1998 DODGE RAM 1500 torque

INTRODUCTION
TABLE OF CONTENTS
page page
VEHICLE IDENTIFICATION NUMBER
DESCRIPTION..........................1
VEHICLE EMISSION CONTROL INFORMATION
(VECI)
DESCRIPTION..........................2
BODY CODE PLATE
DESCRIPTION..........................3
INTERNATIONAL VEHICLE CONTROL &
DISPLAY SYMBOLS
DESCRIPTION - INTERNATIONAL SYMBOLS . . . 5
FASTENER IDENTIFICATION
DESCRIPTION..........................5FASTENER USAGE
DESCRIPTION - FASTENER USAGE.........8
THREADED HOLE REPAIR
DESCRIPTION - THREADED HOLE REPAIR....8
METRIC SYSTEM
DESCRIPTION..........................8
TORQUE REFERENCES
DESCRIPTION.........................10
VEHICLE CERTIFICATION LABEL
DESCRIPTION.........................11
VEHICLE IDENTIFICATION
NUMBER
DESCRIPTION
VIN CODING/LOCATIONS
The Vehicle Identification Number (VIN) plate is
located on the lower windshield fence near the left
a-pillar (Fig. 1). The VIN contains 17 characters that
provide data concerning the vehicle. Refer to the VIN
decoding chart to determine the identification of a
vehicle.
The VIN is also imprinted on the:
²Body Code Plate.
²Equipment Identification Plate.
²Vehicle Safety Certification Label.
²Frame rail.
To protect the consumer from theft and possible
fraud the manufacturer is required to include a
Check Digit at the ninth position of the VIN. The
check digit is used by the manufacturer and govern-
ment agencies to verify the authenticity of the vehi-cle and official documentation. The formula to use
the check digit is not released to the general public.
POSITION INTERPRETATION CODE = DESCRIPTION
1 Country of Origin 1 = Manufactured By DaimlerChrysler Corporation
3 = Manufactured By DaimlerChrysler De Mexico
2 Make D = Dodge
3 Vehicle Type 2 = Incomplete with Side Airbag
3 = Truck with Side Airbag
6 = Incomplete Less Side Airbag
7 = Truck Less Side Airbag
Fig. 1 VIN LOCATION
1 - DASH PANEL
2 - VIN CODE PLATE
DRINTRODUCTION 1

FASTENER USAGE
DESCRIPTION - FASTENER USAGE
WARNING: USE OF AN INCORRECT FASTENER
MAY RESULT IN COMPONENT DAMAGE OR PER-
SONAL INJURY.
Fasteners and torque specifications references in
this Service Manual are identified in metric and SAE
format.
During any maintenance or repair procedures, it is
important to salvage all fasteners (nuts, bolts, etc.)
for reassembly. If the fastener is not salvageable, a
fastener of equivalent specification must be used.
THREADED HOLE REPAIR
DESCRIPTION - THREADED HOLE REPAIR
Most stripped threaded holes can be repaired using
a Helicoilt. Follow the vehicle or Helicoiltrecommen-
dations for application and repair procedures.
METRIC SYSTEM
DESCRIPTION
The metric system is based on quantities of one,
ten, one hundred, one thousand and one million.
The following chart will assist in converting metric
units to equivalent English and SAE units, or vise
versa.
CONVERSION FORMULAS AND EQUIVALENT VALUES
MULTIPLY BY TO GET MULTIPLY BY TO GET
in-lbs x 0.11298 = Newton Meters (N´m) N´m x 8.851 = in-lbs
ft-lbs x 1.3558 = Newton Meters (N´m) N´m x 0.7376 = ft-lbs
Inches Hg (60É
F)x 3.377 = Kilopascals (kPa) kPa x 0.2961 = Inches Hg
psi x 6.895 = Kilopascals (kPa) kPa x 0.145 = psi
Inches x 25.4 = Millimeters (mm) mm x 0.03937 = Inches
Feet x 0.3048 = Meters (M) M x 3.281 = Feet
Yards x 0.9144 = Meters M x 1.0936 = Yards
mph x 1.6093 = Kilometers/Hr. (Km/h) Km/h x 0.6214 = mph
Feet/Sec x 0.3048 = Meters/Sec (M/S) M/S x 3.281 = Feet/Sec
mph x 0.4470 = Meters/Sec (M/S) M/S x 2.237 = mph
Kilometers/Hr.
(Km/h)x 0.27778 = Meters/Sec (M/S) M/S x 3.600 Kilometers/Hr.
(Km/h)
COMMON METRIC EQUIVALENTS
1 inch = 25 Millimeters 1 Cubic Inch = 16 Cubic Centimeters
1 Foot = 0.3 Meter 1 Cubic Foot = 0.03 Cubic Meter
1 Yard = 0.9 Meter 1 Cubic Yard = 0.8 Cubic Meter
1 Mile = 1.6 Kilometers
Refer to the Metric Conversion Chart to convert
torque values listed in metric Newton- meters (N´m).
Also, use the chart to convert between millimeters
(mm) and inches (in.) (Fig. 7).
8 INTRODUCTIONDR

TORQUE REFERENCES
DESCRIPTION
Individual Torque Charts appear within many or
the Groups. Refer to the Standard Torque Specifica-tions Chart for torque references not listed in the
individual torque charts (Fig. 8).
Fig. 8 TORQUE SPECIFICATIONS
10 INTRODUCTIONDR

SUSPENSION
TABLE OF CONTENTS
page page
WHEEL ALIGNMENT......................1
FRONT - INDEPENDENT FRONT SUSPENSION..8FRONT - LINK/COIL......................29
REAR.................................41
WHEEL ALIGNMENT
TABLE OF CONTENTS
page page
WHEEL ALIGNMENT
DESCRIPTION..........................1
OPERATION............................2
DIAGNOSIS AND TESTING - PRE-ALIGNMENT
INSPECTION..........................2
STANDARD PROCEDURE
STANDARD PROCEDURE - HEIGHT
MEASUREMENT - 4WD (LD)..............3
STANDARD PROCEDURE - HEIGHT
ADJUSTMENT - 4WD (LD)................3
STANDARD PROCEDURE - CAMBER AND
CASTER ADJUSTMENT..................4STANDARD PROCEDURE - TOE
ADJUSTMENT.........................4
STANDARD PROCEDURE - CAMBER,
CASTER AND TOE ADJUSTMENT..........4
STANDARD PROCEDURE - ALIGNMENT
LINK/COIL SUSPENSION.................5
SPECIFICATIONS
ALIGNMENT..........................6
SPECIAL TOOLS
WHEEL ALIGNMENT....................7
WHEEL ALIGNMENT
DESCRIPTION
NOTE: Suspension components with rubber/ure-
thane bushings should be tightened with the vehi-
cle at normal ride height. It is important to have the
springs supporting the weight of the vehicle when
the fasteners are torqued. If springs are not at their
normal ride position, vehicle ride comfort could be
affected and premature bushing wear may occur.
Wheel alignment involves the correct positioning of
the wheels in relation to the vehicle. The positioning
is accomplished through suspension and steering
linkage adjustments. An alignment is considered
essential for efficient steering, good directional stabil-
ity and to minimize tire wear. The most important
measurements of an alignment are caster, camber
and toe (Fig. 1).
CAUTION: Never attempt to modify suspension or
steering components by heating or bending.
Fig. 1 Wheel Alignment Measurements
1 - FRONT OF VEHICLE
2 - STEERING AXIS INCLINATION
3 - PIVOT POINT
4 - TOE-IN
DRSUSPENSION 2 - 1

angle while adjusting caster, move one pivot bolt of
the upper control arm in or out. Then move the other
pivot bolt of the upper control arm in the opposite
direction. Install special tool 8876 between the top of
the upper control arm bracket and the upper control
arm (on 1500 series 4X2 & 4X4). Install special tool
8876 between the bottom of the upper control arm
bracket pressing the tool against the frame and the
upper control arm (on 2500/3500 series 4X2) in order
to move the upper control arm outwards for proper
adjustment with the vehicle at normal ride height
(Fig. 3).
To increase positive caster angle, move the rear
position of the upper control arm inward (toward the
engine). Move the front of the upper control arm out-
ward (away from the engine) slightly until the origi-
nal camber angle is obtained using special tool 8876
to move the upper control arm for proper adjustment.
(Fig. 3)
CAMBER
Move both pivot bolts of the upper control arm
together in or out. This will change the camber angle
significantly and little effect on the caster angle
using special tool 8876 to move the upper control
arm for proper adjustment. (Fig. 3)
After adjustment is made tighten the upper control
arm nuts to proper torque specification.
TOE ADJUSTMENT
The wheel toe position adjustment is the final
adjustment.
(1) Start the engine and turn wheels both ways
before straightening the wheels. Secure the steering
wheel with the front wheels in the straight-ahead
position.
(2) Loosen the tie rod jam nuts.
NOTE: Each front wheel should be adjusted for
one-half of the total toe position specification. This
will ensure the steering wheel will be centered
when the wheels are positioned straight-ahead.
(3) Adjust the wheel toe position by turning the
inner tie rod as necessary (Fig. 4).
(4) Tighten the tie rod jam nut to 75 N´m (55 ft.
lbs.).
(5) Verify the specifications
(6) Turn off engine.
STANDARD PROCEDURE - ALIGNMENT
LINK/COIL SUSPENSION
Before each alignment reading the vehicle should
be jounced (rear first, then front). Grasp each
bumper at the center and jounce the vehicle up and
down several times. Always release the bumper inthe down position.Set the front end alignment to
specifications while the vehicle is in its NOR-
MALLY LOADED CONDITION.
CAMBER:The wheel camber angle is preset and
is not adjustable.
CASTER:Check the caster of the front axle for
correct angle. Be sure the axle is not bent or twisted.
Road test the vehicle and make left and right turn.
Observe the steering wheel return-to-center position.
Low caster will cause poor steering wheel returnabil-
ity.
Caster can be adjusted by rotating the cams on the
lower suspension arm (Fig. 5).
TOE POSITION:The wheel toe position adjust-
ment should be the final adjustment.
Fig. 4 TIE ROD END
1 - JAM NUT
2 - TIE ROD - INNER
3 - TIE ROD END - OUTER
Fig. 5 ALIGNMENT ADJUSTMENT CAM
1 - BRACKET REINFORCEMENT
2 - ADJUSTING BOLT
3 - ADJUSTMENT CAM
DRWHEEL ALIGNMENT 2 - 5
WHEEL ALIGNMENT (Continued)

FRONT - INDEPENDENT FRONT SUSPENSION
TABLE OF CONTENTS
page page
FRONT - INDEPENDENT FRONT SUSPENSION
DESCRIPTION
DESCRIPTION........................9
DESCRIPTION........................10
SPECIFICATIONS
TORQUE CHART......................10
SPECIAL TOOLS
FRONT SUSPENSION..................12
BUSHINGS
REMOVAL
REMOVAL - LOWER CONTROL ARM
BUSHINGS - 4WD (LD).................13
REMOVAL - TORSION BAR
CROSSMEMBER BUSHING..............13
REMOVAL - LOWER CONTROL ARM
BUSHINGS - 2WD (LD).................13
INSTALLATION
INSTALLATION - LOWER CONTROL ARM
BUSHINGS - 4WD (LD).................14
INSTALLATION - TORSION BAR CROSS
MEMBER BUSHING....................15
INSTALLATION - LOWER CONTROL ARM
BUSHINGS - 2WD (LD).................15
HUB / BEARING
REMOVAL
REMOVAL - 4X4......................16
REMOVAL - 4X2......................17
INSTALLATION
INSTALLATION - 4X4...................17
INSTALLATION - 4X2...................18
KNUCKLE
DESCRIPTION.........................18
OPERATION...........................18
REMOVAL.............................18
INSTALLATION.........................19
LOWER BALL JOINT
DIAGNOSIS AND TESTING - LOWER BALL
JOINT..............................19
REMOVAL.............................19
INSTALLATION.........................20
LOWER CONTROL ARM
REMOVAL
REMOVAL - 4X4 (LD)...................21REMOVAL - 4X2......................21
INSTALLATION
INSTALLATION - 4X4 (LD)...............21
INSTALLATION - 4X2...................22
SPRING
REMOVAL.............................22
INSTALLATION.........................23
SHOCK
DIAGNOSIS AND TESTING - SHOCK........24
REMOVAL
REMOVAL - 4X2......................24
REMOVAL - 4X4......................24
INSTALLATION
INSTALLATION - 4X2...................24
INSTALLATION - 4X4...................24
STABILIZER BAR
DESCRIPTION.........................24
OPERATION...........................25
REMOVAL.............................25
INSTALLATION.........................25
STABILIZER LINK
REMOVAL
REMOVAL - 4X4......................25
REMOVAL - 4X2......................25
INSTALLATION
INSTALLATION - 4X4...................26
INSTALLATION - 4X2...................26
TORSION BAR
DESCRIPTION.........................26
OPERATION...........................26
REMOVAL.............................26
INSTALLATION.........................27
UPPER BALL JOINT
DIAGNOSIS AND TESTING - UPPER BALL
JOINT..............................27
UPPER CONTROL ARM
REMOVAL.............................28
INSTALLATION.........................28
2 - 8 FRONT - INDEPENDENT FRONT SUSPENSIONDR

FRONT - INDEPENDENT
FRONT SUSPENSION
DESCRIPTION
DESCRIPTION
The front suspension is designed to allow each
wheel to adapt to different road surfaces indepen-
dently. The wheels are mounted to hub/bearings
units bolted to the steering knuckle. The double-row
hub bearings are sealed and lubricated for life. The
steering knuckles turn (pivot) on ball joints.
The front suspension is comprised of (Fig. 1) (Fig.
2):
²Shock absorbers
²Torsion bar - 4X4 (LD only)
²Coil Spring - 4X2
²Control arms
²Steering knuckles
²Stabilizer bar
²Stabilizer link
²Tie Rod Ends
²Hub/Bearing
²Rack & Pinion
²Ball Joints
NOTE: Components attached with a nut must be
torqued to specification.
NOTE: Suspension components with rubber/ure-
thane bushings should be tightened with the vehi-
cle at normal ride height. It is important to have the
springs supporting the weight of the vehicle when
the fasteners are torqued. If springs are not at their
normal ride position, vehicle ride comfort could be
affected and premature bushing wear may occur.
Fig. 1 FRONT SUSPENSION - 4X2
1 - STABILIZER BAR
2 - UPPER CONTROL ARM
3 - STEERING KNUCKLE
4 - ROTOR
5 - CALIPER ADAPTER
6 - OUTER TIE ROD END
7 - STABILIZER LINK
8 - LOWER CONTROL ARM
9 - RACK & PINION
10 - COIL SPRING
11 - SHOCK ABSORBER
DRFRONT - INDEPENDENT FRONT SUSPENSION 2 - 9

DESCRIPTION
The upper control arm bolts on frame brackets.
The frame brackets have slotted holes which allow
the arms to be adjusted for caster and camber.
The lower control arms bolt to the lower frame
brackets and pivots through bushings.
The control arms have lube for life ball studs. The
control arm travel (jounce) is limited through the use
of rubber/urethane bumpers. Rebound travel is lim-
ited by the shock absorber.
SPECIFICATIONS
TORQUE CHART
TORQUE SPECIFICATIONS
DESCRIPTION N´m Ft. Lbs. In. Lbs.
Shock Absorber
Upper Nut
4X454 40 Ð
Shock Absorber
Lower Bolt
4X4135 100 Ð
Shock Absorber
Upper Nut
4X254 40 Ð
Shock Absorber
Lower Bolt
4X228 21 Ð
Fig. 2 FRONT SUSPENSION - 4X4 (LD ONLY)
1 - STABILIZER BAR
2 - UPPER CONTROL ARM
3 - STEERING KNUCKLE
4 - ROTOR
5 - OUTER TIE ROD END
6 - SHOCK ABSORBER
7 - STABILIZER LINK
8 - LOWER CONTROL ARM
9 - INNER TIE ROD
10 - RACK & PINION
2 - 10 FRONT - INDEPENDENT FRONT SUSPENSIONDR
FRONT - INDEPENDENT FRONT SUSPENSION (Continued)