jump start FORD FIESTA 1989 Service Repair Manual

6Unscrew the nut securing the cooling fan
shroud to the radiator, noting the insulating
washer arrangement, then lift the fan shroud
and motor assembly from the vehicle (see
illustration) .
7 To separate the fan from the motor shaft,
first remove its retaining clip and washer, then
withdraw the fan (see illustration) . A new clip
will be needed upon reassembly. Remove the
three nuts securing the motor to the shroud
and separate the two components.
Turbo models
8 Disconnect the battery negative (earth) lead
(refer to Chapter 5A, Section 1).
9 Undo the two retaining screws and move
the HT lead bracket clear of the working area,
disconnecting the HT leads as required.
10 Disconnect the fan motor wiring multi-
plug and the two auxiliary lamp wiring multi-
plugs. Unclip the wiring from any local
retaining clips.
11 Remove the front bumper as described in
Chapter 11.
12 Undo the two lower fan shroud retaining
bolts, release the shroud upper locating
tongue from the radiator and withdraw the
assembly from the front of the car.
13 To separate the fan from the motor shaft,
pull off the fan guard from the shroud, flatten
back the raised lockwasher tab, and unscrew
clockwise (a left-hand thread is employed)
the nut securing the fan to the motor shaft.
Remove the fan then undo the three nuts
securing the motor to the shroud and
separate the two components.
Refitting
All models
14 Refitting is a reversal of the removal
procedure. On non-Turbo models, ensure that
the locating tags on the base of the shroud
locate correctly in their slots in the body
crossmember. On Turbo models, if the fan
was removed, use a new lockwasher when
refitting. On all models, ensure that the wiring
connections are cleanly and securely made,
and locate the loom in the retaining clips.
6 Cooling system electrical switches and sensors -
testing, removal and refitting
2
Note: Refer to the warnings given in Section 1
of this Chapter before starting work.
Coolant temperature gauge
sender
Testing
1 If the coolant temperature gauge is
inoperative, check the fuses first (see Chap-
ter 12).
2 If the gauge indicates overheating at any
time, consult the “Fault finding” section at the
end of this manual, to assist in tracing
possible cooling system faults. 3
If the gauge indicates overheating shortly
after the engine is started from cold,
disconnect the temperature gauge sender’s
wiring multi-plug. The sender is located below
the thermostat housing on HCS engines,
adjacent to the thermostat housing on CVH
and PTE engines, and on the forward-facing
side of the thermostat housing on Zetec
engines. If the gauge reading now drops,
renew the sender. If the reading remains high,
the wire to the gauge may be shorted to earth,
or the gauge is faulty.
4 If the gauge fails to indicate after the engine
has been warmed up (approximately
10 minutes) and the fuses are known to be
sound, switch off the engine. Disconnect the
sender’s wiring multi-plug, and use a jumper
wire to ground the connector to a clean earth
point (bare metal) on the engine. Switch on
the ignition without starting the engine.
If the gauge now indicates Hot, renew the
sender.
5 If the gauge still does not work, the circuit
may be open, or the gauge may be faulty. See
Chapter 12 for additional information.
Removal
6 Refer to the relevant Part of Chapter 4 and
remove the air cleaner or air inlet hoses,
according to engine type as necessary, to
gain access to the sender unit.
7 Drain the cooling system (see Chapter 1).
8 On Zetec engines, disconnect the
expansion tank coolant hose and the radiator
top hose from the thermostat housing’s water
outlet.
9 Disconnect the wiring multi-plug from the
sender unit.
10 Unscrew the sender and withdraw it.
Refitting
11Clean as thoroughly as possible the
sender unit location, then apply a light coat of
sealant to the sender’s threads. Screw in the
sender, tighten it to the specified torque, and
reconnect the wiring multi-plug.
12 Reconnect the hoses, and refit any
components disconnected for access. Refill
or top-up the cooling system (see “Weekly
Checks” or Chapter 1) and run the
engine. Check for leaks and proper gauge
operation.
Engine coolant temperature
sensor
Testing
13 Disconnect the battery negative (earth)
lead (see Chapter 5A, Section 1).
14 Locate the coolant temperature sensor,
which will be found below the inlet manifold
on HCS engines, on the side or centre of the
inlet manifold on CVH and PTE engines, or on
top of the thermostat housing on Zetec
engines. Once located, refer to the relevant
Part of Chapter 4 and remove the air cleaner
or air inlet hoses, according to engine type as
necessary, to improve access to the sensor
unit.
15 Disconnect the wiring multi-plug from the
sensor.
16 Using an ohmmeter, measure the
resistance between the sensor terminals.
Depending on the temperature of the sensor
tip, the resistance measured will vary, but
should be within the broad limits given in the
Specifications of this Chapter. If the sensor’s
temperature is varied - by removing it (see
below) and placing it in a freezer for a while, or
by warming it gently - its resistance should
alter accordingly.
17 If the results obtained show the sensor to
be faulty, renew it.
18 On completion, reconnect the wiring
multi-plug and refit any components removed
for access, then reconnect the battery.
Removal
19 Disconnect the battery negative (earth)
lead (see Chapter 5A, Section 1).
20 Locate the sensor as described
previously, and remove any components as
necessary for access.
21 Drain the cooling system (see Chapter 1).
22 Disconnect the wiring multi-plug from the
sensor.
23 Unscrew the sensor and withdraw it.
Refitting
24Clean as thoroughly as possible the
sensor location, then apply a light coat of
sealant to the sensor’s threads. Refit and
tighten the sensor to the specified torque
Cooling, heating and ventilation systems 3•5
5.7 Nuts securing fan motor to shroud (A),
and shroud to body crossmember locating tags (B). Inset shows fan to motor shaft retaining clip (arrowed)5.6 Radiator cooling fan shroud securing nut (arrowed)
3
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1 General information,precautions and battery
disconnection
General information
The engine electrical system consists
mainly of the charging and starting systems.
Because of their engine-related functions,
these components are covered separately
from the body electrical devices such as the
lights, instruments, etc (which are covered in
Chapter 12). Information on the ignition
system is covered in Part B of this Chapter.
The electrical system is of the 12-volt
negative earth type. The battery is of the low maintenance or
“maintenance-free” (sealed for life) type and is
charged by the alternator, which is belt-driven
from the crankshaft pulley. The starter motor is of the pre-engaged
type incorporating an integral solenoid. On
starting, the solenoid moves the drive pinion
into engagement with the flywheel ring gear
before the starter motor is energised. Once
the engine has started, a one-way clutch
prevents the motor armature being driven by
the engine until the pinion disengages from
the flywheel.
Precautions
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 the
batteries positive-to-positive and 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.
Battery disconnection
Several systems fitted to the vehicle require
battery power to be available at all times, either
to ensure that their continued operation (such as
the clock) or to maintain control unit memories
(such as that in the engine management
system’s ECU) which would be wiped if the
battery were to be disconnected. Whenever the
battery is to be disconnected therefore, first note
the following, to ensure that there are no
unforeseen consequences of this action:
a) First, on any vehicle with central locking, it is a wise precaution to remove the key
from the ignition, and to keep it with you,
so that it does not get locked in, if the
central locking should engage accidentally
when the battery is reconnected.
b) On cars equipped with an engine
management system, the system’s ECU will
lose the information stored in its memory -
referred to by Ford as the “KAM” (Keep-
Alive Memory) - when the battery is
disconnected. This includes idling and
operating values, and any fault codes
detected - in the case of the fault codes, if
it is thought likely that the system has
developed a fault for which the
corresponding code has been logged, the
vehicle must be taken to a Ford dealer for
the codes to be read, using the special
diagnostic equipment necessary for this.
Whenever the battery is disconnected, the
information relating to idle speed control
and other operating values will have to be
re-programmed into the unit’s memory.
The ECU does this by itself, but until then,
there may be surging, hesitation, erratic idle
and a generally inferior level of
performance. To allow the ECU to relearn
these values, start the engine and run it as
close to idle speed as possible until it
reaches its normal operating temperature,
then run it for approximately two minutes at
1200 rpm. Next, drive the vehicle as far as
necessary - approximately 5 miles of varied
driving conditions is usually sufficient - to
complete the relearning process.
c) If the battery is disconnected while the alarm system is armed or activated, the
alarm will remain in the same state when the battery is reconnected. The same
applies to the engine immobiliser system
(where fitted).
d) If a Ford “Keycode” audio unit is fitted,
and the unit and/or the battery is
disconnected, the unit will not function
again on reconnection until the correct
security code is entered. Details of this
procedure, which varies according to the
unit and model year, are given in the
“Ford Audio Systems Operating Guide”
supplied with the vehicle when new, with
the code itself being given in a “Radio
Passport” and/or a “Keycode Label” at
the same time. Ensure you have the
correct code before you disconnect the
battery. For obvious security reasons, the
procedure is not given in this manual. If
you do not have the code or details of the
correct procedure, but can supply proof
of ownership and a legitimate reason for
wanting this information, the vehicle’s
selling dealer may be able to help.
Devices known as “memory-savers” (or
“code-savers”) can be used to avoid some of
the above problems. Precise details vary
according to the device used. Typically, it is
plugged into the cigarette lighter, and is
connected by its own wires to a spare battery;
the vehicle’s own battery is then disconnected
from the electrical system, leaving the
“memory-saver” to pass sufficient current to
maintain audio unit security codes and ECU
memory values, and also to run permanently-
live circuits such as the clock, all the while
isolating the battery in the event of a short-
circuit occurring while work is carried out.
Warning: Some of these devices
allow a considerable amount of
current to pass, which can mean
that many of the vehicle’s
systems are still operational when the
main battery is disconnected. If a
“memory-saver” is used, ensure that the
circuit concerned is actually “dead” before
carrying out any work on it!
2 Electrical fault finding - general information
Refer to Chapter 12.
3 Battery -testing and charging
1
Standard and low maintenance
battery - testing
1If the vehicle covers a small annual mileage,
it is worthwhile checking the specific gravity
of the electrolyte every three months to
determine the state of charge of the battery.
Use a hydrometer to make the check and
compare the results with the following table.
5A•2 Starting and charging systems
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flux can pass between the magnet and the
sensor. When a trigger vane segment is in line
with the sensor, the magnetic flux is diverted
through the trigger vane, away from the
sensor. The sensor detects the change in
magnetic flux and sends an impulse to the
EEC IV module. Additional data is received
from the engine coolant temperature sensor,
manifold absolute pressure sensor, inlet air
temperature sensor, throttle position sensor
and vehicle speed sensor. Using this
information the EEC IV module calculates the
optimum ignition advance setting and
switches off the low tension circuit via the
ignition module. This results in the collapse of
the magnetic field in the coil which generates
the high tension voltage. The high tension
voltage is then fed, via the coil HT lead and
the carbon brush in the centre of the
distributor cap, to the rotor arm. The voltage
passes across to the appropriate metal
segment in the cap and via the spark plug HT
lead to the spark plug where it finally jumps
the spark plug gap to earth. It can be seen
that the ignition module functions basically as
a high current switch by controlling the low
tension supply to the ignition coil primary
windings.In the event of failure of a sensor, the
EEC IV module will substitute a preset value
for that input to allow the system to continue
to function. In the event of failure of the
EEC IV module, a “limited operation strategy”
(LOS) function allows the vehicle to be driven,
albeit at reduced power and efficiency. The
EEC IV module also has a “keep alive
memory” (KAM) function which stores idle and
drive values and codes which can be used to
indicate any system fault which may occur.
Distributorless ignition systems
The main ignition system components
include the ignition switch, the battery, the
crankshaft speed/position sensor, the ignition
module, the coil, the primary (low tension/LT)
and secondary (high tension/HT) wiring
circuits, and the spark plugs. The system used on carburettor models is
termed DIS (Distributorless Ignition System),
and on fuel injection models E-DIS, (Electronic
Distributorless Ignition System). The primary
difference between the two is that the DIS
system is an independent ignition control
system while the E-DIS system operates in
conjunction with the EEC IV engine
management module which also controls the
fuel injection and emission control systems.
With both systems, the main functions of
the distributor are replaced by a computerised
ignition module and a coil unit. The coil unit
combines a double-ended pair of coils - each
time a coil receives an ignition signal, two
sparks are produced, at each end of the
secondary windings. One spark goes to a
cylinder on compression stroke and the other
goes to the corresponding cylinder on its
exhaust stroke. The first will give the correct power stroke, but the second spark will have
no effect (a “wasted spark”), occurring as it
does during exhaust conditions.
The ignition signal is generated by a
crankshaft position sensor which scans a
series of 36 protrusions on the periphery of
the engine flywheel. The inductive head of the
crankshaft position sensor runs just above the
flywheel periphery and as the crankshaft
rotates, the sensor transmits a pulse to the
ignition module every time a protrusion
passes it. There is one missing protrusion in
the flywheel periphery at a point
corresponding to 90° BTDC. The ignition
module recognises the absence of a pulse
from the crankshaft position sensor at this
point to establish a reference mark for
crankshaft position. Similarly, the time interval
between absent pulses is used to determine
engine speed. On carburettor engines, the ignition module
receives signals provided by information
sensors which monitor various engine
functions (such as crankshaft position,
coolant temperature, inlet air temperature,
inlet manifold vacuum etc). This information
allows the ignition module to generate the
optimum ignition timing setting under all
operating conditions.
On fuel injection engines, the ignition
module operates in conjunction with the
EEC IV engine management module, and
together with the various additional
information sensors and emission control
components, provides total control of the fuel
and ignition systems to form a complete
engine management package. The information contained in this Chapter
concentrates on the ignition-related
components of the engine management
system. Information covering the fuel, exhaust
and emission control components can be
found in the applicable Parts of Chapter 4.
Precautions
When working on the ignition system, take
the following precautions:
a) Do not keep the ignition switch on for
more than 10 seconds if the engine will
not start.
b) If a separate tachometer is ever required
for servicing work, consult a dealer
service department before buying a
tachometer for use with this vehicle -
some tachometers may be incompatible
with these types of ignition systems - and
always connect it in accordance with the
equipment manufacturer’s instructions.
c) Never connect the ignition coil terminals to earth. This could result in damage to
the coil and/or the ignition module.
d) Do not disconnect the battery when the
engine is running.
e) Make sure that the ignition module is
properly earthed.
f) Refer to the warning at the beginning of the next Section concerning HT voltage.
2 Ignition system - testing
2
Warning: Voltages produced by
an electronic ignition system are
considerably higher than those
produced by conventional
ignition 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.
Note: Refer to the precautions given in
Section 1 of Part A of this Chapter before
starting work. Always switch off the ignition
before disconnecting or connecting any
component and when using a multi-meter to
check resistances.
1 If the engine turns over but won’t start,
disconnect the (HT) lead from any spark plug,
and attach it to a calibrated tester (available at
most automotive accessory shops). Connect
the clip on the tester to a good earth - a bolt
or metal bracket on the engine. If you’re
unable to obtain a calibrated ignition tester,
have the check carried out by a Ford dealer
service department or similar. Any other form
of testing (such as jumping a spark from the
end of an HT lead to earth) is not
recommended, because of the risk of
personal injury, or of damage to the ignition
module.
2 Crank the engine, and watch the end of the
tester to see if bright blue, well-defined sparks
occur.
3 If sparks occur, sufficient voltage is
reaching the plug to fire it. Repeat the
check at the remaining plugs, to ensure
that all leads are sound and that the
coil is serviceable. However, the plugs
themselves may be fouled or faulty, so
remove and check them as described in
Chapter 1.
4 If no sparks or intermittent sparks occur,
the spark plug lead(s) may be defective. Also,
on distributor systems, there may be
problems with the rotor arm or distributor cap
- check all these components as described in
Chapter 1.
5 If there’s still no spark, check the coil’s
electrical connector (where applicable), to
make sure it’s clean and tight. Check for full
battery voltage to the coil at the connector’s
centre terminal. Check the coil itself (see
Section 3). Make any necessary repairs, then
repeat the check again.
6 The remainder of the system checks should
be left to a dealer service department
or other qualified repair facility, as there is a
chance that the ignition module may
be damaged if tests are not performed
properly.
Ignition system 5B•3
5B
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wiring diagrams are included at the end of this
manual.
2Before attempting to diagnose an electrical
fault, first study the appropriate wiring
diagram, to obtain a complete understanding
of the components included in the particular
circuit concerned. The possible sources of a
fault can be narrowed down by noting if other
components related to the circuit are
operating properly. If several components or
circuits fail at one time, the problem is likely to
be related to a shared fuse or earth
connection.
3 Electrical problems usually stem from
simple causes, such as loose or corroded
connections, a faulty earth connection, a
blown fuse, a melted fusible link, or a faulty
relay (refer to Section 3 for details of testing
relays). Visually inspect the condition of all
fuses, wires and connections in a problem
circuit before testing the components. Use
the wiring diagrams to determine which
terminal connections will need to be checked
in order to pinpoint the trouble-spot.
4 The basic tools required for electrical fault-
finding include a circuit tester or voltmeter (a
12-volt bulb with a set of test leads can also
be used for certain tests); an ohmmeter (to
measure resistance and check for continuity);
a battery and set of test leads; and a jumper
wire, preferably with a circuit breaker or fuse
incorporated, which can be used to bypass
suspect wires or electrical components.
Before attempting to locate a problem with
test instruments, use the wiring diagram to
determine where to make the connections.
Warning: Under no
circumstances may live
measuring instruments such as
ohmmeters, voltmeters or a bulb
and test leads be used to test any of the
air bag circuitry or components. Any
testing in these areas must be left to a
Ford dealer as there is a danger of
activating the system if the correct
procedures are not followed.
5 To find the source of an intermittent wiring
fault (usually due to a poor or dirty
connection, or damaged wiring insulation), a
“wiggle” test can be performed on the wiring.
This involves wiggling the wiring by hand to
see if the fault occurs as the wiring is moved.
It should be possible to narrow down the
source of the fault to a particular section of
wiring. This method of testing can be used in
conjunction with any of the tests described in
the following sub-Sections.
6 Apart from problems due to poor
connections, two basic types of fault can
occur in an electrical circuit - open-circuit, or
short-circuit.
7 Open-circuit faults are caused by a break
somewhere in the circuit, which prevents
current from flowing. An open-circuit fault will
prevent a component from working.
8 Short-circuit faults are caused by a “short”
somewhere in the circuit, which allows the current flowing in the circuit to “escape” along
an alternative route, usually to earth. Short-
circuit faults are normally caused by a
breakdown in wiring insulation, which allows a
feed wire to touch either another wire, or an
earthed component such as the bodyshell. A
short-circuit fault will normally cause the
relevant circuit fuse to blow.
Finding an open-circuit
9
To check for an open-circuit, connect one
lead of a circuit tester or the negative lead of a
voltmeter either to the battery negative
terminal or to a known good earth.
10 Connect the other lead to a connector in
the circuit being tested, preferably nearest to
the battery or fuse. At this point, battery
voltage should be present, unless the lead
from the battery or the fuse itself is faulty
(bearing in mind that some circuits are live
only when the ignition switch is moved to a
particular position).
11 Switch on the circuit, then connect the
tester lead to the connector nearest the circuit
switch on the component side.
12 If voltage is present (indicated either by
the tester bulb lighting or a voltmeter reading,
as applicable), this means that the section of
the circuit between the relevant connector
and the switch is problem-free.
13 Continue to check the remainder of the
circuit in the same fashion.
14 When a point is reached at which no
voltage is present, the problem must lie
between that point and the previous test point
with voltage. Most problems can be traced to
a broken, corroded or loose connection.
Finding a short-circuit
15 To check for a short-circuit, first
disconnect the load(s) from the circuit (loads
are the components which draw current from
a circuit, such as bulbs, motors, heating
elements, etc).
16 Remove the relevant fuse from the circuit,
and connect a circuit tester or voltmeter to the
fuse connections.
17 Switch on the circuit, bearing in mind that
some circuits are live only when the ignition
switch is moved to a particular position.
18 If voltage is present (indicated either by
the tester bulb lighting or a voltmeter reading,
as applicable), this means that there is a
short-circuit.
19 If no voltage is present during this test,
but the fuse still blows with the load(s)
reconnected, this indicates an internal fault in
the load(s).
Finding an earth fault
20 The battery negative terminal is
connected to “earth” - the metal of the
engine/transmission and the vehicle body -
and many systems are wired so that they only
receive a positive feed, the current returning
via the metal of the car body. This means that
the component mounting and the body form
part of that circuit. Loose or corroded mountings can therefore cause a range of
electrical faults, ranging from total failure of a
circuit, to a puzzling partial failure. In
particular, lights may shine dimly (especially
when another circuit sharing the same earth
point is in operation), motors (eg wiper
motors or the radiator cooling fan motor) may
run slowly, and the operation of one circuit
may have an apparently-unrelated effect on
another. Note that on many vehicles, earth
straps are used between certain
components, such as the engine/
transmission and the body, usually where
there is no metal-to-metal contact between
components, due to flexible rubber
mountings, etc.
21
To check whether a component is
properly earthed, disconnect the battery (refer
to Chapter 5A, Section 1) and connect one
lead of an ohmmeter to a known good earth
point. Connect the other lead to the wire or
earth connection being tested. The resistance
reading should be zero; if not, check the
connection as follows.
22 If an earth connection is thought to be
faulty, dismantle the connection, and clean
both the bodyshell and the wire terminal (or
the component earth connection mating
surface) back to bare metal. Be careful to
remove all traces of dirt and corrosion, then
use a knife to trim away any paint, so that a
clean metal-to-metal joint is made. On
reassembly, tighten the joint fasteners
securely; if a wire terminal is being refitted,
use serrated washers between the terminal
and the bodyshell, to ensure a clean and
secure connection. When the connection is
remade, prevent the onset of corrosion in the
future by applying a coat of petroleum jelly or
silicone-based grease, or by spraying on (at
regular intervals) a proprietary ignition sealer
or a water-dispersant lubricant.
3 Fuses and relays -
general information
Note: It is important to note that the ignition
switch and the appropriate electrical circuit
must always be switched off before any of the
fuses (or relays) are removed and renewed.
1 The main fuse and relay board is located
below the facia panel to the right of the
steering wheel. The fuses can be inspected
and if necessary renewed, by removing the
hinged access cover. The remaining
additional fuses and relays (depending on
model) may be accessed by removing the two
fuse board retaining screws, releasing the
retaining lugs on either side of the main fuse
plate and withdrawing the fuse/relay board
downwards into the driver’s footwell. Each
fuse location is numbered - refer to the fuse
chart in the Specifications at the start of this
Chapter to check which circuits are protected
by each fuse. Plastic tweezers are attached to
12•4 Body electrical systems
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The vehicle owner who does his or her own
maintenance according to the recommended
service schedules should not have to use this
section of the manual very often. Modern
component reliability is such that, provided
those items subject to wear or deterioration
are inspected or renewed at the specified
intervals, sudden failure is comparatively rare.
Faults do not usually just happen as a result of
sudden failure, but develop over a period of
time. Major mechanical failures in particular are usually preceded by characteristic
symptoms over hundreds or even thousands
of miles. Those components which do
occasionally fail without warning are often
small and easily carried in the vehicle.
With any fault-finding, the first step is to
decide where to begin investigations.
Sometimes this is obvious, but on other
occasions, a little detective work will be
necessary. The owner who makes half a
dozen haphazard adjustments or replacements may be successful in curing a
fault (or its symptoms), but will be none the
wiser if the fault recurs, and ultimately may
have spent more time and money than was
necessary. A calm and logical approach will
be found to be more satisfactory in the long
run. Always take into account any warning
signs or abnormalities that may have been
noticed in the period preceding the fault -
power loss, high or low gauge readings,
unusual smells, etc - and remember that
Engine
m
m
Engine backfires
m
m Engine difficult to start when cold
m
m Engine difficult to start when hot
m
m Engine fails to rotate when attempting to start
m
m Engine hesitates on acceleration
m
m Engine idles erratically
m
m Engine lacks power
m
m Engine misfires at idle speed
m
m Engine misfires throughout the driving speed range
m
m Engine noises
m
m Engine rotates, but will not start
m
m Engine runs-on after switching off
m
m Engine stalls
m
m Engine starts, but stops immediately
m
m Oil pressure warning light illuminated with engine running
m
m Starter motor noisy or excessively-rough in engagement
Cooling system
m
mCorrosion
m
m External coolant leakage
m
m Internal coolant leakage
m
m Overcooling
m
m Overheating
Fuel and exhaust systems
m
mExcessive fuel consumption
m
m Excessive noise or fumes from exhaust system
m
m Fuel leakage and/or fuel odour
Clutch
m
mClutch fails to disengage (unable to select gears)
m
m Clutch slips (engine speed increases, with no increase in vehicle
speed)
m m Judder as clutch is engaged
m
m Noise when depressing or releasing clutch pedal
m
m Pedal travels to floor - no pressure or very little resistance
Manual transmission
m
mJumps out of gear
m
m Lubricant leaks
m
m Noisy in neutral with engine running
m
m Noisy in one particular gear
m
m Vibration
Automatic transmission
m
mEngine will not start in any gear, or starts in gears other than Park
or Neutral
m m Fluid leakage
m
m General gear selection problems
m
m Transmission fluid brown, or has burned smell
m
m Transmission slips, shifts roughly, is noisy, or has no drive in
forward or reverse gears
m m Transmission will not downshift (kickdown) with accelerator fully
depressed
Driveshafts
m mClicking or knocking noise on turns (at slow speed on full-lock)
m
m Vibration when accelerating or decelerating
Braking system
m
mBrake pedal feels spongy when depressed
m
m Brakes binding
m
m Excessive brake pedal effort required to stop vehicle
m
m Excessive brake pedal travel
m
m Judder felt through brake pedal or steering wheel when braking
m
m Noise (grinding or high-pitched squeal) when brakes applied
m
m Rear wheels locking under normal braking
m
m Vehicle pulls to one side under braking
Suspension and steering systems
m
mExcessive pitching and/or rolling around corners, or during
braking
m m Excessive play in steering
m
m Excessively-stiff steering
m
m Lack of power assistance
m
m Tyre wear excessive
m
m Vehicle pulls to one side
m
m Wandering or general instability
m
m Wheel wobble and vibration
Electrical system
m
mBattery will not hold a charge for more than a few days
m
m Electric windows inoperative, or unsatisfactory in operation
m
m Horn inoperative, or unsatisfactory in operation
m
m Ignition warning light fails to come on
m
m Ignition warning light remains illuminated with engine running
m
m Instrument readings inaccurate or erratic
m
m Lights inoperative
m
m Windscreen/tailgate washers inoperative, or unsatisfactory in
operation
m m Windscreen/tailgate wipers inoperative, or unsatisfactory in
operation
REF•14Fault finding
1595 Ford Fiesta Remake
Introduction
procarmanuals.com
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1595 Ford Fiesta Remake
Glossary of technical termsREF•25
REF
JJump startStarting the engine of a vehicle
with a discharged or weak battery by
attaching jump leads from the weak battery to
a charged or helper battery.
LLoad Sensing Proportioning Valve (LSPV) A
brake hydraulic system control valve that
works like a proportioning valve, but also
takes into consideration the amount of weight
carried by the rear axle.
Locknut A nut used to lock an adjustment
nut, or other threaded component, in place.
For example, a locknut is employed to keep
the adjusting nut on the rocker arm in
position.
Lockwasher A form of washer designed to
pr event an attaching nut from working loose.
MMacPherson strut A type of front
suspension system devised by Earle
MacPherson at Ford of England. In its original
form, a simple lateral link with the anti-roll bar
cr eates the lower control arm. A long strut - an
integral coil spring and shock absorber - is
mounted between the body and the steering
knuckle. Many modern so-called MacPherson
strut systems use a conventional lower A-arm
and don’t rely on the anti-roll bar for location. Multimeter An electrical test instrument with
the capability to measure voltage, current and
resistance.
NNOx Oxides of Nitrogen. A common toxic
pollutant emitted by petrol and diesel engines
at higher temperatures.
OOhm The unit of electrical resistance. One
volt applied to a resistance of one ohm will
pr oduce a current of one amp.
Ohmmeter An instrument for measuring
electrical resistance.
O-ring A type of sealing ring made of a
special rubber-like material; in use, the O-ring
is compressed into a groove to provide the
sealing action. Overhead cam (ohc) engine
An engine with
the camshaft(s) located on top of the cylinder
head(s).
Overhead valve (ohv) engine An engine with
the valves located in the cylinder head, but
with the camshaft located in the engine block.
Oxygen sensor A device installed in the
engine exhaust manifold, which senses the
oxygen content in the exhaust and converts
this information into an electric current. Also
called a Lambda sensor.
PPhillips screw A type of screw head having a
cr oss instead of a slot for a corresponding
type of screwdriver.
Plastigage A thin strip of plastic thread,
available in different sizes, used for measuring clearances. For example, a strip of Plastigage
is laid across a bearing journal. The parts areassembled and dismantled; the width of the
crushed strip indicates the clearance between
jour nal and bearing.
Pr opeller shaft The long hollow tube with
universal joints at both ends that carries
power from the transmission to the differential on front-engined rear wheel drive vehicles.
Pr oportioning valve A hydraulic control
valve which limits the amount of pressure to
the rear brakes during panic stops to prevent
wheel lock-up.
RRack-and-pinion steering A steering system
with a pinion gear on the end of the steering
shaft that mates with a rack (think of a geared
wheel opened up and laid flat). When the
steering wheel is turned, the pinion turns,
moving the rack to the left or right. This
movement is transmitted through the track
r ods to the steering arms at the wheels.
Radiator A liquid-to-air heat transfer device
designed to reduce the temperature of the
coolant in an internal combustion engine
cooling system.
Refrigerant Any substance used as a heat
transfer agent in an air-conditioning system.
R-12 has been the principle refrigerant for
many years; recently, however, manufacturers
have begun using R-134a, a non-CFC
substance that is considered less harmful to the ozone in the upper atmosphere.
Rocker arm
A lever arm that rocks on a shaft
or pivots on a stud. In an overhead valve
engine, the rocker arm converts the upward
movement of the pushrod into a downward
movement to open a valve.
Rotor In a distributor, the rotating device
inside the cap that connects the centre
electr ode and the outer terminals as it turns,
distributing the high voltage from the coil
secondary winding to the proper spark plug.
Also, that part of an alternator which rotates
inside the stator. Also, the rotating assembly
of a turbocharger, including the compressor
wheel, shaft and turbine wheel.
Runout The amount of wobble (in-and-out
movement) of a gear or wheel as it’ s rotated.
The amount a shaft rotates “out-of-true.” The
out-of-r ound condition of a rotating part.
SSealant A liquid or paste used to prevent
leakage at a joint. Sometimes used in
conjunction with a gasket.
Sealed beam lamp An older headlight design
which integrates the reflector, lens and
filaments into a hermetically-sealed one-piece
unit. When a filament burns out or the lens
cracks, the entire unit is simply replaced.
Serpentine drivebelt A single, long, wide
accessory drivebelt that’s used on some
newer vehicles to drive all the accessories,
instead of a series of smaller, shorter belts.
Serpentine drivebelts are usually tensioned by
an automatic tensioner.
Shim Thin spacer, commonly used to adjust
the clearance or relative positions between
two parts. For example, shims inserted into or
under bucket tappets control valve
clearances. Clearance is adjusted by
changing the thickness of the shim.
Slide hammer A special puller that screws
into or hooks onto a component such as a
shaft or bearing; a heavy sliding handle on the
shaft bottoms against the end of the shaft to
knock the component free.
Sprocket A tooth or projection on the
periphery of a wheel, shaped to engage with a
chain or drivebelt. Commonly used to refer to
the sprocket wheel itself.
Starter inhibitor switch On vehicles with an
O-ring
Serpentine drivebelt
Plastigage
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Fault finding - clutch - REF•17
Fault finding - cooling system - REF•16
Fault finding - driveshafts - REF•19
Fault finding - electrical system - 5A•2,
12 •3, REF •20
Fault finding - engine - REF•15, REF•16,
REF•18
Fault finding - fuel and exhaust systems -
REF•17
Fault finding - manual transmission - REF•17
Fault finding - suspension and steering
systems - REF•19
Filling - 11•3
Filter, air -1•22, 1•23, 4A•3, 4B•4, 4C•3,
4D•3, 4E•5
Filter, oil -1•9
Filter, fuel -1•25
Fire - 0•5
Float - 4A•7, 4A•9, 4A•16
Fluid seals - 7B•3
Fluids - 0•17
Flywheel - 2A•11, 2B•14, 2C•16
Fuel consumption high - REF•17
Fuel cut-off switch - 4B•5, 4C•5, 4D•4
Fuel filler pipe - 4A•6, 4B•5, 4C•5, 4D•4
Fuel filter - 1•25
Fuel gauge - 4A•6, 4B•4, 4C•5, 4D•4, 12 •12
Fuel gauge fault - REF•20
Fuel hoses - 1•13
Fuel injectors - 4B•5, 4C•5, 4D•5
Fuel lines - 1•17, 4B•3, 4C•3, 4D•2
Fuel pressure check - 4C•4
Fuel pressure regulator - 4B•6, 4C•6, 4D•5
Fuel pump - 4A•5, 4B•4, 4C•4, 4C•5, 4D•4
Fuel rail - 4C•5, 4D•5
Fuel system - carburettor engines -4A•1 et
seq
Fuel system - central fuel injection engines
-4B•1 et seq
Fuel system - electronic fuel injection engines -4C•1 et seq
Fuel system - sequential electronic fuel
injection engines -4D•1 et seq
Fuel and exhaust systems - REF•13
Fuel and exhaust systems fault finding - REF•17
Fuel tank - 4A•5, 4A•6, 4B•4, 4B•5, 4C•5,
4D•4
Fuel trap - 4B•7
Fume or gas intoxication - 0•5
Fuses - 0•16, 12 •4
G
Gaiters - 1•16, 8•3, 8•4, 10 •15
Gashes in bodywork - 11•3
Gaskets - REF •4
Gear lever - 7A•2
Gear selection problems - REF•18
Gear selector - 7B•2
Gearbox oil - 0•17, 1•14
Gearbox - See Manual gearbox
Gearchange linkage - 7A•2
Gearchange selector - 7A•3
Glossary of technical terms - REF•22 et seq
Grab handle - 11•20
H
Handbrake - 1•25, 9•12, 9•13, 12 •6,
REF•10
Handles - 11•11, 11•13, 11 •20
Hazard warning switch - 12•8
HC emissions - REF•13
HCS engine in-car repair procedures -
2A•1 et seq
Headlight - 12•7, 12 •9, 12 •10
Heater - 3•2, 3•8, 12 •6, 12•9
Horn - 12•12
Horn fault - REF•20
HT lead - 1•20
Hub bearings - 10•5, 10•8, REF •12
Hydraulic pipes and hoses - 9•9
Hydraulic tappets - 2C•8
Hydrofluoric acid - 0•5
I
Idle speed -1•14, 1•15, 1•20, 4C•6
Idle speed control valve - 4D•6
Idling fault - REF•15
Ignition amplifier - 5B•5
Ignition switch - 12•5
Ignition system -5B•1 et seq
Ignition fault - REF•20
Ignition timing - 5B•7
Indicators - 12•7, 12•9, 12 •10
Injector ballast resistor - 4B•9
Injectors - 4C•5, 4D•5
Inlet manifold - 4A•18, 4B•9, 4C•8, 4D•7
Instruments - 1•18, 12•8, 12•11
Instrument fault - REF•20
Intercooler - 4C•8
Interior light - 12•6, 12 •9
J
Jacking and vehicle support - REF•5
Joint mating faces - REF•4
Joystick - 12•16
Jump starting - 0•7
L
Leaks -0•9, 1•12, REF •16, REF•17, REF•18,
REF•20
Light-laden valve - 9•13, 9•14
Lighter - 12•9, 12 •12
Lights-on warning module - 12•16
Load compartment - 11•20
Load-apportioning valve - 9•16
Locknuts ,locktabs and washers - REF•4
Locks - 11•11, 11•12, 11•13, 12 •5
Loudspeaker housing - 11•20
Lower arm - 10•8
Lubricants - 0•17
Luggage area - 12•6, 12•9
M
Main bearings - 2D•21, 2D•22
Manifold absolute pressure sensor - 4B•8,
4C•7 Manifolds -
4A•18, 4B•9, 4C•8, 4D•7, 4E•3
Manual gearbox
Manual transmission -2A•10, 2B•13,
2C•15, 2D•6, 2D•8, 2D•10, 7A•1 et seq
Manual transmission fault finding - REF•17
Manual transmission oil - 0•17, 1•14
Mass air flow sensor - 4D•6
Master cylinder - 9•7
Minor scratches in bodywork - 11•2
Mirrors - 11 •8, 11•9, REF •10
Misfire - REF•15
Mixture - 1•14, 1•15, 4C•7, REF•13
Modulator - 9•16
MOT test checks - REF•10et seq
Mountings - 2A•10, 2B•13, 2C•15
N
Needle valve - 4A•7, 4A•9, 4A•16
Number plate light - 12•8, 12 •10
O
Oil filter - 1•9
Oil pressure fault - REF•16
Oil pump - 2A•8, 2A•9, 2B•11, 2B•12,
2C•13
Oil seals - 2A•9, 2B•7, 2B•12, 2C•8, 2C•14,
7A•3, 7B•3, REF •4
Oil separator - 4E•5
Oil, engine - 0•12, 0•17, 1•9
Oil, manual transmission - 0•17, 1•14
Open-circuit - 12•4
Overcooling - REF•16
Overheating - REF•16
Oxygen sensor - 4B•8, 4C•7, 4D•7
P
Pads -9•2
Paint - 1•18
Parcel shelf - 11•20
Parking light - 12•7
Passive Anti-Theft System (PATS) - 12•17
Pedals - 4A•4, 4B•4, 4C•4, 4D•3, 6•2, 9•8,
9•9
Pinking - REF•16
Piston rings - 2D•22
Pistons - 2D•17, 2D•24, 2D•25
Plastic components - 11•4
Poisonous or irritant substances - 0•5
Positive crankcase ventilation system - 4E•1, 4E•5
Power steering - 10•14, 10•15, 10•16,
10 •17
Power steering fluid - 0•13, 0•17
Power steering pressure switch - 4B•8,
4C•7, 4D•7
Pre-ignition - REF•16
Printed circuit - 12•11
Pulse-air system - 4E•2, 4E•6, 4E•7
Q
Quarter mouldings - 11•8
REF•28Index
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