1987 NISSAN PULSAR oil type

70 Cooling and Heating Systems


Installed view of the heater hoses. 1.6 liter models with the air cleaner removed for clarity
.
When the engine is at normal operating
temperature and the heater valve is open,
both of the heater hoses should feel
warm/hot. If the valve is not allowing the
coolant to flow, one hose will be hot while
the other will be cold.

NO COOLED AIR INSIDE VEHICLE
(1) Compressor drive belt slipping or broken:
Renew and/or adjust the drive belt as described in the
Engine Tune-up section.
(2) Insufficient refrigerant: Check the system for
leaks and charge as necessary. Refer to the Air
Conditioning heading in th is section for information
on checking the refrigerant level. (3) Compressor inoperative: Check for power to
the compressor clutch before removing the compres-
sor for repair by a specialist. (4) Heater system allowing warm air to mix with
cooled air: Check the operation of the heater system.
NOTE: The above trouble shooting proce-
dures are basic checks only. If the air
conditioning system is suspect, it is rec-
ommended that the vehicle be taken to an
authorized dealer for testing and repair.
It is normal for water to be seen drain-
ing under the vehicle from the evaporator
after the vehicle has been operated with
the air conditioning on.

3. DESCRIPTION
The cooling system is of the sealed, pressurized
type with fan and water pump assistance. The system
is pressurized in order to raise the boiling point of the
coolant and so increase the efficiency of the engine.

Provision for pressure a nd vacuum relief of the
system is incorporated in the radiator cap.

The radiator overflow hose is connected to a
reserve tank mounted adjacent to the battery. As the
coolant volume expands due to an increase in tem-
perature, the pressure valve in the radiator cap opens
and allows the excess coolant to flow into the reserve
tank. When the engine is stopped and the temperature
of the coolant falls, the vacuum valve in the radiator
cap opens and allows the excess coolant in the reserve
tank to siphon back into the radiator. Thus the
necessity for frequent topping up of the coolant is
eliminated.

The temperature of the cooling system is con-
trolled by a thermostat located in the thermostat
housing attached to the cylinder head.

The thermostat prevents circulation of coolant
through the radiator by directing coolant through the
by-pass circuit, until the engine has reached operating
temperature. This restricted circulation allows the
engine to reach operating temperature quickly, im-
proving drivability and fuel economy.

Removal of the thermostat to cure overheating is
not recommended because th e by-pass circuit will
remain open reducing the amount of water flowing
through the radiator.

An anti-corrosion inhibitor should always be
added to the coolant to protect the cooling and
heating systems from corrosion.

The water pump is mounted to the front of the
engine and is driven by the camshaft drive belt. It is
equipped with a double row ball bearing and a spring
loaded seal assembly. The water pump is a disposable
unit and cannot be repaired.

The fan is driven by an electric motor which is
actuated by the coolant temperature sensor and the
control unit.

On vehicles equipped with air conditioning, an
additional electric fan is m ounted to the radiator. This
fan is controlled by a sw itch connected to the air
conditioning compressor.

The radiator consists of an aluminum core with
plastic side tanks. Minor damage to the core can be
repaired using Nissan repair agent.

The left hand tank of the radiator houses the
transaxle oil cooler on automatic transaxle models.

To drain the cooling system a drain plug is
provided on the lower radiator pipe outlet.

4. RADIATOR
NOTE: To avoid scalding, use caution when
releasing the radiator cap on an engine
which is at the normal operating tempera-
ture. Turn the cap anti-clockwise to the first
stop and allow any pressure in the system to
release. When the pressure is released turn
the cap past the stop and remove it from the
radiator.

82
FUEL AND ENGINE MANAGEMENT
CAUTION: To prevent severe electrical shock, extreme care must be taken when
working on or near the electronic ignition system as dangerous high tension voltages
are produced in both the primary and secondary circuits. See the text fo\
r
precautionary notes.

SPECIFICATIONS
FUEL INJECTION
Type:
1.6 liter engine .................................. Single point
1.8 liter engine................................... Multi point
FUEL PUMP
Type ................................................................ Electric
Pressure at idle:
1.6 liter engine ..................................... 62-90 kPa
1.8 liter engine ................................ 190-230 kPa
FUEL FILTER
Type ................................................ Inline, disposable
AIR FILTER
Type ................................... Disposable paper element
DISTRIBUTOR
Make ........................................................ Delco Remy
Advance contro l .......................................... Electronic
Rotation of rotor .................................. Anti-clockwise
Firing order....................................................1 -3-4-2
ADJUSTMENTS
Base idle speed ..................................... 550-650 rpm
Ignition timing.......................................... 10° BTDC
TORQUE WRENCH SETTINGS
Throttle body nuts.......................................... 10 Nm
*Throttle body bolts ........................................ 12 Nm
*Fuel hose fittings............................................ 35 Nm
Fuel rail bolts ....................................................8 Nm
Fuel tank drain plug ........................................ 24 Nm
Coolant temperature sensor ............................ 12 Nm
Oxygen sensor .................................................. 40 Nm
MAT sensor..................................................... 14 Nm
*1.6 liter engine
l . 8 liter engine

1. FUEL AND ENGINE MANAGEMENT
TROUBLE SHOOTING

NOTE: The following Trouble Shooting pro-
cedures are basic checks only. If these pro-
cedures fail to locate the fault, refer to the
System Diagnosis and Adjustments heading
for more thorough testing.

Prior to performing any of the following
operations, refer to the Service Precautions
and Procedures heading.

ENGINE WILL NOT START OR HARD TO
START
(1) Water in the fuel: Dr ain the fuel from the
system and renew the fuel filter.
(2) Fault in the power supply: Check the battery,
fusible links and fuses. Check for clean, secure con-
nections, particularly the earth connections. Check the
EG1 and fuel pump relays.
NOTE: If the fuel pump relay fails, power
will be supplied to the fuel pump via the oil
pressure switch. When starting the engine,


Check that the MAP sensor hose is not blocked or split
and ensure that all electrical connections are clean and
secure.

Fuel and Engine Management 89
The procedure for fabricating an LED test lamp is
fully described in the El ectrical System section.

If a conventional test lamp with a filament type
bulb is to be used, ensure that the current draw of the
test lamp does not exceed 0.3 amp to avoid damage to
the electronic components.

To check the current draw connect an accurate
ammeter, such as the multimeter described previ-
ously, in series with the test lamp and a battery.

If the ammeter reads less than 0.3 amp the test
lamp is suitable.

Tachometer
(1) Disconnect the resistor from the tachometer
pick-up wiring connector which is located on the
ignition coil wiring harness, and connect the positive
lead of an accurate tachometer to the brown wire
terminal in the wiring connector. (2) Connect the negative lead to a good earthing
point.

View showing the location of the tachometer pickup
wiring connector with the resistor installed.
Timing Light
(1) Connect the timing light to the engine fol-
lowing the instrument manufacturers instructions.

NOTE: Do not connect or disconnect the
timing light with the engine running as
voltage surges could damage the alternator
or control unit. Do not allow the high
tension leads to open circuit with the engine
running as damage to the engine manage-
ment system could result.

(2) Do not connect the timing light positive lead
to the alternator output terminal. Where possible,
connect the power leads of the timing light to an
external power source to prevent possible transient
voltages damaging the alternator or control unit.

4. SYSTEM DIAGNOSIS AND ADJUSTMENTS
NOTE: Due to the use of complex electronic
components in the engine management sys-

tem, the diagnosis and testing procedures
described in this section should not be
carried out by persons lacking an under-
standing of electronics and the precautions
associated with the servicing of electronic
components. It is rec ommended that should
a fault arise in the system, the vehicle be
referred to an authorized workshop.

The control unit can be damaged by
component faults not indicated by the self
diagnosis codes and the renewal of the
control unit without lo cating the cause of
the failure will result in the failure of the
replacement unit. It is for this reason that
the practice of substituting components to
isolate faults is not recommended.

Prior to performing any of the follow-
ing operations, refer to the Service Pre-
cautions and Procedures heading.

PRELIMINARY CHECKS
Prior to performing the Self Diagnosis Test Pro-
cedures, perform the following preliminary checks and
rectify any problems as necessary.

(1) Check for an adequate supply of fuel in the
fuel tank. (2) Check the wiring connectors and earth points
of all engine management components for clean,
secure connections. To prevent damage to the control
unit, disconnect the negative battery terminal before
disconnecting any engine ma nagement wiring connec-
tors. (3) Check the condition of the battery. Refer to
the Electrical System sectio n for checking procedures.
Rectify any faults as necessary. (4) Check the air cleaner element for restriction.
(5) Check for air leaks at the throttle body, inlet
manifold and all related hoses. (6) Check the fuel pump pr essure as described
later in this section. (7) Ensure that the engine is in a satisfactory
mechanical condition and is in tune. Refer to the
Engine and Engine Tune-up sections as necessary.
SELF DIAGNOSIS

This function is very useful in locating system
faults particularly intermittent problems. However,
the self diagnosis mode does not provide comprehen-
sive testing of the engine management system, and
therefore should always be used in conjunction with
the other test procedures described later, in order to
accurately locate system faults.

To Interpret Self Diagnosis Codes
Once the self diagnosis mode is activated, various
fault codes will be displayed as a series of flashes by
the ECM warning lamp on the instrument cluster.

117
EMISSION CONTROL
INTRODUCTION
To reduce the output level of the three primary
automotive emissions, carbon monoxide (CO), hydro-
carbons (HC) and oxides of nitrogen (NOx), and thus
comply with legislation on the maintenance of clean
air, several different emissi on control systems are used
in the Pulsar range of vehicles covered by this manual.

The systems will be discussed under the headings
( 1 ) Crankcase Ventilation System, (2) Evaporative
Control System, (3) Air Preheat System — 1.6 Liter
Engine and (4) Exhaust Control System.

1. CRANKCASE VENTILATION SYSTEM
DESCRIPTION
The crankcase ventilation system is of the closed
type and is designed to prevent crankcase vapors
being emitted into the atmosphere. Crankcase
vapors are caused by gases escaping past the piston
rings into the crankcase during the combustion pro-
cess.

The crankcase vapors are collected in the cam-
shaft housing from the cra nkcase via the various oil
drain passages and the pipe from the side of the
crankcase.


The crankcase vapors are then drawn into the
engine via a branched hose connected to the camshaft
housing oil baffle and the throttle body (1.8 liter
engines) or inlet manifold (1.6 liter engines).

At idle speed, vapors are drawn through the
small branch of the hose and into the engine.

As the engine speed increases, vapors are also
drawn into the engine via the main hose.

TO SERVICE THE SYSTEM
(1) At intervals of 40 000 km, disconnect the
small engine ventilation hose from the throttle body
or inlet manifold and check that the metering orifice
is not blocked.

If necessary, clean the orifice using compressed air
and solvent.

(2) Disconnect all the engine ventilation hoses
and check for blocking, collapsing and deterioration.
Renew the hoses as necessary.

2. EVAPORATIVE CONTROL SYSTEM
Special Equipment Required:
To Test Purge Valve — Hand vacuum pump
DESCRIPTION
The evaporative control system reduces the
amount of hydrocarbons emitted to the atmosphere
through fuel evaporation.

The vehicles covered by this manual use an
absorption regeneration system to reduce vapor loss.
The system utilizes a canister of activated charcoal to
trap and hold the fuel vapors until they can be fed
into the induction system for burning in the combus-
tion chambers.

The basic components of the evaporative control
system are a fuel tank with a sealed filler cap, a
charcoal canister with a pur ge control valve, a fuel
check valve and pipes a nd hoses to connect the
various components.

NOTE: The fuel tank filler cap is not vented
to the atmosphere but is equipped with a one
way relief valve to prevent a vacuum form-
ing in the fuel tank.
View of the engine ventilation hoses and pipe. 1.8 liter
engine.

121
CLUTCH
SPECIFICATIONS
Type................................................... Single dry plate
Operation................................................... Mechanical
Pressure plate type .................................... Diaphragm
Release bearing type .......................Prelubri cated ball
Driven plate:
Outside diameter .................................... 215 mm
Rivet depth limit ....................................0.3 mm
Runout limit .........................................0.5 mm
Maximum spline backlash ...................0.7 mm
Pressure plate:
Diaphragm spring height
(installed) ...................................... 30.5-32.5 mm
Spring finger vari ation limit.....................0.5 mm
Clutch pedal:
Height .............................................. 175-185 mm
Free play ....................................... 12.5-17.5 mm
Release lever free play............................ 2.5-3.5 mm
Flywheel machining limit ...............................0.3 mm
TORQUE WRENCH SETTINGS
Pressure plate bolts.......................................... 29 Nm
Pedal pivot pin nut ......................................... 22 Nm
Cable loc knut.................................................... 4 Nm
Lower clutch housing to engine bolts.............. 21 Nm
Centre and upper clutch housing
to engine bolts .................................................. 49 Nm
1. CLUTCH TROUBLE SHOOTING
CLUTCH SLIPPING
(!) Worn driven plate facing: Check and renew
the clutch driven plate.

(2) Insufficient clutch pedal free play: Check and
adjust the clutch pedal free play. Ensure that the
release lever free play is correct.
(3) Weak or broken pressure plate diaphragm
spring: Check and renew the pressure plate assembly. (4) Worn or scored flywh eel: Machine or renew
the flywheel. Worn or scored pressure plate face: Renew the
pressure plate assembly.


Renew the clutch driven plate if the friction material is
worn down to, or is within 0.3 mm of the rivets.
NOTE: In most cases clutch slippage is first
evident by a marked increase in engine revs,
for no apparent reason, when pulling up a
steep hill. The clutch condition can be
positively diagnosed as follows: With the
handbrake firmly applied, and the rear
wheels chocked, select top gear and release
the clutch with the engine running at ap-
proximately 2 000 rpm. Clutch slippage is
evident if the engine does not stall. Make the
test as quickly as possible to prevent any
further clutch damage.

CLUTCH SHUDDER
(1) Oil on the driven plate facings: Renew the
clutch driven plate. Invest igate and rectify the source
of the oil leak.
(2) Scored pressure plate or flywheel face: Re-
new the pressure plate assembly or machine the
flywheel. (3) Loose or damaged driven plate hub: Check
and renew the clutch driven plate. (4) Loose driven plate facings: Renew the clutch
driven plate. (5) Cracked pressure plate face: Renew the pres-
sure plate assembly.

122 Clutch


Check the engine mountings for damage and deterio- ration.
NOTE: Clutch shudder is usually most
evident when reversing up an incline. As
loose or damaged engine mountings are a
cause for clutch shudder, thoroughly check
the engine mounting rubbers and mounting
hardware for damage or looseness before
removing the clutch for inspection.

CLUTCH GRAB
(1) Oil soaked driven plate facings: Renew the
clutch driven plate. Invest igate and rectify the source
of the oil leak.
(2) Cracked pressure plate face: Renew the pres-
sure plate assembly. (3) Loose or broken engine mountings: Check
and renew the engine mountings as necessary.
(4) Binding release mechanism: Check the oper-
ation of the release mechanism.
NOTE: Visually check the operation of the
cable actuated release mechanism. Check
the inner cable for fraying and jamming in
the outer cable.

INSUFFICIENT CLUTCH RELEASE
(1) Stretched, frayed or broken clutch cable:
Check and renew the clutch cable. (2) Worn or damaged release mechanism: Check
and renew components as necessary. (3) Insufficient pedal height: Check and adjust
the pedal height.
(4) Warped clutch driven plate: Renew the
clutch driven plate. (5) Excessive clutch release lever free play:
Check and adjust the release lever free play to
Specifications.
NOTE: Visually check that the clutch cable
operates the release lever before removing
the clutch for inspection.

RELEASE BEARING NOISE
(1) Dry or worn release bearing: Check and
renew the release bearing.
(2) Damaged pressure plate diaphragm spring;
Check and renew the pressure plate assembly.
NOTE: Lightly depress the clutch pedal with
the engine running to check for release
bearing noise. If the release bearing is faulty
and has to be renewed, always check the
other clutch components.


Check the diaphragm spring fingers for scoring and damage.
2. DESCRIPTION
The clutch consists of a single, dry, driven plate
assembly, splined to slide on the transaxle input shaft.
A diaphragm spring type pr essure plate assembly is
bolted to the engine flywheel.

The driven plate is sandwiched between the
pressure plate and the flywheel and transmits the
drive from the engine to the transaxle.

Cushion rubbers are interposed between the hub
of the driven plate assembly and the plate friction
surfaces in order to cushion the drive.

The release mechanism is actuated by the clutch
pedal through a cable to the release lever and bearing.

Operation of the clutch pedal moves the release
lever which pushes the release bearing into contact
with the diaphragm spring fingers, forcing the dia-
phragm centre towards the flywheel. When the outer
edge of the diaphragm deflects, the clutch is caused to
disengage.

Clutch pedal free play is adjusted at the release
lever end of the clutch cable.

Clutch pedal height is adjusted at the pedal stop
on the pedal mounting bracket located under the
dashboard.

Manual Transaxle and Drive Shafts 127
(6) Lubricating oil too thick: Drain the transaxle
and refill with the corre ct amount and grade of
lubricating oil. (7) Excessive end float in the mainshaft or input
shaft gears: Overhaul the transaxle.
NOTE: Check the clutch for correct opera-
tion. If reverse gear can be selected without
any gear clash this is a good indication that
the clutch is operating normally. Also check
that the correct type and grade of lubricating
oil is being used.

SLIPPING OUT OF GEAR
(1) Worn gear control rod assembly bushes:
Check and renew the worn components as necessary. (2) Faulty gear lever assembly: Check and renew
the faulty components. (3) Faulty synchroniser mechanism: Overhaul
the transaxle.

Check the engine mountings for damage and deterio-
ration.
(4) Worn or fatigued detent components: Renew
the faulty components as necessary.
(5) Excessive end float in the mainshaft or input
shaft: Overhaul the transaxle. Check and renew the
faulty components.
NOTE: In most cases, slipping out of gear is
caused by wear or damage to internal
components of (he tran saxle. However, prior
to removing and dismantling the transaxle
assembly, check the engine mounting rub-
bers and mounting hardware as vibrations
caused by loose or deteriorated engine
mountings can cause the transaxle to slip
out of gear.

GEARS CLASH ON CHANGING DOWN
(1) Faulty clutch or clutch release mechanism:
Check, adjust or overhaul the clutch or the clutch
release mechanism.


Check the friction surface of the synchro rings and cones
for wear or damage.
(2) Faulty synchro rings or cones: Overhaul the
transaxle assembly.
(3) Lubricating oil too thick: Drain the transaxle
and refill with the correct grade and quantity of
lubricating oil. (4) Broken, weak or incorrect positioning of the
springs in the synchro asse mblies: Overhaul the tran-
saxle assembly.
(5) Excessive end float in the mainshaft or input
shaft gears: Overhaul the transaxle assembly.
NOTE: Check the clutch as previously de-
scribed prior to removing and dismantling
the transaxle. Also check that the correct
grade of transaxle oil is being used.

TRANSAXLE NOISE (IN NEUTRAL)
(1) Insufficient lubricant: Fill the transaxle with
the correct quantity and grade of lubricant. (2) Worn input shaft bearings: Overhaul the
transaxle and renew the bearings. (3) Chipped or pitted constant mesh gears:
Overhaul the transaxle and renew the damaged com-
ponents as necessary. (4) Worn mainshaft bearings: Overhaul the tran-
saxle as necessary.
NOTE: First check the oil level in the
transaxle. To isolate the noise in neutral,
run the engine, depress the clutch and
engage any gear. If the noise ceases with the
clutch depressed it indicates that the noise is
in the transaxle.

Check the input shaft for damaged gears.

140
AUTOMATIC TRANSAXLE
SPECIFICATIONS
Make .............................................. JATCO RL3F01A
Type .....................3 speed and reverse epicyclic gear
train with lock up torque converter
Operation .................................... Automatic hydraulic
Lubricant:
Type....................................................... Dexron IT
Capacity................................................. 6.3 liters
TORQUE WRENCH SETTINGS
Drive plate to crankshaft bolls ........................60 Nm
Drive plate to torque converter bolts ..............49 Nm
Convener housing to engine ...........................22 Nm
Converter housing to transaxle ........................23 Nm
Transaxle sump to transaxle ............................. 7 Nm
Oil cooler pipe to transaxle .............................49 Nm
Selector shaft locknut .......................................42 Nm
Transaxle filter bolts.........................................12 Nm
1. AUTOMATIC TRANSAXLE TROUBLE SHOOTING
NO DRIVE IN D RANGE
{1) Low fluid level in transaxle: Check the fluid
level in the transaxle and top up if required.

(2) Incorrectly adjusted selector cable: Check
and adjust the selector cable as detailed. (3) Incorrect or contaminated transaxle fluid:
Drain and refill with the recommend type and quan-
tity of transaxle fluid.
NOTE: Check the possible causes in the
order given.

NO REVERSE IN R RANGE
(1) Low fluid level in transaxle: Check the fluid
level and top up if required. (2) Incorrectly adjusted selector linkage: Check
the condition of the selector cable, selector quadrant
and selector arm for wear and damage. Adjust as
required.

Check the drive shaft oil seals as a likely leak source.
SLIPPING OR ROUGH UPSHIFT
(1) Incorrectly adjusted selector linkage: Check
and adjust the selector linkage. (2) Low fluid level in transaxle: Check the fluid
level and top up if required.
NO TRANSAXLE KICKDOWN
(1) Incorrectly adjusted throttle cable: Check
and adjust the cable as detailed in the Fuel and Engine
Management section.
Check the oil cooler hose connections for leaks if the
fluid level is low.