1988 PONTIAC FIERO relay

386-2 STEERING LINKAGE
LUBRICATION ADJUSTMENTS
The steering linkage should be lubricated with any
water resistant
EP type chassis lubricant at specified Toeein
intervals. Lubrication points and additional information on Adjust
the steering linkage for proper toe-in setting as
chassis lubrication can be found in Section
OB. outlined in Section 3A.
ON-CAR SERVICE 3. To remove outer ball stud, use a tool such as
RELAY ROD
Fig. 3B6-2--Series Linkage Components
TIE RODS
There are two tie rod assemblies. Each assembly is of
five piece construction, consisting of a sleeve, two clamps
and two tie rod ends. The ends are threaded into the sleeve
and locked with the clamps.
Right and left hand threads are
provided to facilitate toe-in adustment and steering gear
centering.
The tie rod ends are self-adjusting for wear and require
no attention in service other than periodic lubrication and
occasional inspection to see that ball studs are tight.
Tie rod adjuster components often become rusted
in
service. In such cases, it is recommended that if the torquc
required to remove the nut from thc bolt after break:iw:~>
exceeds 9 N.m (7 Ib, ft.), discard the nuts and bolth. Appl!
any penetrating oil betwoon thc clamp and tube ;~nd roliitc
the clamps until they movt. frcely. Install nc\4 bolts and nuts
having the same part number to assure proper clamping at
the specified nut torque.
Removal
I. qaise vehicle on hoiht.
2. Remove cotter pins and nuts from ball studs.
5-243 19-01, or 5-6627 as shown in Fig. 3B6-3
NOTICE: Do not attempt to disengage the joint by
driving a wedge between the joint and the knuckle,
because seal damage could result.
4. Remove inner ball stud from relay rod using same
procedure as described in Step 3.
5. To remove tie rod ends from tie rods, loosen clamp bolts
and unscrew end assemblies.
Installation
NOTICE: See NOTICE on page I of this section
regarding the fasteners referred to in step
4.
1. If the tie rod ends were removed, lubricate the tie rod
threads with any
EP type 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 the threads on the ball stud and in the
ball stud nuts are clean and smooth. If threads are not
clean and smooth, ball studs may turn in tie rod ends
when attempting to tighten nut. In addition tapered
surfaces should be clean and free from grease. Install
seals on ball studs.
3. Install ball studs in steering arms and relay rod.
4. Torque nuts to 48N.m (35 Ib. ft.). Then tighten nuts
enough to align the slot in the nut with the hole in the
stud. Install cotter pins. Lubricate tie rod
end\.
5. Lower vehicle to floor.
Fig. 3B6-3--Freeing Ball Stud

STEERING LINKAGE 386-3
ADJUSTER SLEEVE SLOT
HORIZONTAL
NOTE Slot Iri adjuster
sleeve must not be
w~th~n th~q area of
clamp laws.
ROTATION NOTE Must have mlnlmum slot
shown after torqulng tie rod
TIE ROD-INNER
RELAY ROD
CAUTION Clamp must be between & clear of d~mples before torqulng
TIE ROD-OUTER
NOTE Equal w~th~n three
threads, must be vis~ble at Inner and outer ends of adjuster sleeve when
assembled to steerlng
Torque Nuts 19 N m (14 Ft Lbs
Fig. 3B6-4--Tie Rod Clamp and Sleeve Orientation
6. Adjust toe-in as described in Section
3A. rod is carefully controlled to assure that the rod is at the
Before tightening the tie rod adjusting sleeve clamp Proper height. Both the left end and the right end of the
bolts, be sure that the following conditions have been met: relay
rod MUST be held at the same height. The side-to-
side height is controlled by adjusting the position of the idler
a. The sleeve clamps must be positioned between the
arm. locating dimples at either end of the sleeve.
Whenever disconnecting the relay rod assembly, it is
b. The
clalnps must be positioned within the angular important to first scribe the position of the idler arm-to- travel indicated in Figure 3B6-4 for the Proper fi.ame. and to rein4tall the idler arm in the same position.
vehicle.
Be w1.e to prevent the idler support hom turning in the
c. The relationship of the clamp slot with the slit in the
bu4hing. since that motion could result in improper relay
sleeve should be maintained as shown in Figure
3B6- rod height.
4. Whenever replacing the relay rod, or the idler arm, or
d. Both inner and outer tie rod ends must rotate for the pitman arm, it is mandatory to establish the correct
their full travel. The position of each tie rod end must height
by following the procedure shown
in Fig. 3B6-5.
be maintained as the clamps are tightened to ensure
free movement of each joint.
Removal
e. All procedures for alignment, adjustment and
assembly
~f tie rods applies to both left and right I. Raise vehicle hoist.
side. 2. Remove inner ends of tie rods from relay rod as
RELAY ROD described under Tie Rod - Removal.
During production, the installed position of the relay
3. Remove nut from relay rod ball stud attachment at

386-4 STEERING LINKAGE
DIMENSION "B"
Fig. 3B6-5--Setting Relay Rod Heighi
pitman arm.
4. Detach relay rod from pitman arm by using tool such as
5-24319-01. Shift steering linkage as required to free
pitman arm from relay rod.
5. Remove nut from idler arm and remove relay rod from
idler arm.
Installation
NOTICE: See NOTICE on page 1 of this section
regarding the fasteners referred to in steps
1, 2, 3 and
4.
1. Install relay
rod to idler arm, making certain idler stud
seal is in place. Use
5-29193 or 5-29194 as shown in
Fig. 3B6-6 to seat the tapers. A torque of
20 N.m is
required. With the tapers seated, remove the tool, then
.
install a prevailing torque nut, and tighten to 48 N.m
(35 ft. Ibs.).
2. Raise end of rod and install on pitman arm. Use
5-29193 or 3-29194 as shown in Fig. 3B6-6 to seat the
tapers. A torque of
20 N.m is required. With the tapers
seated, remove the tool, then install a prevailing torque
nut, and tighten to 48 N.111 (35 ft. Ibs.).
3. Install tie rod ends to relay rod as previously described
under Tie Rods. Lubricate tie rod ends.
4. ~nstall damper if equipped and torque to specifications.
5. Refer to3B6-5 for setting relay rod height.
6. Lower vehicle to floor
7. Adjust toe-in (see Section 3A) and align steering wheel
as described in Section
3B4 under Steering Wheel
Alignment and High Point Centering.
IDLER ARM
Use of the proper diagnosis and checking procedure is
essential to prevent needless replacement of good idler arms.
The proper checking procedure is as follows:
1. Raise the vehicle in such a manner as to allow the front'
Fig. 3B6-6--Special Tools Used to Seat the Tapers wheels to rotate freely and the steering mechanism
freedom to turn. Position the wheels in the-straight
ahead position.

STEERING LINKAGE 386-5
Fig. 3B6-7--Checking Idler Movement
2: As near the relay rod end of the idler arm as possible,
exert a 110 Newton
(25 pound) force upward and then
downward while noticing the total distance the end of '
the arm moves. This distance should not exceed a total
acceptable movement of
118 inch (Fig. 3B6-7). It is
necessary to ensure that the correct load is applied to
the arm since it will move more when higher loads are
applied. It is also necessary that a scale or ruler
be rested
against the frame and used to determine the amount of
movement because the actual movement can be over-
estimated when a scale is not used. The idler
arm should
always be replaced if it fails this test.
Jerking the right wheel and tire assembly back and
forth, thus causing an up and down movement of the idler
arm, is NOT an acceptable method of checking because
there is no control on the amount of force being applied.
Caution should be used in assuming shimmy
complaints are caused by loose idler arms. Before suspecting
suspension or steering components, technicians should
eliminate shimmy excitation factors, such as dynmamic
imbalance,
runout or force variation of wheel and tire
assemblies and road surface irregularities.
Removal
Refer to procedure for RELAY ROD REMOVAL,
and to Fig.
3B6-5 before removing idler arm.
1. Raise vehicle on hoist.
2. Remove idler arm to frame nuts, washers, and bolts.
3. Remove nut from idler arm to relay rod ball stud.
4. Remove relay rod from idler arm by using
5-24319-01
or similar puller.
5. Remove idler arm.
Installation
NOTICE: See NOTICE on page 1 of this section
regarding the fasteners referred to in steps
1 and 2.
I. Position idler arm on frame and LOOSELY install
mounting bolts, washers and nuts. 2.
Install relay rod to idler arm, making certain seal is on
stud. Use 5-29 193 or 5-29 194 as shown in Fig.
3B6-6 to
seat the tapers. A torque of 20
N.m is required. With
the tapers seated, remove the tool, then install a
prevailing torque nut, and tighten to
.48 N-m (35 ft.
Ibs.).
3. Follow the procedure in Fig. 3B6-5 to set the relay rod
height. Torque the idler arm-to-frame mounting
+Its
to specifications.
4. Lower vehicle to floor.
PITMAN ARM
Refer to procedure for RELAY ROD REMOVAL,
and to Fig.
3B6-5 before removing pitman arm.
Removal
1. Raise vehicle on hoist.
2. Remove nut from
pitman arm ball stud.
3. Remove relay rod from pitman arm by using a tool such
as
5-243 19-01. Pull down on relay rod to remove from
stud.
4. Remove pitman arm nut from pitman shaft and mark
relation of arm position to shaft.
5. Remove
pitman arm with Tool 5-5504 or Tool 5-6632,
as seen in Fig.
3B6-8. DO NOT HAMMER ON
PULLER.
Installation
. NOTICE: See NOTICE on page 1 of this section
regarding the fasteners referred to in steps 2 and
3.
1. Install pitman arm on pitman shaft, lining up the marks
made upon removal.
2. Install pitman shaft nut and torque to specifications.
3.
Pcrition relay rod on pitman arm. Use 5-29193 or
5-29194 as shown in Fig. 3B6-6 to seat the tapers. A
torque of 20
N.m is required. With the tapers seated,
remove the tool, then install a prevailing torque nut,
and tighten to 48 N.m (35 ft. Ibs.).
4. Follow the procedure in Fig.
3B6-5 to set the relay rod
height. Torque the idler arm-to-frame mounting bolts
to specifications.
5. Lower vehicle to floor.
Fig. 3B6-8--Removing Pitmon Arm I I

FRONT SUSPENSION 3C-1
SEC"T0RI 3C
FRONT SUSPENS
NOTICE: All front suspension fasteners are an important attaching part in that it could affect the
performance of vital parts and systems, and/or could result in major repair expense. They must be replaced with
one of the same part number or with an equivalent part if replacement becomes necessary. Do not use a
replacement part of lesser quality or substitute design. Torque values must be used as specified during reassembly
to assure proper retention of this part.
NOTICE: Never attempt to heat, quench or straighten any front suspension part. Replace it with a new part
or
damage to the part may result.
CONTENTS
General lnformation ....................................................................................................... 3C-I
On-Car Service ................................................................................................................... 3C- I
Specifications ..................................................................................................................... 3C- 10
GENERAL INFORMATION
The front suspension is designed to allow each
wheel to compensate for changes in the road surface ON-CAR SERVICE
level without appreciably affecting the opposite wheel. WHEEL BEARINGS
Each wheel is independently connected to the frame by
The proper functioning of the front suspension
a steering
kunckle, strut assembly, ball joint, and lower cannot be maintained unless the front wheel tapered arm. The steering in a roller bearings are correctly adjusted. The bearings
prescribed three dimensional arc. The front wheels are
must be a slip fit on the spindle and the inside diameter held in proper relationship to each other by two tie rods of the bearings should be lubricated to insure proper which are connected to steering arms on the knuckles ~h~ spindle nut must be a free-running fit and to the relay rod assembly.
on the threads.
Coil chassis springs are mounted between the
spring housings on the front crossmember and the
lower control arms. Ride control is provided by double,
direct acting strut assemblies. The upper portion of
each strut assembly extends through the fender well
and attaches to the upper mount assembly with a nut.
Side roll of the front suspension is controlled by
a spring steel stabilizer shaft. It is mounted in rubber
bushings which are held to the frame side rails by
brackets. The ends of the stabilizer are connected to the
lower control arms by link bolts and are isolated by
rubber grommets.
The inner ends of the lower control arms have
pressed in bushings. Bolts (passing through the
bushings) attach the arm to the suspension
crossmember. The lower ball joint assembly is a press
fit in the arm and attaches to the steering knuckle with
a torque prevailing nut.
Rubber grease seals are provided at ball socket
assemblies to keep dirt and moisture from entering the
joint and damaging bearing surfaces.
Adjustment
Figure 602
NOTICE: See NOTICE on Page 3C-1
of this
section.
1. Remove dust cap from hub.
2. Remove cotter pin from spindle and spindle nut.
3. Tighten the spindle nut to 16 Nsm (12 lb. ft.)
while turning the wheel assembly forward by
hand to fully seat the bearings. This will remove
any grease or burrs which could cause excessive
wheel bearing play later.
4. Back off the nut to the "just loose" position.
5. Hand tighten the spindle nut. Loosen spindle nut
until either hole in the spindle lines up with a slot
in the nut. Not
nlore than 1/2 flat.
6. Install
new cotter pin. Bend the ends of the cotter
pin against nut, cut off extra length to ensure ends
will not interfere with the dust cap.
7. Measure the looseness in the hub assembly. There
will be
from .03 to . l3mm (.001 to .005 inches)
end play when properly adjusted.
8. Install dust cap on hub.
FRONT SUSPENSION
Refer to Fig. 610 for illustration of attachment
provisions for the bolted-on front suspension
suspension
crossmember.

ENGINE COOLING 88.3
since a small oil pump driven by the separator plate
forces the silicone oil into a reservoir between the
separator plate and the front cover assembly. In this
position, the passage from this cavity to the clutch area
is closed by a slide valve. As operating conditions
produce a high radiator air temperature discharge,
above approximately 66°C
(150"F), the temperature
sensitive bi-metal coil tightens to move the slide valve
(attached to the coil) which opens a port in the
separator plate. This allows a flow of silicone oil into
the clutch chamber to engage the clutch, providing a
maximum fan speed of approximately 2200 rpm. The
clutch coil is calibrated so that, with a road load at an
ambient temperature of approximately 32°C
(90T), the
clutch is just at a point of shift between high and low
fan speed. No attempt should be made to disturb the
calibration of the engine clutch fan assembly as each
assembly is individually calibrated at the time of
manufacture. Under certain temperature conditions
there is a lateral movement at the fan tip which should
not be considered as a hub or bearing failure. This
condition is a design feature of the clutch assembly
which allows up to approximately
1/4" lateral
movement measured at the fan tip.
Testing a clutch fan by holding the small hub
with one hand and rotating the aluminum housing in
a
clockwise/counter-clockwise motion will cause the
clutch to freewheel, which is a normal condition when
operated in this manner. This should not be considered
a test by which replacement is determined.
Temperature Switch
This switch activates a warning lamp in the
instrument cluster if the engine overheats. With
optional instrumentation, a temperature gage replaces
the warning lamp and the temperature switch is
replaced with a transducer. See Section
8A for
Temperature Switch location and diagnosis.
Coolant Temperature Fan Switch
This switch regulates voltage to the coolant fan
relay, which operates the fan whenever the engine
coolant temperature exceeds 230"
F (110" C). For
location and diagnosis see Section 8A for Coolant
Temperature Fan Switch.
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
temperatures.
A wax pellet element in the thermostat
expands when heated and contracts when cooled. The
pellet element is connected through a piston to a valve.
When the pellet element is heated, pressure is exerted
against a rubber diaphragm which forces the valve to
open. As the pellet element 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. At this
point, coolant is allowed to circulate only throughout
the engine to warm it quickly and evenly.
As the engine warms, the pellet element expands
and the thermostat valve opens, permitting coolant to flow
through the radiator, where heat is dissipated
through the radiator walls. This opening and closing of
the thermostat permits enough coolant to enter the
radiator to keep the engine within operating limits.
Fig. 3 Pellet Type Thermostat
Coolant Recovery System
A recovery-type cooling system is standard on all
cars and is designed to maintain the engine at proper
operating temperatures. The recovery tank collects
coolant that expands with rising temperature and
would otherwise overflow from the system. When the
system temperature drops, the coolant is drawn from
the recovery tank back into the radiator by the suction
created by coolant contraction. The cooling system has
been filled at the factory with a high-quality, inhibited,
year-around coolant that meets the standards of
General Motors Specification 1825-M. This coolant
solution provides freezing protection to at least -37°C
(-34°F). It has been formulated to be used for two full
calendar years or
30,OO miles, whichever first occurs,
of normal operation without replacement, provided the
proper concentration of coolant is maintained.
DIAGNOSIS
The following diagnostic information covers
common problems and possible causes. When the
proper diagnosis is made the problem should be
corrected by part replacement, adjustment, or repair as
required. Refer to the appropriate section of the service
manual for these procedures.
SERVICE PROCEDURES
Cooling System Care
The radiator cap should not be removed to check
coolant level. Check the coolant level visually in the
"see-through" coolant recovery tank every time hood
is up. Level should be near "ADD" mark when the
system is cold. At normal operating temperature the
coolant level should increase to the "FULL" mark on
the recovery tank. Coolant should be added only to the
reservoir to raise level to the "FULL" mark. Use a
50/50 mixture of high-quality ethylene glycol
antifreeze and water for coolant additions.

ENGINE FUEL BC-1
SECTION 6C
NE FUEL
CONTENTS
General Description ..................................... 6C-1 Fuel
Cap ........................................................... 6C-3
.................................................. ............................................. Alcohol-In-Fuel 6C- 1 Fuel Filter Neck 6C-3
................... ............ Fuel Metering .................................................. 6C-2 Fuel Gage Sending Unit .. 6C-4
....................... ............................... Throttle Body Injection (TBI) .... 6C-2 Diagnosis ,. 6C-4 ................... Service
Procedures ............................................. 6C-4
Port Fuel Injection ...................................... 6C-2
Pressure Relief ........................................... 6C-4
Fuel Feed and Return Pipe
............................... 6C-2
Flow Test .................................................... 6C-4
Fuel Pipes (MPFI)
.......................................... 6C-3
Pressure Test - TBI ................................... 6C-4
Fuel and Vapor Hoses
....................................... 6C-3
Pressure Test - MPFI .................................... 6C-4
Fuel Pump ........................................................ 6C-3 ...................................................... Fuel Pump Relay .............................................. 6C-3 Fuel Tank 6C-4
Fuel Filter
......................................................... 6C-3 Accelerator Controls ...................................... 6C-5
Fuel Tank
....................................................... 6C-3
All new General Motors vehicles are certified by
the United States Environmental Protection Agency as
conforming to the requirements of the regulations for
the control of air pollution from new motor vehicles.
This certification is contingent on certain adjustments
being set to factory standards. In most cases, these
adjustment points either have been permanently
sealed and/or made inaccessible to prevent
indiscriminate or routine adjustment in the field. For
this reason, the factory procedure for temporarily
removing plugs, caps, etc., for purposes of servicing the
product must be strictly followed and, wherever
practicable, returned to the original intent of the
design.
GENERAL DESCRIPTION
All gasoline engines are designed to use only
unleaded gasoline. Unleaded gasoline must be used for
proper emission control system operation. Its use will
also minimize spark plug fouling and extend engine oil
life. Using leaded gasoline can damage the emission
control system and could result in loss of emission
warranty coverage.
All cars are equipped with an Evaporative
Emission System. The purpose of the system is to
minimize the escape of fuel vapors to the atmosphere.
Information on this system will be found in Section
6E2, or 6E3.
When working on the fuel system, there are
several things to keep in mind.
@ Any time fuel system is being worked on,
disconnect the negative battery cable
except for those tests where battery
Adhere to all Notices and Cautions.
Always keep a dry chemical (Class B) fire
extinguisher near the work area.
-
Always use a backup wrench when loosening or
tightening a screw couple fitting.
The torque on a screw fitting is
30 N-m (22 lb.
ft.).
Pipe is used on all MPFI, TPI, SFI, and TBI
applications. Fittings require the use of an
"0"
Ring. Replace all pipe with the same type of pipe
and fittings that were removed.
All fuel pipes must meet GM Specification
124-M, or its equivalent.
All fuel hoses must meet GM Specification
6163-M, or its equivalent.
Do not replace fuel pipe with fuel hose.
voltage is required.
@ On MPFI, TPI, SF1 and TBI systems, always A1cohol-ln-Fuel
relieve the line pressure before servicing any fuel Certain driveability complaints such as
system components. hesitation, lack of power, stall, no start, etc., may be
@ Do not repair the fuel system until you have read caused
by an excessive amount of alcohol-in-fuel. The
the copy and checked the illustrations relating to complaints
may be due to fuel system corrosion and
that repair. subsequent
fuel filter plugging, deterioration of rubber

ENGINE FUEL 6C.3
a Fuel feed and return pipes are secured to the
underbody with clamps and screw assemblies.
The pipes should be inspected occasionally for
leaks, kinks or dents.
e Follow the same routing as the original pipe.
e Pipes must be properly secured to the frame to
prevent chafing. A minimum of 6 mm
(1/4")
clearance must be maintained around a pipe to
prevent contact and chafing.
MPFl Fuel Pipes
Due to the fact that fuel pipes are under high
pressure, these systems require special consideration for service.
Many feed and return pipes use screw couplings
with
"0" Rings. Any time these fittings are loosened
to service or replace components, ensure that:
a A backup wrench is used while loosening and
tightening the fitting.
e Check all "0" rings at fitting locations (if
applicable) for cuts or any damage and replace
any that appear worn or damaged.
e Use correct torque when tightening fittings.
If pipes are replaced always use original
equipment parts, or parts that meet GM
specifications.
Fuel and Vapor Hoses
NOTICE: Fuel and vapor hoses are specially
manufactured. If replacement becomes necessary,
it is important to use only replacement hoses
meeting GM Specification 6163-M. These hoses
are identified with the words "Fluoroelastomer"
on them. Hoses not so marked could cause early
failure, or fail to meet emission standards.
e Do not use rubber hose within 4" of any part of
the exhaust system, or within
10" of the catalytic
converter.
FUEL PUMP
The electric fuel pump is in the fuel tank. The
tank has an outlet for a vapor return system. Any vapor
which forms is returned to the fuel tank along with hot
fuel through a separate line. This greatly reduces any
possibility of vapor lock by keeping cool fuel from the
tank constantly circulating through the fuel pump.
FUEL PUMP RELAY
To control fuel pump operation, a fuel pump
relay is used.
When the ignition switch is turned to "RUN"
position, the fuel pump relay activates the electric fuel
pump for
1.5 to 2.0 seconds to prime the injector(s). If
the ECM does not receive reference pulses from the
distributor after this time, the ECM signals the relay
to turn off the fuel pump. The relay will once again
activate the fuel pump when the
ECM receives
distributor reference pulses.
Fuel Filter
CAUTION: To reduce the risk of fire
and personal injury, it is necessary
to
relieve the fuel system pressure
before servicing fuel system
components. (See Fuel System
Pressure Relief.)
The inline filters can be found on the rear
crossmember of the vehicle. Always use a backup
wrench any time that the fuel filter is removed or
installed. Also make sure that a good
"0" Ring is used
at all screw couple locations. Torque on fittings is
30
N-m (22 lb. ft.).
FUEL TANK
The fuel tank is usually located under the rear of
the vehicle and a number of shapes and sizes are used
depending on the application.
The tank is held in place by two metal straps,
hinged (with a bolt through the hinge) and secured at
the opposite end with a nut and bolt assembly.
Anti-squeak pieces are used on top of the tank to
reduce rattles and other annoying noises.
The fuel tank, cap and lines should be inspected
for road damage, whch could cause leakage. Inspect
fuel cap for correct sealing and indications of physical
damage. Replace any damaged or malfunctioning
parts.
Before attempting service of any type on the fuel
tank, always
(1) remove negative battery cable from
battery, (2) place "no smoking" signs near work areas,
(3) be sure to have C02 fire extinguisher handy, (4)
wear safety glasses and
(5) siphon or pump fuel into an
explosion proof container.
Fuel Filler Gap
The fuel tank filler neck is equipped with a
screw-type cap. The threaded part of the cap requires
several turns counterclockwise to remove. The long
threaded area is designed to allow any remaining fuel
tank pressure to escape while the cap is being removed.
A built-in torque-limiting device prevents
overtightening. To install, turn the cap clockwise until
a clicking noise is heard. This signals that the correct
torque has been reached and the cap is fully seated.
N OTI G E: If a fuel filler cap requires replacement,
use only a cap with the same features. Failure to
use the correct cap can result in a serious
malfunction of the system.
Available on some models is an electric locking
fuel filler cap. Information on this option will be found
in Section
9E.
FUEL TANK FILLER NECK
To help prevent refueling with leaded gasoline,
the fuel filler neck on gasoline engine cars has a built-in
restrictor and deflector. The opening in the restrictor
will only admit the smaller unleaded gas nozzle spout,
which must be fully inserted to bypass the deflector.
Attempted refueling with a leaded gas nozzle or failure