronizer ring has on both sides a wedge angle (9 and 4, Fig. 14). Through the press of these wedge angles, the engagement of the gears is prevented until the synchronizer ring (7, Fig. 14) has brought the mainshaft 1st speed gear (5, Fig. 14) to the speed of the hub (3, Fig. 14). SYNCHRONIZING OPERATION When shifting into 1st speed, the 1st and reverse synchronizer sleeve (1, Fig. 17) is moved toward the 1st speed gear. As the three keys (2, Fig. 17) are springloaded, they are moved along at first until they contact the synchronizer ring (3, Fig. 17) which is also moved toward the 1st speed gear (4, Fig. 17). The synchronizer ring pressing against the 1st speed gear cone causes friction and starts pre-synchronization. The friction instantly causes the synchronizer ring to turn in relation to the hub to the amount of the clearance between the keys and the sides of the synchronizer ring slots (Fig. 17). This small turning action of the syncrhonizer ring relative to the hub causes the wedge angles (4, Fig. 14) of the 1st and reverse synchronizer gear to press against the wedge angles (9, Fig. 14) of the syncrhonizer ring. Through the movement of the 1st and reverse synchronizer sleeve to the point where the wedge angle contact is made, the keys are pressed out of the 1st and reverse synchronizer sleeve annular groove, and the action of pre-synchronization by means of the keys is ended. The necessary additional pressure for the friction clutch is now directly applied by the pressure of the wedge angles of the 1st and reverse synchronizer sleeve onto the wedge angles of the synchronizer ring. The pressure caused by this friction prevents a further engagement of the 1st and reverse synchronizer sleeve as the wedge angles of the synchronizer ring lock the wedge angles of the 1st and reverse synchronizer sleeve. Only when the friction of the syncrhonizing clutch has equalized the speeds of the 1st speed gear and the hub synchronization - friction and pressure on the synchro­ nizer ring wedge angles are relieved. The wedge angles of the 1st and reverse synchronizer sleeve now can push aside the synchronizer ring wedge angles allowing the 1st and reverse synchronizer sleeve splines to engage the 1st speed gear teeth (Fig. 17). The keys are now again located in the middle of the synchronizer cover slots. According to the relative speeds of the roating hub and the gear to be synchronized either the right or the left wedge angles of the hub apply pressure onto the right or left wedge angles of the synchronizer ring. Fig. 1 6 — S y n c h ro n iz e r H u b a n d R in g LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S STEP 3 STEP 2 Fig. 1 7 — S y n c h ro n iz e r O p e ra tio n (S te p 7M -23 1) LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 4 CLUTCHES & M A N U A L T R A N S M IS S IO N S 1ST GEAR 2-3 SYNCHRONIZER 1ST-REV. SYNCHRONIZER REVERSE GEAR 3RD GEAR COUNTERGEAR IDLER GEAR Fig. 1 8 — N e u tra l P ow er Flow POWER FLOW Neutral (Fig. 18) In neutral, with the engine clutch engaged, the main drive gear turns the countergear. The countergear then rotates the 2nd speed, 1st speed, and reverse idler (and reverse) gears. But, because the 2nd-3rd sliding sleeve and the 1st speed sliding sleeve are neutrally positioned, no power will flow through the mainshaft. NOTE: The 2nd-3rd sliding sleeve is in a neutral position when it does not mesh with either the 2nd speed blocking ring and 2nd speed gear or with the 3rd speed blocking ring and main drive gear. The 1st speed sliding sleeve is in a neutral position when it does not mesh with either the 1st speed blocking ring and 1st speed gear or with the reverse gear. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 1ST GEAR 1 2ND-3RD SYNCHRONIZER 7M -25 1ST-REV. SYNCHRONIZER (1ST GEAR ENGAGED) REVERSE GEAR 3RD GEAR IDLER GEAR COUNTERGEAR Fig. 1 9 — F irst G e a r P ow er Flow First Gear (Fig. 19) In the first speed, the 1st speed sliding sleeve is moved forward to engage the 1st speed blocking ring and 1st speed gear (which is being turned by the countergear). Because the 1st speed synchronizer hub is splined to the mainshaft, torque is imparted to the mainshaft from the 1st speed gear through the 1st speed sliding sleeve to the synchronizer hub. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 6 CLUTCHES & M A N U A L T R A N S M IS S IO N S 2-3 SYNCHRONIZER (2N D GEAR ENGAGED) 1ST GEAR 1-REV. SYNCHRONIZER REVERSE M AIN DRIVE (3RD) GEAR COUNTERGEAR REV. IDLER GEAR Fig. 2 0 — S ec o n d G e a r Pow er Flow Second Gear (Fig. 20) In second speed, the 1st speed sliding sleeve assumes a neutral position. The 2nd-3rd sliding sleeve moves rearward to engage the 2nd speed blocking ring and 2nd speed gear (which is being turned by the counter gear). Because the 2nd-3rd speed synchronizer hub is splined to the mainshaft, torque is imparted to the mainshaft from the 2nd speed gear through the 2nd-3rd sliding sleeve to the synchronizer hub. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 2-3 SYNCHRONIZER (3RD ENGAGED) 1ST GEAR 1ST-REV. SYNCHRONIZER M AIN DRIVE (3RD) GEAR COUNTERGEAR 7M -27 REV. GEAR REV. IDLER GEAR Fig. 2 1 —T h ir d G e a r P ow er Flow Third Gear (Fig. 21) In third speed, or direct drive, the 2nd-3rd sliding sleeve is moved forward to engage the 3rd speed blocking ring and main drive gear and the 1st speed sliding sleeve remains in a neutral position. This engagement of the main drive gear with the 2nd-3rd sliding sleeve imparts torque directly through the 2nd-3rd synchronizer hub to the mainshaft. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 2 8 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. 2 2 b — R ev e rse G e a r P ow er Flow Reverse Gear (Fig. 22b) In reverse, the 2nd-3rd sliding sleeve assumes a neutral position. The 1st speed sliding sleeve is moved rearward to engage the reverse gear. Because the reverse gear is held to the mainshaft through the 1st speed synchronizer assembly and reverse gear is in constant mesh with the reverse idler gear, the power flows from the main drive gear to the countergear and through the reverse idler gear to the reverse gear in a direction of rotation that is opposite that of engine rotation. It should be noted, that for any forward gear or for reverse gear, only one synchronizer assembly is engaging a gear while the other synchronizer assembly is in a neutral position. And, if both synchronizer assemblies are in the neutral position, no power is being transmitted to the mainshaft. This should be remembered especially when diagnosing manual transmissions for malfunction. For example, if both synchronizer assemblies were engaging gears at the same time the transmission would be locked up and no power would be transmitted through it. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7 M -29 SERVICE OPERATIONS TRANSMISSION LINKAGE ADJUSTMENT 3-Speed Column Shift (Figs. 23, 24 and 25) In cases where gearshift linkage has been disconnected or removed, proper adjustment sequence is important. 1. Install control rods to both second and third shifter lever and first and reverse shifter lever. Set both shifter levers in neutral position. 2. Align both shifter tube’levers on mast jacket in the neutral position. Install gauge in holes of levers to hold levers in alignment. Position relay levers so that gearshift control lever is in neutral position. 3. Connect control rods to tube levers making sure clamps are properly adjusted so that tube levers and transmission shifter levers remain in their neutral positions while tightening. 4. Remove gauge and move selector lever through all positions to check adjustment and insure over-travel in all positions. NOTE: If mast jacket lower dash clamp has been disturbed at its mounting on dash, its adjustment to the steering m ainshaft should be checked as outlined in Section 9 of this manual. 4. 5. 6. 7. 8. 9. TRANSMISSION FLOOR SHIFT CONTROL LEVER REPLACEMENT 1. On K-Series models remove transfer case shift lever boot retainer attaching screws and retainer from compartment floor. 2. Remove floor covering from vehicle. 3. Remove transmission shift lever boot retainer attaching screws. 4. Slide boot and retainer up on shift lever and remove the transmission shift lever using Tool J-8109 as shown in Figure 26. 5. To install, reverse removal procedure Steps 1-4. TRANSMISSION REPLACEMENT Removal—Except “K” Series Models 1. Raise vehicle on suitable hoist and drain lubricant from transmission. 2. Disconnect speedometer cable, back-up lamp and TCS switch at transmission. 3. Remove shift controls from transmission. NOTE: On vehicle equipped with Muncie 4-Speed transmission, remove the gearshift lever using Tool J-8109 as shown in Figure 10. 11. 12. 13. 26. Press down firmly and rotate tool counter­ clockwise to release gearshift lever. Place clean lint-free cloth or other suitable covering over opening on transmission to prevent entry of dirt or foreign material (applies to 4-speed transmissions). Disconnect parking brake lever and controls (when used) and back up lamp switch wire. If vehicle is equipped with power take-off, remove unit and controls from transmission. Place protec­ tive covering over opening. Disconnect propeller shaft from transmission as described in “PROPELLER SHAFTS” (SEC.4) of this manual. Position a suitable dolly or jack under the vehicle and adjust to carry the weight of the transmission. Visually inspect to determine if other equipment, lines or brackets must be removed to permit removal of the transmission. Remove crossmember. NOTE: Mark front of crossmember to prevent incorrect installation. Tapered sur­ face must be to rear of vehicle. CAUTIO N: Be sure to support the clutch release bearing and support assembly during removal o f the transmission main drive gear from the flywheel housing. This will prevent the release bearing from falling out o f the flywheel housing when the transmission is removed. Remove flywheel housing underpan and transmission-to-flywheel housing mounting bolts. CAUTIO N: When removing the transmission, do not allow the weight o f the transmission to hang on the clutch disc hub, as the disc will become distorted, seriously affecting clutch operation. Move the transmission assembly straight away from the engine, using care to keep the transmission main drive gear shaft in alignment with the clutch disc hub. When the transmission is free from the engine, lower the transmission and move from under the vehicle. If desired, a careful check of clutch components should be made after the transmission has been removed. If the clutch requires repair, refer to “CLUTCHES” (Section 7) before transmission is reinstalled in the vehicle. Installation—Except “K” Series Models 1. Apply a light coating of High Temperature Grease to the main drive gear bearing retainer and splined portion of transmission main drive gear shaft to LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 3 0 CLUTCHES & M A N U A L T R A N S M IS S IO N S VIEW B K M O D ELS Fig. 23—Column Shift Controls (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7 M -3 1 Fig. 24—Column Shift Controls (G Models) assure free movement of clutch and transmission components during assembly. CAU TIO N : Do not apply an excessive amount o f grease in the above areas, as under normal operation this grease would be thrown onto clutch facings resulting in clutch failure. 2. Shift the transmission into high gear. 3. Mount transmission on dolly or jack and move into position under the vehicle. CAUTIO N: A void springing the clutch when the transmission is being installed to the engine. Do not force the transmission into the clutch disc hub. Do not let the transmission hang unsupported in the splined portion o f the clutch disc. Install flywheel housing-to-transm ission mounting bolts and washers. Tighten bolts to specifications. 4. Align the transmission main drive gear shaft with the clutch disc hub by rotating the transmission companion flange or output yoke. Move the 5. 6. 7. 8. 9. 10. transmission forward, guiding the main drive gear shaft into the clutch disc splines. Install crossmember. Also, if vehicle is equipped with power take-off, reinstall unit and controls on transmission. Connect propeller shaft to transmission as de­ scribed in “PROPELLER SHAFTS” (Section 4) of this manual. Remove transmission jack. Connect parking brake lever and controls (if used). Adjust brakes as outlined in “PARKING BRAKE” (Section 5) of this manual. Install flywheel housing underpan. Tighten cap screws firmly. Reconnect speedom eter cable to adapter at transmission, connect back-up lamp switch wire and TCS switch. Reinstall shift controls on transmission. NOTE: On vehicle equipped with 3-speed transmission, reconnect shift levers to trans­ mission side cover. On vehicle equipped with LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 3 2 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. 26—Removing Transmission Gearshift Lever Fig. 25—Column Shift Controls (P Models) Muncie 4-Speed transmission, install gear­ shift lever using Tool J-8109 as shown in Figure 11. Press down firmly and rotate clockwise to install gearshift lever. Install transmission floor pan cover and floor mat. 11. If other equipment (exhaust pipe, support brackets, etc.) was removed, reinstall these parts. 12. Refill transmission with lubricant recommended in LUBRICATION (Section 0) of this manual. 13. If necessary, adjust clutch or transmission control linkage to achieve proper transmission operation. Replacement—“K” Series 3-Speed Transmission 1. Raise vehicle on hoist. 2. Drain transfer case and transmission. Disconnect the speedometer cable from speedometer driven gear fitting, and TCS switch connections. 3. Disconnect propeller shafts front U-joint yoke at case, and tie up out of way. 4. Remove bolt holding the shift lever control assembly to the adapter assembly. Push assembly to one side and tie up out of way. 5. Support transfer case in a suitable cradle. Remove bolts attaching transfer case to adapter. 6. Remove bolts attaching transfer case to frame bracket at right side of case and remove case from adapter. 7. Disconnect shift control rods from the shifter levers at the transmission. 8. Support rear portion of engine. Remove two (2) adapter mount bolts. 9. Remove the 2 top transmission to clutch housing cap screws and insert 2 transmission guide pins, Tool J-l 126 in these holes. 10. Remove flywheel under pan. Remove the 2 lower transmission-to-clutch housing cap screws. 11. Slide the transmission and adpater assembly straight back on guide pins until the clutch gear is free of splines in the clutch disc. NOTE: The use of the 2 guide pins during this operation will support the transmission and prevent damage to the clutch disc through springing. 12. Remove the transmission and adapter as an assembly from under the body. 13. Remove adapter from transmission. 14. To install, reverse removal procedure. 4-Speed Transmission—Removal 1. Remove attaching screws from transfer case shift lever boot retainer and remove retainer. 2. Remove floor mat or carpeting from compartment. 3. Remove attaching screws from transmission shift lever boot retainer. Slide boot and retainer up lever and remove transmission shift lever using Tool J-8109 as shown in Figure 26. 4. On Utility models remove center floor outlet from heater distributor duct. NOTE: On Utility models equipped with a center console, remove console before pro­ ceeding to next step. 5. Remove transmission floor cover attaching screws and cover. Rotate cover approximately 90° to clear transfer case shift lever while lifting cover from vehicle. 6. Disconnect shift lever link assembly from transfer LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. case shift rail connecting rod. Remove shift lever attaching bolt and shift lever control from adapter. Disconnect back-up lamp wiring from switch and remove attaching clamp from top cover bolt. Raise and support vehicle on hoist. Support engine with suitable floor stand. Drain transfer case and transmission assemblies. Disconnect speedometer cable from transfer case. Disconnect back-up lamp switch wiring and TCS switch. Disconnect prop shaft at rear of transfer case and tie up away from work area. Disconnect front prop shaft from transfer case and tie up away from work area. Open lock tabs and remove transmission mount-toframe crossmember bolts. Also remove transfer case-to-frame bracket attaching bolts. Support transmission and transfer case assembly with suitable floor stand. Remove frame to crossmember bolts and remove crossmember from vehicle. Rotate crossmember to clear frame rails. Remove flywheel housing cover. On V-8 engine models, remove exhaust crossover pipe. Remove transmission to flywheel housing attaching bolts. NOTE: Remove upper bolts first and install transmission guide pins J-1126. Use of the guide pins will prevent damage to the clutch assembly. Slide transmission rearward until main drive gear clears the clutch assembly and lower assembly from vehicle. 4-Speed Transmission—Installation 1. Position transmission, with transfer case attached to the flywheel housing. Install bolts attaching transmission to flywheel housing. 2. Install flywheel housing cover and attaching bolts. On V-8 models, install exhaust crossover pipe. 3. Position frame crossmember and install retaining bolts. Install bolts retaining adapter assembly to crossmember and transfer case to frame rail bracket. Torque all bolts to specification. 4. Torque front and rear transfer case yoke lock nuts to specifications. 5. Install front and rear propshafts to transfer case output yokes. 6. Connect the speedometer cable, back-up lamp wiring and TCS switches. 7. Fill transmission and transfer case to proper level with lubricant specified in the lubricant section, Truck Chassis Service Manual. 7M -33 8. Install transfer case shift lever assembly and attaching bolt. Connect shift lever link to shift rail bar. 9. Install transmission floor cover and attaching bolts. 10. Install heater distributor duct center outlet. NOTE: On models with center console, install console and retaining bolts. 11. Install floor mat, transfer case shift lever retainer and attaching screws. 12. Install transmission shift lever. TRANSMISSION ALIGNMENT In some instances where “excessive” gear whine or high gear hop out, particularly at 50 MPH and up, are encountered; and after all other probable causes have been checked, an alignment check of the transmission and clutch housing may be helpful. A special tool, on which a dial indicator is mounted, is necessary to check the transmission case rear bore alignment. This tool may be made from a new or good used clutch gear which has a good bearing surface on the crankshaft pilot end and at the front main bearing location. The splines on the clutch gear shaft and the teeth on the clutch gear should be ground off so the shaft may be rotated in a clutch disc hub without interference when assembled in the car. Weld a piece of 1/4" rod in the mainshaft pilot bore long enough to extend out the case rear bore. Assemble a good bearing on the clutch gear shaft and secure it with the clutch gear bearing snap ring. Attach a suitable dial indicator to the rod. Procedure 1. Remove the transmission from the vehicle and completely disassemble, except for the reverse idler gear. NOTE: In any case where the clutch gear pilot or pilot bearing is excessively loose or worn, the pilot bearing should be replaced before checking the transmission case rear bore alignment by the dial indicator method. 2. Carefully install the special tool with the dial Fig. 27—Removing Mainshaft Rear Oil Seal LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 3 4 CLUTCHES & M A N U A L T R A N S M IS S IO N S 3. 4. 5. 6. 7. 8. indicator in the transmission case with the face of the indicator to the rear of the case and with the tracing finger contacting the I.D. of the case rear bore. Secure in place with a clutch gear bearing retainer. Assemble the transmission case to the clutch housing and tighten the four transmission mount­ ing bolts securely. NOTE: Be sure to clean off any paint or other foreign material on the mating faces of the clutch housing and transmission as any foreign material on these faces will change alignment; also, check carefully for dings or burrs on these mating surfaces and remove carefully as necessary. Dial indicate the transmission case rear bore and record the indicator readings in the 12, 3, 6 and 9 o’clock positions. NOTE: It is best to start the reading at the 3, 6, 9 or 12 o’clock position closest to the point where the indicator plunger reaches its maximum outward travel. Set the dial indicator at “O” at this location and then record the 3, 6, 9 and 12 o’clock readings in rotation. Install tem porary slotted shims between the transmission case and the clutch housing in the quantities and at the bolt locations as necessary to bring misalignment at the transmission case rear bore to a maximum of .005" indicator reading in either the vertical or horizontal direction. EXAMPLE: If the maximum indicator reading is at the 12 o’clock position, put shims on the two bottom bolts. After the position and quantity of shims has been determined and recorded the transmission case may be removed. NOTE: The clutch housing should then be stamped, showing the position where shims are to be installed and the thickness of shims at each location. Inspect the external clutching teeth of the clutch gear and second speed gear. Inspect the second and third speed clutch internal clutching teeth. If the teeth are worn or tapered, even slightly, the gears should be replaced. Reassemble the transmission. Install the transmission assembly to the clutch housing, using the correct number of shims at the proper locations as previously determined. Shims are available by unti part number with each unit consisting of the following shims: 4—.002" shims Identification—two corners cut off. 2—.005" shims Identification—one corner cut off. 1-.010" shims Identification—all corners square. NOTE: These special shims have a tab on one end for ease of installation. Do not slot the shims for the perm anent installation. REAR OIL SEAL REPLACEMENT 1. Drain lubricant from transmission. 2. Disconnect propeller shaft from transmission as described in “PROPELLER SHAFTS” (Section 4) of this manual. 3. On 3-speed transmissions, perform the following replacement procedures: a. Remove slip joint yoke from rear of transmis­ sion mainshaft. b. Pry seal out of extension housing or remove oil seal using oil seal remover (J-5859) and slide hammer (J-2619) as shown in Figure 27. c. Coat outer diameter of new oil seal with sealing cement. Install new oil seal using extension housing oil seal installer (J-5154). d. Install slip joint yoke on rear of transmission mainshaft. 4. On Muncie 4-speed transmissions, perform the following: a. Remove parking brake from rear of transmission as described in “PARKING BRAKE” (Section 5), when used. b. Disconnect speedometer cable and remove speedom­ eter driven gear from mainshaft rear bearing cap. c. Using flange or yoke holding tool, remove the out­ put yoke or companion flange nut. Pull output yoke or companion flange nut off the mainshaft. d. Remove mainshaft rear bearing cap and gasket. Dis­ card gasket. e. Remove oil seal from rear bearing cap. Discard oil seal. f. Coat outer diameter of new oil seal with sealing cement. Install oil seal in rear bearing cup using a suitable installer. Drive seal flush with outside of rear bearing cap, being careful not to damage seal as shown in Figure 13. NOTE: On Muncie 4-speed use Installer J-22834 with Adapter J-22834-1 as required. g. Clean all gasket surfaces, then install the rear bearing cap with a new gasket on the transmission. Tighten cap screws firmly. h. Install output yoke or companion flange or mainshaft. Using a flange or yoke holding tool install retaining nut. Torque the retaining nut to specification. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S i. Install speedometer driven gear, then connect speedometer cable. 5. Reconnect propeller shaft to transmission as described in “PROPELLER SHAFTS” (Section 4) of this manual. 6. Refill transmission with lubricant recommended in LUBRICATION (Section 0) of this manual. SPEEDOMETER DRIVEN GEAR REPLACEMENT Disconnect speedometer cable, remove lock plate to housing bolt and lock washer and remove lock plate. Insert screw driver in lock plate slot in fitting and pry fitting, gear and shaft from housing. Pry “O ” ring from groove in fitting. Install new “O” ring in groove in fitting, coat “O ” ring and driven gear shaft with transmission lubricant and insert shaft. Hold the assembly so slot in fitting is toward lock plate boss on housing and install in housing. Push fitting into housing until lock plate can be inserted in groove and attached to housing. TRANSMISSION SIDE COVER REPLACEMENT/REPAIR Saginaw and Muncie 3-Speed (Fig. 29) 1. Disconnect control rods from levers, back-up lamp wiring and TCS switch. 2. Shift transmission into neutral detent positions before removing cover. Remove cover assembly from transmission case carefully and allow oil to drain. 7M -35 3. Remove the outer shifter levers. 4. Remove both shift forks from shifter shaft assemblies. Remove both shifter shaft assemblies from cover. Seals around shifter shaft may now be pried out if replacement is required because of damage. 5. Remove detent cam spring and pivot retainer “C” ring. Remove both detent cams. 6. With detent spring tang projecting up over the 2nd and 3rd shifter shaft cover opening install the first and reverse detent cam onto the detent cam pivot pin. With the detent spring tang projecting up over the first and reverse shifter shaft cover hole install the 2nd and 3rd detent cam. 7. Install detent cam retaining “C ” ring to pivot shaft, and hook spring into detent cam notches. 8. Install both shifter shaft assemblies in cover being careful not to damage seals. Install both shift forks to shifter shaft assemblies, lifting up on detent cam to allow forks to fully seat into position. 9. Install outer shifter levers, flat washers, lock washers and bolts. 10. Shift shifter levers into neutral detent (center) position and slide cover into place making sure the shift forks are aligned with their respective mainshaft clutch sliding sleeves. 11. Install cover attaching bolts and tighten evenly to specified torque. Install TCS switch and connect wiring. 12. Remove filler plug and add lubricant specified in Section 0, to level of filler plug hole. TRANSFER CASE REPLACEMENT (Figs. 30 thru 34) Removal 1. Raise and support vehicle on hoist. Drain transfer case. 2. Disconnect speedometer cable, back-up lamp and TCS switch. 3. Remove skid plate and crossmember supports as necessary. 4. Disconnect rear prop shaft from transfer case and tie up away from work area. 5. Disconnect front prop shaft from transfer case and tie up shaft away from work area. 6. Disconnect shift lever rod from shift rail link. On full time 4 wheel drive models with automatic transmission, disconnect shift levers at transfer case. 7. Remove transfer case to frame mounting bracket bolts. LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 3 6 CLUTCHES & M A N U A L T R A N S M IS S IO N S Installation DETENT CAM DETENT SPRING DETENT CAM 2-3 SHIFT FORK SHAFT 1ST & SHIFTER SHAFT ____ __ CAM RETAINER RING Fig. 29—Transmission Side Cover Assy. (3-Speed Saginaw) 8. Support transfer case and remove bolts attaching transfer case to transmission adapter. 9. Move transfer case to rear until input shaft clears adapter and lower assembly from vehicle. 1. Support transfer case in suitable stand and position case to transmission adapter. Install bolts attaching case to adapter and torque to 45 ft. lbs. 2. Remove stand as required and install bolts attaching transfer case to fram e rail. Bend lock tabs after assembly. 3. Install connecting rod to shift rail link or connect shift levers to transfer case, as applicable. 4. Connect front prop shaft to transfer case front output shaft. 5. Connect rear prop shaft to transfer case rear output shaft. 6. Install crossmember support and skid plate, if removed. 7. Connect speedometer cable, back-up lamp and TCS switch. 8. Fill transfer case to proper level with lubricant specified in the lubricant section of the Truck Chassis Service Manual. 9. Lower and remove vehicle from hoist. CAUTIO N: Check and tighten all bolts to specified torques. NOTE: Before connecting prop shafts to companion flanges be sure locknuts are torqued to specifications. LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES 8c M A N U A L T R A N S M IS S IO N S 7M -37 FULL TIME 4-WHEEL DRIVE TRANSFER CASE 4-SPEED TRA N SM ISSIO N - K 10-20 3-SPEED TRA N SM ISSIO N -K105 MODELS AUTOM ATIC TRA N SM ISSIO N -K105 W /LG 8 OR LS9 AUTOM ATIC TRANSM ISSION A LL EXC. K105 W /LG8 OR LS9 K 105 (FULL TIM E) K 1 0 0 + 2 0 0 (0 0 ) SUPPORT AND BRACKET ASSEMBLY (ALL MODELS) Fig. 30—Transfer Case Installation LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 3 8 CLUTCHES & M A N U A L T R A N S M IS S IO N S Fig. 31—3-Speed Automatic and 4-Speed Manual Transmission Transfer Case Controls (Except K105 W/LG8 and LS9) LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L T R A N S M IS S IO N S VIEW 7M -39 B Fig. 32—3-Speed Automatic Transmission Transfer Case Controls (K105 W/LG8 and LS9) LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 4 0 CLUTCHES & M A N U A L T R A N S M IS S IO N S [ NOTE N o i n s u l a t i o n to be installed under R etain er NOTE Shi ft p a t t e r n s h o u l d be- in h o r i z o n t a l p o s i t i o n t o d r i v e r NOTE I ns ta ll Boot p r i or to i n s t a l l a t i o n of N u t & K n o b NOTE with t r a n s c a s e in " N e u t r a l ” position, al ign I n d i c a t o r P l a t e to c en te r of Shi f t L e v e r VIEW Fig. 33—3-Speed Transmission Transfer Case Controls LIGHT DUTY TRUCK SERVICE MANUAL C L U T C H E S & M A N U A L T R A N S M IS S IO N S |VIEW 7 M -4 1 A Fig. 34—Transfer Case Skid Plate (K105) D IA G N O S IS Before attempting to repair the clutch, transmission or related linkages for any reason other than an obvious failure, the problem and probable cause should be identified. A large percentage of clutch and manual transmission problems are manifested by shifting difficulties such as high shift elfort, gear clash and grinding or transmission blockout. When any of these problems occur a careful analysis of these difficulties should be accomplished, and the following checks and adjustments performed in the presented sequence before removing the clutch or transmission for repairs. CLUTCH ADJUSTMENT A. Clutch Free Pedal Travel 1. The clutch free pedal travel adjustment should be made as outlined in the Clutch and Transmission section of the Chassis Service Manual for the specific vehicle involved. 2. Check clutch linkage for lost motion caused by loose or worn swivels, deflection of mounting brackets or damaged cordon shaft. B. Clutch Spin Down Time 1. Run the engine at a normal idle with transmission in neutral and clutch engaged. 2. Disengage the clutch, wait nine seconds and shift the transmission to reverse. No grinding noise should be heard. A grinding noise indicates incorrect clutch adjustment, lost motion clutch misalignment, or internal problems such as failed dampers, facings, cushion springs, diaphragm spring fingers, pressure plate drive straps, etc. SHIFT LINKAGE ADJUSTMENT A. Steering Column Shift Control 1. Remove the shift control rods from the column levers. 2. Check shift effort at the shift control lever knob. (Effort should not exceed 2 lbs. with transmission linkage removed.) 3. If binding is felt, refer to the adjustment procedure for the steering column lower bearing for Manual LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 4 2 C LU T C H E S & M A N U A L T R A N S M IS S IO N S Transmission Column Shift as described in the Steering Section of the appropriate Chassis Service Manual. 4. Lubricate all rod and swivel connections and re­ check shift effort after installation. 5. If shift linkage is free from binding, the column levers should be checked for end play. A .005 feeler gauge should fit between the levers and control lever. 6. Connect control rods and check steering column control levers for alignment. In neutral, the column control lever tangs should line up with the slot in the main control lever. B. Floor Shift Control All swivels, rods and mountings should be checked for lost motion and repaired or replaced as necessary. Transmission control levers should be checked for wear and repaired or replaced as necessary. TRANSMISSION SHIFT EFFORT A. Transmission Shift Effort Checking Procedures 1. Remove the shift rods at the transmission and align the sleeve, blocker ring and gear by shifting into the offending gear and then back into neutral. 2. Check the torque required to shift into gear with an inch pound torque wrench on the shift lever attaching bolt. If more than the specified torque (see below) is required, the transmission shift lever should be checked for rust or dirt binding the lever. 3. Clean levers, lubricate and recheck the torque value. NOTE: If at this point in the procedure, it is found that high shift effort or gear clashing still exists, an anti-chatter lubricant (positraction additive) should be used. The lubricant is available in a 4 oz. plastic bottle and can be squirted into the transmission through the filler plug. B. Transmission Internal Problems Related to Shift Effort When the above procedures have been checked and the problem still exists, the transmission will have to be removed and disassembled for further diagnosis. There are three basic types of transmission internal problems reflected by shifting effort. 1. Hard Shifting — The effort to shift is excessive, but the gears engage. The lever moves with excessive Shift Torque Chart Shift Torque 3-Saginaw 50 3-Muncie 60 effort throughout the entire travel range. If the static shift effort is high, (clutch depressed, engine not running) the synchronizer sleeve and hubs should be checked for a tight fit. With the three synchronizer keys removed, the sleeve should be loose on the hub. If the hub and sleeve are not a loose fit, replace the synchronizer assembly. 2. Blockout — The lever moves freely until the synchro­ nizer is engaged. Synchronization should be heard to take place, but the gear will not engage. When it does engage, a double bump is generally felt in the lever. The synchronized blocker ring can be damaged by ex­ cessive force on gear cones that are finished improperly. The blocker ring material may stick to the synchronizer gear cone causing it to be a yellowish brass color, in streaks, which results in hard shifts when present. The gear cone should be a bright silver color. Polish the gear cone with 400 grit paper to a bright silver when this condition is present. The blocker rings should be re­ placed if the thread is damaged or worn. 3. Clash — Gear clash is a typical sound which occurs when the sleeve and gear chamfers contact each other in the unsynchronized state. The characteris­ tics of clash are a grating or loud buzzing sound from the transmission. The shift lever load will be lower, but a vibration should be felt. The Noise (clash) can be for a short instant or long enough to keep the gear from being engaged. This condition should not be confused with hard shifting or reported as such. Hard shifting and clash are directly opposite conditions. When the clash is slight, the load will build up on the shift lever and then fall off rapidly followed by the grating sound. If the transmission has been clashing, the sleeve ends should be examined for chipping and burrs. If the sleeves are damaged, the synchronizer assemblies and blocker rings should be replaced. Synchronizer sleeve ends should have an angular surface. The surfaces should be even from side to side and the radii indicated should be very small. Any chipping will require synchronizer replacement. Check the synchronizer load. W hen the keys are installed, the spring ends on one side of the hub should be hooked in one key and the spring on the opposite side of the synchronizer should not be hooked on the same key. A definite load should be felt when the sleeve is moved on the hubs with the keys and springs in proper position. LIGHT DUTY TRUCK SERVICE MANUAL C L U T C H E S & M A N U A L T R A N S M IS S IO N S 7M 43 SHIFTING DIFFICULTY DIAGNOSIS CHART CONDITION High Shift Effort-Column Shift (Effort exceeds 2 ft. lbs. at lever knob with transmission linkage disconnected.) PROBABLE CAUSE Binding of column levers CORRECTION Adjust column mechanism per Section 9, Steering of the Chassis Service Manual Clean and lubricate all rod and swivel connections. Lever end play exceeds .005 in. Adjust levers Misalignment of column control levers. Adjust levers Improper linkage Adjustment Adjust linkage Lost motion due to damaged or worn swivels, rods, grommets or mountings. Repair or replace defective components. Loose lever attaching bolts Binding Tighten bolts and check levers for correct fit on shifter shafts. Clean and Adjust linkage Stiff shift lever boot Replace boot Gear Clash and binding Improper linkage Adjustment Adjust Shift linkage Lost motion Loose or worn swivels and grommets. Deflection of Mounting Brackets. Loose shift levers. Damaged Cordon Shaft Replace defective parts High Shift Effort-Floor Shift (crossover from lst-2nd to 3rd4th position cannot be accom­ plished without offset or step) LIGHT DUTY TRUCK SERVICE MANUAL 7 M - 4 4 C LU T C H E S & M A N U A L T R A N S M IS S IO N S MANUAL TRANSMISSION DIAGNOSIS CHART CONDITION Slips out of High Gear PROBABLE CAUSE CORRECTION a. Transmission loose on clutch housing b. Shift rods interfere with engine mounts or clutch throw-out lever c. Shift linkage does not work freely; binds d. Damaged mainshaft pilot bearing e. Main drive gear retainer broken or loose f. Dirt between transmission case and and clutch housing g. Misalignment of transmission a. Tighten mounting bolts b. Replace or bend levers and rods to eliminate interference c. Adjust and free up shift linkage h. Stiff shift lever seal i. Pilot bearing loose in crankshaft j. Worn or improperly adjusted linkage Noisy in All Gears a. Insufficient lubricant b. Worn countergear bearings c. Worn or damaged main drive gear and countergear d. Damaged main drive gear or main shaft bearings e. Worn or damaged countergear anti­ lash plate d. Replace pilot bearing e. Tighten or replace main drive gear f. Clean mating surfaces g. Refer to TRANSMISSION ALIGNMENT h. Replace seal i. See Section 6 for brg. fits j. Adjust or replace linkage as required a. Fill to correct level b. Replace countergear bearings and shaft c. Replace worn or damaged gears d. Replace damaged bearings or main drive gear e. Replace countergear Noisy in High Gear a. Damaged main drive gear bearing b. Damaged mainshaft bearing c. Damaged high speed gear synchronizer a. Replace damaged bearing b. Replace damaged bearing c. Replace synchronizer Noisy in Neutral with Engine Running a. Damaged main drive gear bearing b. Damaged or loose mainshaft pilot bearing c. Worn or damaged countergear anti­ lash plate d. Worn countergear bearings a. Replace damaged bearing b. Replace pilot bearings. See Section 6 for bearing fits c. Replace countergear Noisy in all Reduction Gears a. Insufficient lubricant b. Worn or damaged main drive gear or countergear a. Fill to correct level b. Replace faulty or damaged gears Noisy in Second Only a. Damaged or worn second-speed constant mesh gears b. Worn or damaged countergear rear bearings c. Damaged or worn second-speed synchronizer a. Replace damaged gears Noisy in Third Only (Four Speed) a. Damaged or worn third-speed constant mesh gears b. Worn or damaged countergear bearings d. Replace countergear bearings and shaft b. Replace countergear bearings and shaft c. Replace synchronizer a. Replace damaged gears b. Replace damaged countergear bearings and shaft LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L TRANSMISSIONS 7M-45 MANUAL TRANSMISSION DIAGNOSIS CHART (CONT'D.) PROBABLE CAUSE Worn or damaged reverse idler gear or idler bushing Worn or damaged reverse gear on mainshaft Damaged or worn reverse countergear Damaged Shift mechanism CORRECTION a. Replace reverse idler gear assembly Excessive Backlash in all Reduction Gears a. Worn countergear bearings b. Excessive end play in countergear a. Replace bearings b. Replace countergear thrust washers Main Drive Gear Bearing Retainer Burned or Scored by Input Shaft a. Loose or damaged mainshaft pilot bearing b. Misalignment of transmission a. Replace bearing. See Section 6 for bearing fit b. Align transmission Leaks Lubricant a. Excessive amount of lubricant in transmission b. Loose or1 broken main drive gear bearing retainer c. Main drive gear bearing retainer gasket damaged d. Side cover loose or gasket damaged e. Rear bearing retainer oil seal leaks f. Countershaft loose in case g. Shift lever seals leak a. Drain to correct level CONDITION Noisy in Reverse Only a. b. c. d. b. Replace reverse gear c. Replace countergear assembly d. Inspect linkage and adjust or replace damaged parts b. Tighten or replace retainer c. Replace gasket d. e. f. g. Tighten cover or replace gasket Replace seal Replace case Replace seal LIGHT DUTY TRUCK SERVICE MANUAL 7M-46 CLUTCHES & M A N U A L TRANSMISSIONS SPECIAL TOOLS 1. 2. 3. 4. 5. J-6456 J -1048 J-1522 J-5824 J-1448 Height Gauge Gauge Plate Pilot Bearing Driver Clutch Pilot Tool Pilot Bearing Puller Fig. 1ST—Clutch Special Tools LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L TRANSMISSIONS 7M-47 3 1. 2. 3. 4. 5. J--1126 J-8059 J-22246 J-5778 J-5154 Transmission Guide Pins Retainer Snap Ring Pliers Countergear Loading Tool Extension Bushing Remover and Extension Seal Installer Installer 6. 7. 8. 9. J-2228 J-5590 J-9772 J-23096 Rear Bearing Press Plates Clutch Gear Bearing Installer Clutch Gear Bearing Installer Clutch Gear Retainer Seal Installer Fig. 2 ST —3-Speed Manual Transmission Special Tools LIGHT DUTY TRUCK SERVICE MANUAL 7M-48 CLUTCHES & M A N U A L TRANSMISSIONS 1. 2. 3. 4. 5. 6. 7. 'in ? ™ 2 J-8 4 3 3 -1 *i o o o o ? C o u n te rg e a r R e a r B e arin g R e m o v e r B e a rin g P u lle r 8. g J-2 2 8 74 -1 j-2 2 8 74 -5 C lu t c h G e a r B e a rin g R e m o v e r a n d Ins ta lle r 10. J-2 2 8 74 -2 F r o n t B e a rin g R e t a in e r Se a l In s ta lle r 11. J-2 2 8 3 4 -2 io o o o c 2 n d S p e e d B u s h in g In s ta lle r 1 1a. J-2 2 8 3 4 -1 i o o o o o 3 r d S p e e d B u s h in g In s ta lle r S n a p R in g Ins ta lle r 12. i o o o ^ o J-2 2 8 3 0 J-2 3 0 70 B e a rin g In s ta lle r M a in s h a ft S u p p o r t T o o l C o u n te rsh a ft S u p p o rt T o o l R e a r B e a rin g R e t a in e r S e a l Ins ta lle r A d a p t e r f o r Seal In s ta lle r M a in s h a ft R e a r B e a rin g L o c k N u t Ins ta lle r Fig. 3ST—Muncie Transmission Model CH 465 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L TRANSMISSIONS 2 7 7. 1. J -23432 -1 Snap 2. 3. 4. J-23432 J-8092 J-23429 5. 6. J-22836 J-21359 S n a p R in g P l ie r s H a n d le In te rm e d ia te S h a ft Remover and In s ta lle r F ront O u t p u t S h a ft Be aring R e ta in e r Seal In s ta lle r Rea r O u t p u t S h a f t B e a r i n g R e t a i n e r S e a l I n s t a l l e r R in g 8 P icks 8. 9. 10 . 9 J -23431 J —7 1 3 7 J-9 2 7 6 -2 J-22875 Re ar O u t p u t 7M-49 10 S h aft H o u sin g B e aring R e m o v e r a n d I n s t a 1le r A d a p t e r S e a l I n st a 1le r In te rm e d ia te G e a r B e aring C u p In s ta lle r Re ar O u t p u t S h a f t Re ar B e a r i n g I n s t a l l e r Fig. 4ST—New Process Transfer Case Model 205 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL 7M-50 CLUTCHES & M A N U A L TRANSMISSIONS f - - ' 1. J-22836 - Front Output Shaft Bearing Retainer Seal Installer 2. J-22388 - Rear Output Shaft Seal Installer : • • - -w - .; ' - ' 3. J-21359 - Input gear Bearing Retainer Seal Installer 4. J-8614-1 - Companion Flange Remover Fig. 5ST—New Process Transfer Case Model 203 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL CLUTCHES & M A N U A L TRANSMISSIONS 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. J-8092 J-8331 J-23422 J-23423 J-5590 J-23419 J-22833 J-23420 J 7137 J-6219 7M-51 Handle. Rear Output Shaft Front Bearing Remover. Rear Output Shaft Front Bearing Cup Installer. Rear Output Shaft Rear Bearing Cup Installer. Bearing Installer. Intermediate Shaft Remove and Installer. Output Shaft Housing Seal Installer. Pilot Bearing Installer. Adapter Seal Installer. Front Output Shaft Bearing Installer. Fig. 6ST—Dana Transfer Case Special Tools LIGHT DUTY TRUCK SERVICE MANUAL ' SECTION 7A AUTOMATIC TRANSMISSION CONTENTS OF THIS SECTION Turbo Hydra-Matic 350 Transm ission.................................... 7A-1 Turbo Hydra-Matic 400/475 Transm ission........................... 7A-44 Special Tools.................................................................................... 7A-86 TURBO HYDRA-MATIC 3 5 0 TRANSM ISSION INDEX General Description....................................................... Theory of Operation...................................................... Power Flow...................................................................... Hydraulic System - Functions of Valves and Hydraulic Control U nits........................................ Hydraulic Oil System................................................... Maintenance and Adjustment..................................... Checking Transmission M ount.........................^...... Transmission Fluid....................................................... Manual Shift Linkage Check and Adjust (C and P Models)........................................................... Manual and Control Linkage Adjustment (G Model).................................................................... Detent Cable Adjustm ent........................................... Service Operations.......................................................... Transmission Replacem ent........................................ Other Service Operations.............................................. 7A-1 7A-2 7A-2 7A-2 7A-11 7A-28 7A-28 7A-28 7A-29 7A-29 7A-30 7A-32 7A-32 7A-34 G overnor........................................................................... Intermediate Clutch Accumulator............................ Diagnosis............................................................................. Sequence for Diagnosis............................................... Oil Checking Procedures............................................. Oil Leak D iagnosis....................................................... Oil Pressure Check........................................................ Case Porosity R epair................................................... Vacuum Modulator Diagnosis................................... Clutch Plate D iagnosis................................................ Causes of Burned Clutch Plates............................... Governor Pressure C heck........................................... Manual Linkage............................................................. Road Test.......................................................................... Trouble Diagnosis............................................................ Diagnosis Chart.............................................................. Special Tools..................................................................... 7A-34 7A-34 7A-34 7A-34 7A-35 7A-35 7A-36 7A-36 7A-36 7A-38 7A-38 7A-38 7A-38 7A-38 7A-39 7A-39-43 7A-86 GENERAL DESCRIPTION The Turbo Hydra-Matic 350 transmission is a fully automatic unit consisting prim arily of 3-element hydraulic torque converter and two planetary gear sets. Four multiple-disc clutches, two roller clutches, and an intermediate overrun band provide the friction elements required to obtain the desired function of the two planetary gear sets. The 3-element torque converter consists of a pump, turbine and a stator assembly. The stator is mounted on a one way roller clutch which will allow the stator to turn clockwise, but not counterclockwise. References to clockwise and counterclockwise are determined by looking toward rear of vehicle. The torque converter is of welded construction and is serviced as a complete assembly. The unit is filled with oil and is attached to the engine crankshaft by a flywheel, thus always rotates at engine speed. The converter pump is an integral part of the converter housing, therefore, the pump blades, rotating at engine speed, set the oil within the converter into motion and direct it to the turbine, causing the turbine to rotate. As the oil passes throughout the turbine it is traveling in such a direction that if it were not redirected by the stator it would hit the rear of the converter pump blades and impede its pumping action. So at low turbine speeds, oil is redirected by the stator to the converter pump in such a manner that it actually assists the converter pump to deliver power, or multiply engine torque. As turbine speed increases, the direction of oil leaving the turbine changes and flows against the rear side of the stator vanes in a clockwise direction. Since the stator is now impeding the smooth flow of oil, its roller clutch releases and it revolves freely on its shaft. Once the stator becomes inactive, there is no further multiplication of engine torque within the converter. At this point, the converter is merely acting as a fluid coupling as both the converter pump and turbine are being driven at approximately the same speed. LIGHT DUTY TRUCK SERVICE MANUAL 7A-2 A U TO M A T IC T R A N S M IS S IO N A hydraulic system pressurized by a gear type pump provides the working pressure required to operate the friction elements and automatic controls. External control connections to the transmission are: • Manual Linkage - To select the desired operating range. • Engine Vacuum - To operate the vacuum modulator. • Cable Control - To operate the detent valve. A vacuum modulator is used to automatically sense any change in the torque input to the transmission. The vacuum modulator transmits this signal to the pressure regulator, which controls line pressure, so that all torque requirements of the transmission are met and smooth shifts are obtained at all throttle openings. The detent valve is activated by a cable that is connected to the accelerator lever assembly. When the throttle is half open, the valve is actuated causing throttle downshift at speeds below 50 mph. When the throttle is fully open the detent valve is actuated causing the transmission to downshift from 3-1 at speeds below 40 mph and 3-2 below 75 mph. THEORY OF OPERATION POWER FLOW Refer to figures 1M through 7M for related mechanical power flow. Each figure explains what component is applied or related in each stage of transmission operation. HYDRAULIC SYSTEM FUNCTIONS OF VALVES AND HYDRAULIC CONTROL UNITS Pressure Control The transmission is controlled automatically by a hydraulic system. Hydraulic pressure is supplied by the transmission oil pump, see Figure 8M, which is engine driven. Main line pressure is controlled by a pressure regulator valve train and by the vacuum modulator which is connected to engine vacuum. The pressure regulator valve train controls line pressure automatically, in response to a pressure signal from a modulator valve, in such a way that the torque requirements of the transmission clutches are met and proper shift spacing is obtained at all throttle openings. To control line pressure properly, a modulator pressure is used which varied in the same manner as torque input to the transmission. Modulator pressure is regulated by engine vacuum which is an indicator of engine torque and carburetor opening. Pressure Regulator Valve (Fig. 9M) 1. Regulates line pressure according to a fixed spring force and forces controlled by modulator intermedi­ ate and reverse pressure. 2. Controls flow of oil that charges the torque converter, feeds the oil cooler and provides lubrication and oil for clutch applications. Vacuum Modulator Assembly The engine vacuum signal is provided by the vacuum modulator, which consists of an evacuated metal bellows, a diaphragm and two springs. See Figure 10M. These are so arranged that when installed, the bellows and its external spring apply a force which acts on the modulator valve. This force acts on the modulator valve so that it increases modulator pressure. Engine vacuum and the other spring acts in the opposite direction to decrease modulator, or low engine vacuum, high modulator pressure; high engine vacuum, and low modulator pressure. To reduce the effect of engine power loss at high altitudes on shift points, the effective area of the diaphragm is made somewhat larger than that of the bellows. Atmospheric pressure then acts on the resulting differential area to reduce modulator pressure. Governor Assembly (Fig. 11M) The vehicle speed signal to the modulator valve is supplied by the transmission governor, which is driven by the output shaft. The governor consists of a pair of dual weights and a regulator valve. As the car begins to move the weight assemblies move outward to provide a regulating force against the valve through the springs between the primary and secondary weights. As car speed is further increased, regulating force against the valve is provided by the secondary weights moving outward. At approximately 22 MPH the primary weights have reached the limit of their travel and the force against the valve is then entirely through the secondary weights. Thus, governor valve pressure is determined at very low speeds by the prim ary and secondary weights and at higher speeds by the secondary weights plus the force of the springs between the weights. In this manner governor pressure is increased rapidly but smoother from very low speeds to approximately 22 MPH, where it increases at a slower rate. Manual Valve (Fig. 12M) Establishes the range of transmission operation i.e. P, R, N, D, LI, L2, as selected by the vehicle operator through the manual selector lever. Modulator Valve (Fig. 10M) Regulates line pressure to modulator pressure that varies with torque to the transmission. It senses forces created by: LIGHT DUTY TRUCK SERVICE MANUAL PARK OR NEUTRAL Forward Clutch - OFF Low & Reverse Clutch - OFF Low and Roller Clutch - INEFFECTIVE 7A-3 LIGHT DUTY TRUCK SERVICE MANUAL TRANSMISSION In park and neutral, all clutches and the intermediate overrun band are released: therefore no power is transmitted from the torque converter turbine to planetary gear sets or output shaft. AUTOMATIC Intermediate Clutch - OFF Direct Clutch - OFF Intermediate Overrun Roller Clutch - INEFFECTIVE Intermediate Overrun Band - OFF Fig. 1M—Power Flow in Neutral Range • Typical f r o n t g e a r set R E A R G E A R SET DRIVE RANGE (LOW-FIRST GEAR) O U TPU T TO REAR UNI T INEFFECTIVE OFF OFF OFF ON OFF Intermediate Clutch - OFF Direct Clutch - OFF Intermediate Overrun Roller Clutch - INEFFECTIVE Intermediate Overrun Band - OFF LO C KED Forward Clutch - ON Low and Reverse Clutch - OFF Low and Roller Clutch - LOCKED With the range selec to r lev er in Drive "D" range, the forw ard clutch is applied. T his d eliv ers turbine torque from the input shaft through the forw ard clutch, to the input ring gear in a clockw ise direction. (Convertor torque ratio equ als approxim ately 2:00 at stall) C lockw ise rotation of the input ring gear cau ses the output planet pinions to rotate in a clock w ise direction, driving the sun gear coun terclock­ w ise. In turn, the sun gear turns causing the reaction ca rrier planet pinions to turn clo ck w ise. C lockw ise rotation of the reaction ca rrier planet pinions ca u ses the output ring gear and output shaft to turn in a clock w ise direction in a reduction ratio of approxim ately 2. 52 to 1. The reaction of the reaction ca rrier planet pinions against the output ring gear is taken by the low and ro ller clutch which is grounded to the ca se. Fig. 2M—Power Flow in Drive Range ■ Low (First Gear) - Typical DRIVE RANGE F R O N T G E A R SET INPUT REAR G E A R S E T (INTERMEDIATE-SECOND GEAR) OU TP UT HELD FREE WHEELING Forward Clutch - ON Low and Roller Clutch - Low and R everse Clutch OFF FREEWHEELING TRANSMISSION 7A-5 LIGHT DUTY TRUCK SERVICE MANUAL In D rive "D" range interm ediate, (second gear) the interm ediate clutch is applied to allow the interm ediate overrun ro ller clutch to hold the sh ell and sun gear stationary (against counterclockw ise rotation .) Turbine torque, through the applied forw ard clutch is delivered to the input ring gear in a clock w ise direction. C lockw ise rotation of the input ring gear ca u ses the output planet pinions to walk around the stationary sun gear in a clock w ise direction. T his cau ses the output shaft to turn in a clock w ise direction in a reduction ratio of approxim ately 1.52 to 1. AUTOMATIC Intermediate Clutch - ON Direct Clutch - OFF Intermediate Overrun Roller Clutch - LOCKED Intermediate Overrun Band - OFF Fig. 3M—Power Flow in Drive Range ■ Intermediate (2nd Gear) - Typical 7A-6 INPUT REAR G E A R SE T (HIGH-THIRD GEAR) AUTOMATIC DRIVE RANGE F R O N T G E A R SET T R A N S M IS S IO N FREE WHEELING Intermediate Clutch - ON Direct Clutch - ON Intermediate Overrun Roller Clutch - FREE WHEELING Intermediate Overrun Band - OFF Forward Clutch - ON Low and R everse Clutch OFF Low and Roller Clutch - FREE WHEELING LIGHT DUTY TRUCK SERVICE MANUAL In direct drive, engine torque it transm itted to the converter then through the forw ard clutch, to the input ring gear in clock w ise direction the direct clutch is applied transm itting torque through the sun gear drive sh ell to the sun gear in a clo ck w ise d irection. Since both the sun gear and the planet pinion g ea rs are both turning in a clock w ise direction at the sam e speed, the planetary gear se ts are locked and turn as one unit in direct drive or at a ratio of 1:1. Fig. 4M—Power Flow in Drive Range - Direct (Third Gear) - Typical Li RANGE F R O N T G E A R SET REAR G E A R SET OUTPUT HELD INPUT INEFFECTIVE OFF OFF OFF ON LOCKED Forward Clutch - ON Low and Reverse Clutch - ON Low and Roller Clutch - LOCKED When the transmission is shifted into Lj (first gear), the low and reverse clutch is applied below a preset controlled speed in addition to The low and rev erse clutch provides overrun braking as it holds the reaction ca rrier Fig. 5M—Power Flow in LI Range (Manual First Gear) - Typical 7A-7 the forward clutch which is on for all forward ranges. fixed. TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL With the range selector lever in L j range, the forward clutch is applied. This d eliv ers turbine torque from the input shaft through the forward clutch, to the input ring gear in clockw ise direction. (Converter torque ratio equals approxim ately 2:00 at sta ll.) C lockw ise rotation of the input ring gear ca u ses the output planet pinions to rotate in a clockw ise direction, driving the sun gear counter w ise. In turn, the sun gear turns, causing the reaction ca rrier planet pinions to turn clock w ise. C lockw ise rotation of the reaction ca rrier planet pinions cau ses the output ring gear and output shaft to turn in a clockw ise direction in a reduction ratio of approxim ately 2:52 to 1. The reaction of the reaction carrier planet pinions against the output ring gear is taken by either the low and roller clutch or the low & rev erse clutch which are grounded to the case. AUTOMATIC Intermediate Clutch - OFF Direct Clutch - OFF Intermediate Overrun Roller Clutch - INEFFECTIVE Intermediate Overrun Band - OFF ON r 7A-8 REAR G E A R SET INPUT OUTPUT AUTOMATIC L, RANGE - MANUAL SEC OND GEAR F R O N T G E A R SET T R A N S M IS S IO N HELD FREE WHEELING Intermediate Clutch - ON Direct Clutch - OFF Intermediate Overrun Roller Clutch - LOCKED Intermediate Overrun Band - ON Forward Clutch - ON Low and Reverse Clutch - OFF Low and Roller Clutch - FREE WHEELING LIGHT DUTY TRUCK SERVICE MANUAL In L.2 range interm ediate, the interm ediate clutch is applied to allow the interm ediate overrun ro ller clutch to hold the shell and sun gear stationary (against counterclockw ise rotation). Turbine torque, through the applied forward clutch is delivered to the input ring gear in a clockw ise direction. Clockwise rotation of the input ring gear ca u ses the output planet pinions to walk around the stationery sun gear in a clockw ise direction. This causes the output ring gear and output shaft to turn in a clockw ise direction in a reduction ratio of approxim ately 1:52 to 1. The reaction of the output planet pionions against the sun gear is taken by either the interm ediate overrun roller clutch or the in ter­ m ediate overrun band. When the transm ission is shifted into L2 (second gear), the interm ediate overrun band is applied in addition to the forward and interm ediate clutches. The interm ediate overrun band provides overrun braking as it holds the sun gear fixed. Fig. 6M—Power Flow in L2 Range (Manual Second Gear) - Typical REVERSE FRONTGEARSET Forward Clutch - OFF Low & Reverse Clutch - ON Low and Roller Clutch - INEFFECTIVE DUTY TRUCK TRANSMISSION LIGHT In R everse "R", the direct clutch is applied to transm it torque from the forward clutch housing to the sun gear drive sh ell and the sun gear. The low and re v erse clutch is applied preventing the output ca rrier from turning. C lockw ise rotation of the sun gear ca u ses the reaction ca rrier pinions to turn counterclockw ise, thus turning the output ring gear and output shaft counterclockw ise in a reduction ratio of approxim ately 1. 93 to 1. AUTOMATIC Intermediate Clutch - OFF Direct Clutch - ON Intermediate Overrun Roller Clutch - INEFFECTIVE Intermediate Overrun Band - OFF REARGEARSET MANUAL 7A-9 SERVICE Fig. 7M—Power Flow in Reverse Range - Typical 7 A - 10 A U T O M A T IC T R A N S M IS S IO N Fig. 8 M — Oil P u m p Fig. 1 1 M —G o ve rn o r A ss e m b ly -n— t — n -----1.i ....... 3-2 PART THROTTLE: s s i L!n= P. =asr MANUAL VAlVE -ZX PRESSURE REGULATOR STRAINER I I I I I I P R N D l 2 Li M ANUAL VALVE Fig. 1 2 M — M a n u a l V alve Fig. 9 M — P re s s u re R e g u la to r Valve 1-2 ACCUMULATOR 1-2 SHIFT VALVE Fig. 1 3 M — 1-2 S h ift V alve a n d A c c u m u la to r 2-3 Accumulator (Fig. 14M) 1. The vacuum modulator bellows that increases modulator pressure. 2. Engine vacuum acting on a diaphragm to decrease modulator pressure. 3. Governor pressure which is generated by the governor assembly. Governor pressure tends to decrease modulator pressure. 1-2 Accumulator (Fig. 13M) Line pressure routed to the 1-2 accumulator causes the piston to cushion application of the intermediate clutch. The spring with the accumulator acts against the piston. The force of the spring and the pressure of the 1-2 clutch oil push the 1-2 accumulator piston back towards the line oil to allow a gradual build up of the 1-2 clutch pressure. 1-2 Shift Valve (Fig. 13M) Routes oil pressure that causes the transmission to shift from 1-2 or 2-1. Its operation is controlled by governor pressure, detent pressure, modulator pressure, and spring force. See Figure 13M. Oil routed to the 2-3 accumulator cushions the application of the direct clutch. The spring within the accumulator acts against the piston. The force of the spring and the pressure of the 2-3 clutch oil push the 2-3 accumulator piston back towards the R, D, N oil to allow a gradual build up of the 2-3 clutch pressure. 2-3 Shift Valve (Fig. 14M) Routes oil pressure that causes the transmission to shift from 2-3 or 3-2. Its operation is controlled by modulator, governor, detent and modulator, valves pressures as well as a spring force. Detent Valve (Actuated by Cable Linkage From Throttle Linkage) Affects regulated modulator pressure tending to hold the 1-2 shift and 2-3 shift valves in the downshift position and provides areas for modulator and detent regulated pressures for detent 2-1, 3-1, and 3-2 downshifts. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7 A -11 INTERMEDIATI SMVO t (AND APPIY PIN 2-3 SHIFT VALVE 2-3 ACCUMULATOR Fig. 14M—2-3 Shift Valve and Accumulator “ Fig. 15M-Detent Valve and Pressure Regulator Valve MAN. LOW C O N T R O L ! M A N U A L LOW CONTROL VALVE Detent Pressure Regulator Valve (Fig. 15M) The detent pressure regulator valve and spring regulate line pressure into detent regulator oil which is used to control the car speed at which the 1-2 and 2-3 upshifts occur. Cooler By-Pass Valve (Fig. 16M) The cooler by-pass valve permits oil to be fed directly from the converter to the lubrication circuit when the oil is very cold or if the cooler or lines whould become restricted. Manual Low Control Valve (Fig. 17M) The manual low control valve is positioned to exhaust the manual low apply line when the manual valve is placed in the m anual low (LI) position above approximately 50 MPH. At speeds below 50 MPH low oil is fed into the manual low apply line which move the 1-2 shift valve to the downshifted position (exhausting the 1-2 clutch) and moves the 1-2 shift control valve to the upshifted position which sends low apply oil to the low and reverse clutch which engages this clutch. Once the manual low control valve is in the downshifted position, its spring plus low apply oil acting on it will keep it in 1 -2 SHIFT VALVE Fig. 17M—Manual Low Control Valve this position; therefore, with the transmission in manual low (LI range), the transmission cannot upshift to intermediate (second gear) regardless of vehicle or engine speed once low gear has been engaged. The manual low control valve is used also to protect the engine by preventing low range engagement (indicated by high car speed which is sensed by high governor pressure) at car speeds over 50 MPH. HYDRAULIC OIL SYSTEM Refer to Figures 18M through 25M for explanation of hydraulic system that applies the clutches and bands and controls the automatic shifting. NOTE: All pressures, MPH and RPM are approxim ate and are to be used for illustrating hydraulic operation only. LIGHT DUTY TRUCK SERVICE MANUAL NEUTRAL - ENGINE RUNNING Intermediate Clutch - OFF Direct Clutch - OFF Forward Clutch - OFF Low and Reverse Clutch - OFF DUTY TRUCK Sum m ary MANUAL The converter is filled, all clutches and bands are released. The transmission is in neutral. 7 A -13 SERVICE Oil flows from the pump to the priming valve and then to the pressure regulator valve which regulates the pump pressure. When pump output exceeds the demand of line pressure, oil from the pressure regulator valve is directed to the converter feed passage to fill the converter. Converter return oil is directed to the cooler by-pass valve and transmission cooler. Oil from the cooler is direct­ TRANSMISSION LIGHT Cooling and Lubrication ed to the transmission lubrication system. The cooler by-pass valve permits oil to be fed directly from the converter to the lubrication circuit if the cooler should become restricted. The priming valve provides an exhaust for any air that may be trapped in the pump. The priming valve spring holds the valve in an open position until the pump primes allowing any trapped air to exhaust. As hydraulic pressure reaches approximately 5 PSI, the valve is forced to the bottom of its bore, closing the exhaust bleed hole. From the pressure regulator valve line oil is then routed as follows— 1. Manual Valve 2. 2-3 Accumulator 3. Detent Pressure Regulator 4. 1-2 Accumulator 5. Vacuum Modulator Valve Line pressure at the modulator valve is regulated to modulator oil which acts on the modulator and reverse boost valve, detent valve, 2-3 shift control valve, and the 1-2 shift control valve. AUTOMATIC Whenever the engine is running at idle with the selector lever in neutral, oil from the pump is directed to— 1. Pump Priming Valve 2. Pressure Regulator Valve 3. Converter (With Pressure Regulator Valve regulating) a. Cooler By-pass Valve b. Oil Cooler c. Lubrication System. 4. Manual Valve 5. Modulator Valve 6. 2-3 Accumulator (Neutral - Not In Park) 7. Detent Pressure Regulator 8. 1-2 Accumulator Intermediate Overrun Roller Clutch - FREE WHEELING Low and Reverse Roller Clutch - FREE WHEELING Intermediate Overrun Band - OFF 7A-14 AUTOMATIC T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 19M—Drive Range - Low (First Gear) - Typical D R IV E R A NG E - LOW ( F I R S T G E A R ) Line pressure is fed to the: 1. M odulator Valve 2. 1-2 A ccu m u la tor Piston 3. D e te n t Pressure Regulator Valve 4. Manual Valve F ro m the m anual control valve line pressure form s drive oil and is fed to the: 1. F orw ard C lutch 2. G overnor 3. 1-2 Shift Valve 4. 2-3 Shift Valve 5. Interm ediate Servo (as R .N .D . oil) directs line pressure to the R .N .D . and drive ports. R .N .D . pressure strokes the 2-3 accu m u lator so that it is prepared to cu sh io n the 2-3 clu tch for an upshift. T h e 1-2 accum u lator has already been stroked w ith line oil to prepare it to cush ion the 1-2 clutch. Drive oil applies the forw ard clu tch , feeds the governor and also th e 1-2 and 2-3 shift valves. DUTY TRUCK Basic C ontrol W hen the selector lever is m oved to the drive p o sition , the m anual valve Sum m ary Drive oil is d irected to the forward clu tch and is regulated to a variable pressure called governor pressure at th e governor assem bly. G overn or pressure in creases w ith sp e e d and acts against th e e n d s o f th e 1-2 and 2-3 shift valves, and the m o d u la tor valve. TRANSMISSION Interm ed iate Overrun R oller C lutch - IN E F F E C T I V E L o w and Reverse Roller C lu tch - L O C K E D Interm ed iate Overrun Band - O F F AUTOMATIC LIGHT In term ediate C lu tch - O F F D irect C lutch - O F F F orw ard C lu tch - O N L o w and Reverse C lu tch - O F F MANUAL 7 A -15 SERVICE 7A-16 AUTOMATIC T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 20M—Drive Range - Intermediate (Second Gear) Typical D R IV E R A NG E - I N T E R M E D I A T E (S E C O N D G E A R ) Intermediate Clutch - ON Direct Clutch - OFF Forward Clutch - ON Low and Reverse Clutch - OFF Basic C o ntro l Intermediate clutch oil flows from the 1-2 shift valve through the 2-3 accu­ mulator. And then to the 1-2 accumulator which cushions intermediate clutch application. The 1-2 accumulator has clutch apply pressure and a calibration spring acting on one side with line pressure on the other side. Intermediate (1-2) clutch oil from the 1-2 shift valve is directed to: 1. Intermediate Clutch 2. 2-3 Accumulator 3. 1-2 Accumulator The forward and intermediate clutch are applied. The transmission is in drive range 2nd gear. When in drive range the full throttle 1-2 upshift will occur at approximately 50 MPH and minimum throttle 1-2 upshift will occur at approxi­ mately 12 MPH. TRANSMISSION Sum m ary AUTOMATIC As both vehicle speed and governor pressure increase, the force of governor pressure (46 PSI @ W.O.T.) acting on the 1-2 shift valve overcome the force of the 1-2 shift valve spring and modulator oil regulated by the modulator valve. This allows the 1-2 shift valve to move to the upshifted position which directs drive oil to apply the intermediate clutch. Oil in this passage is called (1-2) clutch oil. Intermediate Overrun Roller Clutch - LOCKED Low and Roller Clutch - FREE WHEELING Intermediate Overrun Band - OFF 7A -17 t : K. v. AUTOMATIC PRESSURE 7 A -18 MAINLINE PRESSURE SUCTION PRESSURE T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 21M—Drive Range - Direct (Third Gear) - Typical D R IV E RANGE - Intermediate Clutch - ON Direct Clutch - ON Forward Clutch - ON Low and Reverse Clutch - OFF DUTY TRUCK Direct (2-3) clutch oil from the 2-3 shift valve flows to the direct clutch and GEAR) Intermediate Overrun Roller Clutch - FREE WHEELING Low and Roller Clutch - FREE WHEELING Intermediate Overrun Band - OFF also to the 2-3 accumulator piston. The shift is cushioned by the R.N.D. oil force on the other side of the accumulator pistons. Sum m ary The forward, intermediate and direct clutches are applied. The transmission is in drive range - third gear (direct drive). When in drive range the full throttle 2-3 upshift will occur at approximately 85 MPH and minimum throttle 2-3 upshifts will occur at approximately 22 MPH. TRANSMISSION LIGHT Basic C ontrol ( T H IR D AUTOMATIC As vehicle speed and governor pressure increases, the force of the governor pressure (83 PSI @ W.O.T.) acting on the 2-3 shift valve overcomes the force of the 2-3 shift valve spring and modulator oil. This allows the 2-3 shift valve to move to the upshifted position feeding drive oil to the direct clutch. This oil is called 2-3 (direct) clutch oil. Direct (2-3) clutch oil is directed from the 2-3 shift valve to: 1. Direct Clutch 2. 2-3 Accumulator D IR E C T MANUAL 7 A -19 SERVICE 7A-20 AUTOMATIC TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL Fig. 22M—LI Range - Manual First Gear - Typical L-| R A N G E - M A N U A L F IR S T G E A R Intermediate Clutch - OFF Direct Clutch - OFF Forward Clutch - ON Low and Reverse Clutch - ON Basic C ontrol Sum m ary The forward clutch and the low and reverse clutch are applied. The trans­ mission is in low (first gear) Li range. The manual low control valve is used also to protect the engine by pre­ venting low range engagement (indicated by high speed which is sensed by high governor pressure) at speeds over 50 MPH, or approximately 3600 engine rpm. TRANSMISSION The manual low control valve is positioned to exhaust the manual low apply line when the manual valve is placed in the manual (L i) position above approxi­ mately 50 MPH. At speeds below 50 MPH low oil is fed into the manual low apply line which moves the 1-2 shift valve to the downshifted position (ex­ hausting the 1-2 clutch) and moves the 1-2 shift control valve to the upshifted position which sends low apply oil to the low and reverse clutch which engages this clutch. Once the manual low control valve is in the downshifted position, its spring plus low apply oil acting on it will keep it in this position; therefore, with the transmission in manual low (Li range), the transmission cannot upshift to intermediate (second gear) regardless of vehicle or engine speed once low gear has been engaged. AUTOMATIC Maximum downhill braking can be attained at speeds below approximately 50 MPH with the selector lever in Li range position. Low range oil from the manual valve is then directed to the manual low control valve which in turn directs it through the 1-2 shift valve train to the low and reverse clutch piston (inner area only). Intermediate Overrun Roller Clutch - INEFFECTIVE Low and Reverse Roller Clutch - LOCKED Intermediate Overrun Band - OFF 7A- AUTOMATIC PRESSURE BBS 7A-22 MAINLINE PRESSURE SUCTION PRESSURE T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 23M—L2 Range - Manual Second Gear Typical l_2 R A N G E - M A N U A L SECOND GEAR Intermediate Clutch - ON Direct Clutch - OFF Forward Clutch - ON Low and Reverse Clutch - OFF provides engine braking in the intermediate range by preventing clockwise rota­ tion of the direct clutch drum, sun gear drive shell, and sun gear once the transmission is in second gear, it cannot upshift to third gear regardless of speed. DUTY TRUCK When the forward, intermediate clutches and intermediate overrun band are applied, the transmission is in intermediate range—second gear and allows engine braking. When vehicle slows down to approximately 9 MPH a 2-1 shift will oc­ cur when decreased governor pressure allows the 1-2 shift valve to move and exhaust the 1-2 clutch. TRANSMISSION Sum m ary AUTOMATIC LIGHT A manual 3-2 downshift can be accomplished by moving the selector lever from drive to intermediate range (L2 ). Intermediate oil from the manual valve is then directed to: 1. Intermediate Boost Valve 2. 2-3 Shift Valve Intermediate oil at the pressure regulator intermediate boost valve will in­ crease minimum line pressure to 80 PSI. Intermediate oil will move the 2-3 shift valve to the downshifted position regardless of speed. This in turn releases the direct clutch. When the manual valve is moved to the intermediate position R.N.D. oil is exhausted. 1-2 clutch oil acting on the intermediate servo piston then applies the intermediate overrun band which places the transmission in second gear. This Intermediate Overrun Roller Clutch - LOCKED Low and Reverse Roller Clutch - FREE WHEELING Intermediate Overrun Band - ON MANUAL 7 A -23 SERVICE 7A-24 AUTOMATIC T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 24M—Drive Range Detent Downshift (1-2 and 2-3 Shift Valves in Second Gear Position) - Typical D R IV E RANGE VALVES DETENT D O W N S H IF T (1-2 A N D 2 -3 S H IF T IN S E C O N D G E A R Intermediate Clutch - ON Direct Clutch - OFF Forward Clutch - ON Low and Reverse Clutch - OFF valve. This allows detent regulator oil plus the force of the 1-2 shift control valve spring to move the 1-2 shift valve to the downshifted position placing the trans­ mission in first gear. Detent regulator oil is directed to the modulator valve to prevent modulator pressure from falling below that of detent regulator at high speeds or at high altitudes. the 3-2 part throttle downshift can be made below 50 MPH (see insert of detent valve in part throttle position). At light throttle opening the 3-2 part throttle passage is exhausted; however, at moderate throttle opening the detent valve connects modulator pressure to the 3-2 part throttle passage. If modulator pressure acting on the 3-2 part throttle area of the 2-3 shift control valve plus the 2-3 shift valve spring is sufficient to move the valve to the downshifted position, the transmission will be in second gear. NOTE: TRANSMISSION Modulator oil, detent regulator oil plus the force of the 2-3 shift control valve spring will move the 2-3 shift valve to the downshifted position below approximately 75 MPH shifting the transmission to second gear. A detent 2-1 or 3-1 downshift can also be accomplished below approxi­ mately 40 MPH because detent regulator oil is directed to the 1-2 shift control Intermediate Overrun Roller Clutch - LOCKED Low and Roller Clutch - FREE WHEELING Intermediate Overrun Band - OFF AUTOMATIC While operating at speeds below approximately 75 MPH, a forced or detent 3-2 downshift is possible by depressing the accelerator fully. This moves the detent valve by cable linkage, to its extreme inner position allowing modulator oil to be routed into the 3-2 part throttle passage and detent regulator oil to be routed into the modulator shift valve and detent passages. Detent regulated oil therefore acts on both the 1-2 & 2-3 shift control valves and modulator pressure also acts on the 2-3 shift control valve through the 3-2 part throttle passage. Detent regulator oil is also routed to the modulator valve via the detent passage. P O S IT IO N ) 7 A -2 5 7A-26 AUTOMATIC T R A N S M IS S IO N LIGHT DUTY TRUCK SERVICE MANUAL Fig. 25M—Reverse Range - Typical REVERSE RANGE Intermediate Clutch - OFF Direct Clutch - ON Forward Clutch - OFF Low and Reverse Clutch - ON piston, to the outer area of the low and reverse clutch piston, to the 1-2 shift valve and to the 2-3 shift valve. From the 1-2 shift valve, it is directed to the inner area of the low and reverse clutch piston. From the 2-3 shift valve it is directed to the inner area of the direct clutch piston. Reverse oil also acts on the reverse boost valve to increase line pressure to a maximum of 250 PSI at stall. Reverse oil from the manual valve flows to the outer area of the direct clutch The direct clutch and the low and reverse clutch are applied. Line pressure is boosted and the transmission is in reverse. TRANSMISSION Sum m ary Basic C ontrol AUTOMATIC When the selector lever is moved to the reverse position, the manual valve is repositioned to allow line pressure to enter the reverse circuit. Reverse oil then flows as shown below. 1. Direct (2-3) Clutch. 2. Low and Reverse Clutch 3. 1-2 Shift Valve 4. 2-3 Shift Valve 5. Reverse Boost Valve Intermediate Roller Clutch - INEFFECTIVE Low and Reverse Roller Clutch - INEFFECTIVE Intermediate Overrun Band - OFF 7A -27 7 A -2 8 A U TO M A T IC T R A N S M IS S IO N MAINTENANCE A N D ADJUSTMENTS CHECKING TRANSMISSION MOUNT Raise the vehicle on a hoist. Push up and pull down on the transmission tailshaft while observing the transmis­ sion mount. If the rubber separates from the metal plate of the mount or if the tailshaft moves up but not down (mount bottomed out) replace the mount. If there is relative movement between a metal plate of the mount and its attaching point, tighten the screws or nuts attaching the mount ot the transmission or crossmember. TRANSMISSION FLUID Checking Procedure The transm ission fluid level should be checked periodically as recommended in Section 0. Oil should be added only when level is on or below the "ADD" mark on the dip stick with oil hot or at operating temperature. The oil level dip stick is located at the right rear of the engine compartment. Fill with oil specified in Section 0. In order to check oil level accurately, the engine should be idled with the transmission oil hot and the control lever in neutral (N) position. It is important that the oil level be maintained no higher than the "FU LL" mark on the transmission oil level gauge. DO NOT OVERFILL, for when the oil level is at the full mark on the dip stick, it is just slightly below the planetary gear unit. If additional oil is added, bringing the oil level above the full mark, the planetary unit will run in the oil, foaming and aerating the oil. This aerated oil carried through the various oil pressure passages (low servo, reverse servo, clutch apply, converter, etc.) may cause m alfunction of the transmission assembly, resulting in cavitation noise in the converter and improper band or clutch application. Overheating might also occur. If the transmission is found consistently low on oil, a thorough inspection should be made to find and correct all external oil leaks. Draining and Refilling Transmission The transmission oil should be changed periodically as recommended in Section 0, and whenever transmission is to be removed from the vehicle for repairs. D rain oil immediately after operation before it has had an opportunity to cool. To drain oil, proceed as follows: 1. Raise vehicle on hoist or place on jack stands and place container beneath transmission to collect draining fluid. 2. Remove thirteen (13) oil pan attaching bolt and washer assemblies, oil pan and gasket. Discard gasket. 3. Drain fluid from oil pan. Clean pan with solvent and dry thoroughly with clean compressed air. 4. Remove two (2) strainer-to-valve body screws, strainer and gasket. Discard gasket. 5. Thoroughly clean strainer assembly in solvent and dry throughly with clean compressed air. 6. Install new strainer-to-valve body gasket, strainer and two (2) screws. 7. Install new gasket on oil pan and install oil pan. Tighten its thirteen (13) attaching bolt and washer assemblies to 12 lb. ft. torque. 8. Lower vehicle. Add approximately 5 pints U.S. measure (4 pints Imperial measure) of transmission fluid through filler tube. 9. With selector lever in PARK position, apply hand brake, start engine and let idle (carburetor off fast idle step). DO NOT RACE ENGINE. 10. Move selector lever through each range and, with selector lever in PARK range, check the fluid level. 11. Add additional fluid to bring level to 1/4 " below the ADD mark on the dipstick. CAUTION: if overfull. Do not overfill. Foaming will result Adding Fluid to Fill Dry Transmission and Converter Assembly The fluid capacity of the Turbo Hydra-Matic 350 transmission and converter assembly is approximately 20 pints, but correct level is determined by the mark on the dipstick rather than by amount added. In cases of transmission overhaul, when a complete fill is required, including a new converter, proceed as follows: 1. Add 8 pints of transmission fluid through filler tube. If installation of a new converter is not required add only 5 pints of transmission fluid. NOTE: The converter should be replaced only if the converter itself fails. On any major failure, such as a clutch or gearset, the strainer must be cleaned. 2. With manual control lever in PARK position, start engine and place on cold idle cam. DO NOT RACE ENGINE. Move manual control lever through each range. 3. Immediately check fluid level with selector lever in PARK, engine running and vehicle on LEVEL surface. 4. Add additional fluid to bring level to 1/4" below the "A D D " mark on the dipstick. Do not overfill. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 9. 10. 11. 12. 13. SHIFT CONTROLS Column Shift Linkage - CK Series (Fig. 26M) 1. The shift tube and lever assembly must be free in the mast jacket. See Section 9 for alignment of steering column assembly if necessary. 2. To check for proper shift linkage adjustment, lift the transmission selector lever towards the steering wheel. Allow the selector lever to be positioned in drive (D) by the transmission detent. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. 3. Release the selector lever. The lever should be inhibited from engaging low range unless the lever is lifted. 4. Lift the selector lever towards the steering wheel, and allow the lever to be positioned in neutral (N) by the transmission detent. 5. Release the selector lever. The lever should now be inhibited from engaging reverse range unless the lever is lifted. 6. A properly adjusted linkage will prevent the selector lever from moving beyond both the neutral detent, and the drive detent unless the lever is lifted to pass over the mechanical stop in the steering column. 7. If adjustment is required, remove screw (A) and spring washer from swivel (B). 8. Set transmission lever (C) in Neutral position by 7 A -29 moving lever counterclockwise to LI detent and then clockwise three (3) detent positions to Neutral. Position transmission selector lever in Neutral position as determined by the mechanical stop in steering column assembly. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. Assemble swivel, spring washer and screw to lever assembly (D) and tighten screw to 20 pound feet. Readjust indicator needle if necessary to agree with the transmission detent positions. See Section 9. Readjust neutral safety switch if necessary to provide the correct relationship to the transmission detent positions. See Section 12. Check operation: a. With key in "R un" position and transmission in "Reverse" be sure that key cannot be removed and that steering wheel is not locked. b. With key in "Lock" position and shift lever in "Park", be sure that key can be removed, that steering wheel is locked, and that transmission remains in "Park" when steering column is locked. CAUTION: Any inaccuracies in the above adjustments may result in premature failure of the transmission due to operation without controls in fu ll detent. Such operation results in reduced oil pressure and in turn partial engagement o f the affected clutches. Partial engagement o f the clutches with sufficient pressure to cause apparent normal operation of the vehicle will result in failure o f the clutches or other internal parts after only a few miles of operation. Column Shift Linkage - G and P Series (Figs. 27M and 28M) 1. The shift tube and lever assembly must be free in the mast jacket. See Section 9 for alignment of steering column assembly if necessary. 2. To check for proper shift linkage adjustment, lift the transmission selector lever towards the steering wheel. Allow the selector lever to be positioned in drive (D) by the transmission detent. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When perform ing linkage adjustment, pointer is adjusted last. 3. Release the selector lever. The lever should be inhibited from engaging low range unless the lever is lifted. 4. Lift the selector lever towards the steering wheel, LIGHT DUTY TRUCK SERVICE MANUAL 7 A -3 0 A U TO M A T IC T R A N S M IS S IO N NEUTRAL SAFETY SWITCH NEU SAF SW ROD TRANSMISSION CLEVER (E) reduced oil pressure and in turn partial engagement o f the affected clutches. Partial engagement o f the clutches with sufficient pressure to cause apparent normal operation of the vehicle will result in failure of the clutches or other internal parts after only a few miles of operation. DETENT CABLE (FIGS. 29M and 30M) Remove Do not use impact wrench VIEW A to f'9hten nu\ 1. Push up on bottom of snap-lock and release lock and detent cable. 2. Compress locking tabs and disconnect snap-lock assembly from bracket. 3. Disconnect cable from carburetor lever. 4. Remove clamp around filler tube, remove screw and washer securing cable to transmission and discon­ nect detent cable. Install Fig. 27M—Column Shift Linkage - P Series 5. 6. 7. 8. 9. 10. 11. 12. and allow the lever to be positioned in neutral (N) by the transmission detent. Release the selector lever. The lever should now be inhibited from engaging reverse range unless the lever is lifted. A properly adjusted linkage will prevent the selector lever from moving beyond both the neutral detent and the drive detent unless the lever is lifted to pass over the mechanical stop in the steering column. If adjustment is required, loosen nut (A) on steering column to allow swivel (B) and clamp (C) to move freely on rod (D). Set transmission lever (E) in Neutral position by moving lever counter-clockwise to LI detent and then clockwise three (3) detent positions to Neutral. Position transmission selector lever in Neutral position as determined by the mechanical stop in steering column assembly. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. Tighten nut (A) 18 pound-feet. Readjust indicator needle if necessary to agree with the transmission detent positions. See Section 9. Readjust neutral safety switch if necessary to provide the correct relationship to the transmission detent positions. See Section 12. CAUTION: Any inaccuracies in the above adjustments may result in premature failure of the transmission due to operation without controls in fu ll detent. Such operation results in 1. Install new seal on detent cable lubricant seal with transmission fluid. 2. Connect transmission end of detent cable and secure to transmission case with bolt and washer tightened to 75 pound inches. 3. Route cable in front of filler tube and install clamp around filler tube, modulator pipe and detent cable. Locate clamp approximately 2 inches above filler tube bracket. 4. Pass cable through bracket and engage locking tabs of snap-lock on bracket. 5. Connect cable to carburetor lever. Adjust With snap-lock disengaged, position carburetor to wide open throttle (W.O.T.) position and push snap-lock downward until top is flush with rest of cable. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7A-31 'SNAP LOCK' 'SNAP LOCK' P MODEL C-K MODEL V - 8 3 0 7 E N GI NE C-K MODEL V-8 350 ENGINE P MODEL VIEW A C-K MODEL VIEW B Fig. 29M—Detent Cable - C, K and P Series LIGHT DUTY TRUCK SERVICE MANUAL 7 A -3 2 A U TO M A T IC T R A N S M IS S IO N SERVICE OPERATIONS TRANSMISSION REPLACEMENT (All Except K Model) Removal 1. Raise truck on hoist and remove oil pan to drain oil. NOTE: If desired, the oil may be drained after transmission removal. 2. Disconnect the vacuum modulator line and the speedometer drive cable fitting at the transmission. Tie lines out of the way. 3. Disconnect manual control lever rod and detent cable from transmission. 4. Disconnect prop shaft from transmission. 5. Install suitable transmission lift equipment to jack or other lifting device and attach on transmission. 6. Disconnect engine rear mount on transmission extension, then remove the transmission support crossmember. 7. Remove converter underpan, scribe flywheelconverter relationship for assembly, then remove the flywheel-to-converter attaching bolts. 8. Support engine at the oil pan rail with a jack or other suitable brace capable of supporting the engine weight when the transmission is removed. Lower the rear of the transmission slightly so that the upper transmission housing-to-engine attaching bolts can be reached using a universal socket and a long extension. Remove upper bolts. CAUTION: It is best to have an assistant observe clearance o f upper engine components while the transmission rear end is being lowered. 10. Remove rem ainder of transmission housing-toengine attaching bolts. 11. Remove the transmission by moving it slightly to the rear and downward, then remove from beneath the vehicle and transfer to a work bench. NOTE: Observe converter when moving the transmission rearward. If it does not move with transmission, pry it free of flywheel before proceeding. Keep front of transm ission upward to prevent the converter from falling out. Install suitable converter holding tool after removal from the engine. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N Installation 1. Mount transmission on transmission lifting equip­ ment installed on jack or other lifting device. 2. Remove converter holding tool. CAUTION: Do not permit converter to move forward after removal of holding tool. 3. Raise transmission into place at rear of engine and install transmission case to engine upper mounting bolts, then install remainder of the mounting bolts. Torque bolts to 25-30 ft. lbs. 4. Remove support from beneath engine, then raise rear of transmission to final position. 5. If scribed during removal, align scribe marks on flywheel and converter cover. Install converter to flywheel attaching bolts. Torque bolts to 30-35 ft. lbs. 6. Install flywheel cover. 7. Reinstall transmission support crossmember to transmission and frame with taper on support sloping toward rear. 8. Remove transmission lift equipment. 9. Connect propeller shaft to transmission. 10. Connect vacuum modulator line, and speedometer drive cable to transmission. 12. Refill transmission through filler tube, and follow­ ing the recommended procedure provided earlier in this section. 13. Check transmission for proper operation and for leakage. Check and, if necessary, adjust linkage. 14. Remove truck from hoist. 7A-33 8. Remove transfer case to frame bracket attaching bolts and remove transfer case. 9. Remove exhaust system crossover pipe on vehicles with V-8 engine. 10. Remove the transm ission support rear crossmember. 11. Remove converter under pan (scribe flywheel to converter relationship for assembly), then remove flywheel to converter attaching bolts. 12. Support engine at the oil pan rail with a jack or other suitable brace capable of supporting the engine weight when the transmission is removed. 13. Lower rear of the transmission slightly so that the upper transmission housing-to-engine attaching bolts can be reached using a universal socket with a long extension. Remove upper bolts. CAUTION: It is best to have an assistant observe clearance of upper engine components while the transmission rear end is being lowered. 14. Remove rem ainder of transmission housing-toengine attaching bolts. 15. Remove transmission by moving it slightly to the rear and downward, then remove from beneath vehicle and transfer to work bench. Observe converter when moving the transm ission rearward. If it does not move with the transmission, pry it free of flywheel before proceeding. Keep front of transmission upward to prevent the converter from falling out. Install suitable converter holding tool after removal from engine. Installation TRANSMISSION REPLACEMENT (K Model) Removal 1. Raise vehicle on hoist and remove oil pan to drain oil. NOTE: If desired, the oil may be drained after transmission removal. 2. Remove transfer case shift lever and rod. 3. Disconnect the vacuum modulator line and the speedometer drive cable at the transmission. Tie lines out of the way. 4. Disconnect manual control lever rod and detent cable from transmission. 5. Disconnect front and rear axle prop shafts at transfer case. 6. Remove transmission to adapter case attaching bolts and place suitable support under transfer case. 7. Install suitable transmission lift equipment to lifting device and attach to transmission. 1. Mount transmission on transmission lifting equip­ ment installed on jack or other lifting device. 2. Remove converter holding tool. CAUTION: Do not permit converter to move forward after removal o f holding tool. 3. Raise transmission into place at rear of engine and install transmission case to engine upper mounting bolts, then install remainder of the mounting bolts. Torque bolts to 25-30 ft. lbs. 4. Remove support from beneath engine, then raise rear of transmission to final position. 5. If scribed during removal, align scribe marks on flywheel and converter cover. Install converter to flywheel attaching bolts. Torque bolts to 30-35 ft. lbs. 6. Install flywheel cover. 7. Place transfer case and adapter assembly at rear of transmission on suitable lift equipment and install transfer case to frame bracket attaching bolts. Torque to 110 to 150 ft. lbs. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -3 4 A U TO M A T IC T R A N S M IS S IO N 8. Reinstall transmission support crossmember to adapter and frame. 9. Install transmission to transfer case adapter attaching bolts tighten 21 to 29 pound feet and remove lift equipment. 10. Connect front and rear axle prop shafts to transfer case. 11. Install exhaust system crossover pipe. 12. Connect manual control lever rod and detent cable to transmission. 13. Connect vacuum modulator line and speedometer drive cable to transmission. 14. Assemble rod on transfer case shift lever before installing rod to transfer case shift linkage. Tighten shift lever attaching bolt 40 to 45 pound feet. 15. Lower vehicle and remove from hoist. 16. Refill transmission through filler tube following the recommended procedure outlined in this Section. 17. Check transmission for proper operation and for leakage. Check, and if necessary, adjust linkage. OTHER SERVICE OPERATIONS Although certain operations, such as oil pan gasket or manual levers and oil seal replacement, detent cable, filler pipe "O " ring, speedometer drive gear, case extension "O " ring and rear oil seal and vacuum modulator service may be performed from underneath the vehicle without removing the Turbo Hydra-Matic 350; their service procedure is covered in the Overhaul Manual and is not repeated here. Refer to the Over­ haul Manual for all other service operations not covered here. The governor and intermediate clutch accumulator replacement procedure without removing transmission are different than Overhaul Manual. GOVERNOR (WITHOUT REMOVING TRANSMISSION) INTERMEDIATE CLUTCH ACCUMULATOR Remove 1. Remove two transmission oil pan bolts below the intermediate clutch cover. Install J-23069 in place of bolts removed. 2. Press in on cover and remove retaining ring. 3. Remove cover "O " ring seal, spring and intermedi­ ate clutch accumulator. Install Remove 1. Hoist vehicle disconnect speedometer transmission. 2. Remove governor cover retainer and cover. NOTE: Be careful not to damage cover "O " ring seal. 3. Remove governor. Inspect weights and freeness. 3. Install retainer. 4. Connect speedometer cable, lower vehicle and check transmission oil level. cable at governor and valve for Install 1. Install governor. 2. Install governor cover using a brass drift around the outside flange of the cover. NOTE: Do not distort cover on installation. Be sure "O " ring seal is not cut or damaged. 1. Install intermediate clutch accumulator piston. NOTE: Rotating piston slightly when install­ ing will help to get rings started in bore. 2. Position spring, "O " ring seal and cover in place. 3. Press in on cover with J-23069 and install retaining ring. 4. Remove tool and install oil pan bolts. STEEL TUBING REPLACEMENT If replacement of transmission steel tubing cooling lines is required, use only double wrapped and brazed steel tubing meeting GM specification 123M or its equivalent. Under no condition use copper or aluminum tubing to replace steel tubing. Those materials do not have satisfactory fatique durability to withstand normal vehicle vibrations. Steel tubing should be flared using the upset (double lap) flare method which is detailed in Section 5. D IA G N O S IS SEQUENCE FOR DIAGNOSIS 1. Check and correct fluid level. 2. Check detent cable adjustment. 3. Check and correct vacuum line and fittings. 4. Check and correct manual linkage. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 5. Road test vehicle. a. Install oil pressure gauge. b. Road test using all selective ranges, noting when discrepancies in operation or oil pressure occur. c. Attempt to isolate the unit or circuit involved in the malfunction. d. If engine performances indicates an engine tune-up is required, this should be performed before road testing is completed or transmission correction attempted. Poor engine performance can result in rough shifting or other malfunctions. OIL CHECKING PROCEDURES Before diagnosis of any transmission complaint is attempted, there must be understanding of oil checking procedure and what appearance the oil should have. Many times a transmission malfunction can be traced to low oil level, improper reading of dipstick, or oil appearance; therefore, a careful analysis of the condition of oil and the level may eliminate needless repairs. W hen checking oil level, proceed as follows: 1. Engine Running. 2. Vehicle on level surface. 3. Brakes applied. 4. Move lever through all ranges. 5. Place transmission in "PARK". 6. Check oil level. 7. If oil is low, check for possible causes. Level should be between the "A dd" and "Full" marks at normal operating temperature (180°F.) This temperature is obtained after at least 15 miles of expressway driving or equivalent city driving. If the transmission is not at operating temperature, the oil level should be approximately 1/4" below the "A dd" mark with the oil at approximately 70°F. (Room temperature.) If the oil level is correctly established at room temperature (70°F.), it should be at the "Full" mark on the dip stick when the transmission reaches normal operating temperature (180°F.). When the dipstick is removed, it should be noted whether the oil is devoid of air bubbles or not. Oil with air bubbles gives an indication of an air leak in the suction lines, which can cause erratic operation and slippage. W ater in the oil imparts a milky, pink cast to the oil and can cause spewing. Do not overfill transmission, as this will cause foaming and loss of oil through the vent pipe. CAUTION: 7 A -35 OIL LEAK DIAGNOSIS Determining Source of Oil Leak Before attempting to correct an oil leak, the actual source of the leak must be determined. In many cases, the source of the leak can be deceiving due to "wind flow" around the engine and transmission. The suspected area should be wiped clean of all oil before inspecting for the source of the leak. Red dye is used in the transmission oil at the assembly plant and will indicate if the oil leak is from the transmission. The use of a "Black Light" to locate the point at which the oil is leaking is helpful. Comparing the oil from the leak to that on the engine or transmission dipstick, when viewed by black light, will determine the source of the leak - engine or transmission. Oil leaks around the engine and transmission are generally carried toward the rear of the vehicle by air stream. For example, a transmission oil filler tube to case leak will sometimes appear as a leak at the rear of the transmission. In determining the source of a leak, proceed as follows: 1. Degrease underside of transmission. 2. Road test to get unit at operating temperature. 3. Inspect for leak with engine running. 4. With engine off, check for oil leaks due to the raised oil level caused by drain back. Possible Points of Oil Leak 1. Transmission Oil Pan Leak. a. Attaching bolts not correctly torqued. b. Improperly installed or damaged pan gasket. c. Oil pan gasket mounting face not flat. 2. Extension Housing. a. Attaching bolts not correctly torqued. b. Rear seal assembly damaged or improperly installed. c. Square seal, extension to case, damaged or improperly installed. d. Porous casting. See subparagraph C. 3. Case Leak. a. Filler pipe "O " ring seal damaged or missing; misposition of filler pipe bracket to engine. b. Modulator assembly "O " ring seal damaged or improperly installed. c. Detent cable connector "O " ring seal damaged or improperly installed. d. Governor cover not tight, gasket damaged or leak between case face and gasket. e. Speedometer gear "O " ring damaged. f. Manual shaft seal damaged or improperly installed. g. Line pressure tap plug loose. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -3 6 A U TO M A T IC T R A N S M IS S IO N h. Vent pipe (refer to item 5). i. Porous casting. See Subparagraph C. 4. Leak at Front of Transmission. a. Front pump seal leaks. 1. Seal lip cut. Check converter hub, etc. 2. Bushing moved and damaged, Oil return hole plugged. 3. No oil return hole. b. Front pump attaching bolts loose or bolt washer type seals damaged or missing. c. Front pump housing "O " ring damaged or cut. d. Converter leak in weld area. e. Porous casting (pump). 5. Oil Comes Out Vent Pipe. a. Transmission over-filled. b. W ater in oil. c. Foreign material between pump and case or between pump cover and body. d. Case - porous near converter bosses. Front pump cover or housing oil channels shy or stock near breather. See Subparagraph C. e. Pump to case gasket mis-positioned. OIL PRESSURE CHECK While vehicle is stationary (service brake on), engine speed set to 1200 rpm, transmission oil pressure gauge attached, and vacuum modulator tube disconnected, the transmission line should check as shown in Figure 31M. While vehicle is stationary (service brake on), engine speed set to maintain 12 inches hg absolute manifold pressure, transmission oil pressure gauge attached, and vacuum modulator tube connected, the transmission line should check as shown in Figure 32M. CASE POROSITY REPAIR External oil leaks caused by case porosity can be Approximate Altitude of Check (Ft. Above Sea Level) 0 2000 4000 6000 8000 307 V-8 & '350 V-8 250 L-6 Drive Neutral Park LI or L2 Reverse Drive Neutral Park LI or L2 Reverse 173 163 154 146 138 166 159 152 146 141 262 248 254 221 210 167 158 149 141 133 166 159 152 146 140 254 240 226 213 202 Fig. 31M—Oil Pressure Check Approximate Altitude of Check (Ft. Above Sea Level) 0 2000 4000 6000 8000 Relative Engine Vacuum (” Hsg.) 13.92 11.83 9.86 7.96 6.23 250 L-6 307 V-8 & 350 V-8 Drive LI Drive LI Neutral or Reverse Neutral or Reverse Park L2 Park L2 79 84 55 85 105 129 63 108 134 85 96 88 91 109 72 91 110 138 79 97 120 94 112 142 86 102 131 96 113 146 Fig. 32M—Oil Pressure Check successfully repaired with the transmission in the vehicle by using the following recommended procedures: 1. Road test and bring the transmission to operating temperature, approximately 180 degrees F. 2. Raise vehicle on a hoist or jack stand, engine running, and locate source of oil leak. Check for oil leaks in Low, Drive, and Reverse. 3. Shut engine off and thoroughly clean area to be repaired with a suitable cleaning solvent and a brush - air dry. A clean, dry soldering acid brush can be used to clean the area and also to apply the epoxy cement. 4. Using instructions of the manufacturer, mix a sufficient amount of epoxy to make the repair. Make certain the area to be repaired is fully covered. 5. Allow cement to cure for 3 hours before starting engine. 6. Road test and check for leaks. VACUUM MODULATOR DIAGNOSIS A defective vacuum modulator can cause one or more of the following complaints. 1. Harsh upshifts and downshifts. 2. Delayed upshifts. 3. Soft upshifts and downshifts. 4. Slips in low, drive and reverse. 5. Transmission overheating. 6. Engine burning transmission oil. If any one of the above complaints are encountered, the modulator must be checked. Vacuum Diaphragm Leak Check Insert a pipe cleaner into the vacuum connector pipe as far as possible and check for the presence of transmission oil. If oil is found, replace the modulator. Gasoline or water vapor may settle in the vacuum side of the modulator. If this is found without the presence of LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7A-37 oil, the modulator is serviceable and should not be changed. Atmospheric Leak Check Apply a liberal coating of soap bubble solution to the vacuum connector pipe seam, the crimped upper to lower housing seam (Fig. 33M). Using a short piece of rubber tubing, apply air pressure to the vacuum pipe by blowing into the tube and observe for leak bubbles. If bubbles appear, replace the modulator. NOTE: Do not use any method other than human lung power for applying air pressure, as pressures over 6 psi may damage the modulator. H OLD M O D U L A T O R S IN A H O R IZ O N T A L P O S I T I O N , A S S H O W N , B RIN G THEM S L O W L Y TO GE TH ER UNDER PRESS URE Fig. 35M—Checking Bellows Load Bellows Comparison Check Using a comparison gauge, as shown in Fig. 34M, compare the load of a known good Turbo Hydra-Matic 350 modulator with the assembly in question. a. Install the modulator that is known to be acceptable on either end of the gauge. b. Install the modulator in question on the opposite end of the gauge. c. Holding the modulators in a horizontal position, bring them together under pressure until either modulator sleeve end just touches the line in the center of the gauge. The gap between the opposite modulator sleeve end and the gauge line should then be 1/16" or less. If the distance is greater than this amount, the modulator in question should be replaced. (Figs. 35M, 36M, and 37M). Sleeve Alignment Check Roll the main body of the modulator on a flat surface and observe the sleeve for concentricity to the cam. If the sleeve is concentric and the plunger is free, the modulator is acceptable. Fig. 37M—Modulator Bellows Good LIGHT DUTY TRUCK SERVICE MANUAL 7 A -3 8 A U TO M A T IC T R A N S M IS S IO N Once the modulator assembly passes all of the above tests, it is an acceptable part and should be re-used. TRANSMISSION CLUTCH PLATES DIAGNOSIS 1. Lined Drive Plates. a. Dry plates with compressed air and inspect the lined surface for: 1. pitting and flaking 2. wear 3. glazing 4. cracking 5. charring 6. chips or metal particles imbedded in lining. If a lined drive plate exhibits any of the above conditions, replacement is required. Do not diagnose drive plates by color. 2. Steel Driven Plates Wipe plates dry and check for heat discoloration. If the surface is smooth and an even color smear is indicated, the plate should be reused. If severe heat spot discoloration or surface scuffing is indicated, the plate must be replaced. 3. Clutch Release Springs Evidence of extreme heat or burning in the area of the clutch may have caused the springs to take a heat set and would justify replacement of the springs. CAUSES OF BURNED CLUTCH PLATES 1. FORWARD CLUTCH a. Check ball in clutch housing damaged, stuck or missing. b. Clutch piston cracked, seals damaged or missing. c. Low line pressure. d. Pump cover oil seal rings missing, broken or undersize; ring groove oversize. e. Case valve body face not flat or porosity between channels. 2. INTERMEDIATE CLUTCH a. Intermediate clutch piston seals damaged or missing. b. Low line pressure. c. Case valve body face not flat or porosity between channels. 3. DIRECT CLUTCH a. Restricted orifice in vacuum line to modulator (poor vacuum response). b. Check ball in direct clutch piston damaged, stuck or missing. c. Defective modulator bellows. d. Clutch piston seals damaged or missing. e. Case valve body face not flat or porosity between channels. f. Clutch installed backwards. NOTE: Burned clutch plates can be caused by incorrect usage of clutch plates. Also, anti­ freeze in transmission fluid can cause severe damage, such as large pieces of composition clutch plate material peeling off. GOVERNOR PRESSURE CHECK 1. Install line Pressure Gage. 2. Disconnect vacuum line to moldulator. 3. With vehicle on hoist (rear wheels, off ground), foot off brake, in drive, check line pressure at 1000 RPM. 4. Slowly increase engine RPM to 3000 RPM and determine if a line pressure drop occurs (7 PSI or more). 5. If not pressure drop occurs: a. Inspect Governor 1. Stuck valve. 2. Free Weights. 3. Restricted orifice in governor valve. b. Governor Feed System 1. Check screen in control valve assembly. 2. Check for restrictions in feed line. 3. Scored governor bore. MANUAL LINKAGE Manual linkage adjustment and the associated neutral safety switch are im portant from a safety standpoint. The neutral safety switch should be adjusted so that the engine will start in the Park and Neutral positions only. With the selector lever in the Park position, the parking pawl should freely engage and prevent the vehicle from rolling. The pointer on the indicator quadrant should line up properly with the range indicators in all ranges. ROAD TEST Drive Range Position selector lever in DRIVE RANGE and accelerate the vehicle from 0 MPH. A 1-2 and 2-3 shift should occur at all throttle openings. (The shift points will vary with the throttle opening). As the vehicle decreases in speed to 0 MPH, the 3-2 and 2-1 shifts should occur. Low L2 Range Position the selector lever in L2 RANGE and accelerate LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7 A -39 Reverse Range: (R) Position the selector lever in REVERSE POSITION and check for reverse operation. TROUBLE DIAGNOSIS C O O L E R O IL FROM R A D IA T O R 1-2 C LU T C H (IN T E R M E D IA T E ) P R ES SU R E TAP C O O L E R O i l TO R A D IA T O R G O VERN O R P R ES S U R E TAP D E TE N T C O N T R O L V A L V E W IR E H O L E j 2-3 C LU T C H (D IR E C T ] P R ES S U R E TAP LIN E P R ES SU R E T A P 1 Fig. 38M—Pressure Tap Locations the vehicle from 0 MPH. A 1-2 shift should occur at all throttle openings. (No. 2-3 shift can be obtained in this range). The 1-2 shift point will vary with throttle opening. As the vehicle decreases in speed to 0 MPH, a 2-1 shift should occur. The 1-2 shift in INTERMEDIATE RANGE is somewhat firmer than in DRIVE RANGE. This is normal. Low LI Range Position the selector lever in LI RANGE and accelerate the vehicle from 0 MPH. No upshift should occur in this range. 2ND Gear — Overrun Braking: (L2) Position the selector lever in DRIVE RANGE, and with the vehicle speed at approximately 35 MPH, move the selector lever to L2 RANGE. The transmission should downshift to 2nd. An increase in engine RPM and an engine braking effect should be noticed. Line pressure should change from approximately 100 PSI to approxi­ mately 125 PSI in 2nd. 1ST Gear — Overrun Braking: (L I) Position the selector lever in L2 RANGE at approxi­ mately 30 to 50 MPH, with throttle closed, move the selector lever to LI. A 2-1 downshift should occur in the speed range of approximately 45 to 30 MPH, depending on axle ratio and valve body calibration. The 2-1 downshift at closed throttle will be accompanied by increased engine RPM and an engine braking effect should be noticed. Line pressure should be approxi­ mately 150 PSI. Stop vehicle. Refer to Diagnosis Chart to determine a possible cause of a transmission problem. Additional diagnosis of a malfunction is as follows: No Drive in Drive Range (Install pressure gauge) • Low Oil Level - correct level and check for external leaks or defective vacuum modulator (leaking diaphragm will evacuate oil from unit). • Manual Linkage - misadjusted, correct alignment to manual lever shift quadrant is essential. • Low Oil Pressure - refer to LOW LINE PRESSURE below. • Forward Clutch: a. Forward clutch does not apply - piston cracked; seals missing or damaged; clutch plates burned (see BURNED CLUTCH PLATES below). b. Pump feed circuit-to-forward clutch oil seal rings missing or broken on pump cover; leak in feed circuits; pump-to-case gasket mispositioned or damaged; clutch drum ball check stuck or missing. • Low and Reverse Roller Clutch Assembly - broken spring, damaged cage or installed backwards. High or Low Oil Pressure (Refer to OIL PRESSURE CHECKS) High Line Pressure • Vacuum Leak: a. Vacuum line disconnected. b. Leak in line from engine to moldulator. c. Improper engine vacuum. d. Leak in vacuum-operated accessory (hoses, vacuum advance, etc.). • Moldulator: a. Stuck modulator valve. b. W ater in modulator. c. Damaged, not operating properly. • Detent System - detent valve or cable stuck in detent position. • Valve Body: a. Pressure regulator and/or boost valve stuck. b. Boost valve sleeve broken or defective. c. Incorrect pressure regulator valve spring. LIGHT DUTY TRUCK SERVICE MANUAL R O AD TEST POSSIBLE CAUSE LIGHT DUTY TRUCK SERVICE M ANUAL LOW O IL L E V E L/W A TE R IN O IL V A C U U M LEAK M O D U L A T O R & /O R V A LV E S T R A IN E R & /O R GASKET GOVE R N O R -V A L V E /S C R E E N V A L V E B O D Y -G A S K E T /P L A T E PRES. REG. & / OR BOOST V A L V E BALL (# 1 ) SHY 1-2 S H IF T V A LV E 2-3 S H IF T V A L V E M A N U A L LOW C O N T'L. V A L V E D E TE N T V A L V E & LIN K A G E D E TE N T REG. V A LV E 2-3 A C C U M U LA TO R M A N U A L V A L V E /L IN K A G E P O R O SITY /CROSS LEAK P U M P -G E A R S P R IM IN G V A L V E SHY C OOLER V A L V E LEA K C LU TC H SEAL RINGS P OROUS/CROSS LEA K G A SK ET SC R E E N -P R ES S U R E B A N D —IN T E R M . O.R. C A S E -P O R O U S /X LEAK 1-2 A C C U M U LA TO R IN T E R M E D . SERVO FO R W A R D C LU TCH ASS'Y D IR E C T C LUTCH ASS'Y IN T E R M E D . CL. ASS'Y L & R EV. CL. ASS'Y IN T . R O LLER CL. ASS'Y L. & R. R O LLER CL. ASS'Y PARK P A W L /L IN K A G E C O N V ER TER ASS'Y GEAR SET & BEARINGS T R A N S M IS S IO N LEGEND X -P R O B L E M A R EA VS. CAUSE * " O" V A C U U M O N LY O —B A L L S /# 2 /3 /4 ON LY L -L O C K E D S -S T U C K AUTOMATIC PROBLEM 7A-40 Turbo Hydra-Matic 350 Diagnosis Chart A U T O M A T IC T R A N S M IS S IO N Low Line Pressure • Low transmission oil level. • Defective vacuum moldulator assembly. • Strainer Assembly: a. Blocked or restricted. b. Gasket omitted or damaged. • Oil Pump: a. Gear clearance, damaged, worn, gear installed backwards: b. Pump-to-case gasket mispositioned. c. Defective pump body and/or cover. • Valve Body: a. Pressure regulator or boost valve stuck. b. Pressure regulator valve spring, too weak. • Internal Circuit Leaks: a. Forward clutch leak (pressure low in Drive range, pressure normal in Neutral and Reverse). 1. Check pump oil seal rings. 2. Check forward clutch seals. b. Direct clutch leak (pressure low in Reverse, pressure normal in other ranges). 1. Check direct clutch outer seal. 2. Check 1-2 accumulator and 2-3 accumulator pistons and rings for damage or missing. • Case Assembly - check ball missing from cored passage in case face. 1-2 Shift * Full Throttle Only • Detent Valve - sticking or linkage misadjusted. • Vacuum Leak - vacuum line or fittings leaking. • Control Valve Assembly: a. Valve body gaskets - leaking, damaged or incorrectly installed. b. Detent valve train stuck. c. 1-2 valve stuck closed (in downshifted position). • Case Assembly - refer to case porosity repair. First Speed Only - No 1-2 Shift • Detent (downshift) cable - binding. • Governor Assembly: a. Governor valve sticking. b. Driven gear loose, damaged or worn (check for pin in case and length of pin showing; also, check output shaft drive gear for nicks or rough finish if driven gear shows damage). • Control Valve Assembly: a. Valve body gaskets - leaking, damaged or incorrectly installed. 7A-41 b. Governor feed channels blocked. c. 1-2 shift valve train stuck closed (in downshifted position). • Intermediate Clutch: a. Clutch piston seals - missing, im properly installed or cut. b. Intermediate roller clutch - broken spring or damaged cage. • Case: a. Porosity between channels. b. Governor feed channel blocked; governor bore scored or worn, allowing cross pressure leak. First and Second Speeds Only - No 2-3 Shift • Control Valve Assembly: a. Valve body gaskets - leaking, damaged or incorrectly installed. b. 2-3 shift valve train stuck closed (in downshifted position). • Direct Clutch: a. Pump hub - direct clutch oil seal rings - broken or missing. b. Clutch piston seals - missing, improperly assembled or cut. c. Clutch plates burned (see BURNED CLUTCH PLATES below). No First Speed - Starts in Second Speed (Locks up in LI Range) Intermediate Clutch: 1. Too many plates in intermediate clutch pack. 2. Incorrect intermediate clutch piston. Drive in Neutral • Manual Linkage - misadjusted, (correct alignment in manual lever shift quadrant is essential). • Internal Linkage - manual valve disconnected or end broken. • Oil Pump - line pressure leaking into forward clutch apply passage. • Forward Clutch - incorrect clutch plate usage or burned clutches (see BURNED CLUTCH PLATES below). No Motion in Reverse or Slips in Reverse (Install pressure gauge) • Low Oil Level - add oil. • Manual Linkage - misadjusted (correct alignment in manual lever shift quadrant is essential). LIGHT DUTY TRUCK SERVICE MANUAL 7 A -4 2 A U TO M A T IC T R A N S M IS S IO N • Low Oil Pressure - refer to LOW LINE PRESSURE above. • Control Valve Assembly: a. Valve body gaskets - leaking, damaged or incorrectly installed. b. 2-3 shift valve train stuck open (in upshifted position). • Intermediate Servo - piston or pin stuck so intermediate overrun band is applied. • Low and Reverse Clutch - piston outer seal damaged or missing. • Direct Clutch: a. Outer seal damaged or missing. b. Clutch plates burned (see BURNED CLUTCH PLATES below). • Forward Clutch - clutch does not release (will cause DRIVE in NEUTRAL). Slips in All Ranges or Slips on Start (Install pressure gauge) • Low Oil Level - add oil. • Low Oil Pressure - refer to LOW LINE PRESSURE above. • Forward clutch: a. Clutch plates burned (see BURNED CLUTCH PLATES below). b. Pump cover oil seal rings broken or worn. i Case - cross leaks or porosity. Slipping 1-2 Shift (Install pressure gauge) • Low Oil Level - add oil. • Low Oil Pressure - refer to LOW LINE PRESSURE above. • 2-3 Accumulator - oil ring damaged or missing. • 1-2 Accumulator - oil ring damaged, missing or case bore damaged. • Pump-to-Case Gasket - mispositioned or damaged. • Intermediate Clutch: a. Piston seals damaged or missing. b. Clutch plates burned (See BURNED CLUTCH PLATES below). • Case - porosity between channels. Slipping 2-3 Shift (Install pressure gauge) • Low Oil Level - add oil. • Low Oil Pressure - refer to LOW LINE PRESSURE above. • Direct Clutch: a. Piston seals leaks, damaged or missing. b. Clutch plates burned (see BURNED CLUTCH PLATES below). c. Inspect for proper number and type of clutch plates. • Case - refer to case porosity repair. Rough 1-2 Shift (Install pressure gauge) • High Oil Pressure - refer to HIGH LINE PRESSURE above. • 1-2 Accumulator: a. Oil rings damaged. b. Piston stuck. c. Broken or missing spring. d. Bore damaged. • Intermediate Clutch - check for burned and number (type) of plates. • Case: a. Check for correct number and location of check balls. b. Porosity between channels. Rough 2-3 Shift (Install pressure gauge) • High Oil Pressure - refer to HIGH LINE PRESSURE above. • 2-3 Accumulator: a. Oil ring damaged. b. Piston stuck. c. Broken or missing spring. d. Piston bore damaged. No Engine Braking in L2 (Install pressure gauge) • Low Oil Pressure - pressure regulator and/or boost valve stuck. • Intermediate Servo and 2-3 Accumulator: a. Servo or accumulator oil rings or bores leaking or damaged. b. Servo piston stuck or cocked. • Intermediate Overrun Band - intermediate overrun band broken or burned (look for cause), not engaged or servo pin. No Engine Braking in LI (Install pressure gauge) • Low Oil Pressure - pressure regulator and/or boost valves stuck. • Manual Low Control Valve Assembly - stuck. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N • Low and Reverse Clutch - piston inner seal damaged or missing. No Part Throttle Downshift (Install pressure gauge) • Oil Pressure - vacuum modulator assembly, modulator valve or pressure regulator valve train (other malfunctions may also be noticed). • Detent Valve and Linkage - sticks, disconnected or broken. • 2-3 shift valve - stuck. No Detent (Wide Open Throttle) Downshift • Detent cable or retainer not adjusted properly. • Detent cable disconnected at transmission or throttle linkage. • Valve Body: a. Detent valve sticks. b. Detent regulator valve sticks. c. Incorrect spacer plate or gasket. High or Low Shift Points (Install pressure gauge) • Oil Pressure: a. Engine Vacuum - check at transmission end of modulator pipe. b. Check vacuum line connections at engine and transmission. c. Vacuum modulator assembly and valve and pressure regulator valve train. • Governor: a. Valve sticking. b. Feed holes restricted or leaking. • Detent Valve and Linkage - stuck open (will cause high shift points). • Control Valve Assembly: a. 1-2 shift valve train sticking. b. 2-3 shift valve train sticking. • Case - refer to case porosity repair. Won’t Hold in Park • Manual Linkage - misadjusted (correct alignment in manual lever shift quadrant is essential). • Internal Linkage: a. Inner lever and actuating rod assembly defective or improperly installed. 7A-43 b. Parking pawl - broken or inoperative. c. Parking lock bracket loose, burred or rough edges or incorrectly installed. d. Parking pawl disengaging spring missing, broken or incorrectly hooked. Transmission Noisy CAUTION: Before checking transmission for noise, make certain that the noise is not coming from the water pump, alternator, power steering, etc. These components can be isolated by removing the proper belt and running the engine not more than two minutes at one time. Park, Neutral and all Driving Ranges • Pump Cavitation: a. Low oil level. b. Plugged or restricted strainer. c. Strainer-to-valve body gasket damaged. d. Porosity in valve body intake area. e. W ater in oil. f. Porosity or voids at transmission case (pump face) intake port. g. Pump-to-case gasket off location. • Pump Assembly: a. Gears damaged. b. Driving gear assembled backwards. c. Crescent interference. d. Oil seal rings damaged or worn. • Converter: a. Loose flexplate-to-converter bolts. b. Converter damage. c. W ater in oil (causes whine). First, Second and /o r Reverse Gear Planetary Gear Set: 1. Gears or thrust bearings damaged. 2. Input or output ring gear damaged. During Acceleration - Any Gear • Transm ission or cooler lines grounded underbody. • Motor mounts loose or broken. to Squeal at Low Vehicle Speed Speedometer driven gear shaft seal - requires lubrication or replacement. LIGHT DUTY TRUCK SERVICE MANUAL 7A-44 AUTOM ATIC TRANSM ISSION TURBO HYDRA-MATIC 4 0 0 /4 7 5 TRANSMISSION INDEX General D escription....................................................... Theory of O peration...................................................... Hydraulic System - Functions of Values and Hydraulic Control U n it................................................. Hydraulic Oil System................................................... Maintenance and Adjustment..................................... Checking Transmission M ount................................. Transmission Fluid....................................................... Column Shift Linkage Adjustment......................... Detent Switch Adjustm ent.......................................... Neutral Start Backup Lamp Switch Adjustment. Service O perations........................................................... Pressure Regulator Valve............................................ Control Valve Body...................................................... G overnor............................................................................ 7A-44 7A-45 7A-45 7A-54 7A-72 7A-72 7A-72 7A-73 7A-74 7A-74 7A-75 7A-75 7A-75 7A-75 Modulator and Modulator Valve.............................. Parking Linkage - 10, 20 Series.............................. Rear S eal.......................................................................... Other Service Operations............................................ Transmission Replacem ent......................................... Diagnosis............................................................................. Sequence for Diagnosis............................................... Oil Checking Procedure.............................................. Oil Leak D iagnosis....................................................... Oil Pressure Check........................................................ Case Porosity R epair.................................................... Vacuum Modulator Diagnosis................................... Manual Linkage............................................................. Trouble Diagnosis.......................................................... Special Tools...................................................................... 7A-75 7A-76 7A-76 7A-76 7A-76 7A-77 7A-77 Ik-11 7A-77 7A-78 7A-78 7A-78 7A-80 7A-80 7A-87-88 GENERAL DESCRIPTION The Turbo Hydra-Matic 400/475 transmission is a fully automatic unit consisting primarily of a 3-element hydraulic torque converter and a compound planetary gear set. Three multiple-disc clutches, one gear unit, one roller clutch, and two bands provide the friction elements required to obtain the desired function of the compound planetary gear set. The torque converter couples the engine to the planetary gears through oil and provides hydraulic torque multiplication when required. The compound planetary gear set produces three forward speeds and reverse. The 3-element torque converter consists of a pump or driving member, a turbine or driven member, and a stator assembly. The stator is mounted on a one-way roller clutch which will allow the stator to turn clockwise but not counter-clockwise. The torque converter housing is filled with oil and is attached to the engine crankshaft by a flex plate and always rotates at engine speed. The converter pump is an integral part of the converter housing, therefore the pump blades, rotating at engine speed, set the oil within the converter into motion and direct it to the turbine, causing the turbine to rotate. As the oil passes through the turbine it is traveling in such a direction that if it were not re-directed by the stator it would hit the rear of the converter pump blades and impede its pumping action. So at low turbine speeds, the oil is re-directed by the stator to the converter pump in such a manner that it actually assists the converter pump to deliver power or multiply engine torque. As turbine speed increases, the direction of the oil leaving the turbine changes and flows against the rear side of the stator vanes in a clockwise direction. Since the stator is now impeding the smooth flow of oil, its roller clutch releases and it revolves freely on its shaft. Once the stator becomes inactive, there is no further multiplication of engine torque within the converter. At this point, the converter is merely acting as a fluid coupling as both the converter pump and turbine are being driven at approximately the same speed - or at one-to-one ratio. A hydraulic system pressurized by a gear type pump provides the working pressure required to operate the friction elements and automatic controls. External control connections to transmission are: Manual Linkage - To select the desired operating range. Engine Vacuum - To operate a vacuum modulator unit. 12 Volt Electrical - To operate an electrical detent solenoid. A vacuum modulator is used to automatically sense any change in the torque input to the transmission. The vacuum modulator transmits this signal to the pressure regulator for line pressure control, to the 1-2 accumulator valve, and to the shift valves so that all torque requirements of the transmission are met and smooth shifts are obtained at all throttle openings. The detent solenoid is activated by an electric switch on the carburetor. When the throttle is fully opened, the switch on the carburetor is closed, activating the detent solenoid and causing the transmission to downshift for passing speeds. The selector quadrant has six selector positions: P, R, N, D, L2, LI. P. PARK position positively locks the output shaft to the transmission case by means of a locking pawl to LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N R. N. D. L2. prevent the vehicle from rolling in either direction (not on CL model). The engine may be started in Park position. REVERSE enables the vehicle to be operated in a reverse direction. Neutral postion enables the engine to be started and run without driving the vehicle. DRIVE Range is used for all normal driving conditions and maximum economy. Drive Range has three gear ratios, from the starting ratio to direct drive. Detent downshifts are available by depressing the accelerator to the floor. L2 Range has the same starting ration as Drive Range, but prevents the transmission from shifting ration when extra performance is desired. L2 Range can also be used for engine braking. L2 Range can be selected at any vehicle speed, and the 7A -45 transmission will shift to second gear and remain in second until the vehicle speed or the throttle are changed to obtain first gear operation in the same manner as in D Range. LI. LI Range can be selected at any vehicle speed, and the transmission will shift to second gear and remain in second until vehicle is reduced to approximately 40 MPH, depending on axle ratio. LI Range position prevents the transmission from shifting out of first gear. NOTE: It is very important that any communication concerning the Turbo HydraMatic 400/475 always contain the transmision serial and vehicle identification number. THEORY OF OPERATION MECHANICAL POWER FLOW Refer to figures IT through 6T for related mechanical power flow. Each figure explains what component is applied or related in each stage of transmission operation. HYDRAULIC SYSTEM FUNCTIONS OF VALVES AND HYDRAULIC CONTROL UNITS Pressure Control (Fig. 7T) The transmission is automatically controlled by a hydraulic system. Hydraulic pressure is supplied by the transmission gear type oil pump, which is engine driven. M ain line pressure is controlled by a pressure regulator valve train located in the pump. This regulator controls line pressure automatically, in response to a pressure signal from a modulator valve, in such a way that the torque requirements of the transmission are met and smooth shifts are obtained at all throttle openings. To control line pressure properly, modulator pressure is used which varies in the same manner as torque input to the transmission. Since the converter torque output is the product of engine torque and converter ratio, modulator pressure must compensate for changes in either or both of these. To meet these requirements, modulator pressure is regulated by engine vacuum which is an indicator of engine torque and carburetor opening. It is decreased by governor pressure with increase in vehicle speed because converter torque ratio also decreases. Pressure Regulator Valve (Fig. 7T) 1. Regulates line pressure according to a fixed spring force and forces controlled by modulator and reverse pressure. 2. Controls the flow of oil that charges the torque converter, feeds the oil cooler and provides lubrication for the transmission. Vacuum Modulator Assembly (Fig. 8T) The engine vacuum signal is provided by the vacuum modulator, which consists of an evacuated metal bellows, a diaphragm and two springs. These are so arranged that when installed, the bellows and its external spring apply a force which acts on the modulator valve. This force acts on the modulator valve so that it increases modulator pressure. Engine vacuum and the internal spring act in the opposite direction to decrease modulator, or low engine vacuum high modulator pressure; high engine vacuum, and low modulator pressure. To reduce the effect of altitude on shift points, the effective area of the diaphragm is made somewhat larger than that of the bellows. Atmospheric pressure then acts on the resulting differential area to reduce modulator pressure. Governor Assembly (Fig. 9T) The vehicle speed signal to the modulator valve is supplied by the transmission governor, which is driven by the output shaft. The governor consists of two flyweights and a regulator valve. Centrifugal force of the flyweights is imposed on the regulator valve causing it to regulate a pressure signal that increases with speed. To increase the accuracy of the governor signal at low speeds, the flyweights are so designed that their effective mass is greater at speeds below approximately 720 output RPM than it is above this speed. This is done by dividing each flyweight into two parts and arranging them so that the prim ary weights act through preloaded springs on the secondary weights, LIGHT DUTY TRUCK SERVICE MANUAL 7 A -4 6 A U TO M A T IC T R A N S M IS S IO N a. Operation o f Components in Drive Range — First Gear INTERMEDIATE CLUTCH OFF LOW ROLLER CLUTCH EFFECTIVE FRONT BAND OFF DIRECT CLUTCH OFF REAR BAND OFF FORWARD W ith the selector lever in Drive Range, the forward clutch is applied. This delivers turbine torque to the mainshaft and turns the rear internal gear in a clockwise direction. (Converter torque ratio = approxim ately 2.: 1. at stall). Clockwise m otion o f the rear internal gear causes the rear pinions to tu rn clockwise to drive the sun gear counterclockwise. In turn, the sun gear drives the fro n t pinions clockwise, thus turning the fro n t internal gear, o u tp u t carrier, and o u tp u t shaft clockwise in a reduction ratio o f approxim ately 2.5:1. The reaction of the fro n t pinions against the fro n t internal gear is taken by the reaction carrier and one-way roller clutch assembly to the transmission case. (A pproxim ate stall ratio = 5.: 1.) Fig. IT —Drive Range - First Gear LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N b. 7A-47 Operation o f Components in Drive Range — Second Gear INTERMEDIATE CLUTCH O N FRONT BAND OFF INTERMEDIATE ROLLER CLUTCH EFFECTIVE DIRECT CLUTCH OFF LOW ROLLER CLUTCH INEFFECTIVE FORWARD CLUTCH O N In second gear, the interm ediate clutch is applied to a llow the interm ediate ro lle r clutch to hold the sun gear against counterclockw ise ro ta tio n . T u rb in e torque through the forw ard clu tch is now applied through the m ainshaft to the rear internal gear in a clockwise d ire ction . Clockwise ro ta tio n o f the rear internal gear turns the rear pinons clockwise against the sta­ tio n a ry sun gear. This causes the o u tp u t carrier and o u tp u t shaft to tu rn clockwise in a reduc­ tio n ratio o f a pp ro xim a te ly 1.5:1. Fig. 2T—Drive Range - Second Gear LIGHT DUTY TRUCK SERVICE MANUAL 7 A -4 8 A U TO M A T IC T R A N S M IS S IO N c. Operation o f Components in Drive Range — T hird Gear IN T E R M E D IA T E R O LLER C LU TC H IN E F F E C T IV E INTERMEDIATE CLUTCH ON FRONT BAND OFF LOW ROLLER CLUTCH OFF DIRECT CLUTCH O N In direct drive, engine torque is transm itted to the converter through the forward clutch to the mainshaft and rear internal gear. Because the direct clutch is applied, equal power is also trans­ m itted to the sun gear shaft and the sun gear. Since both the sun gear and internal gears are now turning at the same speed, the planetary gear set is essentially locked and turns as one u n it in direct drive or a ratio o f 1:1. Fig. 3T—Drive Range - Third Gear LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N d. 7 A -49 O peration o f Components in Low — L 2 Range — Second Gear INTERMEDIATE ROLLER CLUTCH EFFECTIVE FRONT BAND O N INTERMEDIATE CLUTCH ON LOW ROLLER CLUTCH INEFFECTIVE DIRECT CLUTCH OFF In second gear, the interm ediate clu tch is applied to a llow the interm ediate ro lle r clu tch to hold the sun gear against co unterclockw ise ro ta tio n . T u rb in e to rq u e through the forw ard clutch is now applied through the m ainshaft to the rear internal gear in a clockw ise d ire ctio n . Clockwise ro ta tio n o f the rear internal gear turns the rear pinions clockw ise against the sta­ tio n a ry sun gear. This causes the o u tp u t carrier and o u tp u t shaft to tu rn clockwise in a reduc­ tio n ra tio n o f a p p ro xim a te ly 1.5:1. In L n fix e d . Range second gear, overrun braking is provided by the fro n t band as it holds the sun gear W ith o u t the band applied, the sun gear w o u ld overrun the interm ediate ro lle r clutch. Fig. 4T—L2 Range ■ Second Gear LIGHT DUTY TRUCK SERVICE MANUAL 7 A -5 0 A U T O M A T IC T R A N S M IS S IO N e. Operation o f Components in Low — L 1 Range — First Gear INTERMEDIATE CLUTCH OFF FRONT BAND OFF INTERMEDIATE ROLLER CLUTCH INEFFECTIVE LOW ROLLER CLUTCH EFFECTIVE REAR BAND O N W ith the selector lever in L 1 Range, the forward clutch is applied. This delivers turbine torque to the mainshaft and turns the rear internal gear in a clockwise direction. (Converter torque ratio = approxim ately 2.: 1. at stall.) Clockwise m otion o f the rear internal gear causes the rear pinions to tu rn clockwise to drive the sun gear counterclockwise. In turn, the sun gear drives the fro n t pinions clockwise, thus turning the fro n t internal gear, o u tp u t carrier, and o u tp u t shaft clockwise in a reduction ratio o f approxim ately 2.5:1. The reaction of the fro n t pinions against the fro n t internal gear is taken by the reaction carrier and the low ro lle r clutch. (Total stall ra tio = a p p ro xim a te ly 5.:1.) D ow nhill or overrun braking is provided in L 1 Range by applying the rear band as this prevents the reaction carrier fro m overrunning the low ro lle r clutch. Fig. 5T—LI Range • First Gear LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N f. 7A-51 Operation o f Components in Reverse INTERMEDIATE CLUTCH FRONT BAND INTERMEDIATE ROLLER CLUTCH INEFFECTIVE LOW ROLLER CLUTCH INEFFECTIVE DIRECT CLUTCH ON FORWARD In Reverse, the direct clutch is applied to direct turbine torque to the sun gear shaft and sun gear. The rear band is also applied, holding the reaction carrier. Clockwise torque to the sun gear causes the fro n t pinions and fro n t internal gear to turn counter­ clockwise in reduction. The fro n t internal gear is connected d ire ctly to the o u tp u t shaft, thus providing the reverse o u tp u t gear ratio o f approxim ately 2.:1. The approxim ate reverse torque m u ltip lica tio n at stall (converter and gear ratios) is approxim ately 4.: 1. Fig. 6T—Reverse LIGHT DUTY TRUCK SERVICE MANUAL 7 A -5 2 A U T O M A T IC T R A N S M IS S IO N LzMOD. OR INT. Fig. 7T—Pump and Pressure Regulator Valve DRIVEN GEAR SCREEN DRIVE GOV. PRIMARY WEIGHT SPRING VALVE SECONDARY WEIGHT which in turn acts on the valve. At approximately 720 RPM the centrifugal force on each primary weight exceeds the spring force and the primary weights move to a grounded stop. With the primary weights grounded, the force on the governor regulator valve is equal to the spring forces, plus the centrifugal force on the secondary weights. Governor pressure acts on the modulator valve to cause m odulator pressure to decrease as vehicle speed increases. Manual Valve (Fig. 10T) Establishes the range of transmission operation, i.e. P, R, N, D, L2, LI, as selected by the vehicle operator through the manual control lever. Modulator Valve (Fig. 8T) Regulates line pressure to modulator pressure that varies with torque to the transmission. It senses forces created by: L The vacuum modulator bellows that increases modulator pressure. 2. Engine vacuum acting on a diaphragm to decrease modulator pressure. 3. Governor pressure which is generated by the governor assembly. Governor pressure tends to decrease modulator pressure. Fig. 9T—Governor Assembly 1-2 Detent Valve (Fig. 11T) Senses regulated modulator pressure tending to hold the 1-2 shift valve in the downshift position and provides an area for detent pressure for detent 2-1 shifts. 2-3 Shift Valve (Fig. 12T) Controls the oil pressure that causes the transmission to shift from 2-3 or 3-2. Its operation is controlled by modulator, L2, governor and detent pressure as well as a spring force. LINE 1-2 Shift Valve (Fig. 11T) Controls the oil pressure that causes the transmission to shift from 1-2 or 2-1. Its operation is controlled by governor pressure, low oil pressure, detent pressure, modulator pressure, and spring force. Regulator Valve (Fig. 11T) Regulates modulator pressure to a pressure proportional to modulator pressure, tending to keep the 1-2 shift valve in the downshift position. Fig. 10T—Manual Valve LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7 A -53 G O V .H 1-2 VALVE Fig. 12T—2-3 Valve and 2-3 Modulator Valve Train (Typical) Fig. 1IT —1-2 Shift Valve and 1-2 Detent Valve and Regulator Valve (Typical) II I-' lL 2-3 Modulator Valve (Fig. 12T) Senses modulator pressure to apply a variable force proportional to modulator pressure which tends to hold the 2-3 shift valve downshifted. Q o fiftfiflflflflffflflrf ' DIRECT C LUTC h | 3-2 V A L V E 3-2 Valve (Fig. 13T) Shuts off modulator pressure from acting on the shift valve trains after the direct clutch has been applied. This allows fairly heavy throttle operation in third gear without downshifting. In third speed, modulator pressure or detent pressure above 87 psi will provide part throttle downshift forces. (Resulting in a 3-2 downshift at less than wide open throttle). d O £ 11 Fig. 13T-3-2 Valve Detent Valve (Fig. 14T) Shifts when line oil is exhausted at the end of the valve when the detent solenoid is energized, thus allowing the detent regulator valve to regulate. This directs detent pressure to the 1-2 accumulator valve, 1-2 regulator and 2-3 modulator valves, 3-2 valve, and the vacuum modulator valve. Detent Regulator Valve (Fig. 14T) W hen the detent valve shifts, the detent regulator is free to allow drive oil to enter the detent passage and thus becomes regulated to a value of 70 psi. Detent pressure will also flow into the modulator passage which flows to the 2-3 modulator valve, 3-2 valve and the 1-2 detent valve. LI oil moves the detent regulator open to drive oil allowing drive oil to enter the modulator and detent passages. M O DULATOR DETENT Q ...| P LU z _1 II R[EG. i_ n . ■ n h n m m f ------------ 1 tU C __ M O D .Z j 1= O _l 11= Fig. 14T—Detent Valve and Detent Regulator Valve LIGHT DUTY TRUCK SERVICE MANUAL 7 A - 5 4 A U T O M A T IC T R A N S M IS S IO N TO INT CL. Fig. 15T—Front Servo Front Servo (Fig. 15T) The front servo applies the front overrun band to provide engine braking in 2nd gear in L2 Range. It is also used as an accumulator for the application of the direct dutch and in conjunction with a series of check balls and controlling orifices is a part of the timing for the release of the direct clutch. To prevent the application of the front overrun band in Neutral, Drive and Reverse ranges, oil is directed from the manual valve to the release side of the servo piston. In Drive range the servo release oil from the manual valve also acts to charge the servo in preparation for the application of the direct clutch. Direct clutch oil is directed to the front servo accumulator piston where spring force plus direct clutch pressure stroke the piston up against the force of servo Fig. 16T—Rear Servo release oil. This lowers the clutch apply pressure during the shift for a smooth engagement. The release of the direct clutch and the exhausting of the front servo accumulator is slowed down by three check balls and three orifices which permits a soft return of the drive load to the intermediate roller clutch and also allows engine RPM to increase during a detent 3-2 downshift in preparation for the lower gear ratio, which results in a smooth shift and better acceleration. Rear Servo (Fig. 16T) The rear servo applies the rear band for overrun engine braking in LI range 1st gear. It applies the band in Reverse to hold the reaction carrier to provide the reverse gear ratio. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N CU o 1-2ACCUM 9 1-2 ACCUM Fig. 17T—1-2 Accumulator Valve Train (Typical) 7A-55 1-2 Accumulator (Fig. 17T) 1-2 accumulator oil charges the rear servo accumulator in 1st gear in preparation for the apply of the intermediate clutch on the 1-2 shift. The valve train consists of a 1-2 primary valve and spring, a 1-2 accumulator valve and spring and plug. 1-2 accumulator oil pressure is a two-stage pressure which increases as modulator pressure increases to obtain greater flexibility in obtaining the desired curve during the 1-2 shift for various engine requirements. HYDRAULIC OIL SYSTEM Refer to figure 18T through 25T for an explanation of the hydraulic oil system that applies the clutches and bands and controls the automatic shifting. LIGHT DUTY TRUCK SERVICE MANUAL 7A-56 TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL Fig. 18T—Neutral Range - Engine Idling Typical AUTOMATIC MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N Power Flow 7 A -57 NEUTRAL RANGE-ENGINE IDLING 6. Vacuum Modulator Valve 7. Front Servo (Neutral only) Forward Clutch - Off Roller Clutch - Ineffective Direct Clutch - Off Front Band - Off Rear Band - Off Intermediate Roller Clutch - Ineffective Detent Solenoid - De-energized In Neutral or Park, no bands or clutches are applied. Therefore no power is transmitted. Oil Flow Whenever the engine is running at idle with the selector lever in P or N, oil from the pump is directed to the: 1. Pressure Regulator Valve 2. Converter: a. Oil Cooler b. Lubrication System 3. Manual Valve 4. Detent Valve 5. Detent Solenoid Basic Control Oil flows from the pump to the pressure regulator valve which regulates pump pressure. When the pump output exceeds the demand of line pressure, oil from the pressure regulator is directed to the converter feed passage to fill the converter. Oil from the converter is directed to the transmission cooler. Oil from the cooler is directed to the transmission lubrication system. Line pressure acts on the: 1. Manual Valve 2. Detent Valve 3. Detent Solenoid 4. Modulator Valve 5. Front Servo Piston (Neutral Only) Line pressure at the modulator valve is re-regulated to modulator oil, which acts on the pressure boost valve and 1-2 accumulator valve train and passes through the detent valve and 3-2 valve to the 1-2 and 2-3 valve trains. Summary The converter is filled and all clutches and bands are released. The transmission is in Neutral or Park. LIGHT DUTY TRUCK SERVICE MANUAL 7A-58 TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL Fig. 19T—Drive Range - First Gear Typical AUTOMATIC MAINLINE PRESSURE I I INTAKE PRESSURE rTT! CONVERTER PRESSURE GOVERNOR PRESSURE rp ip MODULATOR PRESSURE I f DETENT PRESSURE I I 1-2 ACCUMULATOR PRESSURE I I A U T O M A T IC T R A N S M IS S IO N Power Flow 7A -59 DRIVE RANGE-FIRST GEAR manual lever is repositioned to allow line pressure to enter the drive circuit. Drive oil then flows to the: 1. Forward Clutch 2. 1-2 Shift Valve 3. Governor Assembly 4. 1-2 Accumulator Valve 5. Detent Regulator Valve Forward Clutch - On Low Roller Clutch - Effective Direct Clutch - Off Front Band - Off Rear Band - Off Intermediate Clutch - Released Intermediate Roller Clutch - Ineffective Detent Solenoid - De-energized With the selector lever in any forward range, the forward clutch is applied. This delivers turbine torque to the mainshaft and turns the rear internal gear in a clockwise direction, viewed from front (Converter torque ratio equals approximately 2:1 at stall). Clockwise motion of the rear internal gear causes the rear pinions to turn clockwise, driving the sun gear counterclockwise. In turn, the sun gear drives the front pinions clockwise, thus turning the front internal gear, output carrier and output shaft clockwise in a reduction ratio of approximately 2.5:1. Reaction of the front pinions against the front internal gear is taken by reaction carrier and roller clutch assembly to the transmission case (Approximate stall ratio equals 5:1). Oil Flow When the selector lever is moved to Drive position, the Basic Control Drive oil is directed to the foward clutch where it acts on two areas of the clutch piston to apply the forward clutch. The inner area is fed through an unrestricted passage. The outer area is fed through an orifice to insure a smooth shift from Park, Neutral and Reverse to Drive. Drive oil at the governor assembly is regulated to a variable pressure. This pressure increases with vehicle speed and acts against the ends of the 1-2 and 2-3 shift valves and an area on the modulator valve. This variable pressure is called governor pressure. Drive oil is also regulated to another variable pressure at the 1-2 accumulator valve. This pressure, called 1-2 accumulator oil, is controlled by modulator oil and is directed to the rear servo. 1-2 accumulator oil at the rear servo acts on the accumulator piston. Summary The converter is filled and the forward clutch is applied. The transmission is in Drive range - first gear. LIGHT DUTY TRUCK SERVICE MANUAL 7A-60 TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL Fig. 20T—Drive Range ■ Second Gear Typical AUTOMATIC MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N Power Flow 7A-61 DRIVE RANGE-SECOND GEAR pressure. This allows the 1-2 shift valve to open, permitting drive oil to enter the intermediate clutch passage. Intermediate clutch oil from the 1-2 shift valve is directed to the: 1. Intermediate Clutch 2. Rear Servo 3. Front Servo and Accumulator Pistons 4. 2-3 Shift Valve Forward Clutch - On Low Roller Clutch - Ineffective Direct Clutch - Off Front Band - Off Rear Band - Off Intermediate Clutch - On Intermediate Roller Clutch - Effective Detent Solenoid - De-energized In second gear, the intermediate clutch is applied to allow the intermediate roller to hold the sun gear against counterclockwise rotation. Turbine torque, through the forward clutch, is applied through the mainshaft to the rear internal gear in a clockwise direction. Clockwise rotation of the rear internal gear turns the rear pinions clockwise against the stationary sun gear. This causes the output carrier and output shaft to turn clockwise in a reduction ratio of approximately 1.5:1. Oil Flow As both vehicle speed and governor pressure increase, the force of governor oil acting on the 1-2 shift valve will overcome the force of re-regulated modulator oil Basic Control Intermediate clutch oil from the 1-2 shift valve seats a one-way check ball and flows through an orifice to the intermediate clutch piston to apply the intermediate clutch. At the same time, intermediate clutch oil moves the accumulator piston against the 1-2 accumulator oil. The accumulator spring maintains controlled pressure in the clutch during a 1-2 shift for a smooth clutch apply. Intermediate clutch oil seats a second one-way check ball and flows to the front servo and accumulator pistons. Intermediate clutch oil is also directed to a land of the 2-3 shift valve. Summary The forward and intermediate clutches are applied. The transmission is in second gear. LIGHT DUTY TRUCK SERVICE MANUAL 7A-62 TRANSMISSION LIGHT DUTY TRUCK SERVICE MANUAL Fig. 21T—Drive Range - Third Gear Typical AUTOMATIC MAINLINE PRESSURE HZJ INTAKE PRESSURE ZZ2 CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE I 1 DETENT PRESSURE C~T1 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N Power Flow 7A-63 DRIVE RANGE-THIRD GEAR Direct clutch oil from the 2-3 shift valve is directed to the: 1. Direct Clutch 2. Front Accumulator Piston 3. 3-2 Valve Forward Clutch - On Low Roller Clutch - Ineffective Direct Clutch - On Front Band - Off Rear Band - Off Intermediate Clutch - On Intermediate Roller Clutch - Ineffective Detent Solenoid - De-energized In direct drive, engine torque is transmitted to the converter through the forward clutch to the mainshaft and rear internal gear. Because the direct clutch is applied, torque is also transmitted to sun gear shaft and sun gear. Since both sun gear and internal gears are now turning at the same speed, the planetary gear set is essentially locked and turns as one unit in direct drive or a ratio of 1:1. Oil Flow As vehicle speed and governor pressure increase, force of governor oil acting on the 2-3 shift valve overcomes the force of 2-3 shift valve spring and modulator oil. This allows the 2-3 shift valve to move, feeding intermediate clutch oil to the direct clutch passage. Basic Control Direct clutch oil from the 2-3 shift valve flows past a one-way check valve to the inner area of the direct clutch piston to apply the direct clutch. Simultaneously, direct clutch oil is fed to the front accumulator piston. Pressure of the direct clutch oil, combined with the accumulator spring, moves the accumulator and servo pistons against servo oil. This acts as an accumulator for a smooth direct clutch apply. Direct clutch oil is also supplied to the 3-2 valve to move the valve against modulator pressure. This cuts off modulator oil to the 1-2 and 2-3 shift valve trains and allows the transmission to utilize the torque multiplying characteristics of the converter during medium throttle operation without downshifting. Summary The forward, intermediate and direct clutches are applied. The transmission is in third gear (direct drive). LIGHT DUTY TRUCK SERVICE MANUAL 7A-64 AUTOMATIC LIGHT DUTY TRUCK SERVICE MANUAL Fig. 22T—Detent Downshift (Valves in Second Gear Position) Typical P— \ CHJ I H r~ ~ l TRANSMISSION MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N 7A-65 DETENT DOWNSHIFT (Valves in Second Gear Position) 5. 1-2 Primary Accumulator Valve Power Flow 6. Vacuum Modulator Valve Forward Clutch - On Detent oil in the modulator passage and at the 2-3 Low Roller Clutch - Ineffective modulator valve will close the 2-3 valve, shifting the Direct Clutch - Off transmission to second gear (below approximately 70 Front Band - Off mph). Rear Band - Off A detent 2-1 downshift can also be accomplished below approximately 20 mph because detent oil is directed to Intermediate Clutch - On the 1-2 regulator valve. This allows detent oil to act on Intermediate Roller Clutch - Effective the 1-2 regulator and 1-2 detent valve to close the 1-2 shift valve, shifting the transmission to first gear. Detent Solenoid - Energized In second gear, the intermediate clutch is applied to To insure clutch durability during 1-2 upshifts under detent conditions, detent oil is directed to the 1-2 allow the intermediate roller to hold the sun gear against accumulator prim ary valve to increase 1-2 accumulator counterclockwise rotation. Turbine torque, through the forward clutch, is now applied through the m ainshaft to oil pressure acting on the rear servo accumulator piston. the rear internal gear in a clockwise direction. Detent oil is also directed to the modulator valve to Clockwise rotation of the rear internal gear turns the prevent modulator pressure from regulating below 70 psi at high speed or at high altitudes. rear pinions clockwise against the stationary sun gear. This causes the output carrier and output shaft to turn Part Throttle 3-2 Downshifts clockwise in a reduction ratio of approximately 1.5:1. Forward Clutch - On Oil Flow Low Roller Clutch - Ineffective While operating at speeds below approximately 70 mph, Direct Clutch - Off in 2nd a forced or detent 3-2 downshift is possible by Direct Clutch - On in 3rd depressing the accelerator fully. This engages an electrically operated switch and actuates the detent Front Band - Off solenoid. The detent solenoid opens an orifice that allows Rear Band - Off line oil at the detent valve to be exhausted, thus permitting the detent regulator valve to operate. Line oil Intermediate Clutch - On acting on the detent valve and solenoid is supplied by a Intermediate Roller Clutch - Effective in 2nd small orifice. Intermediate Roller Clutch - Ineffective in 3rd Drive oil on the detent regulator valve is then regulated part throttle 3-2 downshift can be accomplished below to a pressure of approximately 70 psi and called detent Aapproximately 33 mph by depressing the accelerator far oil. Detent oil is then routed to the: enough to raise modulator pressure to approximately 87 1. Modulator Passage psi. Modulator pressure and the 3-2 valve spring will move the 3-2 valve against direct clutch oil and allow 2. 1-2 Regulator Valve modulator oil to act on the 2-3 modluator valve. This 3. 2-3 Modulator Valve moves the 2-3 valve train against governor oil and shifts the transmission to second speed. 4. 3-2 Valve LIGHT DUTY TRUCK SERVICE MANUAL 7A-66 AUTOMATIC LIGHT DUTY TRUCK SERVICE MANUAL Fig. 23T—L2 Range Second Gear (Valves in Second Gear Position) Typical TRANSMISSION MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N Power Flow 7 A -67 L2 RANGE-SECOND GEAR (Valves in Second Gear Position) band as it holds the sun gear fixed. Without the band applied while coasting, the sun gear would overrun the intermediate roller clutch. Forward Clutch - On Low Roller Clutch - Ineffective Direct Clutch - Off Front Band - On Rear Band - Off Intermediate Clutch - On Intermediate Roller Clutch - Effective Detent Solenoid - De-energized In second gear, the intermediate clutch is applied to allow the intermediate roller clutch to hold the sun gear against counterclockwise rotation. Turbine torque, through the forward clutch, is now applied through the mainshaft to the rear internal gear in a clockwise direction. Clockwise rotation of the rear internal gear turns the rear pinions clockwise against the stationary sun gear. This causes the output carrier and output shaft to turn clockwise in a reduction ratio of approximately 1.5:1. In second gear, engine braking is provided by the front Oil Flow When the selector lever is in L2, intermediate oil from the manual valve is directed to the: 1. Pressure Boost Valve 2. 2-3 Shift Valve Intermediate oil at the boost valve will increase line pressure to 150 psi. This increased intermediate oil pressure at the 2-3 shift valve will close the 2-3 shift valve, regardless of car speed. For engine braking, the front band is applied by exhausting servo oil at the manual valve. This allows intermediate clutch oil, acting on the servo piston, to move the piston and apply the front band. Once the transmission is in second gear-L2, it cannot upshift to third gear regardless of vehicle speed. Summary The forward and intermediate clutches and front band are applied. The transmission is in second gear - L2 Range. LIGHT DUTY TRUCK SERVICE MANUAL 7A-68 AUTOMATIC LIGHT DUTY TRUCK SERVICE MANUAL Fig. 24T—LI Range First Gear (Valves in First Gear Position) Typical TRANSMISSION MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N 7A -69 LI RANGE-FIRST GEAR (Valves in First Gear Position) Power Flow Oil Flow Forward Clutch - On Low Roller Clutch - Effective Direct Clutch - Off Front Band - Off Rear Band - On Intermediate Clutch - Off Intermediate Roller Clutch - Ineffective Detent Solenoid - De-energized With the selector lever in LI range, the forward clutch is applied. This delevers turbine torque to the mainshaft and turns the rear internal gear in a clockwise direction (Converter torque ratio equals approximately 2.00:1 at stall). Clockwise motion of the rear internal gear causes the rear pinions to turn clockwise to drive the sun gear counterclockwise. In turn, the sun gear drives the front pinions clockwise, thus turning the front internal gear, output carrier and output shaft clockwise in a reduction ration of approximately 2.5:1. The reaction of the front pinions against the front internal gear is taken by the reaction carrier and roller clutch to the transmission case (Total stall ratio equals approximately 5.00:1). Down hill or overrun braking is provided in LI range by applying the rear band as this prevents the reaction carrier from overrunning the roller clutch. Maximum downhill braking can be attained at speeds below 40 mph with the selector lever in LI range, as this directs LI oil from the manual valve to the: 1. Rear Servo 2. 1-2 Accumulator Valve 3. Detent Regulator Valve 4. 1-2 Shift Valve Basic Control LI oil flows past a ball check to the apply side of the rear servo piston and to the 1-2 accumulator valve to raise the 1-2 accumulator oil to line pressure for a smooth band apply. LI oil acts on the detent regulator valve. Combined with the detent spring, LI oil holds the detent valve against line oil acting on the detent valve, causing drive oil to flow through the detent regulator valve into the detent and modulator passages. Moldulator and detent oil at line pressure, acting on the 1-2 regulator and 1-2 detent valve, overcomes governor oil and LI oil on the 1-2 shift valve at any vehicle speed below approximately 40 mph and the transmission will shift to first gear. In first gear - LI range, the transmission cannot upshift to second gear regardless of vehicle or engine speed. Summary The forward clutch and rear band are applied. The transmission is in first gear - LI Range. LIGHT DUTY TRUCK SERVICE MANUAL 7A-70 AUTOMATIC LIGHT DUTY TRUCK SERVICE MANUAL Fig. 25T—Reverse Range - Reverse Gear Typical f: 0 TRANSMISSION MAINLINE PRESSURE INTAKE PRESSURE CONVERTER PRESSURE GOVERNOR PRESSURE MODULATOR PRESSURE DETENT PRESSURE 1-2 ACCUMULATOR PRESSURE A U T O M A T IC T R A N S M IS S IO N 7A-71 REVERSE RANGE-REVERSE GEAR Power Flow Oil Flow Forward Clutch - Off Low Roller Clutch - Ineffective Direct Clutch - On Front Band - Off Rear Band - On Intermediate Clutch - Off Intermediate Roller Clutch - Ineffective Detent Solenoid - De-energized When the selector lever is moved to the Reverse position, the manual valve is repositioned to allow line pressure to enter the reverse circuit. Reverse oil then flows to the: 1. Direct Clutch 2. 2-3 Shift Valve 3. Rear Servo Piston 4. Pressure Boost Valve In reverse gear, the direct clutch is applied to transmit turbine torque from the forward clutch drum to the sun gear shaft and sun gear. The rear band is also applied, preventing the reaction carrier from turning clockwise. Clockwise torque to the sun gear causes the front pinions and front internal gear to turn counterclockwise in reduction. The front internal gear is connected directly to the output shaft, thus providing the reverse output gear ratio of approximately 2.00:1. The reverse torque multiplication at stall (converter and gear ratios) is approximately 4.00:1. Basic Control Reverse oil from the manual valve flows to the large area of the direct clutch piston and to the 2-3 shift valve. From the 2-3 shift valve, it enters the direct clutch passage and is directed to the small area of the direct clutch piston to apply the direct clutch. Reverse oil flows to the rear servo and acts on the servo piston to apply the rear band. Reverse oil also acts on the pressure boost valve to boost line pressure. Summary The direct clutch and the rear band are applied. The transmission is in Reverse. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -7 2 A U T O M A T IC T R A N S M IS S IO N MAINTENANCE A N D ADJUSTMENTS CHECKING TRANSMISSION MOUNT Raise the car on a hoist. Push up and pull down on the transmission tailshaft while observing the transmission mount. If the rubber separates from the metal plate of the mount or if the tailshaft moves up but not down (mount bottomed out), replace the mount. If there is relative movement between a metal plate of the mount and its attaching point, tighten the screws or nuts attaching the mount to the transmission or crossmember. TRANSMISSION FLUID Fluid Level The fluid level indicator is located in the filler pipe at the right rear of the engine. To bring the fluid level from the ADD mark to the FULL mark requires ONE PINT. Fluid level should be to the FULL mark with transmission at normal operating temperature (180190°F). With warm fluid (room temperature 70°F.), the level should be approximately 1/4" below the ADD mark. NOTE: In checking the oil, insert the dipstick in the filter tube with the markings up (toward center of car). Checking Procedure To determine proper fluid level, proceed as follows: The full mark on the dipstick is an indication of transmission fluid at normal operating temperature of 18(fF. This tempera­ ture is only obtained after at least 15 miles of highway driving or equivalent of city driving. CAUTION: 1. With manual control lever in Park position and parking brake applied, start engine. DO NOT RACE ENGINE. Move manual control lever through each range. 2. Immediately check fluid level with selector lever in Park, engine running and vehicle on LEVEL surface. At this point, when a reading is made, fluid level on the dipstick should be at the FULL mark. 3. If additional fluid is required, add enough fluid to bring level to the FULL mark on the dipstick. If vehicle is not driven 15 expressway miles, or its equivalent, and it becomes necessary to check fluid level, the transmission fluid must be at room temperature (70°F). W ith fluid at room temperature (70°F), follow steps 1, 2 and 3 below: 1. With manual control lever in Park position, start engine. DO NOT RACE ENGINE. Move manual control lever through each range. 2. Immediately check fluid level with selector lever in Park, engine running and vehicle on LEVEL surface. At this point, when a reading is made, fluid level on the dipstick should be 1/4" below the ADD mark. NOTE: If transmission fluid level is correctly established at 70°F, it will appear at the FULL mark on the dipstick when the transmission reaches normal operating tem­ perature (180°F). 3. If additional fluid is required, add fluid to bring level to 1/4" below the ADD mark on the dipstick. Do Not Overfill, as foaming and loss offluid through the vent pipe might occur as fluid heats up. Iffluid is too low, especially when cold, complete loss of drive may result which can cause transmissionfailure. CAUTION: IMPORTANT: W hen adding fluid, use only DEXRON or equivalent automatic transmis­ sion fluid. The difference in oil level between ADD and FULL is one pint. Fluid Capacity Approximately 7 1/2 pints of fluid are required to refill transmission after oil pan has been drained. When unit has been disassembled and rebuilt, approximately 19 pints will be required to refill. Use one DEXRON automatic transmission fluid or equivalent. Draining and Refilling Transmission Drain oil immediately after operation before it has had an opportunity to cool. To drain oil, proceed as follows: 1. Remove bottom pan attaching screws, pan and gasket. Discard gasket. 2. Remove oil filter retainer bolt, oil filter assembly, O-ring seal from intake pipe and discard the filter and O-ring seal. 3. Install new O-ring seal on intake pipe and install new filter on pipe assembly. 4. With O-ring seal on intake pipe, install pipe and filter assembly, attaching filter to the control valve assembly with its retainer bolt, torquing to 10 lb. ft. 5. Thoroughly clean bottom pan. 6. Install new gasket to bottom pan with petrolatum. 7. Install bottom pan with attaching screws and torque to 12 lb. ft. 8. Pour approximately 7 1/2 pints of fluid into the transmission (if the valve body has also been removed, use 9 1/2 pints). After a complete LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N overhaul, approximately 19 pints are required. Be sure container, spout or funnel is clean. 9. Start engine and let idle (carburetor off fast idle step). Place selector lever in Park position and apply hand brake. 10. With transmission hot (approximately 180-190°F), add fluid to bring level to FULL mark on indicator. With transmission at room temperature (70°F), add fluid to bring level to 1/4" below the ADD mark. CAUTION: Do not overfill. Foaming willresult. SHIFT CONTROLS Column Shift Linkage - CK Series (Fig. 26T) 1. The shift tube and lever assembly must be free in the mast jacket. See Section 9 for alignment of steering column assembly if necessary. 2. To check for proper shift linkage adjustment, lift the transmission selector lever towards the steering wheel. Allow the selector lever to be positioned in drive (D) by the transmission detent. NOTE: Do not use indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. 3. Release the selector lever. The lever should be inhibited from engaging low range unless the lever is lifted. 4. Lift the selector lever towards the steering wheel and allow the lever to be positioned in neutral (N) by the transmission detent. 7A-73 5. Release the selector lever. The lever should now be inhibited from engaging reverse range unless the lever is lifted. 6. A properly adjusted linkage will prevent the selector from moving beyond both the neutral detent, and the drive detent unless the lever is lifted to pass over the mechanical stop in the steering column. 7. If adjustment is required, remove screw (A) and spring washer from swivel (B). 8. Set transmission lever (C) in Neutral position by moving lever counter-clockwise to LI detent and then clockwise three (3) detent positions to Neutral. 9. Position transmission selector lever in Neutral position as determined by the mechanical stop in steering column assembly. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. 10. Assemble swivel, spring washer and screw to lever assembly (D) and tighten screw to 20 pound feet. 11. Readjust indicator needle if necessary to agree with the transmission detent positions. See Section 9. 12. Readjust neutral safety switch if necessary to provide the correct relationship to the transmission detent positions. See Section 12. 13. Check operation: a. With key in "R un" position and transmission in "Reverse" be sure that key cannot be removed and that steering wheel is not locked. b. With key in "Lock" position and shift lever in "Park", be sure that key can be removed, that steering wheel is locked, and that transmission remains in "Park" when steering column is locked. CAUTION: Any inaccuracies in the above adjustments may result in premature failure of the transmission due to operation without controls infull detent. Such operation results in reduced oil pressure and in turn partial engagement of the affected clutches. Partial engagement of the clutches with sufficient pressure to cause apparent normal operation of the vehicle will result infailure of the clutches or other internalparts after only a few miles of operation. COLUMN SHIFT LINKAGE - P SERIES (FIG. 27T) 1. The shift tube and lever assembly must be free in the mast jacket. See Section 9 for alignment of steering column assembly if necessary. 2. To check for proper shift linkage adjustment, lift the transmission selector lever towards the steering LIGHT DUTY TRUCK SERVICE MANUAL 7 A -7 4 A U TO M A T IC T R A N S M IS S IO N 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. wheel. Allow the selector lever to be positioned in drive (D) by the transmission detent. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. Release the selector lever. The lever should be inhibited from engaging low range unless the lever is lifted. Lift the selector lever towards the steering wheel, and allow the lever to be positioned in neutral (N) by the transmission detent. Release the selector lever. The lever should now be inhibited from engaging reverse range unless the lever is lifted. A properly adjusted linkage will prevent the selector lever from moving beyond both the neutral detent and the drive detent unless the lever is lifted to pass over the mechanical stop in the steering column. If adjustment is required, loosen nut (A) on steering column to allow swivel (B) and clamp (C) to move freely on rod (D). Set transmission lever (C) in Neutral position by moving lever counter-clockwise to LI detent and then clockwise three (3) detent positions to Neutral. Position transmission selector lever in Neutral position as determined by the mechanical stop in steering column assembly. NOTE: Do not use the indicator pointer as a reference to position the selector lever. When performing linkage adjustment, pointer is adjusted last. Tighten nut (A) 18 pound-feet. Readjust indicator needle if necessary to agree with the transmission detent positions. See Section 9. Readjust neutral safety backup lamp switch if necessary to provide the correct relationship to the transmission detent positions. See Section 12. CAUTION: Any inaccuracies in the above Fig. 2 7 T —Column S h ift Linkage - P Series TRANSMISSION CONTROL SWITCH 1. Install switch as shown in Figure 28T. 2. After installing the switch, press the switch plunger as far forward as possible. This presets the switch for adjustment. The switch will then adjust itself with the first wide open throttle application of the accelerator pedal. NEUTRAL START BACKUP LAMP SWITCH ADJUSTMENT The neutral start backup lamp switch must be adjusted so that the car will start in the park or neutral position, but will not start in the other positions. For replacement and adjustment refer to Section 12 of this manual. adjustments may result in premature failure of the transmission due to operation without controls infull detent. Such operation results in reduced oil pressure and in turn partial engagement of the affected clutches. Partial engagement of the clutches with sufficient pressure to cause apparent normal operation of the vehicle will result infailure of the clutches or other internalparts after only a few miles of operation. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 7A-75 SERVICE OPERATIONS 4. Remove control valve body assembly and governor pipes. If care is taken in removing control valve Removal body the six (6) check balls will stay in place above 1. Remove bottom pan and filter. the spacer plate. 2. Compress regulator boost valve bushing against 5. Remove the governor screen assembly from end of pressure regulator spring and remove snap ring, governor feed pipe or from the governor feed pipe using J-5403 pliers. hole in the case (fig. 30T). Clean governor screen in 3. Remove regulator boost valve bushing and valve. clean solvent and air dry. 4. Remove pressure regulator spring. CAUTION: Do not drop manual valve. 5. Remove spring retainer, washer spacer(s) is present, 6. Remove the governor pipes and manual valve from and regulator valve. control valve body. PRESSURE REGULATOR VALVE Installation NOTE: A solid type pressure regulator valve must only be used in a pump cover with a squared-off pressure regulator boss (See Figure 29T). A pressure regulator valve with oil holes and orifice cup plug may be used to service either type pump. Installation of the pressure regulator valve is the reverse of the removal. Installing new gasket on oil pan and adjusting fluid level. CONTROL VALVE BODY Installation Installation of control valve body is in reverse of removal. See Overhaul Manual. Adjust fluid level. GOVERNOR Removal 1. Remove governor cover attaching screws, cover, and gasket. 2. Discard gasket. 3. Withdraw governor assembly from case. Installation Removal 1. Remove bottom pan and filter. 2. Disconnect lead wire from pressure switch assembly. 3. Remove control valve body attaching screws and detent roller spring assembly. NOTE: Do not remove solenoid attaching screws. Installation of the governor assembly is the reverse of the removal. Use a new gasket under the governor cover. Adjust fluid level. MODULATOR AND MODULATOR VALVE Removal If the transmission is in the vehicle, the front servo parts may drop out as the control valve assembly isremoved. 1. Remove modulator assembly attaching screw and retainer. 2. Remove modulator assembly from case. Discard "O " ring seal. 3. Remove modulator valve from case. Fig. 29T—Pressure Regulator Valve Fig. 30T—Governor Screen Position CAUTION: LIGHT DUTY TRUCK SERVICE MANUAL 7 A -7 6 A U TO M A T IC T R A N S M IS S IO N Installation Installation of the modulator assembly and modulator valve is the reverse of the removal. Use a new "O " ring seal on the modulator assembly. Adjust fluid level. PARKING LINKAGE-10, 20 SERIES Removal 1. Remove bottom pan and oil filter. 2. Unthread jam nut holding detent lever to manual shaft. 3. Remove manual shaft retaining pin from case. 4. Remove manual shaft and jam nut from case. NOTE: Do not remove manual shaft seal unless replacement is required. 5. Remove parking actuator rod and detent lever assembly. 6. Remove parking pawl bracket attaching screws and bracket. 7. Remove parking pawl return spring. NOTE: The following steps should be completed unless part replacement is required. 8. Remove parking pawl shaft retainer. 9. Remove parking pawl shaft, cup plug parking pawl shaft, and parking pawl. Installation Installation of the parking linkage is the reverse of the removal. Use new seal and cup plug, if removed, and new bottom pan gasket. REAR SEAL Removal 1. Remove propeller shaft. 2. Pry seal out with screw driver. Installation All Models Except CM 1. Use a non-hardening sealer on outside of seal body; and using Tool J-2139, drive seal in place. 2. Re-install propeller shaft. Model CM 1. Use a non-hardening sealer on outside of seal body; and using Tool J-21464, drive seal in place. 2. Re-install propeller shaft. OTHER SERVICE OPERATIONS The following operations when done as single operations and not as part of a general overhaul should, as a practical matter, be performed with the transmission in the vehicle. Refer to the "Transmission Disassembly and Reassembly" section of the Overhaul Manual for service procedures. 1. Oil filler pipe and "O " ring seal. 2. Oil pan and gasket. 3. Down shift solenoid or connector. 4. Valve body spacer plate, gasket and check balls 5. Front accumulator piston. 6. Rear servo and rear accumulator assembly. 7. Rear band apply checking with Tool J-21370. 8-. Front servo assembly. 9. Speedo driven gear. 10. Case extension or gasket. 11. Filter and " 0 " ring. 12. Pressure switch assembly. TRANSMISSION REPLACEMENT Removal Before raising the truck, disconnect the battery and release the parking brake. 1. Raise truck on hoist. 2. Remove propeller shaft. 3. Disconnect speedometer cable, electrical lead to case connector, vacuum line at modulator, and oil cooler pipes. 4. Disconnect shift control linkage. 5. Support transmission with suitable transmission jack. 6. Disconnect rear mount from fram e crossmember. 7. Remove two bolts at each end of the frame crossmember and remove crossmember. 8. Remove converter under pan. 9. Remove converter to flywheel bolts. 10. Loosen exhaust pipe to manifold bolts approxi­ mately 1/4 inch, and lower transmission until jack is barely supporting it. 11. Remove transmission to engine mounting bolts and remove oil filler tube at transmission. 12. Raise transmission to its normal position, support engine with jack and slide transmission rearward from engine and lower it away from vehicle. 13. Use converter holding Tool J-5384 when lowering transmission or keep rear of transmission lower than front so as not to lose converter. Installation The installation of the transmission is the reverse of the removal with the following additional steps. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 1. Before installing the flex plate to ocnverter bolts, make certain with the flex plate that the weld nuts on the converter as flush with the flex plate and the converter rotates freely by hand in this position. Then, hand start all bolts and tighten finger tight 7 A -77 before torquing to specification. This will insure proper converter alignment. 2. After installation of transmission check linkage for proper adjustment. 3. Remove truck from hoist. D IA G N O S IS SEQUENCE FOR DIAGNOSIS 1. 2. 3. 4. 5. 6. Check and correct oil level. Check detent switch. Check and correct vacuum line and fittings. Check and correct manual linkage. Install oil pressure gage. Road test car. a. Road test using all selective ranges, noting when discrepancies in operation or oil pressure occur. b. Attempt to isolate the unit or circuit involved in the malfunction. c. If engine performance indicates an engine tune up is required, this should be performed before road testing is completed or transmission correction attempted. Poor engine performance can result in rough shifting or other malfunctions. OIL CHECKING PROCEDURES Before diagnosis of any transmission complaint is attempted, there must be an understanding of oil checking procedures and what appearance the oil should have. Many times a transmission malfunction can be traced to low oil level, incorrect dipstick, improper reading of dipstick, or oil appearance; therefore, a careful analysis of the condition of oil and the level may eliminate needless repairs. W hen checking oil level, proceed as follows: 1. Engine running. 2. Vehicle on level surface. 3. Brake applied. 4. Move lever through all ranges. 5. Place transmission in "PARK". 6. Check oil level. 7. If oil is low, check for possible cause Level should be to the FULL mark with the transmission at normal operating temperature (180°F.). With warm fluid (room temperature 80°F.), the level should be at or 1/4 inch below the ADD mark. (See checking procedure). The condition of the oil is often an indication of whether the transmission should be removed from the vehicle, or to make further tests. When checking oil level, a burned smell and discoloration indicate burned clutches or bands and the transmission will have to be removed. When the dipstick is removed, it should be noted whether the oil is devoid of air bubbles or not. Oil with air bubbles gives an indication of an air leak in the suction lines, which can cause erratic operation and slippage. W ater in the oil imparts a milky, pink cast to the oil and can cause slipping. OIL LEAK DIAGNOSIS Determining Source of Oil Leak Before attempting to correct an oil leak, the actual source of the leak must be determined. In many cases, the source of the leak can be deceiving due to "wind flow" around the engine and transmission. The suspected area should be wiped clean of all oil before inspecting for the source of the leak. Red dye is used in the transmission oil at the assembly plant and will indicate if the oil leak is from the transmission. The use of a "Black Light" to locate the point at which the oil is leaking is helpful. Comparing the oil from the leak to that on the engine or transmission dipstick, when viewed by black light, will determine the source of the leak - engine or transmission. Oil leaks around the engine and transmission are generally carried toward the rear of the car by the air stream. For example, a transmission oil fill pipe to case leak will sometimes appear as a leak at the rear of the transmission. In determining the source of a leak, proceed as follows: 1. Degrease underside of transmission. 2. Road test to get unit at operating temperature. (180 degrees F.) 3. Inspect for leak with engine running. 4. With engine off, check for oil leaks due to the raised oil level caused by drain back. Possible Points of Oil Leak 1. Transmission Oil Pan Leak a. Attaching bolts not correctly torqued. b. Improperly installed or damaged pan gasket. c. Oil pan gasket mounting face not flat. 2. Case Extension LIGHT DUTY TRUCK SERVICE MANUAL 7 A -7 8 A U T O M A T IC T R A N S M IS S IO N a. Attaching bolts not correctly torqued. b. Rear seal assembly damaged or improperly installed. c. Extension to case, gasket damage or improperly installed. d. Porous casting. See paragraph C. e. Output shaft "O " ring damaged. 3. Case Leak a. Filler pipe "O " ring seal damaged or missing; misposition of filler pipe bracket to engine "loading" one side of "O " ring. b. Modulator assembly "O " ring seal damaged or improperly installed. c. Electrical connector "O " ring seal damaged or improperly installed. d. Governor cover bolts not torqued, gasket damaged or leak between case face and gasket. e. Speedometer gear "O " ring damaged. f. Manual shaft lip seal damaged or improperly installed. g. Parking pawl shaft cup plug damaged, im prop­ erly installed. h. Line pressure band release tap plug loose. i. Vent pipe (refer to item 5). j. Porous casting. See subparagraph C. 4. Leak at Front of Transmission a. Front pump seal leaks. 1. Seal lip cut. Check converter hub for nicks, etc. 2. Bushing moved forward and damaged. 3. Garter spring missing from seal. b. Front pump attaching bolts loose or bolt seals damaged or missing. c. Front pump housing "O " ring damaged or cut. d. Converter leak in weld area. e. Porous casting (pump). 5. Oil Comes Out Vent Pipe a. Transmission over-filled. b. W ater in oil. c. Foreign matter between pump and case or between pump cover and body. d. Case - porous, front pump cover mounting face shy of stock near breather. See subparagraph C. e. Pump to case gasket mispositioned. f. Incorrect dipstick. g. Cut "O " ring or grommet on filter. h. Pump - shy of stock on mounting faces, porous casting, breather hole plugged in pump cover. OIL PRESSURE CHECK Road or Normal Operating Conditions While road testing (with the transmission oil pressure gage attached and the vacuum m odulator tube connected, the transmission pressure should check approximately as shown on figure 3 IT. Vehicle Stationary - Engine at 1200 RPM With the transmission oil pressure gauge attached and the vacuum modulator tube disconnected, the transmis­ sion pressures should check approximately as shown in Fig. 32T. Vehicle Stationary - Engine at 1000 RPM With the transmission oil pressure gauge attached and the vacuum modulator tube connected for normal modulator operation, the transmission pressure should check approximately as shown in Fig. 33T. NOTE: Pressures are not significantly af­ fected by altitude or barometric pressure when the vacuum m odulator tube is connected. Case Porosity Repair External leaks caused by case porosity have successfully been repaired with the transmission in the vehicle by using the following recommended procedures: 1. Road test and bring the transmission to operating temperature, approximately 180 degrees. 2. Raise vehicle on hoist or jack stand, engine running and locate source of oil leak. Check for leak in all operating positions. Use of a mirror is helpful in finding leaks. 3. Shut engine off and thoroughly clean area to be repaired with a cleaning solvent and a brush air dry. 4. Using instructions of the m anufacturer, mix a sufficient amount of epoxy, Part No. 1360016, or equivalent to make repair. Observe cautions of mfg. in handling. 5. While the transmission case is still HOT apply the epoxy to the area to be repaired. A clean, dry soldering acid brush can be used to clean the area and also to apply the epoxy cement. Make certain the are to be repaired is fully covered. 6. Allow cement to cure for three hours before starting engine. 7. Road test and check for leaks. VACUUM MODULATOR DIAGNOSIS A defective vacuum modulator can be determined by performing the following procedures. Vacuum Diaphragm Leak Check Insert a pipe cleaner into the vacuum connector pipe as LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N M inimum M axim um 145 psi 155 psi M inimum M axim um L2-2nd Gear - Steady road load at approxim ately 25 m ph Gear 1st 2nd 3rd 3rd Reverse Selector Lever Position 7 A -79 Drive (“ Z ero” th ro ttle to full th ro ttle ................................. ............... Drive Range, Zero T hrottle at 30 m p h ............... ............... Rev. (Zero to full th ro ttle ....................................... ............... 150 60 60 95 260 Fig. 31T—Oil Pressure Check - Road or Normal Operating Conditions A pproxim ate A ltitude of Check (Ft. above sea level) 0 2,000 4,000 6,000 8,000 10,000 12,000 14,000 Drive N eutral Park LI or L2 Reverse 150 150 145 138 132 126 121 116 150 150 150 150 150 150 150 150 244 233 222 212 203 194 186 178 Drive, Neutral, Park 60 LI or L2 150 Reverse 107 Fig. 33T—Oil Pressure Check • Vehicle Stationary, Vacuum Tube Connected Fig. 32T—Oil Pressure Check • Vehicle Stationary, Vacuum Tube Disconnected far as possible and check for the presence of transmission oil. If oil is found, replace the modulator. Gasoline or water vapor may settle in the vacuum side of the modulator. If this is found without the presence of oil, the modulator should not be changed. Atmospheric Leak Check Apply a liberal coating of soap bubble solution to the vacuum connector pipe seam, the crimped upper to lower housing seam, and the threaded screw seal (Fig. 34T). Using a short piece of rubber tubing apply air pressure to the vacuum pipe by blowing into the tube and observe for leak bubbles. If bubbles appear, replace the modulator. NOTE: Do not use any method other than human lung power for applying air pressure, as pressures over 6 psi may damage the modulator. Bellows Comparison Check Using a comparison gauge, as shown in Figure 35T, compare the load of a known good Hydra-Matic modulator with the assembly in question. a. Install the modulator that is known to be acceptable on either end of the gauge (Fig. 36T). b. Install the modulator in question on the opposite end of the gauge. (Fig. 37T). c. Holding the modulators in a horizontal position, bring them together under pressure until either modulator sleeve end just touches the line in the center of the gauge (Fig. 38T). The gap between the opposite modulator sleeve end and the gauge line should then be 1/16" or less. If the distance is greater than this amount, the modulator in question should be replaced. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -8 0 A U T O M A T IC T R A N S M IS S IO N M O D U L A T O R PART NUMBER IS L O C A T E D O N B A CK S ID E EN D S T O BE SQ U A RE R O U N D O R FLAT STO CK SCRIBE CENTER A N D OUTER LINES H O L D M O D U L A T O R S IN A H O R IZ O N T A L P O S I T I O N , A S S H O W N , B RIN G THEM S L O W L Y TO GE THER UNDER PRESS URE Fig. 36T—Holding Modulators in Horizontal Position Fig. 35T—Bellows Comparison Gauge Sleeve Alignment Check Roll the main body of the modulator on a flat surface and observe the sleeve for concentricity to the can. If the sleeve is concentric and the plunger is free, the modulator is acceptable. Once the modulator assembly passes all of the above tests, it is an acceptable part and should be re-used. MANUAL LINKAGE Manual linkage adjustment and the associated neutral safety switch are im portant from a safety standpoint. The neutral safety switch should be adjusted so that the engine will start in the Park and Neutral positions only. With the selector lever in the Park position, the parking pawl should freely engage and prevent the vehicle from rolling. The pointer on the indicator quadrant should line up properly with the range indicators in all ranges. TROUBLE DIAGNOSIS No Drive in Drive Range (Install pressure gage) • Low oil level - check for external leaks or defective vacuum modulator (leaking diaphragm will evacuate oil from unit). • Manual linkage maladjusted (correct alignment in manual lever shift quadrant is essential); manual valve disconnected from manual lever pin. • Low oil pressure - refer to LOW LINE PRESSURE below. • Forward clutch: a. Clutch does not apply - piston cracked; seals missing, damaged; clutch plates burnt (see BURNED CLUTCH PLATES below). b. Pump feed circuit-to-forward clutch oil seal rings missing or broken on pump cover; leak or restriction in feed circuits; pump-to-case gasket Fig. 38T—Modulator Bellows (Good) mispositioned or damaged. Clutch drum ball check stuck or missing. • Roller Clutch - broken springs, damaged cage or' installed backwards. High or Low Oil Pressure (Refer to OIL PRESSURE CEHCKS) High Line Pressure • Vacuum Leak: a. Vacuum line disconnected. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N b. Leak on line from engine to modulator. c. Improper engine vacuum. d. Leak in vacuum-operated accessory (hoses, vacuum advance, etc.). • Modulator: a. Stuck modulator valve. b. W ater in modulator. c. Damaged, not operating properly. • Detent System: a. Detent switch actuated (plunger stuck) or shorted. b. Detent wiring shorted. c. Detent solenoid stuck open. d. Detent feed orifice in spacer plate blocked or restricted. e. Detent solenoid loose. f. Detent valve bore plug damaged. g. Detent regulator valve pin short. • Oil Pump: a. Pressure regulator and/or boost valve stuck. b. Incorrect pressure regulator valve spring. c. Too many pressure regulator valve spacers. d. Pressure boost valve installed backwards or defective. e. Pressure boost bushing broken or defective. f. Pump casting bad. Low Line Pressure • Low transmission oil level. • Defective vacuum modulator assembly. • Filter Assembly: a. Blocked or restricted. b. "O " Ring seal on intake pipe and/or grommet omitted or damaged. c. Split or leaking intake pipe. d. Wrong filter assembly. • Oil Pump: a. Pressure regulator and/or boost valve stuck. b. Pressure regulator valve spring too weak. c. Not enough spacers in pressure regulator. d. Gear clearance, damaged, worn, drive gear installed backwards. e. Pump-to-case gasket mispositioned. f. Defective or mismatched pump body/pum p cover. • Internal Circuit Leaks: a. Forward clutch leak (pressure low in Drive 7A-81 range - pressure normal in Neutral and Reverse). 1. Check pump oil seal rings. 2. Check forward clutch seals. b. Direct clutch leak (pressure low in Reverse, pressure normal in all other ranges). 1. Check center support oil seal rings. 2. Check direct clutch outer seal. 3. Check rear servo and front accumulator pistons and rings for damage or missing. 6. Case Assembly: a. Porosity in intake bore area. b. Check case for intermediate clutch cup plug leak or blown out. c. LI-reverse check ball mispositioned or missing (this will cause no reverse and no overrun braking in LI range). 1-2 Shift-Full Throttle Only • Detent switch sticking or defective (may stick in cold or wet weather). Can be detected by pulling connection at transmission and obtaining normal upshifts. • Detent solenoid: a. Loose. b. Gasket leaking. c. Sticks open. • Control valve: a. Valve body gaskets - leaking, damaged, incorrectly installed. b. Detent valve train stuck. c. 3-2 valve stuck. • Case - porosity. First Speed Only, No 1-2 Shift • Governor: a. Valve sticking. b. Driven gear loose, damaged or worn (check for pin in case and length of pin showing); also check output shaft drive gear for nicks or rough finish if driven gear shows damage. • Control valve: a. 1-2 shift valve train stuck closed. b. Governor feed channels blocked, leaking, pipes out of position, governor screen plugged. c. Valve body gaskets leaking, damaged, incor­ rectly installed. • Case: a.' Intermediate clutch cup plug leaking or blown out. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -8 2 A U TO M A T IC T R A N S M IS S IO N b. Porosity between channels. c. Governor feed channel blocked; governor bore scored or worn, allowing cross pressure leak. • Intermediate clutch: a. Case center support - oil rings missing, broken, defective; orifice plug missing. b. Clutch piston seals missing, improperly assem­ bled, cut. • First and Second Speeds Only, No 2-3 Shift • Detent solenoid - stuck open (detent shifts only - the 2-3 shift would occur at very high speeds, being interpreted as no 2-3 shift). • Detent switch. • Control valve: a. 2-3 valve train stuck. b. Valve body gaskets leaking, damaged, incor­ rectly installed. • Direct clutch: a. Center support oil rings missing, broken, defective. b. Clutch piston seals missing, improperly assem­ bled, cut; piston ball check stuck or missing. Drive in Neutral • Manual linkage maladjusted. • Internal Linkage: a. Manual valve disconnected or end broken. b. Inside detent lever pin broken. • Pump Assembly - transmission lube pressure leaking into forward clutch apply passage. • Forward Clutch: a. Burned plates - check cause. b. Clutch doesn’t release - will also cause no drive in Reverse. No Drive in Reverse or Slips in Reverse (Install pressure gauge) • Low fluid level. • Manual linkage maladjusted. • Oil pressure - refer to LOW LINE PRESSURE above. • Control valve: a. Valve body gaskets leaking, damaged, incor­ rectly installed (Other malfunctions may also be indicated). b. Low reverse ball check missing from case (this will also cause no overrun braking in LI Range). • • • • c. 2-3 valve train stuck open (this will also cause 1-3 upshift in Drive range). d. Reverse feed passage restricted; also check case passages. Rear servo and accumulator: a. Servo piston seal ring damaged or missing. b. Short band apply pin (this may also cause no overrun braking or slips in overrun braking - LI range). Refer to INSTALLATION OF REAR SERVO ASSEMBLY for pin selection procedure. c. Defective rear servo piston or bore. Reverse or low band burnt, loose lining; apply pin or anchor pins not engaged; band broken. Direct clutch: a. Outer seal damaged or missing. b. Clutch plates burnt (see BURNED CLUTCH PLATES below). Forward clutch - clutch does not release (will also cause Drive in Neutral). Center support - oil seal rings or grooves damaged or worn. Slips in all Ranges, Slips on Start (Install pressure gauge) • Low fluid level. • Oil pressure - refer to LOW LINE PRESSURE above. • Case - cross leaks, porosity. • Forward and direct clutches slipping (if burnt, see BURNED CLUTCH PLATE below); oil seal rings on pump cover broken or worn. Slips 1-2 Shift (Install pressure gauge) • Low fluid level. • Oil pressure - refer to LOW LINE PRESSURE above. • Front accumulator piston oil ring damaged or missing. • Control valve: a. 1-2 accumulator valve train sticking. b. Porosity in valve body or case. c. Valve body attaching bolts not properly torqued. • Rear accumulator oil ring missing or damaged; case bore damaged. • Pump-to-case gasket mispositioned. • Case: a. Intermediate clutch cup plug leaks excessively. b. Porosity between channels. LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N c. Raised ridge around case center support bolt (does not allow control valve assembly to seat properly). • Intermediate clutch: a. Piston seals missing or damaged; clutch plates burnt (see BURNED CLUTCH PLATES below). b. Center support - leak in feed circuit (oil rings damaged or grooves defective), excessive leak between tower and bushing, orifice bleed plug hole (.020 dia.) blocked, center support bolt not seated properly in case. Rough 1-2 Shift (Install pressure gauge) • Oil pressure - refer to HIGH LINE PRESSURE above. • Control valve: a. 1-2 accumulator valve train. b. Valve body-to-case bolts loose. c. Wrong gaskets or off location, damaged. • Case: a. Intermediate clutch ball missing or not sealing. b. Porosity between channels. • Rear servo accumulator: a. Oil rings damaged. b. Piston stuck. c. Broken or missing spring. d. Bore damaged. • Intermediate clutch - clutch plates burnt (see BURNED CLUTCH PLATES below). Slips 2-3 Shift (Install pressure gauge) • Low fluid level. • Oil pressure - refer to LOW LINE PRESSURE above. • Control valve - accumulator piston pin (leak at swedge end). • Case porosity. • Direct clutch: a. Piston seals leaking or ball check leaks. b. Center support oil seal rings damaged; excessive leak between tower and bushing. Rough 2-3 Shift (Install pressure gauge) • Oil Pressure - refer to HIGH LINE PRESSURE above. • Front servo accumulator: 7 A -83 a. Front accumulator spring missing, broken. b. Accumulator piston stuck. • Direct clutch - air check for leak to outer area of clutch piston or center piston seal. • Damaged center support. No Engine Braking in L2 Range - 2nd Gear • Front servo accumulator: a. Servo or accumulator oil rings or bores leaking. b. Servo piston cocked or stuck. • Front band broken, burnt (check for cause), not engaged on anchor pin and/or servo pin. No Engine Braking in LI Range - 1st Gear • Case assembly - LI-reverse check ball mispositioned or missing from case; case damaged at Ll-reverse check ball area. • Rear servo: a. Oil seal ring, bore or piston damaged; leaking apply pressure. b. Rear band apply pin short, im properly assembled. • Rear band broken, burnt (check for cause), not engaged on anchor pins or servo pin. NOTE: Items above will also cause slips in Reverse or no Reverse. No Part Throttle Downshift (Install pressure gauge) • Oil pressure - refer to HIGH OR LOW OIL PRESSURE above. • Control valve - 3-2 valve stuck spring missing or broken. No Detent Downshifts • Detent switch adjustments, connection (switch plunger activated approx. 7/8" at full throttle opening). • Solenoid inoperative, connections. • Control valve-detent valve train sticking. Low or High Shift Points (Install pressure gauge) • Oil Pressure - refer to HIGH OR LOW OIL PRESSURE above. • Governor: a. Valve sticking. b. Feed holes restricted or leaking; pipes damaged or mispositioned. c.- Feed line screen plugged. • Detent switch. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -8 4 A U TO M A T IC T R A N S M IS S IO N • Detent solenoid stuck open, loose, etc. (will cause late shifts). • Control valve: a. Detent valve train. b. 3-2 valve train (detent upshifts possible). c. 1-2 shift valve train - 1-2 regulator valve stuck (this would cause a constant 1-2 shift point, regardless of throttle opening). d. Spacer plate gaskets mispositioned; spacer plate orifice holes missing or blocked. • Case porosity; intermediate clutch cup plug leaking, missing. Won’t Hold in Park • Manual linkage maladjusted. • Internal linkage: a. Parking brake lever and actuator defective (check for chamfer on actuator rod sleeve). b. Parking pawl broken. c. Parking pawl bracket loose, burned, rough edges or incorrectly installed. d. Parking pawl return spring missing, broken or incorrectly hooked. Transmission Noisy CAUTION: Before checking transmission for what is believed to be "transmission noise", make sure that the noise is not from the water pump, alternator, power steering, etc. These components can be isolated by removing the proper belt and running the engine no more than two minutes at one time. Park, Neutral and all Driving Ranges • Pump Cavitation: a. Oil level low. b. Plugged or restricted filter. c. Intake pipe "O " ring damaged. d. Intake pipe split, porosity in case intake pipe bore. e. W ater in oil. f. Porosity or voids at transmission case (pump face) intake port. g. Pump-to-case gasket off location. • Pump Assembly: a. Gears damaged or defective; driving gear installed backwards. b. Crescent interference. c. Oil seal rings damaged or worn. • Converter: a. Loose flywheel-to-converter bolts. b. Damaged converter. First, Second and /o r Reverse Gears Planetary Gear Set: a. Gears or thrust bearings damaged. b. Front internal gear ring damaged. During Acceleration - Any Gear • Transm ission or cooler lines grounded to underbody. • Motor mounts loose or broken. Squeal at Low Vehicle Speed Speedometer driven gear shaft seal - requires lubrication or replacement. Burned Clutch Plates • Forward clutch: a. Check ball in clutch drum damaged, stuck or missing. b. Clutch piston cracked, seals dam aged or missing. c. Low line pressure (see LOW LINE PRESSURE above). d. Manual valve mispositioned (may also cause front band failure). e. Restricted oil feed to forward clutch (clutch housing to inner and outer areas not drilled, restricted, porosity in pump, etc.). f. Transmission case valve body face not flat or porosity between channels. g. Manual valve bent and center land not ground properly. h. Pump cover oil seal rings missing, broken or undersize, ring groove oversize. • Intermediate Clutch: a. Constant bleed orifice in center support missing. b. Rear accumulator piston oil ring damaged or missing. c. 1-2 accumulator valve stuck in control valve assembly. d. Intermediate clutch piston seals damaged or missing. e. Center support bolt loose. f. Low line pressure (see LOW LINE PRESSURE above). g. Intermediate clutch cup plug in case missing. h. Transmission case valve body face not flat or porosity between channels. i. Manual valve bent and center land not ground properly. • Direct Clutch: LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N Restricted orifice in vacuum line to modulator (poor vacuum response). Check ball in clutch piston damaged, stuck or missing. Defective modulator bellows. Center support bolt loose (bolt may be tight in support but not holding support tight to the case). Center support oil rings or grooves damaged or missing. Clutch piston cracked, seals damaged or missing. Front and rear servo pistons and/or seals damaged. 7A -85 h. 3-2 valve, 3-2 valve spring or 3-2 spacer pin installed in wrong location in 3-2 valve train bore. i. Manual valve bent and center land not ground properly. j. Transmission case valve body not flat or porosity between channels. k. Intermediate roller clutch installed backwards. • In addition, burned clutch plates can be caused by incorrect usage of clutch plates. Also, anti-freeze in transmission fluid can cause severe damaged, such as large pieces of clutch plate material peeling off. LIGHT DUTY TRUCK SERVICE MANUAL 7 A -8 6 A U T O M A T IC T R A N S M IS S IO N SPECIAL TOOLS % O 11 tt 12 13 I 14 15 A 21 ■1 20 18 1. J-8763-02 2. J-3289-20 3. 4. 5. J-8092 J-21465-13 J-23062-3 6. 7. J-23062-7 J-21465-15 8. 9. 10. 11. J-23329 J-9534-01 J-23327 J-23062-2 12. 13. J-23062-1 J-21424-9 Transmission Holding F ixture (Used w ith J-3289-20 Base) Transmission Holding F ixture Base Driver Handle (Threaded type) Driver Handle Extension (Used w ith J-8092) Sun Gear and Reaction Carrier Bushing O u tp u t Shaft Bushing Installer Stator Shaft F ront Bushing Remover (Used w ith J-8092) D irect Clutch Bushing Installer O u tp u t Shaft Bushing Remover Clutch Spring Compressor Stator Shaft Rear Bushing Installer (Both Rear) Case Bushing Remover and Installer Extension Housing Bushing Remover and Installer (Used w ith J-8092) 14. J-21424-7 15. J-23062-5 16. 17. 18. J-5154 or J-21426 J-21359 J-7004 19. J-21885 20. J-23069 21. J-2619-01 Stator Shaft F ro n t Bushing Installer (Used w ith J-8092) In p u t Ring Gear Bushing Remover and Installer Extension Housing Oil Seal Installer Pump Oil Seal Installer Slide Hammers (Pair) (Ear Pump Body removal) (3 /8 " x 16 tread) 2-3 A ccum ulator Piston Compressor Intermediate A ccum ulator Cover Remover and Installer Slide Hammer (5 /8 " x 18 w ith 1 /2 " x 13 Adapter) N ot Illustrated J-21369 J-8001 Converter Pressure Check Fixture Dial Indicator Set (.001” Increments, .0 0 1 " Travel) Fig. 1ST—Turbo Hydra-Matic 350 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL A U T O M A T IC T R A N S M IS S IO N 1. 2. 3. 4. J - 6 1 16-01 J-8092 J -2 1 3 5 9 J -2 1 3 6 4 5. J -2 6 1 9 6. 7. 8. J-5154 J-6585 J-9539 9. 10. 11. 12. 13. J-5 5 9 0 J-21867 J - 2 1370-6 J -2 1370-5 J - 2 1795-1 Rear Unit Holding Fixture Driver Handle Pump Oil Seal Installer Holding Fixture Ad apter (Used with J - 6 1 1 6-0 1 Fixture) Slide Ha mmer (Used with 2 6 1 9 - 4 Adapter and Remover Tools J - 2 1 4 6 5 - 0 1 ) Extension Oil Seal Installer Slide Hammer Weights Slide Hamm er Bolts ( 3 / 8 " - 16 Threads) Speedo Gear Installer Pressure Gauge and Hose Rear Band Apply Fixture Rear Band Apply Pin Gear Unit Assembly Holding Tool 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29 J-2 1 7 9 5 - 2 J -5384 J -2 1465-01 J - 2 1465-5 J -2 1465-3 J-2 1 4 6 5 - 2 J - 2 1 4 65-1 J -2 1465-17 J -2 1465-8 J - 2 146 5 -1 3 J -2 1465-6 J-2 1 465-1 5 J - 2 146 5 -1 6 J -2 1465-9 J - 2 14 6 5 -1 0 J -2 2 1 8 2 7A-87 Part of Above Holding Tool Converter Holding Strap Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Part of Bushing Tool Set Ext. Bushing Rem. and Inst. (Not Illustrated) Fig. 2ST—Turbo Hydra-Matic 400/475 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL 7 A -8 8 A U TO M A T IC T R A N S M IS S IO N 1. 2. 3. 4. J -8 76 3 J -3 2 8 9 -1 4 J -2 1427-1 J -9 53 9 5. 6. 7. J -8 10 5 J - 2 1885 J -2 1369 8. J -2 13 62 Transmission Holding Fixture Holding Fixture Base Speedo Gear Remover Slide Hammer Bolts (3 /8 " - 16 Threads) Speedo Gear Remover Puller Accumulator Piston Installer Converter Pressure Check Fixture Seal Protector - Forward and Direct Clutch - Inner 9. J -2 1363 10. J -2 14 09 11. J -2 1664 12. 13. 14. 15. 16. J -4 6 7 0 J -8 0 5 9 J -5 5 8 6 J -5 4 0 3 J -1 3 1 3 Seal Protector - Intermediate Clutch - Inner Seal Protector - Forward Clutch - Outer Clutch Spring Compressor Adapter Ring Clutch Spring Compressor Snap Ring Pliers Snap Ring Pliers Snap Ring Pliers Torque W rench 0 -1 4 0 Ft. Lbs. Fig. 3ST—Turbo Hydra-Matic 400/475 Special Tools LIGHT DUTY TRUCK SERVICE MANUAL FUEL T ANKS A N D EXHAUST 8-1 SECTION 8 FUEL TANKS AND EXHAUST Also refer to the "Emission Control Systems Booklet for required maintenance and warranty information. CONTENTS OF THIS SECTION Description............................................................................. 8-1 Service Operations (Incl. M aintenance Item s)......... 8-2 Diagnosis (Exhaust and ECS System)......................... 8-34 Special Tools......................................................................... 8-35 DESCRIPTION All cab model trucks have fuel tanks relocated and mounted outside of the cab, outboard of the right frame rail. The tank is constructed of two steel sections, seam welded, together. Because of the outside location of the base and optional auxiliary tank, a plastic shield is released for all series and models for 1973. The shield is clipped to the tank and is bolted to the bracket mounting which is attached to the frame, protecting the full frontal area of the tank. Also a steel "bathtub type" skid plate, is bolted to frame and fuel tank bracket. On 1 ton forward control models and cowl models, the tank is mounted on the outside of the left frame side rail. A strong mounting of two metal straps anchor these tanks to mounting brackets which are bolted to the frame side member. On 1/2 and 3/4 ton conventional and 4-wheel drive models, Suburban and Utility, the tank is located to the rear of the axle and between the side rails and envelopes the forward edge of the spare tire. These tanks are supported by one or two steel straps which are held at either end by a hook into the side rail. Metal to metal contact between tank and brackets or straps is prevented by the use of anti-squeak material. Upper and lower filler necks vary as to size, length and shape, depending on model requirements. These necks are treated so that rust will not form and get into the fuel system. Lower filler necks are first bolted or riveted to the tank, except on cab models, and then sweat soldered in place to eliminate any possibility of leakage at this point. The fuel pickup pipe is built integrally with the tank gauge unit, located at the top of the tank. A large area, fine-mesh screen is located on the bottom of the fuel pickup pipe. This screen is designed to prevent the entrance of dirt or water into the fuel system, and operates with a self-cleaning action. Frame mounted tanks consist of an upper and lower half, each with a wide flange. The two tank sections are seam welded at the flange around the entire tank to assure leakproof construction. Exceptional stiffness is secured by the combination of the welded flanges and depressed ribs in both upper and lower tank sections. EVAPORATION CONTROL SYSTEM (ECS) The Evaporation Control System (ECS) is standard equipment under federal regulations for all truck series rated under 6,000 pounds maximum obtainable GVW and all people carrying vehicles. Important changes have been made to improve performance and increase reliability. The most noteworthy being in the area of fuel fill. Past versions used partial inner tanks as fuel fill limiter devices. Current designs use filler necks extended further into the fuel tank and a revised fill vent tube. TANK FILLER NECK GAS C A P -1 0 SERIES AND TRUCKS CLASSED AS PEOPLE CARRIERS The truck fuel tank filler cap has a pressure-vacuum safety relief valve. NOTE: The gas cap requires replacement, only a cap identified on the inside of the cap with "pressure-vacuum" should be used. Failure to use the correct cap can result in a serious malfunction of the system. LIGHT DUTY TRUCK SERVICE MANUAL 8-2 FUEL TANKS AND EXHAUST SERVICE OPERATIONS (INCLUDING MAINTENANCE ITEMS) INDEX Fuel Tanks and Attachments.......................................... 8-2 Fuel Lines.............................................................................. 8-10 Evaporation Control System (ECS)............................... 8-20 Exhaust Systems................................................................... 8-27 Special Tools......................................................................... 8-35 FUEL TANKS AND ATTACHMENTS FUEL CAP, FUEL LINES AND FUEL TA N K -The fuel tank, cap and lines should be inspected for road damage which could cause leakage. Inspect fuel cap for correct sealing ability and indications of physical damage. Replace any damaged or malfunctioning parts. INDEX Component Part Replacem ent........................................ 8-2 Draining Fuel T ank....................................................... 8-2 Fuel Tanks..........................................................................8-3 Metering Units (Gauge Sending U n it).................8-3 Cleaning Fuel Systems.................................................8-5 C O M P O N E N T PART REPLACEMENT (REFER TO ILLUSTRATIONS) DRAINING FUEL TANK If the fuel tank does not incorporate a drain plug, it will be necessary to siphon fuel from the tank when draining is needed. The following procedure is recommended. 1. Obtain approximately 10 feet of 3/8" I.D. hose and cut a flap-type slit 18" from one end. Make this cut in the direction of the shorter end of hose (See Figure 1). 2. Insert a small pipe nipple (slightly larger O.D. than the hose I.D.) into the opposite end of hose. 3. Insert the nipple end of siphon hose into the fuel tank filler neck with the natural curl of the hose pointed down. Insert until the hose is heard to strike the bottom of the tank. 4. With the opposite end of the hose in a suitable container, insert an air hose in the downward direction in the flap-type slit and trigger the flow of fuel. CAUTION: Before draining be sure that the fuel tank gauge unti wire or battery negative cable is disconnected. Always drain gasoline from complete fuel system including carburetor, fuel pump, all fuel lines and fuel tank if the vehicle is to be stored for any appreciable length of time. This precaution will prevent accumulation of gum formation and resultant poor engine performance. GAUGE UNIT OR STRAINER Replacement LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A NK S A N D EXHAUST The following procedure is intended as a general guide only and will vary according to truck series and model. 1. Drain tank to a level below gauge unit mounting location or if nuit is inaccessible remove fuel tank. 2. Disconnect fuel feed line and wiring from gauge unit. 3. Unlock gauge cam ring using Tool J-24187 and remove gauge unit from tank. NOTE: On some chassis mounted tanks, remove gauge attaching screws and then disengage unit from tank. 4. Replace or clean strainer with compressed air as required. 5. Install gauge unit using reverse of removal procedure. O U T S ID E C A B F U E L T A N K S C R E W M A N M O D E L S (Fig. 2) GAS CAP IDENTIFICATION Removal and Installation The easiest way to identify the correct filler neck gas cap for trucks with the Evaporation Control System (ECS), is to check for the words "pressure-vacuum" on the inside of the cap. Also check for proper gas cap fit. If gas cap replacement is required, always check vehicle identification and order by part number. 8-3 FUEL TANKS - REMOVE AND INSTALL W ARNING: Before attempting fuel tank removal, always; remove battery negative cable from battery, place "N O SM OKING" signs and a C02 fire extinguisher near work area, wear safety glasses, and siphon or pump fuel from tank into an explosive proof container. NOTE: The optional auxiliary fuel tank is located outboard of the left frame rail in the same manner as the base tank in 1973. It is connected to the frame rail as illustrated. CAB A N D 1. Drain tank as previously outlined. Also see Warning above. 2. Disconnect fuel lines, meter wire and ground lead. 3. Remove strap supports (lines, vent) and clips. 4. Loosen clamps from filler neck and vent line. 5. Remove strap bolts and lockwashers from tank front and rear locations on inside frame rail. 6. Remove tank from frame simultaneously disengaging filler neck hose from filler neck. 7. Remove meter assembly from fuel tank using Tool J-24187. 8. To install, reverse removal procedure. FUEL TANK (FIG. 3) - VAN Removal and Installation 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Drain tank. Raise vehicle on hoist. Unclamp filler neck and vent tube hose. Unclamp gauge unit hose at fram e end. For 10 series, disconnect all evaporation control attaching hoses (Fig. 36). Support tank and remove support strap(s). Lower tank until gauge unit wiring can be removed. Remove fuel tank. Install in the reverse order. Lower vehicle and remove from hoist. 1/2 AND 3 /4 TON CHASSIS CENTER AND AUXILIARY MOUNTED TANKS Removal and Installation 1. Drain tank. LIGHT DUTY TRUCK SERVICE MANUAL 8 -4 FUEL T ANKS A N D EXHAUST CROSS SILL BRACKET FUEL TANK ASSEMBLY BRACKET REAR CROSS SILL V IE W B Position anti-squeak to a lig n w ith bracket. V IE W C ANTI-SQUEAK Fig. 3 — Fuel T a n k - G -V an M o d els 2. 3. 4. 5. 6. 7. 8. Raise vehicle on hoist. Unclamp filler neck and vent tube hose. Unclamp gauge unit hose at fram e end. Support tank and remove support strap(s). Lower tank until gauge unit wiring can be removed. Remove fuel tank. Install in the reverse order, being sure that the anti­ squeak material is replaced. 9. Lower vehicle and remove from hoist. P MODELS AND 1 TON CHASSIS (FRAME) MOUNTED TANKS Removal and Installation 1. Drain tank. 2. Remove filler neck. 3. Disconnect gauge unit fuel line and wiring. Ignition switch must be in OFF position. 4. Remove bolts attaching tank supports to frame. LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST Fig. 5 —Fuel Tank M o un ting - Cab and Crewm an Models 5. Remove tank complete with mounting brackets and support straps. 6. Remove tank from brackets and support straps, if necessary. 7. To install, reverse the removal procedures. Replace all anti- squeak material. 6. 7. CLEANING FUEL SYSTEMS If trouble is due to contaminated fuel or foreign material that has been put into the tank, it can usually be cleaned. If tank is rusted internally, it should be replaced. 1. Disconnect battery and ignition coil prim ary wire (+ wire on ignition coil). 2. Drain fuel tank. (See DRAINING FUEL TANK.) 3. Remove fuel tank. (See FUEL TANKS - REMOVE AND INSTALL.) 4. Remove fuel inlet filter at carburetor and inspect for contamination. If filter is plugged, replace. (Leave fuel line disconnected.) 5. Locate tank away from heat, flame or other source of ignition. Remove fuel gauge tank unit and 8. 9. 10 11. 8-5 inspect condition of filter. If filter is contaminated, a new filter should be installed upon reassembly. Complete draining of tank by rocking it and allowing fuel to run out of tank unit hole. Purge fuel tank with steam or running hot water for at least five min utes. Pour water out of tank unit hole. (Rock tank to assure complete removal of water.) IMPORTANT: This procedure will not remove fuel vapor. Do not attempt any repair on tank or filler neck where heat or flame is required. Disconnect inlet fuel line at pump and use air pressure to clean fuel line and fuel return line (if equipped). Apply air pressure in the direction fuel normally flows through line. Use low air pressure to clean pipes on tank unit. Install new filter on fuel tank unit if required. Install fuel tank unit with new gasket into tank and install tank. Connect tank unit wires and all fuel lines except pump to carburetor line. (See REMOVAL OF TANK for proper procedure). Connect a hose to fuel line at carburetor; insert other end of hose into a one gallon fuel can. LIGHT DUTY TRUCK SERVICE MANUAL 8 -6 FUEL T ANKS A N D EXHAUST Fig. 7--Fuel Tank and Mounting • P20-30 Models Fig. 9--Fuel Tank Lower Neck and Meter, P 10 Series 12. Connect battery cable. MAKE SURE IGNITION COIL PRIMARY WIRE ( + TERM INAL) IS DISCONNECTED. 13. Put six gallons of clean fuel in tank and operate starter to pump two quarts of fuel into fuel can. This will purge fuel pump. 14. Remove hose and connect fuel line to carburetor. 15. Connect coil prim ary wire. LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A NK S A N D EXHAUST 5. 6. 7. 8. 9. 8-7 NOTE: For correct gasoline emulsifying agent - water mixture, refer to the emulsify­ ing agent m anufacturer’s specifications. Use an available emulsifying agent such as "Product-Sol No. 913" or equivalent. Fill tank (with water) to capacity and agitate again. Empty contents into floor drain. When empty, refill to overflowing with water to completely flush out remaining mixture and then empty tank. If any vapor is present, repeat Steps 4 thru 8. Repeat as necessary until there is no evidence of fuel vapor. Dry tank with compressed air and perform required service work. FUEL TANK LEAK TEST PROCEDURE FUEL TANK PURGING PROCEDURE 1. Remove fuel gauge unit and drain all remaining fuel from tank. 2. Visually inspect interior cavity of tank; if any fuel is evident, drain again. 3. Move tank to flushing area (wash rack). 4. Pour gasoline emulsifying agent and water solution into the tank and agitate mixture for 2 to 3 minutes, wetting all interior surfaces. 1. Plug all outlets as follows: a. Use a known good filler cap for filler neck. b. Install tank unit and plug fuel line. c. Plug two (2) of the three (3) tank vent tubes using a single short piece of fuel line hose. d. Install another short piece of fuel line hose on third vent tube. 2. Apply air pressure to tank through open vent tube. Use extreme caution to prevent rupturing the tank. When air can be heard escaping from the filler neck cap (approximately 1 to 1 1/2 lbs. of pressure) pinch the fuel line hose to retain pressure. 3. Test repaired area for leaks with soap solution or by submersion. If leak is noted, make repair and retest. CLAM P SIDE MEMBER HOSE-FILLER AUX, FUEL TANK (A) Do not install binding strap around vent hose. (B) One groove in cap denotes vented anti-surge, two grooves in cap denotes pressure vacuum . (A) STRAP Fig. 11-Filler Neck - C-K (03-63) LIGHT DUTY TRUCK SERVICE MANUAL 8 -8 FUEL T ANKS A N D EXHAUST SIDE MEMBER R.H. Fig. 12-Filler Neck C-K C-20-30 (03) and E56 GASKET SCREW HOSE BRACKET CLAMP NECK ASSEMBLY cap " a s s e m b l y / CLAMP CLAMP CLAMP Fig. 13-Filler Neck C-K 10-20 (06-14) LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST 8-9 Fig. 15—Filler Neck and Vent Hose -Van LIGHT DUTY TRUCK SERVICE MANUAL 8 -1 0 FUEL T ANKS A N D EXHAUST Fig. 16—Fuel Feed and Return Pipes - Front (C-K) LIGHT DUTY TRUCK SERVICE MANUAL FUEL T ANKS A N D EXHAUST 8-11 FUEL LINES (REFER TO ILLUSTRATIONS FIGS. 17 THRU 29). NOTE: When steel tubing replacement is required on any vehicle, only released steel tubing or its equivalent should be used for applicable replacement. Under no conditions should copper or aluminum tubing be used to replace steel tubing. All steel tubing should be flared using the upset (double lap) flare method which is detailed in Section 5 of the Service Section in applicable shop manuals. The fuel lines should be inspected occasionally for leaks, kinks or dents. If evidence of dirt is found in the carburetor, fuel pump or on a disassembly, the lines should be disconnected and blown out. Check the fuel strainer in the tank for damage or omission. When replacing a fuel line, only seamless steel tubing is to be used. Also, the ends of the tubing must be double­ flared using commercially available double flaring tools. All fuel lines must be properly routed and retained. FRAME MOUNTED FUEL FILTER Frame mounted fuel filters are standard equipment on some vehicles. The fuel filter element should be replaced at the recommended mileage intervals outlined in Section 0, this manual. FUEL LINE SERVICE The fuel lines should be inspected occasionally for leaks, kinks or dents. If evidence of dirt is found in the carburetor, fuel pump or on a disassembly, the lines should be disconnected and blown out. Check the fuel strainer in the tank for damage. When replacing a metal fuel line, only seamless steel tubing is to be used. Also, the ends of the tubing which join at a connector, must be double-flared using commercially available double flaring tools. All fuel lines must be properly routed and retained. TORQUE AT 100 IN. LBS. PIPE-FU EL RETURN C L IP ^ H O SE-FU EL RETURN HO SE—FU EL^ 7 RETURN / CLAMP CLAMP M 3 8 / M 4 9 W IT H O U T E V A P O R A T IO N C O N TR O L SYSTEM (ECS) CLAMP L F8/LS 9 & M 3 8 / M 4 9 W IT H E V A P O R A T IO N C O N TR O L SYSTEM (ECS) CKOO (0 3 ) EVAPORATIVE EMISSION PIPE CK10 (03) CK20 + C30 (03) & NA9 Fig. 17—Fuel Feed and Return Hoses - Rear C-K (03) LIGHT DUTY TRUCK SERVICE MANUAL 8 -1 2 FUEL TANKS A N D EXHAUST BRAKE PIPE PIPE FUEL FEED HOSE BRAKE PIPE CLIP CLAMP Fig. 18—Fuel Feed and Return Pipes - Rear C-K (06-14) LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A NK S A N D EXHAUST 8 -1 3 LIGHT DUTY TRUCK SERVICE MANUAL 8 - 1 4 FUEL TANKS A N D EXHAUST LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST 8-15 HOSE CLAMP Fig. 2 4 — D u a l T a n k Fuel R e tu rn Pipes a n d Hoses ■ C-K ( 0 3 - 6 3 ) LIGHT DUTY TRUCK SERVICE MANUAL 8 - 1 6 FUEL TANKS A N D EXHAUST Fig. 2 5 — Fuel Feed P ip e F ro n t, P -1 0 5 ( 4 2 ) LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A N K S A N D EXHAUST • TORQUE AT ^ 1 6 5 IN. LBS, 8 -1 7 METER ASSEMBLY PIPE ASSEMBLY CLAMP HOSE /PIPE ^ / a ssem b ly UNION GROMMET BRAKE CLIP BRAKE PIPE FRONT FUEL PIPE P20 & 3 0 W ITHO UT EVAPO RATIO N CONTROL SYSTEM Fig. 2 6 — Fuel Feed 'UNION FUEL VENT PIPE BRAKE PIPE P20 & 3 0 W ITH EVA PO RA TIO N CONTROL SYSTEM P ip e In te r a n d R ea r P 2 0 -3 0 LIGHT DUTY TRUCK SERVICE MANUAL 8 - 1 8 FUEL TANKS A N D EXHAUST TO RQ U E AT, 90 IN. LBS. CLIP PIPE-FUEL FEED ,PIPE-FUEL T o r q u e AT ^ CU P 90 IN. LBS P IP P -F I IPI PIPE-FUEL 'VENT PIPE /TO RQ U E AT 90 IN. LBS. FEED VEN T PIPE PIPE RETURN H O SE GROM M ET TO RQ U E AT 9 0 IN. LBS. PIPE FUEL FEED PIPE RETURN BRAKE PIPE VEN T PIPE Fig. 2 8 — Fuel Feed a n d R e tu rn T Y P IC A L 4 PLACES Pipes - R e a r G -V an LIGHT DUTY TRUCK SERVICE MANUAL FUEL T ANKS A N D EXHAUST PIPE-FUEL FEED INTERMEDIATE BRAKE PIPE 8 -1 9 HOSE CLAMP \ ^ PIPE-RETURN INTERMEDIATE VENT PIPE PIPE-FUEL FEED INTERMEDIATE ^ CLAMP VENT PIPE VIEW TYPICAL 5 PLACES PIPE-RETURN INTERMEDIATE FUEL FEED PIPE—INTERMEDIATE & RETURN PIPE—INTERMEDIATE -------------------------------(G -1 0 -2 0 , G 3 0 (0 5 & 0 6 ) -------------------------------- PIPE-FUEL FEED REAR FUEL VENT HOSE HOSE \ ;C L IPX ^ < PiPE-RETURN ^ CLAMP FUEL METER x GROMMET HOSE PIPE-FUEL FEED REAR TORQUE AT 90 IN. LBS INTERMEDIATE PIPES PIPE-RETURN TORQUE AT 90 IN. LBS. TORQUE AT 90 IN. LBS. VENT PIPE VIEW VIEW PIPE-FUEL FEED REAR /TORQUE / AT 90 IN. LBS. J CLIP VENT PIPE PIPE-FUEL FEED REAR FUEL FEED PIPE-REAR & RETURN PIPE-REAR ------------------------- (G -l 0 - 2 0 - 3 0 ) -------------------------- VIEW Fig. 29—Fuel Feed Pipes - (Inter and Rear) and Return Pipes (Inter and Rear) - G-Van LIGHT DUTY TRUCK SERVICE MANUAL 8-20 FUEL TANKS AND EXHAUST EVAPORATION CONTROL SYSTEM NOTE: Also refer to the "Emission Control Systems" Booklet for required maintenance and warranty information. INDEX Service Inform ation.............................................................. 8-20 Component Part Replacement..........................................8-21 -C anister and/or Canister F ilter....................................8-21 -C anister Purge V alve........................................................8-21 —Separator................................................................................8-21 —Fuel Tank..............................................................................8-21 EVAPORATION CONTROL SYSTEM FUEL & VAPOR LINES-A11 fuel and vapor lines and hoses must be in good condition with no signs of leakage. Any damaged or deterio­ rated lines or hoses must be replaced. All lines should be inspected for proper connections and correct routing. should copper or aluminum tubing be used to replace steel tubing. All steel tubing should be flared using the upset (double lap) flare method which is detailed in Section 5 o f the Service Section in applicable shop manuals. Before making part replacement, refer to “Hoses” under Service Information and also “Caution” below covering steel tubing part replacement. CAUTIO N: When steel tubing replacement is required on any vehicle, only released steel tubing or its equivalent should be used for applicable replacement. Under no conditions EVAPORATION CONTROL SYSTEM CANISTER - Check canister for cracks or damage when replacing the canister filter. Replace parts as necessary. FILTER-ECS-CANISTER-Remove canister and replace filter every 24,000 miles in lower section of canister. SERVICE INFO RM ATIO N The Components of this System are: FUEL TANK FILLER NECK GAS CAP The fuel tank filler cap has a new two-step removal and installation procedure plus a pressure-vacuum relief valve. It is equipped with a double set of locking tangs. To remove: • Rotate cap one-half turn counterclockwise to clear the first set of tangs from the slots inside the filler neck. • This will allow any residual pressure to escape. • Pull the cap outward and rotate one quarter turn counterclockwise to clear second set of tangs. Then remove the cap. • To install, reverse this procedure. NOTE: If this cap requires a replacement, only a cap with these same features should be used. Failure to use the correct cap can result in a serious malfunction of the system. Correct replacement caps may be obtained from your dealer. GASOLINE TANK The gasoline tanks incorporate special extended filler necks and vents and also external hose connections. LIQUID VAPOR SEPARATOR The separator mounts to the right or left hand side of the gasoline tank. If service is necessary, the entire assembly must be replaced. CANISTER FILTER The canister is mounted on the side of the engine compartment. A filter is mounted in the bottom of the canister. It is to be replaced according to the recommended maintenance schedule. HOSES When replacing any evaporative emission hose, use only replacement hose marked "EVAP". No other type of hose is to be used. LIGHT DUTY TRUCK SERVICE MANUAL FUEL TANKS AND EXHAUST 8-21 C O M P O N E N T PART REPLACEMENT (Fig. 3 1 -3 6 ) (REFER TO ILLUSTRATIONS) 3. Install canister and tighten clamp bolts. 4. Connect hoses to top of canister in same position as in Step 3 above. CANISTER PURGE VALVE (Fig. 30) Disassembly 1. Disconnect lines at valve. 2. Snap off valve cap (slowly remove cap as diaphragm is under spring tension). Remove diaphragm, spring retainer and spring. 3. Replace parts as necessary. Check orifice openings. Assembly 1. Install spring, spring retainer, diaphragm and cap. 2. Reinstall canister as previously outlined, connect lines to valve. CANISTER WITH CANISTER FILTER Removal 1. 2. 3. 4. Raise vehicle on hoist. Note installed position of hoses on canister. Disconnect hoses from top of canister. Loosen clamps and remove canister. If replacing filter, pull out filter from bottom of canister. Inspection 1. Check hose connection openings. Assure that they are open. 2. Check operation of purge valve by applying vacuum to the valve. A good valve will hold vacuum. Installation 1. Install new filter. 2. Assemble bottom of canister to canister body. SEPARATOR Removal 1. Raise vehicle on hoist. 2. Disconnect lines from separator. 3. Remove retaining screw and remove separator. Installation 1. Install separator and its retaining screw. 2. Connect lines to separator. NOTE: If replacing hose, use only replace­ ment hose marked EVAP. 3. Lower vehicle and remove from hoist. FUEL TANK Removal and installation procedures are the same as outlined for other models with exception of disconnect­ ing and connecting fuel tank-to-separator vent lines. Refer to Fuel Tank Section. LIGHT DUTY TRUCK SERVICE MANUAL 8 -2 2 FUEL T ANKS A N D EXHAUST CRANKCASE VENT HOSE & CONNECTOR CARBURETOR TORQUE AT 40 IN. LBS. CRANKCASE SPARK VENT HOSE CONNECTION & CONNECTION CK10 (0 0 ) 1CK20 (0 6 ) & LD4 CK20 (03 + 63) C30 & LD4/L25 & N A 9 Fig. 3 1 —C a n is te r H ose R o u tin g C-K C l 0 + 20 (0 0 ) & LG8 1 0 -3 0 Fig. 32—Canister Hose Routing CIO (03-06) and 20 (06) and LF-8 LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST 8 -2 3 CLAMP (DARKGREEN) CLAMP (DARK GREEN) DISTRIBUTOR VACUUM PIPE CK20 (03 + 6 3 )+C 30 (00) & LS9 & NA9 CK10 (0 0 )+ 2 0 (06) & LS9 CLAMP (DARK GREEN) HOSE ASSEMBLY TORQUE AT 4 0 IN. LBS. HOSE ASSEMBLY CLAMP (DARK GREEN) PCV VALVE CANISTER VIEW C20 (03 + 6 3 )+ C 3 0 (00) & LF8 Fig. 3 3 —C a n is te r H ose R o u tin g w /o EGR ( 3 5 0 a n d 4 5 4 ) LIGHT DUTY TRUCK SERVICE MANUAL 8 -2 4 FUEL TANKS A N D EXHAUST / / X' CRANKCASE VENT HOSE & CONNECTOR CARBURETOR CARBURETOR HEAT SHIELD HOSE ASSEMBLY TORQUE A T o r ^ 20 LBS. IN. CLIP SPARK CONNECTION HOSE ASSEMBLY CLAMP VIEW CLAMP (RED) VENT PIPE HOSE CANISTERx DASH PANELX HOSE ASSEMBLY x BRACKET TORQUE AT 45 LBS. IN VIEW ^ P I05 (4 2 ) P20 + 3 0 (4 2 ) & LD 4/L25 & N A 9 CLAMP (DARK GREEN)./ HOSE ASSEMBLY CLAMP (DARK GREEN) PCV VALVE— _ CARBURETOR CLAMP (RED) VENT PIPE HOSE CANISTER CLAMP (DARK GREEN) HOSE ASSEMBLY Fig. 34—Canister Hose Routing ■ P Models LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST 8 -2 5 CARBURETOR HOSE ASSEMBLY HOSE ASSEMBLY DASH PANEL / BRACKET TORQUE A T . 1 4 0 IN . LBS. V IE W HOSE ASSEMBLY, VENT PIPE HOSE CLAM P^2_ (DK GREEN) C A N IS T E R ^ HOSE ijc! ASSEM BLY^ / V IE W C LA M P ' = (DK GREEN) LS9 4 BBL CARBURETOR CLAMP (RED) V IE W LG8 V8 ENGINE Fig. 3 5 — C a n is te r H ose R o u tin g P 2 0 a n d 3 0 ( 4 2 ) a n d L G 8 /L S 9 LIGHT DUTY TRUCK SERVICE MANUAL 8 -2 6 FUEL TANKS A N D EXHAUST CANISTER CLAMP'(BLACK) CLAMP (RED) / AIR CLEANER Maintain 2.00 minimum clearance between A.I.R. pump pulley and vapor hose NOTE! G 1 0 + 2 0 (0 0 ) 3 0 (0 6 ), G 3 0 (0 5 ) & N A 9 CLAMP (DK GREEN) HOSE ASSEMBLY CLAMP (DK GREEN) CLAMP (DK GREEN) PCV VALVE ^ |— I |VIEW| A G 1 0 + 2 0 + 3 0 (0 6 ) & LS9 G 3 0 (0 5 ) & N A 9 HOSE ASSEMBLY <3- \ __ PCV VALVE ' FRONT VENT PIPE ill / G 1 0 (0 0 ) & LG8, G 1 0 + 2 0 + 3 0 (0 6 ) & LS9, G 3 0 (0 5 ) & N A 9 Fig. 36—Canister Hose Routing - G-Van LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A N K S A N D EXHAUST 8 -2 7 EXHAUST SYSTEM IMPORTANT: Make sure that exhaust system components have at least 3/4 inch clearance from the floor pan to avoid possible overheating of the floor pan and possible damage to the passenger compartment carpets. SERVICE IN FO R M A TIO N When installing a new exhaust pipe, muffler or tailpipe, on any model, care should be taken to have the correct alignment and relationship of the components to each other. Particular care should be given to the installation of the exhaust pipe and crossover pipe assembly on V-8 engine single exhaust systems. Incorrectly assembled parts of the exhaust system are frequently the cause of annoying noises and rattles due to improper clearances or obstructions to the normal flow of gases. Leave all clamp bolts and muffler strap bolts loose until all parts are properly aligned and then tighten, working from front to rear. NOTE: When reinstalling exhaust pipe to manifold, always use new packings and nuts. Be sure to clean manifold stud threads with a wire brush before installing the new nuts. C O M P O N E N T PART REPLACEMENT (FIGS. 3 7 -4 3 ) (REFER TO ILLUSTRATIONS) EXHAUST SYSTEM PIPES AND RESONATORS REARW ARD OF THE M U FFLERS MUST BE REPLACED WHENEVER A NEW M UFFLER IS INSTALLED. Truck exhaust systems vary according to series and model designation. Series 10-30 trucks use a split-joint design system in which the exhaust pipe-to-muffler are clamped together and muffler-to-tailpipe connections are welded together. All mufflers and tailpipes are welded assemblies (no clamps) in 1973. NOTE: All 10-20-30 Series exhaust have been aluminized. Always use the correct replace­ ment parts when servicing these systems. When installing a new exhaust pipe or muffler and tailpipe, on any model, care should be taken to have the correct alignment and relationship of the components to each other. Particular care should be given to the installation of the exhaust pipe and crossover pipe assembly on V-8 engine single exhaust systems. Incorrectly assembled parts of the exhaust system are frequently the cause of annoying noises and rattles due to improper clearances or obstructions to the normal flow of gases. Leave all clamp bolts and muffler strapbolts loose until all parts are properly aligned and then tighten, working from front to rear. NOTE: When reinstalling exhaust pipe to manifold, always use new packings and nuts. Be sure to clean manifold stud threads with a wire brush when installing the new nuts. LIGHT DUTY TRUCK SERVICE MANUAL 8-28 FUEL TANKS AND EXHAUST EXHAUST PIPE CLAMP EXHAUST PIPE TORQUE AT 30 FI. LBS. CLAMP TYPICAL IN S T A L L A T IO N TYPICAL IN S TA LLA TIO N AT MUFFLER EXHAUST CLAMPING INSTALLATION SLOT CENTERLINE OF CLAMP -C LA M P Locate centerline of clamp to end of slot in exhaust pipe, as shown. EXHAUST PIPE FLUSH TO .25 FROM KEY SLOT \ EXHAUST PIPE ^ F L U S H TO .10 FROM KEY CLAMP EXHAUST PIPE SLO T Locate from edge of clamp to end of slot in exhaust pipe, as shown NOTE Key must bottom in slot. CLAMP EXHAUST CLAMPING INSTRUCTION Fig. 37—Exhaust Clamping Installation and Instructions LIGHT DUTY TRUCK SERVICE MANUAL FUEL TANKS AND EXHAUST 8-29 EXHAUST PIPE & ATTACHING PARTS PIPE ASSEMBLY LD4/L25 TORQUE AT'._____ n 15 FT. LBS. |VIEW| D TYPICAL Fig. 3 8 — E xhaust P ip e a n d C ro ssover A tta c h m e n t to E n g in e C -K M o d e ls LIGHT DUTY TRUCK SERVICE MANUAL 8 -3 0 FUEL T ANKS AND EXHAUST Fig. 40—Exhaust Pipe • P Models LIGHT DUTY TRUCK SERVICE MANUAL FUEL TA NK S A N D EXHAUST 8-31 LIGHT DUTY TRUCK SERVICE MANUAL 8 -3 2 FUEL TANKS A N D EXHAUST LOCK WASHER M * * ------- TORQUE AT 2 0 IN. LBS. SUPPORT a ssem b ly; LOCK V IE W WASHER Fig. 4 2 — T a il P ip e a n d M u ffle r G -V an a n d ( L G 8 /L S 9 a n d LD 4) LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A NK S A N D EXHAUST 8 -3 3 LIGHT DUTY TRUCK SERVICE MANUAL 8 - 3 4 FUEL T ANKS A N D EXHAUST DIAGNOSIS EXHAUST SYSTEMS C O N D IT IO N L e a k in g E x h a u s t Gases P O S S IB L E C A U S E L e a k s a t p ip e jo in ts . C O R R E C T IO N T ig h t e n U - b o lt n u ts a t le a k in g jo in ts t o 1 5 0 in c h -p o u n d s . D a m a g e d o r im p r o p e r ly R e p la c e g askets as in s ta lle d gaskets. nece ss a ry . Loose h e a t tu b e c o n ­ R e p la c e gaskets as n e c tio n s . re q u ir e d . T ig h t e n s tu d n u ts o r b o lts to s p e c ific a tio n s . E x h a u s t N oises B u rn e d o r ru s te d o u t R e p la c e h e a t tu b e s h e a t tu b e s . as r e q u ir e d . L e a k s a t m a n if o ld T ig h t e n c la m p s a t o r p ip e c o n n e c tio n s . le a k in g c o n n e c tio n s . B u rn e d o r b lo w n o u t R e p la c e m u f f le r m u f f le r . a s s e m b ly . B u rn e d o r ru s te d o u t R e p la c e e x h a u s t p ip e . e x h a u s t p ip e . E x h a u s t p ip e le a k in g T ig h t e n a tta c h in g a t m a n ifo ld fla n g e . b o lts n u ts to 1 7 f o o t ­ pounds. E x h a u s t m a n if o ld c ra c k e d o r b r o k e n . R e p la c e m a n if o ld . L e a k b e tw e e n m a n if o ld a n d c y lin d e r h e a d . T ig h t e n m a n if o ld t o c y lin d e r h e a d s tu d n u ts o r b o lts t o s p e c ific a tio n s . E n g in e H a rd to W a r m U p H e a t c o n tr o l v a lv e F re e u p m a n if o ld h e a t O r W ill N o t R e tu r n to fr o z e n in th e o p e n c o n t r o l u sin g a s u it ­ N o r m a l Id le p o s itio n . a b le m a n if o ld h e a t c o n tr o l s o lv e n t. M a n if o ld H e a t C o n tr o l T h e r m o s ta t b r o k e n . R e p la c e t h e r m o s t a t . B ro k e n , w e a k o r R e p la c e s p rin g . V a lv e N o is e m issing a n t i- r a t t le s p rin g . LIGHT DUTY TRUCK SERVICE MANUAL FUEL T A N K S A N D EXHAUST 8 -3 5 EVAPORATION CONTROL SYSTEM (ECS) The Evaporation Control System should not require any maintenance other than the charcoal canister filter replacement. See "Emissions Control Section" Group 25 of this manual. Any loss of fuel or vapor from the fuel filler cap would indicate one or more of the following: (1) An unsatisfactory seal between cap and filler neck. (2) A malfunction of filler cap release valve. A quick check of the filler fuel cap may be made by placing against the mouth and blowing into the hole in the release valve housing. An immediate leak with light blowing or lack of release with hard blowing indicates a defective or incorrect unit. (3) All vapor lines plugged between fuel tank and vapor separator. (4) Plugged vapor lines between the vapor separator and the canister. SPECIAL TOOLS SP ANNER -FUEL TANK LO C KING CAM REPLACEMENT Fig. 44--Special Tool J-24187 LIGHT DUTY TRUCK SERVICE MANUAL SECTION 9 STEERING The following caution applies to one or more steps in the assembly procedure of components in this portion of the manual as indicated at appropriate locations by the terminology “See Caution on page 1 of this Section” . CAU TIO N THIS FASTENER IS A N IMPORTANT ATTACHING PART IN THAT IT COULD AFFECT THE PERFORMANCE OF VITAL COMPONENTS AND SYSTEM S, AND/OR COULD RESU LT IN MAJOR REPAIR EXPENSE. IT M U ST BE REPLACED WITH ONE OF THE SAM E PART NUMBER OF WITH AN EQUIVALENT PART IF REPLACEM ENT BECOMES NECESSARY. DO NOT USE A REPLACEM ENT PART OF LESSER QUALITY OR SUBSTITUTE DESIGN. TORQUE VALUES M U ST BE USED A S SPECIFIED DURING REASSEM BLY TO ASSU RE PROPER RETENTION OF TH IS PART. CONTENTS OF THIS SECTION General Description............................................................................... Theory of Operation............................................................................. Maintenance and Adjustments.............................................................. Component Replacement and Repairs................................................ Diagnosis................................................................................................. Special Tools.......................................................................................... 9-2 9-2 9-24 9-29 9-68 9-96 INDEX General Description................................................................ Theory of Operation.............................................................. Steering Ratio...................................................................... Manual Steering Gear............................................................ Steering Columns................................................................... Tilt Columns......................................................................... Power Steering System.......................................................... Power Steering Gear............................................................... Power Steering Pump............................................................ Steering Linkage..................................................................... Maintenance and Adjustments.............................................. Lubrication........................................................................... Adjustments.......................................................................... Steering Gear - Manual........................................................ Steering Gear High Point Centering................................... Steering Wheel Alignment.................................................. Steering Column Lower Bearing Adjustment................... Shifter Tube Adjustment..................................................... Power Steering Gear............................................................ Belt Tension....................................................................... Fluid Level.......................................................................... Bleeding System................................................................. System Checks.................................................................... Component Replacement and Repairs................................. Steering Wheel...................................................................... Steering Coupling................................................................. Flexible Type..................................................................... 9-2 9-2 9-2 9-4 9-6 9-7 9-10 9-11 9-16 9-22 9-24 9-24 9-24 9-24 9-25 9-25 9-25 9-26 9-26 9-27 9-27 9-27 9-28 9-29 9-29 9-29 9-29 Intermediate Steering Shafts with Pot Joint Couplings............................................................................... Intermediate Steering Shaft with Universal Joint Couplings.................................................................... Steering Gear......................................................................... Pitman Shaft Oil Seal Replacement................................... Directional Signal Switch.................................................... Lock Cylinder....................................................................... Ignition Switch...................................................................... Steering Column................................................................... Removal.............................................................................. Column Disassembly (Except Tilt).................................... Column Assembly (Except Tilt)........................................ Column Disassembly - Tilt.................................................. Column Assembly - Tilt....................................................... Column Installation - Mandatory Sequence............................................................................... Steering Column Service G and P ........................................ Upper Bearing G and P ........................................................ Lower Bearing G and P........................................................ Directional Switch................................................................ Tilt Column Bearing Housing........,................................... Column Removal.................................................................. Disassembly Standard Column........................................ Assembly Standard Column............................................. Disassembly Tilt Column................................................... Assembly Tilt Column....................................................... 9-30 9-31 9-32 9-33 9-33 9-35 9-37 9-37 9-39 9-39 9-41 9-43 9-45 9-47 9-48 9-48 9-48 9-48 9-50 9-51 9-52 9-53 9-53 9-56 LIGHT DUTY TRUCK SERVICE MANUAL 9-2 STEERING Column Installation P Series..............................................9-58 Column Installation G Series........................................... .9-59 Steering Linkage....................................................................9-59 Tie Rod............................................................................... .9-59 Relay Rod............................................................................9-62 Idler Arm .............................................................................9-62 Pitman Arm..........................................................................9-62 Steering Connecting Rod.................................................. .9-63 Power Steering System.........................................................9-63 Power Gear...........................................................................9-63 Pump.....................................................................................9-64 Hoses.....................................................................................9-65 Diagnosis.................................................................................. Steering Linkage................................................................... Manual Steering Gear.......................................................... Steering Column (C and K ).................................................. Collision Diagnosis............................................................... Automatic Column............................................................ Manual Column.................................................................. Tilt Column......................................................................... Electrical Analyzer J-23980............................................... Signal Switch........................................................................... Power Steering System ........................................................ External Leakage................................................................ Special Tools........................................................................... 9-68 9 -6 8 9-70 9-72 9-72 9 -7 3 9 .7 7 9-78 9 -7 9 9 .7 9 9-85 9 .9 1 9 .9 6 GENERAL DESCRIPTION The steering gear is of the recirculating ball type. This gear provides for ease of handling by transmitting forces from the wormshaft to the pitman shaft through the use of ball bearings. The steering column is connected to the steering gear by a flexible coupling. This coupling incorporates a capturing strap which is designed to prevent column-tocoupling deflection from exceeding the length of the coupling alignment pins. The steering columns are new for C and K Series Trucks but are basically the same as passenger vehicle columns. The G and P Series trucks use the same type of columns as in 1972. Optional tilt columns are available for all Series trucks. The trucks incorporate “Forward Steering” whereas the steering linkage is located forward of the front crossmember. Steering effort is transmitted to left and right hand adjustable tie rod through a relay rod. The relay rod is connected to an idler arm on the right and to the pitman arm on the left. THEORY OF OPERATION STEERING RATIO The ratio of a steering system is the relationship of steering wheel movement to that of the front wheels that is, the amount, in degrees, that the steering wheel must be turned to turn the front wheels one degree. For example, if a truck with power steering has a steering ratio of 17.5:1, and that is a constant ratio gear, it is necessary to turn the steering wheel approximately 17.5 degrees for each degree of turn desired. Part of the ratio is developed in the linkage, but the greatest part of the overall ratio is developed in the steering gear itself. Comparatively, vehicles with manual steering utilize steering ratios of 24:1 to help minimize the steering effort. With variable ratio power steering the steering ratio varies continuously from a moderate 16.0:1 or 15.0:1 for straight-ahead driving to a low 13.1:1 in full turns. From the straight-ahead position, the steering ratio stays constant for the first 40 degrees of steering wheel movement, then decreases very gradually at first. This provides precise steering control for highway driving with a ratio always higher than 15:1, as passing or even steering through curves seldom requires more than a quarter turn of the steering wheel. When cornering, such as at an intersection, the ratio spread will be somewhat broader - anywhere between 16:1 and 14.1:1 — as the steering necessary generally ranges from a half to a full turn of the steering wheel. While this provides an excellent average cornering ratio of about 14:1, the most im portant factor is that the response increases as the need increases. The low end of the ratio spread is utilized only near the extremes of the steering wheel travel-after approx­ imately one full turn. Since the steering wheel is generally turned to its limit only when parking or backing up, the added maneuverability of these extreme low ratios is purely a bonus, since directional stability is not a factor at low speeds. The design of the sector and rack are responsible for the steering flexibility. Notice that the center tooth of the variable ratio sector (C & K) is longer than the teeth on either side, while all teeth of the conventional sector (G & P) are of equal length. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-3 VARIABLE RATIO STEERING _______________ /> I. f CEhITER 16.0 to 1 > ______ ^ \ 9/4 " - '" I \ /' / , | 1 ------ - FULL RIC>HT 13.'1to 1 FIJLL LEFT 13.1 tc> l 1V i V y2 || || ’/4 1 ’/4 ’/a % 1 W a STEE RIN G WHEEL TURNS Fig. 1—Steering Ratio Since the sector, like any gear, is basically a series of levers, it is easily seen that any movement of the rack will always cause the conventional sector to swing the pitman arm in the same ratio -that is, to turn the pitman arm the same number of degrees with each tooth in the sector. To increase or decrease the ratio, it is only necessary to change the length of the sector teeth, and we see that a low ratio, or smaller radius sector with shorter teeth, produces a greater pitman arm movement than the high ratio sector with its longer teeth and greater leverage. On this basis, the variable ratio sector is in reality one long high ratio lever at the center flanked by two lower ratio levers for left and right turns. Since only the tip of the long center tooth is in contact with the rack when the front wheels are straight, initial movement of the rack in either direction causes a relatively small response of the sector and pitman arm because of the high ratio that results from this long lever relationship. As a result, the steering ratio remains a nearly constant 16.0:1 for the first 40 degrees of steering wheel movement either direction from center. Turning the steering wheel further, the effective length of the lever is reduced as the point of contact now rolls down the side of the center tooth, to act as a shorter radius. As a result, the steering ratio is reduced, causing the pitman arm to move noticeably further for a given steering wheel movement. With the wheel turned onehalf turn, the steering ratio is reduced to approximately 14.2:1. With a three-quarter turn of the steering wheel, the leverage has been further reduced to approximately 13.3:1. This smooth reduction in steering ratio is produced by the rolling action between the rack and center tooth that constantly shortens the effective leverage by moving the contact point down the side to the root of the long center tooth. At this time, the tip of the short tooth begins contact with the rack at the same radius and soon takes over the load. From three-quarters to one full turn of the steering wheel the ratio continues to diminish as the same rolling action moves the point of contact from the tip to the root of the short tooth. This action comples the ratio reduction from 13.3 to 13.1:1. For the last quarter turn of the steering wheel, the ratio remains constant at 13.1:1 to provide greatest maneuverability for backing and parking. LIGHT DUTY TRUCK SERVICE MANUAL 9 -4 STEERING MANUAL STEERING GEAR The manual steering gear (Figs. 2-7) is of the recirculating-ball-nut type with the steering shaft, worm shaft and worm nut all in line. The steering shaft and worm shaft are separated with a coupling which permits removal of the gear assembly or steering shaft (and column) independent of each other. The mechanical element of this steering gear is a recirculating ball system in which steel balls act as a rolling thread between the steering worm and nut. The nut is one piece and is geared to the sector of the pitman shaft, and mounted on the worm. It is driven through the steel balls which circulate in helical grooves in both the worm and nut. Ball return guides, attached to the nut, serve to recirculate the two sets of balls. Lash between the pitman shaft sector and rack of the ball nut is maintained by an adjusting screw through the side cover which is retained in the end of the pitm an shaft (Fig. 3). The teeth on the sector, which are an integral part of the pitman shaft, and the ball nut are so designed that a tighter fit exists between the two when the front wheels are straight ahead. Proper engagement between the sector and the ball nut is obtained by an adjusting screw which moves the pitman shaft endwise, permitting desired engagement of the tapered teeth of the ball nut and sector gear. The worm bearing adjuster can be turned to provide proper preloading of the upper and lower worm thrust bearings. For overhaul procedures see the proper Overhaul M anual . PITMAN SHAFT WORM BEARING (LOWER) SECTOR BALL NUT WORMSHAFT W O RM BEARING (UPPER) ADJUSTER PLUG SEAL BEARING CUP EXPAN SION PLUG BEARING CUP CLAMP BALL GUIDE B A ll LOCK NUT BEARINGS Fig. 2—Steering Gear—T ypical Except G Series (Side View) Fig. 4 — S te e rin g G e a r— G S e rie s (S id e V ie w ) SIDE COVER BALL NUT LOCKNUT LASH ADJUSTER SCREW Fig. 3—Steering Gear—Typical Except G Series (End View) PITMAN SHAFT SEAL Fig. 5-Steering Gear-G Series (End View) LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-5 *» 1. Side C o ve r Screw s 2. Lash A dju ster L o c k n u t 10. 9. Expansion Plug Steering G e a r H ou sin g 17. W orm 18. A d ju s te r Plug Bearing Race—Upper 3. Side C o ve r and Bushing 11. P it m a n S h a ft Seal 19. W o r m s h a f t Seal 4. Lash Adjuster Sh im 12. W orm Bearing 20. A d ju s te r Plug 5. Lash Adjuster Screw 13. W orm Bearing— Lo w e r 21. Clam p Screw 6. Side C o ve r G a ske t 14. Ball N u t 22. Ball G u i d e C l a m p 7. Pitm an Shaft 15. W orm shaft 23. Balls 8. P itm a n S h a ft Bushings 16. W orm 24 Ball G u id e s Race—Low er Bearing—U p p e r Fig. 6 - S te e rin g G e a r - G Lo ck n u t S eries Explode 21 1. 2. 3. 4. 5. 6. 7. 8. W orm Bearing Adjuster Locknut W orm Bearing Adjuster Lower W orm Bearing Race Low er Ball Bearing Low er Bearing Retainer Ball N u t W ormshaft U pper Ball Bearing 9. 10. 11. 12. 13. 14. 15. Upper W orm Bearing Race Pitman S haft Seal Housing W orm shaft Seal Side Cover Gasket Pitman Shaft Bushing (2 Bushings on G 10-30 Series Trucks) Pitm an Shaft Lash Adjuster Lash Adjuster Shim Housing Side Cover and Bushing Assembly Lash Adjuster Locknut Side Cover Bolts Ball Guide Clam p Screws Ball Guide Clam p Ball Guides Balls Fig. 7—Steering Gear—All Except G Series-Explode LIGHT DUTY TRUCK SERVICE MANUAL 9 -6 STEERING STEERING COLUMNS C AND K SERIES The function locking energy absorbing steering column on C and K Series Trucks which, in addition to steering the vehicle, includes three im portant functions: 1. The column is energy absorbing, designed to compress up to 8.25 inches in a front-end collision to minimize the possibility of injury in the event of an accident. 2. The ignition switch and lock are mounted conveniently on the column. 3. With the automatic transmission column, the ignition, steering and gearshifting operation can be locked to inhibit theft of the vehicle. The function locking energy absorbing steering column assembly is used on all C and K series trucks. This column is designed to compress under impact. When an vehicle is being driven, the forward movement of the vehicle and the forward movement of the driver both constitute a form of energy or force (Fig. 8). If a vehicle is involved in a frontal collision, the prim ary force (forward movement of the vehicle) is suddenly halted, while the secondary force (the driver) continues in the pre-collision direction. A frontal collision generally involves these two factors - the prim ary and the secondary forces. The secondary impact occurs if the driver is thrust forward onto the steering wheel and column. The function locking energy absorbing column is designed to absorb these prim ary and secondary forces to the extent that the severity of the secondary impact is reduced. In reacting to the prim ary force the steering column compresses (Fig. 9), thereby reducing its tendency to move rearward. A split second later, if the driver is thrown forward and strikes the steering wheel (the secondary impact), his energy is also partially absorbed by compression characteristics of the column. The operation of the column mounted lock (Fig. 10) is described as follows: To start the vehicle, you insert the key in the lock, turn the unit to “start” and let the switch return to the “on” position. The “off”, and “accessory” positions are also the same as in previous years, and are located in exactly the same order as they were when the unit was mounted on the instrument panel. The only thing that has changed is the lock’s position and its function. By mounting the ignition lock on the column, two new features are possible. When you engage the shift lever in “park” for automatic transmissions, and lock the ignition, the steering wheel locks and the gearshift locks. On standard transmission vehicles just the steering wheel locks. The function locking energy absorbing column may be easily disassembled and reassembled, by following procedures in this section. The serviceman should be BEFORE COLLAPSE AFTER COLLAPSE PLASTIC SLEEVE WITH BALLS Fig. 9 — S te e rin g C o lu m n J a c k e t D esig n aware that it is im portant that only the specified screws, bolts and nuts be used as designated and that they are tightened to their specified torque. This precaution will insure the energy absorbing action of the assembly. Care should be exercised NOT to use overlength bolts, as they may prevent a portion of the assembly from compressing under impact. Equally as important is correct torque of bolts and nuts. Care should be taken to assure that the bolts or nuts securing the column mounting bracket to the instrument panel are torqued to the proper specification in order that the bracket will break away under impact. See the specifications section at the rear of this manual. W hen the function locking energy absorbing column LIGHT DUTY TRUCK SERVICE MANUAL STEERING ADAPTER 9-7 column it will be necessary to check the neutral start switch for proper operation, and reposition if needed. A typical standard column is shown in Figure 11. ANTI-THEFT RING WAVE WASHER TILT-COLUMNS C and K Series The function locking energy absorbing tilt steering column option is available on all C and K series trucks (fig. 12). The tilt function locking column is designed for ease of entry and driver comfort. Tilt columns have seven different steering wheel angle position. LOCK CYLINDER SLEEVE IGNITION LOCK CYLINDER Fig. 1 0 — Lock C y lin d e r A s s e m b ly assembly is installed in a vehicle, it is no more susceptible to damage through usage than an ordinary column; however, when the column is removed, special care must be taken in handling this assembly. Only the specified wheel puller should be used. W hen the column is removed from the vehicle, such actions as a sharp blow on the end of the steering shaft or shift levers, leaning on the column assembly, or dropping of the assembly could shear or loosen the plastic fasteners that m aintain column rigidity. It is, therefore, im portant that the removal and installation and the disassembly and reassembly procedures be carefully followed when servicing the assembly. W henever the column is removed on autom atic transmission equipped vehicles, upon reinstalling the The tilt mechanism consists of an upper and lower steering shaft assembly with a universal joint between them. A support assembly is held to the mast jacket by a lock plate, and a bearing housing assembly is positioned over the upper steering shaft and secured to the support by two pivot pins. Two lock shoes are pinned to the housing assembly and engage a pin in the support assembly. When the release lever is pulled up and the lock shoes disengage the support pin, the steering wheel is pushed up by a spring compressed between the support and housing assemblies. The tilt release lever is located on the left side of the steering column and below the directional lever. The tilt lever is pulled toward the steering wheel and the wheel moved to the desired angle. G and P Series A tilt column is also available for G and P series trucks this year. It is the same as last years truck tilt column and all applicable service inform ation will be found in the service section of this manual. LIGHT DUTY TRUCK SERVICE MANUAL LIGHT DUTY TRUCK 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. Shaft Nut Cover Lock Plate Retaining Ring Lock Plate Cancelling Cam Bearing Preload Spring Turn Signal Screws Turn Signal Switch Protector Cover Turn Signal Housing Screws Bearing Thrust Washer 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. Turn Signal Housing Ignition Switch Sector Switch Rack Preload Spring Shaft Lock Bolt Switch Rod and Rack Assembly Thrust Cap Shaft Lock Bolt Washer Shift Lever Detent Plate Detent Plate Screws Shift Lever Spring Gearshift Lever Housing 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. Shift Shroud Gearshift Housing Bearing Ignition Switch Screws Ignition Switch Neutral Safety or Back-Up Switch Retainers Shift Tube Thrust Spring Washer Shift Tube Thrust Spring Lower Bearing Adapter Lower Bearing Reinforcement Retainer 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. Lower Bearing Shaft Stop Ring Steering Shaft Pot Joint Bolt Nut Pot Joint Cover Seal Retaining Ring Bearing Spring Bearing Blocks Pot Joint Seal Intermediate Shaft SERVICE MANUAL O O LIGHT TRUCK SERVICE M ANUAL 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. Lock Bolt Spring Lock Shoes Sector Shaft Lock Shoe Pin Bearing Housing Tilt Lever Spring Retainer Tilt Lever Spring Tilt Lever Spring Guide Lock Bolt Spring Screw Sector Snap Ring Sector Bearing Housing Pivot Pins Shoe Release Springs Spring Shoe Release Lever Pin Shoe Release Lever Lower Bearing Ignition Switch Rack Spring 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. Ignition Switch Rack Ignition Switch Rod Upper Steering Shaft Centering Spheres Center Sphere Spring Lower Steering Shaft Bearing Housing Support Screws Bearing Housing Support Pin Shift Tube Index Plate Screws Shift Tube Index Plate Support Retaining Ring Support Thrust Washer Support Plate Lock Support Wave Washer Gearshift Lever Spring Gearshift Lever Housing Ignition Switch Screws 55. Ignition Switch 56. Mast Jacket 57. Neutral-Safety or Back-Up Switch Retainers 58. Shift Tube 59. Lower Bearing Adapter 60. Lower Bearing 61. Lower Bearing Reinforcement 62. Retainer 63. Pot Joint Bolt 64. Nut 65. Pot Joint Cover 66. Seal Retaining Ring 67. Bearing Spring 68. Bearing Blocks 69. Pot Joint Seal 70. Intermediate Shaft 9-9 Shaft Nut Cover Lock Plate Retaining Ring Lock Plate Cancelling Cam Bearing Preload Spring Turn Signal Screws Turn Signal Switch Protector Cover Upper Bearing Seat Upper Bearing Race Turn Signal Housing Screws Turn Signal Housing Tilt Lever Opening Shield Upper Bearing Shaft Lock Bolt STEERING DUTY 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 15. 16. 17. 18. 9 -1 0 STEERING POWER STEERING SYSTEM HYDRAULICS Hydraulics is the science of liquids, such as water or oil. When we study hydraulics, we learn that pressure can be exerted through liquids, and that this pressure can transmit motion from one place to another. The reason for this is that liquids are incompressible. That is, they cannot be compressed to a smaller volume. TRANSMITTING MOTION WITH LIQUIDS Since liquid is not compressible, motion may be transmitted by liquid. For example, consider two pistons in a cylinder with a liquid between them. When the applying piston is moved into the cylinder 8 inches, then the output piston will be pushed along the cylinder the same distance. You could substitute a solid connecting rod between piston A and piston B and get the same result. But the advantage of such a system is that you can transmit motion between cylinders at any angle or distance. As the applying piston is moved, liquid is forced out of cylinder A, through the tube, and into cylinder B. This causes the output piston to move in cylinder B. TRANSMITTING PRESSURE WITH LIQUIDS The pressure applied to a liquid is transmitted by the liquid in all directions and to every part of the liquid. For example, when a piston with 1 square inch of area applies a force of 100 pounds on a liquid, the pressure on the liquid is 100 psi (pounds per square inch). This pressure will be registered throughout the entire hydraulic system. If the area of the piston is 2 square inches and the piston applies a force of 100 pounds, then the pressure is only 50 psi. With an input-output system we can determine the force applied to any output piston by multiplying the pressure in pounds per square inch by the area of the output piston in square inches. For example, if the pressure is 10 psi, and the output piston has an area of 16 square inches, the output force on this piston is 10 times 16 or 160 pounds. If a piston has an area of 2 square inches its output force is therefore 20 pounds (10 x 2) (Fig. 13). The bigger the output piston, the greater the output force. If the area of the piston were 100 square inches, for example, the output force would be 1,000 pounds. Likewise, the higher the hydraulic pressure, the greater the output force. If the hydraulic pressure on the 2-square-inch piston went up to 1,000 psi, then the output force on the piston would be 2,000 pounds. In all the preceding examplies, a piston-cylinder arrangement was the means of producing the pressure and this is the method used in hydraulic brakes. However, any sort of pump or pressure-producing device can be used. Several types of pump (gear, rotor, vane) have been used in automatic transmissions and power steering. G.M. Power Steering uses a constant displace­ ment vane type pump. The hydraulic power steering system consists of a pump, an oil reservoir, a steering gear, a supply hose, and a return hose (Figs. 14-15). The integral power steering gear may be either constant ratio or variable ratio. The integral power steering gear has an open center, rotary type, three-way control valve, which directs oil to either side of the rack piston. The Fig. 14—Power Steering System w/L-6 EngineTypical LIGHT DUTY TRUCK SERVICE MANUAL STEERING rack piston converts hydraulic power into mechanical output. The steering gear is mounted on the left frame rail by three mounting bolts. The steering shaft is joined to the steering gear through a flexible coupling, which allows for the possibility of slight shaft to gear misalignment. The pump is pulley driven, having an oil reservoir, which is part of the pump. It is attached to the front of the engine by a bracket, and is belt driven from the engine crankshaft. 9-11 P IT M A N SHAFT SECTOR POWER STEERING GEAR (Fig. 2 0 ) CONSTANT RATIO Two variations of integral power steering are used in trucks; “constant ratio” (“P” Models) and “Variable Ratio” (“C, G and K ” Models). The power steering gears are of the same general design and are overhauled in a like manner. Both gears incorporate the recirculating ball system in which steel balls act as a rolling thread between the steering wormshaft and rack-piston. The rack-piston nut is geared to the sector of the pitman shaft. The valve is contained in the gear housing thus eliminating the need for separately mounted valve and cylinder assemblies. VARIABLE RATIO Fig. 1 6 — P itm a n S h a ft S e c to r T e e th Variable ratio steering is faster when cornering, requiring fewer turns of the steering wheel to move the front wheels from stop to stop, while steering effort is not increased. It also provides more precise control and better response in maneuvering, particularly in sharp rapid turns and in parking. Variable ratio steering is accomplished by a pitman shaft sector incorporating a short tooth on either side of STEERING GEAR A SM . Fig. 15—Power Steering System V8—Typical LIGHT DUTY TRUCK SERVICE MANUAL 9 -1 2 STEERING INLET OUTLET STUB SHAFT •TOR SIO N BAR SEAL RACK PISTON NUT •ADJUSTER PLUG THRUST BEARING PITM A N SHAFT Fig. 1 7 — P ow er S te e rin g G e a r—(T y p ic a l) a long center tooth, rather than a sector with three teeth of equal length as in the constant ratio gear (fig. 16). Companion changes are also made in the rack-piston teeth. OPERATION Neutral (Straight Ahead Position) (Fig. 19) wheel, the slots in the spool valve are positioned so that oil entering the valve body from the housing pressure port passes through the slots in the spool valve to the oil return port in the housing. The chambers at both ends of the rack-piston and around the pitm an shaft are always full of oil, which acts as a cushion to absorb road shock so that they are not transferred to the driver. In addition, this oil lubricates all the internal components of the gear. When turning effort is not being applied at the steering LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-13 ------- 46 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. Locknut Retaining Ring Dust Seal Oil Seal Bearing Adjuster Plug " 0 " Ring Thrust Washer (Large) Thrust Bearing Thrust Washer (Small) Spacer Retainer ” 0 " Ring Spool Valve Teflon Oil Rings “ 0 " Rings 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. Valve Body Stub Shaft " 0 " Ring Wormshaft Thrust Washer Thrust Bearing Thrust Washer Housing Locknut Attaching Bolts and Washers Side Cover “ 0 " Ring Pitman Shaft Screws and Lock Washers Clamp Ball Return Guide 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. Balls Rack-Piston Teflon Oil Seal " 0 " Ring Plug " 0 " Ring Housing End Cover Retainer Ring Needle Bearing Oil Seal Back Up Washer Oil Seal Back Up Washer Retaining Pump Fig. 18—Power Steering Gear—Exploded (Typical) LIGHT DUTY TRUCK SERVICE MANUA 9 - 1 4 STEERING Right Turn (Fig. 20) When the steering wheel is turned to the right, the worm resists being turned because of the resistance offered by the front wheels. The valve body also resists turning because it is pinned to the worm. Driver force exerted at the steering wheel turns the lower shaft and spool valve a slight amount in relation to the valve body because of the twisting action of the torsion bar. This slight amount of turning of the spool valve is sufficient to position the slots in the valve body and spool valve for power assist. The right turn slots in the spool valve are closed off from the return (wide) slots in the valve body and opened more to the pressure (narrow) slots in the valve body. The left turn slots in the spool valve are closed off from the pressure slots in the valve body and opened more to the return slots in the valve body. Pressure immediately begins to build up against the lower end of the rack-piston, forcing it upward to apply turning effort to the pitm an shaft. The oil in the chamber at the upper end of the rack-piston is then forced out through the valve body and spool valve through the oil return port to the pump reservoir. The instant the driver stops applying turning effort to the steering wheel, the spool valve is forced back into its neutral position by the torsion bar. Oil pressure on the lower end of the rack-piston then decreases so that pressure is again equal on both sides of the rack piston and the front wheels return to the straight ahead position when the car is moving. Under normal driving conditions, oil pressure does not exceed 200 psi except when turning corners where it does not ordinarily exceed 450 psi. Oil pressure, when parking, ranges from 900 to 1,300 psi depending upon road conditions and weight of the vehicle. The steering effort during normal driving, ranges from 1 to 2 lbs. and during parking from 2 to 3-1/2 lbs. again depending upon road conditions. A check valve located under the high pressure connector seat hydraulically dampens the shock transmitted to the steering gear when driving on washboard roads. Left Turn (Fig. 21) When the steering wheel is turned to the left, the relationship between the spool valve slots and valve body slots is again changed through twisting of the torsion bar. Pressure immediately builds up against the upper end of the rack-piston, forcing it downward to apply turning effort to the pitman shaft. The oil in the chamber at the lower end of the rack-piston is forced out through the valve body and spool valve to the pump reservoir. Fig. 19—Neutral Position LIGHT DUTY TRUCK SERVICE MANUAL STEERING OIL PRESSURE OIL RETURN PORT 9-15 VALVE BODY Fig. 21—Left Turn Position LIGHT DUTY TRUCK SERVICE MANUAL 9 -1 6 STEERING POW ER STEERING PUM P PUMP DESCRIPTION The housing and internal parts of the pump are inside the reservoir so that the pump parts operate submerged in oil. The reservoir is sealed against the pump housing, leaving the housing face and the shaft hub exposed. The reservoir has a filler neck fitted with a cap. A shaft bushing and seal are pressed into the housing from the front. The drive shaft is inserted through this seal and bushing. A large hole in the rear of the housing contains the functional parts; namely ring, rotor, vanes and plates. A smaller hole contains the control valve assembly and spring (Fig. 22). The thrust plate (Fig. 23) is located on the inner face of the housing by two dowel pins. This plate has four central blind cavities for undervane oil pressure. The two outer blind cavities direct discharge oil through the two cross-over holes in the pump ring (Fig. 23), through the pressure plate, and into cavity l (Figs. 25, 26 and 27). The two outside indentations in the thrust plate are for intake of the oil from the suction part of the pump. The pump ring (Fig. 23) is a plate having the mating surfaces ground flat and parallel. The center hole is a two lobed cam in which the rotor and vanes operate. The ring is placed next to the thrust plate, and located with the same dowel pins. The pressure plate is fitted against the ring and located with the same two dowel pins. This plate has six through ports. The four central through ports connect from cavity l (Figs. 25, 26 and 27) to supply undervane oil pressure. The two outer ports pass oil under discharge pressure to cavity 1. The two identations are for oil intake from the suction part of the pump, cavity 7 (Figs. 25, 26 and 27) into the rotor. The reservoir is for oil storage. It receives and directs the return oil back to the make-up passage of the pump. The drive shaft is fitted with a pulley and is belt driven from the crankshaft. The rotor is loosely splined to the drive shaft and secured with a retaining ring. It is located centrally within the ring and between the thrust and pressure plates. The ten vanes are mounted in radial slots in the rotor (Fig. 23). PUMP OPERATION (Fig. 24) The mode of operation of the power steering pump is based upon the demand of the power steering gear. The various major modes of operation are: Slow cornering, moderate to high speed straight ahead driving, and cornering against the wheel stop. The pump is designed to recognize these conditions as required by the steering gear valve and compensates for them internally. As the drive shaft turns the rotor, the vane tips follow L-6 AND SMALL V-8 MARK V-8 18 1. 2. 3. 4. 4A. 5. 6. 7. 8. 9. 2 3 20 t (JSr-Q rm 1 19 tup 0 o 4 6 7 8 9 Union Union " 0 " Ring Seal Mounting Studs Reservoir Mark Engine & Truck Reservoir L-6 and Small V-8 Only Dip Stick and Cover Element (Corvette only) Filter Assembly (Corvette only) End Plate Retaining Ring End Plate 10 1 12 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 13 14 15 16 17 21 1 1 22 Spring Pressure Plate Pump Ring Vanes Drive Shaft Retaining Ring Rotor Thrust Plate Dowel Pins End Plate " 0 " Ring Pressure Plate "0 '''R in g 23 20. 21. 22. 23. 24. 25. 26. 27. 25 26 27 Mounting Stud Square Ring Seals Flow Control Valve Flow Control Valve Spring Flow Control Valve Square Ring Seal Pump Housing Reservoir ''O '' Ring Seal Shaft Seal Shaft Fig. 22—Power Steering Pump—Explode LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-17 the force of the flow control spring (10) the valve remains closed to the bypass hole (5). The oil pressure does not build up high enough to cause the pressure relief valve to actuate, because the oil pumped through the steering gear is allowed to recirculate through the entire system. MODERATE TO HIGH SPEED OPERATION (Fig. 26) Fig. 23—Pump Components the inner cam surface of the pump ring, moving outward and inward twice during each revolution. This results in a complete pumping cycle every 180 degrees of rotation (Fig. 23). Oil is moved in the spaces between the vanes. As the vane tips move outward, oil is sucked into the intervane spaces through four suction ports in the pressure and thrust plates. The pressure of the oil is raised, and the oil is discharged from the pump ring, as the vane tips move inward. High pressure oil discharges into cavity 1 (Figs. 25, 26 and 27), through two open ports in the pressure plate, and through two blind ports in the thrust plate, which are connected to cavity 1 by the cross-over holes in the ring. A portion of this oil is circulated through the central port system in the pressure plate, forcing the vanes to follow the cam surface of the ring. The ring-rotor leakage oil (12) is used for bushing lubrication and then bled to the reservoir. SLOW CORNERING (Fig. 25) During slow cornering maneuvers, the oil pressure required will usually not exceed 400 p.s.i. The speed of the pump is not high enough to require internal bypassing of oil, therefore, the pump by-pass port to (5) remains closed. The high pressure discharge oil (7) is slightly lower in pressure than the internal high pressure oil (1). The drop in pressure occurs as oil flows through the flow control orifice (2). This lower pressure is communicated to the bottom end of the pump control valve (9) via orifice (11) and passage (8), resulting in a pressure unbalance on the valve itself. The flow control valve moves away from the discharge fitting, but due to When operating at moderate to high speed, it is desirable to limit the temperature rise of the oil. This is done by flow controlling. The control valve in the steering gear is an open center rotary valve. When this valve is in the straight ahead position, oil flows from the pump through the open center valve and back to the pump reservoir without traveling through the power cylinder. When this flow exceeds the predetermined system requirements, oil is bypassed within the pump. This is accomplished by the pressure drop which occurs across the flow control orifice (2). The pressure is reduced at the bottom of the flow control valve (9) via orifice (11) and passage (8). The pressure unbalance on the valve is sufficient to overcome the force of the spring (10), allowing the valve to open the bypass hole (5), and diverting oil into the intake cham ber (6). Supercharging of the intake chamber occurs under these conditions. Oil at high velocity discharging past the valve into the intake chamber picks up make-up oil at hole (4) from the reservoir on the jet pump principle. By reduction of velocity, velocity energy is converted into supercharge pressure in cavity (6). During this straight ahead driving condition, the discharge pressure should not exceed 100 p.s.i. CORNERING AGAINST WHEEL STOPS (Fig. 27) When the steering gear control valve is actuated in either direction to the point of cut-off, the flow of oil from the pump is blocked. This condition occurs when the front wheels meet the wheel stop, or when the wheel movement is otherwise blocked by a curb or deep sand or mud. The pump is equipped with a pressure relief valve. The relief valve is contained inside the flow control plunger (13). When the pressure exceeds a predetermined pressure, (greater than maximum system requirements) the pressure relief ball (14) opens, allowing a small amount of oil to flow into the bypass hole (5). This flow of oil passing through the pressure relief orifice (11) causes a pressure drop and resulting lower pressure on the bottom end of the control valve (9). The pressure unbalance then causes the valve to compress the spring (10) allowing the major portion of the oil to bypass into the intake cham ber (from 3 to 6) in the same manner as is accomplished by flow controlling. Relief pressures are usually between 1200 and 1300 p.s.i. depending on the vehicle requirements. LIGHT DUTY TRUCK SERVICE MANUAL 9 -1 8 STEERING 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. Shaft W o o d ru ff Key Shaft Seal Pump Housing Thrust Plate Vanes Pump Ring Reservoir "O " Ring Seal Pressure Plate " O " Ring Pressure Plate End Plate 12. 13. 14. 15. 16. 17. 18. 19. 20. End Plate R etaining Ring Pressure Plate Spring Pump In le t Tube R o to r-to -D riv e Shaft R etaining Ring Pump O u tle t Union Reservoir Flow C on trol V a lv e Flow C on trol V a lv e Spring Rotor Fig. 24—Power Steering Pump—Typical LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-19 HIGH PRESSURE DISCHARGE INTERNAL HIGH PRESSURE RESERVOIR AND RETURN OIL RING, ROTOR LEAKAGE OIL 1. PUMP M AIN CAVITY 2. FLOW CONTROL ORIFICE 8. PUMP CONTROL VALVE PASSAGE 9. PUMP CONTROL VALVE 3. INTAKE CHAMBER 10. FLOW CONTROL SPRING 4. MAKE-UP OIL HOLE 11. PUMP CONTROL VALVE ORIFICE OR PRESSURE RELIEF ORIFICE 5. BY-PASS PORT 6. INTAKE CHAMBER DURING FLOW CONTROLLING 7. HIGH PRESSURE DISCHARGE OIL 12. RING ROTOR LEAKAGE OIL 13. FLOW CONTROL PLUNGER 14. PRESSURE RELIEF BALL Fig. 25—Pump Flow During Slow Cornering LIGHT DUTY TRUCK SERVICE MANUAL 9 -2 0 STEERING INTERNAL LOW PRESSURE OIL LOW PRESSURE DISCHARGE OIL RESERVOIR AND RETURN OIL am El- ■ RING ROTOR LEAKAGE OIL SUPERCHARGE OIL ^^ 1. PUMP MAIN CAVITY 8. PUMP CONTROL VALVE PASSAGE 2. FLOW CONTROL ORIFICE 9. PUMP CONTROL VALVE 3. INTAKE CHAMBER 10. FLOW CONTROL SPRING 4. MAKE-UP OIL HOLE 11. PUMP CONTROL VALVE ORIFICE OR PRESSURE RELIEF ORIFICE 5. BY-PASS PORT 6. INTAKE CHAMBER DURING FLOW CONTROLLING 7. HIGH PRESSURE DISCHARGE OIL 12. RING ROTOR LEAKAGE OIL 13. FLOW CONTROL PLUNGER 14. PRESSURE RELIEF BALL Fig. 26—Pump During Flow Controlling (Moderate to High Speed Operation) LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-21 INTERNAL AND DISCHARGE HIGH PRESSURE OIL sssatss PRESSURE RELIEF ORIFICE OIL FLOW RESERVOIR AND RETURN OIL i 111 I RING, ROTOR LEAKAGE OIL SUPERCHARGE OIL 1. PUMP MAIN CAVITY 2. FLOW CONTROL ORIFICE 8. PUMP CONTROL VALVE PASSAGE 9. PUMP CONTROL VALVE 3. INTAKE CHAMBER 10. FLOW CONTROL SPRING 4. MAKE-UP OIL HOLE 11. PUMP CONTROL VALVE ORIFICE OR PRESSURE RELIFE ORFICE 5. BY-PASS PORT 6. INTAKE CHAMBER DURING FLOW CONTROLLING 7. HIGH PRESSURE DISCHARGE OIL 12. RING ROTOR LEAKAGE OIL 13. FLOW CONTROL PLUNGER 14. PRESSURE RELIEF BALL Fig. 27—Pump Flow During Pressure Relief (Cornering Against Wheel Stops) LIGHT DUTY TRUCK SERVICE MANUAL 9 -2 2 STEERING STEERING LINKAGE In order to steer a vehicle, the wheels of the vehicle must be changed from their straight-ahead position. The Ackerman system (patented in 1900) is used in most vehicles. For this method of steering, the front wheels are mounted on pivoted knuckles, and a steering linkage is used to tie the knuckles together so that the wheels rotate together about their pivots. The center of rotation of a vehicle is the intersection of lines drawn perpendicular to the wheels (fig. 28). The purpose of the steering linkage is to turn the wheels while keeping this exact geometrical relationship which is necessary for minimum tire wear while turning. With the Ackerman system the front wheels do not turn equal amounts. One turns slightly more than the other so the geometrical center of rotation can be kept constant. The problems the steering linkage encounters are keeping the geometrical relationship as well as moving with the front suspension (fig. 28). Presently all trucks except K series incorporate designs that are of the parallelogram type (fig. 29). The basic parallelogram type linkage is made with five major components: Two adjustable tie rods, one relay rod, one pitman arm and one idler arm. The adjustable tie rods have both left and right hand threads to allow for toe-in adjustment. The pitm an arm and the idler arm are connected to the gear and fram e respectively, and both are connected to the center link, or relay rod. As the steering wheel is turned, the gear rotates the pitman arm which forces the relay rod to one side. The relay rod, which is connected to the tie rods, moves the wheels which are pivoted on the control arms. All K series vehicles use a FORE-AFT and CROSS STEER linkage which consists of an adjustable connecting rod, steering arm and a tie rod which connects the two steering knuckles together. The tie rod joints in the steering linkage system require multi-axis motion (similar to your shoulder joint). This is accomplished by a ball and socket joint more commonly referred to as a ball stud. These joints allow the tie rod to follow the steering arm as the wheel is turned and as the suspension moves with road shock. While the joints connecting the idler and pitman arms to the relay rod often allow motion about a pivot in one plane only (similar to door hinge). In summation, as the pitman arm moves, it moves the relay rod. The tie rods, that are connected to the relay rod by ball studs, transmit the steering force to the wheels. Figure 30-32 shows the present steering linkages used on all series trucks. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9 -23 ADJUSTABLE CONNECTING ROD Fig. 2 9 — P a ra lle lo g ra m ! KNUCKLE L in k a g e — F ro n t STEERING GEAR K-SERIES PITMAN ARM Fig. 3 1 — S te e rin g L in k a g e K S e rie s - T y p ica l Fig. 3 0 — S te e rin g L in k a g e C, G a n d P S e rie s - T y p ica l Fig. 32—Steering Linkage Motor Home - Typical LIGHT DUTY TRUCK SERVICE MANUAL 9 -2 4 STEERING M A INTENANCE A N D ADJUSTMENTS LUBRICATION The manual steering gear is factory-filled with steering gear lubricant. Seasonal change of this lubricant should not be performed and the housing should not be drained - no lubrication is required for the life of the steering gear. Every 36,000 miles, the manual gear should be inspected for seal leakage (actual solid grease - not just oily film). If a seal is replaced or the gear is overhauled, the gear housing should be refilled with #1051052 (13 oz. container) Steering Gear Lubricant which meets GM Specification GM 4673M, or its equivalent. NOTE: Do not use EP Chassis Lube, which meets GM Specification GM 6031M, to lubricate the gear. DO NOT OVER-FILL the gear housing. The steering linkage under normal conditions should be lubricated with any water resistant EP type chassis lubricant every 6,000 miles or four months, whichever occurs first. Lubricate every 3,000 miles or two months whichever occurs first when operating in dusty or muddy conditions or if the vehicle is used "off-road". Lubrication points and additional information on the chassis lubricant recommended can be found in Section 0-G eneral Information and lubrication. ADJUSTMENTS CAUTIO N: See Caution on page one of this section regarding the fasteners referred to in steps 9d and 10. Manual Steering Gear CAUTIO N: See CAUTION on page 1 o f this section regarding the fastener referred to in step 10. Before any adjustments are made to the steering gear attempt to correct complaints of loose or hard steering, or other wheel disturbances, a careful check should be made of front end alignment, shock absorbers, wheel balance and tire pressure for possible steering system problems. See Diagnosis in sections 3 and 9. Correct adjustment of steering gear is very important. While there are but two adjustments to be made, the following procedure must be followed step-by-step in the order given. 1. Disconnect the battery ground cable. 2. Raise the vehicle. 3. Remove the pitman arm nut. Mark the relationship of the pitman arm to the pitm an shaft. Remove the pitman arm with Tool J-6632 or J-5504 as shown in Figure 45. 4. Loosen the steering gear adjuster plug locknut and back the adjuster plug off 1/4 turn (fig. 33). 5. Remove the horn shroud or button cap. 6. Turn the steering wheel gently in one direction until stopped by the gear; then turn back one-half turn. CAUTIO N: Do not turn the steering wheel hard against the stops when the steering linkage is disconnected from the gear as damage to the ball guides could result. 7. Measure and record "bearing drag" by applying a torque wrench with a socket on the steering wheel nut and rotating through a 90° arc (fig. 34). NOTE: Do not use a torque wrench having a maximum torque reading of more than 50 inch pounds. 8. Adjust “thrust bearing preload” by tightening the adjuster plug until the proper “thrust loading preload” is obtained (See specifications section at rear of this manual). When the proper preload has been obtained, tighten the adjuster plug locknut to specifications and recheck torque. If the gear feels “lumpy” after adjustment, there is probably damage in the bearings due to severe impact or improper adjustment; the gear must be disassem­ bled and inspected for replacement of damaged parts. 9. Adjust “over-center preload” as follows: a. Turn the steering wheel gently from one stop all the way to the other carefully counting the total number of turns. Turn the wheel back exactly half-way, to center position. b. Turn the lash adjuster screw clockwise to take out all lash between the ball nut and pitman shaft sector teeth and then tighten the locknut. c. Check the torque at the steering wheel, taking LIGHT DUTY TRUCK SERVICE MANUAL STEERING the highest reading as the wheel is turned through center position. See the Specifications Section for proper over-center preload. d. If necessary, loosen locknut and readjust lash adjuster screw to obtain proper torque. Tighten the locknut to specifications and again check torque reading through center of travel. NOTE: If maximum specification is ex­ ceeded, turn lash adjuster screw counter­ clockwise, then come up on adjustment by turning the adjuster in a clockwise motion. 10. Reassemble the pitman arm to the pitm an shaft, lining up the marks made during disassembly. Torque the pitman shaft nut to specifications. CAUTIO N: I f a clamp type pitman arm is used, spread the pitman arm just enough, with a wedge, to slip the arm onto the pitman shaft. Do not spread the clamp more than required to slip over pitman shaft with hand pressure. Do not hammer the pitman arm onto the pitman shaft. Be sure to install the hardened steel washer before installing the nut. 11. Install the horn button cap or shroud and connect the battery ground cable. 12. Lower the vehicle to the floor. Steering Gear High Point Centering 1. Set front wheels in straight ahead position. This can be checked by driving vehicle a short distance on a flat surface to determine steering wheel position at which vehicle follows a straight path. 2. With front wheels set straight ahead, check position of mark on wormshaft designating steering gear high point. This mark should be at the top side of the shaft at 12 o’clock position and lined up with the mark in the coupling lower clamp. 9-25 3. On C, G and P series if gear has been moved off high point when setting wheels in straight ahead position. Loosen adjusting sleeve clamps on both left and right hand tie rods, then turn both sleeves an equal number of turns in the same direction to bring gear back on high point. NOTE: Turning the sleeves an unequal number of turns or in different directions will disturb the toe-in setting of the wheels. 4. On K series if the gear has been moved off high point when setting wheels in straight ahead position. Loosen adjusting sleeve clamps on the connecting rod then turn sleeve to bring gear back on high point. 5. Readjust toe-in as outlined in Section 3 (if necessary). 6. Be sure to properly orient sleeves and clamps as shown in figure 100 (and 102B). When fastening and torque clamps to proper specification. Steering Wheel Alignment NOTE: On all series vehicles check steering gear for high point centering before checking steering wheel alignment. 1. Set wheels in straight ahead position by driving vehicle a short distance. 2. Note steering wheel position. If off more than 1 inch from center (fig. 35), remove steering wheel as outlined under "Steering Wheel - Removal", center high point on gear, reposition and reinstall the wheel. Steering Column Lower Bearing Adjustment G and P Series 1. Loosen clamp on steering shaft. 2. Applying 50 lb. force to the steering wheel end of Fig. 34—Checking Torque at Steering Wheel LIGHT DUTY TRUCK SERVICE MANUAL 9 -2 6 STEERING Fig. 3 8 — S h ift T u b e A d ju s tm e n t - A u to m a tic T ra n s m is s io n Automatic Transm ission the steering shaft, adjust clamp to obtain clearances indicated in Figure 36. 3. Tighten clamp bolt to specified torque. Shifter Tube Adjustment G and P Series 3-Speed Transmission 1. Loosen adjusting ring attaching screws and clamp bolt. 2. Rotate adjusting ring to give .005" end play between adjusting ring and first and reverse shifter lever (fig. 37). 3. Tighten attaching screws and clamp bolt. Transmission 1. Place the shift tube lever in "N eutral" or "Drive". 2. Loosen adjusting ring clamp screws and rotate the shift tube adjusting ring to obtain .33" to .36" clearance between the shift tube lever and adjusting ring (fig. 38). 3. Tighten the adjusting ring clamp screws to 70 in. lbs. Power Steering Gear The over-center adjustment (fig. 39) is the only power steering gear adjustment which can be made on the vehicle. However, in order to make this adjustment, it is also necessary to check the combined ball and thrust bearing preload. CAUTIO N: See CAUTION on page 1 of this Section regarding the fastener referred to in step 10. 1. Disconnect the battery ground cable. 2. Raise and support front of vehicle so wheels hang free. 3. Remove the pitm an shaft nut. Mark the relation of the pitman arm to the pitm an shaft. Disconnect the pitman arm from the pitm an shaft using Puller Tool J-6632 (fig. 45). 4. Loosen the pitman shaft adjusting screw locknut and thread the adjusting screw out to the limit of its travel through the side cover. 5. Remove the horn button cap or shroud. 6. Turn the steering wheel through its full travel, then locate the wheel at its center of travel. 7. Check the combined ball and thrust bearing preload with an inch-pound torque wrench on the steering shaft nut by rotating through the center of LIGHT DUTY TRUCK SERVICE MANUAL STEERING 8. travel (approximately 1/4 turn in each direction). Note the highest reading. Tighten the pitman shaft adjusting screw and check torque at steering shaft nut until over-center preload and total steering gear preload falls within specifications. Refer to torque specifications at rear of manual for correct torque values. Install horn button cap or shroud. Connect the pitman arm to the pitman shaft, lining up the marks made at removal. Torque nut to specifications. Lower vehicle to floor and connect the battery ground cable. 9-27 necessary use only power steering fluid or equivalent upon refilling. BLEEDING HYDRAULIC SYSTEM 1. Check oil level in the reservoir by checking the dip stick when oil is at operating temperature. On models equipped with remote reservoir, the oil level should be maintained approximately 1/2 to 1 inch from top with wheels in full left turn position. 2. Fill, if necessary, to proper level with GM Power Steering Fluid or equivalent. If this is not available, any automatic transmission fluid bearing the mark Dexron may be used. NOTE: During flushing, overhaul or any operation where a complete change of fluid is 1. Fill oil reservoir to proper level and let oil remain undisturbed for at least two minutes. 2. Start engine and run only for about two seconds. 3. Add oil if necessary. 4. Repeat above procedure until oil level remains constant after running engine. 5. Raise front end of vehicle so that wheels are off the ground. 6. Increase engine speed to approximately 1500 rpm. 7. Turn the wheels (off ground) right and left, lightly contacting the wheel stops. 8. Add oil if necessary. 9. Lower the vehicle and turn wheels right and left on the ground. 10. Check oil level and refill as required. 11. If oil is extremely foamy, allow vehicle to stand a few minutes with engine off and repeat above procedure. a. Check belt tighteness and check for a bent or loose pulley. (Pulley should not wobble with engine running.) b. Check to make sure hoses are not toughing any other parts of the truck, particularly sheet metal. c. Check oil level, filling to proper level if necessary, following operations 1 through 10. This step and Step “D ” are extremely important as low oil level and/or air in the oil are the most frequent causes of objectional pump noise. d. Check the presence of air in the oil. If air is present, attempt to bleed system as described in operations 1 through 10. If it becomes obvious Fig. 39-Over-Center Adjustment Fig. 40-Checking Belt Tension with J-23600 9. 10. 11. Pump Belt Tension 1. Loosen pivot bolt and pump brace adjusting nuts. CAUTION: Do not move pump by prying against reservoir or by pulling on filler neck. 2. Move pump, with belt in place until belt is tensioned to specifications as indicated by Tool J-23600 (Fig. 40). 3. Tighten pump brace adjusting nut. Then tighten pivot bolt nut. FLUID LEVEL LIGHT DUTY TRUCK SERVICE MANUAL 9 -2 8 STEERING 3. 4. 5. Fig. 4 1 —C h e c k in g P ow er S te e rin g P ressures that the pump will not bleed after a few trials, proceed as outlined under Hydraulic System Checks. 6. HYDRAULIC SYSTEM CHECKS The following procedure outlines methods to identify and isolate power steering hydraulic circuit difficulties. The test provides means of determining whether power steering system hydraulic parts are actually faulty, this test will result in readings indicating faulty hydraulic operation, and will help to identify the faulty component. Before performing hydraulic circuit test, carefully check belt tension, fluid level and condition of driving pulley. Power Steering Hydraulic System Test Engine must be at normal operating temperature. Inflate front tires to correct pressure. All tests are made with engine idling, check idle adjustment and if necessary adjust engine idle speed to correct specifications listed in Section 6M and proceed as follows: 7. 1. With engine NOT running disconnect pressure hose from pump and install Tool J-5176 using a spare pressure hose between gauge and pump. Gauge must be between shut-off valve and pump. Open shut-off valve. 2. Remove filler cap from pump reservoir and check fluid level. Fill pump reservoir to full mark on dip stick. Start engine and, momentarily holding 8. steering wheel against stop, check connections at Tool J-5176 for leakage. Bleed system as outlined under Maintenance and Adjustments. Insert thermometer (Tool J-5421) in reservoir filler opening. Move steering wheel from stop to stop several times until thermometer indicates that hydraulic fluid in reservoir has reached temperature of 150° to 170°F. CAUTIO N: To prevent scrubbing flat spots on tires, do not turn steering wheel more than five times without rolling vehicle to change tire-tofloor contact area. Start engine and check fluid level adding any fluid if required. When engine is at normal operating temperature, the initial pressure read on the gage (valve open) should be in the 80-125 PSI range. Should this pressure be in excess of 200 PSI - check the hoses for restrictions and the poppet valve for proper assembly. Close gate valve fully 3 times. Record the highest pressures attained each time. (Note: do not leave valve fully closed for more than 5 seconds as the pump could be damaged internally). a. If the pressures recorded are within the listed specs and the range of readings are within 50 PSI, the pump is functioning within specs. (Ex. Spec. 1250 - 1350 PSI - readings - 1270 - 1275 1280). b. If the pressures recorded are high, but do not repeat within 50 PSI, the flow controlling valve is sticking. Remove the valve, clean it and remove any burrs using crocus cloth or fine hone. If the system contains some dirt, flush it. If it is exceptionally dirty, both the pump and the gear must be completely disassembled, cleaned, flushed and reassembled before further usage. c. If the pressures recorded are constant, but more than 100 PSI, below the low listed spec., replace the flow control valve and recheck. If the pressures are still low, replace the rotating group in the pump. If the pump checks within specifications, leave the valve open and turn (or have turned) the steering wheel into both corners. Record the highest pressures and compare with the maximum pump pressure recorded. If this pressure cannot be built in either (or one) side of the gear, the gear is leaking internally and must be disassembled and repaired. See the current Overhaul Manual. Shut off engine, remove testing gage, spare hose, reconnect pressure hose, check fluid level and/or make needed repairs. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-29 C O M P O N E N T REPLACEMENT A N D REPAIRS STEERING WHEEL Removal G and P Series 1. Disconnect battery ground cable. 2. Remove horn button or shroud, receiving cup, belleville spring and bushing and mark steering wheel to steering shaft relationship. 3. Remove steering shaft nut and washer. 4. Use Tool J-2927 to remove wheel (fig. 42). Installation 1. 2. 3. 4. 5. CAUTIO N: See CAUTION on page 1 o f this section regarding the fastener referred to in step 2. CAUTIO N: Directional signal control assembly must be in neutral position when assembling steering wheel to prevent damage to cancelling cam and control assembly. Place the steering wheel onto the steering shaft, aligning the marks made at removal. Position into place and secure to proper torque with washer and nut. Install belleville spring, receiving cup, bushing and attaching screws. Install horn button assembly. Connect battery ground cable. Removal C and K Series 1. Disconnect battery ground cable. 2. Remove horn shroud or button. 3. Lift steering wheel shroud and horn contact lead from the steering wheel. 4. Remove steering wheel nut. 5. Using tool J-2927, thread puller anchor screws into holes provided on steering wheel. Turn center bolt of tool clockwise to remove wheel. NOTE: Do not hammer on puller. The tool centering adapters need not be used. Installation 1. 2. 3. 4. CAUTION: See CAUTION on page 1 o f this section regarding the fasteners referred to in step 1. With turn signal in neutral position, align marks and set wheel onto steering shaft. Torque steering shaft nut to specifications. CAUTION: Do not over torque shaft nut or steering wheel rub may result. Place steering wheel shroud or horn button on wheel and align horn contact lead into the cancelling cam tower. Install shroud attaching screws. Connect battery ground cable. STEERING COUPLING Flexible Type (Fig. 43) Removal 1. Remove the coupling to steering shaft flange bolt nuts. 2. Remove the coupling clamp bolt. NOTE: This is a special bolt and will require a 12 pt. socket or box wrench. 3. Remove the steering gear to frame bolts and lower the steering gear far enough to remove the flexible coupling. NOTE: It is not necessary to disconnect the pitman arm from the pitm an shaft. 4. Tap lightly on the flexible coupling with a soft mallet to remove the coupling from the steering gear wormshaft. Installation CAUTION: Fig. 42—Steering Wheel Removal Typical See CAUTION on page 1 o f this section regarding the fasteners referred to in steps 2, 4 and 5. LIGHT DUTY TRUCK SERVICE MANUAL 9 -3 0 STEERING CAPTURING STRAP SPRING COUPLING TO STEERING SHAFT FLANGE BOLTS Fig. 4 3 — Flexib le T ype S te e r in g C o u p lin g — M a n u a l 1. Install the flexible coupling onto the steering gear wormshaft, aligning the flat on the shaft with the flat in the coupling. NOTE: Push the coupling onto the worm­ shaft until the coupling reinforcem ent bottoms against the end of the worm. 2. Install the special bolt into the split clamp and torque to specifications. NOTE: The bolt must pass through the shaft undercut. 3. Place the steering gear into position, guiding the flexible coupling bolts into the proper holes in the steering shaft flange. 4. Install and tighten the steering gear to frame bolts. 5. Install the coupling to flange bolt nuts and washers and torque to specifications. Be sure to maintain a coupling to flange dimension of .250" to .375". The coupling alignment pins should be centered in the flange slots. INTERMEDIATE STEERING SHAFTS WITH POT JOINT COUPLINGS Removal (Fig. 44) 1. Remove the lower shaft flange to flexible coupling bolts. 2. Remove upper shaft to intermediate coupling bolt. 3. Remove the steering gear to frame bolts and lower the steering gear far enough to remove the intermediate shaft assembly. NOTE: It is not necessary to remove the pitman arm from the pitm an shaft. Disassembly 1. Mark cover to shaft relationship. Pry off snap ring and slide cover from shaft. Fig. 4 4 — S te e rin g S h a ft In te r m e d ia te C o u p lin g (C a n d K ) 2. Remove bearing blocks and tension spring from pivot pin. 3. Clean grease off pin and end of shaft. Scribe location mark on pin on same side as chamfer in shaft. 4. Supporting shaft assembly securely, with chamfer up, press pin out of shaft with arbor press. CAUTIO N: Do not drive pin out with hammer. This will cause sticky or binding bearings when reassembled. 5. Remove seal clamp and slide seal off end of shaft. Assembly 1. Be sure all parts are free of dirt. Slide seal onto steering shaft. With lip of seal against step in shaft clamp seal. 2. Press pin back into shaft from chamfered side. Locate pin in shaft using scribe mark as reference. CAUTIO N: Pin must be centered within .012 in. or binding in the coupling will result. 3. Check centering of pin (fig. 45). a. Place just enough 3 /8 ” flat washers on pin to prevent bearing block from bottoming when installed. b. Measure distance from end of pin to top of bearing with micrometer. c. Remove bearing and washers and place same bearing and washers on other end of pin. Measure distance from end of pin to top of bearing. If micrometer readings in Steps b and c differ more than .012, repeat last part of Step 2 and recheck. 4. Apply a liberal amount of wheel bearing grease to inside and outside of bearing blocks and inside of cover. 5. Position tension spring and bearing blocks on pin. 6. Slide cover over bearing blocks aligning reference mark on cover with mark on shaft. Install seal into end of cover and secure with snap ring retainer. LIGHT DUTY TRUCK SERVICE MANUAL STEERING Installation CAU TIO N: 1. 2. 3. 4. See CAUTION on page 1 of this section regarding the fasteners referred to in steps 1, 3 and 4. Install the intermediate shaft assembly onto the steering shaft, aligning the flat on the shaft with the flat in the coupling. Install the pot joint clamp bolt and torque to specifications. Lift the steering gear into position, guiding the flexible coupling bolts into the shaft flange holes. Install the steering gear to frame bolts and torque to specifications. Install the flexible coupling to steering shaft flange bolt lockwashers and nuts. Check that the coupling alignment pins are centered in the flange slots and then torque the coupling bolts to specifications. INTERMEDIATE STEERING SHAFT WITH UNIVERSAL JOINT COUPLINGS Removal (Fig. 46) 1. Set front wheels in straight ahead position. This can be done by driving the vehicle a short distance on a flat surface. 2. Mark upper universal joint yoke to steering shaft relationship and lower yoke to steering gear wormshaft relationship. 3. Remove both upper and lower universal yoke pinch bolts. 4. Remove steering gear to fram e bolts and lower the gear. Fig. 45—Checking Coupling Pin Centering 9-31 NOTE: It is not necessary to disconnect the pitman arm from the steering gear pitman shaft. 5. Remove the interm ediate steering shaft and universal joint assembly. Disassembly 1. If the upper or lower half of the intermediate steering shaft is to be replaced, proceed as follows: a. With the shaft assembly on a bench, straighten the tangs on the dust cap. Separate the upper and lower portions of the shaft assembly. b. Remove the felt washer, plastic washer and dust cap. Discard the felt washer. 2. If the trunnion assemblies are to be replaced, proceed as follows: a. Remove the snap rings retaining the trunnion bushings in one of the yokes. b. Support the yoke on a bench vise and drive out one bushing by tapping on the opposite bushing using a soft drift and hammer. c. Support the other side of the yoke and drive out the remaining bushing as in Step b above. d. Move the yoke on the trunnion as necessary to separate the upper and lower yokes. e. Remove the trunnion from the lower yoke as outlined in Steps a through d above. Remove and discard the seals. Assembly 1. If the yoke trunnions were removed, reassemble as follows: a. Place the new trunnion into the lower yoke. b. Place new seals onto the trunnion and then press the new bushings into the yoke and over Fig. 46—Intermediate Steering Shaft — P Series LIGHT DUTY TRUCK SERVICE MANUAL 9 -3 2 STEERING the trunnion hubs far enough to install the snap rings. c. Install the snap rings. d. Repeat Steps a through c to attach the upper yoke to the trunnion. 2. Reassemble the intermediate shaft assembly as follows: a. Place the dust cap, plastic washer and a new felt seal over the shaft on the lower yoke assembly. b. Align the arrow on the lower yoke assembly shaft with the arrow on the upper yoke assembly tube and push the two assemblies together. c. Push the dust cap, plastic washer and felt washer into position on the lower end of the upper yoke assembly and bend the tangs of the dust cap down against the yoke tube. Installation CAUTIO N: 1. 2. 3. 4. See CAUTION on page 1 o f this section regarding the fasteners referred to in steps 1, 3 and 4. Align the marks made at removal and assemble the intermediate shaft lower yoke onto the steering gear wormshaft. Install the pinch bolt and torque to specifications. NOTE: The pinch bolt must pass through the shaft undercut. If a new yoke was installed, the slit in the yoke should be up (12 o’clock position). Raise the steering gear into position while guiding the upper yoke assembly onto the steering shaft. NOTE: The marks on the coupling and steering shaft must align. If a new yoke was installed, assemble the upper yoke to the steering shaft with the steering wheel in straight ahead position (gear must be on high point). Install the steering gear to frame bolts and torque to specifications. Install the upper yoke to steering shaft pinch bolt and torque to specifications. NOTE: The pinch bolt must pass through the shaft undercut. pitman shaft. Remove the pitman shaft nut or pitman arm pinch bolt and then remove the pitman arm from the pitman shaft using Puller J-6632 (fig. 45). 4. Remove the steering gear to frame bolts and remove the gear assembly. 5. C-K Models — Remove the flexible coupling pinch bolt and remove the coupling from the steering gear wormshaft. Installation CAUTIO N: See CAUTION on page 1 of this section regarding the fasteners referred to in steps la, lc, Id, le, 2b, 2c, and 3. 1. C-K Models a. Install the flexible coupling onto the steering gear wormshaft, aligning the flat in the coupling with the flat on the shaft. Push the coupling onto the shaft until the wormshaft bottoms on the coupling reinforcement. Install the pinch bolt and torque to specifications. NOTE: The coupling bolt must pass through the shaft undercut. b. Place the steering gear in position, guiding the coupling bolt into the steering shaft flange. c. Install the steering gear to frame bolts and torque to specifications. d. If flexible coupling alignment pin plastic spacers were used, make sure they are bottomed on the pins, torque the flange bolt nuts to specifications and then remove the plastic spacers. e. If flexible coupling alignment pin plastic spacers were not used, center the pins in the slots in the steering shaft flange and then install and torque the flange bolt nuts to specifications. STEERING GEAR Removal 1. Set the front wheels in straight ahead position by driving vehicle a short distance on a flat surface. 2. Remove the flexible coupling to steering shaft flange bolts (C-K models) or the lower universal joint pinch bolt (P models). Mark the relationship of the universal yoke to the wormshaft. 3. Mark the relationship of the pitman arm to the Fig. 4 7 — S te e rin g G e a r M o u n tin g — M o to r H o m e T y p ica l LIGHT DUTY TRUCK SERVICE MANUAL STEERIN G T O O L — J -5 5 0 4 T O O L — J -6 6 3 2 Fig. 4 8 — R em o v in g P itm a n A rm — T y p ica l 2. P Models a. Place the steering gear in position, guiding the wormshaft into the universal joint assembly and lining up the marks made at removal. NOTE: If a new gear was installed, line up the mark on the wormshaft with the slit in the universal joint yoke. b. Install the steering gear to frame bolts and torque to specifications. c. Install the universal joint pinch bolt and torque to specification. NOTE: The pinch bolt must pass through the shaft undercut. 3. Install the pitman arm onto the pitm an shaft, lining up the marks made at removal. Install the pitman shaft nut or pitman arm pinch bolt and torque to specifications. CAUTIO N: I f a clamp type pitman arm is used, spread the pitman arm just enough, with a wedge, to slip the arm onto the pitman shaft. Do not spread the clamp more than required to slip over pitman shaft with hand pressure. Do not hammer the pitman arm onto the pitman shaft. Be sure to install the hardened steel washer before installing the nut. PITMAN SHAFT SEAL REPLACEMENT Manual Steering Gear A faulty seal may be replaced without removal of steering gear from C, G and P trucks by removing pitman arm as outlined under Maintenance and Adjustments - Steering G ear Adjustments and proceed as follows: NOTE: On K series vehicles remove the gear from the vehicle first. 9-33 1. Rotate the steering wheel from stop to stop, counting the total num ber of turns. The turn back exactly half-way, placing the gear on center (the wormshaft flat should be at the 12 o’clock position). 2. Remove the three self-locking bolts attaching side cover to the housing and lift the pitm an shaft and side cover assembly from the housing. 3. Pry the pitm an shaft seal from the gear housing using a screwdriver and being careful not to damage the housing bore. CAUTIO N: Inspect the lubricant in the gear for contamination. I f the lubricant is contaminated in any way, the gear must be removed from the vehicle and completely overhauled as outlined in the Overhaul Manual. 4. Coat the new pitm an shaft seal with Steering Gear Lubricant meeting GM Specification GM4673M (or equivalent). Position the seal in the pitm an shaft bore and tap into position using a suitable size socket. 5. Remove the lash adjuster lock nut. Remove the side cover from the pitm an shaft assembly by turning the lash adjuster screw clockwise. 6. Place the pitm an shaft in the steering gear such that the center tooth of the pitm an shaft sector enters the center tooth space of the ball nut. 7. Fill the steering gear housing with Steering Gear Lubricant meeting GM Specification GM4673M (or equivalent). 8. Install a new side cover gasket onto the gear housing. 9. Install the side cover onto the lash adjuster screw by reaching through the threaded hole in the side cover with a small screwdriver and turning the lash adjuster screw counter-clockwise until it bottoms and turn back in 1/4 turn. 10. Install the side cover bolts and torque to specifications. 11. Install the lash adjuster screw locknut, perform steering gear adjustment and install the pitm an arm as outlined under “Maintenance and Adjustments” . NOTE: On K series install the gear into the vehicle using previously outlined procedure. DIRECTIONAL SIGNAL SWITCH The directional signal switch can be removed with the steering column in the vehicle and without disturbing any of the column mountings. C and K Series Removal 1. Remove the steering wheel as outlined under “Steering Wheel - Removal” . 2. Remove the column to instrum ent panel trim cover. LIGHT DUTY TRUCK SERVICE MANUAL 9 - 3 4 STEERING Fig. 4 9 — R e m o v in g Lock P la te R e ta in in g R in g Fig. 5 0 —T a p in g D ire c tio n a l S ig n a l C o n n e c to r a n d 3. Remove the three cover screws and lift the cover olf the shaft. W ire s NOTE: The cover screws have plastic retainers on the back of the cover so it is not necessary to completely remove these screws. 4. Screw the center post of Lock Plate Compressing Tool J-23653 onto the steering shaft as far as it will go. Compress the lock plate by turning the center post nut clockwise (fig. 49). Pry the round wire snap ring out of the shaft groove and discard the ring. Remove Tool J-23653 and lift the lock plate off the end of the shaft. 5. 6. 7. 8. 9. CAU TIO N: I f the column is being disassembled on the bench, with the snap ring removed the shaft could slide out o f the lower end o f the mast jacket, damaging the shaft assembly. Slide the directional signal cancelling cam, upper bearing preload spring and thrust washer off the end of the shaft. Remove the directional signal lever screw and remove the lever. Push the hazard warning knob in and unscrew the knob. All Columns - Pull the switch connector out of the bracket on the jacket and wrap the upper part of the connector with tape (fig. 50) to prevent snagging the wires during switch removal. Tilt Column - Position the directional signal and shifter housing in the “low” position. Remove the harness cover by pulling toward the lower end of the column, be careful not to damage the wires. Remove the three switch mounting screws and pull the switch straight up, guiding the wiring harness and cover through the column housing (fig. 51). Fig. 5 1 — R e m o v in g D ire c tio n a l S ig n a l S w itch A s s e m b ly Installation CAUTIO N: It is extremely important that only the specified screws, bolts and nuts be used at assembly. Use o f overlength screws could prevent a portion o f the assembly from compressing under impact. 1. All except Tilt - Be sure that the wiring harness is in the protector. Feed the connector and cover down through the housing and under the mounting bracket (column in vehicle.) Tilt - Feed the connector down through the housing and under the mounting bracket. Then install the cover on the harness. 2. Install the three mounting screws and clip the connector to the bracket on the jacket (fig. 52). 3. Install the column to instrument panel trim plate. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 4. Install the hazard warning knob and directional signal lever. 5. Make certain that the switch is in “N eutral” and the hazard warning knob is out. Slide the thrust washer, upper bearing preload spring and cancel­ ling cam onto the upper end of the shaft. 6. Place the lock plate onto the end of the shaft. Screw the center post of Lock Plate Compressing Tool J-23653 onto the steering shaft as far as it will go. Place a NEW snap ring over the center post. Place the “C” bar over the center post and then compress the lock plate by turning the nut clockwise. Slide the new snap ring down the tapered center post and into the shaft groove (fig. 53). Remove Tool J-23653. CAU TIO N: Always use a new snap ring when reassembling. 9-35 7. Place the cover on the end of the shaft and reinstall the three screws. 8. Install the steering wheel as outlined uner “Steering Wheel - Installation” . LOCK CYLINDER (C AND K SERIES) The lock cylinder is located on the upper right hand side of the column. The lock cylinder should be removed in the “ RUN” position only. Removal 1. Remove the steering wheel as outlined under “Steering Wheel - Removal” . 2. Remove the directional signal switch as outlined under “Directional Signal Switch - Removal” . NOTE: It is not necessary to completely remove the directional signal switch from the column. Pull the switch rearward far enough to slip it over the end of the shaft - do not pull the harness out of the column. 3. Insert a small screw driver or similar tool into the turn signal housing slot as shown in Figure 54. Keeping the tool to the right side of the slot, break the housing flash loose and at the same time depress the spring latch at the lower end of the lock cylinder. With the latch depressed, the lock cylinder can be removed from the housing. Assembly (Fig. 55) 1. Place the key part way into the lock cylinder assembly. Place the wave washer and anti-theft ring onto the lower end of the lock cylinder. NOTE: If the key is installed all the way into Fig. 5 2 — In s ta llin g S w itch C o n n e c to r O n to J a c k e t C lips Fig. ,53—Installing Snap Ring Fig. 54—Lock Cylinder Removal LIGHT DUTY TRUCK SERVICE MANUAL 9 -3 6 STEERING SLOT BOLT MUST PROTRUDE FROM SLEEVE Fig. 5 5 — Ig n itio n Lock C y lin d e r E xplo de 2. 3. 4. 5. 6. 7. 8. the lock cylinder, the plastic keeper in the lock cylinder protrudes and prevents installa­ tion of the sleeve assembly. Make sure that the plastic keeper in the sleeve assembly protrudes from the sleeve (fig. 56). Align the lock bolt on the lock cylinder and the tab on the anti-theft washer and the slot in the sleeve assembly (fig. 56). Push the sleeve all the way onto the lock cylinder assembly, push the ignition key the rest of the way in and rotate the lock cylinder clockwise. Rotate the lock counter-clockwise into “LOCK” position. Place the lock in a brass jawed vise or between two pieces of wood (fig. 57). NOTE: If a vise is used, place cloth around the knob to prevent m arring the knob surface. Place the adapter ring onto the lower end of the cylinder so that the finger of the adapter is located at the step in the sleeve and the serrated edge of the adapter is visible after assembly to the cylinder and before “staking” (fig. 58). The key must be free to rotate at least 1/3 of a circle (120°). NOTE: Tap the adapter onto the cylinder until it is stopped at the bottom of the cylinder flats (cylinder will extend above adapter approximately 1/16”). Using a small flat punch, at least 1/8” in diameter, stake the lock cylinder over the adapter ring in four places just outboard of the four dimples as shown in Figure 58. Check lock operation before reinstalling vehicle. Fig. 5 6 — Ig n itio n Fig. 5 7 — Ig n itio n ADAPTER SERRATIONS UP Lock C y lin d e r A s s e m b ly Lock C y lin d e r In s ta lle d in a Vise ADAPTER RING AGAINST STEP IN SLEEVE Fig. 5 8 — In s ta llin g A d a p te r R in g Installation 1. Hold the lock cylinder sleeve and rotate the knob clockwise against the stop. Insert the cylinder into the housing bore with the key on the cylinder sleeve aligned with the keyway in the housing. Push the LIGHT DUTY TRUCK SERVICE MANUAL STEERING cylinder into abutment of cylinder and sector. Hold an .070” drill between the lock bezel and housing. Rotate the cylinder counterclockwise, m aintaining a light pressure until the drive section of the cylinder mates with the sector. Push in until the snap ring pops into the grooves and the lock cylinder is secured in the housing. Remove the .070” drill. Check lock cylinder for freedom of rotation. 2. Install the Direction Signal Switch and Steering Wheel as outlined previously in this section. IGNITION SWITCH (C AND K SERIES) The ignition switch is mounted on top of the column jacket near the front of the dash. For anti-theft reasons, the switch is located inside the channel section of the brake pedal support and is completely inaccessible without first lowering the steering column (see steering column removal). The switch is actuated by a rod and rack assembly. A portion of the rack is toothed and engages a gear on the SWITCH IN LOCK POSITION Fig. 5 9 —Ignition Switch Assembly 9-37 end of the lock cylinder, thus enabling the rod and rack to be moved axially (with respect to the column) to actuate the switch when the lock cylinder is rotated. Removal 1. Lower the steering column as outlined under “Steering Column Removal” later in this section. It is not necessary to remove the steering wheel. CAUTION: I f the steering column is not removed from the vehicle, be sure that it is properly supported, before proceeding. 2. The switch should be positioned in “Lock” position before removing. If the lock cylinder has already been removed, the actuating rod to the switch should be pulled up until there is a definite stop, then moved down one detent, which is the “Lock” position. 3. Remove the two switch screws and remove the switch assembly. Installation 1. Before replacing the switch, be sure that the lock is in the “Lock” position. Make certain that the switch is in “Lock“ position (fig. 59); if it is not, a screwdriver (placed in the locking rod slot) can be used to move the switch to “Lock” . 2. Install the activating rod into the switch and assemble the switch on the column; tighten the mounting screws. CAUTION: Use only the specified screws since over-length screws could prevent a portion of the assembly from compressing under impact. 3. Reinstall the steering column assembly following the “M andatory Installation Sequence” outlined later in this section. STEERING COLUMN All models which are equipped with the Function Locking Energy Absorbing Steering Columns are one of five basic designs. 1. Synchromesh — The synchromesh column is used on models with the standard transmission and column mounted shift levers. The shift tube, within the outer column jacket, includes two lower shift levers for connection to the transmission control linkage. This column does not lock the transmission when the lock cylinder is in the "lock" position. 2. Floor Shift — This column is used on models equipped with a manual transmission with the shift lever on the floor. This column does not lock the transmission when the lock cylinder is in the "lock" position. 3. Automatic Column Shift—this column is used on all models with an automatic transmission and a standard column. This column has a single lower shift lever for shifting the automatic transmission. LIGHT DUTY TRUCK SERVICE MANUAL 9 -3 8 STEERING The transmission is locked in Park when the lock cylinder is in "Lock", thus locking the transmission. 4. Tilt Column Option automatic transmission — The upper end and steering shaft of this column is specifically designed to accommodate the optional tilt steering wheel. The lower portion of the column is the same as in item num ber 3. 5. Tilt Column Option Manual Transmission-This column is the same as the automatic transmission tilt column except incorporating provisions for the manual transmission shifting and the transmission is not locked when the lock cylinder is in "Lock" position. To perform service procedures on the steering column upper end components, it is not necessary to remove the column from the vehicle. The steering wheel, horn components, directional signal switch, and ignition lock cylinder may be removed with the column remaining in the vehicle as described earlier in this section. CAUTION: The outer mast jacket shift tube, steering shaft and instrument panel mounting bracket are designed as energy absorbing units. Because o f the design o f these components, it is absolutely necessary to handle the column with care when performing any service operation. Avoid hammering, jarring, dropping or leaning on any portion of the column. When reassem­ bling the column components, use only the specified screws, nuts and bolts and tighten to specified torque. Care should be exercised in using over-length screws or bolts as they may prevent a portion o f the column from compressing under impact. Inspection To determine if the energy absorbing steering column components are functioning as designed, or if repairs are required, a close inspection should be made. Inspection is called for in all cases where damage is evident or whenever the vehicle is being repaired due to a front end collision. Whenever a force has been exerted on the steering wheel or steering column, or its components, inspection should also be made. If damage is evident, the affected parts must be replaced. The inspection procedure for the various steering column components on all C and K Series Trucks is as follows: Fig. 6 1 —A u to m a tic T ra n s m is s io n In d ic a to r C o n n e c tio n (T y p ic a l) Shifter Shaft Separation of the shifter shaft sections will be internal and cannot be visually identified. Hold lower end of the “shifter shaft” and move “shift lever” on column through its ranges and up and down. If there is little or no movement of the “shifter shaft” , the plastic joints are sheared. Steering Shaft If the steering shaft plastic pins have been sheared, the shaft will rattle when struck lightly from the side and some lash may be felt when rotating the steering wheel while holding the rag joint. It should be noted that if the steering shaft pins are sheared due to minor collision with no appreciable damage to other components, that the vehicle can be safely steered; however, steering shaft replacement is recommended. Column Support Bracket Damage in this area will be indicated by separation of the mounting capsules from the bracket. The bracket will have moved forward toward the engine compartment and will usually result in collapsing of the jacket section of the steering column. Column Jacket Inspect jacket section of column for looseness, and/or bends. Fig. 62—Steering Column to Dash Panel - C, P and K Typical LIGHT DUTY TRUCK SERVICE MANUAL STEERING Because of the differences in the steering column types, be sure to refer to the set of instructions below which apply to the column being serviced. COLUMN REMOVAL-C AND K COLUMNS 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. NOTE: Front of dash mounting plates must be loosened whenever the steering column is to be lowered from the instrument panel. Disconnect the battery ground cable. Remove the steering wheel as outlined under “Steering Wheel Removal”. Remove the nuts and washers securing the flanged end of the steering shaft to the flexible coupling. Disconnect the transmission control linkage (backdrive linkage on floor shift models) from the column shift tube levers. Disconnect the steering column harness at the connector. Disconnect the neutral-start switch and back-up lamp switch connectors if so equipped. Remove the floor pan trim cover screws and remove the cover. Remove the screws securing the two halves of the floor pan cover; then remove the screws securing the halves and seal to the floor pan and remove the covers (figs. 62 and 63). Remove the transmission indicator cable, if so equipped (fig. 61). Move the front seat as far back as possible to provide maximum clearance. Remove the two column bracket-to-instrument panel nuts and carefully remove from vehicle. Additional help should be obtained to guide the lower shift levers through the firewall opening. 9 -3 9 DISASSEMBLY-C AND K SERIES EXCEPT TILT COLUMNS—(Fig. 64) NOTE: G and P Series columns differ from those shown in Figures 64 thru 72. 1. Remove the four dash panel bracket-to-column screws and lay the bracket in a safe place to prevent damage to the mounting capsules. 2. Place the column in a vise using both weld nuts of either Set A or B as shown in Figure 65. The vise jaws must clamp onto the sides of the weld nuts indicated by arrows shown on Set B. CAUTION: Do not place the column in a vise by clamping onto only one weld nut, by clamping onto one weld nut of both sets A and B or by clamping onto the sides not indicated by arrows, since damage to the column could result. 3. Remove the Directional Signal Switch, Lock Cylinder, and Ignition Switch as outlined previously in this section. 4. Column Shift Models —Drive out the upper shift lever pivot pin and remove the shift lever. 5. Remove the upper bearing thrust washer. Remove the four screws attaching the turn signal and ignition lock housing to the jacket and remove the housing assembly (fig. 66). 6. Remove the thrust cap from the lower side of the housing. 7. Lift the ignition switch actuating rod and rack assembly, the rack preload spring and the shaft lock bolt and spring assembly out of the housing (fig. 67). 8. Remove the shift lever detent plate (shift gate). 9. Remove the ignition switch actuator sector through the lock cylinder hole by pushing firmly on the block tooth of the sector with a blunt punch or screwdriver (fig. 68). 10. Remove the gearshift lever housing and shroud from the jacket assembly (transmission control lock tube housing and shroud on floor shift models. 11. Remove the shift lever spring from the gearshift lever housing (lock tube spring on floor shift models). 12. Pull the steering shaft from lower end of the jacket assembly. 13. Remove the two screws holding the back-up switch or netural-safety switch to the column and remove the switch. 14. Remove the lower bearing retainer clip (fig. 69). 15. Automatic and Floorshift Columns — Remove the lower bearing retainer, bearing adapter assembly, shift tube thrust spring and washer. The lower bearing may be removed from the adapter by light LIGHT DUTY TRUCK SERVICE MANUAL 9-40 STEERING LIGHT DUTY 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. Shaft Nut Cover Lock Plate Retaining Ring Lock Plate Cancelling Cam Bearing Preload Spring Turn Signal Screws Turn Signal Switch Protector Cover Turn Signal Housing Screws Bearing Thrust Washer 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. Turn Signal Housing Ignition Switch Sector Switch Rack Preload Spring Shaft Lock Bolt Switch Rod and Rack Assembly Thrust Cap Shaft Lock Bolt Washer Shift Lever Detent Plate Detent Plate Screws Shift Lever Spring Gearshift Lever Housing 25. 26. 27. 28. 29. TRUCK 30. 31. 32. 33. 34. 35. Shift Shroud Gearshift Housing Bearing Ignition Switch Screws Ignition Switch Neutral Safety or Back-Up Switch Retainers Shift Tube Thrust Spring Washer Shift Tube Thrust Spring Lower Bearing Adapter Lower Bearing Reinforcement Retainer SERVI CE MANUAL Fig. 64—Standard Steering Column Explode Typical C and K 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. Lower Bearing Shaft Stop Ring Steering Shaft Pot Joint Bolt Nut Pot Joint Cover Seal Retaining Ring Bearing Spring Bearing Blocks Pot Joint Seal Intermediate Shaft STEERING Fig. 65—Installing Steering Column in Vise 9-41 Fig. 66—Removing Turn Signal Housing SHIFT GATE RACK LOCK BOLT CK BOLT SPRING THRUST CUP Fig. 67—Turn Signal Housing Assembly Fig. 68-Removing Ignition Switch Actuator Sector pressure on the bearing outer race. Slide out the shift tube assembly. Manual Transmission — Column Shift — Remove the lower bearing adapter, bearing and the firstreverse shift lever. The lower bearing may be removed from the adapter by light pressure on the bearing outer race. Remove the three screws from bearing at the lower end and slide out the shift tube assembly. Remove the gearshift housing lower bearing from the upper end of the mast jacket. ASSEMBLY-ALL EXCEPT TILT COLUMNS NOTE: Apply a thin coat of lithium soap grease to all friction surfaces. 1. Install the sector into the turn signal and lock cylinder housing. Install the sector in the lock cylinder hole over the sector shaft with the tang end Fig. 69—Removing Lower Bearing Retainer LIGHT DUTY TRUCK SERVICE MANUAL 9 -4 2 STEERING the bearing from the very end of the jacket. Aligning the indentations in the bearing with the projections on the jacket (fig. 71). CAUTION: If the bearing is not installed correctly, it mil not rest on all of the stops provided. Fig. 70—Installing Rack Preload Spring 2. 3. 4. 5. 6. to the outside of the hole. Press the sector over the shaft with a blunt tool. Install the shift lever detent plate onto the housing. Insert the rack preload spring into the housing from the bottom side. The long section should be toward the handwheel and hook onto the edge of the housing (fig. 70). Assemble the locking bolt onto the crossover arm on the rack and insert the rack and lock bolt assembly into the housing from the bottom with the teeth up (toward hand-wheel) and toward the centerline of the column (fig. 67). Align the 1st tooth on the sector with the 1st tooth on the rack; if aligned properly, the block teeth will line up when the rack assembly is pushed all the way in. Install the thrust cup on the bottom hub of the housing. Install the gearshift housing lower bearing. Insert Fig. 71—Installing Gearshift Housing Lower Bearing 7. Install the shift lever spring into the gearshift lever (or lock tube) housing. Install the housing and shroud assemblies onto the upper end of the mast jacket. Rotate the housing to be sure it is seated in the bearing. 8. With the shift lever housing in place, install the turn signal and lock cylinder housing onto the jacket. The gearshift housing should be in “Park” position and the rack pulled downward. Be sure the turn signal housing is seated on the jacket and drive the four screws. 9. Press the lower bearing into the adapter assembly. 10. Insert the shift tube assembly into the lower end of the jacket and rotate until the upper shift tube key slides into the housing keyway. 11. Automatic and Floorshift Columns — Assemble the spring and lower bearing and adapter assembly into the bottom of the jacket. Holding the adapter in place, install the lower bearing reinforcement and retainer clip. Be sure the clip snaps into the jacket and reinforcement slots. 12. Manual Transmission — Column Shift — Loosely attach the three screws in the jacket and shift tube bearing. Assemble the 1st-Reverse lever and lower bearing and adapter assembly into the bottom of the jacket. Holding the adapter in place, install the bearing reinforcement and retaining clip. Be sure the retaining clip snaps into the jacket and reinforce­ ment slots. Place a .005” shim between the 1st-Reverse lever and lever spacer and turn the upper shift tube Fig. 72—Adjusting Lower Bearing - Typical LIGHT DUTY TRUCK SERVICE MANUAL STEERING 13. 14. 15. 16. 17. 18. bearing down and tighten the three screws. Remove the shim (fig. 72). Install the neutral-safety or back-up switch as outlined in Section 12 of this manual. Slide the steering shaft into the column and install the upper bearing thrust washer. Install the turn signal switch, lock cylinder assembly and ignition switch as previously outlined in this section. Install the shift lever and shift lever pivot pin. Remove the column from the vise. Install the dash bracket to the column; torque the screws to specifications. DISASSEMBLY—TILT COLUMNS (Figs. 73) NOTE: Steps 3-14 may be performed with the steering column in the vehicle. 1. Remove the four screws retaining the dash mounting bracket to the column and set the bracket aside to protect the breakaway capsules. 2. Mount the column in a vise using both weld nuts of either Set A or B as shown in Figure 65. The vise jaws must clamp onto the sides of the weld nuts indicated by arrows shown on Set B. CAUTION: Do not place the column in a vise by clamping onto only one weld nut, by clamping onto one weld nut of both Sets A and B or by clamping onto the sides not indicated by arrows, since damage to the column could result. 3. Remove the directional signal switch, lock cylinder and ignition switch as outlined previously in this section. 4. Remove the tilt release lever. Drive out the shift lever pivot pin and remove the shift lever from the housing. 5. Remove the three turn signal housing screws and remove the housing. 6. Install the tilt release lever and place the column in the full “up” position. Remove the tilt lever spring retainer using a #3 phillips screwdriver that just fits into the slot opening. Insert the phillips screwdriver in the slot, press in approximately 3/16”, turn approximately 1/8 turn counter­ clockwise until the ears align with the grooves in the housing and remove the retainer, spring and guide (fig. 74). 7. Remove the pot joint to steering shaft clamp bolt and remove the intermediate shaft and pot joint assembly. Push the upper steering shaft in sufficiently to remove the steering shaft upper bearing inner race and seat. Pry off the lower bearing retainer clip and remove the bearing reinforcement, bearing and 8. 9. 10. 11. 12. 13. 14. 15. 9 -4 3 bearing adapter assembly from the lower end of the mast jacket. Remove the upper bearing housing pivot pins using Tool J-21854-1 (fig. 75). Install the tilt release lever and disengage the lock shoes. Remove the bearing housing by pulling upward to extend the rack full down, and then moving the housing to the left to disengage the ignition switch rack from the actuator rod. Remove the steering shaft assembly from the upper end of the column. Disassemble the steering shaft by removing the centering spheres and the anti-lash spring. Remove the transmission indicator wire, if so equipped. Remove the four steering shaft bearing housing support to gearshift housing screws and remove the bearing housing support. Remove the ignition switch actuator rod. Remove the shift tube retaining ring with a screwdriver and then remove the thrust washer. Install Tool J-23072 into the lock plate, making sure that the tool screws have good thread engagement in the lock plate. Then, turning the center screw clockwise, force the shift tube from the housing (fig. 76). Remove the shift tube (transmission control lock tube on floor shift models) from the lower end of the mast jacket. Remove Tool J-23072. CAUTION: When removing the shift tube, be sure to guide the lower end through the slotted opening in the mast jacket. I f the tube is allowed to interfere with the jacket in any way, damage to the tube and jacket could result. 16. Remove the bearing housing support lock plate by sliding it out of the jacket notches, tipping it down toward the housing hub at the 12 o’clock position and sliding it under the jacket opening. Remove the wave washer. 17. All Columns - Remove the shift lever housing from the mast jacket (transmission control lock tube housing on floor shift models). Remove the shift lever spring by winding the spring up with pliers and pulling it out. On floor shift models, remove the spring plunger. 18. Disassemble the bearing housing as follows: a. Remove the tilt lever opening shield. b. Remove the lock bolt spring by removing the retaining screw and moving the spring clockwise to remove it from the bolt (fig. 77). c. Remove the snap ring from the sector drive shaft. With a small punch, lightly tap the drive shaft from the sector (fig. 78). Remove the drive shaft, sector and lock bolt. Remove the rack and rack spring. LIGHT DUTY TRUCK SERVICE MANUAL 9-44 STEERING LIGHT DUTY TRUCK SERVI CE 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 15. 16. 17. 18. Shaft Nut Cover Lock Plate Retaining Ring Lock Plate Cancelling Cam Bearing Preload Spring Turn Signal Screws Turn Signal Switch Protector Cover Upper Bearing Seat Upper Bearing Race Turn Signal Housing Screws Turn Signal Housing Tilt Lever Opening Shield Upper Bearing Shaft Lock Bolt MANUAL 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. Lock Bolt Spring Lock Shoes Sector Shaft Lock Shoe Pin Bearing Housing Tilt Lever Spring Retainer Tilt Lever Spring Tilt Lever Spring Guide Lock Bolt Spring Screw Sector Snap Ring Sector Bearing Housing Pivot Pins Shoe Release Springs Spring Shoe Release Lever Pin Shoe Release Lever Lower Bearing Ignition Switch Rack Spring 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. ^61 Ignition Switch Rack Ignition Switch Rod Upper Steering Shaft Centering Spheres Center Sphere Spring Lower Steering Shaft Bearing Housing Support Screws Bearing Housing Support Pin Shift Tube Index Plate Screws Shift Tube Index Plate Support Retaining Ring Support Thrust Washer Support Plate Lock Support Wave Washer Gearshift Lever Spring Gearshift Lever Housing Ignition Switch Screws Fig. 73—Tilt Steering Column Assembly (Typical C and K) 55. Ignition Switch 56. Mast Jacket 57. Neutral-Safety or Back-Up Switch Retainers 58. Shift Tube 59. Lower Bearing Adapter 60. Lower Bearing 61. Lower Bearing Reinforcement 62. Retainer 63. Pot Joint Bolt 64. Nut 65. Pot Joint Cover 66. Seal Retaining Ring 67. Bearing Spring 68. Bearing Blocks 69. Pot Joint Seal 70. Intermediate Shaft STEERING Fig. 74—Removing Tilt Lever Spring Retainer 9 -4 5 Fig. 76—Removing Shift Tube LOCK BOLT SPRING Fig. 75—Removing Bearing Housing Pivot Pins d. Remove the tilt release lever pin with a punch and hammer. Remove the lever and release lever spring. To relieve the load on the release lever, hold the shoes inward and wedge a block between the top of the shoes (over slots) and bearing housing. e. Remove the lock shoe retaining pin with a punch and hammer. Remove the lock shoes and lock shoe springs. NOTE: With the tilt lever opening on the left side and shoes facing up, the four slot shoe is on the left. f. Remove the bearings from the bearing housing only if they are to be replaced. Remove the separator and balls from the bearings. Place the housing on work bench and with a pointed punch against the back surface of the race, carefully hammer the race out of the housing Fig. 77—Replacing Lock Bolt Spring until a bearing puller can be used. Repeat for the other race. ASSEMBLY-TILT COLUMNS Apply a thin coat of lithium grease to all friction surfaces. 1. If the bearing housing was disassembled, repeat the following steps: a. Press the bearings into the housing, if removed, using a suitable size socket. Be careful not to damage the housing or bearing during installtion. b. Install the lock shoe springs, lock shoes and shoe pin in the housing. Use an approximate .180” rod to line up the shoes for pin installation. c. Install the shoe release lever, spring and pin. NOTE: To relieve the load on the release lever, hold the shoes inward and wedge a LIGHT DUTY TRUCK SERVICE MANUAL 9 -4 6 STEERING 4. Install the bearing support lock plate. Work it into the notches in the jacket by tipping it toward the housing hub at the 12 o’clock position and sliding it under the jacket opening. Slide the lock plate into the notches in the jacket. 5. Carefully install the shift tube into the lower end of the mast jacket. Align keyway in the tube with the key in the shift lever housing. Install the wobble plate end of Tool J-23073 into the upper end of the shift tube far enough to reach the enlarged portion of the tube. Then install the adapter over the end of the tool, seating it against the lock plate. Place the nut on the threaded end of the tool and pull the shift tube into the housing (fig. 80). Remove Tool J-23073. Fig. 78—Removing Sector Drive Shaft CAUTION: Do not push or tap on the end of the shift tube. Be sure that the shift tube lever is aligned with the slotted opening at the lower end of the mast jacket or damage to the shift tube and mast jacket could result. block between the top of the shoes (over slots) and bearing housing. d. Install the sector drive shaft into the housing. Lightly tap the sector onto the shaft far enough to install the snap ring. Install the snap ring. e. Install the lock bolt and engage it with the sector cam surface. Then install the rack and spring. The block tooth on the rack should engage the block tooth on the sector (fig. 79). Install the external tilt release lever. f. Install the lock bolt spring and retaining screw (fig. 74). Tighten the screw to 35 in. lbs. 2. Install the shift lever spring into the housing by winding it up with pliers and pushing it into the housing. On floor shift models, install the plunger, slide the gearshift lever housing onto the mast jacket. 3. Install the bearing support lock plate wave washer. 6. Install the bearing support thrust washer and retaining ring by pulling the shift lever housing up far enough to compress the wave washer. 7. Install the bearing support by aligning the “V” in the support with the “V” in the jacket. Insert the screws through the support and into the lock plate and torque to 60 in. lbs. 8. Align the lower bearing adapter with the notches in the jacket and push the adapter into the lower end of the mast jacket. Install lower bearing, bearing reinforcement and retaining clip, being sure that the clip is aligned with the slots in the reinforce­ ment, jacket and adapter. 9. Install the centering spheres and anti-lash spring in the upper shaft. Install the lower shaft from the same side of the spheres that the spring ends protrude. Fig. 79—Installing Lock Bolt and Rack Assemblies Fig. 80—Installing Bearing Housing LIGHT DUTY TRUCK SERVICE MANUAL STEERING 10. Install the steering shaft assembly into the shift tube from the upper end. Carefully guide the shaft through the shift tube and bearing. 11. Install the ignition switch actuator rod through the shift lever housing and insert in the slot in the bearing support. Extend the rack downward from the bearing housing. 12. Assemble the bearing housing over the steering shaft and engage the rack over the end of the actuator rod (fig. 81). 13. With the external release lever installed, hold the lock shoes in the disengaged position and assemble the bearing housing over the steering shaft until the pivot pin holes line up. 14. Install the pivot pins. 15. Place the bearing housing in the full “up” position and install the tilt lever spring guide, spring and spring retainer. With a suitable screw driver, push the retainer in and turn clockwise to engage in the housing. 16. Install the upper bearing inner race and race seat. 17. Install the tilt lever opening shield. 18. Remove the tilt release lever, install the turn signal housing and torque the three retaining screws to 45 in. lbs. 19. Install the tilt release lever and shift lever. Drive the shift lever pin in. 20. Install the lock cylinder, turn signal switch and ignition switch as outlined previously in this section. 21. Align the groove across the upper end of the pot joint with the flat on the steering shaft. Assemble the intermediate shaft assembly to the upper shaft. Install the clamp and bolt and torque the nut to specifications. 9 -4 7 NOTE: The clamp bolt must pass through the shaft under cut. 22. Install the neutral-safety switch or back-up switch as outlined in Section 12 of this manual. 23. Install the four dash panel bracket to column screws and torque to specifications. CAUTION: Be sure that the slotted openings in the bracket (for the mounting capsules) face the upper end of the steering column. COLUMN INSTALLATIONMANDATORY SEQUENCE C and K SERIES VEHICLES (Fig. 82) Mandatory Instructions 1. Assemble lower dash cover (A) and upper dash cover (B) to seal (C) with “Carrots” (part of seal). 2. Attach bracket (D) to jacket and tighten four bolts (E) to specified torque. Mandatory Installation Sequence 1. Position column in body and position flange to rag joint and install lock washers and nuts (F) (May be tightened to specified torque at this time). NOTE: Coupling (G) on manual steering must be installed prior to column installation. SHIFT BOWL J 23073-3 J 23073-4 W A V E^ WASHER LOCK PLATE J 23073-1 J 23073-2 UPPER SHIFT TUBE Fig. 81—Installing Shift Tube FLAT WASHER Fig. 82—Steering Column Installation (C and K) LIGHT DUTY TRUCK SERVICE MANUAL 9 -4 8 STEERING 2. Loosely assemble (2) capsule nuts (H) at the instrument panel bracket (D). 3. Position lower clamp (J) and tighten attaching nuts (K) to specified torque. 4. Tighten two nuts (H) at capsules to specified torque. 5. Install seal (C) and covers (A and B) to dash. 6. Install attaching screws (L) and tighten to specified torque. 7. Tighten two nuts (F) at capsules to specified torque if not already done. 8. Remove plastic spacers (M) from flexible coupling pins. 9. Install transmission indicator cable on column automatics. 10. Install the instrument panel trim cover. 11. Connect the transmission control linkage at the shift tube levers. 12. Install the steering wheel as outlined previously in this section. 13. Connect the battery ground cable. STEERING COLUMN LOWER BEARING P SERIES Mandatory System Requirements DIRECTIONAL SIGNAL SWITCH-G AND P SERIES COLUMNS 1. Pot joint operating angle must be 1 1/2° ± 4°. 2. Flexible coupling must not be distorted greater than ±.06 due to pot joint bottoming, in either direction. STEERING COLUMN SERVICE FOR G AND P SERIES STEERING COLUMN UPPER BEARING—G AND P SERIES Standard Column Removal 1. Remove steering wheel as outlined in this section. 2. Remove directional signal cancelling cam. 3. Pry out upper bearing. Removal 1. Remove the intermediate steering shaft and universal joint assembly as outlined earlier in this section. Remove the preload spring clamp and spring from the end of the steering shaft. 2. Pry out the lower bearing assembly. Installation CAUTION: See CAUTION note on page 1 of this section regarding fasteners referred to in step 2. 1. Place the new bearing over the end of the steering shaft and press into position in the column. 2. Install the preload spring and clamp and torque the clamp bolt nut to specifications while maintaining the dimension shown in Figure 87. Reinstall the intermediate shaft and universal joint assembly as outlined under “Intermediate Steering Shaft with Universal Joint Couplings - Installation”. If the directional signal switch must be replaced, the steering column does not have to be removed from the vehicle. Removal 1. Remove the steering wheel as outlined under “Steering Wheel - Removal”. 2. Remove the directional signal switch cancelling cam and spring. 3. Remove the column to instrument panel trim plate (if so equipped). Installation CAUTION: See CA UTION on page 1 o f this section regarding the fasteners referred to in step 1. 1. Replace all component parts in reverse order of removal making sure that directional signal switch is in neutral position before installing steering wheel. Torque steering wheel nut to specifications. Tilt Column The upper bearings on the tilt column are spun into the bearing housing assembly. If the bearings indicate need of replacement, the entire bearing housing must be replaced. See “Tilt Steering Column - Disassembly and Assembly” for the correct replacement procedure. Fig. 83—Removing Wiring Harness Protector LIGHT DUTY TRUCK SERVICE MANUAL STEERING Fig. 84—Removing Wires from Connector 4. Disconnect the directional signal switch wiring harness at the half-moon connector. 5. Pry the wiring harness protector out of the column retaining slots as shown in Figure 83. 6. Mark the location of each wire in the half-moon connector and then remove each individual wire from the connector using Tool J-22727 (fig. 84). Insert the tool into the lower end of the connector and push in until the tool bottoms on the connector. Remove the tool and then pull the wire from the connector. 7. Remove the directional signal lever screw and remove the lever. 8. Push in on the hazard warning light knob and then unscrew and remove the knob. 9. Tilt Columns Only— a. Automatic Transmission Models - Remove the PRNDL dial screws and remove the dial and indicator needle. Remove the cap and dial illumination bulb from the housing cover. b. Unscrew and remove the tilt release lever. c. Assemble Tool J-22708 inside the directional signal housing cover; push in until the tangs lock inside the cover flange (fig. 85). Turn the tool center screw clockwise to pull the cover from the housing. 10. Remove the three directional signal switch mounting screws and then carefully remove the switch assembly from the column while guiding the wiring harness through the opening in the shift lever housing. Installation CAUTION: See CAUTION on page 1 of this section regarding the fasteners referred to in step 9. 1. Wrap the ends of the directional signal switch wires 9 -4 9 with tape and then guide them through the opening at the lower left hand side of the bearing housing (tilt columns) out the lower end of the shift lever housing and under the dash seal. 2. Place the directional signal switch in position and install the three mounting screws; torque to.25 in. lbs. after screw head has been firmly seated. 3. Tilt Columns Only— a. Align the openings in the directional signal switch cover with the proper lever positions and tap the cover into place using a plastic hammer. b. Install the tilt release lever. c. Automatic Transmission Models - Install the PRNDL dial, pointer, dial illumination bulb and cap. 4. Install the directional signal switch lever and hazard warning knob. J-22708 Fig. 85—Removing Directional Signal Housing Cover BEND TABS OUTWARD EACH SIDE Fig. 86—Preparing Wire Retaining Tabs for Installation LIGHT DUTY TRUCK SERVICE MANUAL 9 -5 0 STEERING 5. Bend the wire retaining tabs slightly outward on each wire in the wiring harness as shown in Figure 86; this will provide proper retention of the wire in the half-moon connector. 6. Install each wire in its marked location in the half­ moon connector. Push in until square part of clip is flush with the bottom side of the connector. Connect the directional signal switch wiring harness. 7. Snap the wiring harness protector into the column retaining slots. 8. Install the directional signal cancelling cam and spring. 9. Install the steering wheel as outlined under “Steering Wheel - Installation”. 10. Install the column to instrument panel trim plate (if so equipped). TILT COLUMN BEARING HOUSING ASSEMBLY - G AND P SERIES Removal (Column in Vehicle) 1. Disconnect the battery gound cable. 2. Remove the steering wheel as outlined on Page 9-29. 3. Remove the directional signal switch as outlined on Page 9-48. 4. Column Shift Models- Using a suitable size punch, drive out the shift lever pivot pin and remove the shift lever. 5. Install the tilt release lever and place the column in the full “up” position. Remove the tilt lever spring and retainer using a screwdriver that just fits into the slot opening. Insert the screwdriver into the slot, push in approximately 3/16”, rotate clockwise approximately 1/8 turn until the retainer ears align with the grooves in the housing and remove the retainer and spring. 6. Remove the steering shaft bearing locknut using Socket J-22599. Remove the upper bearing race seat and race. 7. Remove the two bearing housing pivot pins using Tool J-21854. 8. Pull up on the tilt release lever (to disengage the lock shoes) and remove the bearing housing. If the bearing housing is being replaced or it is necessary to disassemble the bearing housing, proceed as follows: a. Press the upper and lower bearings out of the housing. b. Using Puller J-5822 and Slide Hammer J-2619, pull the bearing races from the housing. c. Remove the tilt release lever. d. Drive out the shoe release pivot pin using Tool J-22635 or a suitable punch. Remove the lever spring and remove the wedge. e. Using a suitable size punch, drive out the lock shoe retaining pin. Remove the shoes and shoe springs. If the upper steering shaft, lower steering shaft, or centering spheres are being removed, proceed as follows: 9. To remove the steering shaft assembly through the upper end of the column. If it is necessary to disassemble the shaft, proceed as follows: a. To remove the lower steering shaft first disconnect the shaft at the pot joint coupling clamp. b. Turn the upper shaft 90° to the lower shaft and slide the upper shaft and centering spheres from the lower shaft. c. Rotate the centering spheres 90° and remove the centering spheres and preload spring from the upper shaft. If the bearing housing support is being replaced, proceed as follows: 10. Remove the four bearing housing support screws and remove the support. Assembly CAUTION: See caution note on page 7 of this section regarding the fasteners referred to in steps 3, 9 and 11. 1. Assemble the steering shaft as follows: a. Lubricate and assemble the centering spheres and preload spring. b. Install the spheres into the upper (short) shaft and rotate 90°. c. Install the lower shaft 90° to the upper shaft and over the centering spheres. Slowly straighten the shafts while compressing the preload spring. 2. Install the shaft assembly into the housing from the upper end. 3. Install the lower shaft to the pot joint coupling clamp. Install the coupling clamp bolt and torque to specifications. NOTE: The coupling bolt must pass through the shaft undercut. 4. Assemble the bearing housing as follows: a. Press the new upper and lower bearing races into the bearing housing. b. Lubricate and install the bearings into the bearing races. c. Place the lock shoe springs in position in the housing. Install each shoe in place and compress the spring until a suitable size straight punch can be used to hold the shoe in position (it may LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-51 CLUTCH A N D BRAKE PEDAL SUPPORT PROTRUSION INDEX SLOT VIEW A Fig. 87—Steering Column Installation-G Series 5. 6. 7. 8. 9. 10. be necessary to acquire assistance to install the shoes. Once the shoes are in place, drive in the shoe retaining pin. d. Install the shoe release lever and drive in the pivot pin. e. Install the tilt release lever. f. Lubricate the shoes and release lever. Install the bearing housing assembly to the support. Hold the tilt release lever in the “up” position until the shoes have fully engaged the support. Lubricate and install the bearing housing pivot pins. Press the pins in flush with the housing. Place the housing in the full “up” position and then install tilt spring and retainer (tapered end of spring first). Push into the housing approximately 3/16” and rotate counterclockwise 1/8 turn. Lubricate and install the upper bearing race, race seat and locknut. Tighten the locknut (using Socket J-22599) to remove the lash and then carefully further tighten 1/16 to 1/8 of a turn (column must be in straight ahead position). Remove the tilt release lever. Install the directional signal switch as outlined on Pages 948. Column Shift Models - Install the shift lever and pivot pin. 11. Install the steering wheel as outlined on Page 9-29. 12. Check electrical and mechanical functioning of column. STEERING COLUMN G AND P SERIES Removal (Fig. 87) 1. Disconnect the battery ground cable. 2. Column Shift Models - Disconnect transmission shifter rods at the lower end of the column. 3. G Models - Remove the steering shaft flange to flexible coupling bolts. P Models - Remove the intermediate steering shaft upper universal yoke to steering shaft pinch bolt. Mark the coupling to shaft relationship. 4. Remove column clamp screw(s) on engine side of firewall if equipped and remove or slide the clamp down the column. 5. Front inside the vehicle, remove the screws from the toe pan cover and slide the cover and seal up the column. 6. Remove the steering wheel as outlined under “Steering Wheel-Removal,” and reinstall the shaft nut and washer. 7. All Columns - Disconnect the directional signal wiring harness. LIGHT DUTY TRUCK SERVICE MANUAL 9 -5 2 STEERING 16 , 15 1. Upper Steering Shaft 13. Shift Tube Felt W asher 25. Turn Signal Sw itch Screw 2. Shift Housing Bushing 14. Shift Tube Assembly 2 6. Turn Signal Switch 3. Bushing Seat 15. Shift Lever Spacer 2 7. Steering Shaft Upper Bearing 4. Mast Jacket 16. Ist-Reverse S hift Lever 28. Sw itch C o n ta c t Support 5. Colum n Cover 17. A djusting Ring 29. Turn Signal Housing 6. B ack-U p Lamp Sw itch Screw 18. Shaft Lower Bearing 30. 31. Turn Signal Sw itch Lever Screw Turn Signal Sw itch Lever 32. Rubber Ring 7. B ack-U p Lamp Sw itch 8. Toe Pan Seal Retainer 19. 20. Lower Bearing Preload Spring Preload Spring C lam p 9. Toe Pan Seal 21. N u t and Lockwasher 33. Plastic Thrust Washer 10. Adjusting Ring Clam p Screws 22. Steering Shaft N u t 34. Shift Lever Housing 11. 23 . Lockwasher 35. Shift Lever Pin 24 . Turn Signal C a n c e llin g Cam 36. Shift Lever N u t and Lockwasher 12. Adjusting Ring Clam p Bolt Fig. 88—Standard Colum n - Exploded (Typical G and P) Standard Column with Automatic Transmission Disconnect the conductor tube (for transmission indicator) at the instrument panel. Tilt Column with Automatic Transmission Disconnect the single wire at the fuse block and unclip it from the parking brake bracket. 8. Remove the cap screws from the column support bracket at the dash panel. 9. Carefully lower and then withdraw the column assembly, rotating so that the shift levers clear the toe pan opening. Disassembly-Standard Column (Fig. 88) NOTE: For floor shift transmission models, omit Steps 4, 14, 15 and 16. 1. Remove the steering wheel nut and lock washer and then slide the steering shaft assembly from the lower end of the column. 2. G Models - Remove the lower bearing preload spring and clamp from the steering shaft. P Models - Remove the lower bearing preload spring and clamp. 3. Remove the back-up lamp switch. 4. Drive out the shift lever pivot pin and remove the shift lever. 5. Remove the directional signal cancelling cam. Remove the directional signal switch lever. 6. Remove the column wiring harness cover. 7. Remove the directional signal switch screws. 8. Rotate the directional signal switch housing counterclockwise and remove the housing from the column. NOTE: The housing and switch cannot be fully removed from the column until the shift lever housing is removed. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9. Remove the plastic thrust washer assembly and then remove the shift lever housing (or extension housing) from the column. 10. Separate the directional signal switch, switch control support assembly, directional signal housing and shift lever housing (or housing extension) assemblies. 11. Press the steering shaft upper bearing out of the switch contact support. 12. Remove the shift lever housing (or extension housing) seat and bushing from the upper end of the column. 13. Remove the bolt and screws from the adjusting ring clamp and remove the clamp, adjusting ring and lower bearing. Press the lower bearing out of the adjusting ring. 14. 3-Speed Columns - Remove 1st-reverse shift lever and lever spacer. Automatic Columns - Remove the selector plate clamping ring screws (3). 15. Place the column upright on the floor, supporting it with two pieces of wood. Place a block of wood on the upper end of the shift tube. Press down on the shift lever with foot while tapping on the wood block to withdraw the tube from the column jacket. NOTE: In some tolerance stack-up cases it may be necessary to use a press. Be careful not to damage the tube or jacket. 16. Remove the felt seal from the shift tube. 17. Remove firewall clamp, toe pan seal and dash panel seals from the jacket. Assembly—Standard Column 1. 2. 3. 4. 5. NOTE: In the following assembly sequence use any general purpose lithium soap grease for lubricating those components so indicated. Install the dash panel seal, toe panel and firewall clamps over the end of the jacket. Lubricate all bearing surfaces on the shift tube. Place the felt seal onto the shift tube (next to spring) and then place the shift tube in the jacket. 3-Speed Columns - Temporarily install spacer, 1streverse shift lever and lower adjusting ring. Place a block of wood on top of the adjusting ring and tap until the shift tube bottoms. Remove adjusting ring, shift lever and spacer. NOTE: The shift tube spring retainer must ' be bottomed against the jacket stops. Automatic Columns - Align the three holes in the selector plate with the three holes in the jacket, position the clamping ring and install the three screws. 3-Speed Columns - Lubricate and install the spacer 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 9 -5 3 and 1st-reverse shift lever (tang of lever towards top of column). Install lower bearing in the adjusting ring and then install the adjusting ring, clamp and screws. Install the shift lever housing (or extension housing) seat and bushing to upper end of housing. Thread directional signal switch wiring harness through the switch and shift lever (or extension) housings, lubricate the inner diameter of the shift housing, and then place the shift lever (or extension) housing onto the upper end of the column. Install the switch housing plastic washer assembly. Press the upper bearing into the switch contact support. Install the directional signal switch housing, contact support, bearing and switch and torque the switch screws to 25 in. lbs. Install the column wiring harness cover and back­ up lamp switch. Install the directional signal and gearshift levers. Adjust the shift tube as outlined under “Shifter Tube Adjustment.” Loosely install the lower bearing preload spring and clamp. Slide the steering shaft assembly up through the column assembly. Install the directional signal cancelling cam, steering shaft nut and lock washer. Disassembly—Tilt Column (Fig. 89) 1. If the column is removed from the vehicle, place the column in a bench vise using Holding Fixtures J-22573 (fig. 90). CAUTION: Clamping the column directly in a vise, could result in a damaged column. 2. Remove the directional signal switch as outlined under “Directional Signal Switch-Removal”. 3. Remove the lower steering shaft and pot joint assembly and lower bearing and adapter assembly as outlined under “Lower Bearing and AdapterRemoval”. 4. Column Shift Models - Using a suitable size punch, drive out the shift lever pivot pin and remove the shift lever. 5. Install the tilt release lever and place the column in the full “up” position. Remove the tilt lever spring and retainer using a screw driver that just fits into the slot opening (fig. 91). Insert the screw driver into the slot, push in approximately 3/16”, rotate clockwise approximately 1/8 turn until the retainer ears align with the grooves in the housing and remove the retainer and spring. 6. Remove the steering shaft bearing locknut using LIGHT DUTY TRUCK SERVICE MANUAL 9-54 STEERING COVER SH AFT ASSY. -------RACE W EDGE SCREW (3 ) S P R IN G S W IT C H A S S Y .- . PIN D O W E L SHAFT A S S Y . STEER IN G B E A R IN G ASSY. ^ YOKE IN S T R U . PANEL O P E N IN G C O V E R - , SHAFT RACE JACKET A S S Y .- SH O E BUMPER (3 ) S P R IN G ( 2 K \ PR OTECTOR \ , H O U S I N G ------ H O U S IN G ASSY. B E A R IN G RETAINER SPHERE C E N T E R IN G (2 ) SHAFT > JACKET SU PP O R T AS SY . Q S P R IN G RELEASE, SUPPOR T PIN RELEASE — *-D # j . \ S H O E RELEASE— — ■ ' V B E A R IN G A S S Y . — S P R IN G TILT * “ (2 ) ^ <2 > PIN P1VOT B O W L AS SY , TUBE A S S Y . SHIFT —p SCREW „ D A S H SEAL SC REW (4 ) S P R IN G V- PLATE \ RETAINER THRUST W A S H E R \ PLATE LO C K W AVE W ASHER BOW L LEVER ADAPTER RETAINER ------ CLIP JACKET D A S H SEAL RETAINER B E A R IN G LIGHT DUTY TRUCK SERVICE MANUAL Fig. 89—Tilt Steering Column • G and P Series Explode W IRE STEERING Fig. 90—Securing Column with J-22573 9 -5 5 Fig. 92—Removing Bearing Housing Pivot Pin STEERING SHAFT BEARING LOCKNUT TILT LEVER SPRING RETAINER Fig. 91—Removing Tilt Spring and Retainer socket J-22599. Remove the upper bearing race seat and race. 7. Remove the two bearing housing pivot pins using Tool J-21854 (fig. 92). 8. Pull up on the tilt release lever (to disengage the lock shoes) and remove the bearing housing. If it is necessary to disassemble the bearing housing, proceed as follows: a. Press the upper and lower bearings out of the housing. b. Using Puller J-5822 and Slide Hammer J-2619 pull the bearing races from the housing (fig. 93). c. Remove the tilt release lever. d. Drive out the shoe release lever pivot pin using Tool J-22635 or a suitable punch (fig. 94). Remove the lever spring and remove the wedge. e. Using a suitable size punch, drive out the lock Fig. 93-Removing Bearing Race F'S- 94-Removing Release Lever Pivot Pin LIGHT DUTY TRUCK SERVICE MANUAL 9 -5 6 STEERING 'i. 10. 11. 12. 13. 14. shoe retaining pin. Remove the shoes and shoe springs. Remove the steering shaft assembly through the upper end of the column. If it is necessary to disassemble the shaft proceed as follows: a. Turn the upper shaft 90° to the lower shaft and slide the upper shaft and centering spheres from the lower shaft. b. Rotate the centering spheres 90° and remove the centering spheres and preload spring from the upper shaft. Remove the four bearing housing support screws and remove the support. Column Shift Models - If the shift tube index plate must be removed, remove the two retaining screws and remove the plate. Remove the shift tube retaining ring with a screw driver (fig. 95). Remove the thrust washer. Remove the neutral-safety or back-up lamp switch screws and remove the switch. Rework Shift Tube Removing Tool J-22551 by removing 1/2” from the pilot end of the tool (Fig. 96). This allows the shift tube to be pushed further out of the housing and will not affect the use of the tool on other columns. Remove the shift tube assembly using Tool J-22551 (fig. 97). Insert the hooked end of the tool into the notch in the shift tube just below the shift lever housing key. Pilot the sleeve over the threaded end of the tool and into the upper end of the shift tube. Force the shift tube out of the housing by turning the nut onto the tool. If the shift tube is not completely free when the nut is bottomed on the threads, complete the removal by hand. CAUTION: Do Not hammer or pull on the shift tube during removal. On column shift models, guide the lower shift lever through the slotted opening in the column to prevent damage to the tube or column. 15. Remove the lock plate by sliding out of the column notches, tipping the plate downward toward the housing (to compress the wave washer) and then removing as shown in Figure 98. Remove the wave washer. 16. Remove the shift lever housing. 17. Column Shift Models - Remove the shift lever spring by winding the spring up with pliers. 18. If necessary, remove the dash panel seal, mounting plate and the instrument panel seal from the column jacket. Assembly—Tilt Columns 1. 2. 3. 4. 5. Fig. 95—Removing Shift Tube Retaining Ring NOTE: When lubricating components during the following installation sequence, use any general purpose lithium soap grease. Install the dash panel seal, mounting plate and the instrument panel seal on the column. Column Shift Models - Press a new shift lever spring into the shift lever housing. Slide the shift lever housing over the upper end of the column. Place the wave washer and lock plate in position. Work the lock plate into the notches by tipping the plate toward the housing (compressing the wave washer) at the open side of the column. Lubricate the lock plate and upper end of the shift tube. Carefully install the shift tube into the lower end of the column (make sure the foam seal is at the lower end of the shift tube). Align the keyway in the tube with the key in the shift lever housing and complete installtion of the shift tube using Tool J-22549 (fig. 99). The shift lever housing key must bottom in the shift tube slot to be fully installed. Remove Tool LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9 -5 7 HOOK END OF TOOL SLOT IN SHIFT TUBE Fig. 97—Removing Shift Tube Assembly LOCK PLATE Fig. 98—Removing Lock Plate Assembly J-22549 from the column. Lubricate and push foam seal in flush with column housing. CAUTION: Do Not hammer or force the tube when installing in the column. 6. Pull up on the shift lever housing (to compress the wave washer) and install the thrust washer and retaining ring. Be sure the ring is seated in both slots of the shift tube. 7. Lubricate the I.D. of the bearing housing support and install the support, aligning the bolt holes in the support with the bolt holes in the lock plate. Install the four support screws and torque to 45 in. lbs. 8. Assemble the steering shaft as follows: a. Lubricate and assemble the centering spheres and preload spring. Fig. 99—Installing Shift Pin Tube b. Install the spheres into the upper (short) shaft and rotate 90°. c. Install the lower shaft 90° to the upper shaft and over the centering spheres. Slowly straighten the shafts while compressing the preload spring. 9. Install the shaft assembly into the housing from the upper end. 10. Install the lower bearing and adapter, bearing reinforcement, wire clip, pot joint coupling and lower shaft as described under “Lower Bearing Installation”. 11. Assemble the bearing housing as follows: a. Press the new upper and lower bearing races into the bearing housing. b. Lubricate and install the bearings into the bearing races. c. Place the lock shoe springs in position in the LIGHT DUTY TRUCK SERVICE MANUAL 9 -5 8 STEERING 12. 13. 14. 15. 16. 17. 18. 19. housing. Install each shoe in place and compress the spring until a suitable size straight punch can be used to hold the shoes in position (it may be necessary to acquire assistance to install the shoes). Once the shoes are in place, drive in the shoe retaining pin. d. Install the shoe release lever and drive in the pivot pin. e. Install the tilt release lever. f. Lubricate the shoes and release lever. Install the bearing housing assembly to the support. Hold the tilt release lever in the “up” position until the shoes have fully engaged the support. Lubricate and install the bearing housing pivot pins. Press the pins in flush with the housing. Place the housing in the full “up” position and then install tilt spring and retainer (tapered end of spring first). Push into the housing approximately 3/16” and rotate counter clockwise 1/8 turn. Lubricate and install the upper bearing upper race, race seat and locknut. Tighten the locknut (using Socket J-22599) to remove the lash and then further tighten 1/16 to 1/8 of a turn (column must be in straight ahead position). Remove the tilt release lever. Install the directional signal switch as outlined under “Directional Signal Switch-Installation”. Column Shift Models - Install the shift lever and pivot pin. Install the neutral-safety or back-up lamp switch. Remove the column from the bench vise. COLUMN INSTALLATION-MANDATORY SEQUENCE P SERIES (Fig. 87) CAUTION: See CAUTION note on page 1 of this section regarding the fasteners referred to in steps 1, 2, 3, and 10. 1. Applying 50 lbs. force on the steering wheel end of the steering shaft, adjust the lower bearing preload to allow steering shaft end play as indicated in Figure 87. Tighten the shaft clamp on pot joint bolt to specifications. 2. From the passenger side of the dash panel, carefully insert the lower end of the steering column through the toe panel opening. Guide the steering shaft into the universal yoke, lining up the marks made at removal. Install the yoke pinch bolt and torque to specifications. The pinch bolt must pass through the shaft undercut. 3. Position and attach the lower clamp mounting bracket to the firewall. Locate the steering column protrusions against the toe pan bracket while at the same time, aligning protrusion in brake and clutch pedal support with index slot in the steering column, as shown in Figure 87. Install the column to bracket clamp and torque the clamp bolt to specifications. NOTE: The toe pan bracket must not override the protrusions on the steering column. 4. Position the steering column to dash panel bracket, install the attaching bolts and torque to specifications. 5. If plastic spacers were used on the flexible coupling alignment pins, remove the spacers after all bolts have been properly torqued. 6. Install the seal at the toe pan and then install the toe pan bracket screws; torque to specifications. 7. Install the dash panel trim plate (if so equipped). 8. Connect the transmission shift linkage on column shift models. Fig. 100—Conductor Tube for Automatic Transmission I ndicator LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9. All Columns - Connect the directional signal wiring harness. Standard Column with Automatic Transmission Connect the conductor tube (for transmission indicator) at the instrument panel (fig. 100). 10. Install steering wheel as outlined under “Steering Wheel-Installation”. 11. Connect battery ground cable. Column Installation—Mandatory Sequence G Series CAUTION: See CAUTION on page 1 of this section regarding the fasteners referred to in steps 3 and 10. 1. Adjust the column lower bearing preload by applying a force on the steering wheel end of the steering shaft (A). Position the spring and clamp to maintain the dimension as shown in Figure 87. 2. Install the plastic spacers onto the flexible coupling alignment pins. 3. From inside the vehicle, carefully insert the lower end of the column through the toe pan opening guiding the steering shaft flange onto the flexible coupling. Install and torque the flange to coupling bolts. 4. Locate the index slot in the column jacket with the protrusion on the clutch and brake pedal support. 5. Loosely install the column dash bracket and screws. 6. Push the column down until the steering shaft flange bottoms on the plastic spacers on the flexible coupling and then torque the dash bracket screws. 7. Remove the plastic spacer from the alignment pins using a wire hook. Check the rag joint to steering shaft flange clearance (.250" to .325"), if not within specifications, the dash bracket screws must be loosened and the column raised or lowered as required. Retorque the bracket screws. CAUTION: The alignment pin plastic spacers must be removed before the vehicle can be driven. 8. Push the tow pan seal to the toe pan, install and torque the mounting screws. 9. All Columns Connect the directional signal switch wiring harness. Automatic Columns-Connect the conductor tube (for transmission indicator) to the instrument panel. 10. Install the steering wheel as outlined under "Steering Wheel Installation". 11. Connect the transmission linkage. 12. Connect the battery ground cable. 9 -5 9 STEERING LINKAGE CAUTION: See CAUTION on page 1 of this section regarding all fasteners referred to in servicing steering linkage components. Tie Rods Removal 1. Raise vehicle on hoist. 2. Remove cotter pins from ball studs and remove castellated nuts. 3. To remove outer ball stud, tap on steering arm at tie rod end with a hammer while using a heavy hammer or similar tool as a backing (fig. 103). 4. Remove inner ball stud from relay rod using same procedure as described in Step 3. 5. To remove tie rod ends from tie rod, loosen clamp bolts and unscrew end assemblies. Installation CAUTION: See the CAUTION on page 1 of this section regarding the fasteners referred to in steps 4 and 6. NOTE: Tie rod adjuster components often become rusted in service. In such cases, it is recommended that if the torque required to remove the nut from the bolt after breakaway exceeds 7 pound-feet, discard the nuts and bolts. Apply penetrating oil between the clamp and tube and rotate the clamps until they move freely. Install new bolts and nuts having the same part number to assure proper clamping at the specified nut torque. CAUTION: As a guide to correct orientation of the inner tie rod end relative to the outer tie rod end, rotate both ends to the extremes of travel in the same direction before clamping. The position of each tie rod end must be maintained as the clamps are tightened to ensure free movement of each joint. Return the rod assembly to midposition of its travel. This should result in the inner and outer ball studs being retained in a parallel relationship with the intermediate (relay) rod and steering knuckle (arm) respectively. The following procedure should be used when installing tie rods. 1. If the tie rod ends were removed, lubricate the tie rod threads with EP Chassis lube and install ends on tie rod making sure both ends are threaded an equal distance from the tie rod. 2. Make sure that threads on ball studs and in ball stud nuts are perfectly clean and smooth. Check condition of ball stud seals; replace if necessary. NOTE: Tool J-24434 may be used to install ball stud seals. LIGHT DUTY TRUCK SERVICE MANUAL 9 6 0 STEERING |C I ICAUTIONl Clamp must be between & clear of dimples before torquingnut. 1D 1 Exposed socket thread length must be equal within± . 0 6 at each end of adjusting sleeve on L.H. &R.H.tie rod asm. C-SERIES VANS K-SERIES MOTOR HOME MOTOR HOME Fig. 102—Steering Linkage LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-61 NOTE: If threads are not clean and smooth, ball studs may turn in tie rod ends when attempting to tighten nut. 3. Install ball studs in steering arms and relay rod. 4. Install ball stud nut, tighten to specifications and install new cotter pins; see Specifications Section at rear of manual. Lubricate tie rod ends. NOTE: Never back off nut to align the cotter pin, always tighten nut to next slot that lines up with hole in stud. 5. Adjust toe-in as described in Section 3. CAUTION: Before tightening the tie rod adjusting sleeve clamp bolts, be sure that the following conditions have been met: a. The sleeve clamps must be positioned between the locating dimples at either end of the sleeve. b. The clamps must be positioned within the angular travel indicated in Figure 104. c. The relationship of the clamp slot with the slit in the sleeve should be maintained as shown in Figure 104. d. Rotate both inner and outer tie rod housing rearward to the limit of ball joint travel before tightening clamps. Tighten clamps to specifica­ tions. Return tie rod assembly to the center of travel. e. All procedures for alignment, adjustment and assembly of tie rods applies to each side. f. Check each assembly to be sure that a total travel of at least 35° can be obtained using a bubble protractor and a pair of vise grips. Fig. 104—Tie Rod Clamp Relationships Inspection To ensure proper installation, it is necessary to perform the following inspection after any change of toe setting or removal of any ball stud: Fig. 104A—Tie Rod Inspection Fig. 103—Ball Stud Removal - Typical 1. Check the total rotation of the tie rod assembly using the following procedure: a. Lubricate inner and outer tie rod ends. b. Attach vise grip pliers to the outer tie rod end. c. Rotate outer tie rod end counterclockwise (up) to maximum position. Attach bevel protractor as shown in Figure 104A. Center protractor bubble indicator and record reading. d. Rotate tie rod end clockwise (down) to maximum position. Center protractor bubble indicator and record reading. e. Compare protractor readings obtained in Steps c LIGHT DUTY TRUCK SERVICE MANUAL 9 -6 2 STEERING and d. Total rotation of tie rod assembly should measure at least 35°. f. If rotation is less than 35°, loosen one tie rod sleeve clamp and rotate both tie rod ends to their maximum limit both ends must be rotated in the same direction g. Tighten tie rod clamp and again rotate both ends to their maximum limits, repeating Steps c and d. This recheck of total rotation will result in a minimum of 35° travel. h. After obtaining the correct amount of rotation (35° or greater), position the outer tie rod end approximately midway in this travel. If rotating checks, outlined above, reveal a rough or lumpy feel, the inner or outer tie rod end assembly may have excessive wear and should be replaced. If all of the above mentioned conditions are met, proper tie rod installation is assured. Relay Rod Removal 1. Raise vehicle on hoist. 2. Remove inner ends of the tie rods from relay rod as described under “Tie Rod—Removal”. 3. Remove the cotter pins from the pitman and idler arm ball studs at the relay rod. Remove the castellated nuts. 4. Remove the relay rod from the pitman and idler arms by tapping on the relay rod ball stud bosses with a hammer, while using a heavy hammer as a backing (fig. 103). 5. Remove the relay rod from the vehicle. Installation CAUTION: See the CAUTION on page 1 of this section regarding the fasteners referred to in steps 2 and 3. 1. Make sure that threads on the ball studs and in the ball stud nuts are perfectly clean and smooth. Check condition of ball stud seals; replace if necessary. NOTE: If threads are not clean and smooth, ball studs may turn in sockets when attempting to tighten nut. 2. Install the relay rod to the idler arm and pitman arm ball studs, making certain the seals are in place. Install and torque the nut to specifications and then install the cotter pin. NOTE: Never back off the nut to align cotter pin, always tighten nut to next slot that lines up with hole in stud. 3. Install the tie rods to the relay rod as previously described under “Tie Rod—Installation”. Lubricate the tie rod ends. 4. Lower the vehicle to the floor. 5. Adjust toe-in (see Section 3) and align steering wheel as described previously in this section under “Steering Wheel Alignment and High Point Centering”. Idler Arm Removal 1. Raise vehicle on a hoist. 2. Remove the cotter pin and castellated nut from ball stud at the relay rod. Remove the ball stud from the relay rod by tapping on the relay rod boss with a hammer, while using a heavy hammer as a backing (fig- 103). 3. Remove the idler arm to frame bolt and remove the idler arm assembly. Installation CAUTION: See the CAUTION on page 1 of this section regarding the fasteners referred to in steps 1 and 3. 1. Position the idler arm on the frame and install the mounting bolts (special plain washers under bolt heads); torque the nuts to specifications. 2. Make sure that the threads on the ball stud and in the ball stud nut are perfectly clean and smooth. Check condition of ball stud seal; replace if necessary. NOTE: If threads are not clean and smooth, ball stud may turn in the socket when attempting to tighten nut. 3. Install the idler arm ball stud in the relay rod, making certain the seal is positioned properly; install the nut and torque to specifications. NOTE: Never back off nut to align cotter pin, always tighten nut to the next slot that lines up with the hole in the stud. 4. Install cotter pin. 5. Lower the vehicle to the floor. Pitman Arm Removal 1. Raise vehicle on hoist. 2. Remove cotter pin from pitman arm ball stud and remove nut. 3. Remove pitman arm or relay rod from ball stud by tapping on side of rod or arm (in which the stud mounts) with a hammer while using a heavy hammer or similar tool as a backing (fig. 103). Pull on linkage to remove from stud. 4. Remove pitman arm nut from pitman shaft or clamp bolt from pitman arm, and mark relation of arm position to shaft. 5. Remove pitman arm, using Tool J-6632 or J-5504. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9 -6 3 Installation CAUTION: See the CAUTION on page 1 of this section regarding the fasteners referred to in steps 3 and 4. 1. Install pitman arm on pitman shaft, lining up the marks made upon removal. CAUTION: If a clamp type pitman arm is used, spread the pitman arm just enough, with a wedge, to slip arm onto pitman shaft. Do not spread pitman arm more than required to slip over pitman shaft with hand pressure. Do not hammer or damage to steering gear may result. Be sure to install the hardened steel washer before installing the nut. 2. Make sure that threads on ball studs and in ball stud nuts are clean and smooth. Check condition of ball stud seals; replace if necessary. NOTE: If threads are not clean and smooth, ball studs may turn in sockets when attempting to tighten nut. 3. Install pitman shaft nut or pitman arm clamp bolt and torque to specifications. 4. Position ball stud onto pitman arm or relay rod. Install nut and torque to specifications. 5. Install cotter pin. NOTE: Never back off nut to align cotter pin, always tighten nut to next slot that lines up with hole in stud. 6. Lubricate ball studs. 7. Lower the vehicle to the floor. Steering Connecting Rod Removal 1. Remove cotter pins from ball studs and remove castellated nuts. 2. Remove ball studs from steering arm and pitman arm boss with a heavy hammer and striking other side of boss with lighter hammer (similar to method shown in figure. 103). Installation CAUTION: See the CAUTION on page 1 of this section regarding the fasteners referred to in step 3. For procedure concerning adjustment of connecting rod and steering wheel and gear high point centering. see page 25. 1. Make sure that threads on ball studs and in ball stud nuts are clean and smooth. Check condition of ball stud seals - replace if necessary. NOTE: If threads are not clean and smooth, ball studs may turn in connecting rod when attempting to tighten nut. Fig. 104B—Adjustable Connecting Rod Assembly K Series 2. Install ball studs in steering arm and pitman arm. Be sure to install the long end of the connecting rod assembly to the pitman arm. 3. Install ball stud nuts and torque to specifications. NOTE: Never back off nut to align cotter pin, always tighten nut to next slot that lines up with hole in stud. 4. Install cotter pins and lubricate ball studs. NOTE: For proper alignment and orientation of connecting rod clamps see figure 104B. POWER STEERING SYSTEM Power Steering Gear Removal 1. Disconnect hoses at gear. When hoses are disconnected, secure ends in raised position to prevent drainage of oil. Cap or tape the ends of the hoses to prevent entrance of dirt. 2. Install two plugs in gear fittings to prevent entrance of dirt. 3. Remove the flexible coupling to steering shaft flange bolts (G, C and K models) or the lower universal joint pinch bolt (P models). Mark the relationship of the universal yoke to the stub shaft. 4. Mark the relationship of the pitman arm to the pitman shaft. Remove the pitman shaft nut or pitman arm pinch bolt and then remove the pitman arm from the pitman shaft using Puller J-6632 (fig. 48). 5. Remove the steering gear to frame bolts and remove the gear assembly. LIGHT DUTY TRUCK SERVICE MANUAL 9 -6 4 STEERING 6. G, C and K Models — Remove the flexible coupling pinch bolt and remove the coupling from the steering gear stub shaft. Installation CAUTION: See CAUTION on page 1 of this section regarding the fasteners referred to in steps 1, 3, 4 and 5. 1. Install the flexible coupling onto the steering gear stub shaft, aligning the flat in the coupling with the flat on the shaft. Push the coupling onto the shaft until the stub shaft bottoms on the coupling reinforcement. Install the pinch bolt and torque to specifications. NOTE: The coupling bolt must pass through the shaft undercut. 2. Place the steering gear in position, guiding the coupling bolt into the steering shaft flange. 3. Install the steering gear to frame bolts and torque to specifications. 4. If flexible coupling alignment pin plastic spacers were used, make sure they are bottomed on the pins, tighten the flange bolt nuts to specifications and then remove the plastic spacers. 5. If flexible coupling alignment pin plastic spacers were not used, center the pins in the slots in the steering shaft flange and then install and torque the flange bolt nuts to specifications. P Models a. Place the steering gear in position, guiding the stub shaft into the universal joint assembly and lining up the marks made at removal. NOTE: If a new gear was installed, line up the mark on the stub shaft with the mark on the universal yoke. b. Install the steering gear to frame bolts and torque to specifications. c. Install the universal joint pinch bolt and torque to specification. NOTE: The pinch bolt must pass through the shaft undercut. All Models 6. Install the pitman arm onto the pitman shaft, lining up the marks made at removal. Install the pitman shaft nut or pitman arm pinch bolt and torque to specifications. 7. Remove the plugs and caps from the steering gear and hoses and connect the hoses to the gear. Tighten the hose fittings to specified torque. POWER STEERING PUMP Removal (Fig. 106) 1. Disconnect hoses at pump. When hoses are disconnected, secure ends in raised position to prevent drainage of oil. Cap or tape the ends of the hoses to prevent entrance of dirt. On Models with remote reservoir Engine — Disconnect reservoir hose at pump and secure in raised position. Cap hose pump fittings. 2. Install two caps at pump fittings to prevent drainage of oil from pump. 3. Loosen bracket-to-pump mounting nuts. 4. Remove pump belt. 5. Remove bracket-to-pump bolts and remove pump from vehicle. 6. Remove drive pulley attaching nut. 7. Remove pulley from shaft. Do not hammer pulley off shaft as this will damage pump. Use Tool off shaft as this will damage pump. Use Tool J-21239-1 for pulling stamped pulleys or Tool J-8433-1 with Adapter J-8433-2 for cast pulleys. Installation 1. Install pump pulley. CAUTION: Do not hammer on pump shaft. Use pulley nut to pull pulley onto shaft. Use a new nut. NOTE: On models equipped with a remote power steering pump reservoir fill the pump housing with as much fluid as possible before mounting. Position pump assembly on vehicle and install attaching parts loosely. Connect and tighten hose fittings. Fill reservoir. Bleed pump by turning pulley backward (counter-clockwise as viewed from front) until air bubbles cease to appear. LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-65 5. Install pump belt over pulley. 6. Tension belt as outlined under “Pump Belt Tension—Adjustment” in this section. 7. Bleed as outlined under “Maintenance and Adjustments.” POWER STEERING HOSES When servicing power steering hoses, avoid twisting the hoses unnecessarily. Install hoses with the wheels in the straight ahead position, then turn the wheels to the right and left, while observing movement of the hoses. Note and correct any hose contact with other parts of the vehicle that could cause chafing or wear. Any maintenance operation, on the power steering equipment, should include a thorough inspection of the hydraulic line system. Figure 107 illustrates typical installations. LIGHT DUTY TRUCK SERVICE MANUAL 9-66 STEERING LIGHT DUTY TRUCK SERVICE MANUAL Fig. 106-Power Steering Pump Mounting-Typical PUMP ASSEMBLY STEERING STEERING GEAR TYPICAL LARGE V8 9-67 TYPICAL SMALL V8 9 -6 8 STEERING STEERING SYSTEM DIAGNOSIS CONDITION Excessive Play or Looseness in Steering System. Excessive looseness in tie rod or intermediate rod pivots, or excessive vertical lash in idler support. POSSIBLE CAUSE CORRECTION Front wheel bearings loosely adjusted. Adjust bearings to obtain proper end play. Worn steering shaft couplings. Replace part. Worn upper ball joints. Check and replace if necessary. Steering wheel loose on shaft, loose pitman arm, tie rods, steering arms or steering linkage ball studs. Tighten to specified torque, or replace if necessary. Steering gear thrust bearings loosely adjusted. Adjust preload to specification. Excessive over-center lash in steering gear. Adjust preload to specification. Worn intermediate rod or tie rod sockets. Replace worn part. Seal damage and leakage resulting in loss of lubricant, corrosion and excessive wear. Replace damaged parts as necessary. Properly position upon reassembly. Fig. 108A—Steering Linkage Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL STEERING CONDITION Hard Steering —Excessive Effort Required at Steering Wheel. Poor Returnability. POSSIBLE CAUSE CORRECTION Low or uneven tire pressure. Inflate to specified pressures. Steering linkage or bolt joints need lubrication. Lube with specified lubricant. Tight or frozen intermediate rod, tie rod or idler socket. Lube replace or reposition as necessary. Steering gear to column misalignment. Align column. Steering gear adjusted too tightly. Adjust over-center and thrust bearing preload to specification. Front wheel alignment incorrect, (manual gear) Check alignment and correct as necessary. Steering linkage or ball joints need lubrication. Lube with specified lubricant. Steering gear adjusted too tightly. Adjust over-center and thrust bearing preload to specifications. Align column. Steering gear to column misalignment. Front wheel alignment incorrect. (Caster) 9 -6 9 Check alignment and correct as necessary. Fig. 108B—Steering Linkage Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -7 0 STEERING CONDITION POSSIBLE CAUSE Rattle or Chuck in Steering Gear. Insufficient or improper lubricant in steering gear. Add lube specified. Pitman arm loose on shaft or steering gear mounting bolt loose. Tighten to specified torque. Loose or worn steering shaft bearing. Replace steering shaft bearing. Excessive over-center lash or worm thrust bearings adjusted too loose. Adjust steering gear to specified preloads. CORRECTION NOTE: On turns a slight rattle may occur, due to the increased lash between ball nut and pitman shaft as gear moves off the center of “high point” position. This is normal and lash must not be reduced to eliminate this slight rattle. Poor Returnability Steering column misaligned. Align column. Insufficient or improper lubricant in steering gear or front suspension. Lubricate as specified. Steering gear adjusted too tight. Adjust over-center and thrust bearing preload to specifications. Front wheel alignment incorrect (Caster) Adjust to specifications. Fig. 109A—Manual Gear Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL STEERING CONDITION Excessive Play or Looseness in Steering System. Hard Steering Excessive Effort Required Required at Steering Wheel POSSIBLE CAUSE 9-71 CORRECTION Front wheel bearings loosely adjusted. Adjust to obtain proper end play. Worn upper ball joints. Check and replace ball joints if necessary. Steering wheel loose on shaft, loose pitman arm, tie rods, steering arms or steering linkage ball nuts. Tighten to specification, replace if worn or damaged. Excessive over-center lash. Adjust over-center preload to specifications. Worm thrust bearings loosely adjusted. Adjust worm thrust bearing preload to specifications. Low or uneven tire pressure. Inflate to specified pressures. Insufficient or improper lubricant in steering gear or front suspension. Lubricate as specified. Relubricate at specified intervals. Steering shaft flexible coupling misaligned. Align column and coupling. Steering gear adjusted too tight. Adjust over-eenter and thrust bearing preload to specifications. Front wheel alignment incorrect. (Manual Gear) Adjust to specifications. Fig. 109B—Manual Gear Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -7 2 STEERING DIAGNOSIS C AND K STEERING COLUMNS This section contains diagnostic information to help locate the cause of the problem in the column. Reference should be made to the correct method of column disassembly, repair, adjustment and reassembly. Dam­ aged, broken or deformed parts must be replaced with the correct replacement. GENERAL INFORMATION All C and K models are equipped with function locking energy absorbing Steering Columns. The columns are of five basic designs as follows: 1. Synchromesh — The synchromesh column is used on models with the standard transmission and column mounted shift levers. The shift tube, within the outer column jacket, includes two lower shift levers for connection to the transmission control linkage. 2. Floor Shift — This column is used on models equipped with a manual transmission with the shift lever on the floor. This column does not incorporate a shift tube. 3. AUTOMATIC TRANSM ISSION-Available with col­ umn shift only Locks the transmission and steering wheel while in park position and the lock cylinder is in "Lock" position. 4. TILT WHEEL OPTION - The upper end and steering shaft of this column is specifically designed to accommodate the optional tilt steering wheel. It is available with either manual (the fourth column type) or automatic transmission on (the fifth column type). To perform diagnostic procedures on the steering column upper end components, it is not necessary to remove the column from the vehicle. The steering wheel, horn components, directional signal switch, ignition switch and lock cylinder may be removed with the column remaining in the vehicle as described in the Service Manual under “Component Part Replacement”. CAUTION: The outer mast jacket shift tube, steering shaft and instrument panel mounting bracket are designed as energy absorbing units. Because of the design of these components, it is absolutely necessary to handle the column with care when performing any service operation. Avoid hammering, jarring, dropping or leaning on any portion of the column. When reassem­ bling the column components, use only the specified screws, nuts and bolts and tighten to specified torque. Care should be exercised not to use over-length screws or bolts as they may prevent a portion of the column from compressing under impact. COLLISION DIAGNOSIS To determine if the energy absorbing steering column components are functioning as designed, or if repairs are required, a close inspection should be made. An inspection is called for in all cases where damage is evident or whenever the vehicle is being repaired due to a front end collision. Whenever a force has been exerted on the steering wheel or steering column, or its components, inspection should also be made. If damage is evident, the affected parts must be replaced. The inspection procedure for the various steering column components on C and K trucks is as follows: COLUMN SUPPORT BRACKET Damage in this area will be indicated by separation of the mounting capsules from the bracket. The bracket will have moved forward toward the engine compartment and will usually result in collapsing of the jacket section of the steering column. COLUMN JACKET Inspect jacket section of column for looseness, and/or bends. SHIFTER SHAFT Separation of the shifter shaft sections will be internal and cannot be visually identified. Hold lower end of the “shifter shaft” and move “shift lever” on column through its ranges and up and down. If there is little or no movement of the “shifter shaft”, the plastic joints are sheared. Steering Shaft If the steering shaft plastic pins have been sheared, the shaft will rattle when struck lightly from the side and some lash may be felt when rotating the steering wheel while holding the rag joint. It should be noted that if the steering shaft pins are sheared due to minor collision with no appreciable damage to other components, that the vehicle can be safely steered; however, steering shaft replacement is recommended. Because of the differences in the steering column types, be sure to refer to the set of instructions below which apply to the column being serviced. Method To Determine Column Collapse Measure distance between top of neutral-start switch window opening and the bottom of the upper jacket. The correct value is shown below: a. C-Truck 5 11/16" to 5 1/2". b. K-Truck 5 11/16" to 5 1/2". LIGHT DUTY TRUCK SERVICE MANUAL STEERING V Instrument Panel Bracket Capsule Damage N O TE : The bolt head must not contact surface “A”. If contact is made, the capsule shear load will be increased. If this condition exists replace the bracket. ______ I , 1 9 -7 3 SURFACE “A” i A U T O M A T IC TR A N S M IS S IO N C O LU M N S LOCK S Y S T E M - W IL L N O T U N LO C K Cause Solution A. Lock bolt damaged. B. Defective lock cylinder. Damaged housing. D. Damaged or collapsed sector. E. Damaged rack. F. Shear Flange on sector shaft collapsed. LOCK SYSTEM - W IL L N O T LOCK A. Replace lock bolt. B. Replace or repair lock cylinder. Replace housing. D. Replace sector. E. Replace rack. F. Replace. Cause Solution A. Lock bolt spring broken or defective. B. Damaged sector tooth, or sector installed incorrectly. Defective lock cylinder. D. Burr or lock bolt or housing. E. Damaged housing. F. Transmission linkage adjustment incorrect. G. Damaged rack. H. Interference between bowl and coupling (tilt-tilt and telescope). I. Ignition switch stuck. J. Actuator rod restricted or bent. A. Replace spring. B. Replace, or install correctly. Replace lock cylinder D. Remove Burr. E. Replace housing. F. Readjust (see Sec. 7). G. Replace rack. H. Adjust or replace as necessary. C. C. LOCK S Y S T E M - H IG H C. C. I. Readjust or replace. J. Readjust or replace. EFFORT Cause Solution A. Lock'cylinder defective. B. Ignition switch defective. C. Rack preload spring broken or deformed. D. Burrs on sector, rack, housing, support, tang of shift gate or actuator rod coupling. E. Bent sector shaft. F. Distorted rack. G. Misalignment of housing to cover (tilt-tilt and telescope only). A. Replace lock cylinder. B. Replace switch. C. Replace spring. D. Remove Burr. E. Replace shaft. F. Replace rack G. Replace either or both. Fig. 110—Automatic Transmission Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -7 4 STEERING LOCK SYSTEM - H IG H E F F O R T (C O N T 'D .) Cause Solution H. Distorted coupling slot in rack (tilt-tilt and telescope only). I. Bent or restricted actuator rod. J. Ignition switch mounting bracket bent. H. Replace rack. I. Straighten remove restriction or replace. J. Straighten or replace. H IG H E F F O R T LOCK C Y L IN D E R - BETW EEN " O F F " A N D "O F F -L O C K " PO SITIONS Cause Solution A. Burr on tang of shift gate. B. Distorted rack. A. Remove burr. B. Replace rack. STICKS IN " S T A R T " PO SITIO N . Cause Solution A. Actuator rod deformed. B. Any high effort condition. A. Straighten or replace. B. Check items under high effort section. KEY CAN N O T BE R E M O V E D IN "O F F -L O C K " P O S ITIO N Cause Solution A. Ignition switch is not set correctly. B. Defective lock cylinder. A. Readjust ignition switch. B. Replace lock cylinder. LOCK C Y L IN D E R CAN BE R E M O V E D W IT H O U T DEPRESSING R E T A IN E R Cause Solution A. Lock cylinder with defective retainer. B. Lock cylinder without retainer. C. Burr over retainer slot in housing cover. A. Replace lock cylinder. B. Replace lock cylinder. C. Remove burr. LOCK B O LT H IT S S H A F T LOCK IN " O F F " A N D "P A R K " PO SITIO N S Cause Solution A. Ignition switch is not set correctly. A. Readjust ignition switch. - IG N IT IO N SYSTEM E L E C T R IC A L SYSTEM W IL L N O T F U N C T IO N Cause Solution A. Defective fuse in “accessory” circuit. B. Connector body loose or defective. C. Defective wiring. A. Replace fuse. B. Tighten or replace. C. Repair or replace. Fig. I l l —Automatic Transmission Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL STEERING - IG N IT IO N SYSTEM E L E C T R IC A L S Y S T E M W IL L N O T F U N C T IO N (C O N T 'D .) 9 -7 5 - Cause Solution D. Defective ignition switch. E. Ignition switch not adjusted properly. D. Replace ignition switch. E. Readjust ignition switch. SW ITCH W IL L N O T A C T U A T E M E C H A N IC A L L Y Cause Solution A. Defective ignition switch. A. Replace igntion switch. SW ITCH CAN N O T BE SET C O R R E C T L Y Cause Solution A. Switch actuator rod deformed. B. Sector to rack engaged in wrong tooth (tilt-tilt and telescope). A. Repair or replace switch actuator rod. B. Engage sector to rack correctly. NO ISE IN C O LU M N Cause A. B. C. D. E. F. G. H. I. Solution Coupling bolts loose. Column not correctly aligned. Coupling pulled apart. Sheared intermediate shaft plastic joint. Horn contact ring not lubricated. Lack of grease on bearings or bearing surfaces. Lower shaft bearing tight or frozen. Upper shaft tight or frozen. Shaft lock plate cover loose. J. Lock plate snap ring not seated. K. Defective buzzer dog cam on lock cylinder. L. One click when in “off-lock” position and the steering wheel is moved. A. Tighten pinch bolts to specified torque. B. Realign column. C. Replace coupling and realign column. D. Replace or repair steering shaft and realign column. E. Lubricate with lubriplate. F. Lubricate bearings. G. Replace bearing. Check shaft and replace if scored. H. Replace housing assembly. I. Tighten three screws or, if missing, replace. CAUTION: Use specified screws. (15 in. lbs.) J. Replace snap ring. Check for proper seating in groove. K. Replace lock cylinder. L. Normal condition - lock bolt is seating. Fig. 112—Automatic Transmission Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -7 6 STEERING H IG H S TE E R IN G S H A F T E F F O R T Cause Solution A. B. C. D. A. B. C. D. Column assembly misaligned in vehicle. Improperly installed or deformed dust seal. Tight or frozen upper or lower bearing. Flash on I.D. of shift tube from plastic joint. Realign. Remove and replace. Replace affected bearing or bearings. Replace shift tube. H IG H S H IF T E F F O R T Cause Solution A. B. C. D. E. A. B. C. D. E. Column not aligned correctly in car. Improperly installed dust seal. Lack of grease on seal or bearing areas. Burr on upper or lower end of shift tube. Lower bowl bearing not assembled properly (tilt-tilt and telescope). F. Wave washer with burrs (tilt-tilt and telescope only). Realign. Remove and replace. Lubricate bearings and seals. Remove burr. Reassemble properly. F. Replace wave washer. IMPROPER T R A N S M IS S IO N S H IF T IN G Cause Solution A. B. C. D. E. A. B. C. D. E. Sheared shift tube joint. Improper transmission linkage adjustment. Loose lower shift lever. Improper gate plate. Sheared lower shift lever weld. Replace shift tube assembly. Readjust linkage. Replace shift tube assembly. Replace with correct part. Replace tube assembly. LASH IN M O U N T E D C O L U M N ASSEM B LY Cause Solution A. B. C. D. E. F. G. A. B. C. D. E. F. G. Instrument panel mounting bolts loose. Broken weld nuts on jacket. Instrument panel bracket capsule sheared. Instrument panel to jacket mounting bolts loose. Loose shoes in housing (tilt-tilt and telescope only). Loose tilt head pivot pins (tilt-tilt and telescope only). Loose shoe lock pin in support (tilt-tilt and telescope only). Tighten to specifications. (20 ft. lbs.) Replace jacket assembly. Replace bracket assembly. Tighten to specifications. (15 ft. lbs.) Replace. Replace. Replace. M IS C E LL A N E O U S Cause Solution A. Housing loose on jacket - will be noticed with ignition in “Off-Lock” and a torque applied to the steering wheel. B. Shroud loose on shift bowl. A. Tighten four mounting screws - (60 in. lbs.) B. Bend tabs on shroud over lugs on bowl. Fig. 113—Automatic Transmission Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9 -7 7 M A N U A L TR A N S M IS S IO N CO LUM N S GENERAL INFORMATION All of the preceding diagnosis information for automatic transmission will apply to the manual transmission. The following information is supplied in addition to and specifically for manual transmission columns. D R IV E R CAN LOCK S T E E R IN G IN SECOND G EA R Cause Solution A. Defective upper shift lever. B. Defective shift lever gate. C. Loose relay lever on shift tube. A. Replace shift lever. B. Replace shift lever gate. C. Replace shift tube assembly. H IG H S H IF T E F F O R T Cause Solution A. B. C. D. E. F. G. A. B. C. D. E. F. G. Column not aligned correctly in car. Lower bowl bearing not assembled correctly. Improperly installed seal. Wave washer in lower bowl bearing defective. Improper adjustment of lower shift levers. Lack of grease on seal, bearing areas or levers. Damaged shift tube in bearing areas. Realign column. Reassemble correctly. Remove and replace. Replace wave washer. Readjust (see Sec. 7). Lubricate seal, levers and bearings. Replace shift tube assembly. IM PROPER T R A N S M IS S IO N S H IF T IN G Cause Solution A. Loose relay lever on shift tube. A. Replace shift tube assembly. T I L T - T I L T A N D TELESCOPE C O LU M N S GENERAL INFORMATION All of the preceding diagnosis will generally apply to tilt-tilt and telescope columns. The following is supplied in addition to and specifically for tilt-tilt and telescope columns. H O U SIN G SCRAPING ON BOWL Cause Solution A. Bowl bent or not concentric with hub. A. Replace bowl. Fig. 114—Manual Transmission Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -7 8 STEERING S TE E R IN G W H E E L LOOSE Cause Solution A. Excessive clearance between holes in support or housing and pivot pin diameters. B. Defective or missing anti-lash spring in spheres. C. Upper bearing seat not seating in bearing. D. Upper bearing inner race seat missing. E. Improperly adjusted T & T locking knobs. F. Loose support screws. G. Bearing preload spring missing or broken. A. Replace either or both. B. C. D. E. F. G. Add spring or replace both. Replace both. Install seat. Readjust. Tighten to 60 in. lbs. Replace preload spring. S TE E R IN G W H EEL LOOSE E V E R Y O T H E R T IL T PO SITIO N Cause Solution A. Loose fit between shoe and shoe pivot pin. A. Replace both. NOISE W HEN T IL T IN G C O LU M N Cause Solution A. Upper tilt bumper worn. B. Tilt spring rubbing in housing. A. Replace tilt bumper. B. Lubricate. S TE E R IN G C O LU M N N O T LO C K IN G A N Y T IL T PO S ITIO N IN Cause Solution A. Shoe seized on its pivot pin. B. Shoe grooves may have burrs or dirt. C. Shoe lock spring weak or broken. A. Replace shoe and pivot pin. B. Replace shoe. C. Replace lock spring. S TE E R IN G W H E EL F A IL S TO R E T U R N TO TOP T IL T P O S ITIO N Cause Solution A. Pivot pins are bound up. B. Wheel tilt spring is defective. C. Turn signal switch wires too tight. A. Replace pivot pins. B. Replace tilt spring. C. Reposition wires. Fig. 115—Tilt Column Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL STEERING STEERING COLUMN ELECTRICAL ANALYZER J-23980 FOR C AND K SERIES COLUMNS A new tool has been developed to help the technician analyze the steering column wiring harness for electrical problems. The tool in actuality eliminates the steering column, related wiring and components; and replaces them with the tool itself. In this way disassembly of the column is not performed until the problem has been determined to be in the column. By moving the tester switch, (with the key in the “on” position), the various functions may be checked. The switch positions are “OFF”, “HORN”, “LEFT TURN”, “RIGHT TURN”, “KEY BUZZER”, and “HAZARD”. (Trucks do not incorporate a Key Buzzer Switch) If the systems function properly while using the tester, then the malfunction has been narrowed to the column wiring or components. When this has been determined then the column may be serviced to correct the malfunction. To use the tool just unfasten the harmonica connector on the column and plug the harness from J-23980 into the vehicle chassis harness. The “A”, “B”, and “C” terminals on the tester will overhang the chassis connector. This does not affect the test results. These terminals are for vehicles with cornering lights. Connect the single black jumper to a good ground. The tester is now ready for use (Fig. 116). TURN SIGNAL DIAGNOSIS C AND K SERIES When a complaint is made involving the turn signal 9 -7 9 system, it must first be determined whether the problem is mechanical or electrical. If mechanical, the switch itself is at fault and must be repaired or replaced. If electrical, J-23980 should be used to determine whether the switch, or the chassis wiring is in need of repair or replacement. This diagnostic procedure has been designed to guide the mechanic through the proper diagnosis and repair of the turn signal system. The service section is to be used where assembly and/or disassembly procedures are required. The wiring diagram, found in Section 12, should be used to trouble shoot the chassis and body wiring after the problem has been isolated. The nature of the customer complaint will generally point to the problem area. ELECTRICAL Chassis Electrical The most common turn signal system problems are generally electrical and may easily be fixed by the replacement of fuses, bulbs or flashers First make these checks and replace any non-operative components. 1. Check fuses (Figure 117). Replace if blown. If new fuse blows, replace flasher in system. (There are 2 flashers in the signal switch system. The hazard warning flasher is located on the fuse block, while the turn signal flasher is up under the instrument panel). Fig. 116—Steering Column Electrical Analyzer J-23980 Fig. 117—Checking Fuses on Fuse Block LIGHT DUTY TRUCK SERVICE MANUAL 9 -8 0 STEERING 2. Check for secure connection at the chassis to switch connector. This is the harmonica connector on the column (Figure 118). Secure if loose. Check all individual wire terminals for proper seating in the connector bodies. Terminals should be locked in place. 3. Depress hazard warning button and check all lights in signal switch system. Replace any which do not work. If all lamps light when hazard warning is depressed, but flashing does not occur, replace hazard warning flasher. (On fuse block) (Figure 119). 4. If all directional lamps light when lane change or turn indicator is actuated, but no flashing occurs, replace the turn signal flasher. This flasher is located under the instrument panel. The above four steps will, in most cases, cure the common signal switch system troubles. If the system is still not operating correctly, use J-23980 to determine whether the chassis wiring or the signal switch itself is at fault. Fig. 119—Checking Hazard Warning Flasher MECHANICAL 1. If the customer’s complaint indicates the problem is in the switch, function check as to return from full left and full right turns. Actuate the turn lever into a full turn position in either direction, then turn the steering wheel (motor on — power steering) at least 1/4 turn in the direction indicated and then back to center. Do this in both directions. If the lever does not return to the neutral position, disassemble the upper part of the column until the switch is visible. 2. Check the return from lane change by holding the lever in lane change and releasing (both left and right). If the lever does not return to neutral, disassemble the upper part of the column. 3. If the hazard warning button cannot be depressed or released, the switch must be replaced. LANE CHANGE RETURN SPRING Fig. 121—Checking Turn Signal Switch Visually Switch Visual Inspection Fig. 118—Checking Harmonica Connector on Column 1. With the upper part of the column disassembled so that the signal switch is visible (Figure 121) check for missing springs. Replace any spring that is missing, inspecting the molded pins which secure them. If these pins are broken, the switch must be replaced. 2. Check the position of the switch in the bowl. If it appears cocked or crooked, loosen the securing screws (3) and visually inspect the switch. If any of the plastic is broken or badly deformed, the switch must be replaced. 3. If the switch appears undamaged, replace it being careful to seat the pilot into the housing, tighten the screws to 25 in. lbs. of torque. LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G 9-81 SIGNAL SWITCH DIAGNOSIS CONDITION Turn signal w ill not cancel A. B. C. D. Turn signal d iffic u lt to operate B. Reposition or replace springs as required D. Adjust switch position 1. If interference is correct and switch w ill still not cancel, replace switch. 2. If interference cannot be corrected by switch adjustment, replace cancelling cam. Tighten mounting screw (12 in-lb) Replace switch B. Yoke broken or distorted Loose or misplaced springs Foreign parts and/or materials Switch mounted loosely B. A. B. C. A. B. Broken lane change pressure pad or spring hanger Broken, missing or misplaced lane change spring Jammed base or wires Foreign material or loose parts impeding movement o f yoke Broken or missing detent or cancelling springs Tighten to specified torque (25 in-lbs) Replace switch C. A. E. Hazard switch cannot be turned o ff A. A ctuator rod loose D. Turn signal w ill not stay in tu rn position Loose switch mounting screws Switch or anchor bosses broken Broken, missing or out of position detent, return or cancelling spring Uneven or incorrect cancelling cam to cancelling spring interference. (.120)/side A. C. Turn signal w ill not indicate lane change CORRECTION POSSIBLE CAUSE C. D. E. Reposition or replace springs Remove foreign parts and/or material Tighten mounting screws (25 in-lbs) A. Replace switch B. Replace or reposition as required C. Loosen mounting screws, reposition base or wires and retighten screws (25 in-lbs) A. Remove material and/or parts B. Replace spring C. None o f the above C. Replace switch A. Foreign material between hazard support cancelling leg and yoke A. Remove foreign material 1. No foreign material impeding fun ctio n o f hazard switch — replace tu rn signal switch Fig. 122—Turn Signal Switch Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -8 2 S T E E R IN G SIGNAL SWITCH DIAGNOSIS CONDITION Hazard switch w ill not stay on or d iffic u lt to tu rn o ff No turn signal lights POSSIBLE CAUSE A. A. C. Loose switch mounting screws Interference w ith other components Foreign material D. None o f the above D. A. Defective or blown fuse Inoperative turn signal flasher Loose chassis to column connector Disconnect column to chassis connector. Connect new switch to chassis and operate switch by hand. If vehicle lights now operate norm ally, signal switch is inoperative If vehicle lights do not operate check chassis w iring fo r opens, grounds, etc. A. E. Repair chassis w iring as required using manual as guide A. Inoperative turn flasher A. B. Loose chassis to column connection Inoperative turn signal switch To determine if turn signal switch is defective, substitute new switch into circu it and operate switch by hand. If the vehicle's lights operate norm ally, signal switch is inoperative If the vehicle's lights do not operate, check light sockets fo r high resistance connections, the chassis w iring fo r opens, grounds, etc. B. Replace tu rn flasher Note: There are two flashers in the system. Consult manual fo r location. Connect securely and check operation Replace turn signal switch Replace signal switch B. B. C. D. E. Turn indicator lights on, but not flashing CORRECTION C. D. E. B. C. B. C. D. C. D. E. Tighten mounting screws (25 in-lbs) Remove interference Remove foreign material Replace switch Replace fuse and check operation Replace tu rn signal flasher Connect securely, check operation Replace signal switch Repair chassis w iring as required using manual as guide Fig. 123—Turn Signal Switch Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G 9 -8 3 SIGNAL SWITCH DIAGNOSIS Front or rear tu rn signal lights not flashing Burned out fuse A. B. Burned out or damaged tu rn signal bulb High resistance connection to ground at bulb socket Loose chassis to column connector Disconnect column to chassis connector. Connect new switch into system and operate switch by hand. If tu rn signal lights are now on and flash, tu rn signal switch is inoperative. If vehicle lights do not operate, check chassis w iring harness to light sockets fo r opens, grounds, etc. B. F. Repair chassis w iring as required using manual as guide A. Burned out fuse A. B. Loose column to chassis connection Disconnect column to chassis connector. Connect new switch into system w ith o u t removing old. Operate switch by hand. If brake lights w ork w ith switch in the tu rn position, signal switch is defective If brake lights do not w ork check connector to stop light sockets fo r grounds, opens, etc. B. Replace fuse and check operation Connect securely and check operation Replace signal switch D. E. F. C. D. Turn indicator panel lights not flashing Replace fuse and check operation Replace bulb A. C. Stop light not on when turn indicated CORRECTION POSSIBLE CAUSE CONDITION A. B. C. Burned out bulbs High resistance to ground at bulb socket Opens, grounds in w iring harness from fro n t tu rn signal bulb socket to indicator lights C. D. E. C. Remove or repair defective connection and check operation Connect securely and check operation Replace turn signal switch. D. Repair connector to stop light circuits using manual as guide. A. B. Replace bulbs Replace socket C. Locate and repair as required. Use shop manual as guide. Fig. 124—Turn Signal Switch Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 - 8 4 S T E E R IN G SIGNAL SWITCH DIAGNOSIS CONDITION Turn signal lights flash very slowly A. B. C. D. E. F. Hazard signal lights w ill not flash — tu rn signal functions norm ally CORRECTION POSSIBLE CAUSE Inoperative turn signal flasher System charging voltage low High resistance ground at light sockets A. Loose chassis to column connection Disconnect column to chassis connector. Connect new switch into system w ith o u t removing old. Operate switch by hand. If flashing occurs at normal rate, the signal switch is defective. If the flashing rate is still extremely slow, check chassis w iring harness from the connector to light sockets fo r grounds, high resistance points, etc. D. B. C. E. F. Locate and repair as required. Use manual as guide. See Section 12 Replace fuse and check operation Replace hazard warning flasher Connect securely and check operation Replace the tu rn signal switch A. Blown fuse A. B. Inoperative hazard warning flasher Loose chassis to column connection Disconnect colum n to chassis connector. Connect new switch into system w ith o u t removing old. Depress the hazard warning b utton and observe the hazard warning lights. If they now w ork norm ally, the turn signal switch is defective. If the lights do not flash, check w iring harness "K" lead (brown) fo r open between hazard flasher and harmonica connector. If open, fuse block is defective. B. C. D. E. Replace turn signal flasher Increase voltage to specified. See Sec. 6Y Repair high resistance grounds at light sockets Connect securely and check operation Replace signal switch C. D. E. Replace fuse block (See Sec. 12) Fig. 125—Turn Signal Switch Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G POWER STEERING SYSTEM DIAGNOSIS Complaints of faulty steering are frequently the result of problems other than the steering gear or pump. Those areas of the steering system which can be easily checked and quickly corrected without disassembly and overhaul of any major components should be attempted first. Conditions such as hard or loose steering, road shock or vibrations are not always due to the steering gear or pump, but are often related instead to such factors as low tire pressure and front end alignment. These factors should be checked and corrected before any adjustment or disassembly of the power steering gear or pump is attempted. SYSTEM CHECKS Many factors affect power operation of the steering system, of which the most common are: 1. Fluid level and condition. 2. Drive belt tension. 3. Loose component mountings. 4. Loose pump pulley. These factors must be checked and corrected before making any further diagnosis of the steering system. The need for proper diagnosis cannot be over-emphasized. After the source of the problem has been found, determine the cause. For example, if the oil level in the reservoir is found to be low, refill and check the entire hydraulic system for oil leaks. Refilling the reservoir will not necessarily correct problem. Fluid Level 1. Run engine to normal operating temperature, then shut engine off. Remove reservoir filler cap and check oil level to “hot” mark on dipstick. 2. If oil level is low, add hydraulic fluid to proper level on dipstick and replace filler cap. NOTE: When adding or making a complete fluid change, always use GM power steering fluid or equivalent. 3. When checking fluid level after the steering system has been serviced, air must be bled from the system. Proceed as follows: a. With wheels turned all the way to the left, add power steering fluid to “Cold” mark on dipstick. b. Start engine, and running at fast idle, recheck fluid level. Add fluid if necessary to “Cold” mark on dipstick. c. Bleed system by turning wheels from side to side without hitting stops. Maintain fluid level just above internal pump casting. Fluid with air in it will have a light tan or red appearance. This air must be eliminated from fluid before normal steering action can be obtained. 9 -8 5 d. Return wheels to center position and continue to run engine for two or three minutes, then shut engine off. e. Road test car to make sure steering functions normally and is free from noise. f. Recheck fluid level as described in steps 1 and 2, making sure fluid level is at “hot” mark on dipstick after the system has stabilized at its normal operating temperature approximately 170° to 190°F. BELT ADJUSTMENT When adjusting a power steering pump belt, never pry against the pump reservoir or pull against the filler neck. To increase belt tension move the pump outward by prying against the pump housing casting extension directly behind the pump drive pulley. A belt that has been previously tensioned is considered to be a used belt and should be tightened to 75 pounds. A belt that has never been tensioned is considered to be a new belt and should be tightened to 125 pounds. Place belt tension gage, J 23600 or equivalent midway between the pulleys on drive belt being checked. If the belt tension is incorrect proceed as follows: 1. When power steering pump is driven by a single belt: a. Loosen the pump attaching bolts and adjust the belt to correct tension by moving the pump outward, away from the engine. b. Snug all pump mounting bolts and remove pry bar. c. Tighten all pump mounting bolts to specified torque. d. Check belt tension and remove the belt tension gage. HYDRAULIC SYSTEM CHECKS The following procedure outlines methods to identify and isolate power steering hydraulic circuit difficulties. The test provides means of determining whether power steering system hydraulic parts are actually faulty, this test will result in readings indicating faulty hydraulic operation, and will help to identify the faulty component. Before performing hydraulic circuit test, carefully check belt tension, fluid level and condition of driving pulley. Power Steering Hydraulic System Test Engine must be at normal operating temperature. Inflate front tires to correct pressure. All tests are made with engine idling, check idle adjustment and if necessary adjust engine idle speed to correct specifications listed in Section 6M and proceed as follows: 1. With engine NOT running disconnect pressure hose from pump and install Tool J-5176 using a spare LIGHT DUTY TRUCK SERVICE MANUAL 9 -8 6 S T E E R IN G CONDITION SYSTEM NOISE There is some noise in all power steering systems. Common complaints are listed as follows: Pump noise-“chirp”. Belt squeal. Gear noise (“hissing” sound) Rattle. Gear noise (rattle or chuckle). Rattle or chuckle. Groan. Growl. POSSIBLE CAUSE Loose belt. Loose belt. There is some noise in all power steer­ ing systems. One of the most common is a hissing sound most evident at standstill parking. There is no relation­ ship between this noise and perfor­ mance of the steering. “Hiss” may be expected when steering wheel is at end of travel or when slowly turning at standstill. CORRECTION Adjust belt tension to specification. Adjust belt tension to specification. Do not replace valve unless “hiss” is extremely objectionable. Slight “hiss” is normal and in no way affects steer­ ing. A replacement valve will also exhi­ bit slight noise and is not always a cure for the objection. Investigate clearance around flexible coupling rivets. Be sure steering shaft and gear are aligned so flexible coupling rotates in a flat plane and is not distorted as shaft ro­ tates. Any metal-to-metal contacts through flexible coupling will transmit “hiss” into passenger compartment. Pressure hose touching other parts of Adjust hose position. car. Loose pump pulley nut Replace nut, torque to specs. Pump vanes not installed properly. Install properly. Pump vanes sticking in rotor slots. Free up by removing burrs, varnish or dirt. Improper over-center adjustment Adjust to specifications. NOTE: A slight rattle may occur on turns because of increased clearance off the “high point”. This is normal and clearance must not be reduced below specified limits to eliminate this slight rattle. Loose pitman arm. Tighten to specifications Gear loose on frame. Check gear-to-frame mounting bolts. Tighten bolts to 70 foot-pounds. Steering linkage looseness. Check linkage pivot points for wear. Replace if necessary. Low oil level. Fill reservoir to proper level. Air in the oil. Poor pressure hose Bleed system by operating steering from right to left - full turn. connection. Check connections, torque to specs. Excessive back pressure caused by Locate restriction and correct. Replace hoses or steering gear, (restriction) part if necessary. Fig. 126—Power Steering System Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G CONDITION Pump growl Note: Most noticeable at full wheel travel and stand still parking Swish in pump Whine in pump Squawk in gear (not belt) SYSTEM OPERATION Excessive wheel kick-back or loose steering. Poor return of steering. 9 -8 7 POSSIBLE CAUSE CORRECTION Scored pump pressure plates, thrust plate or rotor. Extreme wear of pump cam ring. Defective pump flow control valve Pump shaft bearing scored. Dampener “0 ” ring on valve spool cut Replace affected parts, flush system. Replace affected parts. Replace valve Replace housing and shaft, flush system Replace “0 ” ring. Adjust parts affected or replace worn parts. Add oil to pump reservoir and bleed by Air in system. operating steering. Check all connections. Adjust to specification. Excessive “over-center” lash. Loose thrust bearing preload adjust­ Adjust to specification. ment. Replace poppet valve. Worn poppet valve (Gear) Tighten attaching bolts to 70 foot­ Steering gear loose on frame. pounds. Steering gear flexible coupling too Tighten flange pinch bolts to 30 foot­ loose on shaft or rubber disc mounting pounds, if serrations are not damaged. Tighten upper flange to coupling nuts screws loose. to 20 foot-pounds. Replace loose components. Steering linkage ball studs worn enough to be loose. Front wheel bearings incorrectly ad­ Adjust bearings or replace with new parts as necessary. justed or worn. Backlash in steering linkage. Tires under-inflated. Lower coupling flange rubbing against steering gear adjuster plug. Steering wheel rubbing against direc­ tional signal housing. Tight or frozen steering shaft bearings. Steering linkage or ball joints binding. Steering gear to column misalignment. Tie rod pivots not centralized. Lack of lubricant in suspension ball joints and steering linkage ' Inflate to specified pressure. Loosen pinch bolt and assemble prop­ erly. Adjust steering jacket. Replace bearings. Replace affected parts. Align steering column. Adjust tie rod ends as required to center pivots. Lubricate and relubricate at proper intervals Fig. 127—Power Steering System Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 - 8 8 S T E E R IN G CONDITION Poor return of steering. (Cont’d.) POSSIBLE CAUSE CORRECTION Steering gear adjustments over specifications. Sticky or plugged valve spool. Rubber spacer binding in shift tube. Check adjustment with pitman arm disconnected. Readjust if necessary. Remove and clean or replace valve. Make certain spacer is properly seated. Lubricate inside diameter with sili­ cone lubricant. Improper front suspension alignment. Check and adjust to specifications. Tight steering shaft bearings. Replace bearings. Adjust to specifications. Vehicle leads to one side or the other. Front suspension misaligned (Keep in mind road condition and wind. Test vehicle on flat road going Steering shaft rubbing ID of shift tube. Align column. in both directions) Unbalanced or badly worn steering Replace valve. gear valve. NOTE: If this is cause, steering effort will be very light in direction of lead and heavy in opposite direction. Steering wheel surges or jerks when turning with engine running especially during parking. Steering linkage not level. Adjust as required. Low oil level in pump. Loose pump belt. Sticky flow control valve. Check oil level, add as necessary. Adjust tension to specification. Inspect for varnish or damage, replace if necessary. Insufficient pump pressure. Check pump pressure. (See pump pressure test). Replace relief valve if defective. Steering linkage hitting engine oil pan Correct clearance. at full turn. Momentary increase in effort when turning wheel fast to right or left. Hard steering or lack of assist. Pump belt slipping. Low oil level in pump. High internal leakage. Tighten or replace belt. Check oil level, add as necessary. Check pump pressure (Test) High internal leakage. (Gear or pump) Check pump pressure. (See pump pressure test). Loose pump belt. Adjust belt tension to specification. Low oil level in reservoir. Fill to proper level. If excessively low, check all lines and joints for evidence of external leakage, torque to specs. Fig. 128—Power Steering Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G CONDITION Hard Steering or lack of assist (Continued) POSSIBLE CAUSE 9 -8 9 CORRECTION Lubricate, relubricate at proper Lack of lubricant in suspension intervals. or ball joints. Inflate to recommended pressure. Tires not properly inflated. Steering gear to column misalignment. Align steering column. Test steering system for binding with Steering gear adjusted too tight. front wheels off floor. Adjust as neces­ sary. Excessive friction in steering linkage. Check tie rod pivot points for exces­ sive friction. Replace the affected pivot. Lower coupling flange rubbing Loosen pinch bolt and assemble against steering gear adjuster plug. properly. Sticky flow control valve. Replace or clean valve. Check frame for proper alignment or Frame bent. cracking. Repair or replace as neces­ sary. Check standing height. Weak or sag­ Front springs weak and sagging. ging springs should be replaced with new ones. Insufficient oil pressure. If above checks do not reveal cause of hard steering, diagnose hydraulic system to determine problem. Low oil pressure due to restriction in Check for kinks in hoses. hoses: Foreign object stuck in hose. Remove kink. Remove hoses and remove restricting object or replace hose. Low oil pressure due to steering gear: Pressure loss in cylinder due to worn piston ring or scored housing bore. Leakage at valve rings, valve body to worm seal. (See pump pressure test) Loose fit of spool in valve body or leaky valve body. Damaged poppet valve. Remove gear for disassembly and in­ spection of ring and housing bore. Replace affected parts. Remove gear for disassembly and re­ place seals. Replace valve. Replace valve. Fig. 129—Power Steering System Diagnosis LIGHT DUTY TRUCK SERVICE MANUAL 9 -9 0 S T E E R IN G CONDITION Low oil pressure due to steering pump: (See pump pressure test.) POSSIBLE CAUSE CORRECTION Loose belt. Low oil level. Air in the oil. Adjust tension to specification. Fill reservoir to proper level. Locate source of leak and correct. Bleed system. Defective hoses or steering gear. Correct as necessary. Flow control valve stuck or inopera­ Remove burrs or dirt or replace. tive. Loose screw in end of flow control Tighten. valve. Cracked or broken thrust or pressure Replace part. plate. Pressure plate not flat against cam Replace pressure plate. ring. Note: Steering system external leakage , Extreme wear of cam ring. Replace parts, flush system Scored pressure plate, thrust plate or Replace parts. (If rotor, replace with rotor. rotating group kit), flush system Vanes not installed properly. Install properly. Radius edge to outside. Vanes sticking in rotor slots. Free-up by removing burrs, varnish or dirt. Foaming milky power steering Air in the fluid, and loss of Check for leak and correct. Bleed fluid, low level and possible fluid due to internal pump system. Extremely cold temperatures low pressure. leakage causing overflow. will cause system aeriation should the oil level be low. If oil level is correct and pump still foams, remove pump from vehicle and separate reservoir from housing. Check welsh plug and housing for cracks. If plug is loose or housing is cracked, replace housing. Fig. 130—Power Steering System Diagnosis PRESSURE ■ HOSE ■ RETURN LHOSEH pressure hose between gauge and pump. Gauge must be between shut-off valve and pump. Open shut-off valve. 2. Remove filler cap from pump reservoir and check fluid level. Fill pump reservoir to full mark on dip stick. Start engine and, momentarily holding steering wheel against stop, check connections at Tool J-5176 for leakage. 3. Bleed system as outlined under Maintenance and Adjustments. GAUG E VALVE Fig. 131—Checking Power Steering Pressures LIGHT DUTY TRUCK SERVICE MANUAL S T E E R IN G 4. Insert thermometer (Tool J-5421) in reservoir filler opening. Move steering wheel from stop to stop several times until thermometer indicates that hydraulic fluid in reservoir has reached temperature of 150° to 170°F. CAUTION: To prevent scrubbing flat spots on tires, do not turn steering wheel more than fixe times without rolling car to change tire-to-floor contact area. 5. Start engine and check fluid level adding any fluid if required. When engine is at normal operating temperature, the initial pressure read on the gage (valve open) should be in the 80-125 PSI range. Should this pressure be in excess of 200 PSI - check the hoses for restrictions and the poppet valve for proper assembly. 6. Close gate valve fully 3 times. Record the highest pressures attained each time. (Note: do not leave valve fully closed for more than 5 seconds as the pump could be damaged internally). a. If the pressures recorded are within the listed specs and the range of readings are within 50 PSI, the pump is functioning within specs. (Ex. Spec. 1250 - 1350 PSI - readings - 1270 - 1275 1280). b. If the pressures recorded are high, but do not repeat within 50 PSI, the flow controlling valve is sticking. Remove the valve, clean it and remove any burrs using crocus cloth or fine hone. If the system contains some dirt, flush it. If it is exceptionally dirty, both the pump and the gear must be completely disassembled, cleaned, flushed and reassembled before further usage. c. If the pressures recorded are constant, but more than 100 PSI, below the low listed spec., replace the flow control valve and recheck. If the pressures are still low, replace the rotating group in the pump. 7. If the pump checks within specifications, leave the valve open and turn (or have turned) the steering wheel into both corners. Record the highest pressures and compare with the maximum pump pressure recorded. If this pressure cannot be built in either (or one) side of the gear, the gear is leaking internally and must be disassembled and repaired. See the current Overhaul Manual. 8. Shut off engine, remove testing gage, spare hose, reconnect pressure hose, check fluid level and/or make needed repairs. POWER STEERING SYSTEM EXTERNAL LEAKAGE General Procedure 1. Wipe suspected area dry. 2. Check for overfilled reservoir. 9 -9 1 3. Check for oil aeration and overflow. 4. Check hose connections - tighten if necessary. 5. Verify exact point of leakage. Example: Torison bar, stub shaft and adjuster seals are close together; exact leakage point could be confused. Example: The point oil drips from is not necessarily the leakage point - oil overflowing from reservoir for instance. 6. When service is required: A. Clean leakage area upon disassembly. B. Replace leaking seal. C. Check component sealing surfaces for damage. D. Reset bolt torque to specifications where required. Some of the customer complaints associated with the power steering system may be reported as: 1. Oil leakage on garage floor. 2. Oil leaks visible on steering gear, pump, or anywhere else on the left side of engine compartment. 3. Growling noise especially when parking or when engine is cold. 4. Loss of power when parking. 5. Heavy steering effort. For the purpose of trouble shooting complaints of this nature, assume that there is an external leak in the power steering system. Leakage Diagnosis (Fig. 132) This section is a guide, which when used in conjunction with your service manual will enable you, a service mechanic, to locate, identify, and repair leaks in the power steering system. It contains: A. Diagram of the complete power steering system with the areas of potential leakage identified. B. Recommended procedure for locating external leakage in the vehicle. C. Areas of leakage to be checked, which can be serviced at once. D. Part replacement recommendations. E. Diagram of the actual areas where leakage will be observed and the action recommended to repair this leakage. Leakage Check The purpose of the diagnostic procedure is to pin-point the location of the leak. The method outlined in this manual can be followed to locate the leak and repair it. In some cases you will be able to locate the leak easily* However, seepage type leaks may be more difficult to LIGHT DUTY TRUCK SERVICE MANUAL 9 -9 2 STEERING RESERVOIR DEFECTS RESERVOIR CAP DRIVE SHAFT SEAL RETURN HOSE & CLAMPS HOUSING DEFECT RESERVOIR " 0 " RING ADJUSTER PLUG O " RING TORSION " 0 " RING RING & STUD/BOLT " 0 " RINGS PRESSURE HOSE PRESSURE & RETURN PORTS STUB SHAFT SEAL SIDE COVER " 0 " RING ADJUSTER LOCK NUT END COVER " 0 " RING PITMAN SHAFT SEAL HOUSING DEFECT Fig. 132—Power Steering System Potential Leakage Areas LIGHT DUTY TRUCK SERVICE MANUAL STEERING isolate. For seepage leaks, the following method is recommended. A. With the vehicle’s engine off, wipe the complete power steering system dry (gear, pump, hoses, and connections). B. Check oil level in pump’s reservoir and adjust as directed in maintenance section. C. Start engine and turn steering wheel from stop to stop several times. Do not hold in corner for any length of time as this can damage the power steering pump. It is easier if someone else operates the steering wheel while you search for the seepage. D. Find the exact area of leakage. E. Refer to the diagnostic chart to find the recommended method of repair. Quick Fixes The purpose of this section is to acquaint you with the types of leakage which can be repaired very easily. It contains information on reservoir oil level, the hoses and the hose connections. An overfilled pump reservoir can be a cause for leakage complaint. The oil in the steering system expands as heated during normal usage. If overfilled the excess is forced through the breather cap hole and may be sprayed over the engine by air blast. Operate the engine and steering system until normal operating temperature is obtained. Remove the reservoir cap and check the graduated level on the dipstick. Adjust the oil level as required. Seepage at the hose connections can be a cause for leakage complaint and can be due to loose connection nuts. If leakage is observed at the hose connections, and the nut is not cross threaded, tighten the nuts at the gear to 30 foot pounds. The nut at the power steering pump should be tightened to 40 foot pounds. If tightening to this torque does not stop the leak, refer to the diagnostic chart. If either the return hose or the pressure hose leaks, replace the hose. Component Replacement Lip seals, which seal rotating shafts, require special treatment. This type of seal is used on the steering gear at the pitman shaft, at the stub shaft, and on the drive shaft of the pump. When leakage occurs in one of these areas, always replace the seal(s), after inspecting and thoroughly cleaning the sealing surfaces. Replace the shaft only if very severe pitting is found. If the corrosion in the lip seal contact zone is slight, clean the surface of 9 -9 3 the shaft with crocus cloth. Replace the shaft only if the leakage cannot be stopped by smoothing with crocus cloth first. Housing or Cover Seepage - Both the power steering gear and pump assemblies are leakage checked before shipment. However, occasionally oil seepage may occur from the gear or pump other than the seal areas. If this type of leakage is found, replace the leaking part. The following diagrams have been prepared to show the potential areas of leakage. If leakage occurs in the zones shown, replace the part listed using the service manual as a guide. STEIRING GEAR LEAKAGE DIAGRAMS (Fig. 133) Pay particular attention to the exact source of leakage as an improper diagnosis will result in an ineffective repair. [~T7| Replace adjuster plug “O” RING SEAL. [X] Replace dust and stub shaft seals. Refer to above on stub shaft seal ride. [~37| Replace rotary valve assembly. [X] Seat ball flush with punch and restake. If seepage persists, replace housing. |~5~1 Replace both pitman shaft seals. Refer to above on seal ride area of pitman shaft. [~6~| Replace end plug “O” ring seal. p7~| Tighten nut to 35 foot pounds. Replace nut if leakage persists. |T | Replace side cover “O” ring seal. |~97| If leakage persists upon tightening the fitting nut (30 foot pounds), replace brass connector and reface hose tube flare. If leakage is due to damaged threads (cross threaded), replace brass connector. Repair fitting nut or replace hose as required. If housing threads are badly stripped, replace housing. PUMP LEAKAGE DIAGRAMS (Fig. 134) [lO~j Tighten hose fitting nut to 40 foot pounds. If leakage persists, replace discharge fitting and reface hose tube flare or replace hose as required. 11 Tighten fitting to 35 foot pounds. If leakage persists, replace both “O” ring seals. 12. Replace reservoir “O” ring. Replace drive shaft seal. Refer to above on seal ride area of drive shaft. Replace reservoir. Check oil level. If leakage persists with the level right and the cap tight, replace the cap. LIGHT DUTY TRUCK SERVICE MANUAL 9 -9 4 STEERING LEAKAGE AREAS Fig. 133—Power Steering Gear Leakage LIGHT DUTY TRUCK SERVICE MANUAL STEERING 9-95 Fig. 134—Power Steering Pump Leakage LIGHT DUTY TRUCK SERVICE MANUAL 9 -9 6 STEERING SPECIAL TOOLS 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. J-6632 J-5504 J-23073 J-23072 J-5176 J-5822 J-8433 J-21854 J-23653 J-5421 J-5860 J 21239 J-2927 J-1614 J-7539 J-7624 J-4245 J-22670 Pitman A rm Puller Pitman A rm Puller S h ift Tube Installer S h ift Tube Remover Oil Pressure Gauge W orm shaft Bearing Cup Remover Pump Pulley Remover (Cast Pulley) C olum n Pivot Pin Remover Lock Plate Compressor Therm om eter Torque Wrench A dapter Pump Pulley Remover (Stamper Pulley) Steering Wheel Puller Sector S haft Bushing Remover Ball Retainer Spanner Wrench #23 Internal Pliers Pump S haft Seal Installer 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. J-6222 J-23600 J-8947 J-5755 J-2619 J-8092 J-6278 J-6278-2 J-7079-2 J-8524-1 J-8524-2 J-6219 J-22407 J-8937 J-6217 J-23980 S haft Seal P rotector Belt Tension Gauge Rack-Piston Seal Compressor W orm shaft Bearing Race Installer Slide Hammer Handle Pitman S haft Bearing Remover Pitman S haft Bearing Installer Handle A d ju ste r Plug Bearing Installer A d ju ste r Plug Bearing Remover Pitman S haft Seal Installer Pitman S haft Bearing Installer Ball Seal Remover C onnector Seat Installer Steering C olum n Electrical A n a lyze r T orque Wrenches Fig. 135—Special Tools C & K LIGHT DUTY TRUCK SERVICE MANUAL STEERING 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. J-6632 J-5504 J-5176 J-5822 J-5860 J-22670 J-6222 J-9226 J-7576 J-21239 J-2927 J-1614 J-7539 J-7624 J-4245 J-23600 J-5755 J-2619 Pitman A rm Puller Pitman A rm Puller Pressure Gauge W orm shaft Bearing Cup Puller Torque Wrench Adapter Pump S haft Seal Installer Shaft Seal Protector Pitman Shaft Bushing Replacer Rack-Piston Seal Compressor Pump Pulley Remover Steering Wheel Puller Sector Shaft Bushing Remover Ball Retainer Spanner Wrench #23 Internal Pliers Belt Tension Gauge W orm shaft Bearing Cup Installer Slide Hammer 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. J-6278 J-6278-2 J-7079-2 J-8524-1 J-8524-2 J-6219 J-6217 J-5421 J-22407 J-22727 J-22708 J-22573 J-22599 J-21854 J-22551 J-22549 ------- 9 -9 7 Pitman Shaft Bearing Remover Pitman Shaft Bearing Installer Drive Handle Adjuster Plug Bearing Installer A djuster Plug Bearing Remover Pitman Shaft Seal Installer Connector Seat Installer Therm om eter Pitman Shaft Bearing Installer Term inal Remover Turn Signal Cover Remover Steering Column Holding F ixture Lock N ut Socket Pivot Pin Remover S h ift Tube Remover S h ift Tube Installer Torque Wrenches Fig. 136—Special Tools G & P LIGHT DUTY TRUCK SERVICE MANUAL SECTION 10 WHEELS AND TIRES INDEX General Description.....................................................10-1 Maintenance..................................................................10-2 Wheel Nut Torques....................................................10-2 Tire Rotation..............................................................10-2 Tire Inflation Pressure...............................................10-2 Service Operations.........................................................10-4 Correcting Irregular Tire W ear................................10-4 Wheel Removal and Installation..............................10-6 Tire Mounting and Demounting..............................10-6 RHP Rims.......................................................................10-8 RHP Rim Tire Mounting and Demounting..........10-9 GENERAL DESCRIPTION The 1973 truck is equipped with a wide range of tube or tubeless type tires and wheels selected according to the truck GVW rating and type of service. The dual rear wheel option is available on Series 30 trucks, except G models. The factory installed tires on your truck are selected to provide the best all around tire performance for all normal operations. All tires are manufactured for use on wheels of specific size, configuration and load carrying capacity. When replacing a worn or damaged tire it is essential to use a replacement tire of the same size and load rating as that with which the vehicle was equipped when manufactured. The load capacity chart in the General Information section of this manual lists the minimum size tire required for each GVW rating. Only tires of the sizes shown in the chart or tires of greater capacity approved for use with your vehicle should be installed. Use of any other size of tire may seriously affect ride, handling, ground clearance, tire clearance and speedometer calibration. Similarly, use of wheels with offsets other than recommended or use of what are commonly referred to as "reversed rims" may seriously overload 10 SERIES wheel bearings or other axle components causing rapid wear or failure of these parts and void your vehicle warranty. NOTE: On four-wheel drive vehicles all tires must be of equal size (but not necessarily ply rating) and of same tread configuration. 10 SERIES 20, 30 SERIES DUAL REAR Fig. 2 — R e a r W h e e ls a n d A tta c h m e n ts TUBELESS TIRES These tires have an inner liner which, if punctured, tends to cling to the penetrating object forming a partial seal until the object is removed from the tire. It is essential to conduct a periodic pressure check according to the tire inflation tables on the following pages plus a visual tire inspection to detect imbedded objects which might otherwise go unnoticed and cause serious casing damage. TUBE TIRES 20-30 SERIES Some commercial vehicles are equipped (at customer option) with synthetic rubber tires and tubes. Fig. 1—Front Wheels and Attachm ents THEORY TIRE TRACTION A decrease in driving, cornering, and braking traction occurs when water, snow, ice, gravel, or other material is on the road surface. Driving practices and truck speed should be adjusted to the road conditions. When driving on wet or slushy roads, it is possible for a wedge of water to build up between the tire and road surface. This phenomenon, known as hydroplaning, may cause partial or complete loss of traction, which adversely affects vehicle control and stopping ability. To reduce the possibility of traction loss, the following precautions should be observed. LIGHT DUTY TRUCK SERVICE MANUAL 1 0 -2 WHEELS AND TIRES 1. Slow down during rainstorms or when roads are slushy. 2. Slow down if road has standing water or puddles. 3. Replace tires when tread depth becomes 1/16". 4. Keep tires properly inflated. TREAD STILL GOOD TREAD WORN OUT Puncture Inspection and Repair At each lubrication, tires should be checked for foreign objects in the tread or breaks in the tread or sidewall. If tire is punctured or otherwise damaged, it should be repaired using one of several repair kits available through tire manufacturers outlets. Tread Wear When the depth of tread becomes 1/16-inch or less, there is a significant decrease in traction and anti-skid properties, also, the majority of tire troubles will occur in the last 10% of tire life. The original equipment passenger type tires on Series 10 Fig. 3 — P a s s e n g e r T yp e T ire T r e a d W e a r trucks incorporate built in tread indicators to assist in judging when tires are worn out and should be replaced. These indicators are molded into the bottom of the tread groove and will appear as bands across the thread as a visual reminder that the tire should be replaced (see fig. 3). MAINTENANCE WHEEL NUT TORQUES On a new vehicle or after the wheel has been changed, the wheel nut torque must be checked at 100, 1,000 and 6,000 miles and every 6,000 miles thereafter. TIRE ROTATION The rotation of truck tires will minimize tire trouble and produce longer tire life. With rotation, accelerated and irregular tire wear on any one particular tire will be spread out over the entire set, and replacement frequency will be reduced. Tire wear may also contribute to such trouble as poor handling and shimmy. No definite tire rotation formula is applicable to all trucks because of the wide range of usage. However, certain fundamentals, mixed with experience and observation, will assist the trucker in reducing tire costs. A rotation sequence that moves the front tires to the rear is a general recommendation. Due to different loading conditions on the wheels, new tires which are broken in on the front wheels usually produce the greatest overall tire life. The outer tire on a dual wheel will skid or drag on a turn because of the difference in the turning radii of the inner and outer tires. This results in faster wear of the outer tire. In general, the tire with the largest diameter or least wear should be at the outside of each dual wheel. In addition, certain truckers have found when trucks are operated continuously on high crown roads an increase in air pressure of from 5 to 10 pounds in the outside tire of each dual produces maximum tire life. To equalize wear it is recommended that the tires be rotated every 6,000 miles. Upon rotation, tire pressure must be adjusted (front and rear) in accordance with the recommendations for inflation pressure. Inflation Pressure Standard inflation pressures for tires are listed in the "Load Capacity Chart" in Section 0 of this manual. These are the minimum required tire pressures and tire sizes for maximum permissible loads. Minimum tire pressures for tires other than those listed in the "Load Capacity Chart" can be determined from the "Tire Load and Inflation Pressure Chart" on the following page, using the weights shown on the vehicle GVW plate. The use of improper tire inflation pressures can affect tire life and load carrying capacity, and may affect vehicle handling. Inflation pressures should be checked at least once a month (and preferably more often) to insure that the right amount of air is contained in the tires. With regard to tire life, too little air pressure allows abnormal deflection of the tire causing excessive operating temperatures, while too much air pressure prevents normal deflection, making the cord body more vulnerable to road impacts. Use of optional inflations is allowable only with a reduced load as shown in the "Tire Load and Inflation Pressure Chart." When operating at loads greater than the optional reduced load, the inflation pressure must be increased to the standard inflation for full rated loads. On K10 4 wheel drive Pick-Ups and Utility vehicles with passenger type tires, reduced tire pressures are recommended for front tires only. Optimum ride and handling require full maximum inflation pressure in the rear tires at all times. LIGHT DUTY TRUCK SERVICE MANUAL WHEELS A N D TIRES 10-3 TIRE LOAD & INFLATION PRESSURE PASSENGER TYPE TIRES FOR LIGHT TRUCKS USED IN HIGHWAY SERVICE T ire S ize Load R ange E78-14 F78-14 G78-14 E78-15 G78-15 H78-15 L78-15 L78-15 6.50-16PT B B B B B B B D C 20 22 973 1054 1136 973 1136 1236 1382 1027 1109 1191 1027 1191 1309 1455 1105 1164 ___ _____ _________ _____ 24 ____ ___ Tire Load. L lth t V arious In fla tio n P res s u re s 30 32 34 26 28 1082 1164 1255 1082 1255 1373 1527 1127 1218 1309 1127 1309 1436 1591 1182 1272 1364 1182 1364 1500 1664 1227 1318 1418 1227 1418 1555 1727 1273 1364 1473 1273 1473 1609 1791 1223 12 77 1332 1386 1436 1855 1486 36 38 40 1909 1536 1973 2024 70 75 TIRE LOAD AND INFLATION PRESSURE TIRES FOR LIGHT TRUCKS USED IN HIGHWAY SERVICE TIRES USED AS SINGLES T ire S ize Load Range Ply Rating T ire Load L im its a t V arious In fla tio n P res s u re s 30 35 40 45 50 55 60 65 1 T U B E TYPE TIRES M O U N T E D ON 5 ° TA PE R E D BEAD SEAT R IM S 6.50-16 7.00-16 7.00-16 7.00-18 7.50-16 7.50-16 7.50-16 C C D D C D E 6 6 8 8 6 8 10 1270 1430 1430 1390 1560 1560 1500 1680 1680 1610 1800 1800 — — — — 1620 1620 1620 1770 1770 1770 1930 1930 1930 2060 2060 2060 T U B E LE S S TIR E S M O U N T E D ON 15 8-19.5 8-19.5 8 10 1910 1950 2030 2090 2130 2220 2350 2470 2590 2190 2190 2310 2310 2440 2410 2560 2670 2780 2410 2540 2410 2540 *With 6 " R im s - -2930 at 80 2680 2680 3060 at 85 TA PER ED BEAD SEAT D RO P C E N TE R RIIVIS — — — — - - 2110 2110 2270 2270 2800 2800* 3170 at 90. TIRES USED AS DUALS T ire S ize Load Range Ply R ating Tir e 30 35 40 Load L im its a t V arious In fla tio n P res s u re s 45 50 55 60 65 70 75 2345 2440 T U B E TYPE TIR E S M O U N T E D ON 5 ° TA P E R E D BEAD SEAT R IM S 6.50-16 7.00-16 7.00-16 7.00-18 7.50-16 7.50-16 7.50-16 C C D D C D E 6 6 8 8 6 8 10 1120 1260 1260 1225 1365 1365 — — 1430 1430 1430 1565 1565 1565 1320 1475 1475 1710 1690 1690 1690 1420 1580 1580 1830 1815 1815 1815 TU B E LE S S TIR E S M O U N T E D ON 15 8-19.5 8-19.5 D E 8 10 - — — 1850 1850 1685 1950 1780 2060 1870 2170 2270 1930 1930 2040 2040 2140 2140 2245 TA PE R E D BEAD SEAT D RO P C E N TE R R IM S 1990 1990 2110 2110 2230 2230 2350 2350 2460 2460 2570 2680(#) (#) 2780 lb s . at 80 lb s . p re s s u re . W IDE BASE TUBELESS TIRES USED AS SINGLES T ire S ize 7.00-14 7.00-14 8.0 0 -1 6 .5 8 .0 0 -1 6 .5 8.75-16.5 8.75-16.5 Load Ply R ating T ire Load L im its a t V arious In fla tio n P res s u re s 30 35 40 45 50 55 60 6 8 1030 1030 1130 1130 1220 1220 1310 1310 1390 1470 1550 D 6 8 C 6 1360 1360 1570 1570 1945 2045 1570 1730 1730 1990 1990 1840 1720 1720 1610 1610 1850 1850 2350 1850 1990 1860 2030 1860 1840 2190 2350 2030 2010 2190 2170 2350 2330 2110 2110 2500 2500 2240 1720 2240 2650 2650 2350 2780 2780 C D C D 8.75-16.5 8 E 9.50-16.5 D 9.50-16.5 10-16.5 C 10 8 10 6 E 1490 1490 65 70 75 2470 2570 2680 3010 3140 3270 (Refer to T ire Load and Inflation Pressure Notes on Page 4 ). LIGHT DUTY TRUCK SERVICE MANUAL 1 0 -4 WHEELS A N D TIRES TIRE LOAD AND INFLATION PRESSURE TIRES FOR LIGHT TRUCKS USED IN HIGHWAY SERVICE (Cont’d) W IDE BASE TUBELESS TIRES USED AS DUALS T ire S ize Load R ange 8 .0 0 -1 6 .5 8 .0 0 -1 6 .5 8 .7 5 -1 6 .5 8.7 5 -1 6 .5 8 .7 5 -1 6 .5 C D C D E Ply R ating 6 8 6 8 10 T ire Load L im its a t V a rio u s In fla tio n P ressures 30 35 1195 1195 1380 1380 1380 1310 1310 1515 1515 1515 40 1415 1415 1630 1630 1630 j Tire Load and Inflation Pressure Notes 1. T ire in fla tio n pressure may increase as much as 6 pounds per square inch (p s i) when hot. 2. For continuous high speed operation, (over 75 m ph) w ith pass­ enger car type tire s increase tire in fla tio n pressure 4 pounds per square inch over the recom m ended pressures up to a m axim um of 32 pounds per square inch cold for load range B tires, or 36 pounds per square inch cold fo r load range C tires. Sustained speeds above 75 mph are not recommended when the 4 pounds per square inch a d ju stm e n t w ould require pressures greater than the m axim um stated above. 3. For sustained high speed d rivin g over 65 MPH, w ith tru c k type tire s cold in fla tio n pressures m ust be increased 10 PSI above those specified in the above table fo r the load being carried. For special operating c o n d itio n s . . . such as cam pers or oth er high center of g ra vity loading v e h ic le s . . . cold in fla tio n pres­ sures may be increased up to 10 PSI. The total increase in 45 1520 1520 1750 1750 1750 50 55 60 1620 1710 1800 1855 1855 1970 1970 2070 2070 65 70 75 2175 2260 2360 cold in fla tio n pressures shall not exceed 10 PSI above those specified in the above ta b le fo r the load being ca rrie d . 4. Cold tire in fla tio n pressure: a fte r vehicle has been inoperative fo r 3 hours or m ore, or d riven less than 1 m ile. Hot tire in fla ­ tion pressure: a fte r vehicle has been d riven 10 m iles or at speeds of more than 60 m iles per hour. 5. Loads should be d is trib u te d as evenly as possible in the cargo area. 6. Vehicles w ith luggage racks do not have a vehicle load lim it greater than specified. 7. When to w in g tra ile rs , the a d d itio n a l load on th e axle induced by the tra ile r tongue load m ust not cause th e axle load to exceed the lim its stam ped on the GVW plate. T ire in fla tio n pressures m ust be adjusted accordingly. 8. M axim um load m ust not exceed the m axim um tire load lim it as indicated by th e underscoring in the table. M in im u m recom ­ mended cold in fla tio n pressures fo r various loads m ust con­ form to the table. SERVICE OPERATIONS CAUTION: Servicing o f tires mounted on multi-piece rims requires proper tools, safety equipment and specialized training. Severe injuries can result from improper servicing techniques. It is recommended that tires on multi-piece rims be serviced only by competent personnel with proper equipment or by competent truck tire repair shops. CORRECTING IRREGULAR TIRE WEAR Heel and Toe Wear This is a saw-toothed effect where one end of each tread block is worn more than the other. The end that wears is the one that first grips the road when the brakes are applied. Heel and toe wear is less noticeable on rear tires than on front tires, because the propelling action of the rear wheels creates a force which tends to wear the opposite end of the tread blocks. The two forces, propelling and braking, make for more even wear of the rear tires, whereas only the braking forces act on the front wheels, and the saw-tooth effect is more noticeable. A certain amount of heel and toe wear is normal. Excessive wear is usually due to high speed driving and excessive use of brakes. The best remedy, in addition to cautioning the owner on his driving habits, is to interchange tires regularly. Side Wear This may be caused by incorrect wheel camber, underinflation, high cambered roads or by taking corners at too high a rate of speed. The first two causes are the most common. Camber wear can be readily identified because it occurs only on one side of the treads, whereas underinflation causes wear on both sides. Camber wear requires correction of the camber first and then interchanging tires. There is, of course, no correction for high cambered roads. Cornering wear is discussed further on. Misalignment Wear This is wear due to excessive toe-in or toe-out. In either case, tires will revolve with a side motion and scrape the tread rubber off. If misalignment is severe, the rubber will be scraped off of both tires; if slight, only one will be affected. The scraping action against the face of the tire causes a small feather edge of rubber to appear on one side of the tread and this feather edge is certain LIGHT DUTY TRUCK SERVICE MANUAL WHEELS A N D TIRES indication of misalignment. The remedy is readjusting toe-in, or rechecking the entire front end alignment if necessary. 10-5 that all rolling components (brake drums, bearings, seals, etc.) are included in the balancing procedure and thereby have any existing unbalance corrected. Uneven Wear Uneven or spotty wear is due to such irregularities as unequal caster or camber, bent front suspension parts, out-of-balance wheels, brake drums out of round, brakes out of adjustment or other mechanical conditions. The remedy in each case consists of locating the mechanical defect and correcting it. Cornering Wear When a truck makes an extremely fast turn, the weight is shifted from an even loading on all wheels to an abnormal load on the tires on the outside of the curve and a very light load on the inside tires, due to centrifugal force. This unequal loading may have two unfavorable results. First the rear tire on the inside of the curve may be relieved of so much load that it is no longer geared to the road and it slips, grinding off the tread on the inside half of the tire at an excessive rate. This type of tire shows much the same appearance of tread wear as tire wear caused by negative camber. Second the transfer of weight may also overload the outside tires so much that they are laterally distorted resulting in excessive wear on the outside half of the tire, producing a type of wear like that caused by excessive positive camber. Cornering wear can be most easily distinguished from abnormal camber wear by the rounding of the outside shoulder or edge of the tire and by the roughening of the tread surface which denotes abrasion. Cornering wear often produces a fin or raised portion along the inside edge of each row in the tread pattern. In some cases this fin is almost as pronounced as a toe-in fin, and in others, it tapers into a row of tread blocks to such an extent that the tire has a definite "step wear" appearance. The only remedy for cornering wear is proper instruction of operators. Driving more slowly on curves and turns will avoid grinding rubber off tires. To offset normal cornering wear as much as possible tires should be interchanged at regular intervals. Wheel and Tire Balancing It is desirable from the standpoints of tire wear and vehicle handling ease to m aintain proper balance of front wheel and tire assemblies on all models. All wheels intended for use on front of vehicle, such as those switched during periodic tire rotation and those installed as new or repaired replacement equipment should be accurately balanced. This may be accomplished by either of the two types of balancing systems in current use which balance wheels either on the vehicle or off. The "on the vehicle" type, however, is the more desirable in Truck W heel Balance W eights All 1973 truck wheels equipped with a tubular side ring (rolled flange rim) on the outboard side of the wheel rims require special design weights to fit. Dynamic balancing can be accomplished through use of these special balance weights which are designed only for installations on the outboard side of these wheels. Conventional weights fit only the inboard side of these wheels. Static Balance Static balance (sometimes called still balance) is the equal distribution of weight of the wheel and tire assembly about the axis of rotation in such a manner that the assembly has no tendency to rotate by itself, regardless of its position. For example: A wheel with a chunk of dirt on the rim will always rotate by itself until the heavy side is at the bottom. Any wheel with a heavy side like this is statically out of balance. Static unbalance of a wheel causes a hopping or pounding action (up and down) which frequently leads to wheel "flutter" and quite often to wheel "tram p". Dynam ic Balance Dynamic balance (sometimes called running balance) means that the wheel must be in static balance, and also run smoothly at all speeds. To insure successful, accurate balancing, the following precautions must be observed: • Wheel and tire must be clean and free from all foreign matter. • The tires should be in good condition and properly mounted with the balance mark on the tire, if any, lined up with the valve. • Bent wheels that have runout over 1/16" should either be replaced or straightened before being balanced. • Inspect tire and wheel assembly to determine if an eccentric or out-of-round condition exists. Note that this condition, if severe, cannot be "balanced out." An assembly which has an out-of-round condition exceeding 3/16" on tire sizes through 19.5" is not suitable for use on the front of the vehicle. Its use on the rear should be governed by its general condition and whether the roundness defect seriously detracts from overall ride quality. • When balancing wheels and tires, it is recom­ mended that the instructions covering the operation of the wheel balancer being used be closely followed. LIGHT DUTY TRUCK SERVICE MANUAL 1 0-6 WHEELS AND TIRES WHEEL REMOVAL A N D INSTALLATION Jacking Instructions Place vehicle jack supplied or recommended as follows: to raise a rear wheel place jack under axle housing; to raise front wheel of C, G, P models place jack under lower control arm pivot; to raise front wheel of K models, place jack under front axle near spring seat. Dual and Single Wheels When installing the tire and wheel on the vehicle, the following procedure should be followed: After wheel nuts are put on loosely, turn the wheel until one nut is at the top of the bolt circle; tighten the nut just snug. Snug up the remaining nuts criss-cross to minimize runout, then tighten the nuts to the recommended torque alternately and evenly to avoid excessive runout. Lateral runout should not exceed 1/8" on front wheel or 3/16" on rear wheel. Matching Side and Lock Rings Side and lock rings of different rim types are not interchangeable Some may appear to be, but they do not fit properly on the rim base. Serious accidents have resulted from the use of mismatched rings. Rim base and rings must be matched according to manufacturer, size and type. This information is stamped on each part. Installing Synthetic Tubes CAUTION: When tube and flap are not 1. 2. 3. 4. 5. 6. 7. 8. properly lubricated and mounted, they will stretch thin in the tire bead and rim region. This will cause premature failure. Before installing tube in tire, clean inside of casing thoroughly. Insert tube in tire and inflate until it is nearly rounded out. Inspect rim for rust scale and bent flanges—clean rust scale and straighten flanges where necessary. Using a brush or cloth swab, apply a solution of neutral vegetable oil soap to the inside and outside of tire beads and also to the rim side of the tube. Do not allow soap solution to run down into tire. When mounting tire and tube on a drop center rim, follow the standard procedure. Be sure tire is centered on rim so that beads are out of rim well before inflating. Do not allow tire to hang loosely on wheel while inflating. Center valve and pull it firmly against the rim. Hold in this position and inflate until tire beads are firmly seated on rim against flanges. Completely deflate tire by removing valve core. Reinflate tire to recommended pressure. TUBELESS TIRES Tubeless tires mounted on one piece full drop center rims are standard on some trucks. These tires have a safety inner liner which if punctured, tends to cling to the penetrating object forming a partial seal until the object is removed from the tire. The mounting and demounting of tubeless truck tires will present no problem when a rubber lubricant, such as Ru-Glyde or equivalent is applied to tire beads and rim flanges. Ru-Glyde or equivalent in addition to materially assisting in mounting and demounting also prevents rusting at the tire sealing area and thus prevents tires from adhering to the wheel. CAUTION: A hammer, or tools with sharp edges, should never be used to demount or mount tubeless tires as damage to rim flange or tire sealing bead may result. Inspection for Leaks 1. With wheel assembly removed from vehicle, inflate the tire to recommended operating pressure. 2. Check for leaks at rim bead by placing wheel and tire horizontal and allowing water to stand in groove between rim and tire. Check for large leaks by lowering assembly into water tank or running water over tire. Demounting (6.50-16 tires) The 6.50-16 size may be demounted using present tire machines or standard tire irons following the same procedure employed in servicing tube type tires. Demounting (all except 6.50-16 tires) 1. Remove valve core to completely deflate tire. With tire lying flat on floor, loosen beads from rim seats by walking around on tire with heels at points close to rim. With wide side of rim down, apply tire lubricant to top bead. With stops toward rim, insert spoon ends of two tire irons about 10" apart. While standing on tire to hold bead in gutter, pull one tool toward center of rim (fig. 4). 2. Hold one iron in position with foot and pull second iron toward center of rim. Progressively work bead off rim, taking additional bites if necessary (fig. 5). 3. Stand assembly in vertical poisition. Lubricate second bead. At top of assembly insert straight end of tire iron between bead and back flange of rim at about a 45 degree angle (fig. 6). 4. Turn iron so that is is perpendicular to rim. Pry second bead off (fig. 7). Mounting (all except 6.50-16 tires) All tubeless tires except the 6.50-16 size will be mounted as follows: 1. Inspect rim to insure bead seats are clean and smooth. Then place rim on floor with wide side LIGHT DUTY TRUCK SERVICE MANUAL WHEELS A N D TIRES Fig. 4—Inserting Tire Iron to Lift Bead Fig. 5—Lifting Bead Over Rim down and lubricate first bead of tire and upper bead seat of rim (fig. 8). 2. Push first bead into well of rim and onto rim as far as possible. Using straight end of tire iron and with stop resting on rim flange, work remaining section of first bead over rim (fig. 9). 3. Hold second bead in well by standing on tire. When necessary, push section of bead into rim well and anchor with vise-grip pliers by pinching pliers on rim flange. Using spoon end of tire iron with stop toward rim, work progressively around bead using small bites until bead slips over flange onto rim base. If necessary, insert second tire iron and lubricate last 6" of bead before completing mounting (fig. 10). 4. Check valve to be certain that hex nut at the valve base is tight. Inflate tire to recommended operating pressure. Check assembly for air leaks. 10-7 Fig. 6—Inserting Tire Iron in Second Bead Fig. 7—Prying Second Bead from Rim Mounting (6.50-16 tires) 1. Use present tire machines or standard tire irons following the same procedure used in mounting tube type tires, however, extreme care must be exercised to prevent injury to the sealing bead when forcing tire over the rim. A slight application of rubber lubricant on the last 1/2" of each bead circle to be mounted will ease mounting. 2. With tire beads still unseated, rotate tire on wheel so that balance mark on tire lines up with the valve stem. 3. Start tire beads into the rim bead seats as follows: If a tire mounting machine is being used, lift the tire high in the rim forcing the top tire bead against the top rim flange seating the top bead. The lower bead will be seated by the tire weight. When a tire mounting machine is not being used, LIGHT DUTY TRUCK SERVICE MANUAL 1 0-8 WHEELS AND TIRES Fig. 8—Lubricating Tire Bead Fig. 10—Working Second Bead onto Rim be accomplished by applying a mounting band or heavy sash cord to the circumference of the tire and then tightening with a tire iron. RHP RIMS The RHP rim uses a continuous side ring which has two cutouts directly opposite each other and a single tool notch located approximately 45 degrees from one cutout, (fig. 11). The cutouts enable the continuous side ring to be buttoned on to the rim base without deforming either the ring or rim. RHP Rim-Tire Replacement S afety Precautions • Use only parts free from damage or heavy rust. Fig. 9—Working Bead onto Rim beads may be seated by holding the tire and wheel assembly in a vertical position and bouncing on the floor at various points about the tire circumference. 4. Install valve core and inflate tire with quick "shots" of air to firmly seat the sealing beads. 5. Insure that air pressure build-up during the bead seating process is not allowed to exceed 30 pounds pressure. If beads have not seated by the time pressure reaches 30 pounds, assembly should be deflated, repositioned on rim, re-lubricated and re-inflated. 6. Check assembly for air leaks, then inflate tire to pressure recommended for vehicle operation. NOTE: If a seal cannot be effected in the foregoing manner with the rush of air, it can TOOL NOTCH S ID E R I N G CU T-O U TS W H E N A S S E M B L IN G TH E S ID E R I N G START TH IS H A LF J O N T O TH E R I M / FIRST — 7 / CONTINUOUS SIDE RING Fig. 11—RHP Continuous Side Ring LIGHT DUTY TRUCK SERVICE MANUAL WHEELS A N D TIRES 10-9 • Insure that side ring is completely seated before inflating tire. • Inflate tire in safety cage or use clip-on type air chuck so that operator may stand aside during inflation. • Insure that tire is completely deflated prior to removal of rings. Dem ounting Fig. 12—Loosening First Bead Fig. 13—Removing Ring 3 . INSERT S E C O N D T O O L N E X T TO THE FIRST A N D W A L K R IN G O U T O F R IM GUTTER. W O R K T O O LS IN C O U N TE R C LO C K W IS E D IR E C TIO N FR O M T O O L 1. First remove valve core to completely deflate tire. 2. Place tire and wheel on floor with side ring up. 3. To loosen first bead, drive hooked end of rim tool between tire and rim flange and press downward on bead (fig. 12). Progress around rim, using 2 tools, as shown. 4. The side ring is ready to demount if it is loose and turns easily in the rim gutter. 5. Locate the tool notch in the side ring and insert the rim tool or a long, husky screwdriver and pry up (fig. 13), making sure the opposite side of the ring is fitting into the rim gutter. Do not bend the ring. 6. Now a second tool can be inserted (see fig. 14) and used with the first to walk the tools in a counterclockwise direction from the tool notch (work toward the cutout that is farthest from the tool notch). 7. When the tools reach the cutout the ring will usually spring off. If necessary, a light tap with the mallet will free the last half of the ring after it has been pried up so both cutouts are visible. 8. Force upper tire bead into well opposite the valve slot and with tire tool pry opposite portion of bead over edge of rim (fig. 15). 9. Turn tire over and by means of rim tools, loosen 2 . INSERT R IM T O O L IN NOTCH A N D PRY R IN G Fig. 14—Removal of Side Ring Fig. 15—Prying Bead Over Edge of Rim LIGHT DUTY TRUCK SERVICE MANUAL 1 0 - 1 0 WHEELS A ND TIRES Fig. 16—Prying Second Bead From Rim Fig. 18—Applying Second Bead bead on opposite bead seat. This can be further aided by using foot pressure. lO. Make sure one portion of second bead is still in the rim well, then pry opposite portion of bead over edge of rim (fig. 16). This will free the tire from the rim. 4 To apply second bead, start at point opposite valve and press bead toe over rim gutter and into rim well with foot pressure (fig. 18). 5. Mount remainder of bead over rim gutter by means of thin tire tool, being careful not to pinch tube. Place half of side ring in rim gutter and push until M ounting 1. Place tire on rim so that valve is in line with valve hole and insert valve through valve hole. 2. Force first bead down into well of rim just to side of valve with foot. 3. Mount first bead over rim gutter with rim tool progressing from each side of foot to point approximately opposite foot (fig. 17). 4. C O N T I N U E 3. W H I L E TA P P IN G R IN G W IT H MALLET W O R K I N G I N T H IS DIRECTIO N T O W A R D S F A R T H E S T C U T - O U T __ TOOL PR Y IN G W IT H G IV E R IN G A RIM SHARP B L O W W IT H MALLET I N T H IS A R E A W H I C H W IL L S T A R T S E C O N D H A LF OF R IN G IN T O P O S ITIO N 2 . IN S E R T T O O L A N D P R Y - * R IN G D O W N A N D OVER RIM GUTTER 1. IN S E R T R I N G H A L F O P P O S I T E T O O L N O T C H IN T O R IM GUTTER U N TIL CU T-O U TS S T R A D D L E TH E R I M / ASSEMBLING SIDE RING Fig. 17—M ou n tin g First Bead Fig. 19—Assem bling Side Ring LIGHT DUTY TRUCK SERVICE MANUAL WHEELS A N D TIRES 7. 8. 9. 10. 10-11 the ring is half on and the crescent shaped cutouts straddle the rim gutter per illustration (fig. 19). Insert rim tool or large screwdriver in the tool notch and pull the ring on and down toward the rim gutter. While pulling on the rim tool or screwdriver, hit the side ring a sharp blow with a mallet in the area between the tool notch and the nearest cutout. The second half of the ring will now be started over the rim gutter (fig. 20). Remove the rim tool and continue the mallet blows starting at the tool notch and progress counterclock­ wise until the entire ring is in the rim gutter. Check to make sure the side ring is properly assembled before inflating the tire. The ring will turn easily on the rim base after it is fully assembled. Fig. 20—Forcing Ring into Gutter LIGHT DUTY TRUCK SERVICE MANUAL SECTION 11 CHASSIS SHEET METAL IN D E X General D escription........................................................... 11-1 Maintenance and Adjustment......................................... 11-1 Hood Assembly - CK Series......................................... 11-1 Hood Hinge Spring Replacement..............................11-1 Hood Hinge.......................................................................11-1 Hood Lock Assembly.....................................................11-2 Hood Assembly.................................................................11-3 Hood Assembly - G Series............................................11-3 Hood Hinge.......................................................................11-3 Hood Lock Assembly.....................................................11-3 Hood Bumper....................................................................11-4 Hood Assembly.................................................................114 Front Sheet Metal - CK Series...................................11-5 Radiator Support............................................................ 11-6 Front Fender.....................................................................11-7 Front Fender and S kirt................................................11-8 Front Fender Skirt......................................................... 11-8 Running Board.................................................................11-8 Front Sheet Metal - G Series...................................... 11-8 Sheet Metal Checking....................................................11-8 Fender Skirt - P Series...................................................11-8 Wood Grain Applique Installation Procedure....... 11-8 GENERAL DESCRIPTION CK Series G Series The chassis sheet metal assembly is attached to the frame and body at adjustment points. The front of the assembly is supported by two mounts located at the frame side rails. Fore and aft and side adjustment is allowed by oversize holes at the fender rear attaching point and chassis sheet metal mounts. Special shims at the rear locations allow adjustment of the rear of the assembly. The lower rear edge of the assembly is attached to the body at the rocker panel by bolts on each side. Shims are used at this location to provide in and out adjustment at the rear of the fender. The bolts that retain the sheet metal braces must be torqued to the required torques. If these bolts are loose, the braces will not provide additional support for the sheet metal assembly. The front end sheet metal design does not include the radiator support and fenders as loose items inasmuch that these items are welded together as an integral part of the body. Front end sheet metal includes the hood assembly, hood hinges, hood lock catch and support, a hood rod assembly which supports the hood, a welded in radiatorupper tie bar, and series designation plates and hoods emblems. Refer to figure 13 for sheet metal checking. Refer to Section 13 for Radiator and Grille service procedures, Section 14 for Bumpers, and Section 1A for Heater. MAINTENANCE AND ADJUSTMENTS HOOD ASSEMBLY - CK SERIES Hood Hinge Spring R eplacem ent For Hinge Spring Replacement, a tool can be made to dimensions as shown in Figure 1. 1. Raise and safely support the hood in full open position. 2. As shown in Figure 2, engage hooked end of tool to spring, then carefully pull forward to engage or disengage spring from hinge assembly. 2. 3. 4. 5. place protective covering over the cowl and fenders. Scribe position of hinge attachment on hood rear reinforcement and remove two bolts. Remove hood hinge spring as described above. Scribe position of hinge attachment on fender assembly and remove bolts. Remove hinge. Installation Hood Hinge (Fig. 2) Removal 1. Prop the hood in the extreme open position and 1. Install hinge assembly to fender and align within scribe marks. Install bolts. 2. Install hood hinge spring. LIGHT DUTY TRUCK SERVICE MANUAL I 1 1-2 CHASSIS SHEET METAL 3. Install bolts and align hood. See Hood Alignment in this section. Hood Lock Assembly A bolt-type hood lock is used as shown in Figure 3. The lock bolt, located on the hood dovetails with the mounted striker plate, preventing upward or downward movement of the hood while the vehicle is in motion. Integral with the striker plate is the combination lock release lever and safety catch. Fig. 2—Hood Hinge and Spring—CK Series Replacement 1. Open hood and remove the four bolts holding the combination lock support and lock bolt. NOTE: If original hood lock assembly is to be replaced, scribe a line around lock for alignment on installation. 2. Place hood lock assembly in position. 3. Adjust as outlined under Adjustments. Adjustment (Fig. 4) 1. Loosen lock nut on lock bolt and adjust lock bolt approximately 2 7/16 inches from bottom of lock bolt to bottom of support. 2. Adjust tightness of support screws so they are just snug enough to hold support in position. 3. Adjust support fore and aft until nubble enters center of elongated guide. Bending nubble to accomplish this adjustment may seriously effect lock operation and safety latch engagement and is, therefore, not recommended. 4. Tighten screws to 140 pound inches. 5. Adjust lock bolt to obtain a secure hood closure and reasonable lock release effort. Hood Bum per Adjustm ent Hood Bumpers must be adjusted until hood and fender line up flush at front corner. Adjust hood lock bolt to obtain a minimum load of 45 pounds to a maximum load of 55 pounds on each bumper after hood is firmly slammed. LIGHT DUTY TRUCK SERVICE MANUAL CHASSIS SHEET M ETAL 11-3 3. Perform hood lock adjustment as outlined in this section if necessary. Hood Assembly - G Series The alignment of the hood is controlled by the position of the hood hinges and the height of the two bumpers located one at each side of the radiator support. The adjustment at the hood lock must be made after the hinges and bumpers are properly adjusted (refer to Hood Lock Adjustment fig. 6). To align the hood and lock proceed as follows: Hood Hinge (Fig. 5) The body mounted portion of slotted to provide up and down mounted end is slotted to provide movement. Hood support rod assembly must binding in assembled position. Fig. 4—Hood Lock Bolt and Bumper—CK Series Hood Assembly Removal 1. Open hood and prop in full open position. NOTE: If hood is to be reinstalled and present alignment is satisfactory, mark each hinge in relation to hood, to assure original alignment. 2. Remove two (2) cap screws which attach each hinge to hood; then with a helper remove hood from vehicle. Installation the hood hinges are movement. The hood forward and rearward operate freely without Hood Lock Assembly A bolt-type hood lock is used as shown in Figure 6. The lock bolt, located on the hood, dovetails with the mounted striker plate, preventing upward or downward movement of the hood while the vehicle is in motion. Integral with the striker plate is the combination lock release lever and safety catch. 1. Scribe a line around the entire hinge plate to be repositioned. 2. Loosen the appropriate screws and shift the position of the hood into correct alignment using the scribe marks to check amount of movement. Check alignment by tightening screws and closing the hood. 1. If original hood is to be installed, position hood to hinges and install four cap screws snug which attach hinges to hood. NOTE: If a new hood is to be installed, perform procedures as outlined under Align­ ment, directly below. 2. Shift hood on hinges to location marks made before removal of hood, then tighten attaching cap screws at hinges firmly. Close hood and check fit. If necessary to align hood perform procedure as outlined under "Alignment" which follows. Alignment (Fig. 2) 1. Loosen hood hinge bolts. Note that rear most bolt hole in hinge is slotted to allow hood trailing edge to move up and down. 2. Adjust hood rear bumper bolt so that bumper is flush with fender. Nut must be threaded completely onto bolt before torquing to maintain design height. LIGHT DUTY TRUCK SERVICE MANUAL 1 1 -4 CHASSIS SHEET METAL Replacement 1. Open hood and remove the four bolts holding the combination lock catch and lock bolt. NOTE: If original hood lock assembly is to be replaced, scribe a line around lock for alignment on installation. 2. Place hood lock assembly in position. 3. Adjust as outlined under Adjustments. Adjustment CAUTION: Hood lock assembly to be adjusted fore and aft until hood lock bolt enters center of elongated guide. Bending bolt to accomplish this adjustment may seriously effect lock operation and safety catch engagement and is, therefore not recommended. 1. Adjust lock bolt as shown in Figure 7. 2. Open hood and adjust tightness of catch assembly so that it is just "snug" enough to hold lock bolt in position. 3. Close hood in a normal manner. 4. Raise hood again; lock bolt assembly will have shifted to operating position. Tighten bolts fully. Further adjustment may be made at lock bolt support, if necessary. 5. Adjust lock bolt to obtain a secure hood closure and reasonable lock release effort. Hood Bumper (Fig. 7) Adjust hood bumpers so that hood top surface is flush with the fender and grille top surfaces. Refer to Figure 13 for correct sheet metal adjustment dimensions. Hood Assembly (Fig. 7) Removal 1. Lay a fender cover along cowl top to prevent hood from scratching painted surfaces. 2. Open hood and prop in full open position. NOTE: If hood is to be reinstalled and present alignment is satisfactory, mark each hinge in relation to hood, to assure original alignment. 3. Remove rod assembly (see fig. 5). 4. Remove two cap screws which attach each hinge to hood; then with a helper remove hood from vehicle. Installation 1. If original hood is to be installed, position hood to hinges with helper and install four cap screws snug which attach hinges to hood. 2. Install rod assembly. NOTE: If a new hood is to be installed, perform procedures as outlined under Align­ ment, directly below. 3. Shift hood on hinges to location marks made before removal of hood, then tighten attaching cap screws at hinges firmly. Close hood and check fit. If necessary to align hood perform procedure as outlined under "Alignment" which follows. Alignment Fig. 7—Hood, Bum pers and Latch—G Series 1. Loosen hood hinge bolts. Note that rear bolt holes in hinge is slotted to allow hood trailing edge to move up and down. 2. Adjust hood bumpers so that hood and adjacent surfaces are flush. 3. Perform hood lock adjustment as outlined in this section if necessary. NOTE: Hood Lock Assembly to be adjusted fore and aft until nubble (part of Hood Lock Bolt Support Assembly) enters center of elongated guide (Socket). Bending nubble to accomplish this adjustment may seriously effect lock operation and safety catch engagem ent and is, therefore, NOT RECOMMENDED. LIGHT DUTY TRUCK SERVICE MANUAL C HASSIS SHEET METAL FRO NT SHEET M ETAL ASSEMBLY-CK SERIES Removal of entire front sheet metal assembly including radiator involves disassembly of mounts, disconnecting radiator hoses and removal of front bumper. Vehicles equipped with air conditioning and/or power steering will require special handling. Refer to appropriate sections of this manual for instructions. Shims which are found at various locations should be recorded to ease installation of sheet metal assembly. Refer to Figure 8 for sheet metal clearance. Removal 1. Drain radiator and remove radiator hoses. Discon­ nect oil cooler lines if so equipped. WARNING: If you siphon coolant from the radiator, do not use mouth to start siphoning action. The coolant solution is POISONOUS and can cause death or serious illness if swallowed. 2. Disconnect wire connectors at the dash HOOD ASS' HOOD ASSY FLUSH FENDER ASSY 11-5 and toe panel and wire connector to horn and voltage regulator. 3. Disconnect battery and generator wires. 4. Remove front bumper bolts and remove bumper. 5. Remove bolts attaching fender upper edge to cowl door frame. 6. Remove fan shroud. 7. W orking from underneath rear of fender, remove attachment from each fender at the hinge pillar. 8. Remove bolt from each radiator support mounting. 9. Remove bolts at each fender skirt to cab underbody (fig. 9). 10. With a helper, remove front sheet metal assembly, with radiator, battery, horn and voltage regulator attached. Installation 1. With a helper place sheet metal assembly in position. NOTE: Install all bolts loosely to facilitate aligning after complete installation. 2. Install fender bolts at cowl. HOOD ASSY FLU SH •FE N D ER ASSY -F E N D E R ASSY FENDER ASSY DOOR ASSY -FLUSH SE C T IO N E -E SECTIO N B -B SEC TIO N C -C I n o t e 1 Hood su r fa c e „ 06 belo w at S e c tio n C -C to flu sh at S e c tio n B -B and S e c tio n D -D . SE C T IO N D -D F E N D E R —^ f"" I \ __DOOR ASSY SECTION F-F^-l-OO ASSY I NOTE I Sh im fro n t fen d er to ob tain s u r fa c e flu s h n e s s sta r tin g at a poin t ap p rox l o00 fro m le a d in g ed ge of d o o r . (T y p ic a l e n tir e len g th of fen d er to d o o r). HOOD ASSY FEN D E R ASSY RA DIATO R GRILLE UPPER PANEL FLUSH ROCK ER PANEL SE C T IO N G -G I NOTE iSh im fro n t fen d er to ob tain s u r fa c e flu s h n e s s to r o c k e r p a n e l. SEC TIO N A -A Fig. 8 —Sheet Metal Clearance—CK Series LIGHT DUTY TRUCK SERVICE MANUAL 11-6 CHASSIS SHEET METAL 6. Install bolts at steering column skirt reinforcement, final torque 25 ft. lbs. 7. Tighten each radiator support mounting bolt 33 ft. lbs. 8. Torque bolts at fender to cowl 25 ft. lbs. 9. Install front bumper. 10. Connect wire connectors at dash and toe panel. Attach generator and regulator wires. 11. Connect upper and lower radiator hoses. Connect oil cooler lines to the radiator on models so equipped. 12. Connect battery and fill radiator. Start engine and check for leaks. Radiator Support Removal 3. Install combination bolt and flat washer assembly into each fender reinforcement while inserting shims required between fender reinforcement and body (See Figure 10). 4. Install two bolts and shims required at each fender rear lower edge to hinge pillar. 5. Install bolt in each fender skirt to underbody. 1. Remove hood as described in this section. 2. Drain radiator, saving coolant, loosen attachments and remove radiator and coolant recovery tank. 3. Disconnect and remove battery. 4. Remove battery tray with battery hanger. 5. Remove wiring from radiator support. 6. Disconnect fan shroud and lay back on engine. 7. Remove both head lamp assemblies. 8. Remove grille assembly. 9. Remove upper and lower radiator grille panels. (Fig. 11). 10. Remove screws securing front fenders to radiator support. 11. Remove screws securing fender skirts to radiator support bottom. (Fig. 9). 12. Remove bolt securing center grille support to radiator support. 13. Remove bolts securing hood catch assembly to radiator support. 14. Remove radiator support bolts secured to frame. 15. Tilt radiator support rearward and lift up and off. Installation Fig. 10—Front Fender Assem bly—CK Series 1. Rotate radiator support into position and loosely install attachments to frame. 2. Connect center grille support to radiator support. 3. Connect hood latch plate. 4. Connect radiator support brackets to fenders. 5. Connect support to fenders. 6. Connect screws from underside of fender skirts to support bottom. 7. Attach grille upper panel to fenders loosely. 8. Attach grille lower panel to fenders. LIGHT DUTY TRUCK SERVICE MANUAL CHASSIS SHEET METAL 9. Tighten radiator support bolts. 10. Place battery tray in position and fasten to radiator support. 11. Install radiator coolant recovery tank hoses and shroud. 12. Connect removed wiring to radiator support. 13. Install both head lamp assemblies. 14. Tighten all previously installed bolts and screws. 15. Install battery and connect leads and wires. 16. Install grille assembly. 17. Fill radiator with coolant as specified in Section 13. 18. Install hood on previously marked outline. F R O N T FENDER (FIG. 1 0) Removal 1. Remove hood and hinge assembly. 2. Remove head lamp bezel, wiring and attachments from fender. 11-7 3. Remove screws attaching upper and lower radiator grille panels. 4. Remove screws attaching fender wheel opening flange to skirt. 5. Remove skirt to fender bolts, located inboard on underside of skirt. 6. Remove two (2) screws attaching support bracket to fender. 7. Remove five (5) \ / screws attachingO radiator support 11 to front fender. 8. Remove bolt and shim attaching trailing edge of fender to hinge pillar. 9. Remove two bolts and shims at top rear of fender attaching to cowl. Installation To install, reverse the removal procedure using sealing tape between filler panel and fender. Check sheet metal alignment. Fig. 11—Radiator Upper and Lower Grille Panels—CK Series LIGHT DUTY TRUCK SERVICE MANUAL 1 1-8 CHASSIS SHEET METAL FR O N T FENDER AND S K IR T (FIG S. 9 AND 10) Removal 1. Remove hood and hood hinge assembly. 2. Disconnect and remove battery (right side or auxiliary left side). 3. Remove head lamp bezel, wiring and attachments from fender. 4. Remove screws attaching upper and lower radiator grille panels. 5. Remove screws attaching skirt to radiator support. 6. Remove two (2) top rear fender bolts and shims. 7. Remove bolt and shims at bottom of fender. 8. Remove bolt and shim(s) attaching skirt to underbody. 9. Remove two (2) screw attaching support bracket to fender. 10. Remove five (5) screws attaching radiator support to front fender. 11. Lift fender and skirt from truck. Installation Install front fender and skirt assembly in reverse order of removal. F R O N T FENDER S K IR T Refer to figure 9 for removal and installation of Front Fender Skirt. R U N N IN G BOARDS Refer to figure 12 for removal and installation of running boards. Front Sheet M etal Assem bly - G Series The front end sheet metal components not covered in this section are covered in the Body Section IB. SHEET M ETA L CHECK IN G Refer to the sheet metal checking illustration figure 13 for proper gaps and hood adjustments. Fender Skirt - P Series Refer to figure 14 for removal and installation of fender skirt, brackets, rear supports and hangers. W O O D G R A IN A PPLIQ U E IN S T A LL A TIO N PRO CEDURE General The wood grain applique (transfer film) is a vinyl material with a pressure sensitive adhesive backing. The Fig. 12—Running Boards—CK Series transfers are serviced in pre-cut panels. The transfers are designed with an appealing wood grain pattern and a 50 degree or semi-gloss finish. Preparation of the surface to which the transfer will be applied is very important. In cases where body metal repair has been made it is necessary to prime and color coat these areas to blend with the undamaged surface. Apply the transfer film to color coated panels only, never to bare metal or primer. The surface must be free of any imperfections that might high-light through the film. Remove dirt nibs and other foreign material in the paint by light sanding with 600 grit sandpaper. The temperature of the body must be m aintained at a moderate level between approximately 70 and 90 degrees. Too warm a body will cause the wood grain film to stick prematurely while too cool a body will reduce the adhesion of the wood grain film. Cool the body panel with cool water when too warm and heat the body panel with a heat gun or a heat lamp when too cold. Transfers should not be replaced in temperatures below 65 degrees Fahrenheit. The transfer should not be subjected to temperature greater than 175°F and should LIGHT DUTY TRUCK SERVICE MANUAL CHASSIS SHEET METAL transfer film may then be removed by lifting an edge and peeling the material from the painted surface. Exercise care so as not to damage the paint. Application of heat to the transfer and the panel by means of a heat gun or heat lamp will aid in the removal. COWL TO HOOD 3 /1 6 ± 1 /3 2 NOTE Hood su rfa ce flush to 1 /1 6 b e lo w c o w l v e n t g r ille a n d co n sta n t fro m <£_ to h o o d re a r corners. Installation FENDER TO COWL 1 /1 6 GAP (Ref) FENDER TO HOOD 3 /1 6 ± 1 /3 2 GAP NOTE Hood su rfa ce flu sh to 1 /1 6 b e lo w fe n d e r a t re a r c o rn e r a n d becom e flu sh a t fr o n t o f ho o d. NOTE Full ra n g e o f g a p to le ra n ce s do n o t a p p ly to a n y one g a p . C le a ran ce s to be h e ld u n ifo rm ly w ith in the ra n g e o f g o o d a s se m b ly pra ctice s. A p p e a ra n c e s d ic ta te th a t g a p cle a ra n ce s sh o u ld be p a ra lle l. Fig. 13-Front End Sheet Metal Checking—G Series not be left at or near this temperature for extended periods of time. Shelf life of the transfer material is 90 days at a temperature not to exceed 105°F. Removal 11-9 Remove the moldings from the affected panel. The 1. With a solvent dampened sponge, clean entire surface to be covered with applique. 2. Wipe area dry with a clean cloth. 3. Prior to application of transfer, wet down the complete transfer surface of the fender with a solution of 1/4 oz. of neutral detergent cleaner (must not contain oils, perfumes, or bleaches) per gallon of clear water. It is essential that no substitute for this solution be used and that the specified proportions be maintained. 4. While entire area is still wet with solution, remove paper backing from transfer and align upper edge with pierced holes in fender and press on lightly. 5. Start at center of transfer and squeeze outboard from middle to edges removing all air bubbles and wetting solution to assure a satisfactory bond. Use teflon-backed plastic squeegee only. 6. Notch applique at fender rear contour bend areas with scissors. Also notch out front marker lamp. 7. Fold ends of applique over fender flanges using squeegee. Heat the wrap-around area of applique with a heat lamp or gun to approximately 90CF and press with squeegee to secure entire edge surface. 8. If the wrap-around of the transfer has trouble sticking to fender edges, brush vinyl adhesive onto the fender or transfer area. Allow the adhesive to set for one minute then press transfer to fender for adhesion. 9. Inspect transfer installation from critical angle using adequate light reflection to detect any irregularities that may have developed during installation. Remove all air or moisture bubbles by piercing each at an acute angle with a fine pin or needle and by pressing the bubble down. 10. Install previously removed parts and clean up vehicle as required. LIGHT DUTY TRUCK SERVICE MANUAL 1 1 -1 0 CHASSIS SHEET METAL LIGHT DUTY TRUCK SERVICE MANUAL SECTION 12 ELECTRICAL—BODY AND CHASSIS C O N TE N TS OF T H IS SEC TIO N Lighting System................................................................................ Instruments and G auges............................................................... Directional Signals........................................................................... Windshield Wiper and W asher.................................................. 12-1 12-9 12-19 12-19 LIGHTING SYSTEM IN D EX General Description........................................................ ..12-1 Maintenance and Adjustm ents.................................... ..12-2 Headlamp Adjustm ent....................................................12-2 Component Part Replacement..................................... ..12-2 Sealed Beam Unit Replacem ent.................................12-2 Parking Lamp Bulb....................................................... ..12-3 Parking Lamp Housing..................................................12-3 Front Side Marker Lamp Bulb and/or Housing. 12-3 Rear Side Marker Lamp Bulb and/or Housing.. 124 Tail, Stop and Backup Lamp Bulbs........................ ..12-4 Tail, Stop and Backup Lamp Housing.....................12-4 Directional Signal Lam ps..............................................12-4 Clearance and Identification Lam ps........................ ..12-4 Light Switch........................................................................12-4 Dimmer Switch................................................................ ..12-7 Stoplamp Switch.............................................................. ..12-7 Neutral Start Sw itch........................................................12-7 Backing Lamp Switch................................................... ..12-9 Windshield W iper/W asher Switch........................... ..12-9 GENERAL DESCRIPTION The lighting system includes the main light switch; stop light, dimmer and backing lamp switches; head and parking lamps; stop, tail, side marker, clearance and identification lamps; instrument illumination, directional signal and indicator lamps and the necessary wiring to complete the various circuits. A bulkhead fuse panel (fig. 1) provides convenient power TR AFFIC H A Z A R D FLASHER (a )FUSE-HEATER & IG N A C C [A )FU S E - H E A T E R /A IR C O N D . [ b] r e c e p t a c l e - h e a t e r [C ]R E C E P T A C L E -IG N A C C [B ] FUSE - A C C E S S O R Y [C ] RECEPTACLE - C 6 9 [D ]R E C E P T A C L E -R A D IO U 6 3 [D ) RECEPTACLE - N L 2 / T P 2 / U 1 6 [E ]F U S E -IN S T p n l l a m p s [E jF U S E - P A N E L LIGHTS ( T jR E C E P T A C L E - INST PNL LA M P S Q D r ECEPTACLE -A C C E S S O R Y LA M P S [G ]F U S E -B /U LA M P S , R A D IO U 6 3 [G lR E C E P TA C LE - ( N O T USED) 0 F U S E -C L U S T E R FEED [H ] FUSE - CLUSTER FEED Q ]O U T L E T -D IR SIG FLASHER (T jF U S E - B / U L A M P S [K ] FUSE-IDLE S T O P J C S [ k ]FUSE - W /S H IE L D W IPER [ H F U S E -W /S H IE L D W IPER [□ F U S E - R A D IO & TCS [M] R E C E P T A C L E -W /S H IE L D W IPER [M lR EC EP TAC LE - A 3 3 / M 4 9 [N ] R E C E PTA C LE -TC S E V IE W FU SE -TA IL, PARK, STO P, D O M E 0 [Q ]FU S E -TR A FFIC H A Z A R D (N)FUSE - TR AFFIC H A Z A R D (PjF U SE - T A IL ,S T O P , C T S Y LA M P S [R ]R E C E P TA C LE - C 8 0 / U F 2 / U 3 5 / U 3 7 [R ]O U T L E T -TR A F F IC H A Z A R D FLASHER 0D R E C E P T A C L E -C IG LIGHTER FLASHER C-K SERIES G SERIES Fig. 1--Fuse Panel LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -2 ELECTRICAL - BODY A ND CHASSIS taps and fuse clips for the appropriate circuits. The engine wiring harness and forward lamp harness connectors are bolted to the fuse panel. All wiring systems not protected by a fuse or circuit breaker incorporate a fusible link which provides increased overload protection. The starting motor circuit is the exception. Composite wiring diagrams are included in a separate manual which was supplied with this manual. The standardized color code is common to all wiring harnesses. The wire covering color designates a particular circuit usage. MAINTENANCE AND ADJUSTMENTS M aintenance of the lighting units and wiring system consists of an occasional check to see that all wiring connections are tight and clean, that the lighting units are securely mounted to provide good ground and that the headlamps are properly adjusted. Loose or corroded connections may cause a discharged battery, difficult starting, dim lights, and possible damage to the A.C. generator. Wire harnesses must be replaced if insulation becomes burned, cracked, or deteriorated. Whenever it is necessary to splice a wire or repair one that is broken, always use solder to bond the splice. Always use rosin flux solder on electrical connections. Use insulating tape to cover all splices or bare wires. When replacing wires, it is important that the correct size be used. Never replace a wire with one of a smaller size. Fusible links in the wiring are four gauge sizes smaller than the cable it is designed to protect. The links are marked on the insulation with wire gauge size because of the heavy insulation which makes the link appear a heavier gauge than it actually is. Each harness and wire must be held securely in place by clips or other holding devices to prevent chafing or wearing away the insulation due to vibration. By referring to the wiring diagram manual, circuits may be tested for continuous circuit or shorts with a conventional test lamp or low reading volt meter. whenever a sealed beam unit is replaced and after repairs of the front end sheet metal assembly. Regardless of the method used for checking headlamp aim, the truck must be at normal weight, that is with gas, oil, water and spare tire. Tires must be inflated to specified pressures. Some states have special requirements for headlamp aiming adjustment and these requirements must be known and followed. Horizontal and vertical aiming of each sealed beam is provided by two adjusting screws visible through the bezel which move the mounting ring against the tension of the coil spring (fig. 2). There is no adjustment for focus since the sealed beam unit is set for focus during manufacturing assembly. H E A D LA M P A D J U S T M E N T (Fig. 2) The headlamps must be properly aimed to obtain maximum road illumination. The headlamps must be checked for proper aim COMPONENT PART REPLACEMENT SEALED BEAM U N IT Replacement (Figs. 3 and 4) l. Remove bezel retaining screws and bezel. 2 . Disengage spring from retaining ring. 3. Turn headlamp unit to disengage assembly from headlamp adjusting screws. 4. Disconnect wiring harness connector located at rear of unit in engine compartment. NOTE: Do not disturb adjusting screw setting. 5. Remove retaining ring and headlam p from mounting ring. 6. Position new sealed beam unit in mounting ring and install retaining ring. NOTE: The number molded into lens face must be at top. 7. Attach wiring harness connector to unit. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND CHASSIS 8. Install headlamp assembly in panel opening, twisting slightly to engage mounting ring tabs with adjusting screws. 9. Install retaining ring spring then check operation of unit and install bezel. P A R K IN G LAM P BULB Replacement (Figs. 3 and 4) 1. Remove lens retaining screws and remove lens from the housing. 2. Replace the bulb and check lamp operation. 3. Install lens and retaining screws. PA R K IN G LAM P H O U S IN G C-K Models 12-3 4. Remove the housing stud nuts and remove the housing and pigtail assembly. 5. Place the new parking lamp housing in position and install the retaining nuts. 6. Connect the wiring harness at the connector. 7. Install the bulb. Install the lens and attaching screws. FRO NT SIDE M A R K E R LA M P BULB A N D /O R H O U S IN G Replacement (Fig. 3) 1. Remove parking lamp lens screws and remove the lens. 2. Remove the lamp housing retaining screws and pull the housing forward. 3. Disconnect the parking lamp wiring harness from the housing by rotating the bulb socket counterclockwise. 4. Connect the wiring harness to the new housing by inserting the bulb socket into the housing and rotating clockwise. 5. Install the bulb if removed during disassembly. Install the lens and retaining screws. G M odels Replacement (Fig. 4) 1. Remove the parking lamp lens screws and remove the lens. 2. Remove the bulb. 3. Disconnect the wiring harness at the harness connector (does not separate at the housing). All Models Replacement 1. 2. 3. 4. 5. NOTE: For housing replacement follow procedure for the right side bulb replacement below. Left Side - Raise hood. Right Side - Remove lamp assembly retaining screws and pull outward on assembly. Twist wiring harness socket 90° counterclockwise and remove harness and bulb from housing. Replace bulb and check lamp operation. Insert bulb into housing, press in on harness socket and twist 90° clockwise. Check that socket is securely attached. Left Side - Lower hood. Right Side - Install housing in opening and install retaining screws. LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -4 ELECTRICAL - BODY AND CHASSIS Fig. 5 -Rear Lighting (G Models) REAR SIDE M A R K ER LAM P BULB A N D /O R H O U S IN G TA IL, STO P AND BAC KUP LA M P H O U S IN G C-K 0 3 M odels with E62 and G Models All G M odels Replacement Replacement Same as Right Front Side Marker Lamp Bulb and/or Housing Replacement - All Vehicles. NOTE: Bulb on G Models without interior trim may be removed from inside the vehicle. C-K 14, 0 3 and 6 3 with E63, and 0 6 M odels Replacement 1. Remove lens to housing four screws. 2. Replace bulb and check operation. 3. Position lens and install four attaching screws. P latform and Stake Rack Models (E 5 6) Exploded views of the different rear lighting arrange­ ments are shown in Figures 7 and 8. The bulbs may be replaced by removing the lamp lens attaching screws and lamp lens. The lamp housings may be replaced by removing the housing attaching nuts or screws, or by removing the nuts and bolts from the bracket. TA IL, STO P AND BACKUP LAM P BULBS Replacement 1. Remove lens to housing attaching screws. 2. Replace bulb and check operation. 3. Position lens and install attaching screws. C-K 14, 0 3 and 6 3 w /E 6 3 and 0 6 Models 1. Remove lens to housing attaching screws. 2. Remove bulbs from sockets. 3. Remove housing attaching screws (nuts on G Models). 4. Rotate wiring harness sockets counterclockwise and remove housing. 5. To install, reverse Steps 1-4 above. D IR E C TIO N A L S IG N A L LAM PS Directional signal lamps are an integral part of parking and tail lamp assemblies. Refer to the applicable lamp or bulb replacement procedures covered previously. CLEARANCE LICENSE PLATE AND ID E N T IF IC A T IO N LAM PS Refer to Figures 7 through 10 for clearance and identification lamp installations. LIG H T S W ITC H C-K M odels (Fig. 11) Replacement 1. Disconnect the battery ground cable. 2. Reaching up behind instrument cluster, depress shaft retaining button and remove switch knob and rod. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A ND CHASSIS 12-5 LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -6 ELECTRICAL - BODY A ND CHASSIS LICENSE PLATE LAMP WIRE — FRONT MARKER LAMP HARNESS | view |A FRONT WIRE ASSEMBLY TAIL & STOP ~ LAMP ASSEMBLY REAR LICENSE ^ LAMP ASSEMBLY •TAIL & STOP LAMP HARNESS CENTER MARKER -X LA M P S WIRE SIDE MARKER LAMP \ SIDE MARKER LAMP VIEW C 2 0 9 ( 0 3 ) W IT H O P T IO N E 5 6 C 3 1 0 ( 0 3 ) W IT H O P T IO N E 5 6 Fig. 7-Rear Lighting (C-K Platform and Stake Rack Models) Fig. 8-Rear Lighting (C30 03 Models with E56 and C-K Models with E62) 3. Remove instrument cluster bezel screws on left end. Pull out on bezel and hold switch nut with a wrench. 4. Disconnect multiple wiring connectors at switch terminals. 5. Remove switch by rotating while holding switch nut. 6. To install, reverse Steps l-5 above. G Models (Fig. 11) Replacement 1. Disconnect battery ground cable. 2. Reaching up behind instrument panel, depress shaft retaining button and remove switch knobshaft. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 12-7 Fig. 9-Clearance Lamps 3. From front of instrument panel remove switch retaining nut. 4. Push switch from panel opening and remove multiple electrical connector at switch terminals. 5. To install, reverse Steps 1-4, making sure grounding ring is installed on switch. D IM M E R SW ITCH Replacement 1. Fold back upper left corner of the floor mat and remove two screws retaining switch to the floor pan. 2. Disconnect wiring connector from switch terminals. 3. Connect wiring to replacement switch and check operation. 4. Position switch to floor pan and install retaining screws. 5. Replace floor mat. S TO P LA M P S W ITC H See Section 5 (Brakes) of this manual for adjustment and replacement procedures. N E U T R A L S TA R T S W ITC H C-K M odels (Fig. 12) Replacement and Adjustment 1. 2. 3. 4. 5. Disconnect battery ground strap. Disconnect electrical harness at switch. Remove switch mounting screws and remove switch. Position shift lever in neutral gate notch. Insert .096" gauge pin to a depth of 3/8 inch into switch gauge hole. Switch assembly is fixed in neutral position with internal plastic shear pin. 6. Assemble the switch to column by inserting the 7. 8. 9. 10. 11. 12. switch carrier tang in the shift tube slot and fasten in position by assembling mounting screws to retainers. NOTE: If retainer strips out it must be replaced. Remove .096" gauge pin. Move shift lever out of neutral gate notch to park gate position to shear switch internal plastic pin. Return shift lever to neutral gate notch. Switch gauge hole will freely admit .089" gauge pin to a depth of 3/8 inch. If pin will not freely enter gauge hole, switch must be reset as below. Connect battery ground cable and electrical harness. R eset Installation Procedure 1. Place shift lever in neutral gate notch. 2. Loosen attaching screws. 3. Rotate switch on column and insert .096" gauge pin to depth of 3/8 inch. 4. Tighten attaching screws. 5. Repeat installation procedure Steps 7 through 12 above. G-P Models Replacement (Fig. 12) 1. 2. 3. 4. 5. Raise vehicle on a hoist. Disconnect the switch harness from the switch. Remove switch mounting bolts and remove switch. Assemble new switch to mounting bracket. Align .093/.097 hole in Lever (B) with hole in Switch Assembly. Insert Pin (A) to hold in NEUTRAL position. LIGHT DUTY TRUCK SERVICE MANUAL 12-8 ELECTRICAL - BODY A ND CHASSIS Fig. 11-Light and Dimmer Switches CONTROL BRACKET .098 DIA. GAUGE PIN * SWITCH LEVER NEUTRAL SAFETY SWITCH I .0 9 3 /0 9 7 HOLE TRANS. LEVER C GAUGE PIN 093 / .097 HOLE REF) STEERING CO LUM N C-K MO DELS ' adjusting pin a G M ODELS SWITCH LEVER B 0 'TRANS. LEVER C P M O DELS Fig. 12-Neutral Start Switch Replacement - Typical 6. Set Transmission Lever (C) in NEUTRAL position by the following method. NOTE: O btain NEUTRAL by moving Transmission Lever counterclockwise to LI detent, then clockwise three detents to the NEUTRAL detent position. 7. Install Swivel onto Rod and adjust to allow free LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS entry on Rod into Transmission Lever and Switch Lever. Secure with Clip. 8. Lower vehicle from hoist and carefully check switch operation. BAC KING LAM P S W ITC H See "Neutral Start Switch" for automatic transmission models. 12-9 Transmission M ounted Switch Replacement 1. 2. 3. 4. Raise vehicle on a hoist. Disconnect switch wiring harness. Remove switch from transmission. To install a new switch, reverse Steps 1-3 above. Colum n M ounted Switch W IN D S H IE LD W A S H E R /W IP E R S W ITC H Replacement C-K M odels 1. Disconnect battery ground cable. 2. Disconnect switch wiring harness. 3. Remove switch to column mounting screws and remove switch. NOTE: A new switch is fixed in reverse position with an internal plastic shear pin. 4. Position column in "lock position". 5. Assemble the switch to the column by inserting the switch carrier tang in the shift tube slot. Fasten in position by installing mounting screws. NOTE: Switch internal plastic pin will shear when the column is "unlocked" and shift bowl is moved out of reverse position. 6. Install battery ground cable. R eset Installation Procedure 1. Position column in "lock" position. 2. Loosen switch attaching screws. 3. Rotate switch on column until gauge hole (in back of switch) freely admits a .089" gauge pin to a depth of 3/8". 4. Tighten switch screws and remove gauge pin. Replacement 1. Disconnect the battery ground cable. 2. Remove the instrument panel bezel screws and remove the bezel. 3. Remove the switch attaching screws. 4. Pull out on switch assembly and disconnect electrical harness - remove switch. 5. To install, reverse Steps 1-4 above. Check switch operation before reinstalling instrument panel bezel. G Models Replacement 1. Disconnect battery ground cable. 2. Reach up behind left side of instrument panel, and: a. Remove plug connector from rear of switch. b. Remove (3) mounting screws securing bezel and ground wires to switch. 3. Replace switch, installing ground wire and connec­ tor. Check operation of switch, first observing washer solvent level. INSTRUMENTS AND GAUGES IN D E X General D escription........................................................ Component Part Replacem ent..................................... Ignition Switch................................................................. Instrument Cluster.......................................................... Indicator and Illuminating Bulb............................... Laminated Circuit.......................................................... Speedom eter..................................................................... 12-9 12-10 12-10 12-10 12-12 12-12 12-12 Speedometer C able.........................................................12-13 Fuel G auge....................................................................... 12-13 Temperature Gauge....................................................... 12-13 Temperature Sending U nit..........................................12-14 Oil Pressure G auge.......................................................12-14 Oil Pressure Sending U n it..........................................12-14 Ammeter G auge..............................................................12-14 GENERAL DESCRIPTION All instruments and gauges are installed in the instrument cluster. Instruments and gauges can be serviced in the vehicle (C-K Models); however, the entire cluster must be removed from the vehicle for servicing LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -1 0 ELECTRICAL - BODY A ND CHASSIS of the instruments and gauges (G Models). Illuminating and indicator lamps may be replaced without removing the cluster from the vehicle. Bulbs are installed in plastic holders which lock into the cluster housing. Regular maintenance is not required on the instrument cluster or its components other than maintaining clean, tight electrical connections, replacing defective parts and keeping the speedometer cable properly lubricated. COMPONENT PART REPLACEMENT IG N IT IO N SW ITCH IN S T R U M E N T CLUSTER C-K Models C-K M odels See Section 9 - Steering, for ignition switch replacement procedure. Replacement (Fig. 14) G Models Replacement (Fig. 13) 1. Disconnect ground cable from battery. 2. Remove lock cylinder by positioning switch in "ACC" position and inserting stiff wire in small hole in cylinder face. Push in on wire to depress plunger and continue to turn key counterclockwise until lock cylinder can be removed. 3. Remove the metallic ignition switch nut. 4. Pull the ignition switch out from behind the instrument panel and remove the "theft resistant" connector. Use a screwdriver to unsnap the locking tangs on the connector from their position on the switch. 5. Snap the connector into place on a new ignition switch. 6. Place the switch into position from behind the instrument panel, first adding grounding ring then install the ignition switch nut. 7. Install the lock cylinder, key inserted. 8. Install ground cable on battery. 1. Disconnect the battery ground cable. 2. Remove the instrument cluster bezel and steering column cover screws and remove the bezel and cover. 3. Remove the clock knob (if so equipped). 4. Remove the lens retaining screws and remove the lens. 5. Remove the transmission PRNDL indicator retain­ ing screws and remove the indicator. Remove the cluster retainer. 6. Reach up under the dash and disconnect the speedometer cable by depressing spring clip and pulling cable out of speedometer head. Disconnect oil pressure line (if so equipped). 7. Disconnect cluster wiring harness. 8. Remove cluster retaining screws and remove cluster. 9. Remove cluster assembly to workbench for further disassembly as required. 10. To install, reverse Steps 1-8 above. G M odels Replacement (Fig. 15) 1. Disconnect ground cable from battery. 2. Reach up under instrument cluster and disconnect speedometer cable by first depressing tang on rear of speedometer head, then pulling cable free from head as tang is depressed. 3. Unplug instrument panel harness connector from printed circuit. 4. Disconnect oil pressure line from gauge if so equipped. 5. Remove (2) two nuts attaching instrument cluster studs to lower opening in instrument panel. 6. Pull top of cluster away from instrument panel and lift out bottom of cluster. 7. Remove cluster to bench for further disassembly (lam inated printed circuit, speedom eter head, gauges). 8. Install cluster in reverse order of removal, noting that clips at top of cluster slip into instrument panel opening after bottom of cluster is installed. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A ND CHASSIS 12-11 Fig. 1 4 -In stru m e n t Cluster Assembly (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 1 2 ELECTRICAL - BODY AND CHASSIS Fig. 15 -Instrument Cluster Assembly (G Models) IN D IC A T O R A N D IL L U M IN A T IN G BULBS All Models Replacement (Figs. 14 and 15) 1. Reach up under instrument panel and turn bulb holder counterclockwise to remove from the cluster housing. 2. Pull bulb straight out to remove from holder. 3. Install replacement bulb in holder, press inward to lock in place. 4. Insert holder into housing, with lugs on holder entering notches in case, and turn clockwise to lock holder against printed circuit. L A M IN A T E D C IR C U IT - A II Models Replacement 1. Remove instrument cluster assembly as previously described in this section. 2. Remove all instrum ent cluster lamp bulb assemblies. 3. Remove laminated circuit retaining screws. NOTE: These screws serve as a ground for the circuit and must be reinstalled to provide the proper ground. 4. G Models - Remove fuel, temperature and ammeter terminal nuts retaining laminated circuit to rear of cluster. 5. Lift laminated circuit from cluster cover. 6. To install, reverse Steps 1-5 and check electrical operation of all affected components. SPEEDO M ETER NOTE: Servicing of the speedometer assem­ bly should only be performed by trained technicians having the proper test equipment. C-K Models Replacement 1. Disconnect the battery ground cable. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 2. Reach up under the dash and disconnect the speedometer cable by depressing the spring clip and pulling the cable out of the speedometer head. 3. Remove the instrument cluster bezel and steering column cover. 4. Remove the instrument cluster lens. 5. Remove the transmission PRNDL indicator and remove the cluster retainer. 6. Remove the speedometer to cluster screws and remove the speedometer assembly. 7. To install, reverse Steps 1-6 above. Check speedometer operation. CAUTION: Use care to prevent kinking the speedometer cable during removal and installation. G Models Replacement 1. Remove instrument cluster as previously described in this section. 2. Remove (4) screws retaining cluster rear cover containing speedometer. 3. Remove (2) hex head screws and rubber grommets securing speedometer assembly to cluster cover. 4. To install, reverse removal procedure and check operation of speedometer assembly. CAUTION: Use care to prevent kinking the speedometer cable during removal and installation. 1 2-13 FUEL G AUG E C-K Models Replacement* 1. Perform Steps 1-5 of "Instrument Cluster Replacement". 2. Remove the fuel gauge attaching screws and remove the gauge. 3. To install, reverse Steps 1-2 above. Check gauge operation. G Models Replacement 1. Remove instrument cluster assembly as previously described. 2. Remove instrument cluster bulb holders, ground screws, nuts and washers retaining laminated circuit to fuel gauge rear cover. 3. Remove (3) screws retaining fuel gauge rear cluster cover. 4. Lift gauge away from laminated circuit and rear cluster cover. 5. To install, reverse Steps 1-4 and check operation of fuel gauge. NOTE: Mount insulator strip on fuel gauge studs first, then resistor, then a nut on each stud, next the laminated circuit, then a plain washer on each of two studs holding laminated circuit and finally a nut on back of the studs that have a washer and laminated circuit. TE M P E R A T U R E G AUG E C-K M odels SPEEDO M ETER CABLE CORE All Vehicles Replacement 1. Disconnect the battery ground cable. 2. Disconnect the speedometer cable from the speedometer head by reaching up under the instrument panel, depressing the spring clip and pulling the cable from the head. 3. Remove old core by pulling it out at the end of the speedometer cable casing. NOTE: If old cable core is broken it will be necessary to remove the lower piece from the transmission end of the casing. 4. Lubricate the entire length of cable core with speedometer cable lubricant. 5. To install, reverse Steps 1-3 above. CAUTION: Use care to prevent kinking the speedometer cable core during installation. Replacement 1. Perform Steps 1-5 of "Instrument Cluster Replacement". 2. Remove the temperature gauge attaching screws and remove the gauge. 3. To install, reverse Steps 1 and 2 above and check gauge operation. NOTE: Be sure gauge studs engage clips holding laminated circuit to back of cluster housing. G Models Replacement 1. Remove instrument cluster assembly as previously described in this section. 2. Remove terminal nuts retaining laminated circuit to gauge unit. 3. Remove attaching screws, cover and gauge assembly from cluster housing. 4. Remove terminal attaching nuts and gauge unit from cover plate. LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 1 4 ELECTRICAL - BODY AND CHASSIS 5. To install, reverse removal procedure and check operation of gauge. T E M P E R A TU R E S EN D IN G U N IT All Models Replacement Do not remove cap with engine hot, allow vehicle to cool off first. WARNING: 1. Relieve cooling system pressure by loosening radiator cap to first stop. Tighten cap after pressure is relieved. 2. Disconnect the sending unit wiring harness. 3. Remove the sending unit from the engine. 4. Install the new sending unit and connect the electrical harness. 5. Check coolant level and unit operation. NOTE: Coolant must have at least 0°F. freeze protection for sending unit to function properly. OIL PRESSURE G AUG E C-K Models Replacement 1. Perform Steps 1-5 of Instrument Cluster - Replacement" procedure. 2. Reach up under the instrument panel and place a cloth under the line to gauge connection. Remove the line to gauge nut. 3. Remove the gauge to cluster attaching screws and remove the gauge. 4. To install, reverse Steps 1-3 above and check gauge operation. G Models Replacement 1. Remove instrument cluster as previously described in this section. NOTE: Oil pressure line connection may leak oil when opened; wrap with cloth. 2. Remove bulb holders, grounding screws and lift laminated circuit aside as necessary. 3. Remove instrument cluster cover to separate oil pressure gauge from cluster. 4. Remove pipe fitting and retaining nut from gauge being replaced then remove gauge from cluster DO NOT KINK PIPE. 5. To install replacement oil pressure gauge, reverse Steps 1-4, then observe operation of guage. OIL PRESSURE S EN D IN G U N IT All Models Replacement 1. Disconnect wiring harness connector from sending unit terminal located in block above starter on L-6 engines, at left front of distributor on V-8 (except 454 V-8) or rear left side of block (454 V-8) engines. 2. Remove sending unit using Tool J-21757. Replace with new unit and check operation. A M M E T E R G AUG E C-K Models Replacement NOTE: First check two in-line fuses at front of engine compartment. 1. Perform Steps 1-5 of "Instrument Cluster Replacement" procedure. 2. Remove the gauge to instrument panel screws and remove the gauge. 3. To install, reverse Steps 1 and 2 above and check gauge operation. NOTE: Be sure gauge studs engage clips holding printed circuit to back of cluster housing. G M odels Replacement 1. 2. 3. 4. 5. 6. NOTE: First check two in-line fuses at front of engine compartment. Remove instrument cluster assembly as previously described in this section Remove terminal nuts retaining laminated circuit to ammeter. Lay back laminated circuit portion after removing grounding screws and bulb holders. Remove attaching screws, cover and ammeter from cluster housing. Remove terminal attaching nuts and ammeter from cover plate. To install, reverse Steps 1-5 and check operation of ammeter. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND CHASSIS 12-15 DIRECTIONAL SIGNAL SWITCH The directional signal switch is a self-contained unit which incorporates the hazard warning switch and the lane changing signal. The hazard warning circuit is activated by a push-pull switch which is located on the right side of the steering column, opposite the directional signal lever. The switch knob must be pulled to cancel circuit. The lane changing circuit is activated by holding the directional signal lever in the first detent position; there is no lock in or cancelling device in this position. See Section 9 "Steering" for all servicing procedures. W INDSHIELD WIPER AND WASHER C-K-G MODELS IN D E X General Description........................................................ ..12-15 Theory of Operation....................................................... ..12-16 Service Operations..............................................................12-19 Wiper M otor......................................................................12-19 Replacem ent.....................................................................12-19 W iper/W asher Disassembly..................................... ..12-20 Motor Disassembly........................................................ ..12-21 Motor Assembly............................................................. 12-23 Adjustments......................................................................12-24 Windshield W asher Pump Assembly......................12-24 Diagnosis.............................................................................12-25 Wiper On Vehicle..........................................................12-25 Wiper Off V ehicle.........................................................12-26 Washer System ............................................................... 12-32 GENERAL DESCRIPTION The wiper motor assembly consists of compound wound 12 volt D.C. motor, gear reduction mechanism and parking switch enclosed in a common die cast housing. The armature has a worm shaft which drives a gear and shaft assembly. A crank arm, which is attached externally to the gear shaft, operates the linkage which activates the blades. The wiper motor is equipped with an internal circuit breaker mounted on the motor brush plate which protects the motor from overheating. Figure 16 shows the assembly of the washer pump to the wiper motor. F ig . 16— W asher M e ch a n ism M o u n tin g o n W ip e r LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 1 6 ELECTRICAL - BODY AND CHASSIS THEORY OF OPERATION ELECTRICAL C IR C U IT S The following facts should be kept in mind throughout the following explanation. 1. The wiper dash switch is a grounding type switch, and therefore must be securely mounted. 2. When installed in a vehicle, the wiper motor is connected to the chassis through a ground strap. This in effect connects the wiper housing to the ground side of the battery. 3. The ignition switch opens and closes the feed wire circuit to the wiper. Therefore, it must be turned ON to operate wipers. The wiper motor operation is controlled by two switches—a dash control switch and a parking switch located in the wiper motor gear box. The parking switch contacts are normally closed and are opened by a cam on the gear when the wiper blades PARK S W ITC H (C O N T A C T S O P EN E D BY C A M ) CAM Fig. 17—Gear in PARK Position—Contacts Open 12 VOLTS SWITCH BLACK WITH PINK STRIPE IGNITION SWITCH FUSE , ^ SPLICE CIRCUIT BREAKER WIPER TERMINAL BOARD RESISTOR 20 OHMS rim S& S& M SXsfz BLACK S P L IC E X ' MOTOR (LO SPEED C IR C U IT ) SERIES FIELD SHUNT FIELD LEGEND POWER CIRCUIT TO SERIES FIELD SERIES FIELD AND ARMATURE CIRCUIT SHUNT FIELD CIRCUIT Fig. 1 8 -LO Speed C ircuit LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 1 2-17 Fig. 19—HI Speed Circuit reach the park position. The park switch acts as a holding switch to maintain the motor circuits to ground during that period of operation between the time the operator turns the wiper off at the dash switch and the blades reach the park position. Figure 17 shows the park switch contacts open. " L o " Speed Operation W hen the operator turns the wiper dash switch to the "LO " speed position, the wiper motor circuits are completed to ground at the dash switch as follows: (Refer to Figure 18). Current flows from thj battery through the ignition switch to the center terminal of the wiper terminal board. From the center terminal, current then passes through the black with pink stripe lead to the series field coils (Larger diameter wire) where it divides and flows as follows: 1. The shunt field coils to wiper terminal No. 3 through the wiring harness to the dash switch to ground. 2. The series field-armature circuit is completed via wiper terminal No. 1 through the wiring harness to the dash switch to ground. " H I" Speed O peration Turning the wiper dash switch to the "H I" or fast speed position changes the shunt field coil circuit as follows: (Refer to Figure 19). With the dash switch in the HI speed position, the shunt field coil current passes through a 20 ohm resistor on the back of the wiper terminal board to terminal No. 1 and then via the wiring harness to the dash switch to ground. The armature and series field circuit is also completed via the wiring harness from wiper terminal No. 1 to the dash switch to ground. Turning the W iper "O F F " Turning the wiper dash switch to the OFF position opens the wiper circuits to ground at the dash switch. If, however, the wiper blades are in any position other than the normal park or off position, the wiper motor circuits are completed to ground by the wiper motor park switch as follows: (Refer to Figure 20). 1. The series field-armature circuit is completed to ground via the parking switch to the wiper housing to chassis of vehicle. 2. The shunt field coil circuit is completed to ground LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -1 8 ELECTRICAL - BODY AND CHASSIS FUSE WIPER TERMINAL BOARD SERIES FIELD -SHUNT FIELD (PARKING C IR C U IT ) LEGEND POWER CIRCUIT TO SERIES FIELD SERIES FIELD AND ARMATURE CIRCUIT SHUNT FIELD CIRCUIT Fig. 20-PARKING Circuit via wiper terminal No. 3 through the wiring harness to the dash wiring harness to wiper terminal No. 1, through the parking switch to ground. IMPORTANT: Note that the shunt field circuit during the parking operation bypasses the resistor causing the wiper to operate in LO Speed. Failure of the wiper to operate in LO Speed during parking results in the wiper failing to shut off. With the wiper motor circuits completed to ground via the parking switch, the wiper motor continues to operate until the wiper gear cam opens the park switch contacts (Figure 17) stopping the wiper. See Figure 21 for W iper OFF Circuit. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D C HASSIS 1 2-19 BATTERY DASH SWITCH BLACK WITH PINK STRIPE IGNITION SWITCH FUSE WIPER TERMINAL BOARD SPLICE RCUIT BREAKER RESISTOR 20 OHMS BLACK SPLICE MOTOR SERIES f i e l d ; 's h u n t f i e l d , (WIPER O FF ) LEGEND POWER CIRCUIT TO SERIES FIELD SERIES FIELD AND ARMATURE CIRCUIT SHUNT FIELD CIRCUIT Fig. 21-OFF Circuit SERVICE OPERATIONS W IP E R M O TO R G Models Replacement (Fig. 23) C-K Models 1. Make sure wiper motor is in Park position. Replacement (Fig. 22) 1. Make sure wiper motor is in Park position. 2. Open hood and disconnect ground cable from battery. 3. Disconnect electrical harness at wiper motor and hoses at washer pump. 4. Reach down through access hole in plenum and loosen wiper drive rod attaching screws. Remove drive rod from wiper motor crank arm. 5. Remove wiper motor to dash panel attaching screws and remove the motor assembly. 6. To install, reverse Steps 1-5 above. NOTE: Lubricate the wiper motor crank arm pivot prior to reinstallation. Fig. 22-Wiper Motor (C-K Models) LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 2 0 ELECTRICAL - BODY AND CHASSIS Fig. 23-Wiper Motor (G Models) 2. Open hood and disconnect ground cable from battery. 3. Remove wiper arms from wiper transmission linkage. 4. Remove remaining screws securing cowl panel cover and lift off. 5. Loosen nuts holding transmission linkage to wiper motor crank arm and lift linkage off arm. 6. Disconnect power feed to wiper motor at multiple connector. 7. Remove left dash defroster outlet from flex hose and push hose aside for access to wiper motor screws. 8. Remove one screw securing left hand heater duct to engine cover shroud and slip heater duct down and out. 9. Protect carpet, then remove windshield washer hoses from washer pump. 10. Remove three screws securing wiper motor to cowl and lift wiper motor out from under dash for further disassembly on bench. 11. To install, reverse Steps 1-10 above. NOTE: Install wiper in the PARK position. Lube wiper motor crank arm pivot prior to installation. W IP E R /W A S H E R DISASSEM BLY Park Switch (Fig. 2 4 ) 1. 2. 3. 4. Remove washer pump (fig. 16). Remove screw retaining park switch. Remove spacer. Unsolder lead. Term inal Board (Fig. 2 4 ) 1. Remove washer pump. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 12-21 PARK SWITCH MOUNTING SCREW SPACER PARK SWITCH ASSEMBLY Fig. 24-PARK Switch Removal Fig. 25-Crank Arm in PARK Position 2. Remove spacer. 3. Unsolder leads. G ear Assem bly 1. Remove washer pump. 2. Remove park switch (See park switch removal). Unsolder lead only if required. 3. Clamp crank arm in vise and loosen crank arm retaining nut. Remove nut and crank arm (fig. 25). 4. Remove seal cap and using No. 22 External Snap Ring Pliers, remove the "C " retaining ring (fig. 26). Next, remove washer, end play washers, and outer spacer (fig. 27). 5. Slide the gear assembly out of the housing and remove the inner spacer washer (fig. 28). 6. To reassemble the gear box, reverse the disassembly procedure. ARMATURE END PLAY ADJUSTING SCREW AND LOCKNUT Crank Arm Assembly 1. Operate wiper gear to park position (fig. 25). 2. Position crank arm on gear shaft flats according to position shown in Figure 25. 3. Install crank arm retaining nut finger tight, then clamp crank arm in vise and tighten retaining nut securely. M O T O R DISASSEMBLY NOTE: Motor section may be disassembled independently of the gear box. Brush P late and Circuit Breaker Fig. 26~"C" Ring Removal and end cap to insure proper reassembly. 2. Remove the two motor through bolts. 3. Feed exposed excess length of motor leads through the casting grommet and carefully back the case and field assembly plus the armature away from the casting (fig. 29). Removal 1. Scribe a reference line along the side of the casting NOTE: It may be necessary to remove the LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -2 2 ELECTRICAL - BODY AND CHASSIS SPACER INNER SPACER WASHER SHIM (AS REQUIRED) Fig. 28 -Drive Gear Removal FLAT WASHER CRANK ARM . SNAP RING SEAL \ Fig. 2 7 -Assembly Above Drive Gear 4. 5. 6. 7. 8. armature end play adjusting screw and insert a rod through the opening in order to apply pressure against the end of the armature. Unsolder the black cotton-covered lead from circuit breaker (fig. 30). Straighten out the four tabs that secure the brush plate to the field coil retainers (fig. 30). CAUTION: Be careful not to break any of the retainer tabs. Install " U " shaped brush retainer clip over brush holder that has brush lead attached to circuit breaker (fig. 30). Holding the opposite brush from that retained in Step 6, carefully lift the brush holder off the mounting tabs far enough to clear the armature commutator (fig. 31). Allow the brush, held in Step 7, to move out of its holder. Remove the brush spring and lift the brush holder off the armature shaft. A rm ature Removal 1. Follow Steps 1 thru 8 under brush plate and circuit breaker removal. 2. Lift armature out of case and field assembly. 3. If armature is being replaced, remove thrust ball Fig. 2 9 -Wiper Motor Separation from end of defective armature shaft and install it in new armature. NOTE: Thrust ball may be easily removed with a magnet. Case and Field Assem bly Removal 1. Remove brush plate and armature. 2. The end case and field assembly is serviced as a unit. To free the field and case assembly, cut the solid black plastic insulation and black with pink LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 1 2 -2 3 CUT MOTOR LEADS IN THIS GENERAL AREA FOR SPLICING BRUSH PLATE ASSEMBLY RETAINER TAB (4) “ U" BRUSH RETAINER CLIP BLACK LEAD TO CIRCUIT BREAKER SPLICE NOTES: 1-SOLID BLACK TO SHUNT FIELD COIL SERIES FIELD COIL TO BLACK WITH PINK STRIPE LEAD CIRCUIT BREAKER Fig. 31-Removing Brush Holder Fig. 30--Circuit Breaker stripe leads in a location convenient for splicingpreferably near the wiper terminal board. Refer to Figure 30 for splicing location. 3. Remove steel thrust plate and rubber disc from case bearing as required. M O T O R ASSEMBLY 1. If new field and case assembly is being installed, splice the black and black with pink stripe leads of the new field with the corresponding leads of the wiper terminal board. 2. Install the rubber thrust disc, steel thrust disc and felt lubricating washer in the case assembly bearing in order indicated. 3. Lubricate end of armature shaft that fits in case bearing Next, install thrust ball in end of shaft. 4. Assemble armature in the case and field assembly (fig. 32). 5. Position the partially assembled brush plate (fig. 33) over the armature shaft far enough to allow assembly of the remaining brush in its brush holder, then position the brush plate on the mounting tabs in the position shown in Figure 30. NOTE: Circuit breaker should be opposite field cross over splice connections (Figure 30). 6. Center the brush plate mounting holes over the Fig. 32--Armature Installation 7 mounting tabs and bend the tabs toward the brush holders as required to secure the brush plate in position. CAUTION: Be sure tabs are centered in brush plate mounting holes. Remove brush retainer clips and resolder black cotton covered lead to circuit breaker (fig. 30). 8 If new case and field assembly is used, scribe a line LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 2 4 ELECTRICAL - BODY AND CHASSIS R ELA Y A R M A TU R E A R M A TU R E SPRING POSITIONED IN GROOVE OF SHAFT LEG A R M A TU R E S P R IN G PA W L R ATC H ET S P R IN G II D O G RATCH ET RATC H ET IT A N G *A C T S O F 9. 10. 11. 12. 13. O F AS S P R IN G 18 T O O T H RATCH ET W H EEL Fig. 34-Washer Pump Assembly Fig. 33-Brush Plate Assembly on it in the same location as the one scribed on the old case. This will insure proper alignment of the new case with the scribed line made on the housing (Step 1 under Brush Plate Removal). Position armature worm shaft inside the housing and, using the scribed reference marks, line up as near as possible the case and field assembly with the housing. M aintaining the armature in its assembled position in the case, start the armature worm shaft through the field and housing bearing until it starts to mesh with the worm gear. At the same time, carefully pull the excess black and black and pink stripe leads through the housing grommet. CAUTION: It may be necessary at this point to rotate armature slightly before the armature worm will engage with worm gear teeth. Rotate the case as required to align the bolt holes in the case with those in the housing. Secure the case to the housing with the two tie bolts. Adjust armature end-play as described under "W iper Adjustments". PA W L W HEEL removed from the wiper assembly as a unit; therefore, it is not necessary to remove the wiper assembly from the vehicle if only the washer pump and/or valve assembly requires service. When the pump is removed from the wiper assembly, all working parts are readily accessible and may easily be serviced as necessary (fig. 34). A cross-section of the washer pump valve assembly is shown in Figure 35. Replacement 1. Raise vehicle hood and disconnect ground cable from battery. 2. G Models - Remove left heater duct attached to engine shroud, for access. 3. Disconnect washer hoses and electrical connections from assembly. 4. Remove three screws securing washer pump and cover to wiper assembly. Remove pump from wiper gear box. 5. To install, reverse Steps 1-4 above. Pump Valve Replacement 1. A rm ature End-Play - Raise hood. Disconnect washer hoses and electrical connections from assembly. 2. Remove the four screws that attach the valve assembly to the pump housing. CAUTION: During re-assembly be sure gasket between housing and valve plate is properly positioned in the housing and valve plate grooves. Also be sure triple "O" ring is properly installed between valve and pipe assembly. 3. To install, reverse removal procedure. Loosen adjusting screw locknut (Figure 26) and tighten the adjusting screw until finger tight, tighten locknut. G ear Assem bly End-Play Add end-play washers as required to obtain .005" minimum end-play (Figure 26). W ASHER P U M P The washer pump and/or valve assembly may be G Models - Remove the washer pump as outlined W IP E R A D JU S T M E N T S above. C-K Models LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND CHASSIS 1 2 -2 5 SPRING COMPRESSED PISTON INTAKE VALVE OPEN DIRECTION OF TR A V EL FROM WASHER JAR // / / \ . : // x 'ACTUATOR P L A T E EXHAUST VALVES CLOSED INTAKE STROKE PISTON SPRING EXPANDED INTAKE V ALVE CLOSED DIRECTION OF TR A V EL Z Z I ACTUATOR P L A T E TO N O ZZLES EXHAUST S T R O K E EXHAUST V ALVES OPEN Fig. 35--Cross Section of Windshield Washer Pump Valve Assembly DIAGNOSIS W IP E R - ON VEHICLE Troubleshooting with wiper installed on the vehicle consists of two basic steps: (A) Preliminary inspection and (B) Operating wiper independent of vehicle wiring and dash switch. Prelim inary Inspection Procedure A. Preliminary Inspection - Check the following items: 1. Body wiring securely connected to wiper unit and dash switch. 2. Wiper ground connection to vehicle chassis. 3. Dash switch is mounted securely. 4. Fuse. 5. With ignition switch "O N ", there should be 12 volts at center terminal (No. 2) of wiper connector body. Refer to Figure 36 for # 2 terminal location. B. To determine if wiper is cause of trouble, disconnect existing harness from wiper and connect jum per leads to wiper terminals as shown in Figure 36. Try operating wiper in LO and HI speeds. Also check if wiper will shut off properly (blades in park position). If wiper operates correctly, trouble must be in wiring harness or dash switch. Refer to TROUBLE CHART. If wiper fails to operate correctly, remove wiper and check it per instructions in TROUBLE CHART - WIPER DETACHED. LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -2 6 ELECTRICAL - BODY AND CHASSIS POWER SOURCE CONNECTIONS TO WIPER GROUND BLACK (PLASTIC COATED] GEAR IN PARK POSITION-WIPER OFF PARK SWITCH CONTACTS OPENED BY GEAR CAM L o Speed “ H i” Speed As shown - D is c o n n e c t Jumper from T e r m i n a No. 3. Park - Reconnect Jumper to No. 3 te rm in al and d i s c o n n e c t Jumper from wi pe r housing. NOTE: To r e c h e c k park po si tio n of gea r, rec on­ ne ct jumper w ir e to Hsg. ( G r d .) mo m ent ari ­ ly. Wiper gear should c on ti nue to ro tate un til it stop s in the po si tio n shown. Fig. 3 6 -Wiper Motor Diagnosis Diagram W IP E R - OFF VEHICLE Connect Ammeter (0-30 amps), Power Source and Jumper wires to wiper as shown in Figure 36. Observe current draw, determine type of trouble that exists and refer to the TROUBLE CHART - WIPER DETACHED. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A ND CHASSIS 12-27 TROUBLE CHA R T Wiper Performs Correctly in Step "B " PO SSIBLE C A U SE But O R IG IN A L T R O U B L E Was 1 — W ip e r in o p e ra tiv e — N o vo lta g e s u p p ly at w ip e r (B lo w n f u s e o r o p e n in w i r e t h a t c o n n e c t s to N o . 2 w ip e r te rm in a l.) — — D e fe c tive D a sh S w itc h W ire fr o m W ip e r T e rm in a l N o . 1 to dash sw itc h o p e n . 2 — W ip e r w o u ld n o t shut o ff b u t h ad : (a) B o th L O an d H I speeds (a) W ire fr o m w ip e r te rm in a l 1 to dash sw itc h g ro u n d e d . (b) L O speed o n ly (b) W ire fr o m w ip e r te rm in a l N o . 3 to dash s w itc h g ro u n d e d . (c) H I speed o n ly (c) W ire fr o m w ip e r te rm in a l N o . 3 to dash s w itc h o p e n . 3 — W ip e r had " H I " speed o n ly S e e i te m 2 (c) a b o v e 4 — W ip e r had " L O " See ite m 2 (b) a b o v e 5 — In te rm itte n t O p e ra tio n speed o n ly L o o s e dash sw itc h m o u n tin g . D e fe c tiv e dash sw itc h . LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -2 8 ELECTRICAL - BODY AND CHASSIS TROUBLE CHART - WIPER DETACHED Trouble Description (1) Check the items shown in the views opposite trouble description W ip e r In o p e ra tive an d ITEM 1 Solder connections to Terminal Board (a) A m m e te r R e a d in g — ITEM 4 ITEM 3 1) Circuit-breaker Contacts clean and closed 2) Solder Connections to 0 Am p. C h e c k ite m s : Splice Connections -Brush pigtail to Field Coil leads ITEM 6 Brushes slide freely in Holdei 1 , 2 (a ), 4 and 5 Brushes and Brush-holders are not damaged ITEM 5 Field crossover splice connection: are secure (b) A m m e te r R e a d in g — Black with Pink Stripe 2 .0 -3 .0 A m p s C h e c k ite m s : 1 ,3 , 4, 6 ITEM 2 Splice Joints: a) Black with Pink Stripe to Series Field Coil b) Solid Black to Shunt Field Coil (c) A m m e te r R e a d in g - 20 + Am ps Check w ill for stall b ro ke n c o n d itio n w ip e r, gear or that such as loc ked arm atu re. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 1 2 -2 9 T R O U B L E C H A R T - W IPER D E TA C H E D (C O NT.) Trouble Description Check Items shown in views opposite trouble description (1) S w i t c h C o n t a c t s n o t o p e n i n g (2) W ip e r w ill n o t shut o f f a n d (a) W ip e r has b o th Speeds. L O Check and HI Ite m s (1) and (2). (b) W ip e r has L O Speed O n ly . Check (3) Ite m s and (4 ). ( 4 ) G r o u n d e d Fi eld Coil S e e 'C H E C K IN G T H E FIELD (c) W ip e r has (Shunt HI fie ld C O IL', Speed O n ly . c irc u it o p e n ) R e fe r to tro u b le c o n d itio n "W ip e r In o p e ra tive ” ch e ck Ite m s 1 , 2 ( 3 ) B l a c k Pl a s t ic C o v e r e d L e a d and (b ), 4 and to N o . 3 T e r m in a l g r o u n d e d 5. (3) R efer W ip e r has " H I ” S p e e d O n l y to vie w o p p o s ite tro u b le co n d itio n "W ip e r In ­ o p e ra tiv e ” a n d ch eck Item s 1 , 2 (b ), 4 an d 5 . (4) W ip e r has ” L O " (5) W ip e r Gear Speed O n ly and/or crank See T r o u b le D e sc rip tio n 2 (b). arm Check fo r b e n t, d a m a g e d o r d ir t y p a rk sw itc h c o n ta c ts . See does n o t park c o rre c tly . W iper Ite m gear and/or w ill n o t s h u t " O f f ” . ro ta tin g crank arm im m e d ia te ly stops ( 1 ) in v i e w o p p o s i t e T r o u b l e D e s c r i p t i o n N o . 2 " W i p e r when w i p e r m o t o r is s h u t o f f . (6) W ip e r Speed Exc e s s iv e in Hi O p e n resistor o n b a c k o f w ip e r t e r m in a l b o a r d . Speed M ode (C rank arm or gear ro ta tio n exceeds 8 0 R P M ) LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 3 0 ELECTRICAL - BODY AND CHASSIS T R O U B L E C H A R T - W IPER D E TA C H E D (C O N T.) Trouble Description (7) Check items shown in view opposite trouble description. In te rm itte n t O p e ra tio n : (a) Current D ra w Norm al (1) C h e c k f o r lo o s e sp lice jo in ts a n d / o r so ld e r jo in ts . (3 .5 — 5 .0 a m p s .) R e fe r to vie w o p p o s ite tr o u b le d e sc rip tio n (w ip e r In o p ). I f i t e m s c h e c k o u t , a d e f e c t i v e c i r c u i t b r e a k e r is i n d i c a t e d . (b) Current am ps. Draw — (W ip e r 6 — runs 8 (1) slo w a n d is n o i s y . ) C h e c k fo r sh o rte d or g ro u n d e d a rm a tu re . (2) C h e c k a rm a tu re en d p la y ( .0 0 2 " — .0 0 3 " N o r m a l) (3) C h e c k gear sh a ft en d p la y ( .0 0 5 " M a x .) C H E C K IN G T H E A R M A T U R E A N D F IE L D C O IL A SSEM BLY Fie ld te stin g the arm ature and c o n tin u ity of fie ld c o ils 25 WATT LAMP c o n s is ts o f u s in g a te s t lig h t s im ila r t o t h a t s h o w n in F i g u r e A. ___________ D is as se m b le M o to r as r e q u i r e d to ga in access t o th e fie ld 115 v. Test Probes a n d a r m a t u r e a s s e m b lie s . Typical Test Light FIGURE A A rm ature Checks: G r o u n d e d —T o u c h te st lig h t p ro b e s to a r m a t u r e la m in a a n d CHECK that commutator hooks are formed tightly over the coil wire c o m m u t a t o r . I f a r m a t u r e is g r o u n d e d , t h e l a m p w ill lig h t. Open — A bar to bar check w ith the test lig h t w ill in d ic a te an o p e n a rm a tu re ( F i g . B ) . If la m p d o e s n o t lig h t b e tw e e n c o m m u ta to r bars, any an tw o open a d ja c e n t arm atu re is in d ic a te d . S h orted — T e s t a rm a tu re o n g ro w le r fo r s h o rte d c o n d itio n . Field Coil Checks: I M P O R T A N T : Insulate c o m m u tato r. A th in brushes fr o m a r m a t u r e pie ce o f p a p e r w ill b e a d e q u a te . FIGURE B LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D C HASSIS 12-31 CHECKING THE ARMATURE AND FIELD ASSEMBLY (CONT.) Open Check Connect test lig h t S h u n t Fie ld : Brush lead to fo llo w in g p o in ts. C . R e fe r to Fig u re " A ” and b la c k w ire te rm in a l ( N o . 3 ) o n w ip e r te rm in a l b o a r d . If la m p fails t o 2, 4 lig h t, ch e ck and 5 in sp lice jo in ts — Ite m s Tro u b le Chart o p p o s ite w ip e r in o p e ra tiv e . S erie s F i e l d : Brush w ip e r fails t o 2, 4 “A " le a d te rm in al and lig h t, ch e ck and 5 No. board in 2 Fig u re te rm in a l C on . If lam p sp lice jo in ts — Ite m s Tro u b le Chart o p p o s ite w ip e r in o p e ra tiv e . Ground Check Connect w ip e r (B e ’t e s t te rm in a l sure End lig h t to fie ld la m ina and b o a r d , te rm in a ls 2 an d Cap and Fie ld 3. L a m i n a are n o t t o u c h i n g w i p e r g e ar c a s tin g .) FIGURE C LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -3 2 ELECTRICAL - BODY AND CHASSIS DIAGNOSIS - WASHER SYSTEM C O N D IT IO N 1. W asher inoperative 2. W asher pum ps continuously when wipers are operating A P P A R E N T CA USE C O R R E C T IO N A. Inadequate quantity of washer solution A. A dd washer solution B. Hoses damaged or loose B. Cut short length to insure air tight connection or replace hose C. Plugged screen at end of jar cover hose C. Clean screen D. Loose electrical connection to washer pum p or wiper switch D. Check electrical connection and repair if necessary E. Open circuit in feed wire to pum p solenoid coil E. Locate open circuit and repair F. W iper switch defective F. Replace wiper switch G. Pum p solenoid coil defective G. Replace solenoid H. W asher nozzles plugged H. Clean washer nozzles I. R atchet wheel tooth missing I. Replace ratchet wheel J. R atchet pawl spring missing J. Replace ratchet pawl spring K. Defective pum p valve assembly K. Replace pum p valve assembly A. G rounded wire from pum p solenoid to switch A. Locate grounded wire and repair B. W iper Switch Defective B. Replace wiper switch C. R atchet wheel tooth missing C. Replace ratchet wheel D. R atchet wheel dog broken or not contacting ratchet wheel teeth D. Replace or repair ratchet wheel dog E. Lock-out tang broken or bent on piston actuating plate E. Replace piston actuating plate LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A N D CHASSIS 1 2 -3 3 W INDHSIELD WIPER AND WASHER P MODELS IN D E X General Description........................................................................ Theory of Operation....................................................................... Service Operations........................................................................... Wiper M otor................................................................................... Windshield W asher....................................................................... Diagnosis............................................................................................ 12-33 12-33 12-34 12-34 12-36 12-39 GENERAL DESCRIPTION The system consists of a compound wound rectangular­ shaped motor attached to a gear box containing a parking switch in addition to the gear train. The gear train consists of a motor armature helical gearshaft which drives an intermediate gear and pinion assembly. The pinion gear of the intermediate gear and pinion drives an output gear and shaft assembly. THEORY OF OPERATION Turning the wiper switch to the LO speed position completes the circuits from the wiper terminals 1 and 3 to ground. Current then flows from the battery via wiper terminal No. 2 through the series field and divides; (1) part passes through the armature to ground via wiper terminal No. 1 to the wiper switch and (2) the second part passes through the shunt field to ground through wiper terminal No. 3 to the wiper switch (fig. 37). NOTE: The wiper switch must be securely grounded to body metal. Moving the wiper switch to the HI speed position opens the shunt field circuit to ground at the switch. However, the shunt field is connected to a 20 ohm resistor which is connected across wiper terminals 1 and 3. The shunt field current then flows via terminal No. 3 through the resistor to terminal No. 1 to the switch, to ground (fig. 38). The parking circuit covers that portion of wiper operation when the wiper switch is turned "off" and the wiper blades have not reached the park position. When the wiper blades are not in the normal park position, the parking switch contacts are still closed. The wiper will continue to operate until the wiper output gear is turned to a position where it’s cam opens the park switch. Referring to Figure 39, it can be seen that the wiper motor circuits are completed to ground through the parking switch. NOTE: The wiper motor must be securely grounded to body metal. WIPER GEAR TRAIN DASH SWITCH WIPER TERMINAL BOARD / m 1 —ll 1____ Tilt —|l SERIES F / SHUNT F - NAT. WIRE IGNITION SWITCH Fig. 3 7 -L O Speed Circuit LIGHT DUTY TRUCK SERVICE MANUAL 1 2 - 3 4 ELECTRICAL - BODY A ND CHASSIS S E R IE S F SHUNT F - NATURAL W IR E Fig. 3 8 -H I Speed C ircuit Fig. 39-P AR K IN G C ircuit The shunt field circuit is completed from terminal No. 3 via the switch to terminal No. 1 through the parking switch to ground. The series field and armature circuit is also completed from terminal No. 1 through the parking switch to ground. NOTE: The shunt field is connected direct to ground, by-passing the resistor. This results in LO speed operation during the parking operation. When the output gear cam opens the park switch contacts, the wiper is OFF. SERVICE OPERATIONS W IP E R M O TO R W iper motor replacement procedures are not included here since installation is performed by the individual body manufacturers; however, disassembly of the unit will be covered. Disassembly (Fig. 4 0 ) Gear Box 1. Remove the two washer pump mounting screws and lift pump off washer. Remove washer pump drive cam as required (figs. 43 and 44). The cam is pressed on the shaft but can be wedged off by using two screwdrivers between cam and plate. 3. Clamp crank arm in a vise and remove crank arm retaining nut. CAUTION: Failure to clamp crank arm may result in stripping of wiper gears. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND C HASSIS 1. 2. 3. 4. 5. 6. N ut Crank Arm Seal Cap Retaining Cap Washer Gear Box Cover 7. O u tp ut Gear and Shaft Assembly 8. Interm ediate Gear 9. Wave Washer 10. Gear Box Housing l I . Brush Plate Assembly and M ounting Brackets 12. Brushes 13. Wave Washers 14. Flat Washers 15. 16. 17. 18. 19. 12-35 Armature Thrust Plug Frame and Field End Plate Tie Bolts (Two Required) Fig. 40-Wiper Motor and Gear Box Assembly 4. Remove crank arm, seal cap, retaining ring, and end-play washers. NOTE: Seal cap should be cleaned and repacked with a waterproof grease before reassembly. 5. Drill out gear box cover retaining rivets, remove cover from gear train. NOTE: Screws, nuts and lockwashers for reassembling cover to wiper are contained in the service repair package. 6. Remove output gear and shaft assembly, then slide intermediate gear and pinion assembly off shaft. 7. If necessary, remove terminal board and park switch assembly as follows: a. Unsolder motor leads from terminals. Code motor leads. b. Drill out rivets securing terminal board and park switch ground strap to mounting plate. NOTE: Screws, nuts and washers for attaching a replacement terminal board park switch assembly are included with the replacement assembly. Motor 1. Follow Steps 1 through 7b under gear box disassembly. 2. Remove motor through bolts, tap motor frame lightly, and remove motor from mounting plate. 3. Remove brush spring tension (fig. 40), slide armature and end plate from motor frame. Pull end plate from armature. NOTE: Thrust plug located between arm a­ ture shaft and end plate. 4. Remove end play adjusting washers from armature, noting arrangem ent for proper reinstallation. Inspection Check and inspect all parts for wear; replace as necessary. All parts can be replaced individually except motor frame and field, which is serviced as an assembly. Service kits also provide screws, nuts and washers to replace gear cover and terminal board rivets. Assem bly Refer to Figure 40 for exploded view of motor and gear train. LIGHT DUTY TRUCK SERVICE MANUAL 12 36 ELECTRICAL - BODY AND CHASSIS PUMP M O U N T IN G SC R E W S Fig. 43--Washer Pump Attaching Screws Fig. 41--End Play Wave Washer Installation Motor Gear Box R eassem b le motor using reverse of disassembly procedure. NOTE: Armature end play is controlled by end play washers. See Figure 4 1 for proper assembly of end play washers. Lubricate armature shaft bushings with light machine oil. 1. Assemble gear box using reverse of disassembly procedure. NOTE: Lubricate gear teeth with Delco Cam and Ball Bearing lubricant (or equivalent). Be sure cover is properly located over dowel pins and be sure to reinstall ground strap. 2. Place wiper in park position and install crank arm on output shaft, rotate crank so alignment marks line up with those on cover (fig. 42). 3. Replace retaining nut, place crank arm in vise, tighten retaining nut. W IN D S H IE L D W ASHER The positive displacement washer pump used on the twospeed non-depressed park wipers (fig. 43) use a pump mechanism consisting of a piston, piston spring and valve arrangement driven by a (4) lobe cam, and follower assembly (fig. 45). The cam is attached to one shaft of the wiper motor output gear (fig. 44). Programming is accomplished electrically and mechani­ cally by a relay assembly and ratchet wheel arrangement. Replacement Fig. 42--W iper M otor C rank Arm in Park Position 1. Disconnect battery ground cable. 2. Remove two (2) pump mounting bolts. 3. Remove washer pump assembly. LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY A ND CHASSIS 12-37 SOLENOID COIL VALVE ASSEMBLY SOLENOID PLUNGER RATCHET PAWL SPRING CAM FOLLOWER UPPER PIN 4 LOBE CAM (PRESS FIT ON SHAFT) "E” RING RATCHET PAWL Fig. 46-Washer Pump Mechanism Solenoid assembly - ratchet dog. a. Remove the ratchet dog retaining screw. Hold the spring loaded solenoid plunger in position and carefully lift the solenoid assembly and ratchet dog off the frame of the pump. b. Separate the ratchet dog from solenoid mount­ ing plate as required. 3 Ratchet pawl. a. Disconnect ratchet pawl spring. b. Remove ratchet pawl retaining ring and slide ratchet pawl off cam follower shaft. 4 Ratchet wheel. a. Follow Step 1 under solenoid - ratchet dog disassembly. 2 Fig. 44- Washer Pump Drive Cam 4. To install reverse Steps 1-3 above. CAUTION: Install washer multiplug harness connector with battery lead on terminal with no tang (fig. 43). Incorrect installation of connector will result in direct ground and destroy wiper motor fuse. Disassembly-Assembly (Figures 4 6 -4 9 ) 1. Remove washer pump cover by squeezing. RATCHET DOG RETAINING SOLENOID ASSEMBLY RATCHET PAWL SPRING VALVE ASSEMBLY MOUNTING SCREW FRAME RATCHET PAWL iv A* i v n t i GROOVES BOTH SIDES Fig. 4 5-W asher Pump Drive Cam and Actuator WHEEL E” RING Fig. 4 7 -W a sh e r Pump-Exploded View LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -3 8 ELECTRICAL - BODY AND CHASSIS a. Remove solenoid assembly - ratchet dog, ratchet pawl and ratchet wheel as outlined in their respective procedures. b. To separate the pump and pump actuator plate from the frame, pull the pump housing in the direction of the arrow until the grooves in the housing clear the frame. Then remove the actuator plate from the ratchet wheel and cam follower shafts. 6. Valve assembly. a. Remove the four (4) screws that attach the valve assembly to the pump housing. CAUTION: During assembly, be sure gasket between housing and valve plate is properly positioned in the housing and valve plate grooves. Also be sure triple "O" ring is properly installed between valve body and pipe assembly. Fig. 48 -Releasing Pump From Lockout Position b. Move ratchet wheel spring out of shaft groove and slide ratchet wheel off its shaft. 5. Pump and actuator plate assembly. PISTON 7. To assemble washer unit, reverse above procedures. SPRING COMPRESSED INTAKE V ALVE OPEN FROM WASHER JAR DIRECTION OF TR A V EL 'ACTUATOR P LA TE EXHAUST VALVES CLOSED INTAKE STROKE PISTON INTAKE V ALVE CLOSED SPRING EXPANDED DIRECTION OF TR A V EL ACTUATOR P LA T E TO NOZZLES EXHAUST VALVES OPEN EXHAUST S T R O K E Fig. 49--Cross Section of W indshield Washer Pump Valve LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND C HASSIS 1 2-39 DIAGNOSIS W IP E R - ON VEHICLE TEST LIGHT PROBES FOR GROUND CHECK. IF LAMP LIG H TS, ARMATURE IS GROUNDED 1. Inspect for the following items: a. W iring harness is securely connected to wiper and switch. b. W iper motor is securely grounded to body. c. W iper switch is securely mounted and grounded. d. Check fuse. 2. If items in Step 1 check out, try operating wiper in both "LO " and "H I" speeds, then turn wiper off (blades should return to park position). If wiper fails to operate correctly, proceed to Step 3. 3. Disconnect wiring harness from wiper and try operating wiper as shown in Figure 50. a. If wiper operates correctly independently of switch and vehicle wiring, refer to the DIAGNOSIS CHART - WIPER ON VEHICLE. b. If wiper still fails to operate correctly in Step 3, disconnect wiper linkage from motor crankarm and try operating wiper again. If wiper operates correctly independently of linkage, check linkage for cause of wiper malfunction. COMMUTATOR HOOK CHECK FOR POOR WELD JOINTS TEST LIGHT PROBES, BAR TO BAR CHECK FOR OPENS - LAMP SHOULD LIGHT BETWEEN ADJACENT BARS Fig. 5 1 -Checking Armature c. If wiper fails to operate correctly independently of linkage, remove wiper motor from vehicle and refer to DIAGNOSIS CHART-WIPER OFF VEHICLE. LO SPEED - AS SHOWN HI SPEED - DISCONNECT JUMPER W IRE FROM TERMINAL NO. 3. GREEN NATURAL OFF - LEAVE JUMPER CONNECTED TO NOS. 1 &3 BUT DISCONNECT IT FROM GRD. STR A P . W IPER SHOULD STOP WITH GEAR SHAFT FLATS AS SHOWN. AMMETER 0 - 3 0 A M P S.) GRAY SLEEVING OVER GREEN WIRE ’‘A" SPLICE JOINT TESTING FOR OPEN COILS: GRAY SERIES F - USING TEST LAMP, TOUCH "A". IF LAMP DOES NOT , LIGHT, FIELD COIL IS OPEN. 1 (RECHECK SPLICE AND SOLDER JOINTS. >' SHAFT IN PARK PO SITIO N W IPER GROUND STRA P Fig. 5 0 -Jum per Wire Connections SHUNT F - TOUCH "A" AND "3". IF LAMP DOES NOT LIGHT. FIELD COIL ISOPEN. (CHECK SPLICE AND SOLDER JO IN T S .) TESTING FOR GROUNDED COIL: TOUCH TEST LIGHT TO "A" AND FRAME IF LAMP LIGHTS, FIELD COILS ARE GROUNDED. TEST LIGHT "•'fc \ \ x \ s. Fig. 5 2 -Testing Field Coils LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -4 0 ELECTRICAL - BODY A N D CHASSIS DIAGNOSIS - WIPER ON VEHICLE NOTE: Ignition CONDITION 1. Wiper Inoperative or intermittent switch must be "on" for all electrical tests. CORRECTION APPARENT CAUSE A. Blown fuse A. Locate short circuit and repair. Replace fuse. B. Open circuit in feed wire (No. 2 terminal on wiper motor) B. Locate broken wire and repair C. Loose mounting of wiper switch C. Tighten switch mounting D. Defective wiper switch D. Replace switch E. Open circuit in wire to wiper switch (No. 1 terminal on wiper motor) E. Locate broken wire and repair A. Grounded Wire (No. 1 terminal on wiper motor) to wiper switch A. Locate short circuit and repair A. Defective wiper switch A. Replace wiper switch B. Grounded wire (No. 3 terminal on wiper motor) to wiper switch B. Locate and repair short circuit A. Defective wiper switch A. Replace wiper switch B. Open circuit in wire (No. 3 terminal on wiper motor) to wiper switch B. Locate and repair broken wire 3. Wiper has "Hi" speed only A. Open circuit in wire (No. 3 terminal on wiper motor) to wiper switch A. Locate broken wire and repair 4. Wiper has "Lo" speed only A. Grounded wire (No. 3 terminal on wiper motor) to wiper switch A. Locate short circuit and repair B. Defective wiper switch B. Replace wiper switch A. Loose wiper ground strap connection A. Tighten strap connection 2. Wiper will not shut off: A. Wiper has both "Lo" and "Hi" speeds B. Wiper has "Lo" speed only C. Wiper has "Hi" speed only 5. Blades do not return to full park position LIGHT DUTY TRUCK SERVICE MANUAL ELECTRICAL - BODY AND CHASSIS 12 41 DIAGNOSIS - WIPER OFF VEHICLE C O N D IT IO N A P PA R E N T CA USE C O R R E C T IO N A. Broken or dam aged gear train (only if inoperative) A. Replace gears as required B. Poor solder connections at term inal board B. Resolder wires at term inals C. Loose splice joints at brush plate C. Recrim p or solder splice joints D. Brushes binding in brush holder D. Clean holder or replace brush, spring or brush plate assembly. E. Open circuit in arm ature E. Replace arm ature A. Defective park switch A. Replace term inal board assembly B. G rounded red lead wire B. R epair short circuit in red wire A. G rounded shunt field coil A. Replace fram e and field assembly B. G rounded black wire B. Repair short circuit in black wire A. Open circuit in shunt field coil A. Replace fram e and field assembly B. Open circuit in black wire B. Repair broken wire or poor solder connection 3. W iper shuts off - but not in park position A. Park switch defective or contacts dirty A. Replace term inal board assembly or clean contacts 4. "H i" speed too fast A. Resistor defective A. Replace term inal board assembly 1. W iper Inoperative or Interm ittent 2. W iper will not shut-off: A. W iper has norm al "Hi" and "Lo" speed B. W iper has "Lo" speed only C. W iper has "H i" speed only LIGHT DUTY TRUCK SERVICE MANUAL 1 2 -4 2 ELECTRICAL - BODY A ND CHASSIS DIAGNOSIS - WASHER SYSTEM C O N D IT IO N A PPA R E N T CA USE C O R R E C TIO N 1. W ashers inoperative A. Inadequate quantity of washer solution A. Add w'asher solution B. Hoses damaged or loose B. Cut short length off end of hose to insure air tight connection or replace hose C. Plugged screen at end of jar cover hose C. Clean screen D. Loose electrical connection to washer pum p or wiper switch D. Check electrical connections and repair if necessary E. Open circuit in feed wire to ratchet relay coil E. Locate open circuit and repair F. W iper switch defective F. Replace wiper switch G. Ratchet relay coil defective G. Replace ratchet relay H. W asher nozzles plugged H. Clean washer nozzles I. R atchet wheel tooth missing I. Replace ratchet wheel J. R atchet pawl spring missing J. Replace ratchet pawl spring K. Defective pum p valve assembly K. Replace pum p valve assembly A. G rounded wire from ratchet relay to switch A. Locate grounded wire and repair B. W iper switch defective B. Replace wiper switch C. R atchet wheel tooth missing C. Replace ratchet wheel D. R atchet wheel dog broken or not contacting ratchet wheel teeth D. Replace of repair ratchet wheel dog E. Lock-out tang broken or bent on piston actuating plate E. Replace piston actuating plate 2. W asher pum ps continously when wipers are operating LIGHT DUTY TRUCK SERVICE MANUAL RADIATOR A N D GRILLE 13-1 SECTION 13 RADIATOR AND GRILLE C O N T E N T S OF T H IS SECTIO N Radiator........................................................................ 13-1 Grille............................................................................. 13-4 RADIATOR IN D E X General Description.................................................... 13-1 Service Procedure........................................................ 13-1 Maintenance............................................................... 13-1 Radiator Replacement (all except P30(32) Chassis).......................................................................... 13-1 Coolant Recovery System........................................ 13-2 Radiator Replacement (P30(32) Chassis).............. 13-2 GENERAL DESCRIPTION P30 (32) Chassis is equipped with down-flow radiator, a coolant recovery system and incorporates a drain cock. All other models are equipped with cross-flow radiators. The cross-flow radiator is similar to the down-flow radiator except it is mounted sideways in the vehicle and attached in the conventional manner. With cross-flow radiator, coolant level should be a maximum of three inches below the bottom of the filler neck when cold on vehicles without recovery system. On vehicle with a coolant recovery system, level in the coolant tank should be at "Full-Cold" line when coolant is cold. At normal operating temperatures, level will reach "Full-Hot" line. The radiator should be completely full at all times. SERVICE PROCEDURES M A IN T E N A N C E For maintenance and checking cooling system, refer to Section 6K, Engine Cooling System. For cooling system capacities, refer to Section 0, General Information and Periodic Maintenance. Radiator R eplacem ent (A ll Except P30 (3 2 ) Chassis) (Figs. 1, 3, 4 ) 1. Drain radiator by removing radiator cap, inserting one end of a 5-foot length of 3/8 inch tubing into the filler neck until it touches the bottom of the radiator and with any type of large syringe inserted in other end of tube, initiate siphoning by squeezing and and releasing the ball. WARNING: If you siphon coolant from the radiator, do not use mouth to start siphoning action. The coolant solution is POISONOUS and can cause death or serious illness if swallowed. 2. Disconnect upper and lower hoses and transmission oil cooler lines if equipped. 3. Disconnect coolant recovery system hose if equipped. 4. If vehicle is equipped with a fan shroud, remove shroud attaching screw and carefully hang shroud, over engine fan assembly to provide clearance for radia­ tor removal. 5. Remove finger guard (G Series L-6 engine). 6. Remove mounting panel (retainers on G Series) from radiator support. Remove upper mounting pads. LIGHT DUTY TRUCK SERVICE MANUAL 1 3-2 RADIATOR A N D GRILLE 7. Lift radiator up and out of lower mounting pads. Lift shroud out of vehicle if applicable. 8. Inspect mounting pads and mounting panel or retainers and replace as required. 9. Inspect hose clamps and all hoses. Replace hoses whenever checked, swollen or otherwise deteriorated. 10. With fan shroud positioned over fan assembly, install radiator into lower mounting pads. 11. Install upper mounting pads and secure radiator by installing mounting panel or retainers. 12. Position fan shroud into clips and attach to mounting panel or retainers. 13. Connect radiator hoses, coolant recovery line and transmission oil cooler lines. 14. Tighten screws and hose clamps to proper torque value. 15. Fill radiator with coolant to three (3) inches below bottom of filler neck. On coolant recovery system, add sufficient coolant to reservoir tank to raise level to "Full-Hot" mark. 16. Run engine with radiator cap removed until upper radiator becomes hot. 17. With engine idling, add coolant to within 1-1/2 inches below bottom of filler neck and install radiator cap making certain arrows line up with overflow tube. 18. Pressure test system and radiator cap for proper pressure holding capacity (15 psi). If replacement of cap is required, use the proper cap specified for your vehicle. M O U N T I N G PA NEL CO O LA N T RECOVERY SYSTEM Refer to Figure 5 for removal and installation of coolant recovery system on CK Series and P (42) Series. CK Series shown, mounts on rear of radiator support and P (42) Series mounts on front of radiator support. Refer to Figure 6 for coolant recovery system on P30 (32) chassis. R A D IA TO R R E P LA C E M E N T (P 3 0 (3 2 ) Chassis) (Fig. 2 ) 1. Remove radiator cap and drain radiator by opening drain cock. 2. Disconnect radiator hoses, coolant recovery hose and transmission oil cooler line if equipped. 3. Place vehicle on hoist or raise front end. 4. Remove four (4) screws from lower support and remove support. 5. Lower radiator from vehicle. 6. Inspect mounting pads in upper and lower support retainers and replace as required. 7. Before installing radiator, caot rubber radiator retaining pads with a rubber lubricant. 8. Install radiator being sure that radiator tank ribs align with mounting pads in upper and lower support retainers. Radiator tanks must be fully seated around radiator support retainers. Do not crush radiator tanks. 9. Connect radiator hoses, coolant recovery system hose and transmission oil cooler lines. 10. Tighten screws to proper torque valve. 11. Fill radiator with coolant to 3 inches below bottom M O U N T IN G PANEL ^ CLIP R A D IA T O R v SUPPORT^ L6 ENGINE ALL P10-20-30(42) V8 ENGINE AUTO. TRANS. HEAVY DUTY RAD?' (TYPICAL SHOWN) Fig. 1—R adiator and Fan Shroud—C K /P Series LIGHT DUTY TRUCK SERVICE MANUAL RADIATOR A N D GRILLE 13-3 SUPPORT UPPER SUPPORT CAP SH RO UD .BRACE d* y UPPER CUSHI ON LOWER C U S HI O N ' Fig. 2—Radiator and Fan Shroud—P30 (32) Fig. 3 —R adiator M o u n tin g —G Series LIGHT DUTY TRUCK SERVICE MANUAL 1 3 -4 RADIATOR A N D GRILLE of filler neck. Add sufficient coolant to reservoir tank to raise level to "Full-Hot" mark. 12. Run engine with radiator cap removed until upper radiator becomes hot. 13. With engine idling, add coolant to within 1 1/2 inches below bottom of filler neck and install radiator cap making certain arrows line up with overflow tube. 14. Pressure test system and radiator cap for proper pressure holding capacity (15 psi). If replacement of cap is required, use the proper cap specified for your vehicle. CAUTION: Radiator support is not a structural member. No body mounting supports or other attachments used fo r structural purposes are to be fastened to radiator support. GRILLE IN D E X Grille - CK Series...................................................... 13-4 Grille - G Series......................................................... 13-5 SERVICE PROCUEDURES GRILLE - CK SERIES (Fig. 7) Removal 1. Remove the six (6) screws retaining cable to brackets and support assembly. 2. Remove molding as required. Installation Reverse removal procedure. Upper and lower molding must be installed with notch down. CAUTION: Grille is made of plastic. Do not use excessive heat or harsh chemicals to clean in this area to prevent distortion and/or paint peeling. LIGHT DUTY TRUCK SERVICE MANUAL R ADIATO R A N D GRILLE 13-5 Fig. 7—Radiator Grille—CK Series GRILLE - G SERIES (Fig. 8) Removal 1. Remove left and right headlamp bezels. 2. Remove attaching screws. Grille to cross sill, body and radiator support and remove the grille. 3. Separate emblem from grille, if necessary, by removing nuts on rear of emblem. Installation Install the grille in reverse order of removal. LIGHT DUTY TRUCK SERVICE MANUAL ' BUMPERS S E C T IO N 14 1 14 BUMPERS IN D E X General Description.................................................... 14-1 Service Procedures - 10 thru 30 Series.................. 14-1 Front Bumper - C, K and P Models................... 14-1 Rear Bumper - C and K Models...........................14-1 Rear Step Bumper - C and K Models.................14-2 Front Bumper G Series............................................14-2 Rear Bumper G Series..............................................14-2 GENERAL DESCRIPTION All 1973 truck front and rear bumpers are of a single piece design. Bumper attachments are the standard bracket and brace to frame mountings. This section contains procedures for the removal and installation of face bars, brackets, braces and license plate brackets, SERVICE PROCEDURES— 10 THRU 3 0 SERIES F R O N T B U M P E R -C , K A N D P MODELS (Fig- 1) Removal 1. Remove parking lamp assemblies. (See Section 12). 2. Remove bolts securing left and right bumper braces to frame. 3. Remove bolts securing two bumper brackets to frame. 4. Remove bolts securing bumper face bar to frame, and remove bumper from vehicle. 5. If necessary, disassemble bumper by removing bolts attaching brackets and braces to bumper face bar. Installation Assemble and install front bumper following the removal procedure in reverse order. Refer to torque specifications in rear of manual for correct torque values. REAR B U M P E R -C A N D K MO DELS (Fig. 2) Removal 1. Remove bolts attaching bumper to each bumper brace. Disconnect license lamp wiring on suburban and panels and pickup. 2. Remove bolts attaching bumper to frame. 3. Remove bumper from vehicle. 4. If necessary, replace body dirt seal. Installation I LIGHT DUTY TRUCK SERVICE MANUAL 1 4-2 BUMPERS Installation Install rear step bumper by reversing removal procedure. Connect license lamp bulb. Refer to torque specifications at the rear of this manual for correct torque values. FR O N T B U M P E R -G M O DELS Removal Fig. 4 1. Remove nuts securing bumper to brackets and braces from left and right side. Remove bumper. 2. Remove the license plate support nuts and bolts. 3. If necessary to remove the braces and brackets: remove screws securing brackets and braces to sheet metal. NOTE: The bumper may be removed with brackets and braces attached. Installation Install rear bumper following removal procedure in reverse order. Connect license lamp wiring on suburban, panel, and pickup models. Refer to torque specifications at the rear of this manual for correct torque values. REAR STEP B U M P E R C A N D K MODELS Rem oval (Fig. 3 ) 1. 2. 3. 4. Remove license plate lamp from socket. Remove bolts connecting bumper to braces. Remove bumper assembly. Remove bolts securing bumper brace to frame and re­ move brace. Install in reverse order of removal. Refer to torque specifications at rear of this manual for correct torque values. REAR B U M P E R -G M ODELS Removal Fig. 5 1. Remove nuts securing bumper to brackets and braces and remove the bumper. 2. Remove brackets and braces from vehicle. NOTE: The bumper may be removed with brackets and braces attached if necessary. Installation Install in reverse order of removal. Refer to torque specifications at the rear of this manual for correct torque values. LIGHT DUTY TRUCK SERVICE MANUAL SECTION 15 ACCESSORIES IN D E X General Description................................................................. Maintenance and Adjustments............................................... Component Part Replacement................................................ Radio......................................................................................... Speaker..................................................................................... Antenna.................................................................................... Diagnosis.................................................................................... 15-1 15-1 15-2 15-2 15-3 15-4 15-4 GENERAL DESCRIPTION AM and AM/FM radios are available on the C-K model trucks; AM only on G model trucks. C-K model trucks incorporate a windshield antenna. The antenna lead snaps onto the center of the windshield, inside the vehicle. G model antennas are mounted externally on the right front fender. M A IN TEN A N C E A N D ADJUSTMENTS R A D IO IN S TA LLA TIO N P R E C A U T IO N S Listed below are common causes of inoperative radio receivers or poor reception on the AM scale upon reinstallation after repair. • Radio speakers not connected-this could cause the output transister to burn out in the receiver. • Antenna lead not plugged into the receiver or windshield. • Antenna trimmer not peaked. 6. Adjust the antenna trimmer screw (±2° screw rotation) until maximum volumn is received (fig. 1). 7. Turn the radio volumn off. 8. Replace the tuner control bezel and knob. 9. Turn the ignition to "lock". T R IM M IN G RADIO If diagnosis indicates the radio receiver must be trimmed, perform the following procedure: 1. 6 Models-Set antenna mast at maximum height. 2. Remove the tuner control knob and bezel (right hand knob). 3. Place the ignition key in the "ACC" position. 4. Turn the volume control to maximum volume. 5. Tune the radio to a weak station (near 1400 CK) on the AM scale. LIGHT DUTY TRUCK SERVICE MANUAL 15-2 ACCESSORIES Fig. 2-Radio Installation (C-K Models) C O M P O N E N T PART REPLACEMENT RADIO G Models C-K M odels Replacement (Fig. 3) Replacement (Fig. 2) 1. 2. 3. 4. 1. Disconnect the battery ground cable. 2. Pull off radio control knobs and remove knob bezels. Remove the nuts and washers from the control shafts using a deep well socket. 3. AM Radio-Remove the radio support bracket stud nut and lockwasher. AM/FM Radio-Remove the radio support bracket to instrument panel screws. 4. Lift up on the rear edge of the radio. Then push the radio forward until the control shafts clear the instrument panel. Lower the control far enough to disconnect the electrical harness. 5. Disconnect the power feed, speaker and antenna lead wires and remove the radio. 6. To install, reverse Steps 1-5 above. 5. 6. 7. 8. 9. Disconnect ground cable from battery. Remove engine cover. Remove air cleaner on carburetor. Remove stud in carburetor throat for mounting air cleaner. Cover carburetor throat with clean plastic to prevent dirt or radio attachments from falling into carburetor. Remove knobs, washers and nuts from control shafts on front of radio. Remove bracket to radio receiver screw. Now guide radio forward and then down through engine access area. Lower the radio far enough to disconnect electrical connectors and antenna lead. Remove radio. Reverse Steps 1-8 for installation of radio. LIGHT DUTY TRUCK SERVICE MANUAL ACCESSORIES 15-3 Fig. 3-Radio Installation (G Models) SPEAKER C-K Models Replacement (Fig. 4) 1. Disconnect the battery ground cable. 2. Remove instrument cluster bezel upper (4) screws. 3. Remove the instrument panel pad screws and remove the pad. 4. Remove the speaker to dash panel screws. 5. Lift up on the speaker, disconnect the speaker wiring harness and then remove the speaker. 6. To install, reverse Steps 1-5 above. LIGHT DUTY TRUCK SERVICE MANUAL 15-4 ACCESSORIES G Models Replacement (Fig. 3) 1. Follow radio removal Steps 1 through 8. 2. Remove left heater duct (attached to engine cover extension by one screw). 3. Remove speaker to mounting bracket screw and lower speaker out engine cover opening. 4. Reverse Steps 1-3 above for speaker replacement. ANTENNA C-K Models (Fig. 5) Antenna Replacement Refer to Section IB of this manual "Windshield Replacement" procedure. cable assembly from turning using a second wrench. Cable Replacement 1. 2. 3. 4. Disconnect battery ground cable. Unsnap antenna cable from the windshield. Remove the bracket to dash panel screws. Disconnect the cable at the rear of the radio receiver and remove the cable assembly. G Models (Fig. 6) Antenna Replacement 1. 2. Unscrew the mast nut. Flolding the cable assembly from turning using two separate wrenches. Remove the rod and mast assembly. To install, insert the rod and mast assembly into the cable assembly and tighten the mast nut. Hold the Cable Assembly Replacement 1. Disconnect the battery ground cable. Remove the antenna assembly as described above. 3. Remove the cable body nut and then remove the seal, bezel, gasket and ring ground. 4. Perform Steps 2-8 of "Radio Removal". 5. Disconnect the cable at the rear of the receiver. Insert the new cable through the dash panel (from the forward side). 9. Reverse Steps 1-5 above to complete installation. NOTE: Be sure cable grommet is properly positioned in the dash panel. 2. D IA G N O S IS The radio trouble diagnosis guide is intended as an aid in locating minor faults which can be corrected without a specialized knowledge of radio and without special radio test equipment. If the suggestions given here do not affect a correction, further testing should be done only by a trained radio technician having proper test equipment. R A D IO DEAD Turn on radio. No Thum p Heard Check fuse. Fuse blown-Check receiver and speaker connectors. Connectors loose or defective-Correct as required. Connectors okay-Check speaker by substituting a known good speaker. Radio does not play even with a known good substitute speakerDefective receiver. Remove for servicing. Radio plays with substitute speaker-Replace speaker. Thum p Heard Check antenna connection at back of radio and at base of windshield or antenna. Connections defectiveSubstitute a known good lead-in cable. Radio plays-Defective cable. Radio still won’t play, even with a known good lead-in cable-Substitute and trim a known good radio. Good radio plays-Defective radio. LIGHT DUTY TRUCK SERVICE MANUAL ACCESSORIES 15-5 Good radio still won’t play-Defective antenna. Change windshield or antenna. RADIO C U TS ON AND OFF Check for defective or loose receiver or antenna connectors at the rear of radio or base of windshield or antenna. Defective or loose connectors-Repair as necessary. Connectors okay-Substitute a known good lead-in cable. Radio plays okay-Defective cable. Radio still cuts out with a known good lead-in cable- Check speaker by substituting a known good speaker. Radio plays okay-Replace speaker. Radio still plays intermittently, even with a known good speakerOefective receiver. R A D IO S T A TIO N S M IX TO G ETH ER Trim radio as described earlier in this section. However, if two or more signals are picked up at the same time, there is no known way to separate them. R A D IO NO ISY Static-Start engine, rev up engine several times, and listen for speaker static. Static Heard-Trim radio - check for spark plug wire breakdown, loose or improperly seated wire, or loose or missing engine ground strap. Check suppressors on voltage regulator, alternator, and resistor on timing control solenoid. Static Still PresentDefective receiver. W EAK RAD IO SIG N A L Test windshield antenna as described under "Antenna Testing" in this section. When antenna failure is suspected, the following checks should be made before replacing the windshield. 1. Check Tester J-23520 for operation on any vehicle radio antenna that is operating normally to test for a weak or dead battery. 2. Check all antenna connectings to insure that the antenna is electrically coupled to the radio. 3. Turn ignition switch to accessory position, turn radio "ON", select AM band if receiver is AM/FM and tune radio to an off station position. 4. Hold tester to antenna beginning at the upper corner of the antenna: CAUTION: The plastic Shield must be on the tester at all times to avoid scratching the windshield. a. If a shrill sound is emitted through the speaker when both antenna wires are tested, the antenna is operational. b. If no sound is emitted through one or both antenna wires, move the tester along the wire toward the center of the windshield and down toward the radio. c. If a shrill sound is picked up, find the exact location where the noise begins, this is the area of the defect. Replace windshield. d. If no noise is heard over the entire length of the antenna, unplug the antenna lead at the radio and touch the tester to the antenna socket in the radio. e. If the radio now makes a shrill sound, check connectors and antenna lead for possible defect before replacing windshield. f. If no noise is emitted, the radio, speaker, or fuse is defective. NOTE: Make sure that the antenna tester is turned off after completing antenna test. D IS TO R TE D TO NE Turn on radio, adjust for high volume and maximum bass. Check speaker by substituting a good speaker. No Distortion-Replace speaker. DistortionOefective receiver-remove for servicing. T E S T IN G W IN D S H IE LD A N T E N N A (FIG . 7) All C-K model trucks with factory installed radios are equipped with windshield antennas. To positively identify antenna failure and eliminate the possibility of unnecessary windshield replacement, Windshield An­ tenna Tester J-23520 should be used to determine the continuity of the thin antenna wire. Fig. 7 -Testing Windshield Antenna (Typical) LIGHT DUTY TRUCK SERVICE MANUAL SPECIFICATIONS HEATING AND AIR CONDITIONING SECTION 1A HEATER Volts Blower Motor C-K Models............ 13.5 G Models..............13.5 Amps. (Cold) 6.25 Max. 7.1 Max. RPM (Cold) 2550 Min. 2950 Max. 2850 Min. 3250 Max. Fuses C-K Models............................................................... 20 Amp. G Models..................................................................20 Amp. AU XILIARY HEATER Volts Blower Motor . . . . 13.5 Amps. (Cold) 9.6 Max. RPM (Cold) 2700 Min. AIR CONDITIONING Compressor Make.................................................................... Frigidaire Type........................................................... 6 Cylinder Axial Displacement.................................................... 12.6 Cu. In. Rotation............................................................... Clockwise Amps. RPM Volts (Cold) (Cold) Blower Motor C-K Four Season . . 12.0 C-K-G Overhead, G Floor and Motor Home' Units................ 12.0 12.8 Max. 3400 Min. 13.7 Max. 3400 Min. Compressor Clutch Coil Ohms (at 80°F)................................................. 3.70 Amps, (at 80°F).................................3.33 @ 12 volts System Capacities Refrigerant 12 C-K Four-Season System ............................ 3 lbs, C-K-G Overhead Systems..................... 5 lbs. 4 oz. G Floor System......................................3 lbs. 4 oz. Motor Home Chassis U nit..................... 3 lbs. 4 oz. Torque Specifications Compressor Suction and Discharge Connector Bolt........................................25 ft. lbs. Rear HeRd to Shell Stud Nuts........................23 ft. lbs. Shaft Mounting N ut...................................... 20 ft. lbs. Compressor Mounting Bracket Bolts.............25 ft. lbs. Front Bracket to Compressor Bolts.............. 20 ft. lbs. Belt Tension....................................See Tune Up Chart Fuses Fuse Block— C-K Systems.............................................25 Amp. Motor Home Chassis Unit..................... 20 Amp. In-LineC-K Systems .............................................25 Amp. Motor Home Chassis Unit............................... None Circuit Breaker G Model Systems........................................45 Amp. LIGHT DUTY TRUCK SERVICE MANUAL SPECIFICATIONS 2 BODY SECTION IB C AND K MODELS FRONT END Windshield Wiper Linkage to Plenum.....................25 in. lb. Sunshade Support....................................................20 in. lb. Inside Rear View Mirror to Bracket..........................45 in. lb. Outside Rear View Mirror to Door Panel — Base Mirror......................................................25 in. lb. West Coast Mirror—Lower Bracket to Door . . . 20 in. lb. —Upper Bracket to Door. . . . 45 in. lb. END GATE (06) Hinges-Hinge to Body.............................................35 ft. lb. —Hinge to End Gate........................................20 ft. lb. Support Cable Bolts................................................. 25 ft. lb. Torque Rod—Silencer Bracket.................................40 in. lb. —End Support Bracket..........................90 in. lb. Latch Assembly to End G ate................................... 20 ft. lb. Latch Remote Control Assembly to End Gate . . . . 40 in. lb. Access Cover ...........................................................18 in. lb. Outside Handle ...................................................... 55 in. lb. Glass Channel...........................................................45 in. lb. DOORS Window Regulator Assembly to Door Panel............85 in. lb. Remote Control Door Lock to Door Panel..............45 in. lb. Lock Striker to Body Pillar...................................... 45 ft. lb. Outside Door Handle................................................. 85 in. lb. Inside Door Handle................................................. 85 in. lb. Hinges to Body and D oor........................................35 ft. lb. Front Door—Window Run Channel Upper Screw Assembly ................................... 85 in. lb. Lower Bolt Assembly........................................18 in. lb. Front Door—Ventilator Assembly Top Vent Screw...............................................18 in. lb. Side Vent Screws and Spacers..........................25 in. lb. Lower Vent Channel Bolts...............................40 in. lb. Side Rear Door—Run Channel Front Upper to Door........................................40 in. lb. RearJJpper to Door ........................................20 in. lb. Front and Rear Lower to Door..........................85 in. lb. Lock Lever to Door ........................................85 in. lb. Rear Door—Lock Striker (06) ................................. 95 in. lb. Rear Door—Latch L.H. and R.H. to Door (06) ... . 85 in. lb. Rear Door—Latch Control Assembly to Door (06) —Upper Assembly...................................85 in. lb. —Lower Assembly................................... 90 in. lb. Rear Door—Weatherstrip L.H. (06 )..........................18 in. lb. TAILGATE (03, 63-w ith E63) Trunnion Assembly..................................................18 ft. lb. Linkage and Striker Assembly-Support .................25 in. lb. TAILGATE (03, 63-w ith E62) Trunnion Assembly................................................. 35 ft. lb. Chain Support Assembly ........................................90 in. lb. SEATS Front Bench Seat Adjuster-to-Seat .......................................... 155 in. lb. Adjuster-to-Floor.............................................25 ft. lb. Front Bucket Type (14, 03) Driver Adjuster-to-Seat........................................18 ft. lb. Adjuster-to-Floor ................................... 25 ft. lb. Passenger (03) Support-to-Seat........................................ 18 ft. lb. Support-to-Floor (Front)..........................25 ft. lb. Support-to-Floor (R ear)..........................40 ft. lb. Passenger (14) Latch Support-to-Seat (Rear) .................18 ft. lb. Striker-to-Floor (Rear) ..........................25 ft. lb. END GATE (14) Support (Upper)-to-Seat (Front) ............18 ft. lb. Support (Lower)-to-Floor (Front)............25 ft. lb. Hinges—Body Half and Gate H alf............................ 35 ft. lb. Support (Upper)-to-Support (Lower) . . . . 30 ft. lb. Support Assembly—Body to End Gate..................... 25 ft. lb. Torque Rod—Retainer Assembly...............................85 in. lb. Rear Bench (06, 14) Support-to-Seat............................................... 18 ft. lb. —Anchor Assembly...............................18 ft. lb. Support-to-Floor .............................................50 ft. lb. Latch Assembly to End G ate................................... 85 in. lb. Latch Control Assembly to End Gate ..................... 40 in. lb. Rear Bench (63) Access Cover.............................................................18 in. lb. Support-to-Seat.............................................150 in. lb. Handle to Latch Control Assembly..........................55 in. lb. Support-to-Floor .............................................35 in. lb. Glass Channel Assembly to End Gate .....................85 in. lb. Folding Rear Seat (06) Cap Assembly to Channel Assembly..........................24 in. lb. Support Asm-to-Floor................................... 150 in. lb. Striker—Body Mounted .......................................... 18 ft. lb. Seat-to-Support Asm........................................18 in. lb. LIGHT DUTY TRUCK SERVICE MANUAL V SPECIFICATIONS 3 BODY MOUNTING (C-K MODELS)-FT. LBS. Model (03) (06) (14) (63) #1 45 35 55 55 #2 45 35 45 35 #3 — — 35 55 #4 35 35 — #5 — — — - #6 35 — — G MODELS MIRRORS AND SUNSHADE SLIDING SIDE DOOR Inside Rear View Mirror to Bracket .....................15 in. lb. Outside Rear View Mirror to Panel..........................40 in. lb. Sunshade Support to Header Panel..........................15 in. lb. Remote Control (front latch) to Door..................... 90 in. lb. Rear Latch to D oor................................................. 90 in. lb. Rear Plate to Door ..................................................90 in. lb. Lower Front Roller and Roller Support Support-to-Door .............................................24 ft. lb. Support to Roller Bracket ...............................24 ft. lb. SIDE WINDOW (SWINGOUT) Roller to Roller Bracket................................... 20 ft. lb. Catch to Roller Bracket................................... 45 in. lb. Latch to Body...........................................................40 in. lb. Upper Front Roller Bracket Latch to Glass...........................................................40 in. lb. Bracket to D oor...............................................24 ft. lb. Hinge to Body...........................................................40 in. lb. Roller to Bracket.............................................20 ft. lb. Upper Left Hinge (Door Half) Hinge to D oor..................................................25 ft. lb. Upper Left Hinge (Body Half) FRONT SIDE DOORS Roller to Hinge..................................................20 ft. lb. Guide Block to Hinge........................................40 in. lb. Door Hinges.............................................................30 ft. lb. Lever Arm-to-Hinge Retaining Nut .............. 120 in. lb. Door Hinge Access Hole Cover ...............................18 in. lb. Lever Retaining Screw...................................... 40 in. lb. Door Lock Striker....................................................45 ft. lb. Striker to Body..................................................20 ft. lb. Door Lock to D oor................................................. 20 ft. lb. Rear Striker Bolt (Body Mounted)..........................45 ft. lb. Outside Door Handle...............................................45 in. lb. Front Striker Retaining Screws (Body Mounted) . . 90 in. lb. SEATS REAR DOOR Hinge Strap to Door................................................. 45 in. lb. Hinge Strap Bracket to Body................................... 45 in. lb. Hinge (to body and door)........................................30 ft. lb. Remote Control Retaining Screws ..........................85 in. lb. Latch-to-Door Retaining Screws.............................. 90 in. lb. Door Strikers-to-Body .............................................90 in. lb. Outside Door Handle...............................................45 in. lb. Seat Belt to S eat...................................................... 37 ft. lb. Passenger and Drivers Seat to Adjuster (Mounting Bracket) ..............18 ft. lb. Saat to R iser....................................................18 ft. lb. Seat Riser-to-Floor.......................................... 50 ft. lb. Bench Seats Seat to Seat Support........................................18 ft. lb. Seat Support to Floor Clamps..........................40 ft. lb. LIGHT DUTY TRUCK SERVICE MANUAL SPECIFICATIONS 4 FRONT SUSPENSION SECTION 3 * WHEEL ALIGNMENT SPECIFICATIONS + See Column 1, 2 or 3 under Vehicle Alignment Tolerances for applicable tolerances. See Page 3-15 for the proper m ethod of determining Caster Angle. See Page 3-15 Figure 20 for m ethod of determining Dimension “A ”, K - 10 with full time four wheel drive toe-in = 0". VEHICLE ALIGNMENT TOLERANCES tt Field Usage Caster................................. Camber............................... ............................ +1 1/2° T o e ................................... oo ±3/4° ±1° ±1/8” 1° 1° Column 2 CO Camber........................ Caster.......................... $ Toe-in.......................... Camber (Side to Side) . Caster (Side to Side) . . Column 3 @Service Reset VEHICLE INSPECTION TOLERANCES tt +1 Column 1 *Service Checking * @ $ ft CO 1 * ** + ff o h-* o to+ 0 CASTER ** Dimension “A” in inches + 2 1/2" 2 3/4” 3" 3 1/4” 3 1/2" 3 3/4" 4” 4 1/4" 4 1/2” 4 3/4” 5” GA10 - 30 +2 1/4° +2° +1 1/2° +1 1/4° +1° +3/4° +1/2° +1/4° 0° -1/4° -1/2° +1 1/2° +1 1/4° +1° +3/4° +1/2° + 1/4° 0° -1/2° CA PA 10 CA PA 20 - 30 +3/4° +1/2° +1/4° 0° -1/4° -1/2° +2° +11/2° +1 1/4° K10 - 20 +4° —no provision for resetting CAMBER CA GA PA 10 - 20 - 30 ................................................................................................................ + 1/4° KA 10-20.......................................................................................No provision for resetting + 1 1/2° TOE-IN (TOTAL) CA GA PA 10 - 20 - 30 K 10 - 20 ............................................................................................ 3/16”t t ± 1/2° ± 1/2° ± 1/16” 1/2° 1/2° Caster and Camber must not vary more than 1° from side to side. Caster and Camber must not vary more than 1/2° from side to side. Toe setting must always be made after caster and camber, See explanatory copy in front suspension section 3 Page 14. LIGHT DUTY TRUCK SERVICE MANUAL SPECIFICATIONS 5 FRONT SUSPENSION BOLT TORQUE (Ft. Lbs.) $ CP-10 Lower Control Arm Shaft U-Bolt 45 Upper Control Arm Shaft Nuts 70 Control Arm Rubber Bushings 140 New 160 Upper Control Arm Bushing Steel $$ Used 95 $$ New 280 Lower Control Arm Bushing Steel Used 130 Upper Ball Joint Nut *50 Lower Ball Joint Nut **90 65 Crossmember to Side Rail Crossmember to Bottom Rail 100 Stabilizer Bar to Control Arm 25 Stabilizer Bar to Frame 25 Shock Absorber Upper End 140 Shock Absorber Lower End 60 Brake Splash Shield to Knuckle 140 In. Lbs. Wheel Bearing Adjustment Zero Wheel Bearing Preload Wheel Bearing End Movement .001 - .008” Caliper Mounting Bolt 35 Spring - Front Eye Bolt Spring - Rear Eye Bolt — Spring - To Rear Shackle Bolt Spring - To Axle U-Bolt Spring - Front Hanger to Frame 15 Suspension Bumper — Stabilizer to Spring Plate * ** *** # $ $$ CP-20-30 85 120 — New 190 Used 115 New 280 Used 130 **90 **90 65 100 25 25 140 60 140 In. Lbs. — Zero .001 - .008” 35 — 15 — K-AII — — **100 ***80 — 65 65 65 Inner # - 35 Outer -50 Zero .001 - .010” 35 90 50 50 150 30 25 130 G-10 G 10-2045 70 140 w/Spacer 160 No Spacer 95 w/Spacer 280 No Spacer 130 ***120 65 100 G-20-30 G3085 155 140 w/Spacer 190 No Spacer 115 w/Spacer 280 No Spacer 130 ***120 ***215 100 100 25 25 75 75 140 In. Lbs. — Zero .001 - .008” 35 — — 15 - Plus additional torque to align cotter pin. Not to exceed 90 ft. lbs. maximum. Plus additional torque to align cotter pin. Not to exceed 130 ft. lbs. maximum. Plus additional torque to align cotter pin. Back nut off to align cotter pin at nearest slot. All specifications are given in foot pounds of Torque unless indicated otherwise. CIO, G10-20 Rubber Bushings; C20-30, G30, P i0-30 Steel Bushings. FOUR WHEEL DRIVE Axle Gear Backlash Preferred Min. and Max. New Pinion Bearing Preload Used Pinion Bearing Preload 5500# (Dana) .004” - .009” .004” - .009” in. lbs. 10-20 in. lbs. 20-40 Carrier Cover Ring Gear Differential Bearing Caps Filler Plugs Drive Pinion Nut Brake - Backing Plate Axle Shaft To Hub Bolts Bolt Torques (Ft. Lbs.) 35 110 85 10 255 35 60 LIGHT DUTY TRUCK SERVICE MANUAL SPECIFICATIONS 6 REAR SUSPENSION SECTION 4 TORQUE SPECIFICATIONS (FT. LBS.) WHEEL BEARING ADJUSTMENT SPECIFICATIONS Ring Gear Size B earing Adjusting Nut Torque* Adjusting Nut Back-off* Outer Locknut Torque 1 0 -1 /2 ” 50 Ft. Lbs. ** 65 Ft. Lbs. 1 2 -1 /4 ” 75-100 Ft. Lbs. 1/8 * 250 Ft. Lbs. Type of Bearing Tapered R oller B arrel R oller Resulting B earing Adjustm ent .001 to .010 End Play Slight Preloaded ** B ack-off nut and retighten to 35 Ft. Lbs. then, back-off nut 1 /4 turn. * With w heel rotating. UNIVERSAL JOINT ATTACHMENT TORQUE SPECIFICATIONS Strap Attachm ents „ . . . . . . . . . 15 Ft. Lbs. “ U” Bolt A ttachm ent......................... . . 20 Ft. Lbs. Lubricant Capacity 3.5 Pints 5.4 Pints 7.2 Pints 14.0 Pints Ring Gear Size 8 -7 /8 ” Chevrolet 1 0 -1 /2 ” Dana 1 0 -1 /2 ” 1 2 -1 /4 ” 1 0 -1 /2 ” C hevrolet H 1 Ha V* 7A a Ha 5/s 'h i *H ....................................... a "M 'H a * 7A a 3/ 4 ............................................ *% A 5'Aa ,3 /l6 2 7/ s Aa ....................................... GAGES GAGE NO. 0000000 000000 00000 0000 000 00 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 U. S. STANDARD GAGE* Approx. Thickness—Inches 0.490 .460 .429 .398 .368 .337 .306 .2757 .2604 .2451 ............................ .2 2 2 3 . .................... . .2145 .1991 .1838 .1685 .1532 .1379 .1225 .1072 .0919 .0766 .0689 .0613 .0551 .0490 .0429 .0368 .0337 .0306 .0276 .0245 .0214 .0184 .0169 .0153 .0138 .0123 .0107 .0100 .0092 .0084 .0077 .0069 .0065 .0061 .0057 .0054 .0052 .0050 .0048 .0046 & AMERICAN WIRE or B S GAGE Thickness—Inches 0.5800 .5165 .4600 .4096 .3648 .3248 .2893 .2576 .2294 .2043 .1819. .1620 .1443 .1285 .1144 .1019 .0907 .0808 .0720 .0641 .0571 .0508 .0453 .0403 .0359 .0320 .0285 .0253 .0226 .0201 .0179 .0159 .0142 .0126 .0113 .0100 .00893 .00795 .00708 .00630 .00561 .00500 .00445 .00397 .00353 .00314 ■/ V DRILL SIZES Wire Gage Sizes Drill Diam. inches Wire Gage Sizes Drill Diam. Inches Wire Gage Sizes Drill • % Diam. Inches Letter Sizes Drill Diam. Inches z 0.413 1 0.2280 28 0.1405 55 0.0520 Y 0.404 2 0.2210 29 0.1360 56 0.0465 X 0.397 3 0.2130 30 0.1285 57 0.0430 w 0.386 4 0.2090 31 0.1200 58 0.0420 V 0.377 5 0.2055 32 0.1160 59 0.0410 u 0.368 6 0.2040 33 0.1130 60 0.0400 T 0.358 7 0.2010 34 0.1110 61 0.0390 s 0.348 8 0.1990 35 0.1100 62 0.0380 R 0.339 9 0.1960 36 0.1065 63 0.0370 Q 0.332 10 0.1935 37 0.1040 64 0.0360 p 0.323 11 0.1910 38 0.1015 65 0.0350 0 0.316 12 0.1890 39 0.0995 66 0.0330 N 0.302 13 0.1850 40 0.0980 67 0.0320 M 0.295 14 0.1820 41 0.0960 68 0.0310 L 0.290 15 0.1800 42 0.0935 69 0.0292 K 0.281 16 0.1770 43 0.0890 70 0.0280 J 0.277 17 0.1730 44 0.0860 71 0.0260 1 0.272 18 0.1695 45 0.0820 72 0.0250 H 0.266 19 0.1660 46 0.0810 73 0.0240 G 0.261 20 0.1610 47 0.0785 74 0.0225 F 0.257 21 0.1590 48 0.0760 75 0.0210 E 0.250 22 0.1570 49 0.0730 76 0.0200 D 0.246 23 0.1540 50 0.0700 77 0.0180 C 0.242 24 0.1520 51 0.0670 78 0.0160 B 0.238 25 0.1495 52 0.0635 79 0.0145 A 0.234 26 0.1470 53 0.0595 80 0.0135 27 0.1440 54 0.0550 * ;• ---------