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Mitsubishi Eclipse. Technical Information Manual (1994) - part 59

Rear Suspension

Bump

Toe-out

Rebound

Toe-in

Toe control arm

VARIATION IN TOE ANGLE ON TURNS

When the vehicle rolls as it makes a turn, the toe geometry
changes as shown by the characteristics curve at the left under
the effect of the toe control arm action. Also, under the side
forces that are generated during a turn, the toe angle of the
outer wheel changes in such a way that the toe-in state will
be maintained thanks to the balance in rigidity of the individual
arms’ bushings properly selected for that effect. These charac-

teristics allow the rear wheels to make directional changes

in phase with the front wheels (steered wheels) during a turn,

assuring better steering stability.

VARIATION IN TOE ANGLE BY SIDE FORCES

Since the side force acting on the tire causes the bushings
at both ends of the trailing arm to twist in an oblique direction,
point A in the illustration is caused to shift toward the center
of the vehicle. The force also acts on the bushings at both
ends of the lower arm in their diametric direction, and point
B is consequently displaced toward the center of the vehicle
by the amount equivalent to the total deflection of the two
bushings (at both ends of the lower arm). The force exerted

to the bushing of the toe control arm also acts in the diametric
direction as in the case of the lower arm bushings, but point
C is displaced toward the center of the vehicle only by the
amount equivalent to the one bushing’s deflection since point
C is a ball joint.
The amount of the displacement of these points are compared
below.

(Large

Point A Point B Point C (Small

displace-

ment)

Such being the displacement relationship of the three points,
a toe-in state is maintained even in side force conditions.

VARIATION IN TOE ANGLE BY REARWARD FORCE INPUT
Generally, when the vehicle goes over a projection on road
or when braking, rearward forces will act on the tires and a
toe-out condition will occur because of the resulting compliance
steer. The multi-link suspension, however, maintains a toe-in
state as shown at the left thanks to its proper arrangement
of the individual control arms even when the vehicle goes
over a bump or it is braked and its wheels are subject to
rearward forces.

Premium price

Items

Medium price

High price

AWD

FWD

Wheel

Tire size

89V

89H

Wheel type

Steel type

Aluminum type

Aluminum

Wheel size

14 x

Amount of wheel offset

mm (in.)

46 (1.8)

Tire inflation pressure

(psi.)

Front

220 (32)

Rear

200 (29)

Spear wheel

Tire size

Wheel size

Amount of wheel offset

mm (in.)

46 (1.8)

Tire inflation pressure

(psi.)

420 (60)

NOTE
(1)
(2)

Option
Option in combination with ABS

Power Steering

All models come standard with an engine speed
sensitive power steering system.

FEATURES

Engine speed sensitive power steering

Impact absorption mechanism

2. Supplemental Restraint System

Double-lip oil seals used in power cylinder

The

type steering wheel with SRS unit

is adopted on all models.

The steering system uses a vane oil

[For information on the SRS, refer to the “Interior

fluid flow control system.

Supplemental Restraint System

The steering gear and linkage system is highly

tion.]

reliable integral rack and pinion type which

tures light weight and compact size.

The steering column incorporates both a shock
absorbing mechanism and a tilt steering mecha-

nism.

SPECIFICATIONS

Items

Non-turbo

Turbo

Steering wheel maximum turns

2.41

Steering angle (vehicle in unladen)

Inner wheel

2”

Outer wheel

Steering gear and linkage

Integral type

Gear type

Rack and pinion

Gear ratio

(infinity)

Rack stroke

mm (in.)

124 (4.9)

Oil pump type

Vane type with fluid flow

control system

Displacement

control system

10.5

9.6

Relief set pressure

(psi.)

8.8 (1,277)

Steering wheel

pipe

Steering column assembly

<Non-Turbo>

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