B
v
ROLLS
Workshop Manual
Engine -Management
Systems
ROYCE
U-
Rolls-Royce B Bentley
motor cars
Rolls-Royce Silver Spirit
Rolls-Royce Silver Spur
Rolls- Royce Corniche
Rolls-Royce Comiche II
Bentley Eight
Bentley Mulsanne
Bentley Mulsanne S
Bentley Turbo R
Bentley Continental
1987,1988, and 1989
model year cars
TSD 4737
September I989
Introduction
This manuai is written specifically for skilled service
personnel and it is therefore assumed that the
warkshop safety and repair procedures generally
accepted by the motor trade are appreciated,
understood, and carried wt
Information relating to any subsequent
modification will be circulated by the issue of amended
or addition+ pages.
Each chapter incorporates an issue record shoet
Reference must be made to these sheets when
determining either the current issue date for a
particular page, or the number of pages contained
within a chapter/section.
Throughout the rnanuat reference is made to the
right-hand and left-hand side of the car, this is
determined when sitting in the driver's scat.
In order to identify the two banks of engine
cylinders, it should be noted that 'K bank of cylinders
is on the right-hand side and '8' bank on the left-hand
side when viewed from the driveis seat
S e ~ c personnel
e
at Rolls-Rgree Motor Cars
Limited are always prepared to aanswr queries or give
advice on individual servicing problems. When making
an enquiry it is essential that the full vehicle
identification number (VINJ is quoted.
important
When obtaining information for a particular model
always refer to the appropriate Chapter and/or Section
contents page.
9/89
TSD 4737
Contents
Uupter A
General information
Chapter B
Fuel injection -ern
Chapter C
Fuel system
Chapter D
Turbochargingsystem
Chapter E
Ignition.system
(For details of the ignition system fitted to l989
r n d l year turbcharged cars. refer to Chapter B.
Seaion 54, K-Moronic)
Chapter F
Exhaust emission control system
Chaptw G
Fuel evaporative emission control system
Chapter U
Crankcase emission con! rol system
Chapter J
Air intake system
Chapter K
Throttle linkage
Chapter L
Special toque tightening figures
Chapter M
Workshop took
Chapter N
-Runningchanges
Chapter A
General information
Contents
Sections
Bentley
Rolls-Royce
Contents and issue record
sheet
Eight
Muisanne/ Turbo R
Mulranne S
Continental
Spur
Comiche /
Comiche II
A1
Al
A9
A1
At
Silver
Spirit
Sihrer
AI
Al.
1987188109 model years
General information
10188
"
TSD 4737
Issue record sheet
The dates quoted below refer to the issue date of individual pages within this chapter.
Sections
Page No.
1 &l 1 ~2
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1
2
10188
3
4
10188
5
6
10188
l0188
10188
10188
lOl88
10188
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Section A2
General information
Heahh risk
Engine oils
Prolongedand repeated contact with mineral oil will
result in the removal of natural fatsfrom the skin.
leading t o dryness. irritation, and dermatitis. In addition.
used engine oil contains potentially harmful
contaminants which may cause skin cancer. Adequate
means of skin protection and washing facilities should
be provided.
Health protectionprecautions
1. Avoid prolonged and repeated contsct with oils,
particularly used engine oils.
2. Wear protective clothing, including impervious
gloves where practicabte.
3. Do not put oily rags in pockets.
4. Avoid contaminating clothes, particularly
underpants. with oil.
5. Overalls must be cleaned regularly. Discard
unwashable clothing and oil impregnated footwear.
6. First aid treatment should be obtained immediately
far open cuts and wounds.
7. Use barrier creams. applying before each work
period. to help the removal of oil from the skin.
8. Wash with soap and water to ensure all oil is
rernwed (skincleansers and nail brushes will help).
Preparations containing lanolin replace the natural skin
oils which have been remwed.
9. Do not use fuel, kerosine, diesel fuel, gas oil,
thinners, or solvents for washing skin.
10. Ifskin disorders develop. obtain medical advice
11. Where practicable, dsgrease components prior t o
handling.
12. Where them is a risk of eye comaet. eye protection
should be worn, for example, chemical goggles or face
shields; in addition an eye-wash facility should be
provided.
See atso UK Health and Safety Executive
Cautionary Notice SHW 397 'Effects ofMineral Oil on
the Skin'.
Operating the air conditioning system in 8 confined
space incmases the danger of these Bases entering the
car.
ideally. engines should be tun inthe open where the
exhaust gases can discharge into the atmosphere
However. when running engines within an enclosed
working area. the exhaust gases must always be
removed safely.
Refer t o further text withirrthis manual regarding
the use of exhaust gas extraction hoses and equipment.
Fuel
Fuel may contain up to 5% of benzene as an anti-knock
additive Benzene is extremely injurious t o health {being
carcinogenic) therefom all cantact should be kspt tb an
absolute minimum, particularly inhalation.
Fuel has a sufficiently high vapour pressurnto allow
a hazardous build-up of vapour in poorly ventilated
areas. Therefore. any work should be carried out in a
well ventilated area.
Fuel vapour is an irritant t o the eyes and lungs, and
if high concentrations are inhaled it may cause nausea,
headache, and depression.
Fuel liquid is an irritant t o the eyes and skin and may
cause dermatitis following prolonged or repeated
contact.
When it becomes necessary t o carry out work
involvingthe risk of contact with fuel, particularly for
prolonged periods, it is advisable t o wear protective
clothing including safety goggles, gloves, and aprons.
If there is contact with fuel the following
emergency treatment is advised.
Ingestion Iswallowing)
Do not induce vomiting. Give thepntient milk to drink (if
none is availabte water can be given). The main hazard
after swallowing fuel is that some of the liquid may get
into the lungs. Send the patient to hospital immediately.
Eyes
Wash with a good supply of clean water for at least 10
minutes.
Environmental protection precautions
tt is illegal to pour used oil onto the ground, down
sewers or drains. or into water courses.
The burning of used engine oil in small space
heaters or boilers is not recommended unless emission
control equipment is fitted. In cases of doubt check
with the Local Authority.
Dispose of used oil through authorized waste
disposal contractors t o licensed waste disposal sites, or
to the waste oil reclamation trade ff in doubt, contact
the Local Authority for adviceor disposal facilities.
Inhalation {breathing in vapour)
Move the patient into the fresh air. Keep the patient
warm and at rest. If there is loss of consciousness give
artificial respiration. Send the patient to hospital.
Exhaust gases
The exhaust gases contain carbon monoxide (CO),
which is odourless and invisible but very poisonous.
High vohage Isvets
Dangerously high vohsge levels are present in an
electronic ignition system. These levels are not only
Skin contact
Immediately drench the affected parts of the skin with
water. Remove contaminated clothing and then wash all
contaminated skin with soap and water.
TSD 4737
A2-1
present in individual components, but also in the wiring
looms, plug& sacketr and test connections.
Both primaty and secondary circuits are subject to
these high wltages.
Therefore. whenever the system is switched &? do
not touch any cornponents/circuits contained within the
ignition system
Always wear thick rubber glows and use insulated
tools when working on the system with the ignition
switched on.
Workshop precsutions
Electrical
Always ensure that the battery master switch is turned
to the OFF position or the battery is disconnected,
before disconnecting or connecting any eteetrical
components. In addition, note the following.
Never disconnect the battery or switch off the
battery master switch when the engine is running.
Always ensure correct polarity when making cable
connections.
Ir is recommendedthat when carrying out tests on
the car wiring. a good quality mufti-meter is used.
Never use generator type meters.
Do not use a test lamp on circuitry that contains
electronic components, such as the ignition system.
Before using test equipment always read the
manufacturer's instructions.
Do not pierce any electricai leads or tooms with test
probes. etc.
Do not remove the high tension lead situated
between the ignition coil and distributor when the
engine is running.
.
Ensure that no arcing takes place:herween -.. electrical connections
Do not supply more than 16 volts direct current t o
the ignition system.
Fire
Fuel is highly flammable, therefore great care must be
exercised whenever 1he fuel system is opened IiAL pipes
or unions disturbed) or the fuel is removed from the
system. Always ensure that 'no smoking' signs and
CO, (carbon dioxide) fire extinguishers are placed in the
vicinity of the vehicle.
Always ensure that the battery is disconnected
before opening any fuel lines.
If the fuel is to be removed from the tank, ensure
that it is siphoned into a suitable covered container.
'Fuel
Pressure
The fuel system contains fuel that may be under high
pressure. Therefore, to reduce the risk of possible injury
and fire, always ensure rhat the system is depressurized
by one of the foIlowing methods before commencing
any work t h a t necessitates opening the system.
1. Allow the pressuret o fall naturally by switching off
the engine and allowing the vehicle to stand for a
minimum of four hours before opening the system.
2. Clean the inlet connection to the fuel fitter. Wrap an
absorbent cloth around the joint and carefully stacken
the pipe nut to release any pressurized fuel from the
system. Tighten the pipe nut. Always dispose of the
cloth carefully, in accordance with the prevailing Health
and Safety regulations.
Cleanliness
It is extremely important t o ensure maximum
cleanliness whenever work is carried out on the system.
The main points are.
1. Inorder t o prevent the ingress of dirt, always clean
the area around a connection before dismantling a joint.
2. Having disconnected a joint (either fuel or air1
always blank off any open connections as soon as
possible
-
3. Any components that require cleaning should be
washed in white spirit and dried, using compressed air.
4. If it is necessary t o use a cloth when working on the
system, ensure that it is lint-free.
Generd
Before working on the ear. always ensure that the
parking brake is firmly applied. the gear range selector
level is in the park position, and f w e A6 is removed from
fuse panel F2 on the main fuseboard.
A number of the nuts. bolts, and setscrews used in
the fuel injection system are dimensioned t o the metric
system, it is important therefore, that when new parts
become necessary the correct replacements are
obtained and fitted.
Terminology
It should be noted that not all of the components listed
are.fiaed to any.one particular model or model year of
car. This section merely explains the abbreviation and
operation of the specialist components used inthe
systems.
Air flow sansor plate
Balances the air flow entering the induction system
with fuel pressure acting an the control pjston.
Air flow sensor potentiorneter
Monitors the quantity of ait flowing into the engine
The information is conveyed ro the ECU as a
measure of engine load and is one of the elements used
in the calculation of ignition timing and fuelling
requirements.
Air pressure transducer {APT)
The air pressure transducer monitors induction manifold
pressura It passes this information to the relevant ECU
so that the necessary electrical corrections can be
made t o the retevant control system.
On cars fined with one APT the unit provides
instantaneous boast pressure information for the fuel
injection end ignition control systems. It also suppties
the information to the boost control system.
On cars fitted with TWO APTs one assembly is
connected to the fuel injection system and the second
unit is connected to the boost control system.
Air pump clutchedpufley
The air injection system is de-activated whenever the
coolant tcrmprature is a b o y 3
3'C (91°F 1 w engine
speed exceeds 3000 + l00 wlmin. This is achieved by
dis-engaging the air pump clutch.
Air swkchingvmlw
The air switching value comprises a vacuum operated
valve with m integml control solenoid.
At coolant temperatures belaw 33OC 19t°F) the
solenoid b energized The resulting vacuum then
applied to the diaphragm chamber opens the valve and
allaws injected air to PISS to the exhaust manifold.
At coolant temperatures above 33OC {91QFl
the solenoid is de-enefgued, the vacuum signal is
inhibited and the injected air is re-routed t o the engine
air intake system.
Auxairy air valve
Allows ealibreted increases in idle circuit air flow and
hence engine speed, with closed throttle plates. 1his
provides the correct mixture strength during cold
starting and warm-up periods.
air intake Closum of the dump valve allows induction
manifold presswe l boost1to build-up during increasing
engine load, tovalues predetermined by the boost
conmh system.
The dump valve also acts as a relief valve /f the
boost presswe exceeds a preset level.
Eleetro-hydraulicactuator (EHAI
Mounted on the fuet distributor. the electro-hydraulic.
actuator replaces the warm-up regulator used on KJetronicsystema A positive increase in cunem (mA)
supply to the EHA results in a corresponding increase in
fuel flow and hence fuel mixture strength.
On 1989 model year cars-fittedwith the
KE3-Settonicfuel injection system, it is also possible t o
have a negative increase in thesupply t o the €HA which
will 'Iran off* the mixture
Engine~ n n i n sensor
g
Inhibits thesupply of power to the fuel pump unless the
engine is running. The only exception being one by-pass
to the circuit. which allows the fuel pump t o operate
when the engine is being 'cranked' by the starter motor.
Check valves
A check valve is fitted into the air injeetion pipe to each
exhaust manifold. The valves prevent the back flow of
exhaust gas.
Cold start injector
Sprays finely atomized fuel during engine cranking (cold
engine) into the induction manifold. The amount and
duration of cold start injector operation a* dependent
upon the coolant ternpenturn
Control piston
Cylindrical plunger type of'&= that moves vertically in
the fuel distributor. A precision machined edge on the
piston opens the metering slits in the fuel distributor.
Coolant temperature sensor
The coolant temperature sensor is located in the
thermostat housing. The internal resistance of the
sensor changes with the engine coolant temperature.
To achieve the correct starting and warm-up
characteristics at low operating temperatures, the ECU
uses the signal it receives from the coolant temperature
sensor to compute the correction factors for the ignition
timing and the fuel injection system electro-hydraulic
actuator.
.Crankshaft refarence sensor
Initiation of A1 ignition and subsequent engine firing
order occurs when The from damper mounted reference
pin passes the crankshaft reference sensor.
Differential pressure vaives
One for each cylinder. maintains the correct pressure of
fuel at the metering slits.
Dump valve
Allows compressed air to recirculate back through the
Engine s p e d sensor
The signal generated by the rotation of the four
segment timing wheel is sensed by the engine speed
sensor. The information is then conveyedt o the KMotronic ECU for calculstion of the engine speed.
Exhaust gas recirculation valw EGR)
The operation of this valve is vacuum controlled.
A proponion of exhaust gas is recirculated from the
exhaust svstem, through the EGR value, into the
induction manifotd where it mixes with intake air.
Exhaust gas wastegate
Regulates the flow of exhaust gas to the turbocharger
turbine when either boost pressure or engine detonation
reach predetermined Iwels. The boost contr01system
actuates wastegate control.
Four segmant timing wheel
The four segment timing wheel has four equal length
segments and gaps. Angular felationship of segment t o
gap is 54 and 36 respectively, ant3 produces a 60:40
ratio signal for engine speed cakulation.
Fuel aceumutatar
When the engine is stopped. the small volume of fuel
held in the accumulator (under pressure from the
accumulator spring) maintains pressure in the primary
fuel circuit to ensure good starting response during the
.engine 'cranking' operation {i.e.fuel is immediately
. ..
availabbl.
. . . ..
..
,
,
Fuel cooler
The fuel cooler is located in the left-hand side of the..
engine compartment. It uses air conditioning system
refrigerant to cool the fuel prior t o its return to the tank.
Fud distributor
Apportions the fuel equally ta h e injectorsadjacent to
each e n ~ i n e
cylinder.
Fuel pressure rngulator
Maintains a eansrant primary circuit fuel pressura
When the engine is stopped. the fuel pressure regulator
allows the system pressure to drop rapidly t o a value
preset by the fuel accumularor (ia.just below the
injeftor valve operating pressure). It also seals the
return tine from the lower chambers of the differential
pressure value.
Haatad ox ygsn sensor
Measures the oxygen content (which is directly related
to the aidfuel ratio) in the exhaust gas and by means of
an electrical signal transmits the information t o the
electronic control unit.
Idle speed actuator
The idle speed actuator contains a stepping motor, the
armature of which is connected to a rotating slide.
This adjusts the crosssectional area of the by-pass
passags
The dury cycle from the K-Motronic ECU produces
a torque at the rotating armature which acts against a
return spring.
The by-pass opening is continuatly adjusted to
maintainthe correct engine idle speed under all
potential engine Load conditions.
Injector
One injector is used for each engine cylinder and sprays
finely atomized fuel under all running conditions into the
induction system.
lntercooier
A charge air intercooler is fitted below the air cleaner
assembly. It is situated in the ambient air stream behind
the air dam and beneath the front bumper. The
intercooler reduces compressed air temperature, this
enables recovery of charge air density and maintains
optimum engine power output.
KEZ-Jetronic electronic control un8 (ECU)
Processes input from a chain of engine mounted
sensors and provides the necessary electronic fuel
corrections in terms of DC mA t o the electro-hydraulic
actuator. This includes start, post s t a n warm-up,
acceleration enrichment, and positive induction
manifold pressure compensation.
K-Motroriic digital ECU
The K-Motronic ECU is mounted in the ECU
compartment in the rear right-handcomet of the engine
compartment.
The K-Matronic system brings together the
benefits of digital fuel injection (KE3-Jeaanicl and
ignition control (£258F)systems into a single electronic
control unit (ECU).Other features of the system include
cold srart and warm-up enrichment, idle speed
regulation. and automatic correction of any long term
mixture strength deviations.
On cars fitted with catalytic conveners the
K-Motronic system also provides an 'on-bard' setf
.diagnostic facility.
The engine is equipped with sweral sensors that
continuously monitor operating parameterssuch as
engine speed, coolant temperature, and load. The
sensors are connected to the digital ECU which is
programmed with eharecteristicdata for the following
functions, mixture strength control, ignition timing, idle
speed control, end purging of the eveporative emission
control canister.
Knock sensors
Sense crankcase vibration and then produce an output
signal which is processed by the boost electronic
contr~ll
unit. If knock is present the ECU signals the
boost conrrol valve t o divert the compressor pressure
signal more towards the wastegate than atrnosphera
'On board' self diagnostic ability
A facia mounted warning panel illuminates to alen the
driver to a number of possible engine related faulta The
lamp displays the message 'Check Engine' and is
illuminated when the engine is running and a failure is
identified.
When the 'Check Engine' lamp is illuminated a fault
message (in the form of a four digit code! is stored
within the K-Motronie ECU and can be subsequently
used to inform workshop personnel of the faulty
components or system.
Pnrssure control vslw
Operating from an electrical signal received from the
electronic control unit. the valve varies the fuel pressure
in the lower chambers of the differential pressure valves.
Pressure damper
Darnpens the pressurepulses caused by the operation
of the pressure control valve.
Purge control valve
This valve is connected into the purge line of the fuel
evaporative emission control system. It regulates the
putge flow rate depending upon engine load and mode
of operation. The valve receives a dury cycle signal from
the engine management system ECU.
Thermal time switch
Situated in the thermostat housing. Depending upon
the temperature of the coolant, it controls the operatian
of the cold stsn injector.
Throttle position switch ITPSI
Identifies the engine operating mode (i.eidle. part load,
or furl ioaul.
Pan load occurs when the switch contacts are
broken between idle and full Load.
Turbocharger
Increases the power and torque of the engine by
utilizing energy from rhe exhaust gas.
Vehicle specification
Specification
l
UK and all countries not Listed
Norway and Sweden
Naturally
Aspirated
Naturally
Aspirated
Turbocharged
Turboc harged
p
-
Engine
L410 1
L 410 If
L 410 IT1
-
-
I
-
87188f89
-
87/88
-
89
-
-
Fuel system
87/88
89
Recircularory with in-tank and main pumps
With fuei cooler
87/88
89
-
87188184
K-Motronic engine management system)
-
87188:89
87/88
89
-
--.
Fuel injection system
Bosch K-Jetronic
Bosch KEZ-Jetronic
Bosch KE3-Jetronic (electronically controiled by
1
-
87/08/89
+
-
87:88
B9
Turbocharging system
Boost pressure control system regulaz~ngexhaust
gas by-passing turbocharger vha a wasregate
-
87/88;89
Ignition control system
Constant energy type. Lucas 35 OM 8 distributor
conventional vacuum and centrifugai advance
87/88/09
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87'88
89
--
87'88
89
87 88
89
8 7 88'89
87'88i89
i
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T
Digital nm-adjustable E2 58F.
Twin 2 X 4 cylinder distributor
,
Digital non-adjustableEZ 58F lelec tronically
controlled by K-Motronic engine management
systemi. Twin 2 X 4 cylinder distributor.
-
Exhaust emission control system
Air injection system
-
-
89
EGR system
-
-
B9
Catalytic converter system with closed-Ioop
-
-
"89
"89
-
88;89
-
W
Fuel cvaporative emission control system
Standard purge control system
Programmed purge control system
1
1
Crankcesr emission control system
Recirculatory closed breather type
89
-
-
87188189
87;88:89
87/88/09
fhronle intake
Rod and feuer system
1
87188
-
With charge air intercoaler
-- -
I
t japan has excessive exhaust temperature warning$+
1
-
89
1
87:88:89
87188!89
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87/88:89
I
Other than Australia
With mods for boos1 system
87:88
87,88:89
89
87/88\89
'Middle East has revised ignition timing "Remote CO tapping
I
89
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Air intake system
Filter rnounted on right-hand inner wing valance
-
89
89
--
87:88:89
87180t89
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Austria and Switzerland
Maddle East and Taiwan
Australia, Canada. Japan.
and USA
Aspirated
Naturally
Asp~rated
Naturally
Aspirated
Narurally
furbocharged
-
87 88/09
-
87
89
-
Turbocharged
-
87 08/89
-
--
-
-
--
-
87
89
B7 88
89
v
87 and 89
'Ld
-
87 88/89
-
87:88
89
87 88
89
h
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87,88189
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07/88/89
'87 88:89
1 89
87188
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a7
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87 88
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B9
-
89
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1
Chapter E
TSD P700
l
89
87/88/89
87 88 89
Workshop
Manual
Turbocharged
87/88i89
87188
89
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B9
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Chapter B
TSD 4737
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Chapter C
TSD 4737
Chapter D
TSD 4737
89
A
Chapter E
TSO 4737
Chapter E
TSD 4737
Chapter 6
TSD 4737
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p
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80 85
e9
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08 89
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"88 89
BR E 9
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"89
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89
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89
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v '871
88/89
' "87188189
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$87108' 89
t 89
tt87188
87!88/09
p
87 '88189
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89
r l
~
87 and B9
87/88;89
87188189
87:88!89
8'7 88!89
87
87;88189
87/88
87188189
89
Chaplet F
TSD 4737
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89
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Chapter G
TSD 4737
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&apter H
TSO 4737
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Chapter J
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TSO 4737
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87 and 89
87/88/89
87/88/89
87/88/89
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Chapter K
TSO 4737
Chapter B
Fuel injection system
I
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8 . .
Sections
Contents
RolleRoyce
Silver
Spur
Silver
Spirit
Comiche /
Comkhe I t
Bentley
Eight
MuIsanne/ Turbo R Cmtinental
Mulsanne S
Contents and issue
record sheet
1987/8&89 model years
Naturally aspirated cars
Fuel injection system
K-Jetronk
-
198 7/88 modd years
Turbocharged cars
Fuel injection system
KE2-Jetronic
-
1 989 model year
Turbncharged cars
Fuel injection and
Ignition control systems
K-Motronic
5/88
-
TSD 4737
.
:
B1-l
Issue record sheet
The dates quoted bsbw refer to the issue date of individual pages within this chapter.
Sections
I B1
I P#
(a3
Paae No.
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1
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B4
IF-a
m
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TSD 4737
B1-3
Section B2
Fuel injection system
K-Jetronic
at the engine idle speed setting, during manufaciure.
of the vehicle. This is achieved by turning a screw
which alters the position of the air flow sensor plate
lever relativeto the control piston. Turning the
adjustment screw either raises or lowers the controi
piston for a given engine idle speed position of the air
flow sensor plate, thereby richening or weakening the
idle mixture. The adjustrrient scmw is subsequently
sealed and no further mixture adjustment should be
necessary.
Naturally aspirated engines are fitted with the Bosch
K-Jetronic continuous fuel injection system.
f he K-Jetroniesystem is a mechanically and
hydraulically controlled fuel injeciion system that
requires no form of drive.
The basic principle of operation is that the
accelerator pedal controls the movement of the
throttle plates which regulate the amount of air drawn
into the engine. An air flow sensor fitted upstream of
the throttle plates, monitorsthe quantity of intake air
entering the system. Dependent upon the volume of
air metered, a fuel distributor apportions a quantity of
fuel to the injector adjacent to each cylinder.
The air flow sensor and the fuel distributor are
combined into one assembly known as the mixture
control unit (see fig. 82-21.
The precisely metered quantity of fuel is
continuously sprayed from the injectors in a finely
atomized form into the induction manifold behind the
engine inlet valves. Theairffuel mixture is then drawn
into the engine cylinders whenever an inlet valve
opens.
Cars fitted with a catalytic converter also have a
'closed loop' (lambda control) system. This system
accurately controls the airlfuel ratio about the
stoichiometric value which is necessaryto achieve
efficient operation of the three-way catalytic
converter.
Differential pressure
valves (upper chambers) 4,6 bar (67.0 Ibflin2)
Differentialpressure
valves (lower chambers) 4,7 bar (68.1 Ibf/ina)
nominal
Control circuit (variable
dependent upon engine
temperature)
0.5 barto 3,6 bar
(7.25 tbflin2to 52.2 lbflinz)
Fuel injector pressure
3,6bar (52.2 Ibflina)
Air Row sensing
The sir flaw sensor consists of an air cone in which
moves an air flow sensor plate mounted on a pivoted
lever (seefig. 82-31. When the engine is operating the
sensor plate is deflected into the air cone, the
deflection being dependent uponthevolume of air
passing through the cone. The air will deflect the
sensor plate until a state of balance exists between
the force on the air sensor plate and the counter force
provided by fuel at a constant pressure acting on the
end of the control piston.
The weight of the sir sensor plate and connecting
lever are balanced by a counterweighton the fuel
distributor side of the lever.
Movement of the control piston and its horizontal
control edge Isee fig. 82-3)either increases or
decreasesthe open area of the eight metering slits
{onefor each engine cylinder) in the fuel distributor.
Differential pressure valves (one for each
cylinder) located within the fuel distributor, maintain
a constant pressure drop across the metering slits.
Since the airflow sensor plate and the control
piston are operated by the same lever, therate of fuel
discharge is proportionalto the deflection of the air
sensor plate which is governed by the calibrated cone
within the funnel.
The mixture strength of each engine is adjusted
Primay fuel circuit (see fig. 82-4)'
The primary circuit fuel pressure is regulated by a
plunger type valve to nominally 5,2 bar to 5,8 bar
175.4 lbflinPto 84.1 ibf/inz).
In the fuel distributor the fuel initially enters a
passage which joins with the lower chambers of the
differential pressure valves via a small fixed orifice
Isee fig. 82-7).
When the engine is operating the fuel flows
through the metering slits (machinedinto the barrel
of the fuel distributor)to the upper side of the
diaphragm in the differential pressurevalves. Then
through injector lines to the injector valves.
The injector valves have an opening pressure of
approximately3,6 bar (52.2 Ibf/inz)and are designed
to spray finely atomized fuel under all operating
conditions,
From the primary fuel circuit a fuel line feeds the
cold start injector.
When the engine is stopped, the primary system
pressure regulator allows the system pressure to
drop rapidly to a pressure governed by the fuel
accumulator which is just below the injector opening
pressure and maintains it at this level by sealing the
return line to the fuel tank. This sealis effected by a
rubber '0' ring fitted to the valve which is compressed
against the fuel distributor housing (see fig. 52-5).
Fuel circuit
The fuel supply system comprises the primary circuit,
control circuit, and the lambda control circuit (if fitted).
The fuel is at different pressures in various patts
of the circuit as follow.
Primary circuit
5,2 bar to 5 8 bar
(75.4 Ibflin2to 84.1 Ibf/in2)
-
TSD 4737
Fig. 82-1 Enginecompartment d m i l s
1 Idle speed control solenoid
2 Fuel pressure damper
3 -Fuel pressurecontrol valve
4 Auxiliary air valve
5 Fuel distributor
6
7
8
9
10
Secondary throttle spindle
Air meter
Primary throttle spindle
Acceleration enrichment switch
Warm-up regulator
Simultaneously a push valve, integral with the system
pressure regulator closes and prevents leakage
through the control circuit. This retention of fuel
pressure in the system is important because during
'hot soak' conditions it prevents fuel vaporization'and
subsequent poor starting. In addition, the sudden
pressure drop at the fuel injectors (causingthem to
close) prevents 'dieseling' (i.e. the tendency of an
engine to continue 'running-on' after the ignition has
been switched off).
Cantrot fuel circuit (see fig. 82-41
f he control circuit provides the control pressure that
acts upon the upper end of the control piston and
provides the balancingforce for the air load acting on
the air sensor plate. In addition, it also provides a
means of enriching the mixture for cold starting.
The control circuit is supplied with fuel from the
primary circuit through a restrictor in the fuel
distributor (see fig. B2-7).The fuel then passes either
into the chamber above the control pistan via a
damping restrictor or via an external connection to
the warm-up regulator, where nominal control
pressure of 3,6 bar (52.2 IbfJin2)[3,5 bar (50.7 Ibf/in2)
on cars f i e d with a lambda control system1 is
maintained at normal engine operating temperature
(at sea level).
The pressure regulator in the warm-up regulator
is tensioned by a bi-metal spring when the engine is
cold. This in turn reduces the load on the regulating
valve and correspondingly lowers the control
pressure.
With a tower control circuit pressure, the air flow
sensor plate is allowed to travel further downwards in
the air cone for a given rate of sir consumption which
in turn; moves the control piston further up'in the
barrel of the fuel distributor. This increasesthe
opening of the fuel metering slits and thereby
enriches the mixture.
The bi-metal of the warm-up regulator is heated
electrically whenever the engine is running. This
causes the effect of the bi-metal to be reduced with a
corresponding reduction in the amount of mixture
enrichment.
The warm-up regulator is mounted so that it can
assume the temperature of the engine. Therefore,
when the engine is started in the semi-warm
condition, unnecessary enrichment of the airlfuel
rni~ture
is avoided.
Fuel from the warm-up regulator flows through
the push valve assembly which assists in maintaining
the pressure by closing the primary circuit when the
engine is switched off. Excess fuel flows around the
push valve and into the fuel tank return line which is
not under pressure (see fig. 02-41.
Fuel distribution (see fig. B2-4)
To-ensurethatthe fuel is uniformly distributed to the
cylinders a control piston and barrel assembly is used
(see fig. 82-1 1l. This assembly operates by controlling
the open cross sectional area of the metering slits
machined in the-barrel.
Fig. 02-2 Mixture acmtml unit
1 Air intake
2 Fuel supply to distributor
3 Fuel distributor
4 Fuet feed to injector
5 Fuel feed to warm-up regulator
6 System pressure regulator
7 Fuel return from warm-up regulator
8 Fuel return to tank
9 fuel feed to cold start injector
10 Fuel feed to pressurecontrol valve
11 Air meter
Fig. 62-3 Airflow sensor and fuel distributor
(mixturecontrol unit)
Fuel feed pipe to injector
Fuel distributor assembly
Control piston
Fuel distributor barrel
Differential pressure valve
Position of sir sensor plate at idle speed
Air meter
Air flow sensor plate
Pivot
Counterbalance weight
Fuel inlet
TSD 4737
B2-3
Fig. B2-4
Fuel injection system
Key to fig. B24 Fuel injection system
1 Thermostat housing
2 Thermal time switch
3 Air cone
4 Air meter
5 Air sensor ptate
6 Differential pressure valve
7 Comrol piston
8 fuel distributor
9 Anti-suction valve
10 System pressure regulator
11 Warm-up regulator
72 Fuel damper
13 Pressure control valve
14 Electronic control unit (ECU)
15 Oxygen sensor
16 Exhaust system
17 Fuel pre-pump
18 Fuel pump
19 Fuel pressure damper
20 Fuel filter
21 Fuel cooler
22 Fuel aeeurnulator
23 fuel tank
24 Throttle body
25 Idle speed adjusting screw
26 Cold start injeetor
27 Injector
28 Auxiliary air valve
29 idle speed control solenoid
A Upper chamber pressure
B Lower chamber pressure
C Control pressure
D Primary circuit pressure
E Injection pressure
F Unpressurizedreturnline
G Pre-pump t o main pump supply pressure
Fig. B2-5 System pressurermgulator
1 Fuel return to tank
2 System pressure line
3 Fuel return from warm-up regulator
4 Push valve
5 Regulator valve sealing face
Note Items 12,13,14and 15 arefittedto cars with a
lambda control system Iclosed loop mixture
control).
1he barrel has one slot shaped opening (the
rectangular metering slit) for each cylinder. Each
metering slit has a differential pressure valve to hold
the drop in pressure at the metering slits constant at
the various flow rates. As a result, effects of variations
in the primary system pressure and differences in the
opening pressure of the injector valves are eliminated.
With a constant drop in pressure at the metering
slits, the amount of fuel flowing t o the injector valves
depends solely upon the open cross sectional area of
the slits.
Differential pressurevalves (seefigs. B2-4 and 02-71
There is a differential pressure valve for each engine
cylinder. The valve is a diaphragm type consisting of
an upper and lower chamber with the diaphragm
separating the two halves (see fig. 82-7).The basic
principle of operation is that the fuel pressure in the
upper chamber is at approximately 0.1 bar (1.5 Ibf/inz)
less than the pressure in the lower chamber. The
Fig. B24 Relationship between primary circuit
pnnrsum and control pressure
1 Damping restrictor
2 fuel feed to warm-up regulator
3 Differential pressure valve
4 Control circuit pressure
5 Control circuit restrictor
6 Primary circuit pressure
7 Control piston
pressure differential is produced by the helicalspring
built into the upper cham bet. Under these conditions
equilibrium of forces exists at the diaphragm.
If additionat fuel flows through the metering slit
into the upper chamber, the pressure rises
temporarily. This increase in pressure will force the
diaphragm downwards until a differential pressure of
0.1 bar (1.5 Ibf/in2)again prevails at the metering slit.
At higher rates of fuel flow, the diaphragm opens
a larger annular cross section, so that the pressure
differential remains constant. If the rate of fuel flow
decreases, the diaphragm reduces the amount of fuel
flowing into the injector line.
The total travel of the diaphragm is only a few
hundredths of a millimetre.
Note f he fuel pressure in the lower system and
therefore, the pressure differential between the
two halves of the chamber is affected slightly
by the operation of the lambda control system.
'Closed loop' mixture control system
(Lambda control system)
Cars fitted with a catalytic converter also have a
'closed loop' lambda control system.
The lambda control system is an addition to the
K-Jetronic fuel injection system and isfitted to give
accurate control of the airlfuel ratio about the
Fig. 82-7
A
B
Diiwential pmssure valve
High flow rate
Low flow rate
stoichiometric value which is necessary to achieve
efficient operation of the threeway catalytic
converter.
The control principle is based on the fact that by
means of the oxygen sensor the exhaust is
continuously monitored and the amount of fuel fed to
the engine is continuously corrected.
With an ideal (stoichiometriclair/fuel mixture the
'air factor is identified by the value * A= 1. At this
mixture ratio the output signal from the oxygen
sensor develops a voltage jump which is processed
by the electronic control unit. This voltage changes
sharply for small deviations from the stoichiometric
mixture (the airlfuel ratio for full combustion of the
fuel). The electronic unit therefore, controls the
injection system for 'closed loop' fuel metering by
modulating the signal to the pressure control valve.
This in turn, affectsthe pressure in the lower
chambers of the differential pressurevalves.
By responding to the unconsurnedoxygen
content of the exhaust gas, the sensor registers the
extent of the complete combustion and regulates the
airffuel mixture to the ideal or stoichiometric ratio.
X
Fig. B24 injector
1 Nozzle
2 Insulating sleeve
3 Fuel supply connection
4 Filter
Actual intake air
=
Theoretical requirement
Description af the components
Injector (seefig. B2-81
An injector is fitted into the inductionsystem just
behind each inlet valve. The injector opens
automatically when the fuel pressure in the injection
lines reaches 3,6 bar (52.2 Ibf/in2).It has no metering
functions, its purpose being to continually spray finely
atomized fuel under all running conditions. The
injector is supported in a spetially shaped moulded
rubber sleeve, it is pressed (not screwed) into
position. The hexagonal section is provided to hold
the injector while the fuel line is attached. A retention
plate is fitted over the injector and secured to the
cyIinder head by two small setscrews, each plate
retains two injectors.
Cold start injector (seefig. 82-91
In order to facilitate engine starting particularly from
low ambient temperatures, a cold start injector is
fitted into the induction manifold and sprays
additional finely atomized fuel during engine
cranking. A thermal time switch mounted in the
thermostat housing controls the operation of the cold
start injector. This injector ceases to operate when the
ignition key is released from the START position.
In the cold start injector a helical spring presses
the movable armature and seal against the valve seat,
closing the fuel inlet. When the armature is energized
{and therefore drawn upwards) the fuel port is opened
and the pressurized fuel flows along the side of the
armature to the swirl nozzle.
Idle speed adjustment screw [see fig. 82-10)
this adjustment screw is situated at the forward end
of the throttle body and allows limited adjustment of
the engine idle speed. During manufacture of the
vehicle the engine idle speed is set using the throttle
butterfly valve adjusting screws. These screws are
situated on the side of the throttle body and sealed
after the initial adjustment.
Afterwards, adjustment to the engine idle speed
is by means of the idle air bleed screw situated at the
forward end of the throttle body. This screw is the
only means of limited adjustment to the engine idle
Fig. B26 Cold start injector
1 Electricsl connection
2 Fuel inlet
3 Magnetic coil
4 Sealing ring
5 Swirl n o u l e
6 Armature
speed.
ldle speed control soknoid {see fig. 82-10)
Movingthe transmission selector from the neutral
position causes the engine idle speed t o decrease,
due to the additional load of the transmission.
To compensate for this idle speed decrease a
solenoid valve is opened (energized) when the
transmission selector i s moved from the neutral
position into any forward gear. This allows more
intake air to by-pass the throttles and effectively
increase the idle speed to the optimum setting.
Air flow sensor plate (see fig. 82-3)
f he sensor plate is housed in the air venturi of the air
meter. Its function is described on page 82-1 under
the heading of Air flow sensing.
DiFferential pressurevalues {see fig. B2-7)
The differential pressure valves (one for each engine
cylinder) are housed in the fuel distributor. Their
function is describedon page 82-5 under the heading
Differential pressure valves.
Fig. 82-10 Idle spe- Gun
1 ldle speed adjustment screw
2 Idle speed control solenoid
TSD 4737
Fwl distributor (see fig. 82-31
The fuel distributor forms part of the mixture control
unit. Its funaion is described earlier in this section.
-Control piston (seefigs. B2-3 and B2-111
This is a cylindrical plunger type of valve that moves
vertically in the fuel distributor. It is operated by a
lever connededto the air flow sensor plate.
A precision machined edge on the control piston
opens the fuel meteringslits in the fuel distributor
barrel and therefore. controls the amount of fuel
injected into the engine cylinders.
System pressure rsgubtor (see fig. 82-5)
When the engine is operating this regulator maintains
a constant primarycircuit fuel pressure. When the
engine is stopped, the regutator valve allows the fuel
pressure in the primarycireuit to fall rapidly to just
below the injector opening pressure. In rrddition, the
push valve (the smaH valve on the outer end of the
regulator) closes and prevents leakagefrom the
control circuit.
Fuel pressure damper {see fig. B2-12)
Fitted to cars with a lambda control system.
This assembly is designed to 'damp' the pressure
pulses caused by the operation of the pressure control
valve.
Fuel pressure control valve (see fig. B2-f 21
Fig. 82-1t Fuel distributor barrel and control
piston
1 Fuel distributor barrel
2 Fuel metering slits
3 Piston control edge
4 Fuel inlet poes
5 Control piston
fig. 82-12 Fuel pressurecontrol valve and damper
1 Air intake elbow
2 Fuel feed from disfrihutor
3 Pressuredamper
4 Crankcase breather housing
5 Pressure control valve
6 Cold start injector
Fitted to cars with a lambda control system.
This valve is operated by an electrical signal
received from the electronic control unit.
The pressure control valve receivessquare-wave
pulses of constant frequency t70 cycles per second)
but of variable width (i.e. the proportion of time that
the valve remains open during any one cycle is
variable, controlling the flow rate through the valve).
This action varies the fuel pressure in the tower
chambers of the differential pressure valves.
Electronic mntml unit (ECU) (see fig. 82-13]
Fitted to cars with a lambda control system.
The electronic control unit, converts the electrical
signal from the oxygen sensor into a hydraulic
of the fuel mixture. This is achieved by the
correc~ion
signal it transmits to the pressure control valve.
The oxygen sensor reacts to a change from a
weakto a rich mixture with a vottage jump which is
processed by the electronic control unit.
As a result of this change to a richer mixture, the
control unit changes the open-closed ratio of the
pressure control valve smoothly towards a weaker
mixture, until the oxygen sensor reacts to the
resulting weaker mixture. This develops a voltage
jump in the opposite direction, causing the openclosed ratio of the pressure control valve to be
changed in the richer mixture direction.
To avoid driving continuously with a weak
mixture if the oxygen sensor malfunctions. the control
operation is periodically monitored within specified
fixed time spans and. in the event of a defect, the
controt operation is switched to the 'internal-signal
mode'. When in this operating mode the pressure
conrrof valve receives a constant pulse signal to
control the on-off ratio. In addition a warning lamp
situated on the facia will be illuminatedto indicate
thar attention is necessary.
In addition to the basic fundion of the electronic
control unit to evaluate the signal from the oxygen
sensor, it also performs the following additional
- functions.
Until theoxygen sensor attains its operating
temperature, a control function cannot take place.
Therefore, during this warm-up periodthe electronic
control unit isswitched to the 'internal-signal mode'
('open loop control').
When it is necessary for the engine to operate
under full load conditions it is also desirable to switch
from the 'external-signal mode' or 'closed loop
control'. This is achieved by a throttle position switch,
situated on the side of the throttle housing activating
a micro-switch and thereby, switching the electronic
control unit into the 'internal-signal mode'.
Simultaneously. the electroniccontrol unit
modifies the signal to the pressure control valve to
provide the additional enrichment required for
satisfactory engine operation at full throttle.
Oxygen sensor (see fig. B2-14)
Fitted to cars with a lambda control system.
The oxygen sensor measures the oxygen content
in the exhaust gas and by means of an electrical signal
transmits the informationto the electronic control
unit.
The assembly consists of a sintered zirconium
dioxide ceramic, impregnatedwith certain metal
oxides. The surfaces of the tube are coated with a thin
layer of platinum. In addition, a porous ceramic layer
is applied to the outer side which is exposed to the
exhaust gas. The surface of the hollow inner side of
the ceramic tube is in contact with the ambient air.
When in position, the ceramic sensor tube is
subjected to the exhaust gas on the outside, whilst
ambient air is allowed to pass inside the sensing tube.
If the oxygen concentration inside the-sensordiffers
from the outside. a voltage is generated between the
two boundary surfaces due to the characteristics of
the material used. This voltage is a measure of the
difference in the oxygen concentration inside and
outside the sensor.
The ceramic sensor tube exhibits a steep change
in signal output (approximately1000 mV) when
stoichiometric conditions are approached (see fig.
32-151.
The oxygen sensor will only exhibit this steep
change in signal output when a certain predetermined operating temperature is attained.
Therefore, to reduce the axygen sensor's dependency
upon exhaust gas to maintain it at operating
.temperature, the sensor is heatedefectrically,using a
ceramic heating rod fitted inside the zirconium
dioxide tube.
When staRing the engine, paniculariy from cold,
satisfactow 'closed loop control' is not possible.
During these conditions the electronic control unit
supplies a fixed on-off ratio signal ('internal-signal
mode') until the oxygen sensor attains its operating
temperature. otherwise driveability would be
impaired at this time without the regulating effea of
fig. B2-I 3 Electronic control unit
1 Knee roll sensor (Auto ACU)
2 Electronic control unit
3 Test lead {blacldslarel
Fig. 62-14 Oxygen sensor
l Two spring contactsfor heater
2 Ceramic insulator
3 Heater
4 Ceramic sensor body
5 Protective tube
6 Air side
7 Exhaust gas side
8 Supporting ceramic
9 Protectivesleeve
10 Contact for sensor
control valve operation. If the oxygen sensor fails to
function, this fixed on-off ratio signal is transmitted to
the control valve in addition to illuminating a warning
lamp on the facia.
Anti-suction vdve (see fig. 82-41
When the engine is switched off it is possible for some
fuel to vapourize and a depression can then occur
above the control piston when the fuel condenses.
The depression would tend to rift the control
piston and cause an excessively rich mixture when
the engine is started.
TSD 4737
82-9