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1.9-Liter TDI Enginewith Pump Injection(Pumpe Düse)Design and Function
Self-Study ProgramCourse Number 841303
Volkswagen of America, Inc.Service TrainingPrinted in U.S.A.Printed 10/2003Course Number 841303
©2003 Volkswagen of America, Inc.
All rights reserved. All information containedin this manual is based on the latestinformation available at the time of printingand is subject to the copyright and otherintellectual property rights of Volkswagen ofAmerica, Inc., its affiliated companies and itslicensors. All rights are reserved to makechanges at any time without notice. No partof this document may be reproduced,stored in a retrieval system, or transmittedin any form or by any means, electronic,mechanical, photocopying, recording orotherwise, nor may these materials bemodified or reposted to other sites withoutthe prior expressed written permission ofthe publisher.
All requests for permission to copy andredistribute information should be referredto Volkswagen of America, Inc.
Always check Technical Bulletins and theVolkswagen Worldwide Repair InformationSystem for information that may supersedeany information included in this booklet.
Trademarks: All brand names and productnames used in this manual are trade names,service marks, trademarks, or registeredtrademarks; and are the property of theirrespective owners.
i
Table of Contents
The Self-Study Program provides you with informationregarding designs and functions.
The Self-Study Program is not a Repair Manual.
For maintenance and repair work, always refer to thecurrent technical literature.
Important/Note!
New!
Introduction ............................................................................... 1
1.9-Liter TDI Engine with Pump Injection System
Engine – Mechanics .................................................................. 2
Development of the 1.9-Liter TDI Engine with PumpInjection System, Technical Data – 1.9-Liter TDI Enginewith Pump Injection System, Trapezoidal Piston andConnecting Rod, Toothed Belt Drive
Fuel Supply ................................................................................ 8
Fuel Supply System Overview, Fuel Pump,Distributor Pipe, Fuel Cooling System
Pump Injection System ..........................................................15
Pump/Injectors, Design, Injection Cycle
Engine Management...............................................................28
1.9-Liter TDI Engine EDC 16 System Overview,Sensors, Actuators
Glow Plug System ..................................................................53
Glow Plug System
Functional Diagram.................................................................54
EDC 16 Functional Diagram for 1.9-Liter TDI Engine
Service......................................................................................56
Self-Diagnosis, Pump/Injector Adjustment, Special Tools
Knowledge Assessment .........................................................61
Introduction
1
1.9-Liter TDI Engine withPump Injection System
The demands on the modern diesel enginefor increased performance and fueleconomy, and reduced exhaust emissionsand noise levels are growing constantly.
Good fuel and air mixture preparation is akey factor in meeting these requirements.
This calls for efficient injection systems thatproduce high injection pressures to ensurethat the fuel is well atomized. It is alsonecessary to precisely control the start offuel injection and the injection quantity.
The pump injection system meetsthese requirements.
In 1905, Rudolf Diesel came up with theidea of a pump/injector, combining theinjection pump and injector in one unitin order to dispense with high-pressurelines and achieve high injection pressures.At the time, however, he did not havethe technical means to put his ideainto practice.
Diesel engines with mechanically controlledpump injection systems have been in usein ships and trucks since the 1950s.
In association with Bosch, Volkswagen hassucceeded in developing a diesel enginewith a solenoid valve controlled pumpinjection system suitable for use inpassenger cars.
The 1.9-liter TDI engine with the new pumpinjection system meets the stringentdemands for improved performance andcleaner emissions.
With continuing advances like this one,Rudolf Diesel’s vision of “smoke- andodor-free exhaust gases” may one daybecome a reality.
SSP304/032
SSP209/027
Engine – Mechanics
2
Development of the1.9-Liter TDI Engine withPump Injection System
The new 100 bhp (74 kW) 1.9-liter TDIengine with pump injection system wasdeveloped from the existing 109 bhp (81kW) 1.9-liter TDI engine with a distributorinjection pump and no intermediate shaft.
The pump injection system comprises theonly significant difference between thetwo engines.
This Self-Study Program concernsthe design and function of the new pumpinjection system, and the modificationsto the fuel system, engine managementsystem, and engine mechanicalcomponents to accommodate the system.
A diesel engine with the pump injectionsystem has the following advantages overan engine with a distributor injection pump:
• Low combustion noise.
• Low fuel consumption.
• Clean emissions.
• High efficiency.
These advantages are attributable to:
• The high injection pressures of up to27,846 psi (192,000 kPa / 1,920 bar).
• Precise control of the injection cycle.
• The pre-injection phase.
SSP209/005
Speed (rpm)
3
Engine – Mechanics
Technical Data –1.9-Liter TDI Engine withPump Injection System
• Engine code
BEW
• Type
Four-cylinder in-line engine with twovalves per cylinder
• Displacement
115.7 cu in (1,896 cm3)
• Bore
3.13 in (79.5 mm)
• Stroke
3.76 in (95.5 mm)
• Compression ratio
19.0 : 1
• Maximum power output
100 bhp (74 kW) @ 4000 rpm
• Maximum torque
177 lbs-ft (240 Nm) @ 1800 to 2400 rpm
• Engine management
EDC 16
• Firing sequence
1-3-4-2
• Emission Control
Bin 10 EPA Federal Emissions Concept,OBD II, catalytic converter, water-cooledEGR system
SSP209/006
To
rqu
e
Ou
tpu
t
1000 2000 3000 4000 5000
lbs-ft Nm
221 300
184 250
148 200
111 150
74 100
37 50
0
hp kW
121 90
101 75
80 60
60 45
40 30
20 15
0
4
Engine – Mechanics
Trapezoidal Pistonand Connecting Rod
To accommodate the higher combustionpressures in the 1.9-liter TDI engine withpump injection system than areencountered in the base engine, the pistonhub and the connecting rod eye aretrapezoidal in shape.
SSP209/007
5
Engine – Mechanics
This distributes the combustion forces overa larger area and relieves the load on thepiston pin and connecting rod.
In comparison with the conventionalparallelogram-shaped link between thepiston and connecting rod, the trapezoidalconnecting rod eye and piston hub have alarger contact surface area at the piston pinowing to their shape.
SSP209/008
Combustion ForceContact Surface
Force Distribution in a Parallelogram-Shaped
Piston and Connecting Rod
Force Distribution in a Trapezoidal Piston
and Connecting Rod
Combustion ForceContact Surface
SSP209/009
Toothed Belt Drive
High pump forces are required to generatehigh injection pressures of up to 27,846 psi(192,000 kPa / 1,920 bar).
These forces subject the components ofthe toothed belt drive to high loads.
To relieve the load on the toothed belt,several modifications have been made.
• A vibration absorber integrated in thecamshaft gear reduces vibration inthe toothed belt drive.
• The toothed belt is about 0.20 inch(5 mm) wider than the toothed belt usedin the base engine. Higher forces can betransmitted by the larger surface area.
• A hydraulic tensioner keeps thetoothed belt evenly tensioned indifferent load states.
• Some of the teeth on the crankshafttiming belt gear have a larger gapclearance to reduce toothed belt wear.
SSP209/089
SSP209/88
GapClearance To relieve the load on the toothed belt
during the injection cycle, the crankshafttiming belt gear has two pairs of teeth witha larger gap clearance than the other teeth.
6
Engine – Mechanics
Function
During the injection cycle, the highpumping forces exert a heavy load on thetoothed belt.
The camshaft timing belt gear is sloweddown by the pumping forces. At the sametime, the combustion process speeds upthe crankshaft timing belt gear. The toothedbelt is stretched and the pitch is temporarilyincreased as a result.
Because of the engine firing order, thisstretching process occurs at regularintervals and the same teeth on the timingbelt gear are in mesh with the toothed beltevery time.
Non-uniform tooth gap clearance
On the 1.9-liter TDI engine with pumpinjection system, the crankshaft timing beltgear teeth have a larger gap clearance atthese points to compensate for the changein belt tooth pitch and thus reduce toothedbelt wear.
SSP209/091
7
Deceleration Force
Acceleration Force
Pitc
h
Engine – Mechanics
8
Fuel Supply
Fuel Supply System Overview
A mechanical fuel pump sucks the fuel outof the fuel tank through the fuel filter andpumps it along the supply line in thecylinder head to the pump/injectors.
Fuel Cooler – Cools the returning fuelto prevent excessively hot fuel frombeing routed back to the fuel tank.
The fuel that is not required for injection isreturned to the fuel tank via the return linein the cylinder head, a fuel temperaturesensor, and a fuel cooler.
Non-Return Valve – Prevents fuelfrom the fuel pump flowing back intothe fuel tank while the engine is notrunning. It has an opening pressureof 2.9 psi (20 kPa / 0.2 bar).
Fuel Filter – Protects the injectionsystem against contamination andwear caused by particles and water.
Fuel Temperature Sensor G81 –Determines the temperature of thefuel in the fuel return line and sends acorresponding signal to the Diesel DirectFuel Injection Engine Control Module J248.
Fuel Tank
9
Fuel Supply
SSP209/018
Fuel Return Line PressureLimiting Valve – Keeps thepressure in the fuel return lineat 14.5 psi (100 kPa / 1 bar).This maintains a forceequilibrium at the pump/injector solenoid valve needle.
Strainer – Collects vapor bubbles in thefuel supply line. These vapor bubbles arethen separated through the restrictorinto the return line.
Fuel Supply Line Pressure Limiting Valve –Regulates the fuel pressure in the fuel supply line.The valve opens when the fuel pressure exceeds109 psi (750 kPa / 7.5 bar). Fuel is routed back tothe suction side of the fuel pump.
Fuel Pump Rotor – Pumps the fuel fromthe fuel tank through the fuel filter andthe fuel supply line in the cylinder headto the pump/injectors.
Restrictor – Located between thefuel supply line and the fuel returnline. Vapor bubbles in the fuel supplyline are separated through therestrictor into the fuel return line.
Pressure Limiting Valve Bypass –If there is air in the fuel system,for example when the fuel tankis empty, the pressure limitingvalve remains closed. The air isexpelled from the system by thefuel flowing into the tank.
Cylinder Head
There is a fitting on the fuelpump for connecting pressuregauge VAS 5187 to check thefuel pressure in the supply line.Please refer to the Repair Manualfor instructions.
Fuel Supply
10
Fuel Pump
The fuel pump is located directly behindthe vacuum pump at the cylinder head.It moves the fuel from the fuel tank to thepump/injectors.
Both pumps are driven jointly by thecamshaft. They are collectively known asa tandem pump.
Fuel Return Line
SSP209/049
Pressure GaugeConnection Fitting
Fuel Pump
Vacuum Pump
Fuel Supply Line
11
Fuel Supply
The fuel pump is a blocking vane-cell pump.The blocking vanes are pressed against thepump rotor by spring pressure. This designenables the fuel pump to deliver fuel evenat low engine speeds.
The fuel ducting system within the pumpis designed so that the rotor alwaysremains wetted with fuel, even if the tankhas been run dry. This makes automaticpriming possible.
SSP209/050
Blocking Vanes
Restrictor
Connection forFuel Supply Line
Fuel Supply LinePressure Limiting Valve
To Fuel Supply Linein Cylinder Head
Strainer
Connection forFuel Return Line
Fuel ReturnLine PressureLimiting Valve
RotorFrom FuelReturn Line inCylinder Head
12
Function
The fuel pump operates by taking fuel in asthe pump chamber volume increases andpushing the fuel out under pressure as thechamber volume is reduced.
The fuel is drawn into two chambers andpumped out from two chambers. Theintake and delivery chambers are separatedfrom one another by the spring-loadedblocking vanes and the pump rotor lobes.
Fuel drawn into chamber 1 is pushed out atchamber 2. Fuel drawn into chamber 3 ispushed out at chamber 4.
The rotation of the rotor increases thevolume of chamber 1 while the volume ofchamber 4 is simultaneously reduced.Fuel is pushed out of chamber 4 to thefuel supply line in the cylinder head.
Fuel Supply
The rotation of the rotor increases thevolume in chamber 3 as it reduces thevolume in chamber 2. Fuel drawn in atchamber 1 is forced out of chamber 2 tothe fuel supply line in the cylinder head.
SSP209/052Rotor
Chamber 4 Chamber 3
Chamber 2
Chamber 1
SSP209/051
Chamber 1
Rotor
Chamber 4
Chamber 3
Chamber 2
13
Fuel Supply
Distributor Pipe
A distributor pipe is integrated in the fuelsupply line in the cylinder head. It distributesthe fuel evenly to the pump/injectors at auniform temperature.
In the supply line, the fuel moves throughthe center of the distributor pipe towardcylinder 1 at the far end.
The fuel also moves through the crossholes in the distributor pipe and enters theannular gap between the distributor pipeand the cylinder head wall.
This fuel mixes with the hot unused fuelthat has been forced back into the supplyline by the pump/injectors.
This results in a uniform temperatureof the fuel in the supply line running toall cylinders.
All pump/injectors are supplied withthe same fuel mass, and the engineruns smoothly.
SSP209/039
Cylinder Head
Annular Gap
Cross Holes
Cylinder 4Cylinder 3Cylinder 2Cylinder 1
Distributor Pipe
SSP209/040
SSP209/29
Cross Holes
Mixing Fuel inAnnular Gap
Fuel to Pump/Injector
Fuel fromPump/Injector
14
Fuel Supply
Fuel Cooling Circuit
The heated fuel returning from the pump/injectors flows through the fuel cooler andits heat transfers to the coolant in the fuelcooling circuit that also flows through thefuel cooler.
The auxiliary water cooler reduces thetemperature of the coolant in the fuelcooling circuit by dissipating the heat inthe coolant to the ambient air.
Pump for Fuel Cooler V166 is an electricrecirculation pump. It circulates the coolantin the fuel cooling circuit through theauxiliary water cooler and the fuel cooler. Itis switched on by the Diesel Direct FuelInjection Engine Control Module J248 viathe Relay for Pump, Fuel Cooling J445 ata fuel temperature of 158°F (70°C).
The fuel cooling circuit is largely separatefrom the engine cooling circuit. This isnecessary because the temperature of thecoolant in the engine cooling circuit is toohigh to cool down the fuel when the engineis at operating temperature.
The fuel cooling circuit is connected to theengine cooling circuit near the expansiontank. This enables replenishment of thecoolant for fuel cooling at the coolantexpansion tank. It also allowscompensation for changes in volume dueto temperature fluctuation.
The fuel cooling circuit is connected so thatthe hotter engine cooling circuit does nothave a detrimental effect on its ability tocool the fuel.
SSP209/048
Fuel Pump
Pump forFuel CoolerV166
Fuel Cooler
AuxiliaryWaterCooler
EngineCoolingCircuit
Fuel Tank
CoolantExpansionTank
FuelTemperatureSensor G81
Fuel Cooling System
The high pressure generated by the pump/injectors heats up the unused fuel so muchthat it must be cooled before it gets back tothe fuel tank.
A fuel cooler is located on the fuel filter.
It cools the returning fuel and thus preventsexcessively hot fuel from entering the fueltank and possibly damaging the Sender forFuel Gauge G.
15
Pump Injection System
Pump/Injectors
A pump/injector is, as the name implies, apressure-generating pump combined with asolenoid valve control unit (Valves for Pump/Injectors, Cylinders 1 through 4, N240,N241, N242, and N243) and an injector.
Each cylinder of the engine has its ownpump/injector.
This means that there is no longer anyneed for a high-pressure line or a distributorinjection pump.
SSP209/012
Just like a conventional system with adistributor injection pump and separateinjectors, the new pump injectionsystem must:
• Generate the high injectionpressures required.
• Inject fuel into the cylinders in the correctquantity and at the correct point in time.
Solenoid Valve Control UnitInjector
Pressure-GeneratingPump
16
Pump Injection System
The pump/injectors are installed directly inthe cylinder head.
SSP209/086
SSP209/087
They are attached to the cylinder head byindividual clamping blocks.
It is important to ensure thatthe pump/injectors are positionedcorrectly when they are installed.Refer to the Repair Manualfor instructions.
If the pump/injectors are not installedperpendicular to the cylinder head, thefasteners could loosen. The pump/injectorsor the cylinder head could be damaged asa result.
ClampingBlock
17
Pump Injection System
Design
SSP209/023
Roller-TypeRocker Arm
O-Ring
O-Ring
O-Ring
Heat-InsulatingSeal
Cylinder Head
Injector Needle
Injector NeedleDamping Element
Injector Spring
Fuel Supply Line
RetractionPiston
Fuel Return Line
High-PressureChamber
Pump/InjectorSolenoid Valve
SolenoidValve Needle
Injection Cam
Piston Spring
Pump Piston
Ball Pin
18
Pump Injection System
Drive Mechanism
The camshaft has four additional cams fordriving the pump/injectors.
They activate the pump/injector pumppistons with roller-type rocker arms.
Valve Cam
SSP209/015
Injection Cam(Hidden byRocker Arm Roller)
Roller-TypeRocker Arm
19
Pump Injection System
The gradual slope of the cam trailing edgeallows the pump piston to move uprelatively slowly and evenly. Fuel flows intothe pump/injector high-pressure chamberfree of air bubbles.
The injection cam has a steep leading edgeand a gradual slope to the trailing edge.
As a result of the steep leading edge, thepump piston is pushed down at highvelocity. A high injection pressure isattained quickly.
SSP209/016
PumpPistonInjection Cam
Roller-TypeRocker Arm
SSP209/017
PumpPiston
Injection Cam
Roller-TypeRocker Arm
20
Pump Injection System
Mixture Formation and
Combustion Requirements
Good mixture formation is a vital factor toensure efficient combustion.
Accordingly, fuel must be injected in thecorrect quantity at the right time and at highpressure. Even minimal deviations can leadto higher levels of pollutant emissions, noisycombustion, or high fuel consumption.
A short firing delay is important for thecombustion sequence of a diesel engine.The firing delay is the period between thestart of fuel injection and the start ofpressure rise in the combustion chamber.If a large fuel quantity is injected during thisperiod, the pressure will rise suddenly andcause loud combustion noise.
Pre-injection phase
To soften the combustion process, a smallamount of fuel is injected at a low pressurebefore the start of the main injection phase.
This is the pre-injection phase. Combustionof this small quantity of fuel causes thepressure and temperature in thecombustion chamber to rise.
This meets the requirements for quickignition of the main injection quantity, thusreducing the firing delay.
The pre-injection phase and the “injectioninterval” between the pre-injection phaseand the main injection phase produce agradual rise in pressure within thecombustion chamber, not a suddenpressure buildup.
The effects of this are low combustionnoise levels and lower nitrogenoxide emissions.
Main injection phase
The key requirement for the main injectionphase is the formation of a good mixture.The aim is to burn the fuel completelyif possible.
The high injection pressure finely atomizesthe fuel so that the fuel and air can mix wellwith one another.
Complete combustion reduces pollutantemissions and ensures high engineefficiency.
End of injection
At the end of the injection process, itis important that the injection pressuredrops quickly and the injector needlecloses quickly.
This prevents fuel at a low injectionpressure and with a large droplet diameterfrom entering the combustion chamber.Fuel does not combust completely undersuch conditions, giving rise to higherpollutant emissions.
Injection curve
The injection curve of the pump injectionsystem largely matches the enginedemands, with low pressures during thepre-injection phase, followed by an“injection interval,” then a rise in pressureduring the main injection phase. Theinjection cycle ends abruptly.
SSP209/101SSP209/100
Inje
ctio
nP
ress
ure
Time
Engine Demand Pump/Injector
21
Pump Injection System
Injection Cycle
High-Pressure Chamber Fills
During the filling phase, the pump pistonmoves upward under the force of thepiston spring and thus increases thevolume of the high-pressure chamber.
The pump/injector solenoid valve isnot activated.
The solenoid valve needle is in itsresting position.
The path is open from the fuel supply lineto the high-pressure chamber.
The fuel pressure in the supply linecauses the fuel to flow into thehigh-pressure chamber.
SolenoidValve Needle
Fuel Supply Line
SSP209/024
Piston Spring
High-PressureChamber
Injector Needle
Fuel Return Line
Pump/InjectorSolenoid Valve
Pump PistonInjection Cam
Roller-TypeRocker Arm
22
Pump Injection System
Pre-Injection Phase Starts
The injection cam pushes the pumppiston down via the roller-type rocker arm.This displaces some of the fuel from thehigh-pressure chamber back into the fuelsupply line.
The Diesel Direct Fuel Injection EngineControl Module J248 initiates the injectioncycle by activating the pump/injectorsolenoid valve.
The solenoid valve needle is pressed intothe valve seat and closes the path fromthe high-pressure chamber to the fuelsupply line.
This initiates a pressure build-up in thehigh-pressure chamber.
At 2,611 psi (18,000 kPa / 180 bar), thepressure is greater than the force of theinjector spring.
The injector needle is lifted from its seatand the pre-injection cycle starts.
SSP209/025
Roller-TypeRocker Arm
Retraction Piston
Injection Cam
Injector Spring
Injector Needle
SolenoidValve Needle
Pump/InjectorSolenoid Valve
Fuel Return Line
Fuel Supply Line
High-PressureChamber
Piston Spring
Pump Piston
23
Pump Injection System
Injector needle damping
During the pre-injection phase, the strokeof the injector needle is dampened by ahydraulic cushion. As a result, it is possibleto meter the injection quantity exactly.
As soon as the damping piston plunges intothe bore in the injector housing, the fuelabove the injector needle can only bedisplaced into the injector spring chamberthrough a leakage gap.
This creates a hydraulic cushion whichlimits the injector needle stroke during thepre-injection phase.
Function
In the first third of the total stroke, theinjector needle is opened undamped.
The pre-injection quantity is injected intothe combustion chamber.
SSP209/036
DampingPiston
HydraulicCushion
Leakage Gap
InjectorHousing
InjectorSpring
InjectorSpringChamber
SSP209/035
UndampedStroke
InjectorHousing
InjectorSpring
InjectorSpringChamber
24
Pump Injection System
Pre-Injection Phase Ends
The pre-injection phase ends immediatelyafter the injector needle opens.
The rising pressure causes the retractionpiston to move downward, thus increasingthe volume of the high-pressure chamber.
The pressure drops momentarily as aresult, and the injector needle closes.
SSP209/026
This ends the pre-injection phase.
The downward movement of the retractionpiston pre-loads the injector spring to agreater extent.
To re-open the injector needle during thesubsequent main injection phase, the fuelpressure must be greater than during thepre-injection phase.
Roller-TypeRocker Arm
Retraction Piston
Injection Cam
Injector Spring
Injector Needle
SolenoidValve Needle
Pump/InjectorSolenoid Valve
Fuel Return Line
Fuel Supply Line
High-PressureChamber
Piston Spring
Pump Piston
25
Pump Injection System
Main Injection Phase Starts
The pressure in the high-pressurechamber rises again shortly after theinjector needle closes.
The pump/injector solenoid valveremains closed and the pump pistonmoves downward.
At approximately 4,351 psi (30,000 kPa /300 bar), the fuel pressure is greaterthan the force exerted by the pre-loadedinjector spring.
The injector needle is again lifted fromits seat and the main injection quantityis injected.
The pressure rises to between 27,121 psi(187,000 kPa / 1,870 bar) and 27,846 psi(192,000 kPa / 1,920 bar) because morefuel is displaced in the high-pressurechamber than can escape through thenozzle holes.
Maximum fuel pressure is achieved atmaximum engine output. This occurs at ahigh engine speed when a large quantity offuel is being injected.
SSP209/027
Roller-TypeRocker Arm
Retraction Piston
Injection Cam
Injector Spring
Injector Needle
SolenoidValve Needle
Fuel Supply Line
High-PressureChamber
Piston Spring
Pump Piston
Pump/InjectorSolenoid Valve
Fuel Return Line
26
Pump Injection System
Main Injection Phase Ends
The injection cycle ends when the DieselDirect Fuel Injection Engine Control ModuleJ248 stops activating the pump/injectorsolenoid valve.
The solenoid valve spring opens the solenoidvalve needle, and the fuel displaced by thepump piston can enter the fuel supply line.
The pressure drops.
The injector needle closes and the injectorspring presses the bypass piston into itsstarting position.
This ends the main injection phase.
Roller-TypeRocker Arm
Injection Cam
Injector Spring
Injector Needle
SolenoidValve Needle
Pump/InjectorSolenoid Valve
Fuel Return Line
Fuel Supply Line
Piston Spring
Pump Piston
SSP209/028
Retraction Piston
SolenoidValve Needle
27
Pump/Injector Fuel Return
The fuel return line in the pump/injector hasthe following functions:
• Cool the pump/injector by flushingfuel from the fuel supply line throughthe pump/injector ducts into the fuelreturn line.
• Discharge leaking fuel at thepump piston.
• Separate vapor bubbles from thepump/injector fuel supply line throughthe restrictors in the fuel return line.
Pump Injection System
SSP209/096
Fuel Supply Line
Leaking FuelPump Piston
Restrictors
Fuel Return Line
Engine Management
28
1.9-Liter TDI Engine EDC 16System Overview
Sensors
Diesel DirectFuel InjectionEngine ControlModule J248
16-PinConnector(DiagnosisConnection)T16
ABS Control Modulewith EDL/ASR/ESP J104
DrivetrainCAN Data Bus
BarometricPressureSensor F96
Additional Signals• Road Speed Signal• Air Conditioner Compressor Ready• CCS Switch• Three-Phase AC Generator Terminal DF
Fuel Temperature Sensor G81
Brake Light Switch FBrake Pedal Switch F47
Clutch Vacuum Vent Valve Switch F36
Manifold Absolute Pressure Sensor G71Intake Air Temperature Sensor G72
Engine Coolant Temperature Sensor G62
Throttle Position Sensor G79Kick Down Switch F8Closed Throttle Position Switch F60
Camshaft Position Sensor G40
Engine Speed Sensor G28
Mass Air Flow Sensor G70
Engine Management
29
SSP209/053
Actuators
Additional Signals• Coolant Auxiliary Heater• Engine Speed• Cooling Fan Run-On• Air Conditioner Compressor Cut-Off• Fuel Consumption Signal
Relay for Pump, Fuel Cooling J445Pump for Fuel Cooler V166
Change-Over Valve for Intake Manifold Flap N239
Wastegate Bypass Regulator Valve N75
EGR Vacuum Regulator Solenoid Valve N18
Glow Plug Indicator Light K29
Valve for Pump/Injector, Cylinder 1 N240Valve for Pump/Injector, Cylinder 2 N241Valve for Pump/Injector, Cylinder 3 N242Valve for Pump/Injector, Cylinder 4 N243
Glow Plugs Q6Glow Plug Relay J52
TransmissionControl ModuleJ217
30
Sensors
Camshaft Position Sensor G40
The Camshaft Position Sensor G40 is aHall-effect sensor.
It is attached to the toothed-belt guardbelow the camshaft gear.
It scans seven teeth on the camshaft sensorwheel attached to the camshaft gear.
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 uses the signal thatthe Camshaft Position Sensor G40generates to determine the relativepositions of the pistons in the cylinderswhen starting the engine.
Effects of signal failure
In the event of Camshaft Position SensorG40 signal failure, the Diesel Direct FuelInjection Engine Control Module J248 usesthe signal that the Engine Speed SensorG28 generates.
Electrical circuit
G40 Camshaft Position Sensor
J248 Diesel Direct Fuel Injection EngineControl Module
J317 Power Supply (Terminal 30, B+) Relay
Engine Management
CamshaftSensor Wheel
SSP209/054
Camshaft PositionSensor G40
SSP209/055
J248
G40
J317S
Engine Management
31
Cylinder recognition when
starting the engine
When starting the engine, the Diesel DirectFuel Injection Engine Control Module J248must determine which cylinder is in thecompression stroke in order to activate thecorrect pump/injector valve. To achieve this,it evaluates the signal generated by theCamshaft Position Sensor G40, whichscans the teeth of the camshaft sensorwheel to determine the camshaft position.
Camshaft sensor wheel
Since the camshaft executes one360-degree revolution per working cycle,there is a tooth for each individual cylinderon the sensor wheel. These teeth arespaced 90 degrees apart.
To differentiate between cylinders, thesensor wheel has an additional tooth withdifferent spacing for each of cylinders1, 2, and 3.
SSP209/094Cylinder 2
Cylinder 1
Cylinder 3
Cylinder 4
90°
Engine Management
32
Function
Each time a tooth passes the CamshaftPosition Sensor G40, a Hall-effect voltageis induced and transmitted to the DieselDirect Fuel Injection Engine ControlModule J248.
Because the teeth are spaced at differentdistances apart, the induced voltage occursat different time intervals.
From this, the Diesel Direct Fuel InjectionEngine Control Module J248 determinesthe relative positions of the cylinders anduses this information to control thesolenoid valves for pump/injectors.
Refer to “Quick-Start Function” (page 34).
SSP209/095a
Signal Pattern, Camshaft Position Sensor G40
90° 90° 90°
Cylinder 1 Cylinder 3 Cylinder 4 Cylinder 2 Cylinder 1
90°
33
Engine Management
Engine Speed Sensor G28
The Engine Speed Sensor G28 is aninductive sensor. It is attached to thecylinder block.
SSP209/056
J248
SSP209/085
Engine speed sensor wheel
The Engine Speed Sensor G28 scans a60-2-2 sensor wheel attached to thecrankshaft. This means that the sensorwheel has 56 teeth with two gaps the widthof two teeth each on its circumference.
These gaps are 180 degrees apart andserve as reference points for determiningthe crankshaft position.
Signal application
The signal generated by the Engine SpeedSensor G28 provides both the engine speedand the exact position of the crankshaft.
The injection point and the injection quantityare calculated using this information.
Effects of signal failure
If the signal of the Engine Speed SensorG28 fails, the engine is switched off.
Electrical circuit
G28 Engine Speed Sensor
J248 Diesel Direct Fuel Injection EngineControl Module
SSP209/057
G28
34
Engine Management
Quick-Start Function
To allow the engine to be started quickly,the Diesel Direct Fuel Injection EngineControl Module J248 evaluates the signalsgenerated by the Camshaft Position SensorG40 and the Engine Speed Sensor G28.
The Diesel Direct Fuel Injection EngineControl Module J248 uses the signal thatthe Camshaft Position Sensor G40generates to determine the relativepositions of the pistons in the cylinderswhen starting the engine.
Because there are two gaps on thecrankshaft sensor wheel, the Diesel DirectFuel Injection Engine Control Module J248receives a usable reference signal from theEngine Speed Sensor G28 after only half aturn of the crankshaft.
Cylinder 1 Cylinder 3 Cylinder 4 Cylinder 2
By interpreting the signals from these twosensors, the Diesel Direct Fuel InjectionEngine Control Module J248 determinesthe position of the crankshaft in relation tothe camshaft and thus the positions of thepistons in the cylinders at an early stage.
With this information, it can activate thecorrect solenoid valve at the proper time toinitiate the injection cycle in the nextcylinder to reach the compression stage.
The quick-start function enables an earlyengine start because synchronization withthe first cylinder is not required.
SSP209/095
Signal Generatedby Engine SpeedSensor G28
SignalGenerated byCamshaft PositionSensor G40
One Crankshaft Rotation
One Camshaft Revolution
Signal Pattern, Camshaft Position Sensor G40
and Engine Speed Sensor G28
35
Engine Management
Fuel Temperature Sensor G81
The Fuel Temperature Sensor G81 islocated in the fuel return line between thefuel pump and the fuel cooler. It determinesthe current temperature of the fuel atthat point.
The Fuel Temperature Sensor G81 has anegative temperature coefficient. Thesensor resistance decreases withincreasing fuel temperature.
Signal application
The signal generated by the FuelTemperature Sensor G81 is used bythe Diesel Direct Fuel Injection EngineControl Module J248 to determinethe fuel temperature.
This signal is needed to calculate thestart of injection point and the injectionquantity so that allowance can be madefor the density of the fuel at differenttemperatures.
This signal is also used to determinethe timing for switching on the fuelcooling pump.
Effects of signal failure
In the event of Fuel Temperature SensorG81 signal failure, the Diesel Direct FuelInjection Engine Control Module J248calculates a substitute value from the signalgenerated by Engine Coolant TemperatureSensor G62.
Electrical circuit
G81 Fuel Temperature Sensor
J248 Diesel Direct Fuel Injection EngineControl Module
SSP209/043
SSP209/058
G81
J248
36
Mass Air Flow Sensor G70
The Mass Air Flow Sensor G70 with reverseflow recognition is located in the intake pipe.It determines the intake air mass.
The opening and closing actions of thevalve produce reverse flows in the inducedair mass in the intake pipe.
The Mass Air Flow Sensor G70recognizes and makes allowance for thereturning air mass in the signal it sendsto the Diesel Direct Fuel Injection EngineControl Module J248.
The air mass is accurately measured.
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 uses the measuredvalues from the Mass Air Flow Sensor G70to calculate the injection quantity and theexhaust gas recirculation rate.
Effects of signal failure
If the signal from the Mass Air Flow SensorG70 fails, the Diesel Direct Fuel InjectionEngine Control Module J248 uses a fixedsubstitute value.
Engine Management
SSP209/044
37
Engine Management
SSP209/60
Engine Coolant Temperature Sensor G62
The Engine Coolant Temperature SensorG62 is located at the coolant connection onthe cylinder head. It sends informationabout the current coolant temperature tothe Diesel Direct Fuel Injection EngineControl Module J248.
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 uses the coolanttemperature as a correction value forcalculating the injection quantity.
Effects of signal failure
If the signal from Engine CoolantTemperature Sensor G62 fails, the DieselDirect Fuel Injection Engine Control ModuleJ248 uses the signal generated by the FuelTemperature Sensor G81 to calculate theinjection quantity.
38
Accelerator Pedal Sensors
The accelerator pedal sensors are integratedinto a single housing and connected to thepedal by mechanical linkage.
• Throttle Position Sensor G79
• Kick Down Switch F8
• Closed Throttle Position Switch F60
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 can recognize theposition of the accelerator pedal fromthis signal.
In vehicles with an automatic transmission,the Kick Down Switch F8 indicates to theDiesel Direct Fuel Injection Engine ControlModule J248 when the driver wantsto accelerate.
Effects of signal failure
Without the signal from Throttle PositionSensor G79, the Diesel Direct Fuel InjectionEngine Control Module J248 is unable torecognize the accelerator pedal position.
The engine will only run at an increasedidling speed.
Engine Management
SSP209/059
39
Engine Management
SSP209/045
Intake Manifold Sensors
The intake manifold sensors are integratedinto a single module and installed in theintake pipe.
• Manifold Absolute Pressure Sensor G71
• Intake Air Temperature Sensor G72
Manifold Absolute Pressure Sensor G71
Signal application
The Manifold Absolute Pressure SensorG71 supplies a signal that is required tocheck the charge pressure (boostpressure).
The Diesel Direct Fuel Injection EngineControl Module J248 compares the actualmeasured value with the setpoint from thecharge pressure map.
If the actual value deviates from thesetpoint, the Diesel Direct Fuel InjectionEngine Control Module J248 adjusts thecharge pressure via the Wastegate BypassRegulator Valve N75.
Effects of signal failure
The charge pressure can no longerbe regulated.
Engine performance drops.
Intake Air Temperature Sensor G72
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 requires the signalgenerated by the Intake Air TemperatureSensor G72 as a correction value forcomputing the charge pressure.
It can then make allowance for the effectof temperature on the density of thecharge air.
Effects of signal failure
If the Intake Air Temperature Sensor G72signal fails, the Diesel Direct Fuel InjectionEngine Control Module J248 uses afixed substitute value to calculate thecharge pressure.
This can result in a drop inengine performance.
40
Engine Management
Barometric Pressure Sensor F96
The Barometric Pressure Sensor F96 islocated inside the Diesel Direct FuelInjection Engine Control Module J248.
Signal application
The Barometric Pressure Sensor F96sends the current ambient air pressure tothe Diesel Direct Fuel Injection EngineControl Module J248.
This value is dependent on the vehicle’sgeographical altitude.
With this signal the Diesel Direct FuelInjection Engine Control Module J248can carry out an altitude correction forcharge pressure control and exhaustgas recirculation.
Effects of signal failure
Black smoke occurs at altitude.
Clutch Vacuum Vent Valve Switch F36
The Clutch Vacuum Vent Valve Switch F36is located at the foot controls on vehicleswith manual transmissions.
Signal application
The Diesel Direct Fuel Injection EngineControl Module J248 determines fromthis signal whether the clutch is engagedor disengaged.
When the clutch is engaged, injectionquantity is reduced briefly to preventengine shudder when shifting gears.
Effects of signal failure
If the signal from the Clutch Vacuum VentValve Switch F36 fails, engine shudder canoccur when shifting gears.
SSP209/061
SSP209/062
Barometric Pressure Sensor F96
41
Engine Management
Brake Pedal Sensors
The brake pedal sensors are integratedinto a single module that is mounted on thebrake pedal bracket.
• Brake Light Switch F
• Brake Pedal Switch F47
Signal application
Both switches supply the Diesel DirectFuel Injection Engine Control Module J248with the “brake activated” signal.
The engine speed is regulated when thebrake is activated for safety reasons,since the Throttle Position Sensor G79could be defective.
Effects of signal failure
If one of the two switches fails, DieselDirect Fuel Injection Engine Control ModuleJ248 reduces the fuel quantity.
Engine performance drops.SSP209/063
42
Engine Management
Cruise control switch
The signal generated by the cruise controlswitch tells the Diesel Direct Fuel InjectionEngine Control Module J248 that the cruisecontrol system has been activated.
Three-phase AC generator terminal DF
The signal supplied by generator terminalDF indicates the load state of the three-phase AC generator to the Diesel DirectFuel Injection Engine Control Module J248.
Depending on available capacity, the DieselDirect Fuel Injection Engine Control ModuleJ248 can switch on one, two, or three GlowPlugs (Coolant) Q7 of the coolant auxiliaryheater via the Relay for Preheating Coolant,Low Heat Output J359 and the Relay forPreheating Coolant, High Heat Output J360.
CAN data bus
The Diesel Direct Fuel Injection EngineControl Module J248, the ABS ControlModule with EDL/ASR/ESP J104, and theTransmission Control Module J217interchange information along aCAN data bus.
Additional Input Signals
Road speed signal
The Diesel Direct Fuel Injection EngineControl Module J248 receives the roadspeed signal from the vehicle speed sensor.
This signal is used to calculate variousfunctions, including cooling fan run-onand engine shudder damping whenshifting gears.
It is also used to check the cruise controlsystem for proper functioning.
Air conditioner compressor ready
The air conditioner switch sends DieselDirect Fuel Injection Engine Control ModuleJ248 a signal indicating that the airconditioner compressor will shortly beswitched on.
This enables the Diesel Direct Fuel InjectionEngine Control Module J248 to increasethe engine idle speed before the airconditioner compressor is switched on toprevent a sharp drop in engine speed whenthe compressor starts up.
SSP209/083
43
Engine Management
Actuators
Pump/Injector Solenoid Valves
The 1.9-liter TDI engine with the new pumpinjection system uses four pump/injectorsolenoid valves:
• Valve for Pump/Injector, Cylinder 1 N240
• Valve for Pump/Injector, Cylinder 2 N241
• Valve for Pump/Injector, Cylinder 3 N242
• Valve for Pump/Injector, Cylinder 4 N243
The pump/injector solenoid valves areattached to their pump/injectors with acap nut.
The Diesel Direct Fuel Injection EngineControl Module J248 regulates the start ofinjection points and injection quantities ofthe pump/injectors by activating theirsolenoid valves at the appropriate times.
Start of injection point
As soon as the Diesel Direct Fuel InjectionEngine Control Module J248 activates apump/injector solenoid valve, the magneticcoil presses the solenoid valve needledown into the valve seat and closes off thepath from the fuel supply line to the high-pressure chamber of the pump/injector.
The injection cycle then begins.
Injection quantity
The injection quantity is determined by thelength of time that the solenoid valve isactivated.
Fuel is injected into the combustionchamber as long as the pump/injectorsolenoid valve is closed.
SSP209/064
44
Effects of failure
If a pump/injector solenoid valve fails, theengine will not run smoothly andperformance will be reduced.
The pump/injector solenoid valve has a dualsafety function.
If the valve stays open, pressure cannotbuild up in the pump/injector.
If the valve stays closed, the high-pressurechamber of the pump/injector can no longerbe filled.
In either case, no fuel is injected intothe cylinders.
Electrical circuit
J248 Diesel Direct Fuel Injection EngineControl Module
N240 Valve for Pump/Injector, Cylinder 1
N241 Valve for Pump/Injector, Cylinder 2
N242 Valve for Pump/Injector, Cylinder 3
N243 Valve for Pump/Injector, Cylinder 4
Engine Management
N240 N241 N242 N243
J248
SSP209/065
45
Engine Management
Pump/injector solenoid valve monitoring
The Diesel Direct Fuel Injection EngineControl Module J248 monitors the electricalcurrent that actuates the solenoid valves atthe pump/injectors.
This provides feedback to the DieselDirect Fuel Injection Engine Control ModuleJ248 of the actual point in time wheninjection begins.
The Diesel Direct Fuel Injection EngineControl Module J248 uses this feedback toregulate the beginning of injection periods(BIP) during subsequent combustioncycles and to detect malfunctions of thepump/injector solenoid valves.
Start of injection is initiated when thepump/injector solenoid valve is actuated.
Actuating current applied to a pump/injectorsolenoid valve creates a magnetic field.As the applied current intensity increases,the valve closes; the magnetic coil pressesthe solenoid valve needle into its valveseat. This closes off the path from thefuel supply line to the pump/injectorhigh-pressure chamber and the injectionperiod begins.
As the solenoid valve needle contacts itsvalve seat, the distinctive signature of analternately dropping and rising current flowis detected by the Diesel Direct FuelInjection Engine Control Module J248. Thispoint is called the beginning of injectionperiod (BIP). It indicates the completeclosure of the pump/injector solenoid valveand the starting point of fuel delivery.
“Start of injection” is the pointin time when the actuatingcurrent to the pump/injectorsolenoid valve is initiated.
”Beginning of injection
period (BIP)” is the point in timewhen the solenoid valve needlecontacts the valve seat.
With the solenoid valve closed, a holdingcurrent is maintained at a constant level bythe Diesel Direct Fuel Injection EngineControl Module J248 to keep it closed. Oncethe required time period for fuel delivery haselapsed, the actuating current is switchedoff and the solenoid valve opens.
SSP209/097
Current Pattern - Pump/Injector Solenoid Valve
Beginning ofInjection Period(BIP) (ValveCloses)
Time
Sol
enoi
d Va
lve
Act
uatin
gC
urre
nt In
tens
ity
End ofValveActuation
Start ofValveActuation(Start ofInjection)
PickupCurrent
ControlLimit
HoldingCurrent
46
Engine Management
The actual moment at which the pump/injector solenoid valve closes (BIP) is usedby the Diesel Direct Fuel Injection EngineControl Module J248 to calculate the pointof actuation for the next injection period.
If the actual BIP deviates from the mappeddetails stored in the Diesel Direct FuelInjection Engine Control Module J248, it willcorrect the point of valve actuation (start ofinjection) for the next combustion cycle.
To detect pump/injector solenoid valvefaults, the Diesel Direct Fuel InjectionEngine Control Module J248 evaluates theBIP position from the current flow pattern.If there are no faults, BIP will be within thecontrol limit. If this is not the case, thevalve is faulty.
Effects of failure
If a fault is detected at the solenoid valve,start of injection is determined based onfixed values from the control map.
Regulation is no longer possible andperformance is impaired.
Example
If there is air inside the pump/injector, thesolenoid valve needle has a low resistancewhen it closes. The valve closes quicklyand the BIP is earlier than expected.
In this case, the self-diagnosis indicates thefollowing fault message:
“BIP below control limit”
47
Engine Management
Change-Over Valve for
Intake Manifold Flap N239
The Change-Over Valve for IntakeManifold Flap N239 is located in theengine compartment, in the vicinity ofthe Mass Air Flow Sensor G70.
It switches the vacuum for actuating theintake manifold flap in the intake pipe.This stops the engine shuddering whenthe ignition is turned off.
Diesel engines have a highcompression ratio.
The engine shudders when the ignition isturned off because of the high compressionpressure of the induced air.
The intake manifold flap interrupts the airsupply when the engine is turned off. Littleair is compressed and the engine runssoftly to a halt.
Function
If the engine is turned off, the Diesel DirectFuel Injection Engine Control Module J248sends a signal to the Change-Over Valve forIntake Manifold Flap N239, which thenswitches the vacuum for the vacuum motor.
The vacuum motor closes the intakemanifold flap.
2SSP09/068
SSP209/069
0 I
48
Engine Management
Effects of failure
If the Change-Over Valve for IntakeManifold Flap N239 fails, the intakemanifold flap stays open.
The tendency of the engine to shudderwhen switched off will increase.
Electrical circuit
J217 Transmission Control Module
J248 Diesel Direct Fuel Injection EngineControl Module
N239 Change-Over Valve for IntakeManifold Flap
S Fuse
S
J317
N239
J248
SSP209/070
49
Engine Management
Relay for Pump, Fuel Cooling J445
The Relay for Pump, Fuel Cooling J445 islocated on the engine control modulemounting bracket.
It is activated by the Diesel Direct FuelInjection Engine Control Module J248 at afuel temperature of 158°F (70°C) andswitches the working current for the Pumpfor Fuel Cooler V166.
Effects of failure
If the Relay for Pump, Fuel Cooling J445fails, the heated fuel flowing back fromthe pump/injectors to the fuel tank will notbe cooled.
The fuel tank and the Sender forFuel Gage G can be damaged.
Electrical circuit
J248 Diesel Direct Fuel InjectionEngine Control Module
J317 Power Supply (Terminal 30, B+) Relay
J445 Relay for Pump, Fuel Cooling
S Fuse
V166 Pump for Fuel Cooler
The Output Check Diagnosisfunction in the self-diagnosis canbe used to check whether theRelay for Pump, Fuel CoolingJ445 has been activated by theDiesel Direct Fuel InjectionEngine Control Module J248.
SSP209/071
SSP209/072
A/+
S
S
J445
J248
J317
V166M
50
Engine Management
Wastegate Bypass Regulator Valve N75
The engine has a variable turbine geometryfor optimally adapting the charge pressureto the actual driving conditions.
To regulate the charge pressure, thevacuum in the vacuum unit for turbochargervane adjustment is set depending on thepulse duty factor.
The Wastegate Bypass Regulator ValveN75 is activated by the Diesel Direct FuelInjection Engine Control Module J248.
Effects of failure
If the Wastegate Bypass Regulator ValveN75 fails, the vacuum unit reverts toatmospheric pressure.
As a result, charge pressure is lower andengine performance is impaired.
SSP209/075
51
Engine Management
SSP209/075
EGR Vacuum Regulator
Solenoid Valve N18
The EGR Vacuum Regulator SolenoidValve N18 enables the exhaust gasrecirculation system to mix a portion ofthe exhaust gases with the fresh airsupplied to the engine.
This lowers the combustion temperatureand reduces the formation of oxides ofnitrogen.
To control the quantity of exhaust gasesreturned for combustion, the Diesel DirectFuel Injection Engine Control Module J248activates the EGR Vacuum RegulatorSolenoid Valve N18 with duty cycles basedon internal control maps.
Effects of failure
Engine performance is lower and exhaustgas recirculation is not assured.
Glow Plug Indicator Light K29
The Glow Plug Indicator Light K29 islocated in the instrument cluster.
It has the following tasks:
• It signals to the driver that the pre-starting glow phase is in progress. In thiscase, it is lit continuously.
• If a component with self-diagnosticcapability becomes faulty, the warninglamp flashes.
Effects of failure
The Glow Plug Indicator Light K29 comeson and does not flash.
A fault message is stored to thefault memory.
SSP209/077
52
Additional Output Signals
Engine Management
Engine speed
This signal provides information onengine speed for the tachometer in theinstrument cluster.
Cooling fan run-on
The run-on period of the cooling fan iscontrolled according to a characteristiccurve stored in the Diesel Direct FuelInjection Engine Control Module J248.
It is calculated from the current coolanttemperature and the load state of theengine during the previous driving cycle.The Diesel Direct Fuel Injection EngineControl Module J248 uses this signal toactivate the cooling fan relay.
Air conditioner compressor cut-off
To reduce engine load, the Diesel DirectFuel Injection Engine Control Module J248switches the air conditioner compressor offunder the following conditions:
• After every starting cycle (forapproximately six seconds).
• During rapid acceleration from lowengine speeds.
• At coolant temperatures in excess of248°F (120°C).
• In the emergency running program.
Fuel consumption signal
This signal provides information on fuelconsumption for the multifunctional displayin the instrument cluster.
Coolant auxiliary heater
Thanks to its high efficiency, the 1.9-literTDI engine with pump injection systemdevelops so little heat that sufficient heatoutput may not be available incertain circumstances.
In countries with cold climates, an electricalauxiliary heater is used to heat the coolantat low temperatures.
The coolant auxiliary heater is comprised ofthree Glow Plugs (Coolant) Q7. They areinstalled to the coolant connection on thecylinder head.
The Diesel Direct Fuel Injection EngineControl Module J248 uses the coolantauxiliary heater signal to activate the relaysfor low and high heat output.
Either one, two, or all three Glow Plugs(Coolant) Q7 are switched on depending onthe available capacity of the three-phaseAC generator.
SSP209/084
53
Glow Plug System
Glow Plug System
The glow plug system makes it easierto start the engine at low outsidetemperatures. It is activated by theDiesel Direct Fuel Injection Engine ControlModule J248 at coolant temperaturesbelow 48°F (9°C).
The Glow Plug Relay J52 is activated by theDiesel Direct Fuel Injection Engine ControlModule J248. The Glow Plug Relay J52then switches on the working current forthe Glow Plugs Q6.
Function
The glow process is divided into twophases, the glow period and the extendedglow period.
Glow Period
The glow plugs are activated when theignition is switched on and outsidetemperature is below 48°F (9°C). The GlowPlug Indicator Light K29 will light up.
Once the glow plug period has elapsed, theGlow Plug Indicator Light K29 will go outand the engine can be started.
Extended Glow Period
The extended glow period takes placewhenever the engine is started, regardlessof whether or not it is preceded by a glowperiod.
This reduces combustion noise, improvesidling quality and reduces hydrocarbonemission.
The extended glow phase lasts no morethan four minutes and is interrupted whenthe engine speed rises above 2500 rpm.
Glow Plug System Overview
SSP209/099
Engine CoolantTemperatureSensor G62
Glow PlugIndicatorLight K29
Glow PlugRelay J52
Glow Plugs Q6
Diesel Direct Fuel InjectionEngine Control Module J248
Engine SpeedSensor G28
54
Functional Diagram
EDC 16 Functional Diagramfor 1.9-Liter TDI Engine
Components
E45 Cruise Control Switch
F Brake Light SwitchF8 Kick Down SwitchF36 Clutch Vacuum Vent Valve SwitchF47 Brake Pedal SwitchF60 Closed Throttle Position Switch
G28 Engine Speed SensorG40 Camshaft Position SensorG62 Engine Coolant Temperature SensorG70 Mass Air Flow SensorG71 Manifold Absolute Pressure SensorG72 Intake Air Temperature SensorG79 Throttle Position SensorG81 Fuel Temperature Sensor
J52 Glow Plug RelayJ248 Diesel Direct Fuel Injection Engine
Control ModuleJ317 Power Supply (Terminal 30, B+) RelayJ359 Relay for Preheating Coolant, Low
Heat OutputJ360 Relay for Preheating Coolant, High
Heat OutputJ445 Relay for Pump, Fuel Cooling
N18 EGR Vacuum Regulator Solenoid ValveN75 Wastegate Bypass Regulator ValveN239 Change-Over Valve for Intake Manifold FlapN240 Valve for Pump/Injector, Cylinder 1N241 Valve for Pump/Injector, Cylinder 2N242 Valve for Pump/Injector, Cylinder 3N243 Valve for Pump/Injector, Cylinder 4
Q6 Glow Plugs (Engine)Q7 Glow Plugs (Coolant)
S Fuse
V166 Pump for Fuel Cooler
Additional Signals
A Brake Lights
B Fuel Consumption Signal
C Engine Speed Signal
D Air Conditioner Compressor Cut-Off
E Air Conditioner Compressor Readiness
F Road Speed Signal
G Cruise Control Switch Voltage Supply
H Cooling Fan Run-On
K Diagnosis and Immobilizer Wire
L Glow Period Control
M Drivetrain CAN Data Bus (Low)
N Drivetrain CAN Data Bus (High)
O Three-Phase AC Generator Terminal DF
Color Coding
Input Signal
Output Signal
Positive
Ground
CAN Data Bus
Bi-directional
55
Functional Diagram
SSP209/080
3015
31 31
31
B D G
J 317S S S S
N239 N75 N18Q7 Q7
J360
A/+
G70F60/F8 G79
G28
G81
F F47
E45
G62F36
J52
A/+
Q6
G72
C
S
G71
S
S
S
N240 N241 N242 N243
S
G40
E
F
V166
J445
J359
A
in out
J248
HK
L
M
N
O
M
56
Service
Self-Diagnosis
The following functions can be read outusing the Vehicle Diagnosis, Test andInformation System VAS 5051:
01 Interrogate control unit version
02 Interrogate fault memory
03 Actuator diagnosis
04 Basic adjustment
05 Erase fault memory
06 End of output
07 Encode control unit
08 Read measured value block
Function 02 – Interrogate fault memory
The color coded components arestored to the fault memory by theself-diagnosis function.
SSP209/082
SSP209/081
N240, N241,N242, N244F96
J248
J104
V166
Q6
J445
N75
N239
N18
K29
J217
G81
G62
G79F8F60
G40
G28
G70 J52
G71G72
FF47
57
Service
Pump/Injector Adjustment
After installing a pump/injector, theminimum clearance between the base ofthe high-pressure chamber and the pumppiston must be adjusted at the pump/injector adjusting screw.
This adjustment prevents the pump pistonfrom knocking against the base of the high-pressure chamber due to heat expansion.
For a complete description ofthis adjustment procedure,refer to the Repair Manual.
SSP209/098
High-PressureChamber
MinimumClearance
Pump Piston
Ball Pin
Adjusting Screw
Injection Cam
Roller-TypeRocker Arm
58
Service
Special Tools
Marking Plate
T 10008
Holds the hydraulic toothed belt tensionerin place when installing and removing thetoothed belt.
Crankshaft Sealing Ring
Assembly Fixture
T 10053
Guide sleeve and compression sleeve forinstalling the crankshaft sealing ring.
Camshaft Gear Puller
T 10052
Camshaft gear removal from the taperedend of the camshaft.
Camshaft Gear Counter-Holder
T 10051
Camshaft gear installation.
Crankshaft Stop
T 10050
Holds the crankshaft in place atthe crankshaft gear when adjustingthe port timing.
SSP209/090a
SSP209/090b
SSP209/090c
SSP209/090d
SSP209/090e
59
Service
Socket Insert
T 10054
Pump/injector clamping block fastenerinstallation.
Pressure Gauge
VAS 5187
Fuel pressure measurement at the supplyline to the fuel pump.
Shackle
T 10059
This shackle is used to remove and installthe engine in the Passat. The engine ismoved into position using this shackle incombination with lifting gear 2024A.
Pump/Injector Puller
T 10055
Pump/injector removal from thecylinder head.
Pump/Injector O-Ring Assembly Sleeves
T 10056
O-ring installation on the pump/injectors.
SSP209/090f
SSP209/090g
SSP209/090h
SSP209/090k
SSP209/090i
60
Notes
61
Knowledge Assessment
An on-line Knowledge Assessment (exam) is available for this Self-Study Program.
The Knowledge Assessment may or may not be required for Certification.
You can find this Knowledge Assessment at:
www.vwwebsource.com
From the vwwebsource.com Homepage, do the following:
– Click on the Certification tab
– Type the course number in the Search box
– Click “Go!” and wait until the screen refreshes
– Click “Start” to begin the Assessment
For Assistance, please call:
Certification Program Headquarters
1 – 877 – CU4 – CERT(1 – 877 – 284 – 2378)
(8:00 a.m. to 8:00 p.m. EST)
Or, E-Mail:
Volkswagen of America, Inc.3800 Hamlin RoadAuburn Hills, MI 48326Printed in U.S.A.October 2003