1985 FORD GRANADA stop start

6If necessary, dismantle the automatic choke
unit (see illustration).
7Refitting is a reverse of the removal
procedure noting the following points.
a)Ensure that the pull-down diaphragm is
correctly seated prior to refitting the cover.
b)Ensure that the O-ring is correctly seated
in the choke housing prior to refitting.
c)With the choke housing installed check
and, if necessary, adjust the vacuum pull-
down diaphragm.
d)Refit the heat shield ensuring that the hole
in the shield engages with choke housing
peg.
e)Engage the bi-metal spring with the choke
lever and refit the bi-metal housing. Align
the marks made, or noted, on removal and
securely tighten the housing retaining
screws.
f)On completion check and, if necessary,
adjust the fast idle speed.
Vacuum pull-down adjustment
8This procedure is as described in Section 18,
referring to the Specifications at the start of this
Chapter for the specified pull-down setting.
Fast idle speed adjustment
9Check the idle speed and mixture adjustment
as described earlier in this Chapter and leave
the tachometer connected. Note that the idle
speed must be correct before attempting to
check or adjust the fast idle speed.
10Warm the engine up to normal operating
temperature and remove the air cleaner.
11Partially open the throttle valve then close
the choke valve until the fast idle adjustment
screw is positioned on the third (middle) step
of the fast idle cam(see illustration)and
release the throttle valve.
12Start the engine without touching the
throttle pedal and check that the engine speed
is within the speed range given in the
Specifications at the start of this Chapter.
13If this is not the case, adjust the engine
speed by rotating the fast idle adjusting screw
until the speed is within the specified range.
Operate the throttle pedal and check that the
engine returns to the specified idle speed.
14Stop the engine then disconnect the
tachometer and refit the air cleaner.1Disconnect the battery negative lead.
2Remove the air cleaner assembly.
3Disconnect the throttle kicker vacuum hose.
4Withdraw the plastic shield from the throttle
kicker(see illustration).
5Remove the two securing screws, then
disconnect the operating rod from the throttle
linkage, and withdraw the assembly from the
carburettor.
6The assembly can be dismantled by
removing the four securing screws and lifting
off the diaphragm cover. Recover the spring.
7Carefully withdraw the diaphragm and the
operating rod assembly from the housing.
Examine the condition of the diaphragm, and
renew it if necessary.
8Clean the mating faces of the housing and
the diaphragm cover.9Commence reassembly by inserting the
diaphragm and operating rod assembly into
the housing.
10Refit the spring, and the cover, ensuring
that the spring is correctly located, and tighten
the securing screws progressively to avoid
distorting the diaphragm.
11Further refitting is a reversal of removal,
but before refitting the plastic shield, check
the throttle kicker adjustment as described in
the following paragraphs.
Adjustment
12Warm the engine up to normal operating
temperature, and check the idle speed and
mixture settings as described earlier in this
Chapter.
13Remove the air cleaner assembly.
14Withdraw the plastic shield from the
throttle kicker, if not already done.
15Disconnect the throttle kicker vacuum
hose, and connect the throttle kicker directly
to the inlet manifold using a length of tubing.
27Weber 2V TLD carburettor -
throttle kicker removal, refitting
and adjustment
Fuel and exhaust systems 4•13
4
26.11 Fast idle speed adjustment - Weber
2V TLD carburettor
A Fast idle cam
B Fast idle screw shown on middle step of cam26.6 Exploded view of the automatic choke mechanism - Weber 2V TLD carburettor
A Upper choke operating link
B Fast idle cam return spring
C Spindle sleeveD Connecting rod and lever assembly
E Pulldown link
F Actuating lever
27.4 Throttle kicker assembly - Weber 2V TLD carburettor
1 Fuel inlet
2 Choke plate
3 Accelerator pump cover
4 Throttle kicker pivot lever5 Plastic cover
6 Throttle kicker
7 Secondary throttle valve vacuum
diaphragm
procarmanuals.com

16Start the engine and note the engine
speed (rpm). The engine speed should
increase above the normal idle speed, and
should be as given in the Specifications.
17If the engine speed is not as specified,
remove the tamperproof plug from the top of
the throttle kicker housing, and turn the
adjustment screw to give the specified speed.
18On completion of adjustment, fit a new
tamperproof cap.
19Disconnect the tubing from the inlet
manifold, and reconnect the throttle kicker
vacuum hose.
20Refit the plastic shield and the air cleaner.
On 2.4 & 2.9 litre V6 models especially,
residual pressure will remain in the fuel lines
long after the vehicle was last used therefore
the fuel system must be depressurised before
any hose is disconnected; the system is
depressurised via the vent valve on the fuel
rail, noting that it may be necessary to depress
the valve several times before the pressure is
fully released. As an added precaution place a
rag over the valve as it is depressed to catch
any fuel which is forcibly expelled. Before
carrying out any operation on the fuel system
refer to the precautions given in Safety first! at
the beginning of this Manual and follow them
implicitly. Petrol is a highly dangerous and
volatile liquid and the precautions necessary
when handling it cannot be overstressed.
Access to the relays is obtained by
removing the facia top cover (crash pad).
The relays are located on the passenger
side(see illustration). Also see Chapter 13,
Section 16.
See Chapter 1, Section 41.
SOHC and 2.8 litre V6 engines
1Idle speed is controlled by the EEC IV
module and no direct adjustment is possible.
2Idle mixture adjustment should not be
necessary on a routine basis. After component
renewal or a similar circumstance it may be
checked and adjusted as follows.
3The engine must be at operating temperature.
The valve clearances must be correct, the air
cleaner element must be clean and the ignition
system must be in good condition.
4Connect an exhaust gas analyser (CO
meter) and a tachometer (rev. counter) to the
engine as instructed by their makers.
5Run the engine at 3000 rpm for 15 seconds,
then allow it to idle. Repeat the procedure
every 60 seconds until adjustment is
complete.
6With the engine idling after the 3000 rpm
burst, record the CO level when the reading
has stabilised. The desired value is given in the
Specifications.
7If adjustment is necessary, remove the
tamperproof plug from the mixture adjusting
screw on the underside of the vane airflow
meter (see illustration).
8On V6 models, note that adjustment should
first be carried out on the front airflow meter.The rear meter should only be adjusted if the
range of adjustment on the front meter is
insufficient.
9Turn the mixture adjusting screw with a
hexagon key until the CO level is correct (see
illustration).
10Stop the engine and disconnect the test
gear.
11Fit a new tamperproof plug if required.
DOHC engine
Note: Before carrying out any adjustments
ensure that the ignition timing and spark plug
gaps are as specified. To carry out the
adjustments, an accurate tachometer and an
exhaust gas analyser (CO meter) will be
required.
12Idle speed is controlled by the EEC IV
module, and manual adjustment is not possible,
although the “base” idle speed can be adjusted
by a Ford dealer using special equipment.
13On models with a catalytic converter, the
mixture is controlled by the EEC IV module,
and no manual adjustment is possible.
14On models without a catalytic converter,
the idle mixture can be adjusted as follows.
15Run the engine until it is at normal
operating temperature.
16Stop the engine and connect a tachometer
and an exhaust gas analyser in accordance
with the manufacturer’s instructions.
17Start the engine and run it at 3000 rpm
for 15 seconds, ensuring that all electrical
loads (headlamps, heater blower, etc) are
switched off, then allow the engine to idle, and
check the CO content. Note that the reading
will initially rise, then fall and finally stabilise.
18If adjustment is necessary, remove the
cover from the mixture adjustment
potentiometer (located on the right-hand side
of the engine compartment, behind the MAP
sensor), and turn the screw to give the
specified CO content (see illustration).
19If adjustment does not produce a change
in reading, the potentiometer may be at the
extreme of the adjustment range. To centralise
the potentiometer, turn the adjustment screw
20 turns clockwise followed by 10 turns anti-
clockwise, then repeat the adjustment
procedure.
31Fuel-injection system - idle
speed and mixture adjustment
30Fuel filter - renewal
29Fuel-injection system relays -
location
28Fuel-injection system -
depressurisation
4•14Fuel and exhaust systems
31.18 Remove the cover from the mixture
adjustment potentiometer31.9 Idle mixture adjustment - fuel-injection
models
29.2 Fuel injection system relays - 2.4 and
2.9 litre V6 engines
A Power relayB Fuel pump relay
31.7 Tamperproof plug (arrowed) covering
mixture adjusting screw
Airflow meter is inverted for photo
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20Checking and adjustment should be
completed within 30 seconds of the meter
readings stabilising. If this has not been
possible, run the engine at 3000 rpm for 15
seconds, then allow the engine to idle. Re-
check the CO content and carry out further
adjustments if necessary.
21On completion of adjustment, stop the
engine and disconnect the tachometer and the
exhaust gas analyser. Refit the cover to the
adjustment screw.
2.4 & 2.9 litre V6 engines
22As with the 2.8 V6, idle speed is
electronically controlled. Basic idle speed
adjustment can only be carried out by a Ford
dealer using special equipment.
23On models not equipped with a catalytic
converter, mixture adjustment can be carried
out as described above.
24On models equipped with a catalytic
converter, the mixture is controlled by the EEC IV
module and no manual adjustment is possible.
SOHC and V6 engines
1Disconnect the battery negative lead.
2Free the throttle position sensor multi-plug
from its clip. On the OHCmodels this is below
the idle speed control valve, on the underside
of the inlet manifold; on V6 engines it is
located below the throttle valve housing.
3Relieve the locktabs and unbolt the throttle
position sensor (see illustration). Pull the
sensor off the throttle valve shaft, disconnect
the multi-plug and remove the sensor.
4Do not rotate the centre part of the sensor
beyond its normal range of movement, or
damage may result.
5When refitting, line up the flat on the throttle
valve shaft with the flat on the centre of the
sensor. Make sure that the sensor is the right
way round and fit it over the shaft.
6Fit and tighten the two bolts and secure it
with the locktabs.
7Reconnect and secure the multi-plug, then
reconnect the battery.
DOHC engine
8Disconnect the battery negative lead.
9Free the throttle position sensor wiring plug
from the retaining clip located on the
underside of the throttle body. Disconnect the
wiring plug halves by releasing the locktabs
and pulling on the plug halves, not the wiring
(see illustration).
10Unscrew the two sensor securing screws,
and withdraw the sensor from the throttle
shaft.
11Refitting is a reversal of removal, noting
that the sensor fits with the wiring at the
bottom, and ensuring that the sensor
actuating arm engages correctly with the
throttle spindle.1On DOHC models, disconnect the battery
negative lead.
2Free the throttle position sensor wiring plug
from the retaining clip located on the
underside of the throttle body. Disconnect the
wiring plug halves by releasing the locktabs
and pulling on the plug halves, not the wiring.
3Disconnect the throttle cable and (where
necessary) the speed control cable from the
throttle linkage.
4Loosen the securing clip, and disconnect
the air inlet hose from the throttle body.
5Unscrew the four securing bolts and
withdraw the throttle body from the inlet
manifold along with the gasket.
6Refitting is a reversal of removal, bearing in
mind the following points.
a)Ensure that the mating faces of the
throttle body and the inlet manifold are
clean, and fit a new gasket.
b)On completion, adjust the throttle cable
and where necessary, adjust the speed
control cable so that there is only a small
amount of slack in the cable.
c)Where applicable, check and if necessary
adjust the idle mixture.
SOHC and all V6 engines
1Disconnect the battery negative lead.
2Disconnect the multi-plug from the idle
speed control valve by prising up the retaining
lug and pulling the plug, not the wires (see
illustration).
3Remove the two securing nuts (OHC) or
bolts (V6) and withdraw the valve (see
illustration). Recover the gasket.
4If necessary, the solenoid can be separated
from the valve block by removing the two
screws to enable the parts to be cleaned.
Contamination or air leaks in this area will
cause unstable idling. After careful cleaning,
the parts can be reassembled.
5Refit the valve, using a new gasket, and
tighten the retaining nuts or bolts. Reconnect
the multi-plug and the battery.
6Start the engine and check that the idle is
steady. Bring the engine to operating
temperature, then switch on all possible electrical
loads (headlights, heated screens, heater blower
etc) and check that the idle remains steady. This
confirms that the valve is working.
DOHC engine
7Disconnect the battery negative lead.
8Loosen the securing clip, and disconnect
the air inlet hose from the throttle body.
34Idle speed control valve -
removal and refitting33Throttle body - removal and
refitting
32Throttle position sensor -
removal and refitting
Fuel and exhaust systems 4•15
4
32.3 Throttle position sensor retaining bolts
(arrowed)32.9 Throttle position sensor (A) and wiring
plug (B)
34.2 Disconnecting the idle speed control
valve34.3 Removing the idle speed control valve
procarmanuals.com

55Release the throttle position sensor wiring
connector from the clip under the throttle
body, and separate the two halves of the
connector.
56Remove the fuel-injectors.
57Check that all relevant wiring, hoses and
pipes have been disconnected to facilitate
removal of the manifold.
58Unscrew the ten bolts and two nuts
securing the inlet manifold to the cylinder
head, and carefully withdraw the manifold.
Recover the gasket.
59Recover the two plastic spark plug
spacers from the recesses in the cylinder head
(see illustration).
60If desired, the manifold can be dismantled
with reference to the relevant paragraphs of
this Chapter.
61Refitting is a reversal of removal, bearing
in mind the following points.
a)Ensure that the spark plug spacers are in
position in the cylinder head recesses
before refitting the manifold.
b)Ensure manifold and cylinder head mating
surfaces are clean and dry and fit a new
gasket.
c)Tighten the manifold retaining nuts and
bolts evenly and progressively to the
specified torque.
d)Refit the fuel-injectors.
e)Make sure that all hoses, pipes and wires
are securely reconnected in their original
positions.
f)On completion, refill the cooling system.
g)Check the adjustment of the throttle cable
and where necessary, adjust the speed
control cable so that only a small amount
of slack is present in the cable.
h)Where applicable, check and if necessary
adjust the idle speed and mixture.
V6 engines
62Disconnect the battery negative lead.
63Drain the cooling system.
64Remove the throttle linkage cover.
65Release the hose clips and move the
airflow meter-to-manifold trunking aside.
Unclip or remove the crankcase ventilation
hose.
66Disconnect the radiator top hose and the
heater hose from the outlet at the front of the
manifold. Be prepared for some coolant spillage.67Disconnect the multi-plugs from the idle
speed control valve, the temperature gauge
sender unit; the coolant temperature sensor
and the throttle position sensor. Also
disconnect the injector wiring harness.
68Disconnect the throttle cable from the
linkage, unclip it and move it aside. On
automatic transmission models, also
disconnect the downshift cable or multi-plug,
as applicable.
69Disconnect the fuel feed and return pipes.
Be prepared for fuel spillage.
70Remove the HT leads and the distributor.
71Remove the plenum chamber, which is
secured by eight bolts.
72Remove the rocker covers, which are each
secured by seven bolts.
73Disconnect the water pump bypass hose
from the inlet manifold.
74Remove the eight bolts which secure the
inlet manifold to the cylinder heads.
75Lift off the manifold complete with fuel
pressure regulator, fuel rail, throttle body
housing etc. If it is stuck, carefully lever it free.
Do not apply leverage at the mating faces.
Recover the gasket.
76Clean all mating faces, being careful to
keep dirt out of ports and other orifices.
Obtain new gaskets for both the cylinder head
and plenum chamber sides of the manifold,
and for the rocker covers.
77Commence refitting by applying sealant
(Ford part No A70X-19554-BA, or equivalent)
around the ports and coolant passages on the
cylinder head.
78Apply sealant around the apertures on
both sides of the gasket. then fit the gasket to
the cylinder heads.
79Refit the manifold and insert the securing
bolts. Tighten the bolts, in the order shown
(see illustration),through the first four stages
given in the Specifications.
80Refit the water pump bypass hose.
81Refit the rocker covers, using new
gaskets. The adhesive sides of the gaskets
must face the covers.
82Reverse the remaining removal
operations, but do not refit the throttle linkage
cover yet.
83When the cooling system has beenrefilled, reconnect the battery and start the
engine. Check for fuel and other leaks.
84Bring the engine to operating temperature,
then stop it and carry out the final tightening of
the inlet manifold bolts as follows.
85Release the air inlet trunking. Unplug the
idle speed control valve and the throttle
position sensor. Unbolt the plenum chamber
and move it aside, disconnecting vacuum and
breather hoses as necessary.
86Slacken, but do not remove, the two bolts
which secure the fuel rail to the manifold.
87Tighten the inlet manifold bolts to the
Stage 5 specified torque, again following the
sequence shown. A special cranked spanner
(Ford tool No 21-079, or equivalent)(see
illustration)will be needed to tighten No 4
bolt when the distributor is fitted. In the
absence of such a spanner, remove the
distributor again.
88Tighten the fuel rail securing bolts.
89Refit the disturbed components. Run the
engine again and check the ignition timing and
the exhaust CO level .
90Refit the throttle linkage cover.
SOHC and all V6 engines
1Disconnect the battery negative lead.
2Apply copious quantities of penetrating oil
to the manifold and exhaust pipe flange nuts
and bolts.
3On carburettor models, remove the air
cleaner and the hot air pick-up pipe.
4Unbolt any heat shields or shrouds from the
manifold.
5Unbolt the exhaust pipe(s) from the manifold
flange. Support the exhaust system if
necessary.
6Unbolt the manifold from the cylinder head
and remove it. Recover the gasket.
7Refit by reversing the removal operations.
Use a new gasket, and apply anti-seize
compound to the various nuts and bolts.
Tighten the manifold fastenings to the
specified torque.
41Exhaust manifold(s) - removal
and refitting
Fuel and exhaust systems 4•21
4
40.59 Removing a spark plug spacer from
the cylinder head recess40.79 Inlet manifold bolt tightening
sequence
Arrow points to front of engine40.87 Cranked spanner needed for
tightening V6 inlet manifold bolt with
distributor fitted
procarmanuals.com

DOHC carburettor engine
8This procedure is essentially as described
above, noting the following points:
a)Note the plastic bush which is fitted to the
rear manifold stud. This must be removed
before the gasket can be withdrawn.
b)On refitting ensure that the mating
surfaces are clean and dry and fit new
gaskets.
c)Apply a thin coat of anti-seize compound
to the manifold studs to aid future
removal.
d)Tighten the manifold nuts to the specified
torque settings.
DOHC fuel-injection engine
9Disconnect the battery negative lead.
10Disconnect the wiring plug from the idle
speed control valve at the front of the plenum
chamber.
11Loosen the clamp, and detach the air inlet
hose from the air inlet tubing.
12Unscrew the securing nut, and release the
air inlet tube from the bracket on the engine
compartment front panel.
13Release the air cleaner lid securing clips,
then lift away the air inlet tube, plenum
chamber and air cleaner lid as an assembly,
disconnecting the breather hose from the air
inlet tube.
14On models fitted with a catalytic
converter, disconnect the exhaust gas oxygen
sensor wiring plug.
15Unscrew the securing nuts and disconnect
the exhaust downpipe from the manifold.
Recover the gasket. Support the exhaust
downpipe from underneath the vehicle (eg
with an axle stand) to avoid placing
unnecessary strain on the exhaust system.
16Unscrew the six securing nuts, and lift the
manifold from the cylinder head. Recover the
gasket.
17Refitting is a reversal of removal, bearing
in mind the following points.
a)Ensure that all mating faces are clean, and
use a new gasket.
b)Tighten the manifold securing nuts and
the downpipe securing nuts progressively
to the specified torque (where given).
SOHC and 2.8 litre V6 engines
1Periodically inspect the exhaust system for
freedom from corrosion and security of
mountings. Large holes will be obvious; small
holes may be found more easily by letting the
engine idle and partly obstructing the tailpipe
with a wad of cloth.
2Check the condition of the rubber
mountings by applying downward pressure on
the exhaust system and observing the
mountings for splits or cracks. Renew
deteriorated mountings.
3The exhaust systems fitted in production
have fewer sections than those available for
repair. Repair sections may be fitted to
production systems by cutting at the
appropriate point.
4The production exhaust systems are made
of aluminised and stainless steel. Repair
systems are available to the same standard, or
in standard quality (SQ) painted mild steel.
5It is recommended that the whole exhaust
system be removed even if only part requires
renewal, since separation of old joints, cutting
pipes etc is much easier away from the
vehicle. Proceed as follows.
6Disconnect the battery negative lead. Raise
and support the vehicle.
7Unbolt the manifold-to-downpipe flanged
joint(s).
8On V6 models, unbolt the left-hand front
silencer mounting.
9Release any earth straps.
10With the help of an assistant, unhook the
system from its mountings and remove it.
11Renew sections as necessary. Apply
exhaust jointing compound to sliding and
flanged joints, but do not tighten their clamps
yet. Use new sealing rings where necessary
(see illustration).
12Offer the system to the vehicle and hook it
onto the mountings.
13Refit any earth straps. On V6 models, also
refit the left-hand front silencer mounting.
14Loosely fit the manifold flange nuts.
Correct the alignment of the system, then
tighten all clamp nuts and bolts, starting at the
manifold flange(s) and working rearwards.
15Check that the system alignment is still
satisfactory then reconnect the battery. Run
the engine and check for leaks.
16When the system has warmed up, stop the
engine and carefully check the tightness of the
clamp nuts and bolts.
DOHC and 2.4 & 2.9 litre V6
engines
17Follow the above procedure, noting that
flanged joints incorporating gaskets may be
used to join exhaust sections on these
models. Where applicable, renew the gaskets
on refitting.
18On models fitted with a catalyticconverter, disconnect the battery negative
terminal and disconnect the exhaust gas
oxygen (HEGO) sensor wiring plug before
removing the downpipe.
DOHC engine
Note: The exhaust gas oxygen (HEGO) sensor
is delicate and will not work if it is dropped or
knocked, if the power supply is disrupted, or if
any cleaning materials are used on it. Never
touch the tip of the sensor as this can also
damage it.
1Ensure that the engine and the exhaust
system are cold.
2Disconnect the battery negative lead.
3Apply the handbrake, then jack up the front
of the vehicle, and support it securely on axle
stands (see “Jacking”).
4Disconnect the sensor wiring plug halves by
releasing the locktabs and pulling on the plug
halves, not the wiring.
5Slide the heat shield (where fitted) from the
sensor.
6Bearing in mind the note made at the start
of this operation, unscrew the sensor from the
exhaust downpipe, and recover the sealing
ring (see illustration).
7Commence refitting by ensuring that the
sensor threads and the corresponding threads
in the downpipe are clean.
8Refit the sensor using a new sealing ring,
and tighten it to the specified torque.
9Further refitting is a reversal of removal, but
on completion start the engine, and check for
leaks around the sensor sealing ring.
V6 engines
10The sensors fitted to these models can be
removed and refitted using the information
given above, noting that on early models there
was only one sensor, which was fitted at the
point where the two downpipes meet below
the engine, and on some later models there
are two sensors, one in each downpipe.
43Exhaust gas oxygen (HEGO)
sensor (models with catalytic
converter) - removal and
refitting
42Exhaust system - inspection,
repair and renewal
4•22Fuel and exhaust systems
43.6 Exhaust gas oxygen (HEGO) sensor
(viewed from underneath)
42.11 Exhaust pipe flanged joint
A Sealing ring
B Flange
procarmanuals.com

engine coolant temperature sensor. The
crankshaft speed/position sensor is activated
by a toothed disc on the rear of the crankshaft,
inside the cylinder block. The disc has 35
equally spaced teeth (one every 10°), with a
gap in the 36th position. The gap is used by
the sensor to determine the crankshaft
position relative to Top Dead Centre (TDC) of
No 1 piston.
The ignition advance is a function of the
ESC II module, and is controlled by vacuum.
The module is connected to the carburettor by
a vacuum pipe, and a transducer in the
module translates the vacuum signal into an
electrical voltage. From the vacuum signal, the
module determines engine load; engine speed
and temperature are determined from the
crankshaft speed/position sensor and the
engine coolant temperature sensor. The
module has a range of spark advance settings
stored in the memory, and a suitable setting is
selected for the relevant engine speed, load
and temperature. The degree of advance can
thus be constantly varied to suit the prevailing
engine speed and load conditions.
On DOHC fuel-injected engines, a
development of the EEC IV (Electronic Engine
Control IV) engine management system is
used to control both the ignition and fuel-
injection systems. The EEC IV module receives
information from a crankshaft speed/position
sensor (the same as that fitted to the
carburettor models), a throttle position sensor,
an engine coolant temperature sensor, a fuel
temperature sensor, an air charge temperature
sensor, a Manifold Absolute Pressure (MAP)
sensor, and a vehicle speed sensor (mounted
on the gearbox). Additionally, on models with
a catalytic converter, an additional input is
supplied to the EEC IV module from an
exhaust gas oxygen (HEGO) sensor. On
models with automatic transmission,
additional sensors are fitted to the
transmission to inform the EEC IV module
when the transmission is in neutral, and when
the downshift is being operated.
The module provides outputs to control the
fuel pump, fuel-injectors, idle speed, ignition
system and automatic transmission .
Additionally, on models with air conditioning,
the EEC IV module disengages the air
conditioning compressor clutch when starting
the engine or when the engine is suddenly
accelerated. On models fitted with a catalytic
converter, the EEC IV module also controls the
carbon canister purge solenoid valve.
Using the inputs from the various sensors,
the EEC IV module computes the optimum
ignition advance, and fuel-injector pulse
duration to suit the prevailing engine
conditions.
On 2.4 & 2.9 litre V6 engines, the system
operates in much the same way as that fitted
to the DOHC fuel-injected engine, noting the
following points.
a)There is no crankshaft speed/position
sensor.
b)The vehicle speed sensor is only fitted to
models equipped with a catalytic
converter.Precautions
ESC II module
Although it will tolerate all normal under-
bonnet conditions, the ESC II module may be
adversely affected by water entry during
steam cleaning or pressure washing of the
engine bay.
If cleaning the engine bay, therefore, take
care not to direct jets of water or steam at the
ESC II module. If this cannot be avoided,
remove the module completely, and protect its
multi-plug with a plastic bag.
Ignition system HT voltage
Take care to avoid receiving electric shocks
from the HT side of the ignition system. Do not
handle HT leads, or touch the distributor or
coil, when the engine is running. When tracing
faults in the HT system, use well insulated
tools to manipulate live leads. Electronic
ignition HT voltage could prove fatal.
Electronic ignition systems
General
Further details of the various systems are
given in the relevant Sections of this Chapter.
While some repair procedures are given, the
usual course of action is to renew the
component concerned. The owner whose
interest extends beyond mere component
renewal should obtain a copy of the
Automobile Electrical & Electronic Systems
Manual, available from the publishers of this
manual.
It is necessary to take extra care when
working on the electrical system, to avoid
damage to semi-conductor devices (diodes
and transistors), and to avoid the risk of
personal injury. In addition to the precautions
given in Safety first!at the beginning of this
manual, observe the following when working
on the system:
Always remove rings, watches, etc before
working on the electrical system.Even with the
battery disconnected, capacitive discharge
could occur if a component’s live terminal is
earthed through a metal object. This could
cause a shock or nasty burn.
Do not reverse the battery connections.
Components such as the alternator, electronic
control units, or any other components having
semi-conductor circuitry, could be irreparably
damaged.
If the engine is being started using jump
leads and a slave battery, connect thebatteries positive-to-positiveand negative-to-
negative(see “Jump starting”). This also
applies when connecting a battery charger.
Never disconnect the battery terminals, the
alternator, any electrical wiring, or any test
instruments, when the engine is running.
Do not allow the engine to turn the alternator
when the alternator is not connected.
Never test for alternator output by “flashing”
the output lead to earth.
Never use an ohmmeter of the type
incorporating a hand-cranked generator for
circuit or continuity testing.
Always ensure that the battery negative lead
is disconnected when working on the
electrical system.
Before using electric-arc welding equipment
on the car, disconnect the battery, alternator,
and components such as the fuel-
injection/ignition electronic control unit, to
protect them from the risk of damage.
Refer to Chapter 13
1In normal use the battery should not require
charging from an external source, unless the
vehicle is laid up for long periods, when it
should be recharged every six weeks or so. If
vehicle use consists entirely of short runs in
darkness it is also possible for the battery to
become discharged. Otherwise, a regular
need for recharging points to a fault in the
battery or elsewhere in the charging system.
2There is no need to disconnect the battery
from the vehicle wiring when using a battery
charger, but switch off the ignition and leave
the bonnet open.
3Domestic battery chargers (up to about 6
amps output) may safely be used overnight
without special precautions. Make sure that
the charger is set to deliver 12 volts before
connecting it. Connect the leads (red or
positive to the positive terminal, black or
negative to the negative terminal) before
switching the charger on at the mains.
4When charging is complete, switch off at
the mains beforedisconnecting the charger
from the battery. Remember that the battery
will be giving off hydrogen gas, which is
potentially explosive.
5Charging at a higher rate should only be
carried out under carefully controlled
conditions. Very rapid or “boost” charging
should be avoided if possible, as it is liable to
cause permanent damage to the battery
through overheating.
6During any sort of charging, battery
electrolyte temperature should never exceed
38°C (100°F). If the battery becomes hot, or
the electrolyte is effervescing vigorously,
charging should be stopped.
3Battery - charging
2Electrical fault-finding - general
information
Engine electrical systems 5•3
5
Warning. The voltages produced
by the electronic ignition system
are considerably higher than those
produced by conventional
systems. Extreme care must be taken when
working on the system with the ignition
switched on. Persons with surgically-
implanted cardiac pacemaker devices
should keep well clear of the ignition
circuits, components and test equipment.
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16Undo the wiring connector retaining bolt
then carefully disconnect the wiring plug and
remove the module from the car (see
illustration).
17Refitting is a reverse of the removal
procedure ensuring that the wiring plug bolt is
securely tightened. On completion start the
engine and check that it runs correctly.
Note: Irregular idle is not necessarily caused
by a faulty or badly adjusted stepper motor.
Good electrical contact between the stepper
motor plunger and the adjusting screw is
essential. Before attempting adjustment or
renewal of the motor, try the effect of cleaning
the plunger and adjusting screw contact faces
with abrasive paper followed by switch
cleaning fluid. Switch cleaning fluid is available
from electronic component shops.
1Disconnect the battery negative lead.
2Remove the air cleaner.
3Disconnect the multi-plug from the stepper
motor. Release the locking clip and pull on the
plug, not on the wires.
4Remove the four screws which secure the
stepper motor bracket to the carburettor.Remove the motor and bracket and separate
them (see illustration).
5Refit the motor and bracket to the
carburettor and secure with the four screws.
Reconnect the multi-plug.
6Make an initial adjustment to the throttle
lever adjusting screw if necessary so that it
protrudes from the lever by dimension X (see
illustration).
7Reconnect the air cleaner vacuum hose.
Position the air cleaner to one side so that
there is still access to the carburettor and
stepper motor.
8Connect a tachometer (rev. counter) to the
engine as instructed by the manufacturers.
Reconnect the battery.
9Run the engine. Check the idle mixture (CO
level) as described in Chapter 4 and adjust if
necessary.
10Switch off all electrical loads (headlights,
heater blower etc). If the idle speed adjustment
lead is earthed, temporarily isolate it. Make
sure that the automatic transmission selector is
in the N or P position (where applicable).
11Accelerate the engine to a speed greater
then 2500 rpm, allow it to return to idle, then
repeat. Insert a feeler blade of thickness 1.0
mm (0.04 in) between the stepper motor
plunger and the adjusting screw(see
illustration).With the feeler blade in place,
engine speed should be 875 ±25 rpm. 12If adjustment is necessary, remove the
tamperproof cap from the adjusting screw
locknut. Release the locknut, turn the
adjusting screw to achieve the correct speed
and tighten the locknut.
13Repeat paragraph 11 and check that the
speed is still correct. Readjust if necessary.
14Remove the feeler blade. Stop and restart
the engine, observing the stepper motor
plunger. Immediately after switching off, the
plunger should move to the “anti-dieseling”
position; after a few seconds it should extend
to the “vent manifold/start” position (see
illustration).
15Disconnect the test gear and refit the air
cleaner.
16Recheck the idle mixture.
17Fit new tamperproof plugs or caps if
necessary - see Chapter 4,
18Reconnect the idle speed adjustment lead
if it was earthed.
1The engine management system
temperature sensor is located on the underside
of the inlet manifold (SOHC engines), the side
of the manifold (DOHC engines) or on the front
face of the cylinder block (V6 engines).
20Coolant temperature sensor -
removal and refitting
19Carburettor stepper motor
(2.0 litre models) - removal,
refitting and adjustment
5•10Engine electrical systems
18.16 Disconnecting the EEC IV module
A Multi-plugB Securing bolt
19.6 Throttle lever initial adjustment
A Plunger
B Adjusting screw
C CapX 7.5 ±1.0 mm
(0.30 ±0.04 in)
19.11 Stepper motor adjustment
A LocknutB Feeler blade
19.14 Stepper motor plunger positions
A Vent manifold/start
B Anti-dieselingC Idle
19.4 Carburettor stepper motor and
mounting bracket18.15 Removing the engine management
modules (glovebox removed for clarity)
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Models covered in this Manual have disc
brakes fitted all round. The footbrake operates
hydraulically on all four wheels, and the
handbrake operates mechanically on the rear
wheels. Both footbrake and handbrake are
self-adjusting in use.
Ford’s anti-lock braking system (ABS) is
fitted to all models. The system monitors the
rotational speed of each roadwheel. When a
wheel begins to lock under heavy braking, the
ABS reduces the hydraulic pressure to that
wheel, so preventing it from locking. When this
happens a pulsating effect will be noticed at
the brake pedal. On some road surfaces the
tyres may squeal when braking hard even
though the wheels are not locked.
The main components of the system are the
hydraulic unit, the calipers, pads and discs,
the wheel sensors and the “brain” or control
module. The hydraulic unit contains the
elements of a traditional master cylinder, plus
an electric motor and pump, a pressure
accumulator and control valves. The pump is
the source of pressure for the system and
does away with the need for a vacuum servo.
The hydraulic circuit is split front and rear,
as is normal practice with rear-wheel drive
vehicles. In the event that the hydraulic pump
fails, unassisted braking effort is still available
on the front calipers only.
Warning lights inform the driver of low brake
fluid level, ABS failure and (on some models)
brake pad wear. The low fluid level light
doubles as a “handbrake on” light; if it
illuminates at the same time as the ABS
warning light, it warns of low hydraulic
pressure.
ABS cannot overturn the laws of physics:
stopping distances will inevitably be greater on
loose or slippery surfaces. However, the system
should allow even inexperienced drivers to
retain directional control under panic braking.
From August 1986 the following
modifications were made to the braking
system.
a)The relays differ from earlier versions.b)The hydraulic pump is constructed of iron
rather than alloy.
c)A new pressure warning switch is used.
d)The earlier high pressure rubber hose is
replaced by a steel pipe.
To overcome the problem of excessive rear
brake pad wear, Ford introduced a differential
valve which is screwed into the ABS valve
block.The valve limits the pressure applied to
the rear brake calipers and so reduces brake
pad wear. From 1988 onwards, the valve has
been fitted during production. The differential
valve can also be fitted to earlier models. Refer
to your Ford dealer for further information.
From April 1992 onwards, the models
covered in this Manual were equipped with a
new Teves MK IV anti-lock braking system
instead of the Teves MK II system fitted to the
earlier models.
The Teves MK IV system differs from the
earlier MK II system in the following ways.
a)The source of hydraulic pressure for the
system is a conventional master cylinder
and vacuum servo assembly.
b)A valve block and pump assembly is used
instead of the hydraulic control unit. The
block contains the inlet and outlet
solenoid valves that control the hydraulic
system. There are three pairs of valves,
one for each brake circuit (paragraph c).
c)The hydraulic braking system consists of
three separate circuits; one for each front
brake (which are totally independent of
each other), and a joint circuit which
operates both rear brakes.
d)A G (gravity) switch is incorporated in the
system. This is an inertia type switch and
informs the control module when the
vehicle is decelerating rapidly.
e)A Pedal Travel Sensor (PTS) is fitted to the
vacuum servo unit. The PTS informs the
control module of the position of the brake
pedal when the anti-lock sequence starts
and ensures that a constant pedal height
is maintained during the sequence.
The MK IV system operates as follows.
During normal operation the system
functions in the same way as a non-ABS
system would. During this time the three inlet
valves in the valve block are open and theoutlet valves are closed, allowing full hydraulic
pressure present in the master cylinder to act
on the main braking circuit. If the control
module receives a signal from one of the
wheel sensors and senses that a wheel is
about to lock, it closes the relevant inlet valve
in the valve block which then isolates the
brake caliper on the wheel which is about to
lock from the master cylinder, effectively
sealing in the hydraulic pressure. If the speed
of rotation of the wheel continues to decrease
at an abnormal rate, the control module will
then open the relevant outlet valve in the valve
block; this allows the fluid from the relevant
hydraulic circuit to return to the master
cylinder reservoir, releasing pressure on the
brake caliper so that the brake is released. The
pump in the valve block also operates to assist
in the quick release of pressure. Once the
speed of rotation of the wheel returns to an
acceptable rate the pump stops, the outlet
valve closes and the inlet valve is opened,
allowing the hydraulic master cylinder
pressure to return to the caliper which then
reapplies the brake. This cycle can be carried
many times a second. The solenoid valves
connected to the front calipers operate
independently, but the valve connected to the
rear calipers operates both calipers
simultaneously.
The operation of the ABS system is entirely
dependent on electrical signals. To prevent
the system responding to any inaccurate
signals, a built-in safety circuit monitors all
signals received by the control module. If an
inaccurate signal or low battery voltage is
detected, the ABS system is automatically
shut down and the warning lamp on the
instrument cluster is illuminated to inform the
driver that the ABS system is not operational.
Whilst in this state the system functions in the
same way as a non-ABS system would. If a
fault does develop in the ABS system, the car
must be taken to a Ford dealer for fault
diagnosis and repair. The system is equipped
with a diagnostic plug into which a special
diagnostic (STAR) tester can be plugged. This
allows faults to be easily traced.
1General information
10•2Braking system
Torque wrench settingsNmlbf ft
Front caliper:
To stub axle carrier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .51 to 6138 to 45
Slide bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20 to 2515 to 18
Rear caliper:
Bracket to carrier plate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .51 to 6138 to 45
Slide bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31 to 3523 to 26
Hydraulic unit to bulkhead . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41 to 5130 to 38
Accumulator to pump body . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .35 to 4526 to 33
Pump mounting bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 to 95 to 7
High pressure hose banjo bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16 to 2412 to 18
Reservoir mounting bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 to 63 to 4
Wheel sensor fixing bolts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 to 116 to 8
Vacuum servo unit retaining nuts (Teves MK IV) . . . . . . . . . . . . . . . . . .35 to 4526 to 33
Master cylinder retaining nuts (Teves MK IV) . . . . . . . . . . . . . . . . . . . . .20 to 2515 to 18
Valve block and pump assembly mounting nuts (Teves MK IV) . . . . . . .21 to 2815 to 21
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