1987 NISSAN PULSAR gas type

General Information 11
Lifting Equipment
When using lifting equipment to lift heavy com-
ponents such as the engine and/or transmission, use
metal slings or chain in preference to rope. If rope
must be used, ensure that it is not placed against sharp
edges on the component.

Automotive Lubricants and Solvents
Avoid prolonged skin contact with oils, greases
and solvents as some can cause skin irritations and
dermatitis.

Exercise caution when us ing cleaning solvents as
many are inflammable. Do not smoke. Keep naked
flames and sparks clear of the work area.

Compressed Air
Never point an air hose at another person or allow
compressed air to blow onto your skin. High pressure
air forced against the skin can enter the bloodstream
and prove fatal.

Suspension and Steering Components
Damaged suspension and steering components
should not be welded. Many of these components are
fabricated from toughened metals. If welded they may
lose their strength or become brittle. Damaged com-
ponents should be renewed.

Air Conditioning
Avoid disconnecting air conditioning hoses as
escaping refrigerant can cause frostbite. The refriger-
ant is highly flammable and when burnt, a poisonous
gas is produced.

VEHICLE SAFETY
To prevent damage to the vehicle during servicing
or repair work, note the following precautions.

Brake Fluid
If spilt on the vehicle paintwork, brake fluid
should be immediately washed away with clean water
and allowed to dry naturally, not wiped with a cloth.

Catalytic Converter
The following should be observed to prevent
damage to the catalytic converter:

Do not operate the vehicle on leaded fuel.
Do not push or tow start the vehicle.
Do not allow the engine to idle for prolonged
periods.

Do not switch the ignition off while the vehicle is
in motion and the transmission is in gear.

Do not 'prime' the engine by pouring fuel into the
inlet manifold.

Do not operate the vehicle if the engine is
misfiring.

Avoid running the vehicle out of fuel.
Ensure that the engine oil is formulated to contain
low phosphorus levels.

Electronic Components
The electronic components of the ignition and
fuel injection systems can be damaged by the use of
incorrect testing equipment.

It is essential in all tests where voltage or resis-
tance is to be measured that a digital display multi-
meter with a minimum 10 megohm input impedance
be used.

Some types of tachometers, timing lights and
ignition system analyzers are not compatible with
certain engine electronic systems. It is therefore
recommended that the manufacturer of the test equip-
ment be consulted before using the equipment.

Jump starting, or being jump started by another
vehicle can cause damage to the electronic compon-
ents of the vehicle. Refer to the Roadside Trouble
shooting section for the correct jump starting proce-
dure.

3. GENERAL REPAIR PROCEDURES
SEIZED FASTENERS
Seized bolts, nuts or screws should first have a
liberal amount of penetrating oil applied. The fastener
should be left for a period of time to allow the oil to
penetrate and soften the corrosion which is causing
the binding.

Often, a sharp hammer blow to the head of the
fastener can dislodge the corrosion and permit it to be
loosened.

An impact driver, which can be fitted with a
socket or screwdriver bit, can be used to loosen a
seized fastener.

Another method is to heat the component in
which the fastener is seized. However, extreme cau-
tion should be exercised when heating aluminum
alloy components as the melting point is much lower
than that of steel.

If the above methods fail to free a seized nut,
carefully hacksaw through one side of the nut until it
can be split. Care should be taken that the threads of
the bolt or stud are not damaged.

Should a bolt or stud break below the surface of
the component, it will be necessary to use a screw
extractor to remove the remaining part. Follow the
screw extractor manuf acturers instructions.


Tap and die set and assorted screw extractors.

12 General Information
Damaged threads can be repaired using a die nut
on studs and bolts, and a tap on nuts and threaded
holes in castings. If the threads of a threaded hole are
damaged beyond repair, it will be necessary to drill
and tap the hole to a larger size. Alternatively, a
Helicoil insert can be used to Testore the hole to the
original thread size.

STUDS
The simplest method for removing studs is to lock
two nuts together on the threaded section. The stud
should then be able to be removed by applying an
unscrewing action to the lower nut.

Alternatively, there are various makes of stud
extracting tools available.


Using two nuts locked together to remove a stud.
OIL SEALS
Oil seals can usually be removed by levering out
with a flat screwdriver or other suitable lever. Care
should be taken not to damage the surface of the
component which the seal lip runs on.

Seals can also be removed by inserting a number
of self tapping screws into the seal body. The seal can
then be withdrawn using pliers gripping the self
tapping screws.

Always apply a smear of grease or oil to the seal lip
prior to installation to provide initial lubrication.

Unless otherwise stated, oil seals should always be
installed with the lip facing inwards or towards the
substance to be sealed. Duri ng installation, the seal l i p
should be protected from damage from sharp com-
ponents such as shaft splines by wrapping tape around
the sharp edges.

Install the new seal using a wooden block, or a
socket or length of tube of the appropriate diameter.
Ensure that the seal is installed squarely or distortion
and subsequent leakage may occur. If an installation
depth is not specified, th e seal should be installed
flush with the component surface.

GASKETS
When separating mating components (i.e.
cylinder
head and cylinder block), do not insert screwdrivers or

similar levers between the components in an attempt
to lever them apart. This can cause severe damage to
the sealing surfaces, particularly if the components are
made of alloy compounds.

The components can be separated by tapping
along the joint with a soft faced hammer or piece of
wood. Before installing a new gasket, the mating
surfaces should be cleaned of all traces of old gasket
material and sealant.

Check that the new gasket is correct by comparing
the bolt holes and passages on the component face
with the openings in the gasket.

Cork and paper gaskets which have been stored
for some time may suffer from shrinkage. This can be
rectified by soaking the gasket in water.

BEARINGS AND BUSHES
If the correct equipment is not available when
removing and installing bearings and bushes, it is
often possible to improvise.

Bearings can often be removed from shafts by
tapping alternately on opposite sides with a hammer
and drift.


A simple bush installing tool using a bolt, nut and two
washers.
If a press is unavailable, bushes can be installed by
placing the bush and component between the jaws of a
vice and screwing the jaws together until the bush is
fully inserted. A vice can also be used to remove
bushes by using suitably sized spacers against either
vice jaw, one bearing on the bush and the other on the
component. This method can also be used with a G
clamp.

A simple removing and installing tool can be
made using a long bolt, large and small washers, a nut
and a tubular spacer. Refer to the illustrations for the
method and applications.

Rubber bushes and bushes in blind holes can be
removed using an expanding type masonry bolt
(Rawlbolt Loxin). Install a neat fitting masonry bolt to
the bush. Install and tighten the bolt until it grips the
bush. The bolt and bush can then be removed using a
slide hammer or levers.

14
LUBRICATION AND MAINTENANCE
SPECIFICATIONS
CAPACITY AND GRADE
Engine:
Lubricant........................................... 15W-50 SF
Sump capacity including filter ........... 3.3 liters
Cooling system capacity............................ 6.0 liters
Manual transaxle:
Lubricant....................................... 80W-90 GL-4
Capacity ............................................... 2.7 liters
Automatic transaxle:
Lubricant.............................................. Dexron II
Capacity ............................................... 6.0 liters
Power steering:
Lubricant.............................................. Dexron II
Capacity ............................................... 1.0 liters
Manual steering lubricant ........ Castrol EPLl grease
Brake fluid type ................................................ Dot 4
1. HOW TO GREASE AND OIL CHANGE
(1) Run the front of the vehicle onto car ramps
and stop the engine. Chock the front wheels. (2) Raise the rear of the vehicle and place
chassis stands under the rear jacking points.
NOTE: It is best if the vehicle is kept as level
as possible to avoi d false readings when
checking the lubricant levels.



(3) Clean around the engine sump drain plug.
(4) Place a drain tin under the engine sump,
remove the engine sump drain plug and allow the
engine sump to completely drain.
NOTE: It is best to drain the engine sump
with the oil at operating temperature. How-
ever, if the oil is hot take care to avoid
scalding.

(5) Check that the sealing gasket on the sump
plug is in a serviceable condition. (6) When the engine sump has completely
drained, install and firmly tighten the sump drain plug.
Wipe around the plug after installation. (7) Place the drain tin under the oil filler,
remove the oil filter using a filter removal tool and
allow the residual engine oil to drain. Smear the
scaling ring of the new filter with engine oil and
lighten the filter by hand as per the instructions
supplied with the new filter.
NOTE: Before installing the new filter, en-
sure that the sealing gasket from the old
filter has not adhered to the filter sealing
surface on the engine.

(8) Remove the level checking plug from the

Location of the engine sump drain plug.
Removing the engine oil filter using a filter removal tool.

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.