Contents

Mitsubishi Motors 3000GT 1993 Information Manual PDF

1 of 216
1 of 216

Summary of Content for Mitsubishi Motors 3000GT 1993 Information Manual PDF

This page intentionally left blank.

Mitsubishi Motors Corporation May 1992

M ITSU BISH I 3000GT

TECHNICAL INFORMATION

MANUAL

FOREWORD

This manual has been prepared as an introduction to the specifications, features, construction, functions, etc. of the newly developed 3000GT. Please read this manual carefully so that it will be of assistance for your service and sales activities. Please note that the following service manuals are also available and should be used in conjunction with this manual. WORKSHOP MANUAL

ENGINE GROUP PWEE (Looseleaf edition) PWUE9119 (Vehicles for Europe) PWUE9203 (Vehicles for General Export and Australia) PHUE9201 (Vehicles for Europe) PHUE9203 (Vehicles for General Export and Australia) B608K402AD (Vehicles for Europe) B808K402AD (Vehicles for General Export) BFA8K402A1 (Vehicles for Australia)

All information, illustrations and product descriptions contained in this manual are current as at the time of publication. We, however, reserve the right to make changes at any time without prior notice or obligation.

CHASSIS GROUP

ELECTRICAL WIRING

PARTS CATALOGUE

GROUP INDEX

GENERAL ....... .

ENGINE ............................................ .

POWER- TRANSMISSION COMPONENTS ......

DRIVE-CONTROL COMPONENTS ................................ .

BODY ................................................ .

EXTERIOR ........................................ .

INTERIOR ......................................... .

EQUIPMENT ..................................... .

MODEL INDICATIONS The following abbreviations are used in this manual for classification of model types. M/T: Indicates the manual transmission, or models equipped with the manual transmission. MPI: Indicates the multi-point injection, or engines equipped with the multi-point injection. 4WD: Indicates the 4 wheel-drive vehicles. DOHC: Indicates an engine with the double overhead camshaft, or a model equipped with such an engine.

INDICATION OF DESTINATION - Europe, General Export, Australia, New Zealand and GCC used for convenience to indicate destination. NOTE 1. "General Export" means territories other than Europe, Australia, New Zealand, GCC, the U.S.A. and

Canada. 2. "GCC" means member of the Gulf Cooperation Council nation. 3. In some instances, vehicles with other specifications may be shipped to some countries.

NOTE For detailed information concerning the reading of circuit diagrams, refer to the separate manual of "ELECTRICAL WIRING".

GENERAL - How to Use This Manual

EXPLANATION OF CIRCUIT DIAGRAMS The symbols used in circuit diagrams are used as described below.

NOTES This electronic document was created from material published and copyrighted in 1992 by Mitsubishi Motor Corporation (MMC). All rights to the original material are reserved by them. This electronic document may be distributed freely, without financial charge. Note that this document is not an exact replica of the original manual. Because of this, copies of this document are easily identified. MMC cannot be held liable for any changes that have occurred. Typographical and factual errors may have been introduced, and some may have been corrected, while others may have been preserved. MMC and I disclaim all liability for direct, indirect, incidental, or consequential damages or personal injury that may result from any use of the information in this manual. MMC and I make no warranty, claim, or representation, expressed or implied, concerning the accuracy of the material here, or the suitability of the information or instructions for any purpose. Please note that this manual does not cover vehicles destined to the USA and Canada. The vehicles covered include the turbocharged model destined for Europe, Australia, New Zealand, the Gulf Coast Council (GCC) nations, and General Export (those territories other than Europe, Australia, New Zealand, GCC, USA, and Canada). In some cases, information here may be identical to that for USA and Canada vehicles. In other case, the information does not apply to USA and Canada vehicles. I used an Epson Perfection 2450 scanner and Readiris Pro 9.04 to scan a single sheet (page) and recognize images, text, and tables. I placed a sheet of black paper behind the sheet to be scanned to reduce bleed-through of images and text from the back of the sheet or from other sheets. Scanner options in Readiris were set to grayscale, 400 dpi, letter format, and contrast and brightness set to 299 to reduce the yellowing caused by the age of the manuscript. Readiris allows the identification and selection or elimination of areas of the scanned image that are text, graphics, or table format. This did not allow the embedding of graphics into text areas or vice versa. These two areas may overlap but this created visual confusion. Pages were deskewed as necessary. The formatted, scanned page was saved in MS Word document format. I used MS Word 2002 to make spelling corrections, format the page size (8.5 x 11), and set margins, generally 0.5 all around. Re-arranging of objects occurred on some pages. From Word, I printed the page to Adobe Distiller 7.0.0, creating a PDF file for each page. Distiller was set to not compress images. This increases the size of the final document, but improves resolution and clarity of the images. In Adobe Acrobat 7.0.0, I concatenated the individual PDF files into a single document, adding bookmarks and thumbnails. I tested the final document with Acrobat and Acrobat Reader versions 5, 6, and 7. No problems were encountered with versions 6 and 7. However, with Acrobat version 5 errors were encountered. These were avoided by having the Bookmarks panel on the left open. I recommend using version 6 or 7 of Acrobat or Acrobat Reader to view this document. I thank the dedication and generosity of Jan Borgelin for getting an original printed version of this publication to me. Jeff Lucius, February 2005

0-1

GENERAL CONTENTS

DESIGN STRATEGIES FOR DEVELOPMENT ...........................................................2 Basic Themes for Development ................................2

COMMODITY FEATURES ............................................3

TECHNICAL FEATURES .............................................4

Exterior ......................................................................4 Interior ........................................................................5 Engine ........................................................................6 Transaxle ...................................................................9 Clutch Booster ........................................................ 10

Chassis ...................................................................11 Supplemental Restraint System (SRS) .................. 13 Small Amount Refrigerant System (Air Conditioner) ...................................................... 14 Theft-alarm System ................................................ 15 Serviceability ........................................................... 16

VEHICLES IDENTIFICATION .................................... 17 Model ...................................................................... 17 Model Code ............................................................. 17

MAJOR SPECIFICATIONS ........................................18

In pursuit of sports car styling Stylish design that abolishes design compromises.

0-2 GENERAL - Design Strategies for Development

DESIGN STRATEGIES FOR DEVELOPMENT BASIC THEMES FOR DEVELOPMENT New 4WD Sports Car A 4WD system that accurately transmits the power of the engine to the road surface, thus eliminating the danger that normally accompanies speed, has been adopted in a sports car so that anyone can comfortably Exhilarating driving and safety Faithful and speedy responsiveness to the intentions of the driver and direct response. Also, safety equipment has been adopted in order to maintain safety.

drive in a sporty manner. The DOHC twin-turbochargers and twin-intercoolers coupled with the 4WD maintain overwhelming performance

Dynamic real sports styling Low and wide proportions Capsule image due to glass with complex curves

Large-diameter wide tyres that symbolize super 4WD

Interior with an abundantly sporty feel

Sports cockpit centered around the driver Simple interior qesign

Front seat which stresses driving performance

Excellent driving performance Excellent acceleration performance from a standing start due to a high-performance engine and 4WD

Excellent steering stability Extra-wide tread and wide tyres together provide a high limit for cornering performance

High-performance brakes due to the combination of 4-piston aluminum caliper brakes and 4-wheel ABS

Optimization of torque distribution to front and rear wheels

High-tech components Full-time 4WD and 5-speed MfT manufactured by GETRAG Combination of 4WD, 41S, 4ABS and 4WS

4-piston aluminum caliper brakes

Active aero system

SRS air bag

Safety features 4WD 4ABS

SRS air bag

Rear seat 3-point seat belts

High-mounted stop lamp

Side door beam

Fire-resistant materials used inside the passenger compartment

GENERAL - Commodity Features 0-3

COMMODITY FEATURES

0-4 GENERAL - Technical Features

TECHNICAL FEATURES EXTERIOR Dynamic sports car proportions with wide tread and tight interior.

5

No. Features

1 The forward passenger compartment looks like a capsule, using glass with complex curves.

2 Side air dam that provides improved aerodynamic characteristics for the side of the vehicle.

3 17" aluminum wheel and wide tread tyre to create the image of a highyerformance sports car.

4 Large soft-face bumper (with built-in bumper absorber) that gives the feeling ot being one unit with the

body.

5 Active aero system improves aerodynamic characteristics when driving at high speed. (movable front venturi skirt and rear spoiler)

GENERAL - Technical Features 0-5 INTERIOR Interior that creates a real feeling of a cockpit centering around the driver.

No. Features

1 An instrument panel that emphasizes a feeling of closeness.

2 Round 3-meter arrangement with sporty imag.e.

3 Easy-to-see goggle type meter cluster.

4 Full round door trim that appears to be one with the instrument panel.

5 Superior sports type front seat that gives support.

6 High, wide and large floor console.

7 Sports steering wheel with built-in air bag (SRS).

0-6

GENERAL - Technical Features

ENGINE A 3.0L DOHC engine with twin-turbochargers and twin-intercoolers have been developed to provide even higher output and higher performance.

SPECIFICATIONS

Items

Specifications

FEATURES

Displacement cm3 (cu. in.)

2972 (181.4)

Maximum output kW (PS)/rpm

210 (285) / 6,000

Maximum torque kgm (Nm)/rpm

41.5 (407) /3,000

High performance and low fuel consumption The roller rocker arm reduces the valve-actuation torque as well as fuel consumption. Improved response and fuel consumption have been achieved by electronic control multi-point fuel injection. Electronic control of fuel pump fuel discharge for high response and low fuel consumption. Overwhelming acceleration due to combination of the twin-turbochargers and twin-intercoolers. A lightweight sodium-filled vacuum valve has been developed for use as the exhaust valve to improve valve follow in high-

speed ranges.

GENERAL - Technical Features

0-7

Quiet operation Noise and vibration have been decreased by the adoption of roller rocker arms. Noise generated by the valve mechanism has been decreased by the hydraulic auto lash adjusters. Both powerful exhaust sound fitting a high performance vehicle and quietness due to the active exhaust system. Reduction in noise and vibration by improving the rigidity of the cylinder block. Vibrations have been decreased by the adoption of bearing caps with beams which increase the rigidity of the crank-

shaft support points. Reduction in vibration due to the use of a crankshaft pulley with torsion damper and, because of that, improvement in

the durability of the belts.

Serviceability Complete self-diagnosis functions. Enhanced reliability through the adoption of gold-plated connector terminals. Use of an auto tensioner achieves maintenance-free, automatic adjustment of timing belt tension. Use of the auto-lash adjusters achieves maintenance-free, automatic adjustment of valve clearance. The 3-coil distributorless ignition system supplies sufficient ignition energy even during high speed operation.

0-8

GENERAL - Technical Features

GETRAG is a German manufacturer who develops and manufactures high performance transaxles especially in Europe.

TRANSAXLE W5MG1 TYPE MANUAL TRANSAXLE The W5MG1 type manual transaxle is a full-time 4WD manual transaxle made by GETRAG* and newly

developed to match the high output and high torque of the 6G72-DOHC (Turbo) engine.

1. Sportier driving is possible by using a centre differential method with viscous coupling for distributing (front 45: rear 55) front and rear torque unevenly.

2. A double-cone synchronizer for 1st and 2nd speeds and a reverse synchronizer are used and, in addition to sure shifting performance, the shift feeling is also improved.

3. Low vibration and low noise are realized by the use of high precision gears and high rigidity shaft.

*

GENERAL - Technical Features 0-9

Release cylinder

0-10 GENERAL - Technical Features

Air intake plenum

Clutch pedal

Clutch booster Vacuum tank

CLUTCH BOOSTER A 4" single type clutch booster is used to reduce the force needed to depress the clutch pedal.

GENERAL - Technical Features 0-11 CHASSIS

Steering A compact lightweight integral type rack and pinion type power steering for outstanding steering response. Tilt steering construction for ideal steering position. SRS built into the steering wheel to protect the driver. 4-wheel steering system (4WS) for improved stability in the medium and high speed range.

Front Axle BJ-TJ type constant velocity joint with high transmission efficiency and minimum vibration and noise. Isometric drive shaft for reduced vibration, noise and torque steer. A unit ball bearing consisting of the hub and bearing for good serviceability and little rolling

resistance.

Front Suspension Very lightweight and rigid McPherson

strut type independent suspension. Offset coil spring for comfortable ride. Anti-diving geometry for outstanding

stability. Negative offset geometry for superior

stability when braking. Electronic control suspension (ECS) for

both driving stability and riding comfort. Liquid filled bushing to reduce noise.

0-12 GENERAL - Technical Features

Propeller Shaft 3-section 4-joint type propeller shaft with two center bearings. Robro joint to absorb lengthwise and angular change and prevent transmission of vibrations. Anti-vibration type propeller shaft (rear propeller shaft) to reduce vibration and noise from the drive train.

8+9 inch tandem brake booster to reduce the force needed to depress the brake pedal.

X-arrangement of lines that maintains balanced braking in front and rear even if the hydraulic system is lost.

4-wheel anti-lock braking system (4ABS) using 4- sensor, 2-channel lock method.

Dual proportioning valve for control of rear wheel braking.

Face-to-face and different diameter 4- piston front ventilated disc brake with stable braking force and good braking feeling.

Rear Suspension Double wishbone type independent suspension for

outstanding riding comfort. Electronic control suspension (ECS) for both stable

handling and riding comfort.

Rear Axle BJ-TJ type constant velocity joint with high transmission

efficiency and minimum vibration and noise. Viscous coupling type limited-slip differential.

Rear drum-in-ventilated disc brake with built-in parking brake and featuring good braking stability.

Brake

0-13 GENERAL - Technical Features

SUPPLEMENTAL RESTRAINT SYSTEM (SRS) SRS is a system that works with the seat belt and is designed as auxiliary equipment to the seat belt. It only functions to protect the upper body of the driver

when a shock that is over the design value (deceleration G) is added to the entire vehicle from the front.

0-14 GENERAL - Technical Features

In order to protect the ozone layer, the small amount refrigerant system was developed by improving the structural parts of the air conditioner, making it more compact, etc. in order to reduce as much as possible

the amount of chloro-fluoro carbon used as the refrigerant in automobile air conditioners.

SMALL AMOUNT REFRIGERANT SYSTEM (AIR CONDITIONER)

0-15

About 20 seconds after all doors are closed and locked, the tailgate is closed, and the hood is closed SYSTEM ARMED

ALARM DEACTIVATED (SYSTEM DISARMED)

GENERAL - Technical Features

Driver unlocks a door or tailgate with the key.

A door, tailgate or hood is broken to open ALARM ACTIVATED

Engine is disabled and will not start

Unauthorized

SYSTEM DISARMED

Authorized

Driver opens door with the key

Normal starting

been forced open without using a key. Furthermore, the starter circuit is interrupted so that the engine may not be operated.

THEFT-ALARM SYSTEM To make the vehicle theftproof, this system is de- signed to operate the horn intermittently for 30 se- conds when the locked door, hood or tailgate has

16F0295

0-16 SERVICEABILITY A series of investigations from a variety of angles are carried out starting from the planning and design stages, to produce a vehicle with complete diagnosis functions

and a reduced need for maintenance, with improvements in reliability and durability.

Items of improved serviceability Adoption of hydraulic-type lash adjusters which make valve clearance adjustment unnecessary Adoption of an auto tensioner which makes timing belt tension adjustment unnecessary Adoption of a distributorless 3 coil ignition system Adoption of a camber adjustment mechanism in the front suspension Adoption of an alignment adjustment mechanism in the rear suspension Adoption of an outer disc method which makes brake disc removal and installation simple Adoption of audible pad wear indicators in the brakes Adoption of a drum in parking disc type brake to improve workability for the rear brakes Adjustment of gap between wheel speed sensors and rotors in 4ABS Colour-coding of service connectors (for ignition timing adjustment, fuel pump inspection and engine speed

inspection) to distinguish then from other connectors and make them easier to find Expansion and full realization of the self-diagnosis system Improvement in reliability due to harness junction connectors Centralization of relays Receiver piping connection has been made into a flange fitting and the end of the piping section has been flared to

prevent falling off of O-rings

GENERAL - Technical Features

0-17 GENERAL - Vehicle Identification

VEHICLE IDENTIFICATION MODEL VEHICLES FOR EUROPE

VEHICLES FOR GENERAL EXPORT

VEHICLES FOR GCC

VEHICLES FOR AUSTRALIA

MODEL CODE

1. Development order (& Drive train) Z1 - MITSUBISHI 3000GT

(Full time 4WD) 2. Engine type

6 - 2,972 cc (181.4 cu. in.), petrol 3. Sort

A - Passenger car 4. Body style

M - 2-door hatchback 5. Transmission type

N - 5-speed manual transmission 6. Trim code

7. Specified engine feature F - Turbocharger (with intercooler)

8. Steering wheel location L - Left hand R - Right hand

9. Destination 6 - For Europe 8 - For Australia W - For GCC None - For General Export

Model code Engine model Transmission model Fuel supply system

Z16AMNGFLW 6G72 [2,972 cm3 (181.4 cu. in.)] W5MG1 MPI

Model code Engine model Transmission model Fuel supply system

Z16AMNGFR8 6G72 [2,972 cm3 (181.4 cu. in.)] W5MG1 MPI

Model code Engine model Transmission model Fuel supply system

Z16AMNGFL 6G72 [2,972 cm3 (181.4 cu. in.)] W5MG1 MPI

Z16AMNGFR

Model code Engine model Transmission model Fuel supply system

Z16AMNGFL6 6G72 [2,972 cm3 (181.4 cu. in.)] W5MG1 MPI

Z16AMNGFR6

Z1 6 A M N G F L 6

1 2 3 4 5 6 7 8 9

0-18 GENERAL - Major Specifications

MAJOR SPECIFICATIONS

OOF0015

Items Z16AMNGFL6 Z16AMNGFL Z16AMNGFLW

, Z16AMNGFR6 Z16AMNGFR Z16AMNGFR8

Dimensions mm(in.)

Overall length 1 4,560 (179.5) Overall width 2 1,840 (72.4) Overall height (unladen) 3 1,285 (50.6) Wheelbase 4 2,470 (97.2) Track-Front 5 1,560 (61.4) Track-Rear 6 1,580 (62.2) Ground clearance (unladen) 7 145 (5.7) Overhang-Front 8 1,030 (40.6) Overhang-Rear 9 1,060 (41.7) Angle of approach degrees 10 11.2

Angle of departure degrees 11 17.3

Weight kg (Ibs.)

Kerb weight 1,740 (3,836) /

Gross vehicle weight 2,120 (4,674) Max. axle weight

Front 1,150 (2,535)

Rear 1,020 (2,249)

Seating capacity 4

Engine Model 6G72

Total displacement cm3 (cu.in) 2,972 (181.4)

Transmission

Model W5MG1

Type 5-speed manual

1-1

ENGINE CONTENTS -

GENERAL INFORMATION .........................................2 Specifications ......... ............................................... 2 Engine Sectional View ............................................ 2

BASE ENGINE ..............................................................4 Oil Jet .........................................................................4 Main Bearing Cap ......................................................4

Crank Angle Sensor and Cam Position Sensor .................................................5 Crank shaft ................................................................5 Exhaust Valve ...........................................................5

MOUNTING .................................................................. 6

LUBRICATION SYSTEM ............................................. 7

COOLING SYSTEM ..................................................... 8 Specifications ............................................................8

INTAKE/EXHAUST SYSTEM .................................... 10 Twin-turbochargers and Twin-intercoolers . 10

Turbo Pressure Control ...........................................10 Exhaust Pipe ..........................................................11

FUEL SYSTEM ...........................................................12 Fuel-pressure Control Valve .................................. 12 Fuel Tank ............................................................... 12

CONTROL SYSTEM ....14 System Block Diagram .15 Sensors .. 16 Actuators .18 Fuel Injection Control 19 Idle Speed Control (ISC) 20 Mechanical Dashpot ...............21

Ignition Timing and On Time Control ......................................................22

Power Supply and Fuel Pump Control ..................................................23

Fuel Pump Discharge Volume Control ............................................ 24 Turbo Meter Control ... ............................................ 24 Turbo Pressure /Control .......................................... 25 Fuel Pressure Control ............................................. 26

Air Flow Sensor (AFS) Filter Reset Control ................................................. 26 Self Diagnosis System ............................................27

EMISSION CONTROL SYSTEM ................................30

CRUISE CONTROL SYSTEM ....................................32

1-2 ENGINE - General Information

GENERAL INFORMATION The engine is a V-type 6-cylinder (bank angle 60) 2,972 cm3 (181.4 cu.in.) DOHC 24 valve design and is basically the same as the engine equipped in the SIGMA. However, twin turbochargers and twin inter- coolers have been installed to provide even higher output and higher performance.

NOTE For details of the basic engine structure, refer to the previously-issued '91 SIGMA Technical Information Manual. (Pub. No. PYGE9008).

SPECIFICATIONS

Items Specifications

Total displacement cm3 (cu. in.) 2,972 (181.4)

Arrangement and number of cylinders V type, 6 cylinders

Combustion chamber type Pentroof type

Number of intake and exhaust valve (per cylinder) 2 each

Valve mechanism OHV, DOHC (per bank)

Bore x stroke mm (in.) 91.1 x 76.0 (3.59 x 2.99)

Compression ratio 8.0

Maximum output PS/rpm 285/6,000

Maximum torque kgm/rpm 41.5/3000

Valve timing Intake Opened 16 BTDC

Closed 55 ABDC

Exhaust Opened 50 BBDC

Closed 17 ATDC

Fuel supply system Electronic controlled multi-point fuel injection

Ignition system Power distribution method Electronic controlled 3-coil type

Ignition timing control method Electronic controlled type

ENGINE - General Information

ENGINE SECTIONAL VIEW

7EN0478

1-3

7EN0477

1-4 ENGINE - Base Engine

BASE ENGINE OIL JET There is an oil jet for cooling the pistons.

Main gallery

Oil jet [opens valve at 2 kg/cm2 (28 psi) or more]

Main bearing 7EN0479

MAIN BEARING CAP The main bearing caps are of a conventional integrated type with beam. By tightening each of the bearing sections with 4 bolts, rigidity has been improved and

vibration from the main drive section has been reduced.

Main bearing cap

7EN0480

Crankshaft

Cam sprocket

Crank sprocket

Crankshaft

Vane 7EN0481

ENGINE - Base Engine 1-5

CRANK ANGLE SENSOR AND CAM POSITION SENSOR An ultra-small crank angle sensor and cam position a large space saving and to provide improved sensor have been positioned inside the crankshaft crank angle detection precision.

sprocket and camshaft sprocket respectively to realize

Na 7EN0482

Caution on handling the metallic sodium-filled exhaust valve. Because metallic sodium reacts violently when it For specific details, refer to the Engine Workshop comes into contact with water or moisture to gener- Manual.) ate hydrogen gas, there is a danger that explosion or fire may occur, so it should be treated with caution.

CRANKSHAFT A steel crankshaft has been adopted in order to cope with the increased engine output and to provide

reduced noise and reduced vibration.

EXHAUST VALVE (VEHICLES FOR EUROPE ONLY) Lightweight sodium-filled vacuum valves have been been improved, and improvements have been real- developed for use as the exhaust valve to improve ized in anti-knock characteristics and fuel consump- valve follow in high-speed ranges. At the same time, tion efficiency at high speeds. the cooling performance of the exhaust valve has

Front roll stopper

MOUNTING

ENGINE - Mounting

The engine mounts use a principal axis inertia support system. This support method on the principal axis inertia is a structure that supports the top of the engine and top of the transmission to effectively control engine vibration. A dynamic damper is provided on top of the engine mount to cut out high-frequency noise.

Roll stoppers (front and rear) are installed on the crossmember that is elastically supported on the body to reduce transmission of engine vibration to the body. The various mounts have the following features Each insulator has a hole to effectively absorb small

and large vibrations.

Insulator

Insulator Hole

01N0101 01R0639

No. 1 crossmember

Front ~

1-6

Insulator

Engine mount

No.2 crossmember

Front ~

Rear roll stopper

Front roll stopper

01F0017

Insulator

Dynamic damper

No.1 crossmember

Hole

No. 2 crossmember

01 F0014

01N0101

To oil level relay

1-7

LUBRICATION SYSTEM An oil pressure gauge unit has been installed in all models. In addition, an oil level sensor has been

equipped in the oil pan (Vehicles for Europe).

Rocker arm

Lash adjuster

Orifice

ENGINE - Lubrication System

Oil pressure gauge unit

Lash adjuster

Oil pan

To turbocharger

t, I

Oil pressure switch,

Relief valve

Oil filter

Oil cooler

Oil level sensor

7EN0483

1-8 ENGINE - Cooling System

COOLING SYSTEM The cooling system uses a water cooling pressure control circulation system and it has the following features. The cooling (radiator) fan uses a motor driven sys-

tem. The fan is driven by the motor only when needed to efficiently control the cooling water temperature and reduce engine output loss .

The cooling fan is a full shroud type for improved cooling performance.

The two step control system is used for the motor driven cooling fan and condenser fan for less fan noise, reduced vehicle vibration and improved cooling when the engine is idling. (Refer to GROUP 7 - Condenser Fan and Radiator Fan Control for fan speed operation mode.)

SPECIFICATIONS

Items Specifications

Cooling fan

Type Motor driven system

Water pump

Type Centrifugal type impeller

Drive method Timing belt

Thermostat

Type Wax type

Open valve temperature C (F) 76.5 (170)

Radiator Coolant capacity (including that in condenser tank) dm3 (U.S. qts., Imp. qts.) 8.0 (8.5, 7.0) Condenser tank capacity dm3 (U.S. qts., Imp. qts.)

Full 0.65 (0.69, 0.57) Low 0.25 (0.25, 0.22)

Type Corrugated type

1-9 ENGINE - Cooling System

04 FOOO3

Items Specifications

Radiator fan motor

Maker Nippon Denso Type Direct flow ferrite type Rated load torque Nm (kgm, ft.lbs.) 53 (5.3, 39) Speed rpm 2,080 250 Current A 13.6 1

Thermo sensor for radiator fan

Operating temperature C (F) OFF --+ ON 81-89 (178-192) ON --+ OFF 77 (171) or more

Thermo sensor for condenser fan

Operating temperature - C (F) OFF --+ ON 91-99 (196-210) ON --+ OFF 87 (189) or more

71N0107

ENGINE - Intake/Exhaust System

INTAKE/EXHAUST SYSTEM TWIN TURBOCHARGERS AND TWIN INTERCOOLERS Compact, lightweight, turbochargers with outstanding response are used in each bank, front and rear, for the best turbo feeling at all speeds, from low to high. The turbocharger is a water-cooled TD04 type with waste gate valve. The intercoolers are very efficient and each

one is arranged on the front and rear banks just like the turbocharger. With the combined action of the turbocharger and intercooler, powerful acceleration is possible from any speed.

Intake

Intercooler

Turbocharger

Turbocharger

Intercooler

1-10

TURBO PRESSURE CONTROL The waste gate operating pressure is controlled to make possible flat turbo pressure characteristics

over the entire rpm range and to provide a linear ac:- celeration feeling.

Intercooler

Air from air cleaner

Waste gate solenoid valve

Waste gate actuator

Air into engine

Exhaust from engine

Exhaust to exhaust pipe

71N0108

ENGINE - Intake/Exhaust System 1-11 EXHAUST PIPE The exhaust pipe is divided into three sections, front pipe, centre pipe and main muffler. It is installed on the body via a rubber hanger to reduce transmission of vibrations from the exhaust system to the body. A dual

pipe is used for the front pipe to improve exhaust efficiency, and a dual tail pipe with muffler cutter is used as the main muffler.

Heat protector

Flexible pipe

Oxygen sensor

05F0061

Pre-muffler

Catalytic converter (Right) or exhaust pipe (Right)

Catalytic converter or pre-muffler

1-12 ENGINE - Fuel System

FUEL SYSTEM The fuel system consists of electromagnetic fuel in- jectors, delivery valves, a fuel pressure regulator for regulating fuel pressure, and an electromagnetic fuel pump which operates at high pressure. It is basically the same as the fuel system in the conventional 6G7 engine, but the fuel pressure is controlled to 3.0 kg/ cm2. In addition, in order to verify the idling stability immediately after re-starting the engine at high temperatures, a fuel pressure control solenoid valve which is the same as the one fitted in the convention-

Fuel pump drive terminal

PCV

Delivery pipe

FUEL-PRESSURE CONTROL VALVE

al 4G63 engine. The fuel tank is located under the luggage compart- ment floor and the fuel filters are in the fuel tank and in the engine compartment to filter the fuel. For better serviceability, there is a terminal for the fuel pump drive in the engine compartment and a service hole in the luggage compartment; the pump and gauge assembly can be removed without removing the fuel tank.

Two-way valve

03 FOO09

Fuel pump and gauge assembly

Fuel tank

Fuel injector

Protector In-tank filter

Fuel filter

Fuel pressure regulator ~

Canister

ENGINE - Fuel System 1-13 Normally, the negative pressure in the intake manifold acts upon the fuel pressure regulator to maintain the fuel pressure at a constant level with regard to the pressure inside the intake manifold, causing the amount of fuel injected to be controlled in proportion to the injector drive time. However, if the engine is started while the engine coolant temperature and the intake air temperature are high, the engine control unit makes

FUEL TANK The electric fuel pump, in-tank filter and fuel gauge unit are built into the fuel tank. The fuel tank has the following features. Baffle plates are placed inside the fuel tank to

prevent abnormal noise due to fuel movement. There is a reseve cup inside the fuel tank for

Thermistor (for fuel warning light)

current flow to the fuel pressure control valve to activate the fuel pressure regulator by means of atmospheric pressure. Because of this, the generation of fuel vapour due to the high fuel pressure and high temperature is avoided, and the idling stability immediately after re- starting the engine at high temperatures is main- tained.

smooth supply of fuel even when there is little fuel remaining.

A pump and gauge assembly that combines the gauge unit and fuel pump in one unit is adopted.

A drain plug is standard-equipped on all models.

Pump and gauge assembly

In-tank filter

03F0008

Fuel tank

Drain plug

1-14 ENGINE - Control System

CONTROL SYSTEM The control system used is basically the same as that in the conventional 6G72 engine in the SIGMA. However,

some parts differ as shown below.

Main items changed or added Notes

Control relay and fuel pump power circuit have Simplified power circuit

been changed. Basically the same as the 4G9-DOHC engine

Crank angle sensor mounting position has been Improvement in crank angle sensor precision changed. (Crank angle previously detected from Improvement in ignition timing control precision the camshaft is now detected directly from the crankshaft.)

Adoption of fuel pump relay No.2 and fuel pump Improvement in fuel pump reliability resistor Fuel pressure control has been added. (Refer to P.1-26.)

Turbo pressure control has been added. Control additions to correspond to adoption of a turbocharger

Turbo meter control has been added.

Adoption of a twin oxygen sensor system Reduction in exhaust gas levels

Remarks The changed or added items with respect to the conventional engine are shown in bold letters.

ENGINE - Control System 1-15

SYSTEM BLOCK DIAGRAM

6AF0002

SENSORS

ENGINE - Control System

Carn position sensor and crank angle sensor

6AF0009

Carn position sensor

The cam position sensor consists of a flux screening plate fixed to the crankshaft sprocket on the rear bank exhaust side and a sensor unit fixed to the cylinder head. The crank angle sensor consists of a flux screening plate fixed to the crankshaft sprocket and a sensor unit fixed to the engine oil pump case. The cam position sensor and crank angle sensor convert the rotation of the camshaft and crankshaft into pulse sig-

NO.1 cylinder TOC signal

1-16

Crank angle sensor

nals as shown in the illustration below, and input these pulse signals to the engine control unit. Furthermore, these waveforms are the same as those for the conventional 6G7-DOHC engine, but the mounting precision of the crank angle sensor has been improved, making basic ignition timing adjustment unnecessary.

5V Crank angle sensor signal OV

No. 1 cylinder TOC signal J

No. 2 cylinder No.3 cylinder No. 4 cylinder No.5 cylinder No.6 cylinder TOC signal TOC signal TOC signal TOC signal TOC signal

Two rev. of engine

7FU0729

.. 5V Cam position sensor signal OV

Flux screening plate for Carn position sensor

Flux screening plate for crank angle sensor

Vane

6AF0010

Vane

6AF0003

ENGINE - Control System 1-17

The shapes of the flux screening plates used in the cam position sensor and crank angle sensor are as shown in the illustration at left. Detection of the cam position and crank angle is the same as for the conventional 4G93-S0HC engine, where the magnetic flux passing through the Hall element inside the sensor unit is alternately screened and allowed through by the vanes on the flux screening plate.

TWIN OXYGEN SENSOR Singapore> There are sub catalysts in both the front and rear banks in the en- gine. In order to maintain the proper air/fuel ratio in both banks, there is an oxygen sensor for each one before the catalyst of both banks to enable feedback control of the air/fuel ratio for each bank separately. Each oxygen sensor is the same as the conventional oxygen sensor with heater.

1-18 ENGINE - Control System

ACTUATORS FUEL PUMP RELAY NO.2 Fuel pump relay No.2 is the relay that changes the supply voltage to the fuel pump in 2 steps, High/Low. The engine control unit controls the amount of fuel discharged from the fuel pump by changing the supply voltage.

FUEL PUMP RESISTOR The fuel pump resistor lowers the supply voltage to the fuel pump.

ENGINE - Control System

SYSTEM CONFIGURATION DIAGRAM

1-19

FUEL INJECTION CONTROL The fuel injection control method is basically the same as that used in the conventional 6G72 engine.

1-20 ENGINE - Control System

IDLE SPEED CONTROL (ISC) (1) Stepper motor (STM) position control with the anti-

lock braking system (ABS) function was added.

SYSTEM CONFIGURATION DIAGRAM

(2) Other controls are basically the same control system as in the conventional 6G72 engine.

ENGINE - Control System 1-21

MECHANICAL DASHPOT There is a mechanical dashpot which gradually closes the throttle valve from a set opening during deceleration to improve deceleration feeling.

1-22 ENGINE - Control System

IGNITION TIMING AND ON TIME CONTROL The ignition timing and on time control methods are basically the same as those used before.

SYSTEM CONFIGURATION DIAGRAM

1-23

Power supply control to the injector, air flow sensor, ISC servo, etc. is the same as in the conventional 6G72 engine.

Fuel pump control for controlling power supply to the fuel pump is also the same as in the conventional 6G72 engine.

FUEL PUMP DISCHARGE VOLUME CONTROL Fuel pump discharge volume is controlled in two steps according to the amount of intake air (engine load) in 1 cylinder in 1 cycle for improved reliability of the fuel pump. When the amount of intake air in this 1 cylinder 1 cycle is small (engine load is low), the engine control unit turns on the power transistor so current flows in the coil of fuel pump relay No.2. As a result, the relay switch changes form A to B (refer to the figure on the left.), and current flows via the resistor to the fuel pump motor. The supply voltage to the fuel pump is reduced since the voltage is lowered by the resistor, pump speed falls and the amount of fuel discharged from the fuel pump is reduced. When the amount of intake air in this 1 cylinder 1 cycle is large (engine load is high), the engine control unit turns off the power transistor and changes the relay switch from B to A (refer to the figure on the left.). As a result, voltage drop due to the resistor increases, pump speed rises and the amount of fuel discharged from the fuel pump increases.

ENGINE - Control System

POWER SUPPLY AND FUEL PUMP CONTROL

1-24 FUEL - Control System

TURBO METER CONTROL

The turbo meter is a current type meter. The engine control unit receives the intake air volume signal from the air flow sensor and the rpm signal from the crank angle sensor and calculates the engine load. Duty ratio ~= Load ~=

Duty Ratio The duty ratio is defined as ON time ratio T2/T1 of a 33.3 Hz pulse. When the duty ratio increases, average current that flows to the turbo meter also increases so that the turbo meter indicates higher value. When the duty ratio is decreased, the turbo meter indicates smaller value.

Then, the unit determines the duty ratio according to the load and drives the turbo meter.

1-25

valve. As a result, turbo pressure corresponding to driving conditions can be obtained.

The engine control unit turns the power transistor in the unit on and, when normal current (duty 100%) flows in the waste gate solenoid valve coil, the waste gate solenoid valve does not open if turbo pressure does not rise above the set pressure of the waste gate actuator spring since some of the turbo pressure used in the waste gate actuator leaks out. On the other hand, when current does not flow in the waste gate solenoid valve coil (duty 0%), the waste gate valve opens if turbo pressure rises to the set pressure of the waste gate actuator spring since no pressure leaks out.

Consequently, by using duty control for the waste gate solenoid valve, turbo pressure can be controlled in a range from 00/0 to 100% duty. This duty control is performed in cycles of approximately 60 ms.

FUEL - Control System

TURBO PRESSURE CONTROL Turbo pressure used in the waste gate actuator is controlled by duty control of the waste gate solenoid

1-26 FUEL - Control System

FUEL PRESSURE CONTROL FUEL SYSTEM-FUEL PRESSURE CONTROL VALVE (Refer to P. 1-12) AIR FLOW SENSOR (AFS) FILTER RESET CONTROL, AIR CONDITIONER RELAY CONTROL These controls are the same as those for the conventional 6G72 engine.

SELF DIAGNOSIS SYSTEM The following items have been made more complete. (1) Check engine lamp ON items (2) Self diagnosis items

CHECK ENGINE LAMP CONTROL The check engine lamp ON items are shown in the following table.

(3) Service data items to be transferred to multi-use tester

(4) Actuator test items by multi-use tester

Remarks *: The check engine lamp lights even when the ignition timing adjustment terminal is short-circuited to the earth during an

injection timing adjustment.

SELF DIAGNOSIS FUNCTIONS (1) Arrangements have been made to allow changeover

of the diagnosis mode from DIAGNOSIS 1 mode to DIAGNOSIS 2 mode by sending a diagnosis mode changeover signal from the multiuse tester. In the DIAGNOSIS 2 mode, note that the time from when a fault is detected to when it is determined as a fault is shorter than in the DIAGNOSIS 1 mode (4 seconds 1 second).

When the multi-use tester is disconnected from the diagnosis connector, all fault codes will' be cleared from the memory, and the DIAGNOSIS 2 mode will be changed back to the DIAGNOSIS 1 mode.

(2) The other functions remain unchanged. (3) The diagnosis items are as shown in the following

table.

Code Diagnosis item Description DIAGNOSIS No. 2 Mode 11 Oxygen sensor (Rear bank) Malfunction of the air/fuel ratio control system -

Open or short circuit in the oxygen sensor circuit

12 Air flow sensor Open or short circuit in sensor and allied circuit Valid

13 Intake air temperature sensor Open or short circuit in sensor and allied circuit Valid

14 Throttle position sensor Abnormal sensor output Valid

Oxygen sensor Barometric pressure sensor

Air flow sensor (AFS) Detonation sensor

Intake air temperature sensor Ignition timing adjustment signal*

Throttle position sensor Injector

Coolant temperature sensor Ignition coil, power transistor unit

Crank angle sensor

Cam position sensor Engine control unit

ENGINE - Control System 1-27

SERVICE DATA OUTPUT The service data output items are shown in the following table.

Item No. Service data item Unit

11 Oxygen sensor output (Rear bank) mV

12 Air flow sensor output Hz

13 Intake air temperature sensor output C

14 Throttle position sensor output mV

16 Battery voltage V

17 Mixture adjusting screw (variable resistor) ON - OFF

18 Cranking signal (ignition switch-ST) ON - OFF

21 Coolant temperature sensor output C

22 Crank angle sensor output RPM

25 Barometric sensor output mmHg

26 Idle position switch ON - OFF

Code Diagnosis item Description DIAGNOSIS No. 2 Mode 21 Coolant temperature sensor Open or short circuit in sensor and allied circuit Valid

Increased connector contact resistance

22 Crank angle sensor Abnormal sensor output Valid

23 Cam position sensor Abnormal sensor output Valid

24 Vehicle speed sensor (reed switch) Open or short circuit in sensor circuit Valid

25 Barometric pressure sensor Open or short circuit in sensor circuit Valid

31 Detonation sensor Abnormal sensor output Valid

36* Ignition timing adjustment signal Short circuit in ignition timing adjustment signal line -

39 Oxygen sensor (Front bank) Malfunction of the air/fuel ratio control system -

Open or short circuit in the oxygen sensor circuit

41 Injector (Rear bank) Open circuit in injector and allied circuit Valid

44 1-4 cylinder ignition coil, power Abnormal ignition signal (No coil primary voltage Valid

transistor unit generated) 52 2-5 cylinder ignition coil, power Abnormal ignition signal (No coil primary voltage Valid

transistor unit generated) 53 3-6 cylinder ignition coil, power Abnormal ignition signal (No coil primary voltage Valid

transistor unit generated)

- Normal - -

*: Fault code No. 36 is not memorized.

1-28 ENGINE - Control System

ENGINE - Control System 1-29

Item No. Service data item Unit

27 Power steering fluid pressure switch ON - OFF

28 Air conditioner switch ON - OFF I

33 Electric load switch ON - OFF

34 Air flow sensor reset signal ON - OFF

36 Ignition timing adjustment mode ON - OFF

37 Volumetric efficiency %

38 Crank angle sensor output (readable at 2,000 rpm or less) RPM

39 Oxygen sensor output (Front bank) mV

41 Injector drive time (Rear bank) mS

44 Ignition advance angle value BTDC,ATDC

45 ISC stepper motor position STEP

47 Injector drive time (Front bank) mS

49 Air conditioner relay ON - OFF

Item No. Actuator test item

01 NO.1 injector: OFF

02 NO.2 injector: OFF

03 NO.3 injector: OFF

04 NO.4 injector: OFF

05 NO.5 injector: OFF

06 NO.6 injector: OFF

07 Fuel pump: ON

08 Purge control solenoid valve: ON

09 Fuel pressure control valve: ON

10 EGR control solenoid valve: ON

12 Waste gate solenoid valve: ON

13 Fuel pump relay No.2: ON (Current flows via the resistor)

17 Ignition timing: 5 BTDC

ACTUATOR TESTS The actuator test items are shown in the following table. NOTE

The items that have been added to the conventional system are shown in bold letters.

OIL LEVEL WARNING SYSTEM This system is the same as that of the conventional 6G72 engine.

Applicable destination

. System Hong Remarks

Kong, General

Europe Singa- Australia GCC Export

pore

Crankcase ventilation system x x x x x

Evaporative emission control Electronics controlled type system (Europe, Hong Kong and

x x x x - Singapore) Vacuum controlled type (Australia and GCC)

Catalytic converter x x x - - Three way cataIyst

Air fuel ratio closed loop control x x x - - Oxygen sensor signal used

Exhaust gas recirculation system x x - x x Electronics controlled type

EMISSION CONTROL SYSTEM that the amount of vapour that escapes to the atmosphere has been reduced. When driving with a low to medium load on the

engine, the fuel vapour absorbed by the, canister is drawn into the P port of the throttle body in the same way as in engines without turbocharger.

When driving with a high load on the engine, the purge control valve opens and the fuel vapour absorbed by the canister is drawn into the air intake hose.

Emission Control System Diagram

1-30 ENGINE - Emission Control System

The emission control system is basically the same as that used in the 6G72 engine fitted to the PAJERO/ MONTERO. However, the following additions have been made to the system in vehicles for Europe, Hong Kong and Singapore only. (1) Oxygen sensors and a front catalytic converter have

been added to reduce the level of exhaust gas emissions.

(2) The evaporative emission control system has been improved as shown below. The fuel vapour intake amount from the canister has been increased so

ENGINE - Emission Control System 1-31

1-32 ENGINE - Cruise Control System

CRUISE CONTROL SYSTEM The cruise control system makes constant-speed driving possible at a speed designated by the driver [within a range of approx. 40 - 200km/h (25 125m ph)] without depressing the accelerator pedal.

NOTE The cruise control system is basically the same as the system equipped in the SIGMA.

2-1

POWER- TRANSMISSION COMPONENTS

CONTENTS

CLUTCH .. 2 Specifications ................. 2 Clutch Booster . .............. 3

MANUAL TRANSMISSION .......................................... 4 Specifications ............................................................ 4 Sectional View ........................................................... 5 W5MG1 4WD Transmission ...................................... 6 Transmission Control ............................................... 10

PROPELLER SHAFT .................................................11

Specifications ..........................................................11

FRONT AXLE ..............................................................12 Specifications ..........................................................12

REAR AXLE ................................................................13 Specifications ..........................................................13 Axle Shaft ................................................................13 Drive Shaft ...............................................................13 Differential ...............................................................15 Differential Support ..................................................16

CLUTCH

Clutch master cylinder

The clutch is the dry single-plate diaphragm type; A hydraulic type with clutch booster is used for the clutch control.

SPECIFICATIONS

Some models are equipped with a clutch damper in the clutch tube to make changes in hydraulic pres- sure smoother when the clutch is engaged and to re- duce the maximum value for the clutch input torque.

Items Specifications

Clutch operating method Hydraulic type

Clutch disc

Type Single dry disc type Facing diameter

0.0. x 1.0. mm (in.) 250 x 160 (9.8 x 6.3)

Clutch cover assembly

Type Diaphragm spring strap drive type

Setting load N (kg,lbs.) 9,200 (920, 2,024)

Clutch release cylinder

1.0. mm (in.) 19.05 (3/4)

Clutch master cylinder

1.0. mm (in.) 15.87 (5/8)

Clutch booster

Type Vacuum type, single Effective dia. of power cylinder mm (in.) 101 (4.0) Boosting ratio 1.7 [at 110 N (11 kg, 24 Ibs.)]

[Clutch pedal depressing force]

Vacuum tank

Capacity dm3 (U.S. qts., Imp. qts.) 1.2 (1.27, 1.06)

Vacuum pipe Check valve

Vacuum pipe

Clutch release cylinder

Clutch tube

clutch hose

Vacuum hose

Pedal support bracket

Clutch booster

Clutch pedal

Clutch vacuum tank

2-2 POWER-TRANSMISSION COMPONENTS - Clutch

A 4" single type clutch booster is used to reduce the force to depress the pedal. The structural operation

of the clutch booster is basically the same as with the brake booster.

Diaphragm Booster piston

Push rod

Valve plunger stopper key

Negative pressure chamber 08F0007

Operating rod Poppet

Valve plunger

Filter

'Reaction disc

Air chamber

/ Booster return spring

2-4 POWER-TRANSMISSION COMPONENTS - Manual Transmission

MANUAL TRANSMISSION

SPECIFICATIONS

Items Specifications

Transmission model W5MG1

Type 5-speed constant-mesh cable controlled type

Gear ratio (number of gear teeth) 1 st 3.071 (43/14) 2nd 1.739 (40/23) 3rd 1.103 (32/29) 4th 0.823 (28/34) 5th 0.659 (31/47) Reverse 3.076 (40/13)

Primary reduction ratio (number of gear teeth) 1.375 (44/32)

Front differential gear ratio (number of gear teeth) 2.888 (52/18)

Transfer gear ratio (number of gear teeth) 0.814 (22/27)

Torque split ratio Front/Rear 45/55

Speedometer gear ratio Drive/Driven 27/36

The manual transmission is a W5MG1 transmission. A cable type floor shift is used for transmission control. The W5MGI is a transmission that has been newly developed to respond to the high output and high torque of the 6G72-DOHC-Turbo engine.

POWER-TRANSMISSION COMPONENTS - Manual Transmission 2-5 SECTIONAL VIEW W5MG1

1. Clutch housing 14. 5th speed gear 2. 1st speed gear 15. Center shaft 3. 1st-2nd synchronizer hub 16. Viscous coupling 4. 2nd speed gear 17. Center differential 5. Transaxle case 18. Reverse idler gear 6. 3rd speed gear 19. Front differential 7. 3rd-4th synchronizer hub 20. Transfer driven bevel gear 8. 4th speed gear 21. Transfer drive bevel gear 9. 5th speed gear input shaft 22. Transfer case

10 5th-reverse synchronizer hub 23. Front output shaft 11 Rear cover 24. Intermediate shaft 12 Input shaft retainer 25. Input shaft 13 Reverse gear

A double-mesh prevention device using an interlock plate and a reverse mis-shift prevention device using a stopper plate are adopted in the shift control system. The construction and operation of the double-mesh prevention device, and reverse mis-shift prevention device are basically the same as on the 4WD trans- mission previously used.

PLANETARY GEAR TYPE CENTRE DIFFERENTIAL Outer pinion

Viscous coupling Front output shaft

Front output

Centre differential case (ring gear)

Furthermore, since there is a viscous coupling built in this centre differential, when a rotational speed difference arises between the front output shaft and centre shaft, differential control torque is redistributed according to that difference so that the ideal drive force is always maintained. In addition, unequal torque distribution is used in this centre differential.

09F0126

2-6 POWER-TRANSMISSION COMPONENTS - Manual Transmission

W5MG1 4WD TRANSMISSION The W5MG1 is a 3-shaft, full time 4WD transmission. It is not only a planetary gear type differential with the center differential on the NO.3 shaft used, but also a viscous coupling acting as a differential limiter that is built into the front and rear output shafts. The gear meshing method is a constant-mesh meth- od also used for reverse. The reverse idler gear is on the rear cover. A double-cone synchronizer is used for 1st speed and 2nd speed for improved shift feeling.

The centre differential has the construction shown in the figure above, and is made up of the differential case (integral part of ring gear), outer pinions (3 pc.), inner pinions (3 pc.), carrier, sun gear, front output shaft, centre shaft and viscous coupling. Drive force input from the outside of the differential case is transmitted to the outer pinions and inner pinions by the ring gear on the inside of the case, from there is distributed to the sun gear and carrier to be transmitted to the front output shaft and centre shaft.

POWER-TRANSMISSION COMPONENTS - Manual Transmission 2-7 The distribution of the drive force to the carrier and sun gear in a planetary gear type differential is determined by the number of teeth on the ring gear and sun gear. Here is the figure of the velocity diagram if the number of teeth on the ring gear is Zr and the number of teeth on the sun gear is Zs. The carrier is considered to be fixed, the ring gear and sun gear revolve in the same direction, and the sun gear rotates Zr/Zs for one rotation of the ring gear. The figure on the left shows the velocity diagram for such a case.

According to the velocity diagram, the result is as follows if we consider a state of balance with the ring gear in the center when the ring gear and sun gear rotate at the same speed.

If Tr: Ring gear input torque Ts: Sun gear output torque (front output) Tc: Carrier output torque (rear output) Then (1) Tr = Tc+Ts (2) Tc x Zs = (Zr - Zs) x Ts From (1) and (2) Ts = Zs/Zr x Tr

Tc = (Zr-Zs)/Zr x Tr

Ts:Tc = Zs: Zr - Zs = Front: Rear With the W5MG1, Zr = 60 and Zs = 27, so Zr - Zs = 33. Front: Rear = 27: 33 = 45 : 55.

2-8 POWER-TRANSMISSION COMPONENTS - Manual Transmission

DOUBLE-CONE SYNCHRONIZER

1st speed gear Synchronizer sleeve Synchronizer

key 2nd speed gear

Synchronizer hub Outer synchronizer ring

Synchronizer cone

09F0123

When the shift lever is moved toward 1st speed, the shift fork moves the synchronizer sleeve to the left. At this time, since the ball in the synchronizer key is pressed into the groove of the synchronizer sleeve by the spring, the synchronizer sleeve and key are joined and move to the left. As a result, the outer synchronizer ring is pressed to the left, friction torque is generated between the synchronizer cone and outer synchronizer ring and inner synchronizer ring, and the 1st speed gear and synchronizer hub (intermediate shaft) begin to synchronize.

Then, when the shift fork moves to the left, the synchronizer sleeve pushes the synchronizer key spring tight, crosses over the synchronizer key and moves to the left.

outer surface liner respectively, and is coupled with the clutch gear by the projections (6 locations) on the speed gear. The outer synchronizer ring touches the outer surface liner of the synchronizer cone at the inside cone surface and is coupled to the synchronizer hub by the projections (3 locations) on the outer circumference. In other words, the inner synchronizer ring and outer synchronizer ring become one ~nit with the synchronizer hub and rotate, and the synchronizer cone becomes one unit with the speed gear and rotates as they touch each other.

The double-cone synchronizer used for 1st speed and 2nd speed are made up, as shown in the figure above, of the speed gear, clutch gear (welded to the speed gear), inner synchronizer ring, synchronizer cone, outer synchronizer ring, synchronizer hub, synchronizer sleeve, synchronizer key, etc. The inner synchronizer ring touches liner of the syn- chronizer cone inner surface at the outer cone surface and is coupled to the outer synchronizer ring by the projections (3 locations) on the synchronizer hub. The synchronizer cone touches the inner synchronizer ring and outer synchronizer ring at the inner surface liner and

Then the chamfer of the outer synchronizer ring spline and the chamfer of the synchronizer sleeve spline come in contact. As a result of this contact, a major pushing force is generated in the outer synchronizer ring, the friction torque between the synchronizer cone and outer synchronizer ring and inner synchronizer ring increases, and then the difference in rotational speed of the 1st speed gear and the synchronizer hub disappears.

Under these conditions, since the synchronizer sleeve is pressed to the left, the synchronizer sleeve spline and outer synchronizer ring spline mesh.

Also, when the synchronizer sleeve moves to the left, the synchronizer sleeve spline chamfer comes in contact with the clutch gear spline chamfer of the 1st speed gear, and then the clutch gear spline and synchronizer sleeve spine mesh to complete the shift to 1 st speed.

POWER-TRANSMISSION COMPONENTS - Manual Transmission 2-9

Shift cable

TRANSMISSION CONTROL

There are vibration-prevention rubber pieces mounted on the transaxle side of the shift cable and selector cable, and on the shift lever assembly side to prevent transmission of fine vibrations to the body.

The eye end on the shift lever assembly of the shift cable has a double structure, a combination of a resin bushing and rubber bushing, and this not only provides smooth movement of the shift cable but also prevents transmission of vibration to the shift lever assembly, improving the shifting feel.

A combination of a wave washer and thrust washer are used in the shift lever shaft of the shift lever assembly, and this not only reduces the looseness in the direction of the lever shaft but also elastically supports the shift cable on the cable bracket of the shift lever assembly, reducing shaking of the shift lever.

Shaking of the shift lever caused when accelerating and decelerating due to bent of the shift and selector cables is reduced.

Vibration-prevention rubber pieces

Selector cable

Shift lever assembly 09F0074

Shift lever

2-10 POWER-TRANSMISSION COMPONENTS - Manual Transmission

The propeller shaft is a 3-section 4-joint shaft with 2 center bearings. This division into 3 sections increases the vibration frequency characteristics of the shaft bending, and reduces vibration and noise when driving at high speed. The joints for connecting each part of the propeller shaft are as follows; No.1, No.2 and No. 4 joints are cross type universal joints and No.3 joint is a Lobro joint (LJ) that can slide and

has small friction in the direction of the shaft. This structure helps reducing torque fluctuation, vibration and noise. Furthermore, the rear propeller shaft is a vibration-control type shaft (using rubber) with an inner tube inserted in the outer tube to reduce vibration and noise from the drive train.

SPECIFICA TIONS

NOTE Propeller shaft length indicates the length between center points of each joint.

CONSTRUCTION DIAGRAM

10F0007

POWER-TRANSMISSION COMPONENTS - Propeller Shaft 2-11

PROPELLER SHAFT

Item Specification

Type 4-joint propeller shaft

Propeller Length x 0.0. Front 673.5 x 65 (26.52 x 2.56)

shaft mm (in.) Center 662.5 x 65 (26.08 x 2.56)

Rear 555.5 x 75 (21.87 x 2.95)

Universal Type No.1 Cross type

joint No.2 Cross type

No.3 Constant velocity type (L6bro joint, LJ95) .

No.4 Cross type

Lubrication Pre-packed

Size mm (in.) Cross type joint 17.996 (0.7085)

journal 0.D.

Constant velocity 99.73 (3.93)

joint 0.D.

Center bearing Lobro joint

Center propeller shaft Center bearing Front propeller shaft

FRONT AXLE The drive shaft is of the Birfield joint (B.J.)-tripod joint (T.J.) type. This type features high power transmission efficiency and low vibration and noise. It has the following features. B.J. Large operating joint angle 'Compact size and decreased space req'ulrements

T.J. Axially slidable Smaller sliding friction The B.J. joint boot is made of highly-durable resin to

provide improved reliability

SPECIFICATIONS

The B.J. joint boot is made of highly-durable resin to provide improved reliability

Item Specifications

Hub, knuckle

Bearing type Unit ball bearing

Drive shaft

Joint type Outer B.J. Inner T.J.

Length (between joints) x 0.D. L.H. mm (in.) 419 x 26 (16.5 x 1.02) R.H. mm (in.) 391 x 26

(15.4 x 1.02)

Inner shaft

Bracket

kn,uckle

11F0048

2-12 POWER-TRANSMISSION COMPONENTS - Front Axle

Centre bearing

T.J.

B.J.

Unit ball bearing

Resin boot

SPECIFICA TIONS

The differential carrier and axle housing have been separated from each other, and T.J. and B.J. drive shafts arranged in between. They drive the axle shafts. The axle shaft is supported by ball bearings (inner and outer) in the axle housing and are coupled with the drive

shaft with the companion flange in between. The front of the differential carrier is supported elastically on the rear suspension crossmember via the differential support and the rear side via the differential support member.

Items Specifications Axle shaft

Type Semi-floating type Shaft dimensions

Outer bearing portion dia. mm (in.) 35 (1.38) Inner bearing portion dia. mm (in.) 28 (1.1 0) Center portion dia. mm (in.) 34.5 (1.36) Overall length mm (in.) 245.4 (9.7)

Bearing 0.D. x I.D. Outer mm (in.) 72 x 35 (2.83 x 1.38)

Inner mm (in.) 58 x 28 (2.28 x 1.10) Drive shaft

Joint type Outer B.J. Inner T.J.

Length (joint to joint) x diameter mm (in.) 395 x 28 (15.6 x 1.10) Differential

Reduction gear type Hypoid gear Reduction ratio 3.545

Differential gear type and configuration Side gear Straight bevel gear x 2* Pinion gear Straight bevel gear x 4

Number of teeth Drive gear 39 Drive pinion 11 Side gear 16 Pinion Gear 10

Bearing 0.D. x I.D. Side mm (in.) 82.500 x 45.242 (3.25 x 1.78)

Front mm (in.) 68.263 x 30.163 (2.69 x 1.19) Rear mm (in.) 76.200 x 36.513 (3.00 x 1.44)

Final drive gear backlash adjustment method Screw type

*. Denotes the gear (L.H.) which is in a single body with the viscous coupling.

Differential carrier

11 N0002

POWER-TRANSMISSION COMPONENTS - Rear Axle 2-13 REAR AXLE

Trailing arm (Axle housing)

T.J. Drive shaft

B.J .Companion flange

Axle shaft

Rotor

AXLE SHAFT

The axle shaft is a semi-floating type supported by ball bearings (outer and inner) in the housing. On models with the anti-lock braking system, there is a wheel speed sensing rotor on the axle shaft.

To prevent mud that may be deposited around the bearing (outer), a dust shield has been provided.

B.J.

Trailing arm

Companion flange

Axle shaft

2-14 POWER-TRANSMISSION COMPONENTS - Rear Axle

Dust shield

11N0009

DRIVE SHAFT A B.J.-T.J. type constant velocity joint is used in the drive shaft, featuring the same good transmission ef- ficiency, low vibration and low noise as the front drive shaft. On the axle shaft side there is a B.J. type joint that can bend to a great degree to match movement of the suspension and on the differential carrier side there is a T.J. type joint that can slide to a large amount in the shaft direction with little sliding friction.

Two-stage serration

On the axle shaft side, they are coupled with the companion flange in between. On the differential side, they are spline coupled with the side gears, the right and left drive shafts are different in length. In addition, the T.J. side of the drive shaft (R.H.) is two-stage serration coupled.

11F0006

While the conventional mechanical type limited slip differential uses a cam (differential pinion shaft) and disc equipment composed of a friction I plate, disc and spring seat in limiting the differential, the viscous

DIFFERENTIAL

The differential uses lower friction torque bearings and oil seals to improve power performance and fuel consumption. For faster differential cooling and higher reliability during high speed operation, a differential carrier with cooling fins has been adopted. A speed difference responsive viscous coupling type

Cooling fins

limited slip differential which provides outstanding performance during operation on a muddy surface has been established. There is a 4-wheel steering (4WS) oil pump on the top of the differential carrier.

11 F0001

VISCOUS COUPLING TYPE LIMITED SLIP DIFFERENTIAL

POWER-TRANSMISSION COMPONENTS - Rear Axle 2-15

coupling type limited slip differential limits the differential by use of a viscous coupling equipment consisting of outer and inner plates and silicone oil.

Front wheel

Center differential (viscous coupling)

Front differential

Rear wheel

Limited slip differential assembly

Differential

Differential limiting section (viscous coupling)

11P0066

DIFFERENTIAL SUPPORT

The front and rear of the differential carrier are mounted on the suspension crossmember by the differential

supports and differential support member. It is elastically mounted via a bushing.

Differential support (R.H.)

Differential support member

Differential support (L.H.) 11N0038

2-16 POWER-TRANSMISSION COMPONENTS - Rear Axle

3-1

DRIVE-CONTROL COMPONENTS

CONTENTS

SUSPENSION ............................................................... 2 Features .................................................................... 2

FRONT SUSPENSION ................................................. 3 Features .................................................................... 3 Specifications ............................................................ 3 Camber Adjustment Mechanism ............................... 4

REAR SUSPENSION ................................ .................. 5 Features ................................................. .................. 5 Specifications ......................................... .................. 5

Crossmember and Crossmember Support Bushing ....................................................... 6

ELECTRONIC CONTROL SUSPENSION (E CS) ..........................................................................................7 Specifications .............................................................7 Main Parts and Their Functions ................................9 System Block Diagram ..............................................9 Features of Each Mode ...........................................10 Features of Each Control .........................................10 Structure and Operation ......................................... 11

WHEEL AND TYPE .................................................... 21 Specifications ......................................................... 21

POWER STEERING ....................................................22 Specifications ..........................................................22 Steering Wheel and Column .................................. 23 Oil Pump ................................................................. 26

4 WHEEL STEERING (4WS) SYSTEM ......................27 Specifications ..........................................................27 System Construction ...............................................28 Rear Wheel Steering Oil Pump, ..............................29 Control Valve ...........................................................29 Power Cylinder ........................................................29

BRAKES ..................................................................... 30 Features .................................................................. 30

SERVICE BRAKES ....................................................31 Specifications ......................................................... 31 Front Disc Brake ..................................................... 32 Rear Disc Brake ...................................................... 33

ANTI-LOCK BRAKE SYSTEM (ABS) ........................ 34 System Drawing ...................................................... 35 ABS Electric Diagram .............................................. 36 ABS Hydraulic Function Drawing ........................... 37 Sensor ..................................................................... 38 Actuator ................................................................... 38 Electronic Control Unit (ECU) ................................. 39

PARKING BRAKE ......................................................41

A 4 wheel independent suspension system has been adopted, with the front suspension of a MacPherson strut type, and the rear suspension of a double

wishbone type. In addition, 4WS is equipped in all models.

FEATURES

1. Adoption of electronic control suspension (ECS) 2. Adoption of 4 wheel independent suspension 3. Adoption of wide tread tyres 4. Optimization of suspension geometry 5. Adoption of pillow ball type stabilizer links 6. Optimization of spring characteristics of suspension bushing 7. Adoption of a liquid filled bushing as the front suspension

lower arm bushing

1. Adoption of double elastic supported suspension members 2. Optimization of coil spring offset amount 3. Adoption of large-sized bump rubber

1. Full realization of self-diagnosis for ECS system 2. Adoption of a camber adjustment mechanism in the front

suspension 3. Adoption of camber and toe-in adjustment mechanisms in the

rear suspension

3-2 DRIVE CONTROL COMPONENTS - Suspension

SUSPENSION

Improved steering stability and riding comfort

Improved riding comfort

Improved serviceability

Perimeter type (crossed parallel) suspension mem- bers are used in the front suspension to improve driv- ing stability.

FEATURES Reduction of vibration and noise because the en-

tire suspension system is elastically supported by rubber bushings.

Ideal wheel alignment for superior driving stability and riding comfort.

Adoption of anti-driving geometry for outstanding driving stability.

Adoption of negative offset geometry for out- standing braking stability.

Offset coil springs for outstanding riding comfort. Improved serviceability due to the adoption of a

camber adjustment mechanism.

SPECIFICATIONS

Items Specifications

Suspension system MacPherson strut with coil spring and compression

rod type

Camber 0 30' Caster 355' 30'

Toe-i n mm (in.) o 3 (0 0.12) Coil spring

Wire dia x 0.D. x free length mm (in.) Vehicles for Europe 15.4 x 185.4 x 293 (0.61 x 7.30 x 11.54)

Vehicles for General Export, GCC and Australia 15.7 x 185.7 x 301.5 (0.62 x 7.31 x 11.87) Coil spring identification colour

Vehicles for Europe Pink x 2 Vehicles for General Export, GCC and Australia Blue x 1

Spring constant N/mm (kg / mm, Ibs. / in.) 39 (3.9, 218)

Shock absorber Type Hydraulic, cylindrical double acting type Stroke mm (in.) 150 (5.91 ) Damping force [at 0.3 m/sec. (0.984 ft./sec)]

Expansion N (kg, Ibs.) Hard: 2,650 (265, 584) Medium: 1,650 (165, 363) Soft: 650 (65, 143)

Contraction N (kg, Ibs.) Hard: 1,200 (120, 265) Medium: 1,150 (115, 253)

Soft: 1,000 (100, 220)

Stabilizer bar Mounting method Pillow ball type 0.D. mm (in.) 23 (0.91)

DRIVE CONTROL COMPONENTS - Front Suspension 3-3 FRONT SUSPENSION

3-4 DRIVE CONTROL COMPONENTS - Front Suspension

CAMBER ADJUSTMENT MECHANISM It is possible to adjust the camber by turning the strut lower mounting bolt.

Section A-A

Adjusting cam (eccentric bolt)

12F0028

12FOO26

Stabilizer bar

Strut assembly

No.2 crossmember

Right member

No.1 cross member Left member Lower arm

12F0082

Anti-lift geometry to control tail lifting when brak- ing.

Improved quietness due to differential carrier double elastic support structure.

SPECIFICATIONS

Items Specifications

Suspension system Double-wishbone type

Camber -010' 30'

Toe-i n mm (in.) 0.5 2.5 (0.02 0.10)

Coil spring

Wire dia. x 0.D. x free length mm (in.) 12.2 x 117.2 x 379.3 (0.48 x 4.61 x 14.93) Coil spring identification colour Blue x 2 Spring constant N/mm (kg / mm, Ibs. / in.) 28.0 (2.8, 157)

Shock absorber

Type Hydraulic, cylindrical double-acting type Stroke mm (in.) 203 (8.0) Damping force [at 0.3 m/sec. (0.984 ft./sec.)]

Expansion N (kg, Ibs.) Hard: 1,710 (171,377) Medium: 1,160 (116, 256) Soft: 560 (56, 123)

Contraction N (kg, Ibs.) Hard: 1,010 (101, 223)

Medium: 880 (88, 194)

Soft: 670 (67, 148)

Stabilizer bar

Mounting method Pillow ball type

0.D. mm (in.) 22 (0.86)

DRIVE CONTROL COMPONENTS - Rear Suspension 3-5

REAR SUSPENSION FEATURES Independent suspension for sure grip on the

ground. Arm arrangement to minimized camber variations

against the ground. Low friction design that does not put bending

force on the damper.

12F0105

Front differential support

12N0014

Rear differential support

CROSSMEMBER AND CROSSMEMBER SUPPORT BUSHING The crossmember not only receives input from each arm and link as a real suspension crossmember but also supports the rear differential.

The crossmember support bushing provides better isolation of high frequency noise such as noise from the differential and gears by using inter-mass to shift resonance.

Shock absorber

Differential support

Crossmember Upper arm

Trailing arm

3-6 DRIVE CONTROL COMPONENTS - Rear Suspension

The electronic control suspension (ECS) is a system that automatically switches the damping force char- acteristics of the four shock absorbers, front and rear, in three steps (SOFT, MEDIUM and HARD) in response to driving conditions and the conditions of the road surface. It is also possible to select two modes (TOUR and SPORT) according to driver preference. The damping

force is changed by commands from the ECS control unit; the actuator built into the shock absorbers is activated and the flow of oil inside the absorbers is varied. This system also has a diagnostic function and a failsafe function for improved serviceability and safety.

SPECIFICATIONS FRONT SUSPENSION

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-7

ELECTRONIC CONTROL SUSPENSION (ECS)

Items Specifications

Suspension system MacPherson strut with coil spring and compression

rod type

Camber 0 30' Caster 355' 30'

Toe-i n mm (in.) o 3 (0 0.12) Coil spring

Wire dia. x 0.D. x free length mm (in.) Vehicles for Europe 15.4 x 185.4 x 293 (0.61 x 7.30 x 11.54)

Vehicles for General Export, GCC and Australia 15.7 x 185.7 x 301.5 (0.62 x 7.31 x 11.87) Coil spring identification colour

Vehicles for Europe Pink x 2 Vehicles for General Export, GCC and Australia Blue x 1

Spring constant N/mm (kg/mm, Ibs./in.) 39 (3.9, 218)

Shock absorber Type Hydraulic, cylindrical double acting type Stroke mm (in.) 150 (5.91) Damping force [at 0.3 m/sec. (0.984 ft./sec.)]

Expansion N (kg, Ibs.) Hard: 2,650 (265, 584)

Medium: 1,650 (165, 363)

Soft: 650 (65, 143) Contraction N (kg, Ibs.) Hard: 1,200 (120, 265)

Medium: 1,150 (115, 253)

Soft: 1,000 (100, 220)

Stabilizer bar Mounting method Pillow ball type 0.D. mm (in.) 23 (0.91 )

Items Specifications

Suspension system Double-wishbone type

Camber -010' 30'

Toe-in mm (in.) 0.5 2.5 (0.02 0.10)

Coil spring

Wire dia. x 0.D. x free length mm (in.). 12.2 x 117.2 x 379.3 (0.48 x 4.61 x 14.93) Coil spring identification colour Blue x 2

Spring constant N/mm (kg/mm, Ibs./in.) 28.0 (2.8, 157)

Shock absorber

Type Hydraulic, cylindrical double-acting type Stroke mm (in.) 203 (8.0) Damping force [at 0.3 m/sec. (0.984 ft./sec.)]

Expansion N (kg, Ibs.) Hard: 1,710 (171, 377) Medium: 1,160 (116, 256) Soft: 560 (56, 123)

Contraction N (kg, Ibs.) Hard: 1,010 (101, 223)

Medium: 880 (88, 194)

Soft: 670 (67, 148)

Stabilizer bar

Mounting method Pillow ball type

0.D. mm (in.) 22 (0.86)

12F0036

G-sensor

3-8 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

REAR SUSPENSION

Front shock absorber (R.H.) (Built-in F.R. position detection switch and F.R. damping force changeover actuator)

ECS switch ECS indicator lamp

Steering wheel angular velocity sensor

Rear shock absorber (R.H.) (Built-in R.R. position detection switch and R.R. damping force changeover actuator)

ECS control unit

Rear shock absorber (L.H.) (Built-in R.L. position detection switch and R.L. damping force changeover actuator)

Diagnosis connector

Stop lamp switch Front shock absorber (L.H.)

(Built-in F.L. position detection switch and F.L. damping force changeover actuator)

Throttle position sensor

Vehicle speed sensor

SYSTEM BLOCK DIAGRAM

Parts Function Mounting position

Sensor ECS switch Control mode selection switch Meter bezel Steering wheel angular velocity sensor Detects turning direction and Column switch

angular velocity of steering wheel Under front seat (LH) G-sensor Detects up/down vibration of vehicle Vehicle speed sensor Detects speed of vehicle Transmission case

Throttle body Throttle position sensor Detects throttle opening Brake pedal bracket Stop lamp switch Detects condition of brake pedal Built in shock absorber (x 4) Position detection switch Detects damping conditions of

shock absorbers Actuator

ECS indicator lamp Indicates control mode Inside combination meter

Damping force changeover actuator Orifice changeover of inside of Built in shock absorber (x 4)

shock absorber

ECS control unit System control Right side of luggage compartment

Diagnosis connector Output of safe diagnosis code Side of junction block

ECS switch ECS indicator lamp

Steering wheel angular velocity sensor

G-sensor F.R. damping force changeover actuator

Vehicle speed sensor

F.L. damping force changeover actuator Throttle position sensor

Stop lamp switch R.R. damping force changeover actuator

F.R. position detection switch

F.L. position detection switch R.L. damping force changeover actuator

R.R. position detection switch

R.L. position detection switch Diagnosis connector

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-9

MAIN PARTS AND THEIR FUNCTIONS

FEATURES OF EACH MODE

Mode ECS indicator Damping force Features J

light TOUR Automatic selection Normal damping force with emphasis on a comfortable ride

depending on driving (SOFT) conditions Safe operation control when making sudden turns or during high

SOFT speed. Vehicle position control when starting and braking Comfortable riding control when there is up/down vibration of

MEDIUM- HARD the vehicle and when driving on bad roads is detected

SPORT

G Normally fixed in high Ideal mode for sporty driving damping force (HARD) Normally high damping force with emphasis on safe operation

and stability (HARD)

FEATURES OF EACH CONTROL

3-10 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

Weight and piezoelectric element

Amplifier circuit 12F0048

Steering Wheel Angular Velocity Sensor The steering wheel angular velocity sensor is made up of 2 photo interrupters and a slit plate. The photo interrupters are mounted on the column switch and the slit plate is mounted on the steering shaft. The slit plate rotates between the photo interrupters so the light from the LED of photo interrupter is interrupted and passed through and that is changed by the photo diode to an electric signal according to the steering wheel angular velocity. Furthermore, the steering turning direction can also be detected by the divergence in each 1/4 cycle of the output wave of the photo interrupters.

The inside of the G-sensor are made up of a piezoelectric ceramic and a weight. The weight adds extra force on the piezoelectric ceramic depending on the up/down vibration and the G-sensor outputs an electric signal according to the vibration due to the piezoelectric effect.

12F0003

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-11

STRUCTURE AND OPERATION SENSOR ECS Switch The ECS switch is a return type switch mounted on the meter bezel. When the battery is connected and the ignition switch turned ON, it starts in the TOUR mode. Then, it changes between the TOUR and SPORT mode each time the mode changeover switch is pressed.

G-Sensor The G-sensor detects the up/down vibration of the vehicle and outputs an electric signal. This sensor is used for controlling a comfortable ride, and it is mounted under the front seat (LH) where it can accurately detect the up/down vibration felt by the driver.

G-sensor output characteristics

Position Detection Switch The position detection switches are combined with the damping force changeover actuator built into each shock absorber. It detects the orifice changeover position of the damping force changeover actuator by the combination of the 2 switches (ON/OFF). The control unit controls the stop position of the orifice changeover based on the signal from this position detection switch.

The inside structure of the position detection switch is as shown in the figure on the left and it is made up of the encoder pattern and the brush rotating above it. Switches 1 and 2 are turned ON and OFF by the rotations of the brush. The relation between the switch output and the damping force characteristics is shown in the table below. For one revolution of the switch, the damping force changes from SOFT HARD MEDIUM HARD (unfixed)

Damping force SOFT HARD MEDIUM HARD (unfixed) Switch 1 ON OFF ON OFF OFF Switch 2 OFF ON ON ON OFF

Rotation angle 0

3-12 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

Vehicle Speed Sensor The vehicle speed sensor is mounted directly onto the transmission. For the structure of the vehicle speed sensor, refer to GROUP 7 - Meters and Gauges.

3600

section and output shaft. The output shaft has a high torque output because the high revolutions of the micro-motor are reduced by the deceleration gear.

12F000 6

Deceleration gear

Position detection switch

12 F0053

Damping force changeover actuator

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-13

ACTUATOR ECS Indicator Lamp There is an indicator lamp (green) to indicate the mode in the combination meter. When a breakdown is detected, it flashes at intervals of 0.5 second to warn the driver.

Mode TOUR SPORT When breakdown

TOUR lamp ON OFF Flashing SPORT lamp OFF ON Flashing

Damping Force Changeover Actuator The damping force changeover actuator is built into the front and rear shock absorbers and designed for compactness, lightweight and reduction of mounting space. It is made up of the micro-motor section, deceleration gear section, position detection switch

Micro-motor

Output shaft

HARD

SHOCK ABSORBER The shock absorber comes with a built in damping force changeover actuator (including a, position detection switch) and the damping force can be changed in 3 steps (SOFT, MEDIUM and HARD) with this actuator.

Furthermore, the piston valve has a double seat and the base valve is made of 2 valves; accurate control is possible at any damping force step for achieving both safe operation and comfortable riding.

12FOOOS

12F0009

Rear shock absorber cross section

Base valve

Piston valve

Front shock absorber cross section

The damping force is changed in 3 steps by combining the rotary valve and piston rod passages. When the ECS control unit confirms the change in the damping force by the command from the position detection switch, it stops the signal sent to operate the damping force changeover actuator.

12F0047

3-14 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

SOFT

MEDIUM

SOFT MEDIUM HARD

Piston speed

Damping force changeover actuator

Rotary valve

Piston rod

Damping force

Expansion side

Contraction side

Damping force characteristics

Check nut

Piston

12F0008

Damping Force Changeover Mechanism For damping force changeover, the damping force changeover actuator is operated by a signal from the control unit which causes the rotary valve built into the piston rod to rotate and changes the opening/closing of the orifice and the oil flow passage area. The rotary valve has large and small orifices (1 each for a total of 8) as shown in the cross sections A-A, B-B, C-C, and D-D in the figure below. There is also one passage (for a total of 4) for each cross section in the piston rod.

12F0037

When rebounding As the piston rod rises, oil flows as shown in the figure on the left and the damping force is determined by the flow resistance of the piston valve.

MEDIUM (medium damping force) When bounding

Compared to SOFT damping force, the orifice diameter is smaller, piston rod flow resistance increases and the damping force is the force combined with the flow resistance on the base valve side.

When rebounding The orifice diameter is smaller just as when bounding and a higher damping force than at SOFT is obtained.

HARD (high damping force) When bounding Since the orifice is closed, oil in the lower part of the piston pushes wide the valve in the upper part of the piston and flows out so flow resistance increases and a higher damping force than at MEDIUM is obtained.

When rebounding This is the same as when bounding. Since the orifice is closed, damping force is at its maximum.

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-15

Internal Operation of Shock Absorber

SOFT (low damping force) When bounding The damping force is determined mainly by the flow resistance on the base valve side and a low damping force is obtained by passing oil in the lower part of the piston through the check valve built into the check nut and the orifice (large dia.) with no resistance.

The ECS control unit is mounted on the inside of the rear side trim. The ECS control unit sends a signal to the damping force changeover actuator to simultaneously

Structure

ECS switch

Vehicle speed sensor

Stop lamp switch

Throttle position sensor

G-sensor

change the damping force of the 4 shock absorbers.

ECS control unit

ECS indicator lamp

F.R. damping force changeover actuator

F.L. damping force changeover actuator

R.R. damping force changeover actuator

R.L. damping force changeover actuator

12F0062

3-16 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

ECS CONTROL UNIT

F.R. position detection switch

F.L. position detection switch

R.R. position detection switch

R.L. position detection switch

Steering wheel angular velocity sensor

Function Chart

S: SOFT M: MEDIUM H: HARD

Anti-Rolling Control CONTROL START

Change to a higher damping force according to the control map for the vehicle speed and steering wheel angular velocity which depends on the operation of the steering wheel. CONTROL HOLD

After switching to a high damping force and holding that condition for 1 second, return to normal damping force (SOFT).

High Speed Response Control

CONTROL START

When vehicle speed exceeds 130km/h (81 mph) in the TOUR mode, the damping force changes from SOFT to MEDIUM to improve high speed stability. CONTROL HOLD

Damping force which is changed to MEDIUM is held while the vehicle speed is over 120km/h (75 mph) but when it falls to 120km/h (75 mph), the damping force returns to SOFT.

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-17

Anti-Squatting Control CONTROL START When the accelerator pedal is pressed (returned), it changes to a higher damping force through map control of the vehicle speed and speed change in throttle opening (closing). There are 2 control maps - when the accelerator pedal is pressed and when it is returned (throttle opened and closed). Furthermore, when the throttle position sensor output voltage stays over 4.0V for more than 1 second at vehicle speed of 3 - 100km/h (2 - 62 mph), it is judged that there is full throttle acceleration and the damping force is switched to MEDIUM. CONTROL HOLD After changing from a high damping force, there is first a 1 second hold in that condition and then the suspension reverts to the normal damping force (SOFT). When full throttle acceleration is judged, the suspension reverts to the normal damping force (SOFT) in one second after the control conditions are not satisfied.

Pitching/Bouncing Control CONTROL START

When the ECS control unit judges that there is serious pitching and bouncing of the vehicle (washboard road driving) via the output of the G-

CONTROL HOLD

When the ECS control unit judges that there is no more pitching and bouncing of the vehicle via the output of the

Bad Road Response Control When the ECS control unit judges that there is fine pitching and bouncing of the vehicle (bad road such as gravel road, etc.) via the output of the G-sensor, the suspension is changed to MEDIUM for improved riding

Warning Display Function When a breakdown is detected, the TOUR and SPORT ECS indicator light in the meter blinks at 0.5 sec.

Fail-safe and Diagnosis Function When the ECS control unit detects a breakdown, control related with that breakdown phenomenon stops and the

sensor, the damping force is changed to HARD for a flat and comfortable ride with no vehicle pitching and bouncing.

G-sensor, normal damping force (SOFT) takes over at the same time.

/

comfort and bad road driving even if the damping force should be set to HARD by some other control.

intervals to warn the driver of an abnormality.

damping force is fixed on the fail safe side. At the same time, the self-diagnosis code related to the breakdown phenomenon is output to the diagnosis connector.

of deceleration exceeds 0.4G, there will be a change to HARD. CONTROL HOLD

The damping force after changeover is held while calculated deceleration is over 0.15G and when it falls below 0.15G, the damping force returns to normal (SOFT).

Anti-Diving Control CONTROL START

When the stop light switch goes ON, the ECS control unit calculates deceleration from the change in vehicle speed. As a result, after the stop light goes ON, if deceleration calculated within 0.4 sec. exceeds 0.15G, the shock absorber damping force is changed to MEDIUM. If the stop light switch is ON and the computed degree

3-18 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

NOTE 1. An "X" indicates normal operation and a "---" indicates stop of control. 2. Control stop, warning display and fixing of damping force return to normal operation when the ignition switch is turned

OFF. However, in the case of breakdowns marked with an asterisk (*), normal operation is resumed if normal output is generated even when the ignition switch is in ON (e.g. transient breakdown). In this case, the self-diagnosis code is in memory in the ECS control unit even while normal operation resumes.

DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS) 3-19 FAIL-SAFE AND DIAGNOSIS CODE TABLE

Service data output function The ECS control unit receives the data input for control and outputs it to the diagnosis connector as a serial signal. SERVICE DATA CHART

Item No. Service data items

11 G-sensor output

14 Throttle position sensor output

21 Steering wheel angular velocity sensor output

24 Vehicle speed sensor output

26 Stop lamp switch

61 F.R. actuator condition

62 F.L. actuator condition

63 R.R. actuator condition

64 R.L. actuator condition

Actuator test function By using the multi-use tester to send an order to the ECS control unit, it is possible to force-drive the ac- tuator. ACTUATOR TEST CHART

Item No. Actuator test items Shock absorber damping condition

01 Damping force SOFT Damping force for 4 shock absorbers set to SOFT

03 Damping force MEDIUM Damping force for 4 shock absorbers set to MEDIUM

04 Damping force HARD Damping force for 4 shock absorbers set to HARD

NOTE The damping force set is released under the following 3 conditions Ignition switch is turned OFF Vehicle speed becomes 3km/h (1.9 mph) or more Multi-use tester is disconnected

3-20 DRIVE-CONTROL COMPONENTS - Electronic Control Suspension (ECS)

DRIVE-CONTROL COMPONENTS - Wheel and Tyre 3-21

WHEEL AND TYRE SPECIFICATIONS

Items Specifications

Tyre size 225/50R17

Wheel type Aluminum type Wheel size 17 x 7 1/2 JJ Amount of wheel offset mm (in.) 46 (1.8) Tyre inflation pressure kPa (kg/cm2, psi)

Front 220 (2.2, 32) Rear 200 (2.0, 29)

POWER STEERING The steering wheel comes with SRS (Supplemental

Restraint System). (Refer to GROUP 6-SRS for SRS.)

The steering column has a shock absorbing struc- ture and tilt steering mechanism.

SPECIFICATIONS

The oil pump is a vane type oil pump with a fluid flow control system so the steering force varies according to engine speed.

The steering gear and linkage uses an integral type rack and pinion system.

Items Specifications

Steering wheel maximum turns 2.52

Steering angle (vehicle in unladen) Inner wheel 3345' 2 Outer wheel 2821'

Steering gear and linkage Type Integral type Gear type Rack and pinion Gear ratio (infinity)

Rack stroke mm (in.) 144 (5.7)

Oil pump type Vane type with fluid flow control system Displacement cm3/rev. (cu.in. / rev.) 9.6 (0.59) Relief set pressure MPa (kg / cm2, psi) 8 (80, 1,138)

13F0054

3-22 DRIVE-CONTROL COMPONENTS - Power Steering

Steering wheel

Steering column

Tilt lever

Steering gear and linkage 13F0044

Oil pump

Oil reservoir

Cooler tube

The steering whee~ and column have the following features that make maneuverability and safety really outstanding. The steering wheel has an outstanding design

that promotes maneuverability and a good view of the meters. Furthermore, SRS is built into the steering wheel to assure driver protection.

STEERING WHEEL CONSTRUCTION

Section A-A

SRS

The steering shaft and column absorb shock energy when there is a collision with its shock absorbing structure that protects the driver.

The height of the steering wheel can be adjusted. A tilt steering mechanism is used to obtain the best driving position and the ideal driving posture.

13F0060

DRIVE-CONTROL COMPONENTS - Power Steering 3-23 STEERING WHEEL AND COLUMN

Auto-cruise control switch

Tilt lever

TILT STEERING CONSTRUCTION The tilt steering consists of the tilt lever, tilt bolts (A, B), tilt bracket and column plate, etc. The tilt bolts (A, B) are attached to the end of the tilt lever; tilt bolt A

has right threads and tilt bolt B has left threads, and the tilt bracket is pressed and fixed to the column plate with the tilt bolts (A, B).

TILT STEERING OPERATION (1) If the tilt lever is lowered to the free position, the tilt bolts (A,

B) move in the loosening direction (outer side) so the steering column can be slid up and down.

(2) If the tilt lever is pulled up to the lock position, the tilt bolts (A, B) move in the tightening direction (inner side) so the tilt bracket is pressed to the column plate, fixing the steering column.

Steering column Cross section A-A

Tilt bracket

Column plate

Tilt bolt B

3-24 DRIVE-CONTROL COMPONENTS - Power Steering

Tilt bolt A

. Lock

Free

Tilt lever

13F0021

13F0016

SHOCK ABSORBING STRUCTURE (1) When the vehicle collides with something and

there is a load added to the steering shaft from the gear box (primary shock), the lower shaft of the steering shaft assembly crushes the polyacetal resin, absorbing the shock load using the friction of the steering column (lower) and steering column bush as it slides into the lower pipe.

(2) When the driver strikes his body on the steering wheel (secondary shock), the steering column bracket crushes the polyacetal resin, pushing it to the front and absorbing the shock load.

DRIVE-CONTROL COMPONENTS - Power Steering 3-25

OIL PUMP

The oil pump is a vane type oil pump with fluid flow control system that provides light steering at low

engine speed and ideal harder steering at high speed.

OIL PUMP PERFORMANCE

13F0042

NOTE (1) P-Qf characteristic: Pump pressure and pump delivery rate (2) N-Qf characteristic: Pump speed and pump delivery rate

3-26 DRIVE-CONTROL COMPONENTS - Power Steering

SPECIFICATIONS

Items Specifications

Rear wheel max. steering angle (deg) 1.5

Steering gear & linkage Type Integral type Gear type Rack & pinion type Gear ratio Infinite Rack stroke mm (in.) 144 1 (5.67 0.04)

Power steering oil pump Type Vane type (with flow control valve) Delivery rate cm3/ rev. (cu.in. / rev.) 9.6 (0.59) Relief set pressure MPa (kg / cm2, psi) 8 (80, 1,138) Rotating direction Clockwise (viewed from pulley side)

Rear wheel steering oil pump Type Vane type (with flow control valve) Delivery rate cm3/ rev. (cu.in. / rev.) 3.3 (0.20) Relief set pressure M Pa (kg / cm2, psi) 4 (40, 569)

Rotating direction (normal) Clockwise (viewed from gear side)

Power cylinder Type Hydraulic double-acting type Full stroke mm (in.) 20 (0.8) [10 (0.4) for one side] Cylinder bore mm (in.) 43 (1.7)

DRIVE-CONTROL COMPONENTS - 4 Wheel Steering (4WS) System 3-27 4 WHEEL STEERING (4WS) SYSTEM By adding steering to the rear wheels, a 4 wheel steering system has been established which improves controllability and stability in the medium and high speed range.

NOTE The 4WS vehicles are basically identical to Galant 4WD in the construction and operation of the 4WS.

Power steering oil pump

Oil reservoir

Power cylinder

Control valve

Rear wheel steering oil pump

13F0039

Steering gear and linkage

SYSTEM CONSTRUCTION The hydraulic power cylinder is connected to the

middle joint of the rear trailing arms. Hydraulic pressure for the rear steering power

cylinder is generated by an oil pump driven by the rear differential gear. This pressure is controlled by the power steering hydraulic pressure via the control valve. In this way, the rear wheel steering angle is controlled according to the front wheel steering effort.

The oil pump for the rear wheel steering delivers the amount of oil proportional to the rear wheel speed. This allows rear wheel steering angle control proportional to the vehicle speed at middle and high speeds [over approx. 50 km/h (31 mph)].

This construction allows the rear wheels to be steered in the same phase with the front wheels when cornering at middle and high speeds, de- veloping side force at the rear tyres almost simul- taneously with side force generation at the front tyres.

Oil reservoir

Power steering oil pump

Rear wheel oil pump

3-28 DRIVE-CONTROL COMPONENTS - 4 Wheel Steering (4WS) System

Steering wheel

Control valve

Power cylinder

Middle joint

Trailing arm

13A0241

Driven gear

The basic construction of the pump is the same as the power steering oil pump.

Drive gear Differential gear

Mounted on the top of the rear suspension cross- member, this control valve controls oil pressure to the power cylinder by controlling the spool that switches the

oil flow path by pilot oil pressure from the steering gear box.

The power cylinder tie rod is linked to the middle joint of the right and left trailing arms. The piston rod in the power cylinder moves either to the right or left ac-

Control valve mounting bracket

cording to the steering wheel effort and vehicle speed, thereby steers the rear wheels.

13N0015

DRIVE-CONTROL COMPONENTS - 4 Wheel Steering (4WS) System 3-29

REAR WHEEL STEERING OIL PUMP The rear wheel steering oil pump driven by a dedicated drive gear in the rear differential carrier delivers the amount of oil corresponding to the rear wheel speed.

CONTROL VALVE 13F0010

13F0006

Crossmember POWER CYLINDER

The service brakes use a brake system featuring ex- cellent braking force and a high level of reliability and durability.

1. Four-wheel anti-lock braking system (4ABS) to prevent slipping due to locking of the wheels and for applying the ideal braking force is used.

2. Ventilated brake discs are used on all four wheels. 3. Face-to-face and different diameter 4-piston front ventilated disc

brakes made from aluminium have been adopted. 4. Face-to-face 2-piston rear ventilated disc brakes made from

aluminium have been adopted. 5. A tandem brake booster is used for a big braking force with a

light pressure on the brake pedal.

A diagnosis function has been adopted in the ABS.

1. An audible wear indicator is adopted to warn the limit of pad use.

2. The X-arrangement of the brake lines for front and rear wheels is used.

3-30 DRIVE-CONTROL COMPONENTS - Brakes

BRAKES

FEATURES

Improved braking performance

Improved serviceability

Improved safety

Items Vehicles for Europe Vehicles for General Export, GCC

and Australia Master cylinder

Type Tandem (with level sensor) Tandem (with level sensor) 1.0. mm (in.) 26.9 (1 1/16)) 26.9 (1 1/16)

Brake booster Type Vacuum type, tandem Vacuum type, tandem Effective dia. of mm (in.) 205 (8.0) + 230 (9.0) 205 (8.0) + 230 (9.0) power cylinder

Proportioning valve Type Dual type Dual type Split point kPa (kg/cm2, psi) 3,750 - 4,250 (37.5 - 42.5, 533 - 604) 2,750 - 3,250 (27.5 - 32.5,391 - 462)

Decompression ratio 0.37 0.25

Front brakes Type Rigid caliper, 4-piston, Rigid caliper, 4-piston,

ventilated disc (M-R76Z) ventilated disc (M-R66Z) Disc effective dia. mm (in.) 270 x 30 (10.6 x 1.18) 249 x 30 (9.8 x 1.18) x thickness Cylinder I.D. mm (in.) 40.4 (1 19/32) x 2 + 42.8 (1 11/16) x 2 40.4 (1 19/32) x 2 + 42.8 (1 11/16) x 2

Clearance adjustment Automatic Automatic

Rear brakes Type Rigid caliper, 2-piston, Floating caliper, 1-piston,

ventilated disc (M-R68X) ventilated disc (M-R58V) Disc effective dia. x mm (in.) 250 x 20 (9.8 x 0.79) 237 x 20 (9.4 x 0.79) thickness Cylinder I.D. mm (in.) 38.1 (1 1/2) x 2 38.1 (1 1/2)

Rotor teeth Front 47 47

Rear 47 47

Speed sensor Magnet coil type Magnet coil type

DRIVE-CONTROL COMPONENTS - Service Brakes 3-31 SERVICE BRAKES SPECIFICATIONS

14F0071

Piston (small)

FRONT DISC BRAKE A face-to-face and different diameter 4-piston type made from aluminium has been adopted for the front disc brakes. Not only is braking force well balanced with pressure applied evenly over the entire pad surface but there is also outstanding and stable braking performance preventing uneven pad wear and providing a good

14F0029

braking feeling. For safety, there is an audible wear indicator on the inner side of the pad to warn when the limit of pad use has been reached. Clearance is automatically adjusted by pressing on the brake pedal.

3-32 DRIVE-CONTROL COMPONENTS - Service Brakes

Piston (large)

14F0030

Wear indicator 14F0041

DIFFERENT DIAMETER PISTONS During braking, hydraulic pressure is generated in each piston to press the pad against the rotor. Since there is a lengthwise play between the pad and the caliper, the pad is pressed against the trailing side caliper and a gap is made on the leading side. At this time, not only the piston surface pressure but also the moment act on the leading side pad and wear on the leading side pad is increased. Therefore, since the leading side piston diameter is made small and the surface pressure distribution is smaller than on the tailing side, the pad acting force both on leading side and trailing side is balanced for equal wear.

14F0123

REAR DISC BRAKE A face-to-face 2-piston type made from aluminium has been adopted for the rear disc brakes in vehicles for Europe, and floating caliper single piston type has been adopted in vehicles for General Export, GCC and Australia. In addition, a drum in disc method is used with a parking

brake built into the brake disc. For safety, there is an audible wear indicator in the inner side of the pad to warn when the limit of pad use has been reached. Clearance is automatically adjusted by pressing on the brake pedal.

Backing plate

Brake shoe

Adjuster

14F0124

Brake shoe

14F0039

14F0122

Wear indicator

DRIVE-CONTROL COMPONENTS - Service Brakes 3-33

Adjuster

Backing plate

14N0162

Wear indicator

14N0131

Brake shoe

14F0039

14N0086

Brake shoe

ANTI-LOCK BRAKING SYSTEM (ABS) With the use of ABS in 4WD models, not only is the driving" of a 4WD model improved but the "stopping" performance is also greatly improved. Driving performance is well balanced in all ways from better

performance on dry roads to better performance under all conditions such as slippery road surfaces, etc. The ABS is a 4 sensor, 2 channel system, and is basically the same as that equipped in the GALANT 4WD.

3-34 DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS)

14F0059

Part name No. Function

Wheel speed sensor 1 Sends a wheel speed signal from each wheel to the ECU.

Sensor G-sensor 2 Sends an ON/OFF signal to the ECU depending on vehicle

acceleration.

Stop lamp switch 3 Sends a signal to the ECU indicating whether the brake pedal is

pressed on not.

Hydraulic unit (HU) 4 Controls braking pressure for each wheel depending on the signal from the ECU.

Includes built-in select-low valve

Motor reltly 5 Is turned ON by the ECU signal and drives the pump motor in HU.

Actuator Valve relay 6 Is turned ON by the ECU signal and supplies power to the solenoid valve in HU.

ABS warning lamp 7 Is in the combination meter and lights up when there is trouble iO

ABS.

Diagnosis connector 8 Outputs diagnosis codes.

Electronic control unit (ECU) 9 Drives the hydraulic unit, etc. based on signals from the various

sensors. Select-low valve 10 Is in HU and matches brake pressure in the rear right and left

wheels to the pressure on the low side.

14F0063

DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS) 3-35

SYSTEM DRAWING

Front left wheel (FL) Rear left wheel (RL)

FL

14F0062

3-36 DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS)

ABS ELECTRIC DIAGRAM

rear right and left wheels - are controlled hydraulically at the same time. Also, if vehicle speed exceeds approximately 8 km/h (5.0 mph), the brake hydraulic pressure control is ap- plied and when it becomes less than approximately 3 km/h (2.0 mph), the control is completed. Select-low: this is a method of providing the same hydraulic control to both wheels when either wheel is about to lock, matching it to the side about to lock, or a method to control by matching pressure to the low side.

14F0061

DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS) 3-37 ABS HYDRAULIC FUNCTION DRAWING The ABS uses 2 channels (2 hydraulic systems) with the hydraulic control method being as follows. It controls the front and rear wheels on the same side with select-low and drives the solenoid valve including the one for the front wheel. For example, when either the front or rear wheel on the right side is about to lock, it maintains or loosely controls the solenoid valve including the one for the front right wheel. And in order to prevent locking of one rear wheel, there is a select- low valve and the rear right and left wheels are controlled mechanically by select-low. Consequently, a total of three wheels - the front right or left wheel and the

The sensors for the front wheel consist of a speed sensor mounted on the knuckle and a rotor (47 teeth) that is mounted on the drive shaft (B.J. outer race).

The sensors for the rear wheel consist of a speed sensor mounted on the trailing arm axle housing and a rotor (47 teeth) that is mounted on the rear axle shaft.

By improving the mounting precision of the sensor, it is possible to make the speed sensor and rotor gap unadjustable types.

Front wheel Rear wheel

14F0057 14N0118

ACTUATOR HYDRAULIC UNIT (HU) The HU is supported elastically via the bracket in the fender shield. Since the brake lines are in an X-arrangement, there is

also a 2-system separation in the HU with one solenoid valve each (for total of 2). There is also a select-low valve.

Relay box

Pump motor

Front

Solenoid valve

Select-low valve

14F0072

3-38 DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS)

SENSOR WHEEL SPEED SENSOR

DRIVE-CONTROL COMPONENTS - Anti-lock Braking System (ABS) 3-39

ELECTRONIC CONTROL UNIT (ECU) The ECU is mounted on the quarter inner lower panel (RH). The ECU is made up of 2 microprocessors, in- put/output interface, etc. Since there are two central processing units (CPU), there is a double check; the wheel speed sensor signal and valve control signal are

compared by both CPUs and, if the data do not match, ABS control is stopped. Furthermore, there is a diagnostic function for easy diagnosis of breakdowns.

WARNING LAMP CONTROL The lamp illuminates when an abnormality is detected in the system. Also, the lamp will illuminate as shown in the illustration at left in conjunction with operation of the ignition switch when checking a lamp blowout.

DIAGNOSIS FUNCTIONS The ECU has the following functions to facilitate in- spection of the system. Self-diagnosis code output function Actuator test function Diagnosis erasure function

SELF DIAGNOSIS CODE OUTPUT FUNCTION There are 13 diagnosis items, and the diagnosis result is recorded even if the battery terminals are disconnected.

Output Diagnosis item Output Diagnosis item code code -- Normal 22 Stop lamp switch ON malfunction or broken

wire

11 Broken wire or short in wheel speed sensor 41 Abnormality in solenoid valve (FL., R.R.)

(FL.)

12 Broken wire or short in wheel speed sensor 42 Abnormality in solenoid valve (FR., R.L.)

(F R.)

13 Broken wire or short in wheel speed sensor 43 Solenoid valve drift error

(R.R.)

14 Broken wire or short in wheel speed sensor 51 Abnormality in valve relay

(R.L.)

15 Wheel speed sensor abnormality 52 Abnormality in motor relay or pump motor

21 Broken wire in G sensor or OFF malfunction 55 Abnormality in ECU

ACTUATOR TESTER FUNCTION The actuator can be force-driven using the multi-use tester to enable easy operation inspection to be carried out.

NOTE 1. If the ECU function has been cancelled, then an

actuator test cannot be carried out.

2. Actuator testing is only possible when the vehicle is stationary. If the vehicle speed during actuator testing exceeds 10 km/h (6 mph), forced actuation will be cancelled.

3. The following item numbers are the numbers input to the multi-use tester when an actuator test instruction has been given.

3-40 DRIVE-CONTROL COMPONENTS - Anti-lock Brake System

PARKING BRAKE The parking brake is of the mechanical rear wheel braking type. The parking brake is offset toward the driver's seat from the vehicle centreline for greater ease of operation.

The parking brake cable is of the V-type and is acces- sible for adjustment through the service hole provided in the floor console.

14F0064

DRIVE-CONTROL COMPONENTS - Parking Brake 3-41

NOTES

BODY CONTENTS

AIR PRESSURE NOISE REDUCTION ........................ 9 Flush Surface ............................................................ 9 Full Glass Catch ...................................................... 10

DOORS .. 10 Door Panel .............................................................. 10 Door Lock ................................................................ 11 Window Glass Regulator ......................................... 12

LID ............................................................................... 13 Hood ........................................................................13 Tailgate ....................................................................13

WINDOW GLASS .......................................................13

SUNROOF ................................................................... 14

4-1

GENERAL DESCRIPTION .............. .............................2 Features ....................................... ............................ 2

MAIN BODY .................................... ............................ 3 Body Panelling ............................. : .......................... 3 Body Shell .................................... .............................4 Interference Panel Coating .......... ............................ 6 3C1B Pearl Coating ..................... ............................ 7 Coloured Pearl Coating ................ ............................ 7 Body Colour Charts ...................... ............................ 8

GENERAL DESCRIPTION FEATURES

Light weight Added rigidity

1. Ample use of high strength steel sheets 2. Improvement in rigidity of outer door panels by use of effective reinforcements

Corrosion control

Ample use of anti-corrosion steel sheets

1. Thorough utilization of flush surfaces 2. Adoption of full glass catches

1. Improvement in door operation feeling due to adoption of a roller type 2-step door check

2. Use of side door beams 3. Adoption of gas springs to reduce the operation force for opening and closing the

hood

1. Rubber coating on door latches to improve the door operational feel and for less noise when opening and closing

2. Adoption of a detachable sunroof

4-2 BODY - General Description

Reduction in vibrations, noises and aerodynamic noise

Improved controllability and safety

Improved merchantability and appearance

BODY - Main Body 4-3

DASH PANEL The dash panel is not a double-walled structure consisting of the dash panel and dash panel reinforcement as in former models but is made

Furthermore, the hood latch bracket has a closed cross section to improve strength.

(2) A large headlamp housing is used to improve strength.

from a single thick plate. The engine compartment has effectively expanded while preserving rigidity.

REAR END PANEL The rear end panel is mounted on the outside of rear lamp housings so the panel replacing work becomes easier.

31F0096

4-4 BODY - Main Body

BODY SHELL HEADLAMP SUPPORT A structure as shown below is used with the large soft fascia which consists of the front bumper, skirt panel and header panel moulded into one unit.

(1) A large and very rigid front end upper bar is used.

Rear lamp housing

Rear end panel 31F0013

Front end upper bar

Hood latch bracket 31 F0124 30F0064

Front end upper bar

Rear lamp housing

Rear end panel

Dash panel

Foot rest bracket

Front floor side sill, inner, front Dash panel crossmember Muffler hanger reinforcement

Front floor upper panel

FRONT FLOOR A double-floor structure is adopted, this not only im- proves rigidity but also reduces air resistance be- cause of the flatness of the floor's bottom surface.

(1) A very rigid, double-layer floor is used with a front floor sidemember on the upper surface of the front floor and also a front floor upper panel on top.

(2) There is Iarge, integrated backbone reinforcement on the upper surface of the front floor to improve rigidity.

(3) The number of beads in the front floor pan is reduced to make the bottom surface of the floor flat.

Backbone reinforcement

Shift lever reinforcement

Front floor pan

Front floor sidemember Backbone crossmember

Front seat rear nut plate

BODY - Main Body 4-5

Front floor crossmember, rear

Front floor crossmember, front

Front floor side sill, inner

31 F01 01

31 F0010

Front door, outer

Side impact bar

31F0011

DOOR A tubular type side impact bar has been adopted.

INTERFERENCE PEARL COATING Powder mica used in interference pearl coating has its surface coated with titanium dioxide in the same way as the powder mica used in conventional white pearl coating. Since light is reflected by a boundary surface between objects of different density, the reflection of light occurs first on the titanium surface and then on the boundary surface between titanium and mica. Therefore, there is a phase lag between these two events of reflection of light. When, however, the amount of titanium dioxide is small as in the case of powder mica used in white pearl coating, the phase lag is almost negligible and a nearly total reflection takes place, giving a pearl white luster tinted by mica.

Interference mica

Titanium dioxide 3050046

Reflection by boundary surface (thin)

Reflection by boundary surface (thick)

Reflection by surface

, Reflection by boundary surface

Surface Boundary surface

3050047

Varieties of blue

Damped

Reflection by boundary surface

Amplified

In interference pearl coating, the thickness of titanium dioxide coating on powder mica is increased to make the phase lag longer so that colours may be developed by interference of light. When the coating is thin, light of short wave length is damped and that of long wave length is amplified. This tendency is reversed when the coating is thick. As the coating thickness increases, the colour changes from white to gold (yellow), red, purple, blue and green in that order. Toscana black: Interference blue mica

Varieties of blue

3050048

Varieties of red

4-6 BODY - Main Body

Boundary surface (thin)

Boundary surface (thick)

Varieties of red Surface

Mica

Amplified

3050050

Reflection by boundary surface

I Reflection by surface

Damped 3050052 3050051

Reflection by surface

3C1B PEARL COATING The 3-coat pearl coating so far effected by 3C38 (3-coating and- 2-baking method) has been made possible by 3C1B (3-coating- and-1-baking method).

COLOURED PEARL COATING The powder mica surface coated with titanium dioxide is further coated with coloured inorganic compound for its colouring. The hue is determined by combination of the hue of powder mica (base) and that of the coloured inorganic compound used. Kutani red: White mica powder coated with a strong red-

coloured iron oxide is in use.

BODY - Main Body 4-7

4-8 BODY - Main Body

Windshield glass

AIR PRESSURE NOISE REDUCTION FLUSH SURFACE Measures were taken to improve the feeling of quality and to reduce air resistance and air noise by making all parts matched with flush surface. Furthermore, indentations of the vehicle underbody have been

drastically reduced to improve the air pressure effect by regulating the flow under the floor.

Windshield glass

BODY - Air Pressure Noise Reduction 4-9

18F0217

Front bumper

Engine hood

Door window glass (complex curved glass)

Roof

Roof

Liftgate glass

18F0078

Since the door glass is sucked out by the vacuum caused by air flow when driving at high speed, a full glass catch is mounted to the weather-strip holder in order to press the door glass in place. As a result, a

good seal between the drip line weather-strip and the door glass is assured and the sucking noise when driving at high speed is shut down.

Cross section A-A

DOORS

Full glass catch

Door window glass-

Drip line weather-strip

Weather-strip holder

4-10 BODY - Air Pressure Noise Reduction I Doors

DOOR PANEL A sashless door is used. Furthermore, rigidity of the outside panel is improved by efficient use of a light-

weight side door beam made of pipe and reinforce- ments.

Side door beam

Beltline outer reinforcement

Door mirror reinforcement

Hinge reinforcement

Beltline inner reinforcement

Door latch reinforcement

18F0209

Door upper hinge

DOOR LOCK A roller type 2-step door check is used on all models which improves the operational feel when opening and closing the door and it holds the door securely at the midway position. The door latch is rubber coated to improve the operation feel and for less noise when opening and closing the door.

Central door locking with a key reminder system has been adopted so that all doors can be locked and un- locked by means of the driver's side inside lock knob or by the door lock key. NOTE Refer to GROUP 54 - ETACS for central door locking.

18F0207

Outside handle

BODY - Doors 4-11

Latch

Door lock actuator

Door check

Door lower hinge

OPERATION OF DOOR CHECK STRAP It is made so the rollers which can rotate in the door check arm is pushed up and down by the spring. When the door is opened/closed and the roller reaches the indented position in the door check arm, the door can be held securely in the opened position. Because the roller rotates, the operational feeling is good when opening/closing the door.

WINDOW GLASS REGULATOR A wire winding system is used in the window glass regulator. Power windows which use a wire winding system in the window glass regulator are equipped on all models. Furthermore, the amount of lateral movement of the window glass regulator carrier plate is increased so the lateral deflection of the glass which happens when opening and closing the com- plex curved glass door window can be absorbed. In

Door window glass

order to prevent the glass from getting scratched, a glass striker is mounted on the outside of the door glass so the beltline weather-strip outer stabilizer is only effective when the window is fully closed. When the window is fully closed, the glass striker is inserted between the outer stabilizer and door glass and firmly presses the door glass.

Carrier plate

Door window regulator assembly

4-12 BODY - Doors

18F0208

BODY - Lid/Window Glass 4-13

LID HOOD Since the hood has been enlarged, a gas type spring is used to reduce the force needed for opening and closing it.

TAILGATE The tailgate uses an inner hinge system with inverted gas springs. Furthermore, a cable type tailgate opener is used for all models.

In order to preserve the image of a capsule cabin, complex curved glass is used for the door window glass.

WINDOW GLASS An adhesive method is used to mount the wind-

shield glass, quarter window glass and tailgate glass.

Laminated glass is used for the windshield glass and reinforced glass is used for the door window glass, quarter window glass and tailgate glass in order to improve safety.

Name Thickness

mm (in.)

(1)Windshield 5.3 (0.21) glass

(2) Door window 5.0 (0.20) glass

(3) Quarter

window glass 3.5 (0.14)

(4) Tailgate glass

Deflector

SUNROOF A tilt-up and detachable sunroof with excellent lighting ability and a feeling of space and made from strengthened glass has been adopted, thereby pro- viding improved comfort.

Sunroof glass assembly

4-14 BODY - Sunroof

Sunroof trim assembly

This sunroof has the following features. Adoption of a sunroof regulator which enables the

sunroof tilt to be adjusted to any desired angle (Tilting is possible to a maximum 50mm (2.0 in.) from the rear edge of the sunroof.)

Equipped with a removable sunroof trim for blocking strong sunlight

Equipped with a deflector for preventing wind drag when the sunroof glass is removed

Sunroof regulator assembly

18F0291

EXTERIOR CONTENTS

ACTIVE AERO SYSTEM ..............................................6 Construction Diagram ...............................................7 Construction and Operation ......................................8

5-1

SUMMARY OF EXTERIOR PARTS ............................. 2

BUMPERS .................................................................... 3

DOOR MIRRORS ......................................................... 4

AERO PARTS ............................................................... 5

SUMMARY OF EXTERIOR PARTS Large resin bumpers have been adopted on both the front and rear in all vehicles to emphasize the sporty look. Together with this, an air intake side air dam and a fixed type rear spoiler have also been equipped to provide improved aerodynamic characteristics.

In addition, an active aero system that operates at vehicle speeds of 80 km/h (50 mph) or more has also been provided.

Improvement in appearance

1. Air intake side air dam 2. Bumpers that emphasize width and lowness 3. Centre pillar garnish to emphasize a stronger sporty feel

Improvement in aerody- namic characteristics

Adoption of aero parts Side air dam Fixed type rear spoiler Active aero system

Improvement in convenience

Adoption of door mirrors with printed heating wires

5-2 EXTERIOR - Summary of Exterior Parts

BUMPERS Bumpers that seem to be an integral part of the body are installed. To improve safety, both front and rear bumpers

have built-in bumper absorbers to absorb shock. The side of the front bumper bends around to the

wheel cut and line up with the fender so that the flash surfaced body is realized.

TPO (Thermo Plastic Olefin elastomer) is used as the material for the bumper face and, by improving molding precision, it seems to be one unit with the body with no gaps between bumper and body.

Outlet 18F0017

EXTERIOR - Bumpers 5-3

The door mirrors are collapsible types with a sporty and aerodynamic design. The door mirror is installed a little away from the

front pillar (off-body type) which takes into consideration the slanted field of view to the front.

MECHANISM OF DOOR MIRROR WITH PRINTED HEATING WIRE There is a printed heating wire inside the mirror. When the rear window defogger switch is turned ON, it operates under the control of the ETACS for

Mirror

Body

All models are equipped with the electric remote control mirror. The electric remote control switch is installed on the left side of the instrument panel.

Door mirrors with printed heating wire are adopted on some models to clear frost and dew, etc. from the surface of the mirror.

approximately 11 minutes along with the rear window defoqqer. For details, refer to GROUP 7 - ETACS.

Printed heating wire

18F0079

5-4 EXTERIOR - Door Mirrors

DOOR MIRRORS

Frame

Actuator assembly

Fixed type rear spoiler

EXTERIOR - Aero Parts 5-5

18F0112 Side air dam

AERO PARTS The following aero parts are used to improve aerody- namic characteristics and marketability. . Fixed type rear spoiler to improve the aerodynamic

characteristics of the rear of the vehicle.

A side air dam is installed to improve the aerody- namic characteristics of the side of the vehicle.

Variable rear spoiler

Variable front venturi skirt

18F0235 18F0233

Deflector

5-6 EXTERIOR - Aero Parts

ACTIVE AERO SYSTEM In order to improve aerodynamic characteristics when driving at high speed, a variable front venturi skirt and a variable rear spoiler which automatically move to the operated positions at vehicle speeds of 80 km/h (50 mph) or more and automatically 'move back to the standard positions at 50 km/h (31 mph) or less are equipped. This active aero system has the following features. Front wheel lifting force has been reduced by

means of the front venturi skirt, and rear wheel

lifting force has been reduced by means of the rear spoiler.

A function is provided to set the aero parts to the standard positions when driving on poor road sur- faces, and to the operated position at times such as when washing the vehicle.

A deflector has been provided on the rear spoiler to prevent dirtying of the rear of the vehicle by sand, etc.

A high-mounted stop lamp has been equipped on the rear spoiler.

EXTERIOR - Aero Parts 5-7 CONSTRUCTION DIAGRAM

Motor Crank arm Linkage

Variable front venturi skirt

Motor Cable

Variable rear spoiler

18F0247

18F0248 Key reminder switch Active aero warning

lamp Vehicle speed sensor

Active aero control unit

18F0301

switch inside the motor turns OFF and the motor stops operating. This causes the linkage to move up and down in an elliptical path, moving the front venturi skirt approxi- mately 50 mm (2.0 in.) up and down.

Linkage

Approx. 50 mm (2.0 in.)

18F0245

VARIABLE REAR SPOILER Operation mechanism The motor in the centre stay of the spoiler turns the drive gear which operates the cable. When the slider is pulled by the cable due to this action, piil A of the slider moves to the rear of the oblong hole in the guide, so that the rear edge of the spoiler lifts pin B to the support point in accordance with the shape of the oblong hole, and the spoiler is tilted forward

18F0246

approximately 15. In addition, when the motor is reversed, the slider is pushed by the cable and the spoiler is lowered by the reverse operation to that of lifting. Then, when the operated position or standard position is reached, the limit switch inside the motor turns OFF and the motor stops operating.

5-8 EXTERIOR - Aero Parts

CONSTRUCTION AND OPERATION VARIABLE FRONT VENTURI SKIRT The motor is mounted on the front end crossmember, and the motor and the front venturi skirt are con- nected via a crank arm and a linkage. When the motor operates, the crank arm turns while pushing the linkage. Then, when the skirt is in the op- erated position or the standard position, the limit

Front venturi skirt

Crank arm

Motor

Slider Motor

Slider

Drive gear

Cable Cable Section A-A 18F0241

DEFLECTOR The deflector that is located on the rear spoiler pre- vents dust from being drawn up from underneath the vehicle and dirtying the rear of the vehicle by increas-

ing the air flow speed over the rear surface of the ve- hicle.

ACTIVE AERO WARNING LAMP Illuminates at the following times: (1) For 3 seconds when the ignition switch is turned from OFF to

ON. (2) When the following problems occur with the front venturi skirt.

When the front venturi skirt does not fully return to the standard position due to blocking by foreign particles or freezing, etc.

When front venturi skirt does not return to the normal standard position due to a defective limit switch.

Re-output function when there is a malfunction When the front venturi skirt and rear spoiler are not fully in the operated position or the standard position, the active aero control unit outputs a signal after 0.5 seconds, as shown in the illustration at left, to re-operate the motor. If the skirt and spoiler are still not in the fully operated position or standard position after this second output signal, output stops. However, when the front venturi skirt has returned to the standard position, the signal will be output a maximum of three times.

Manual operation of the variable front venturi skirt If the front venturi skirt has not fully returned to the standard position, carry out the following procedure. (1) Remove the cover at the right of the front venturi cover. (2) Remove the rubber cap at the back of the motor. (3) Turn the manual knob either to the left or the right to return

the skirt to the standard position.

18F0234 18F0228

Section A-A

EXTERIOR - Aero Parts 5-9

Deflector

Deflector

ACTIVE AERO SWITCH The active aero switch has three contact positions: AUT01, AUT02 and OFF. The front venturi skirt and rear spoiler move to the operated position and the standard position in accordance with the position of this switch and the vehicle speed. In addition, this switch has an operating indicator that indicates the operated position.

The operation of the active aero system is conditional on the ignition key being inserted into the ignition key

Active aero switch Operating conditions Remarks

When the vehicle speed is 80 km/h (50 mph) Driving stability at high speeds is improved. or higher, the front venturi skirt and rear spoiler move to the operated position, and at 60 km/h (31 mph) or less, they retrun to the standard position.

When the vehicle is stopped, if the active aero Use this when washing the front venturi skirt and switch is set to AUT02, the front venture skirt rear spoiler, or when checking their operation. and rear spoiler move to the operated position. If the switch is set to OFF or the ignition key is However, because the switch is a self-return removed, they will return to the standard type, it will move from the AUT02 position back position. to the AUT01 position. Because of this, the front venturi skirt and rear spoiler will return to the standard position at a vehicle speed of 2 km/h (1.2 mph) or more, and after that they will operate according to the AUT01 setting.

The front venturi skirt and rear spoiler are Use when there is a danger that the front always in the standard position. venturi skirt may become damaged, such as when driving on poor road surfaces.

NOTES (1) When driving at speeds of 2 km/h (1.2 mph) or above, the AUT02 setting on the active aero switch is not effective. (2) There may be cases where the active aero system does not operate due to strong winds or freezing. At such times, stop the vehicle, (unfreeze the frozen section), remove the ignition key and then re-insert it. This will make it possible to operate the system.

5-10 EXTERIOR - Aero Parts

cylinder. If the key is removed, the system returns to the standard position.

Because the operation of each limit switch is as shown in the tables below, the DOWN side and SLANT side are ON in the standard position and there is continuity. Because of this, the front venturi skirt drive circuit turns transistor Tr2 ON, thereby turning the contact of relay 1 ON. This causes current to flow from fusible link (11) to the relay 1 contact, motor and earth, operating the motor and moving the front venturi skirt to the operated position.

At this time, the limit switches are also turned by the motor, and when the operated position is reached, the DOWN side contact of the limit switches becomes OFF, relay 1 turns OFF and the motor stops. In the same way, the rear spoiler drive circuit turns transistor Tr3 and relay 2 ON, operating the motor and moving the rear spoiler to the operated position. When the operated position is reached, the SLANT side of the limit switch becomes OFF, and the motor stops.

Condition 1 Condition 2

Key reminder switch Active aero switch Vehicle speed sensor

Case 1 AUTO 1 80 km/h (50 mph) or OFF more

Case 2 (Ignition key is inserted into the ignition key cylinder) AUTO 2 Vehicle stopped

EXTERIOR - Aero Parts 5-11

Operation circuits Moving from standard position to operated position When the front venturi skirt and rear spoiler are in the standard position, each drive circuit outputs a vari

able signal in cases 1 and 2 for the following order of conditions 1 and 2.

switches>

5-12 EXTERIOR - Aero Parts

Active aero switch

Active aero control unit

To rheostat

Front venturi skirt

motor, and when the standard position is reached, the UP side contact of the limit switches becomes OFF, and the motor stops. In the same way, the rear spoiler drive circuit turns transistor Tr4 and relay 3 ON, operating the motor and moving the rear spoiler to the standard position. When the standard position is reached, the FLAT side of the limit switch becomes OFF, and the motor stops.

EXTERIOR - Aero Parts 5-13 Moving from operated position to standard position When the front venturi skirt and rear spoiler are in the operated position, each drive circuit outputs a standard

signal in any of the cases 1 - 4 for the following order of conditions 1, 2 and 3.

Because the operation of each limit switch is as shown in the tables below, the UPside and FLAT side are ON in the operated position and there is continuity. Because of this, the front venturi skirt drive circuit turns transistor Tr1 ON, thereby turning the contact of relay 1 ON. This causes current to flow from fusible link (11) to the relay 1 contact, motor and earth, operating the motor and moving the front venturi skirt to the standard position. At this time, the limit switches are also turned by the

18F0238

5-14 EXTERIOR - Aero Parts

INTERIOR CONTENTS

SUMMARY OF INTERIOR PARTS ..............................2

INSTRUMENT PANEL AND CONSOLE BOX ........................................................................ ......3

SHELF COVER ...................................................... ..... 3

SEATS .................................................................... ......4

Structure Diagram ............................................... ......4 Construction and Operation ............................. ... 5

Head Restraint (Horizontal Adjustment Mechanism) ................... ............. .................8

SEAT BELT .................................................................. 9 Construction and Operation of the

Energy-absorbing Belt and the Buckle ..................... 9 Electric Type Low Tension Seat Belt ...................... 10

SUPPLEMENTAL RESTRAINT SYSTEM (SRS) ........................................................... 13 SRS Schematic ...................................................... 14

Warning/Caution Labels . 15 Construction and Operation .. 17

6-1

Improved safety

SUMMARY OF INTERIOR PARTS In addition to being easier to use, the interior parts improve the feeling of fitness and solidity and

FEATURES

create a high-quality sports car atmosphere.

Improvement of quality feeling

Improvement of easy use

Convenient small storage compartments

6-2 INTERIOR - Summary of Interior Parts

Consideration of ideal driving position

1. Full trim interior 2. Round and one-unit instrument panel 3. Single formed headlining 4. Cubic-formed door trim

1. Large floor console 2. Split type rear seat 3. Automatic roll-up .type shelf cover

1. Ash tray (front part of console) 2. Cup holder (in console box) 3. Floor console box (in console box)

1. Instrument panel pad 2. Knee protector 3. 3-point seat belt with ELR 4. Supplemental restraint system (SRS)

1. 10-way power seat (driver's seat) 2. Electric type low tension seat belt (front)

Lid

INSTRUMENT PANEL AND CONSOLE BOX A round instrument panel is used, creating the feeling of being in a cockpit. The panel surface is covered with padding to improve safety.

Instrument panel

The console box is divided into two sections, front and rear. The rear console has a large lid and there is a cup holder inside the box.

Rear console assembly

Cup holder

Knee protector

Front console assembly

INTERIOR - Instrument Panel and Console Box/Shelf Cover 6-3

Glove compartment

19F0076

SHELF COVER An automatic roll-up type shelf cover is used for easy use. When used, the hooks catch on the liftgate trim. When the hooks are released, a spring automatically rolls the leather into the body. The shelf cover body can be removed easily to fold-down the rear seat forward for an additional space when loading a big cargo.

SEATS

A sports type of front seat that emphasizes the feeling of being supported has been provided, and also real leather seats have been provided as an option. The sports type of seat on the driver's side is a 10-way power seat. The lumber support, side support, dual height (front height and rear height), of the power seat can be adjusted continuously (stepless) for the ideal driving position. In addition, the reclining adjustment in the driver's seat comes with a memory. In addition

STRUCTURE DIAGRAM

Power seat switch A (lumbar and side support adjustments)

to the conventional reclining adjustment, there is a special function in this seat; when the seatback is forward-reclined and then set upright again, it fixes to the original seatback angle. The passenger's seat has a walk-in function so it is easy to get through the rear seat. A split type rear seat for left and right being separated is adopted in order to improve functional use.

19F0166 19F0031

Power seat switch B (slide, front and rear height adjustments)

Motor driven type Manual type

6-4 INTERIOR - Seats

Dual height adjustment

6. Slide adjustment (motor driven type for driver's seat)

7. Side support adjustment 8. Seatback forward-fold-down

1. Front/back (horizontal movement) and up/down adjust- ment of head restraint

2. Reclining adjustment (driver's seat with memory)

3. Lumbar support adjustment 4. Front height adjustment 5. Rear height adjustment

rod in the direction indicated by the arrow and the side support frame moves to the inside. This is a stepless, continuous stroke adjustment. In addition, if the switch is pushed to the opposite side, the operation is reversed.

INTERIOR - Seats 6-5 CONSTRUCTION AND OPERATION POWER SEAT Lumbar Support Structure If the switch on the front console is pushed to the front as shown in the figure, the lumbar support motor revolves, the screw nut and the arm move in the direction indicated by the arrows respectively. Then, the rod joined to the arm moves, pushing the lumbar

support plate to the front. This is a stepless, continuous stroke adjustment. In addition, if the switch is pushed to the rear, the operation is reversed.

Side Support Structure If the switch is pushed as shown in the figure, the side support motor revolves, the screw nut and the arm move in the direction indicated by the arrows respectively. The link connected to the arm moves the connecting

Seat switch A

Lumbar support motor

.Arm

Screw nut

Lumbar support motor '9F0052

Lumbar support plate Rod

19F0064

19F0146

Side support motor

Seat switch A

19F0145

19F0066

Connecting rod

Side support frame

19F0051

Lumbar support motor

Arm

Screw nut

Front Height and Rear Height Adjusting Structure The front and rear portions of the seat cushion can be raised and lowered independently. If the front height and rear height switch is pushed to the UP side, motor revolutions will be transferred to gear A to gear B to sector gear. Since the sector gear, shaft and arm are fixed, the seat cushion rises continuously (stepless) along with the revolution of the sector gear.

As the seat cushion continues to rise, the claw on the shaft turns the limit switch from ON to OFF, cutting off power to the motor and stopping it. In addition, if the front height and rear height switch is pushed to the DOWN side, operation is reversed with the motor revolving in the opposite direction and lowering the seat cushion.

6-6 INTERIOR - Seats

Slide Adjustment Structure The motor and support A are fixed to the upper rail, and the nut housing is attached to the lower rail. When the motor rotates, the worm gear drives the screw to shift the upper rail forward or backward. This controls the forward/backward seat sliding. When the seat cushion reaches the forward or backwards limit, the upper rail pushes the limit switch on the lower rail to turn it OFF, and the motor stops.

INTERIOR - Seats 6-7

RECLINING ADJUSTMENT MECHANISM WITH MEMORY If the seatback is raised after being inclined to the front, it can be returned to the original angle set in memory by previously setting the seatback angle in memory.

Furthermore, even after it is reclined at any angle, if the seatback is raised after being inclined to the front, it can be returned to the original angle set in memory. The construction and operation is the same as that for the '91 PAJERO.

HEADRESTRAINT (HORIZONTAL

ADJUSTMENT MECHANISM) There is a, link mechanism in the headrestraint that can adjust the headrestraint in four steps forward and

CONSTRUCTION The stay and right/left bracket are one unit. The bracket and side frame are connected by right/left link B and link A and by the shaft. The shaft is one unit with the sector gear and right/left link A. There is a pawl on the left side frame and it is made to engage the sector gear by the

OPERATION When the headrestraint is pushed forward, link A and B rotate with support points A and B acting as the centre so the entire headrestraint moves forward. Since the sector gear rotates to the rear relative to the shaft in the centre, the engagement of the sector gear and pawl moves forward one tooth at a time and the headrestraint is fixed in each position. At this time, the plate is pushed forward by pin A. When the headrestraint is pushed straight forward to the maximum forward position, the oval hole hits pin B in the sector gear and the plate cannot move for-

backward without changing the angle at which the head touches its surface.

lock spring. The plate mounted on the shaft is pressed to pin A in the pawl by the spring and pin B in the sector gear is inserted in the oval hole.

ward. In addition, when it is pushed to the maximum forward position, pin A crosses over C in the plate and is caught in the catch. Then, the engagement of the sector gear and pawl is released and the headrestraint is returned to the maximum backward position by the force of the return spring. Since the oval hole hits pin B and the plate cannot move backward at a position just before the maximum backward position, pin A crosses over C. Then the pawl engages the sector gear, and the headrestraint is fixed in the maximum backward position.

6-8 INTERIOR - Seats

19N0053 NOTE mark indicates centre of rotation of each part.

FRONT SEAT BELT 3-point belt with ELR (electric type low tension seat

belt) 3-point belt with ELR

Australia> Buckle built in seat

REAR SEAT BELT 3- point belt with ELR

GCC and Australia>

19F0219

19F0112

INTERIOR - Seat Belt 6-9 SEAT BELT The seat belt has the following mechanisms.

CONSTRUCTION AND OPERATION OF THE ENERGY-ABSORBING BELT AND THE BUCKLE The front seat belt has on it a sleeve inside which the seat belt webbing is folded back over itself in a loop so as to absorb the energy of a shock by pulling loose and releasing slack. There is a spring installed in the portion connecting the buckle to the arm, allowing the buckle to tilt forward and inward so that the belts can be tight enough around the body.

key is turned OFF, and the belt winding force does not return to its original condition immediately after the ignition key is turned OFF so the passenger does not feel any physical disorder.

ELECTRIC TYPE LOW TENSION SEAT BELT There is an electric type low tension mechanism in the front seat belt retractor to reduce belt tension and the feeling of pressure when the seat belt is buckled. Furthermore, the tension reducer is maintained in an ON condition by the ETACS for 30 seconds after the ignition

STRUCTURAL DESCRIPTION The retractor shaft and bush shaft are coupled. The reducing spring and normal spring are springs used to wind the webbing. The reducing spring ends are fixed to the bush shaft and the spring case, and the normal spring ends are fixed to the tape holder and cover, and stored in the cover. There is a solenoid in the cover and when the seat belt is buckled, the solenoid is activated, the lever engages the tape holder, locks the normal

6-10 INTERIOR - Seat Belt

spring, thus lessening the feeling of constriction. The purpose of the memory tape is to eliminate the difference in elongation ratio of the reducing spring and normal spring. The ends are fixed respectively to the tape holder and bushing shaft and stored together with the bushing shaft in the tape holder in a wound up condition.

19N0080

spring that are wound up, moves in the winding direction by the rotation of the bushing shaft and tape holder.

remains buckles. Furthermore, since the tape holder is locked, the memory tape is loosened by the rotation of the bushing shaft in accordance with the winding of the reducing spring. The amount of loosening of the memory tape is the difference in the elongation ratio of the normal spring and reducing spring, and this serves to make the elongation ratio of the 2 springs the same when the seat belt is stored.

INTERIOR - Seat Belt 6-11

OPERATIONAL DESCRIPTION Seat Belt Stored Condition-7When Pulling Out Since the memory tape is wound up, the bushing shaft and tape holder turn as one unit. The torque of the two springs, the reducing spring and normal

Buckle Switch ON When Seat Belt is Initially Wound Up When the webbing is pulled out and the tongue set in the buckle with the ignition switch in the ON position, the switch inside the buckle is turned ON, the solenoid functions and the lever meshes with the outer teeth of the tape holder. As a result, the tape holder is locked in the winding direction, torque of the normal spring falls to zero and the winding torque becomes only the torque of the reducing spring. Consequently, the feeling of oppression is reduced when the seat belt is initially buckled up and when it

-

memory tape and, while the memory tape is loose, torque is not transferred to the bushing shaft. When the memory tape is wound completely tight, the elongation ratio of the normal spring and reducing spring is the same and the webbing is wound up by the torque of the 2 springs. In this way, the condition of the 2 springs is uniform when stored.

19N0079

6-12 INTERIOR - Seat Belt

Buckle Switch ON When Seat Belt is Initially Wound Up When the tongue is released from the buckle with the ignition switch ON, the switch inside the buckle is turned OFF, current to the solenoid is cut off and the meshing of the lever and tape holder is released. As a result, the reducing spring begins winding. On the other hand, the normal spring turns the tape holder in the direction of winding and winds tight the

Front impact sensor (R.H.)

SUPPLEMENTAL RESTRAINT SYSTEM (SRS) The SRS is designed for use as a supplemental system for the seat belt, proving effective only when the seat belt is worn. The SRS is provided for the driver's seat only. The SRS consists of right and left front impact sensors, air bag module, SRS diagnosis unit (with built-in safing impact sensor), clock spring, SRS warning lamp knee protector, etc.

Operates only when a front end collision applies an impact greater than a preset value to the whole vehicle, protecting the upper half of the driver's body.

INTERIOR - Supplemental Restraint System (SRS) 6-13

Front impact sensor (L.H.)

Has a double detection circuit to allow the air bag to deploy only when either of the right and left front impact sensors and safing impact sensor simultaneously enter the ON state, eliminating the possibility of accidental deployment.

Has an SRS diagnosis unit in which the backup function (charge capacitor for the power supply) against a power failure that may occur when the bag is to deploy (at the time of an impact) and the voltage boosting function (D.C. - D.C. converter circuit) against a low voltage battery are accommodated.

Has a self-diagnostic function for higher safety and reliability.

SRS diagnosis unit (with built-in safing impact sensor)

19F0115

6-14 INTERIOR - Supplemental Restraint System (SRS)

SRS SCHEMATIC

The language written in the label is principally English, but some of the labels are written in German or French.

INTERIOR - Supplemental Restraint System (SRS) 6-15 WARNING/CAUTION LABELS A number of caution labels relating to the SRS can be found in the vehicle, as shown in the following illustration. Follow label instructions when servicing SRS.

E. CAUTION: SRS diagnosis unit This unit cannot be repaired. If defective, remove and replace entire unit per service manual instructions. Do not disassemble or tamper. See service manual for handling and storage instructions. Do no drop: keep dry. Failure to follow instructions could render air bag in- operative and result in driver injury.

J. CAUTION: SRS Before removal of steering gearbox, read service manual, centre front, wheels and remove ignition key. Failure to do so may damage SRS clock spring and render SRS system inoperative, risking seri- ous driver injury.

C. This vehicle has a driver's side air bag to supple- ment the driver's seatbelt in certain frontal colli- sions. The driver and all other occupants must wear seatbelts at all times to reduce possible injury.

B. CAUTION: SRS Read service manual. Do not drop. Do not tamper or disassemble.

A. WARNING This vehicle has a supplemental driver's side air bag. Refer to service manual before servicing or dis- assembling underhood components. Read "SRS" section of manual for important instructions. Improper service procedures can result in the air bag firing or becoming inoperative, leading to injury.

D. Driver's air bag information This vehicle has an air bag which will supplement the driver's seatbelt in certain frontal collisions. The air bag is not a substitute for the driver's seatbelt in any type of collision. The driver, and all other occupants, should wear seatbelts at all times. WARNING! If the" SRS" warning light does not come on for about 7 seconds when ignition key is turned to "ON" or engine is started, or if it stays on while driving, drive the vehicle to your nearest authorized dealer right away. Also do so if vehicle's front end is damaged or if air bag has deployed. The air bag system must be inspected by an authorized dealer ten years after the date of vehicle registration. Read "SRS" section of your owner's manual before driving, for important information, about operation and service of the air bag system. When you are going to scrap your gas generator or vehicle, please see your MITSUBISHI dealer.

6-16 INTERIOR - Supplemental Restraint System (SRS)

F. CAUTION: SRS Before replacing steering wheel, read service manual, centre front wheels and align SRS clock spring neutral marks. Failure to do so may render SRS system inop- erative, risking serious driver injury.

G. CAUTION: SRS clock spring This is not a repairable part. Do not disassemble or tamper. If defective, remove and replace entire unit per service manual instructions. Before replacement, read service manual, .centre front wheels and align neutral marks. Failure to follow instructions may render SRS system inoperative, risking serious driver injury.

H. Danger! Poison. Keep out of the reach of children. Contains sodium azide and potassium nitrate contents are poisonous and extremely flammable. Contact with acid, water, or heavy metals may produce harmful and irritating gases or explosive compounds. Do not dismantle, incinerate, bring into contact with electricity or store at temperatures exceeding (93C) 200F. First aid: If contents are swallowed induce vomiting. For eye contact flush eye with water for 15 minutes. If gases from acid or water contact are inhaled, seek fresh air. In every case, get prompt medical attention. For additional information; see material safety data sheet (MSDS) for this product.

I. CAUTION: SRS clock spring This is not a repairable part. Do not disassemble or tamper. If defective, remove and replace entire unit per service manual instructions. Before replacement, read service manual, center front wheels and align neutral marks. Failure to follow instructions may render SRS system inoperative, risking serious driver Injury.

a metallic case, etc. If an impact greater than preset is applied in the direction of the arrow shown in the illustration, the inertial force causes the roller to rotate and move, so that contacts are brought into the ON state. To maintain a high measure of G sensor reliability, the contacts have been gold plated and the metallic case charged with an inactive gas. Each impact sensor contains a resistor connected in parallel with the contacts for detection of a fault in the wiring. The SRS diagnosis unit always supplies a very small amount of current to the sensor circuit to monitor a change in the circuit resistance. Caution Make sure that the impact sensors are never disassembled.

INTERIOR - Supplemental Restraint System (SRS) 6-17 CONSTRUCTION AND OPERATION IMPACT SENSORS There are 2 different types of sensors used; 2 front impact sensors and safing impact sensor. One front impact sensor is provided in each of the right and left lower side members, and one safing impact sensor is built in the SRS diagnosis unit. The right and left front impact sensors are connected in parallel. The front impact sensors are connected in series with the safing impact sensor. If a front-end collision causes either of the front impact sensors and the safing impact sensor to be simultaneously "ON", the air bag will deploy. The front and safing impact sensors are essentially identical in construction. They are constructed as shown below and contain a G sensor each. The G sensor consists of a moving contact which is a roll spring wound around a roller, a fixed contact positioned in its moving direction, consisting of a base,

Front impact sensor (R.H.)

13R0724

Front impact sensor (L..H.)

Air bag module (Squib)

Safing impact sensor (Incorporated in SRS diagnosis unit)

From power supply

G sensor Bracket G sensor

Connector

13R0662

Connector 19N0234

Metallic case

Inactive gas

13R0664

Impact 13R0659 Fixed contact

6-18 INTERIOR - Supplemental Restraint System (SRS)

Sealant

Case

Fixed contact Moving contact

Roller

Front impact sensor Safing impact sensor

G sensor

Bracket

Wire

Base

Roller Moving contact

Roll spring

13R0658

Impact

Section A - A

AIR BAG MODULE The air bag module is an assembly part comprising of an air bag, pad cover, inflator, and parts for securing them. It is provided at the centre of the steering wheel. Caution Make sure that the air bag is never disassembled.

Hinge portion of pad cover

Crease

Hinge portion of pad cover

Air bag

Inflator

13R0694

INTERIOR - Supplemental Restraint System (SRS) 6-19

Groove portion

Inflator

Pad cover

Section B - B

Groove portion

Air bag 13R0695

: Pad cover deploying direction

Air bag The air bag is made of a nylon cloth with a rubber coating inside. It is accommodated in the pad at the centre of the steering wheel together with the inflator. The air bag is inflated by the nitrogen gas from the inflator. The load of the driver pressed against the air

Pad cover The pad cover is made from urethane. When the air bag deploys, the crease is broken, allowing the air bag to move out and deploy with the hinge portions as its fulcrums. The pad cover has a net, etc. insert-molded

bag by the impact causes the nitrogen gas to escape through the two exhaust holes made on the rear, and the deflation helps lessen the impact.

except for the crease to prevent the air bag from being broken as it deploys, and also to prevent broken pieces from scattering around.

gas which is forced through the diffuser screen into the air bag. The diffuser screen serves as a filter to remove cinders and also helps cool down the gas temperature and reduce the gas generation noise. A shorting pin is provided in the connector portion of the squib. Whenever the air bag module is removed, the shorting pin makes a short circuit across the terminals to prevent flow of current caused by static electricity to the squib.

NOTE The cross sectional view of the inflator was plotted on the basis of a sketch prepared by Moton Thiokol

Diffuser Igniter

To air bag

. Connector lock

Automotive Products Division.

Gas generant

Base

Shorting clip 19N0233

6-20 INTERIOR - Supplemental Restraint System (SRS)

Inflator The inflator consists of a squib, igniter, gas generants, diffuser screen, etc. contained in an aluminum container. It is mounted in the air bag module housing. The bottom of the inflator is provided with an electrical connection to which an ignition current is supplied. If current is supplied to the squib, a small amount of explosive in the squib is burnt causing the igniter to burn, and the resultant heat burns the gas generants. Combustion of the generants rapidly produces nitrogen

Air bag deployment operation (in case of 50 km/h (30 mph) frontal impact) (1) OPERATION FOR APPROXIMATELY 15 MILLISECONDS

AFTER THE COLLISION If a strong impact produced by a collision is detected by either of the front impact sensors and the safing impact sensor in approximately 10 milliseconds after the collision, the SRS diagnosis unit will supply an ignition signal to the squib. In approximately 3 milliseconds after the ignition signal has been supplied to the squib, gas generation will begin.

: Nitrogen gas : Flame

Squib

To air bag

Diffuser screen

(2) In approximately 20 milliseconds after the collision, the air bag folded in the pad cover will begin to inflate, the pad cover will break at its crease, and the air bag will expand outward.

(3) In approximately 35 milliseconds after the collision, the inflated air bag will touch the chest of the driver.

(4) In approximately 40 milliseconds after the collision, the air bag will be fully inflated.

(5) In approximately 55 milliseconds after the collision, the pressure of the driver against the air bag causes the gas to escape through the two exhaust holes on the rear of the module, and the deflation helps lessen the impact imposed on the driver.

(6) In approximately 105 milliseconds after the collision, the air bag that has absorbed the impact will rapidly deflate, providing visibility for the driver.

INTERIOR - Supplemental Restraint System (SRS) 6-21

ignition switch is ON to supply the squib ignition ,current, even if the power cable from the battery is broken by the collision, to inflate the air bag as soon as the front impact sensor and safing impact sensor are simultaneously switched ON. Caution Make sure that the SRS diagnosis unit is never disassembled.

Component Main Monitoring Point Diagnosis

Code No.

Short-circuit 11 Front impact sensor Open-circuit once 12

Open-circuit twice 13 Short-circuit 21

Squib Open-circuit 22 Terminal voltage high 31

Condenser Terminal voltage low 32

Cranking detection circuit Cranking signal detection time 33*1

6-22 INTERIOR - Supplemental Restraint System (SRS)

SRS DIAGNOSIS UNIT The SRS diagnosis unit monitors the impact sensors, squib, wiring harness, condensers, battery voltage etc. It detects a problem, it and illuminates the "SRS" warning lamp to alert the driver. It also stores in memory what the problem is, and the duration of the problem (the duration during which the warning lamp kept ON). The condeilsers provided in the diagnosis unit accumulates electric energy during the period the

1. Monitoring function The SRS diagnosis unit monitors the items of the wirin~ harness and SRS components shown in the following table to check whether they satisfy the specified values. When the ignition key is in "ON" or "START" position, the SRS warning lamp should illuminate for about 7 seconds and then tun off. This indicates that the SRS system is in operational order. I' the SRS warning lamp does any of the following, immediate inspection is needed. (1) The SRS warning lamp does not illuminate as described above. (2) The SRS warning lamp stays on for more than 7 seconds. (3) The SRS warning lamp illuminates while driving. The data of the fault is stored in terms of a diagnosis code ir the non-volatile memory (EEPROM) *. The duration of thE fault is also stored in terms of the ON duration of the warning light.

NOTE * EEPROM = Electrically Erasable Programmable ROM

A ROM to which data can be stored and be electrically written and from which data can be electrically erased. *1: Equipped with the automatic diagnosis code erasure function. (Refer to P.6-25)

Component Main Monitoring Point Diagnosis

Code No.

Double lock connector Unlock or lock switch open-circuited 34*1

IG1 voltage low (Multi-purpose fuse No. 11 is 41*1 blown)

Battery IG 1 voltage low (Multi-purpose fuse No. 18 is 42*1 blown)

External circuit open-circuited or short-circuited 43*1 SRS warning lamp

Drive circuit defective 44

EEPROM defective Diagnosis unit 45

A/C converter defective

INTERIOR - Supplemental Restraint System (SRS) 6-23

2. Do not measure the resistance across the terminals of the SRS diagnosis unit. Do not directly touch the test probe to any of the terminals. Even if an attempt is made to measure the resistance, no correct value can be obtained because of the effects of internal circuits. In addition, there is a danger of damage to the gold plated portion of the

terminals.

6-24 INTERIOR - Supplemental Restraint System (SRS)

2. Supplying squib ignition energy

The energy for ignition of the squib is supplied by two circuits; the battery of the vehicle and the condensers. Even if the power voltage of the SRS diagnosis unit is lost, the ignition capability is retained by the condensers for more than 0.5 seconds.

(1) The two independent battery power supplies (from fuses 11 and 18) are connected via diodes in the diagnosis unit. If the voltage is larger than 9V between the connector terminal of the unit and the ground, the squib can be ignited.

(2) The IG 1 voltage is boosted to about 25V by the DC-DC converter to provide more in reserve than the low limit voltage mentioned above in charging the condensers that supply the ignition energy.

Caution 1. When the SRS is to be repaired or parts to be replaced,

make sure that the negative (-) cable of the battery is disconnected beforehand for insulation. After the negative (-) cable of the battery has been disconnected, wait for more than 60 seconds before making any service attempt. The condensers in the SRS diagnosis unit retains for a given period the voltage necessary for inflating the air bag even after removal of the battery voltage. If a service attempt is made during the period, accidental inflation could cause serious personal injury.

3. Diagnosis function

Fault diagnosis continues to be performed during the period the ignition switch is ON except during cranking. If a fault is detected, the SRS warning lamp is lit. The microcomputer determines a diagnosis code on the basis of the results of measurements by various measuring circuits and stores it in "EEPROM". The fault duration (the period the warning lamp has been ON) is integrated in increments of a minute and stored in the EEPROM together with the diagnosis code. The stored data can be read and erased by a Multi-use tester. The number of times the memory has been erased by a Multi-use tester is stored in the "EEPROM" to provide reference information on the past service history. The data can be read by a Multi-use tester in the same way as the fault durations.

NOTE Once a fault is detected, the SRS warning lamp con- tinues to lamp, even if normal operation of the system is restored, until the diagnosis code is erased.

INTERIOR - Supplemental Restraint System (SRS) 6-25

4. Automatic diagnosis code erasure function The Automatic diagnosis code erasure function operates according to the indicated diagnosis code No. (Refer to P.6-23). Once the malfunction location that causes a diagnosis code to be displayed returns to the normal condition, if the malfunction reoccurs continuously at 5-second intervals, the appropriate malfunction code can be erased. At this time, if all other diagnosis codes have been erased, the SRS warning lamp will switch off and the intermittent durations of the malfunction will also be erased automatically. In this case, the erasure is not included in the number of times erased. NOTE If the AID converter inside the SRS diagnosis unit is malfunctioning, diagnosis codes No. 41, 42 and 43 will not be erased by the automatic diagnosis code erasure function. Furthermore, during cranking, none of the codes will be erased by this function.

6-26 INTERIOR - Supplemental Restraint System (SRS)

SRS CONNECTOR The connector of the SRS diagnosis unit has a double lock mechanism, fit verification mechanism and connector shorting mechanism. DOUBLE LOCK MECHANISM The mechanism is composed of two mechanisms: each connector of the SRS diagnosis unit is locked to the connector of the harness, then these connectors (of the four harnesses) are locked with the secondary lock lever mounted on the connector of the SRS diagnosis unit side. The secondary lock lever locking is done as the lock spring fits in the notch of the connector. The operating principle is described below.

When Connectors Are To Be Fitted (1) The SRS diagnosis unit and harness side connectors are

fitted. (Primary lock) (2) The secondary lock lever mounted to the SRS diagnosis unit

side connector is pressed down by finger until a click is heard indicating that the connectors have been locked. (Secondary lock) If the harness and SRS diagnosis unit connectors do not properly fit, the secondary lock lever side projection and the harness side connector projection interfere with each other, making it impossible to lock the connectors.

When Connectors Are Unlocked (1) Press in the lock spring with a flat tip (-) screwdriver to

disengage the lock spring from the notch area of the connector, and release the lock (secondary lock) of the secondary lock lever. Caution Forced removal of the connector without releasing the secondary lock lever will result in a damaged lock lever.

(2) Press the primary lock of each of the harness side connectors and remove the harness side connector.

INTERIOR - Supplemental Restraint System (SRS) 6-27

FIT VERIFICATION MECHANISM The mechanism is used to electrically check the engagement of the connector between the SRS diagnosis unit and the body wiring harness. The operating principle is described below. (1) Securely connect the SRS diagnosis unit and harness side

connectors and press the secondary lock lever down to lock the connectors.

(2) At this time, the short bar provided on the rear surface of the secondary lock lever produces a short circuit across terminals No. 7 and 8 of the SRS diagnosis unit. The SRS diagnosis unit supplies monitoring current to the circuit to electrically verify that the connectors have been locked.

CONNECTOR SHORTING MECHANISM The mechanism is designed for prevention of accidental explosion of the inflator when the clock spring connector (for the squib circuit) is removed from the SRS diagnosis unit. The operating principle is described below. When Connectors Are Fitted When the SRS diagnosis unit and clock spring connector are coupled, the circuit between the short terminals and clock spring connector terminals are kept in the OFF state by the partition plate provided in the connector of the SRS diagnosis unit. When Connectors Are Disconnected When the clock spring connectors are disconnected from the SRS diagnosis unit, the partition plate between the short terminals and clock spring connector terminals is removed. As a result, a short circuit is formed between the two poles of the clock spring connector terminals to prevent generation of a potential difference (current) between the squib terminals.

6-28 INTERIOR - Supplemental Restraint System (SRS)

CLOCK SPRING The clock spring is provided between the steering wheel (air bag module) and column switch body (steering column). The clock spring provides harness connections, not contact connections like horn contact as in the past, between the air bag module and SRS diagnosis unit, between the horn switch and body wiring harness, and between the remote control switch and body wiring harness. The clock spring consists of a neutral position indication mechanism, flat cable, upper case, lower case, rotor, etc. The flat cable loosely wound like a coil is held in the upper and lower cases with one of its ends mounted to

the rotor and the other end mounted to the upper case. The upper and lower cases are mounted to the steering column. The rotor is coupled with the steering shaft. Rotation of the steering wheel (steering shaft) causes the rotor to rotate. Accordingly, the flat cable is wound round the rotor or loosened, and operates with the rotor as the steering wheel is turned.

Caution Make sure that the clock spring is never disassembled. Caution The clock spring must never be disassembled.

Steering wheel

Steering shaft

SRS diagnosis unit

To body wiring harness

Air bag module

To cruise control switch

Clock spring

To horn

To remote control switch

To air bag module

19F0149

Cover

Neutral position indication mechanism

The system comprises of a ring gear (number of teeth: 90) provided in the upper case, a transparent cover mounted on the rotor with screws, and a gear (number of teeth: 80) which is in mesh with the ring gear and is driven by the convex portion of the cover. The upper case is mounted on the steering column and is always held in position. The rotor is coupled with the steering shaft and always operates with the steering wheel. The gear is always kept in mesh with the ring gear by the convex portion of the cover. If the rotor turns through a rotation, the convex portion of the cover also turns through a rotation. So the gear is displaced in the opposite direction to the

rotating direction of the rotor by the difference in the number of teeth between the gear and ring gear or by 10 teeth. Markings R2, 1, NEUTRAL, 1, and 2L are made on the gear for every 10 teeth. An alignment mark is made on the upper case. The clock spring is placed in the neutral (straight ahead) position by lining up the alignment mark with the mark NEUTRAL of the gear. The mark "R" on the gear indicates that the rotor has been turned clockwise, whereas the mark "L" indicates counter- clockwise rotation of the rotor.

Convex portion to drive gear

Upper case

Alignment mark

A quarter of a rotation

INTERIOR - Supplemental Restraint System (SRS) 6-29

Rotor

Gear

Ring gear

Half a rotation

13R0698

Alignment mark

Gear drive portion Gear A rotation Three quarters of a rotation

13F0026

How the gear operates when the rotor is turned one rotation clockwise

6-30 INTERIOR - Supplemental Restraint System (SRS)

SRS WARNING LAMP The SRS warning lamp is provided at the lower right corner of the combination meter. When the SRS is in good order, the lamp should illuminate for approximately 7 seconds after the ignition key has been turned ON, or the engine has been started, and will then go out. The SRS warning lamp has only one display area but contains two lamps. Even if one of the lamps is defective, the other one can be lit. The SRS warning lamp is checked by the SRS diagnosis unit for a defective lamp.

7-1

EQUIPMENT CONTENTS

GENERAL INFORMATION ON EQUIPMENT ................................................................. 2 Features ................................................................... 2

WIRING HARNESS ...................................................... 3 Construction Diagram ............................................... 3

DIAGNOSIS SYSTEM .................................................. 4 Diagnosis Connectors ............................................... 4

BATTERY ...................................................................... 5 Specifications ............................................................ 5

LIGHTING ..................................................................... 5 General Information .................................................. 5 Specifications ............................................................ 5 Structural Diagram .................................................... 6 Headlamp .................................................................. 6 Headlamp Leveling system ..................................... 13 Engine Compartment Inspection Lamp .................. 13

METERS AND GAUGES ............................................ 14 Combination Meter .................................................. 14 Combination Gauge ................................................ 14 Vehicle Speed Sensor ............................................. 15 Electric Type Speedometer ..................................... 16

WIPERS AND WASHERS .......................................... 18 Structural Diagram .................................................. 18

RADIO AND TAPE PLAYER ...................................... 19 Structural Diagram .................................................. 19

ACCESSORY SOCKET ............................................. 20

ETACS (ELECTRONIC TIME AND ALARM CONTROL SYSTEM) ................................................. 21 Summary of Functions ........................................... 21 Operation .................................................................23

Central Door Locking Preventing Doors From Being Locked When Ignition Key Is

Left Behind .............. ...............................................23 Defogger Timer ....... ' .............................................24 Seatbelt Tension Reducer Timer ............................25 Dimmer Type Lamp .................................................26 Seatbelt Warning Lamp ...........................................27

Intermittent Wiper, Mist Wiper and Washer Linked Wiper .......................................28 Input Check Facility of ETACS ................................29 Parts and Functions Related with ETACS ..............30 Theft Alarm System ................................................31

HEATERS AND AIR CONDITIONING ........................33 General Information .................................................33 Components ............................................................34 Small Amount Refrigerant System ..........................36

) Heater Unit ............................................................. 37 Air Conditioner Control Panel ................................. 37 Compressor Control ............................................... 38 Control .................................................................... 40 Refrigerant Line ...................................................... 41 Self-diagnosis and Back-up Function ..................... 41

GENERAL INFORMATION New equipment and new functions have been added to make the equipment better.

FEATURES

Improved visibility and safety

Improved usability and convenience

7-2 EQUIPMENT - General Information

Improved reliability

Improved serviceability

Improved marketability

1. Gold plating of electronic control system terminals. 2. MWP (Multipole Water Proof type) connector. 3. Adoption of small amount refrigerant air conditioner system.

1. Large combination meter. 2. High-mounted stop lamp. 3. Double action ignition switch.

1. Adoption of engine compartment inspection lamp. 2. Adoption of combination gauge (3-set gauge) for a sporty feeling.

1. Diagnosis connector. 2. Ignition timing adjustment terminal. 3. Fuel pump operation check terminal. 4. Engine rpm detection terminal. 5. Adoption of one-touch plug-in method for easy installation and removal of combination

meter. 6. Centralization of control harnesses and sensor connections. 7. Adoption of indicator lamp to show LOW position of front washer fluid. 8. Adoption of level gauge for easy inspection of amount of fluid in rear washer tank.

1. Adoption of electric type speedometer for smooth, shake-free pointer movement in response to speed changes.

2. Adoption of accessory socket. 3. Adoption of theft-alarm system

Front wiring harness

WIRING HARNESS The wiring harness is divided into the main wiring harnesses [front wiring harness, body wiring harness (LH, RH), control wiring harness, instrument panel wiring harness] and sub wiring harnesses (door wiring harness, tailgate wiring harness, roof wiring harness) and has the following characteristics. A junction block, which is one unit consisting of

intermediate connectors for the harnesses, fuse boxes and relay boxes, is used to improve reliability.

STRUCTURAL DIAGRAM

CAVS (Compressed Conductor Automobile Vinyl Semi-rigid Wire) is used for the electrical wiring harness to make it lighter.

There is central connector (diagnosis connector) for diagnosis inspection of each electronic control system for improved serviceability.

Connector terminals in the control units and sensors where weak electric current from the electronic control systems flows are gold-plated to assure flow of current.

NOTE (1) This figure shows the main wiring harnesses only. (2) * mark indicates it is equipped on the right side also.

Instrument wiring harness

Control wiring harness

EQUIPMENT - Wiring Harness 7-3

Body wiring harness (RH)

Roof wiring harness

Tailgate wiring harness

Door wiring harness*

Body wiring harness (LH) 36F0019

NOTE *: Saved in memory as long as the data is not electrically canceled.

7-4 EQUIPMENT - Diagnosis System

DIAGNOSIS SYSTEM Diagnosis system is designed to improve serviceability and has the following functions

DIAGNOSIS CONNECTOR The diagnosis connector for the following systems is located on the right side of the junction block.

1. MPI 2. 3. ECS 4. ABS 5. Cruise control 6. 7. Full auto A/C 8. SRS (Air Bag) 9. ET ACS (Theft Alarm)

10. Diagnosis control 11. Vehicle simulated speed 12. Earth

SPECIFICATIONS

SPECIFICATIONS

There is also a convenient engine compartment in- spection lamp for inspecting at night and for service to improve serviceability.

ELECTRICAL - Battery / Lighting 7-5 BATTERY The battery of the following specifications has been established.

Items STANDARD OPTIONAL

Type 55D23R-MF 75D26R-MF

Capacity (5H R) Ah 50 52 Reserve capacity min. 99 123

Cold cranking current A 300 490

LIGHTING GENERAL INFORMATION Parallel link type pop-up headlamp that go up and down vertically are used. Air resistance when driving is reduced by the aerodynamic shape.

Items Specifications

Exterior lamps

Headlamps W 65/45 Fog lamps or driving lamp W 35 Clearance lamp W 5 Front combination lamp J

Turn-signal lamp/position lamp W 21/5 Side turn signal lamp W 5 Rear combination lamp

Turn-signal lamp W 21 Stop lamp/tail lamp W 21/5 Rear fog lamp W 21

Back-up lamp W 21 Licence plate lamp W 5 High-mounted stop lamp W

Vehicles for Europe W 5 x 3 Vehicles for General Export W 5 x 3 or LED (Light Emitting Diode) Vehicles for Australia W LED (Light Emitting Diode)

Engine compartment inspection lamp W 3.8

Interior lamps

Foot lamps W 3.4 Room lamp W 8 Door courtesy lamp W 5 Glove box lamp W 3.4

STRUCTURAL DIAGRAM

Engine compartment inspection lamp

Headlamp

Driving lamp

Front combination lamp Headlamp

Side turn-signal lamp

Door lamp 16F0421

Engine compartment inspection lamp

Fog lamp

Clearance lamp

Front combination lamp Door lamp 16F0419

Engine compartment inspection lamp

Driving lamp Optical

Front horn lens combination lamp

Headlamp

Door lamp 16F0420

Room lamp Spot lamp Glove compartment

lamp

High-mounted stop lamp\

Luggage compartment lamp

16F0422

License plate lamp

Back-up lamp

Rear combination lamp

Foot lamp

HEADLAMP The headlamps go up and down when the lighting switch or pop-up switch is operated. The operating mechanism for the head lamps is such that the right and left head lamps operate independently so that if

there should be trouble in one side, the other side can still operate. Furthermore, when there is trouble in the electric system, there is a manual knob so the headlamps can be moved up and down manually.

Room lamp Spot lamp

Manual knob Link assembly

Headlamp Rod

I

Pop-up motor

Boot

7-6 ELECTRICAL - Lighting

Room lamp Spot lamp

ELECTRICAL - Lighting 7-7

EXPLANATION OF STRUCTURE Pop-up Headlamp The pop-up head lamp consists of the pop-up motor, link assembly, rod connecting the pop-up motor and link assembly, and head lamp to raise and lower the headlamp. When the pop-up switch or lighting switch is turned ON, the popup motor rotates, the rod connected to the pop-up motor moves the link assembly to raise the headlamp. The link assembly uses a parallel link system so each link operates through the three fixing points on the right and left to raise and lower the headlamp vertically.

Manual Knob When the headlamp pop-up mechanism does not function due to trouble in the electric system, this manual knob can be used to turn the pop-up motor to raise and lower the head lamp manually. The manual knob is operated by removing the boot and turning the manual knob clockwise.

7- 8 ELECTRICAL - Lighting

Driving Lamp The driving lamps come on when the head lamps are flashed for passing or when the headlamp switch is turned to the high beam.

OPTICAL HORN LENS (FOR PASSING LAMP IN VEHICLES FOR AUSTRALIA) Since the head lamp faces the front even when retracted, the head lamp, if used when passing, lamps up and shines in retracted condition through the optical horn lens (place for the lens so lamp can pass through).

OPERATION Headlamp and Driving Lamp Operating Conditions

NOTE "0" indicates the resultant headlamp operation or position. When the lighting switch is ON, it is in the" HEAD" position.

NOTE o indicates the head lamp operation or position resulting from switch operation. Lighting switch ON means that the head- lamps are in the illumination position.

ELECTRICAL - Lighting 7-9

Raising Headlamp When the Pop-up Switch is Turned From OFF to ON and the Lighting Switch is OFF or at TAIL When the pop-up switch is turned ON, the judgment circuit in the ETACS control unit senses the ON signal and activates the UP timer circuit. Then, since transistor Tr1 is turned ON, transistor Tr2 is also ON, current from transistor Tr2 flows through the U-contact in the pop-up motor U/D (UP/DOWN) switch and from the pop-up motor relay (coil side) to earth, the pop-up motor relay

(contact side) goes ON, current flows in the pop-up motor and the headlamp starts to go up. When the crank arm rotates approximately 1800 and reaches the UP position where it stops automatically, current to the pop-up motor is cut off since the con- necting U/D switch contact changes from the U-contact to the D-contact, the pop-up motor stops and the head lamp remains in the up position.

indicates a model with the theft-alarm system installed. indicates models without a theft-alarm system.

NOTES (1) The dotted line (2) The two-dotted line

16F0109

7 -10 ELECTRICAL - Lighting

When the Pop-up Switch is OFF and the Lighting Switch is Turned OFF or From TAIL to HEAD When the lighting switch is turned to HEAD (on mod- els without the theft-alarm system, lighting switch is turned to HEAD after the ignition switch is turned to ACC), current flows from the headlamp relay (coil side) to earth via the column switch (lighting switch),

the head lamp relay (contact side) goes ON, current flows in the headlamp, the judgment circuit in the ETACS control unit senses the ON signal at the same time as the headlamp lights up, and just as in the item mentioned on the previous page, the pop-up motor relay goes ON and the head lamp goes up.

ELECTRICAL - Lighting 7 -11

NOTES (1) The dotted line (2) The two-dotted line

16F0110

indicates a model with the theft-alarm system installed. indicates models without a theft-alarm system.

Lowering Headlamp When the Pop-up Switch is Turned From ON to OFF and the Lighting Switch is OFF or at TAIL When the pop-up switch is turned OFF, the judgment circuit in the ETACS control unit senses the OFF signal and the DOWN timer circuit functions. Then, transistor Tr4 also is ON since transistor Tr3 is turned ON, current from transistor Tr4 passes through D-contact in the U/D (UP/DOWN) switch and flows from the pop-up motor relay (coil side) to earth, the pop-up motor relay (contact side) goes ON, current flows to the pop-up motor and the headlamp starts to go down. Since the connecting U/D (UP/DOWN) switch contact changes from the D- contact to the U-contact when the pop-up motor rotates approximately 1800 and reaches the position for auto-

matically stopping the down movement, current to the pop-up motor is cut off, the pop-up motor stops and the headlamp stays in the down position. When the Pop-up Switch is OFF and the Lighting Switch is Turned from HEAD to TAIL or OFF When the lighting switch is turned to TAIL or OFF, current to the headlamp relay (coil side) is cut off, the headlamp relay (contact side) goes OFF and the judg- ment circuit in the ETACS control unit senses the OFF signal at the same time as the headlamp is extinguished and, just as in the item mentioned above, the pop-up motor relay goes ON and the head lamp goes down.

7 -12 ELECTRICAL - Lighting

16F0111

NOTES (1) The dotted line (2) The two-dotted line

indicates a model with the theft-alarm system installed. indicates models without a theft-alarm system.

ELECTRICAL - Lighting 7-13 HEADLAMP LEVELING SYSTEM The headlamps leveling system is a system that the driver can, if desired, use to change the head lamps illumination angle in the vertical direction so as to prevent approaching vehicles from being subjected to excessive brightness due to a change in the attitude of this vehicles because of the number of people or the amount of load carried. This system is composed of the headlamp leveling unit (installed to the rear of the head lamps) and the headlamp leveling switch (located at the lower left part of the instrument panel). When the headlamps are illuminated, the illumination angle in the vertical direction (lower beam only) can be set to anyone of four steps by using the headlamp leveling switch. NOTE For the construction and operation of the headlamp leveling system, refer to the 1990 LANCER HATCHBACK Technical Information Manual.

ENGINE COMPARTMENT INSPECTION LAMP When the hood is opened with the lighting switch in the TAIL or HEAD position, the inspection lamp switch goes ON, the inspection lamp in the hood lamps up to illuminate the engine compartment.

COMBINATION GAUGE The combination gauge used is a 3-set gauge type with sporty feeling.

68F0053

68F0054

7-14 ELECTRICAL - Meters and Gauges

METERS AND GAUGES COMBINATION METER The combination meter uses analogue meters that are large, and easy-to-read, indicator lights and warning lights. The speedometer is an electric type that is operated by pulse signals from the vehicle speed sensor so the pointer moves smoothly in response the speed variations without pointer shaking.

68F0053

Magneto Resistive Element (MRE) in the top of the magnet detects the rotation of the magnet and generates a 4-pulse electric signal for each rotation of the speedometer driven gear.

the direction of the magnetic field is vertical to the Magneto Resistive Element (MRE), the resistance value is minimum.

into a 1rotation, 4-pulse signal, the transistor turns it ON- OFF when it is output to the transistor base to produce a 4-pulse electric signal per one rotation of the speedometer driven gear.

ELECTRICAL - Meters and Gauges 7-15 VEHICLE SPEED SENSOR STRUCTURE The rotating shaft of the vehicle speed sensor is mounted directly on the transmission speedometer driven gear. The rotation of the driven gear is transmitted to a magnet via the rotating shaft. The IC built into the

Characteristics The magneto resistive element (M R E) has the characteristic that its resistance value varies according to the direction of the magnetic field. When the direction of the magnetic field is parallel to the Magneto Resistive Element (MRE), the resistance value is maximum; when

Operation Since the resistance value of the MRE varies with the variations in the magnetic field when the magnet rotates, the output voltage also varies. The shape of the wave of this output voltage is shaped by the comparator and then, after it is divided by the frequency divider circuit

MAGNETO RESISTIVE ELEMENT (MRE)

that pass directly through it. Furthermore, the odometer and trip meter are directly driven by the stepping motor with built-in gear.

7-16 ELECTRICAL - Meters and Gauges

ELECTRIC TYPE SPEEDOMETER CONSTRUCTION The electric type speedometer uses an electronic circuit to control the electric signal from the vehicle speed sensor and a cross coil type speedometer that has a magnet fixed to the pointer shaft and two coils

OPERATION Electronic Circuit It shapes the wave of the electric signal from the vehicle speed sensor in the shaping circuit and, after calculating vehicle speed at the calculation circuit, it controls current flow to the cross coil and stepping motor. It determines the direction of current flowing in each cross coil by using the quadrant indicating circuit and, at the same time, it determines the current value

using the duty data circuit, and sends current from the meter drive circuit to drive the pointer. It determines the current value flowing to the stepping motor by using the pulse motor data circuit, and sends current from the pulse motor drive circuit to drive the odometer and trip meter.

16F0233

16F0232

Electronic circuit

ELECTRICAL - Meters and Gauges 7-17 Cross Coil When current flows in the cross coil, a magnetic field is generated in coil 1 and coil 2. Since the two magnetic fields pass directly through, the actual magnetic field is a combination of the two magnetic fields. Since the magnet is fixed to the pointer shaft, the magnet rotates to try to align the magnetic axis of the magnet in the direction of the combined magnetic field and thus rotates the speedometer pointer. NOTE The speedometer pointer is attached to the pointer shaft 20 counterclockwise to the magnetic axis of the magnet.

RELATION BETWEEN POINTER ANGLE AND CURRENT VALUE The angle of the pointer is determined by a variation of the current value flowing in coil 1 and coil 2.

Example: When the pointer is at 90 Maximum current flows in coil 1. No current flows in coil 2.

NOTE When the pointer is at an angle of 0, it indicates a speed of o km/h (0 mph).

The front wiper is a semi-concealed type with the following features. A variable time intermittent wiper under ETACS

control is used on all models. (Refer to ETACS for operation of the variable time intermittent wiper.)

There is a mist wiper function for more convenience. The washer is a 2-nozzle 4-jet type and there is a

level gauge switch to inform by an indicator lamp in the combination meter that the washer in the washer tank is low. The rear wiper is used for improved rear

STRUCTURAL DIAGRAM

visibility when it rains, etc. It has the following additional features.

It uses a fixed time intermittent wiper. The washer is a 1-nozzle 2-jet type and there is a

level gauge in the washer tank for easy detection of the amount of liquid. It is mounted in the right rear of the cargo compartment.

The wiper/washer switch is mounted on the right side of the knee protector. It is a combination wiper/washer switch and can be operated when the ignition switch is at ACC or ON.

7-18 ELECTRICAL - Meters and Gauges

WIPER AND WASHER

There are two types of AM/FM multi-electronic tuning radios for the radio and stereo . 6 speakers (front speaker: single cone for high-

frequency sound, door speaker: double cone for high/low-frequency sound, rear speaker: single cone for high/low-frequency sound)

7 stop retractable motor driven antenna with a total length of 900mm (35.4 in.).

STRUCTURAL DIAGRAM

16F0414

NOTE Speakers are also installed on the right side.

AM/FM multi-electronic tuning radio and tape player

Type 1

ELECTRICAL - Meters and Gauges 7-19 RADIO AND TAPE PLAYER

Type 2 Vehicles for Europe

LW/MW/FM electronic tuning radio with tape player (1 DIN)

Vehicles for General Export, GCC and Australia

AM/FM electronic tuning radio with tape player (1 DIN)

16N0598 16N0597

7-20 ELECTRICAL - Radio and Tape Player I Accessory Socket

ACCESSORY SOCKET There is a convenient accessory socket for use when using plug-in type accessories. The maximum load that can be used is 120W.

ETACS (Electronic Time and Alarm Control System) is adopted and uses a micro-computer for centralized control of all timer and alarm functions.

This control unit has an input check function to check normality or abnormality of the circuit from the input switch to micro-computer in the control unit.

SUMMARY OF FUNCTIONS

ELECTRICAL - ETACS 7-21

ETACS (ELECTRONIC TIME AND ALARM CONTROL SYSTEM)

7-22 ELECTRICAL - ETACS

judgement circuit, and when the key cylinder switch ON signal is input, an H signal is input to the lock output side of timer circuit I. This causes Tr2 to turn ON for 0.5 seconds, and all of the doors lock. Also, if the passenger's side door is unlocked by means of the key, an L signal is input to the door lock switch judgement circuit, and when a key cylinder switch ON signal is input, an H signal is input to the unlock side of timer circuit I. This causes Tr1 to turn ON for 0.5 seconds, and all of the doors unlock.

NOTE - - - indicates area of theft-alarm system.

16F0428

ELECTRICAL - ETACS 7-23

OPERATION CENTRAL DOOR LOCKING (1) When the inside lock knob on the driver's side is

locked, AND1 outputs an H signal which causes Tr2 to turn ON for 0.5 seconds by means of timer circuit I, and all of the doors lock. In addition, when the inside lock knob on the driver's side is unlocked, the L signal is reversed by the NOT1 and a H signal is input to the unlock output side of timer circuit I. This causes Tr1 to turn on for 0.5 seconds, and all of the doors unlock.

(2) When the driver's side door is locked by means of the key, the operation is the same as in step (1).

(3) If the passenger's side door is locked by means of the key, an H signal is input to the door lock switch

PREVENTING DOORS FROM BEING LOCKED WHEN IGNITION KEY IS LEFT BEHIND If the key is left in the ignition switch (key reminder switch OFF), when the driver's side door is opened (door switch ON) and the driver's side inside lock knob is locked, AND3 and AND2 output H signals.

This causes timer circuit II to operate to turn Tr1 ON, and all of the doors unlock to prevent the key from being left behind.

16F0384

7-24 ELECTRICAL - ETACS

DEFOGGER TIMER (1) When the ignition switch is ON, if the defogger

switch is turned ON, the signal input to the NOT becomes an L signal, and the converted H signal makes the timer circuit operate. Next, an H signal of the power circuit and an H signal of the timer circuit are input to the AND and the output H signal turns transistor Tr1 ON. This causes the defogger relay to operate, and current flows to the defogger.

After 11 minutes, the signal output by the timer circuit becomes an L signal, and the defogger op- eration is stopped.

(2) Even if the defogger is operating, if the defogger switch is turned once more to ON, the defogger relay turns OFF and the defogger operation is stopped.

(3) When the ignition switch is turned from ON to OFF, an H signal is output from timer I for 30 seconds, but if the driver's side door is opened during this time, the door switch turns ON. The input side of NOT2 then becomes an L signal and the converted H signal is input to the AND. It is matched with the H signal from timer I and the output from the AND is an H signal. This causes timer II to input an H signal to OR2 for 30 seconds. This in turn causes Tr to turn ON, and the front seat belt solenoid can operate for a further 30 seconds.

16F0416

ELECTRICAL - ETACS 7-25

SEAT BELT TENSION REDUCER TIMER (1) Because an H signal is input to the OR1 when the

ignition switch is turned to ON, OR2 outputs an H signal, and transistor Tr turns ON, enabling the front seat belt solenoid (tension reducer function) to operate. (For the tension reducer, refer to GROUP 6 - Seat Belt.)

(2) When the ignition switch is turned from ON to OFF, the H signal converted by NOT1 causes timer I to output an H signal for 30 seconds. Because the H signal is input to OR 1, the front seat belt solenoid can operate in the same way as in step (1). (30 seconds)

and activates the timer circuit. The timer circuit outputs to the Tr base a signal that gradually varies for 6 seconds due to duty control, and the voltage for the lams is gradually reduced to dim the lamps.

(3) If the ignition switch is turned ON, the input to NOT becomes an H signal and the reversed L signal is input to AND. As a result, even if the door is closed, the lamp does not dim but is extinguished immediately since the timer circuit is not activated.

16F0306

7-26 ELECTRICAL - ETACS

DIMMER TYPE LAMP (1) If the room lamp switch is the DOOR position and

the door is opened (door switch ON), current from the battery flows from lamps (room lamp, 'foot lamp ignition key cylinder illumination lamp) ETACS unit door switch earth and the lamp go on.

(2) If the ignition switch is OFF, input to NOT becomes an L signal and the reversed H signal is input to AND. If a door is closed at this time (door switch OFF), the circuit of door switch earth is cut off and, since an H signal is input to AND, AND outputs an H signal

(4) After flashing for 6 second, the lamp goes out. (5) If the ignition switch is turned OFF during the 6

seconds, the lamp goes out. (6) If the seat belt switch is turned OFF (seat belt

buckled) during the 6 seconds, the warning lamps go out.

16F0417

ELECTRICAL - ETACS 7-27

SEAT BELT WARNING LAMP (1) Voltage is applied from the battery via the seat belt

warning lamp to the Tr collector. (2) When the ignition switch is turned ON, the timer

circuit outputs an H signal for 6 seconds and an L signal and H signal are output alternately from the pulse circuit.

(3) When there is output from both the timer circuit and pulse circuit to AND, Tr is turned ON. Consequently, the 6 second lamp flashes.

1 6 F 041 8

7-28 ELECTRICAL - ETACS

INTERMITTENT WIPER (1) If the wiper switch is turned to the INT position

when the ignition switch is in the ON or ACC position, the voltage value from the intermittent variable volume switch is input to the intermittent time detection circuit.

(2) The intermittent time detection circuit outputs an H signal at the intermittent time according to the set value of the intermittent variable volume switch and, via OR, turns the Tr on and off to operate the wiper.

MIST WIPER AND WASHER LINKED WIPER (1) If the washer switch is turned on when the ignition

switch is in the ON or ACC position and the wiper switch is off, an H signal is input to the washer switch ON time detection circuit and, when the washer switch ON time is less than 0.6 second, timer circuit I is activated, there is a t second

(washer switch On time) delay, and the Tr is turned on via OR for one wiper cycle (mist wiper).

(2) When the washer switch ON time is 0.6 second or more, washer switch timer circuit I I is activated, there is a 0.6 second delay due to the functioning of the ON delay timer and the Tr is turned on via OR for one wiper cycle.

(3) In addition, if the washer switch is turned OFF, the timer circuit II operates the wiper for 2-3 cycles after the washer switch is turned OFF since there is a 2.5-3.8 second delay before the output is turned off.

(4) During intermittent operation with the wiper switch in the INT position, the mist wiper and washer linked wiper operate.

INPUT INSPECTION FUNCTIONS OF ETACS The ETACS control unit has an input inspection function that can check everything from each switch to the ETACS control unit by using a multi-use tester to measure the voltage variations at the ETACS terminals on the diagnosis connector. The diagnosis connector is installed on the side of the junction block on the lower left-side of the instrument panel. The ETACS input inspection function has the following functions. (1) Ignition switch (ACC and ON) (2) Wiper switch (I NT) (3) Variable intermittent wiper control switch (4) Washer switch (5) Key reminder switch (6) Door switch (7) Door lock switch (8) Defogger switch (9) Pop-up switch

ELECTRICAL - ETACS 7-29

PARTS AND FUNCTIONS RELATED WITH ETACS

NOTE (1) *mark indicates a switch or sensor that can be used for input inspection with the multi-use tester. (2) 0 mark indicates a part relevant for each function.

7-30 ELECTRICAL - ETACS

OPERATION

16F0295

THEFT-ALARM SYSTEM When the theft-alarm system has been armed by a fixed sequence for locking the doors without the key, if thereafter a door, the tailgate or the hood is opened in an unauthorized way, the horn will sound intermittently for a period of 30 seconds, thus providing audible warning signals. Furthermore, the starter circuit is interrupted in such a way that the engin'e cannot be started, if the ignition key is not used.

Note that this system is controlled by the Electronic Control Unit (ECU) as one function of the ETACS (Electronic Time and Alarm Control System). The system is composed of the components described below. NOTE The "ECU" (Electronic Control Unit) indicates the ETACS control unit.

16F0296

ELECTRICAL - ETACS 7-31

After the following procedures have been completed, the SECURITY lamp illuminates for about 20 seconds, and when illumination stops, the system is armed. (1) Pullout the ignition key from the key cylinder. (2) Open a door. (The other door is locked.) (3) Lock the door with the key or the keyless-locking

method. (The central door locking system will then function to lock all doors.) NOTE (1) The system is set regardless of whether the

hood and tailgate are open or closed, and is armed as soon as the lamp goes out.

(2) While the timer is functioning (approximately 20 sec.), it is not reset even if the hood or tailgate is opened and closed.

The system will be disarmed, (1) If the key is used to unlock a door. (2) If the system is armed while the driver is still in the

vehicle, the system can be disarmed by inserting the ignition key and turning it to the ACC or ON position.

(3) If the door is unlocked while closing the door or the door is ajar.

(4) If the door is unfastened while the SECURITY lamp illuminates.

(5) If, after the keyless warning is set, the door on the driver's side or passenger's side is locked but not completely closed (door-ajar).

(1) If an attempt is made to open a door, the tailgate or hood, without using the key, while the system is armed, the horn will sound intermittently for approximately 30 sec. Furthermore, the starter circuit is interrupted at this time also, making starting of the engine impossible.

(2) If a further attempt at forcible entry is made after the first 30 sec. alarm has finished, the 30 sec. alarm will be activated again.

7-32 ELECTRICAL - Theft-alarm System

ARMING THE SYSTEM

DISARMING THE SYSTEM

ACTIVATING THE ALARM

DEACTIVATING THE ALARM (1) To deactivate the alarm, insert the key into the

door's key cylinder and turn the key. (2) The alarm is deactivated and the system is disarmed

when the tailgate is unlocked with the key.

CHECKING THE SYSTEM OPERATION The activation/operation of the system can be checked by following the steps below. (1) Turn the ignition key to the ON position and then use

the power-window switch to fully open the window on the driver's side.

(2) Turn the ignition key to the LOCK position and then remove the key from the ignition.

(3) Open only the driver's door, and close all the other doors, as well as the hood and the tailgate.

(4) Lock the driver's door with the key or the keyless- locking method.

(5) All doors will then be locked, and the SECURITY lamp (within the combination meter) will illuminate; check to be sure that illumination stops in about 20 seconds.

(6) After about two seconds have passed after the SECURITY lamp illumination stopped, reach through the window of the driver's door, pull up the lock lever to unlock the door, and then open the door.

(7) Check to be sure that, when the door is opened, the horn starts sounding.

(8) To stop the alarm, insert the key into the door's key cylinder and turn the key.

NOTE To check the alarm for the opening of the tailgate or hood, open the tailgate (or the hood) by using the remote tailgate release lever (or the hood release lever), located on the driver's side either before the alarm is activated by the opening of a door, or after the finish of the first 30 sec. alarm.

The heater and air conditioning have outstanding cooling and heating performance and use a small amount refrigerant system.

FEATURES

Improvement of visual recognition

Improvement of reliability and serviceability

Improvement of performance

Improvement in performance

SPECIFICA TIONS

Adoption of air conditioner colour monitor

1. Adoption of a 2-step control system for the condenser and radiator fan speed. 2. Flange fitting of the receiver piping joints. 3. Belt protection by belt lock controller when compressor is locked.

1. Adoption of multi-flow type condenser. 2. Adoption of small amount refrigerant system. 3. Adoption of heater unit with maximum cool by-pass.

1. Adoption of a multi-flow type condenser. 2. Adoption of a small amount refrigeration system.

ELECTRICAL - Heater and Air Conditioning 7-33 HEATER AND AIR CONDITIONING GENERAL INFORMATION

Items Specifications Heater unit

Type Three-way-flow full-air-mix system Heater control switch Push button type Compressor

Model Scroll type (FX-105VS)

Refrigerant unit lubricant cm3 (cu.in.) FREOL S-83 or SUNISO 5GS 160 +20 / -0 (9.8 +1.2 / -0)

V-belt size mm (in.) 1,150 (45.3) Condenser

Type Multi-flow type Dual-pressure switch \

High pressure switch kPa (kg cm2, psi) OFF: 2,700 (27, 384) ON: 2,100 (21, 299) Low pressure switch kPa (kg cm2, psi) OFF: 210 (2.1,30) ON: 235 (2.35, 33)

Freezer prevention C (F) Fin temperature thermostat OFF: -2 (28.4) ON: 2 (35.6)

Refrigerant and quantity g (oz) R-12 MAX 770-870 (27-31)

Air conditioner colour monitor

7-34 ELECTRICAL - Heater and Air Conditioning

COMPONENTS

Interior temperature sensor

Photo sensor

Engine coolant temperature switch (for air conditioner cut-off)

20F0053

To passengers FACE (side ventilator)

Inlet garnish

Rear ventilation duct A

Rear ventilation duct B

Centre ventilator 20F0046

To door window (side defroster)

20F0051

To front window (defroster)

To passenger's feet and knees

Centre ventilator

To driver's feet and knees

- To driver's FACE (side ventilator)

To door window (side defroster)

ELECTRICAL - Heater and Air Conditioning 7-35

From July 1989, the consumption and production of specially designated chlorofluorocarbon have been regulated world-wide to protect the ozone layer. Chloro- fluorocarbon R-12, used as the Refrigerant in automobile air conditioners, is the object of those regulations and there is a need to control the amount of

chlorofluorocarbon used as much as possible. The small amount refrigerant system has been developed to improve the performance of the structural parts of the air conditioner in accord with those regulations, to make them more compact, etc.

REFRIGERANT LINE The 3-layer type hose that was used up to now was replaced by a 4-layer type hose in order to reduce the amount of refrigerant permeated into the refrigerant line rubber hose.

AIR CONDITIONER COMPRESSOR Leakage of refrigerant from bearings has been reduced by changing the air conditioner bearings from metal seal to lip seal type.

CONDENSER By adopting a multi-flow type condenser, not only heat exchange performance has been improved, but also the condenser has become more compact.

RECEIVER A receiver with a shade to prevent bubbling IS used. Bubbling inside the receiver can be controlled with the shade. Consequently, as shown in the figure, the range of liquid refrigerant mixed in the bubbles can be reduced. As a result, the amount of refrigerant can be reduced (Figure on the left (A)). Furthermore, the amount of refrigerant is further reduced by making the bottom of the receiver into a cone shape (Fiqure on the left (B)).

SMALL AMOUNT REFRIGERANT SYSTEM

7-36 ELECTRICAL - Heater and Air Conditioning

The heater unit is a 3-layer flow type full air mix heater with outstanding heating characteristics. There is a by-pass passage to increase the amount of air at maximum cooling. The by-pass passage is opened by the max-cool damper which is connected to the air mix damper and, consequently, some of the air is blown

directly to the air outlet (FACE). As a result, noise is reduced by reducing air flow resistance inside the heater and by controlling the generation of air turbulence inside the heater.

By-pass passage

20F0047

AIR CONDITIONER CONTROL PANEL There is an air conditioner colour monitor in the air conditioner control panel of the full automatic air con- ditioner. The air conditioner colour monitor is a dynamic

display in which the display arrow moves after the mode button is operated.

Air conditioner colour monitor

20F0084 Display arrow Mode button

ELECTRICAL - Heater and Air Conditioning 7-37

HEATER UNIT

Belt lock controller

COMPRESSOR CONTROL

If anyone of the following switches and sensors is turned off, the magnet clutch of the compressor is turned off.

Switch and sensor Operating condition of compressor Blower switch Air conditioner switch } Automatic when in AUTO

Dual-pressure switch High pressure switchkPa (kg cm2, psi) OFF: 2,700 (27, 384) or more ON : 2,100 (21, 299) or less Low pressure switch kPa (kg cm2, psi) OFF: 210 (2.1, 30) or less ON : 235 (23.5, 33) or more

Engine coolant temperature switch OFF at 115 3C (239 5F) or over, ON at 108C (226F) or less

Engine coolant temperature sensor OFF at 155 5C (311 9F) or over, ON at 110C (230F) or less

Air inlet sensor OFF when sensing temperature is lower than a set temperature, ON when sensing temperature is higher than a set temperature (ECONO mode only)

Air thermo sensor OFF at -2C (28.4F) or less, ON at 2C (35.6F) or over Revolution pick-up sensor OFF when compressor slipping rate(s) is 70% or more

S= 1- Nc . x100 Ne: engine rpm Ne x Pulley ratio Nc: compressor rpm

Control when Compressor Locks Since the compressor and alternator are driven by the same belt, the electric generating function of the alternator also stops when the belt is broken. In order to assure the electric generating function of the alternator, there is a belt lock controller to prevent breaking of the belt due to slipping when the compressor locks. The controller makes a comparative calculation of the compressor revolutions and the engine revolutions which are detected by the revolution pick-up sensor. When

Air conditioning color monitor

Blinking 20F0026

7-38 ELECTRICAL - Heater and Air Conditioning

Shower duct (R.H.)

Revolution pick-up sensor

Compressor

20N0071

70% or more slip ratio continues for 3 seconds or more, the compressor relay goes from on to off; at the same time, in models with full automatic air conditioners, the mark in the air conditioner color monitor in the air conditioner control panel blinks to announce (an abnormality and, in models with manual air conditioners, the operation display in the air conditioner switch blinks to announce an abnormality.

ELECTRICAL - Heater and Air Conditioning 7-39

MPI control unit

Engine coolant temperature switch

Thermostat

Dual-pressure switch

Revolution pick-up sensor

Air conditioner control panel

20F0044

CONDENSER FAN AND RADIATOR FAN CONTROL The rotational speed of the condenser fan and radiator fan is controlled by the engine coolant temperature and

is designed to improve cooling efficiency and to reduce fan noise.

FAN REVOLVING OPERATION MODE

20F0147

7-40 ELECTRICAL - Heater and Air Conditioning

Belt lock controller

To dual pressure switch

Condenser fan motor relay (LO)

Condenser fan motor

Radiator fan assembly

Radiator fan motor relay (HI)

Sight glass

REFRIGERANT LINE

The receiver piping joints have flange fittings and the pipe ends are flared (pipe expanded) to prevent the

O-ring from dropping out and to improve workability.

SELF-DIAGNOSIS Code Trouble Back-up function or vehicle condition

0 (Normal) (Normal) 11 Wire in interior temperature sensor broken Reaches condition when 25C (77F) is detected 12 Wire in interior temperature sensor short-circuited 13 Wire of air inlet sensor broken 14 Wire of air inlet sensor short-circuited Reaches condition when 20C (68F) is detected. 21 Wire of air thermo sensor broken Reaches condition when -2C (28F) is detected. 22 Wire of air thermo sensor short-circuited 31 Wire of air mix damper potentiometer broken or Reaches MAX. HOT (MAX. COOL when set to MAX. short circuited COOL) 32 Wire of mode selection damper potentiometer Reaches DEF. (FACE when set to FACE) broken or short-circuited 41 Trouble in air mix damper drive system 42 Trouble in mode selection damper drive system

High pressure pipe A

Flange

- O-ring

Melt plug

ELECTRICAL - Heater and Air Conditioning 7-41

Receiver

High pressure pipe B

20N0092

SELF-DIAGNOSIS AND BACK-UP FUNCTION

(1) It has a self-diagnosis function to diagnose trouble in the 11 systems of sensors, etc. and in the control unit itself and helps assure easy troubleshooting.

(2) When some abnormality is detected in the system, it outputs the location of the abnormality to the diagnosis connector in the side of the fuse box. Use the Multi-use Tester.

(3) It not only displays the code No. but there is also a back-up safe function to stop trouble to the system due to an breakdown.

(4) If there are 2 or more abnormalities, the code Nos. starting with the smallest are continuously displayed. Furthermore, the code No. is kept in memory until battery terminal is disconnected.

RJST 206033-212

Manualsnet FAQs

If you want to find out how the 3000GT Mitsubishi MOTORS works, you can view and download the Mitsubishi Motors 3000GT 1993 Information Manual on the Manualsnet website.

Yes, we have the Information Manual for Mitsubishi MOTORS 3000GT as well as other Mitsubishi MOTORS manuals. All you need to do is to use our search bar and find the user manual that you are looking for.

The Information Manual should include all the details that are needed to use a Mitsubishi MOTORS 3000GT. Full manuals and user guide PDFs can be downloaded from Manualsnet.com.

The best way to navigate the Mitsubishi Motors 3000GT 1993 Information Manual is by checking the Table of Contents at the top of the page where available. This allows you to navigate a manual by jumping to the section you are looking for.

This Mitsubishi Motors 3000GT 1993 Information Manual consists of sections like Table of Contents, to name a few. For easier navigation, use the Table of Contents in the upper left corner.

You can download Mitsubishi Motors 3000GT 1993 Information Manual free of charge simply by clicking the “download” button in the upper right corner of any manuals page. This feature allows you to download any manual in a couple of seconds and is generally in PDF format. You can also save a manual for later by adding it to your saved documents in the user profile.

To be able to print Mitsubishi Motors 3000GT 1993 Information Manual, simply download the document to your computer. Once downloaded, open the PDF file and print the Mitsubishi Motors 3000GT 1993 Information Manual as you would any other document. This can usually be achieved by clicking on “File” and then “Print” from the menu bar.