tow SSANGYONG MUSSO 2003 User Guide

1G1-8 M162 ENGINE INTAKE & EXHAUST
Function Description A pneumatically actuated resonance flap (5) is located on the intake manifold, and will be opened and closed by load, whichoperates resonance flap according to engine and controlled by ECU and rpm.
1. Resonance flap closed (at idle/partial load : less than3,800/rpm) The switch valve (7) will be adjusted by ECU and resonance falp will be colosed. By increasing air flow passage throughdividing intaking air flow toward both air collection housing(8). This leads to a signficant increase in the torque in thelower speed range.
2. Resonance flap open (at full load : over 3,800/rpm) The switch valve (7) will not be adjusted by ECU andresonance falp (5) will be open. The colllected air in the aircollection housing (8) will not be divided and intaking airpassage will be shorten.

WHEEL ALIGNMENT 2B-9
GENERAL DESCRIPTION AND SYSTEM OPERATION
FOUR WHEEL ALIGNMENT CASTER Caster is the tilting 91 the uppermost point of the steering axis either forward or backward from the vertical when viewed from the side of the vehicle. A backward tilt is positive, and a forward tilt is negative. Caster influencesdirectional control of the steering but does not affect
tire wear. Weak springs or overloading a vehicle will affect
caster. One wheel with more positive caster will pull
toward the center of the car. This condition will cause the car to move or lean toward the side with the least
amount of positive caster. Caster is measured in degrees. CAMBER Camber is the tilting of the top of the tire from the vertical when viewed from the front of the vehicle. When thetires tilt outward, the camber is positive. When the tires tilt inward, the camber is negative. The camber angle is measured in degrees from the vertical. Camber
influences both directional control and tire wear.
If the vehicle has too much positive camber, the outside
shoulder of the tire will wear. If the vehicle has too much
negative camber, the inside shoulder of the tire will wear.
The first responsibility of engineering is to design safesteering and suspension systems. Each componentmust be strong enough to withstand and absorb extremepunishment. Both the steering system and the front and the rear suspension must function geometrically with thebody mass. The steering and the suspension systems require that the front wheels self-return and that the tire rolling effortand the road friction be held to a negligible force in orderto allow the customer to direct the vehicle with the least effort and the most comfort. A complete wheel alignment check should include
measurements of the rear toe and camber. Four-wheel alignment assures that all four wheels will be running in precisely the same direction. When the vehicle is geometrically aligned, fuel economy and tire life are at their peak, and steering andperformance are maximized. TOE
Toe-in is the turning in of the tires, while toe-out is the turning out of the tires from the geometric centerline or thrust line. The toe ensures parallel rolling of the wheels. The toe serves to offset the small deflections of the wheel support system which occur when the vehicle is rollingforward. The specified toe angle is the setting whichachieves 0 degrees of toe when the vehicle is moving. Incorrect toe-in or toe-out will cause tire wear and
reduced fuel economy. As the individual steering andsuspension components wear from vehicle mileage,
additional toe will be needed to compensate for the wear. Always correct the toe dimension last.

3A-22 FRONT DRIVE AXLE
Inspection of Ring Gear Tooth Contact Pattern Normal Contact Apply gear-marking compound (prussian blue / red lead) on the ring gear teeth. Rotate the ring gear and check the tooth contact pattern. Abnormal Contact
Tooth Contact pattern Possible CauseRemedy
1. Heel Contact
2. Toe Contact
3. Face Contact
4. Flank ContactInsufficient backlash (little)

Tooth can be damaged or broken under heavy load
Excessive backlash (much)
Drive pinion shaft is apart from the ring gear
Noise can be occurred
Insufficient backlash (much)
Gear contacts on the low flank
Gear can be damaged orworn
Noise can be occurred Adjust backlash(Decrease backlash)

Select proper shim(s) to move the drive pinion toward the ring gear (toward toe)
Adjust backlash(Increase backlash)
Select proper shim(s) to move the drive pinion against the ring gear (toward heel)
Adjust backlash(Increase pinion shim)
Move the drive pinion toward the ring gear (toward center of ring gear)
Adjust backlash(Decrease pinion shim)
Move the ring gear toward the drive pinion (toward ring gear center line)
Excessive backlash (little)

Noise can be occurred

REAR DRIVE AXLE 3D-15
Inspection of Ring Gear Tooth Contact Pattern Normal Contact Apply gear-marking compound (prussian blue / red lead) on the ring gear teeth. Rotate the ring gear and check the tooth contact pattern. Abnormal Contact
Tooth Contact pattern Possible CauseRemedy
1. Heel Contact
2. Toe Contact
3. Face Contact
4. Flank ContactInsufficient backlash (little)

Tooth can be damaged or broken under heavy load
Excessive backlash (much)
Drive pinion shaft is apart from the ring gear
Noise can be occurred
Insufficient backlash (much)
Gear contacts on the low flank
Gear can be damaged orworn
Noise can be occurred Adjust backlash(Decrease backlash)

Select proper shim(s) to move the drive pinion toward the ring gear (toward toe)
Adjust backlash(Increase backlash)
Select proper shim(s) to move the drive pinion against the ring gear (toward heel)
Adjust backlash(Increase pinion shim)
Move the drive pinion toward the ring gear (toward center of ring gear)
Adjust backlash(Decrease pinion shim)
Move the ring gear toward the drive pinion (toward ring gear center line)
Excessive backlash (little)

Noise can be occurred

5B-18 MANUAL TRANSMISSION
8. Remove the counter shaft thrust race and bearing.
9. Carefully remove the oiling funnel from the end of thecounter shaft.
10. Using a 10 mm wrench, remove the 10 bolts from the shift cover. Notice
For assembly, note the location of the two bolts.
11. Lift up the shift cover after sliding it toward the drain plug about 3 cm. At this time remove sealer bond.
12. Using a needle nose pliers, remove the 5-R lever clip.

5D2-4 TRANSFER CASE (TOD)FUNCTION DESCRIPTION
TOD System Select Mode (4H and 4L) 4H is the mode when drive normally of which gear ratio is 1:1 and 4L mode distributes power to front and rear wheels 50:50 of which gear ratio is 2.48:1.
TOD System Function (select 4H mode) TOD system controls clutch mechanism to comply with rotation in front and rear propeller shaft and if its difference exceeds the permissible range, corresponding power is distributed into front wheel through EMC (Electro-MagneticClutch). Hall effect sensor signals speed on front and rear propeller shafts going through with TOD control unit.
Transfercase clutch coil is activated by variable current on exceeding difference of speed in front and rear propeller shafts.
Function of 4L Mode When select 4L mode, EMC is locked to apply maximum torque into front and rear propeller shafts. Shift motor rotates also 4L position by rotation of cam thus propeller shaft torque changes from 1:1 to 2.48:1 by planetarygear set.
Shift Motor It locates backside transfer case, which drives rotary helical cam. When mode select switch changes to 4L, shift fork is on position for 2.48:1 by rotation of helical cam.
Transfer Case
TOD transfer case distributes power into front and rear axle by operation of 4H/4L switch and shift motor. Shifting 4H to 4L, is performed towards reducing HI-LO collar by means for connection HI-LO shift fork with
output shaft in order to join with planetary gear. Torque transmits input shaft then sun gear rotating front planetary
gear. Front planetary gear join with output shaft and drives LO position.

TRANSFER CASE (TOD) 5D2-15
DIAGNOSIS
While the TCCU is active it periodically monitors its inputs and outputs. If a fault is detected the “4WD CHECK ” lamp
is illuminated and a fault code is stored in the TCCU memory.
When requested, fault codes are downloaded to a diagnostic connector (K-line) serial communications using SCAN- 100. DIAGNOSTIC TESTS 1.TCCU Internal Function
When the Ignition is turned on the TCCU tests its ROM and RAM. If there is a fault, the TCCU immediately resets itself and re-tests the ROM and RAM. If the fault persists the TCCU continues to reset and re-test until the fault is corrected or the ignition is turned off. All TCCU functions are inhibited until the fault is corrected. The “4WD
CHECK ” lamp is not illuminated if there is a ROM or RAM fault.
If the ROM/RAM passes the EEPROM memory is tested. If there is a fault the “4WD CHECK ” lamp is illuminated
and the TCCU continues to operate using the default calibration data stored in ROM. Fault codes are not storedwhen there is an EEPROM fault.
An EEPROM fault can only be cleared by cycling ignition off-on.
2.Shift Motor Assembly Test If the TCCU detects a shift motor or position encoder fault continuously for one second the ‘4WD CHECK ” lamp is
turned on and the appropriate fault code is stored in memory.
a. A shift motor fault when the motor is off is defined as follows:
Motor H-L shorted to GroundMotor L-H shorted to GroundMotor open circuit
b. A shift motor fault when the motor is energized is defined as follows: Motor H-L shorted to GroundMotor L-H shorted to GroundMotor H-L shorted to Motor L-H Motor open circuit
c. A position encoder fault is defined as follows: Any position code which does not correspond to the valid 9 codes. A short to ground on any of the encoder lines.
d. If no shifts are in progress when a failure occurs the TCCU will not respond to any shift commands.
e. If a shift command has been received, but not acted upon when a failure occurs the TCCU will cancel the command and not respond to any subsequent shift commands.
f. If a shift command is in progress when an invalid position code is confirmed it will be halted and the TCCU will turn the motor toward the high position. Afterwards the TCCU will not respond to any shift commands.

TRANSFER CASE (TOD) 5D2-23
Error of signal in engine throttle position ; fault code 1715, 1716
Phenomenon
1. Upon diagnosis by SCAN-100, it display on 1715,
1716 codes.
Cause
1. Bad communication line between E/G ECU and CAN.
2. Defect of TOD control unit.
3. Defect of E/G ECU.
Check connection status of connector through CAN communication line.
1. Check connection of connector.
- Does connector connect correctly between TOD
control unit and E/G ECU?
2. In case of bad connection, connect correctly then
perform the follows ;
a . Delete the memorized fault code using SCANNER.
b. Ignition “OFF ”.
c. Ignition “ON ”.
d. Diagnose by SCANNER.
- Does it display fault codes “1715 ” or “1716 ”. Ye s
No
B1
Ye sNo
Check connection status of CAN communication line towards E/G ECU.
1. Ignition “OFF ”.
2. Disconnect 30 pin connector towards TOD control unit.
3. Measure resistance between pin No.22 and 23 in wiring connector using multi-tester.
- Specified value
- Measured value is within specified range?
B2
115-125
Ye s
No
Check connection status of CAN communication line towards TOD control unit.
1. Ignition “OFF ”.
2. Disconnect coupling of E/G ECU (gray, 1-60 pin).
3. Measure resistance between pin No.37 and 38 in coupling using multi-tester.
- Specified value
- Measured value is within specified range?
B3
115-125
Ye s
No
Test Stage / Contents
Result
Stage T est Contents and Procedure Specified Value
/Yes/No Countermeasure
Perform B2 stage Perform B1-2 stage Perform B2 stage Normal system
Perform B3 STAGE Perform B4 stage, check and replace E/ G ECU
Perform B5 STAGE Replace TOD control unit

TRANSFER CASE (TOD) 5D2-35
Removal & Installation Procedure1. Disconnect (-) cable from battery.
2. Lift on vehicle and make sure on safety. NoticeBe careful for catalytic converter due to high temperature after driving or engine running.
3. Prepare a vessel to drain transfer case and manual transmission oil.
4. Release drain plug and drain transfer case and manual transmission oil. If planar damper is installed, unscrew 4 bolts and remove
the planar damper. NoticeOil drain should be along with whole transfer case
disassembly and assembly.
5. Disconnect transmission extension wiring connector back
side transfer case. Notice
When disconnect connector, make sure on direction of locking tab towards inside.
6. Disconnect shift motor/clutch coil connect (Black 7 pin) connector upper backside.
7. Disconnect front and rear speed sensor connector (white 7 pin).
8. Disconnect speedometer sensor connector right upper side.
9. Disconnect breather tube front upper side transfer case (upper connecting point of transfer case and front propeller).
10. Prepare hydraulic jack and support transfer case assembly.

TRANSFER CASE (TOD) 5D2-47
Assembly Procedure Assembly
Before assembly, lubricate all parts with Automatic Transmission Fluid or equivalent.
1. If removed, drive the bearing into the front output case bore.Drive the bearing in staight, making sure it is not cocked in the bore. Install the internal snap ring that retains the bearing to the front case.
2. If removed, install the front yoke to flange seal in the front case bore.
3. If removed, install the yoke to flange seal into the mounting adapter bore.
4 Sun Gear
5 Thrust Plate
6 Input Shaft
7 Thrust Washer
8 Bearing
9 External Snap Ring
10 Internal Snap Ring
4. If the input shaft needle bearing and bushing were removed,
install a new bearing and bushing as detailed in the following steps: Press a new needle bearing, then a new bushing in the input shaft as follows:
a. Position the input shaft on Axle Bearing/Seal Plate or equivalent, and Pinion Bearing Cone Replacer as a
spacer.
b. Press a new needle bearing into the end of the input shaft until it seats in the input shaft.
c. Press in a new bushing.
5. The recessed face of the sun gear and the snap ring groove on the bearing outer race should be toward the rear of thetransfer case. The stepped face of the thrust washer shouldface toward the bearing.
Slide the sun gear, thr ust plate and thrust washer into
position on the input shaft. Press the bearing over the input shaft. Install the external snap ring to the input shaft.