.<br><br> . . .30 · Performance diagram .<br><br> . . .<br><br> . . .<br><br> . . .<br><br> . . .31 · Specifications .<br><br> . . .<br><br> . . .<br><br> . . .<br><br> . . .<br><br> . . .<br><br> . . .<br><br> .32 Detailed instructions regarding testing, adjustment and repair can be found in the Workshop Manual "Volkswagen Industrial Engine". Contents 3 In the direct injection engine, diesel fuel is injected directly into the main combustion chamber. This results in more efficient combustion and lower consumption.<br><br> The intake port, pistons and injectors have been designed specifically to optimise the combustion process with respect to noise emission and running characteristics. Inlet swirl port The intake port is shaped in such a way that it induces a swirling movement of the intake air and, as a result, produces greater turbulence in the combustion chamber and piston recess. Piston recess The shape of the piston recess has been opti- mised specially for this engine.<br><br> 5-hole injector The fuel is injected into the piston recess in two stages and is ignited by the hot air. The two-stage injection process avoids a sharp pressure rise. Combustion process 4 Two-spring injector holder To minimise the combustion noise level in the diesel engine and keep mechanical load low, it is necessary for the pressure to rise gently in the combustion chamber.<br><br> In the case of chamber-type diesel engines, this gentle rise in pressure is achieved, first, by injecting fuel into the pre-chamber or the swirl chamber and, secondly, by using pintle-type injectors. Also, the fuel should be injected gradually, not all at once. A two-spring injector holder has been developed for the 1.9-ltr.<br><br> direct injection engine. This injector holder, a key factor contributing to the engine's "soft" combus- tion characteristic, allows fuel to be injected in two stages. The injector is designed as a five-hole nozzle.<br><br> Function Two springs with different thicknesses are integrated in the injector holder. The springs have been adapted in such a way that the injector needle is only lifted against the force of the first spring when injection starts. A small quantity of fuel is pre-injected through the small gap which appears at low pressure.<br><br> This pre-injection cycle produces a gentle rise in the combustion pressure and creates the conditions for igniting the main fuel quantity. As the injection pump delivers more fuel than can actually flow through the small gap, the pressure in the injector rises. The force of the second spring is overcome, and the injector needle is lifted further.<br><br> The main injection cycle now follows at a higher injection pressure. Injector needle Injector needle Spring 1 Stroke 2 Stroke 1 Stroke 1+2 Spring 2 5 The injector of the 3rd cylinder is equipped with a needle lift sender (G80) for regis- tering the point of commencement of injection. The sender signals the actual opening time of the injector to the control unit.<br><br> This signal provides the control unit with feedback on whether the point of commence- ment of fuel injection conforms to the map. Function Needle lift sender G80 is a solenoid and is supplied with a constant current by the control unit. This produces a magnetic field.<br><br> A pressure pin inside the sole- noid forms an extension to the end of the injector needle. The movement of the injector nee- dle alters the magnetic field and causes distortion of the DC voltage applied to the sole- noid. The control unit calculates the actual point of commencement of fuel injection from the time difference between the needle lift pulse and the TDC signal supplied by the engine speed sender.<br><br> At the same time, the system compares the actual point of commencement of injection with the setpoint stored in the control unit and corrects any deviations from the setpoint. Substitute function If the needle lift sender fails, an emergency running program is started. In this pro- gram, the commencement of fuel injection is controlled according to fixed setpoints as defined in a map.<br><br> The injection quantity reduced in addition. Needle Lift Sender Solenoid Pressure pin Injector holder 6 The task of the air-mass flow meter is to measure the fresh air mass supplied to the engine. This fresh air mass is used to calculate the exhaust gas recirculation rate and the permissible injection quantity.<br><br> Air-mass flow meter Air-mass flow meter Function A heated surface, the hot film, is regulated to a constant temperature. The intake air cools the hot film as it flows past. The current serves as a measure of the intake air mass necessary to keep the tem- perature of the hot film constant.<br><br> Substitute function If the air-mass flow meter fails, the control unit defaults a fixed air mass value. This fixed value is calculated such that a reduction in engine performance can only occur in the part-throttle range. Advantages of hot-film air mass metering ?<br><br> Air-mass data can be acquired without additional air pressure and temperature sensors ? Reduced flow resistance compared to sensor flap air-flow metering ? It is no longer necessary to burn off the hot wire as in the hot wire air-mass flow meter.<br><br> Hot film 7 Modulating piston movement sender G149 supplies the control unit with information on the momentary position of the quantity adjuster in the injection pump. The injected fuel quantity is calculated from this information. Sender G149 is a non-contact sensor for measuring the angle of rotation.<br><br> It is attached to the eccentric shaft of the quantity adjuster. Function An alternating magnetic field is produced in a specially shaped iron core by AC volt- age. A metal ring attached to the eccentric shaft moves along the iron core and influ- ences this magnetic field.<br><br> The change in the magnetic field is evaluated electronical- ly in the control unit and indicates the position of the quantity adjuster. Substitute function If the control unit does not receive a signal from the sender for modulating piston movement, the engine is turned off for safety reasons. The new non-contact sender offers the following advantages: ?<br><br> High wear resistance ? High interference immunity ? Low susceptibility to temperature fluctuation Modulating Piston Movement Sender Iron core Distributor injection pump Fuel temperature sensor G81 Stationary metal ring Eccentric shaft Movable metal ring Coil with AC voltage SSP 153/09 8 Exhaust gas recirculation valve N18 Air-mass flow meter G70 Injector with needle lift sender G80 Distributor injection pump Coolant temperature sender G6 Intake manifold pressure sender Solenoid valve for charge pressure control N75 EGR valve Hose connection Air-mass flow meter 9 Engine speed sender G28 Intake manifold temperature sensor G72 ntrol unit J248 To optimise engine performance with respect to torque delivery, consumption and emission in every operating situation, the EDC control unit refers to 25 maps and characteristic curves.<br><br> Sensors supply the control unit with information regarding the vehicle's momentary operating state. 10 System overview Needle lift sender G80 Engine speed sender G28 Air-mass flow meter G70 Coolant temperature sender G62 Intake manifold temperature sensor G72 Clutch pedal switch F36 Brake switch F Brake pedal switch F47 Modulating piston movement sensor G149 Intake manifold pressure sender Auxiliary signals Diagnostic connector Fuel temperature sen- der G81 Accelerator position sender G79 EDC control unit J248 Note: The self-diagnosis monitors all the com- ponents above. Sensors After the information supplied by the sensors has been evaluated, the control unit sends signaIs to the final control elements (actuators).<br><br> Injection quantity, com- mencement of injection, charge pressure and exhaust gas recirculation are moni- tored and regulated in this way. The EDC control unit also assumes the tasks of controlling the glow plug system, the auxiliary heater and the cruise control system. 11 Glow plug warning lamp Fault warning lamp K29 Exhaust gas recirculation valve N18 Solenoid valve for charge pressure control N75 quantity adjuster N146 Fuel cut off valve N109 Commencement of injection valve N108 Auxiliary signals Actuators SSP 153/11 12 The 1.9-ltr.<br><br> TDI engine meters the fuel quantity electronically. The correct quantity is determined in the EDC control unit using the sensor informa- tion as detailed below, and a signal is sent to the quantity adjuster N146 in the injec- tion pump. There is no mechanical link between the accelerator pedal and the injec- tion pump.<br><br> To avoid black exhaust, the injection quantity is limited via a smoke characteristic curve in order to avoid black smoke. Fuel regulation Fuel temperature sender G81 Overview EDC control unit J248 Accelerator position sender G79 Coolant temperature sender G62 Air-mass flow meter G70 Engine speed sender G28 Secondary influencing factors Quantity adjuster N146 Modulating piston movement sender G149 13 Pedal position determined by G79 A decisive factor for the injection quantity is the accelera- tor pedal position, i.e. the driver input.<br><br> The accelerator position sender is a sliding contact poten- tiometer and includes an idling switch and a kick-down switch (refer to Function Diagram). From these signals, the control unit calculates the necessary fuel quantity using additional parameters. Substitute function If a fault occurs, the engine runs at a higher idling speed so that the customer can reach the next workshop.<br><br> The accelerator position sender is then deactivated. Fuel temperature as determined by G81 and coolant temperature determined by G62 The control unit calculates the quantity of fuel to be inject- ed. To make a precise calculation, allowance must be made for the coolant temperature and the density of the diesel fuel.<br><br> The temperature of the fuel is therefore deter- mined. Substitute function for G81 and G62 If one these signals is missing, or both, the coolant and fuel temperatures are calculated with stored substitute values. Engine speed as determined by G28 The engine speed is one of the main factors which the control unit processes in order to calculate the injection quantity.<br><br> Substitute function If the engine speed sender is faulty, an emergency run- ning program is activated. The needle lift sender G80 supplies a substitute engine speed signal for this pur- pose. The injection quantity is reduced, the commencement of fuel injection is controlled and the charge pressure control is switched off during emergency operation.<br><br> If the substitute engine speed signal of G80 fails as well, the engine is turned off. Main influencing factors SSP 153/13 SSP 153/14 SSP 153/15 SSP 153/16 14 Main influencing factors Air mass determined by G70 The air-mass flow meter determines the intake air mass. A smoke map stored in the control unit limits the injection quantity if the induced air mass is too low for smoke-free combustion.<br><br> Substitute function If this signal fails, an emergency program is activated (refer to page 10). Smoke map The permissible injection quantity is determined using the smoke map stored in the control unit. If the air mass is too low, the injection quantity is limited to the extent that no black smoke occurs.<br><br> Modulating piston movement determined by G149 To check the quantity adjuster and to calculate the fuel quantity, the control unit requires feedback on the actual quantity of fuel injected. Sender G149 is permanently linked to the eccentric shaft of the quantity adjuster. It signals the position of the shaft to the control unit, and thus the exact position of the modulating piston.<br><br> Substitute function If the sender fails, the engine is turned off for safety reasons. Fuel regulation Fuel mass Air mass Engine speed SSP 153/17 SSP 153/18 SSP 153/19 15 Secondary influencing factors ( as required) Clutch pedal position determined by F36 Engine shudder suppression is a convenience function of the quantity control. To suppress engine shudder, the control unit needs to know whether the clutch is engaged or disengaged.<br><br> When the clutch is engaged, the injection quantity is briefly reduced. Brake pedal position determined by F and F47 The switch supplies the "brake actuated" signal (redun- dant system) for safety reasons. This is monitored by the control unit.<br><br> In addition, the two switches use these signals to check the accelerator posi- tion sender (plausibility). This prevents the brake being applied at full throttle for example. Substitute function If one of the two switches fails or if the switches are not set identically, the system activates an emergency run- ning program which intervenes in fuel regulation.<br><br> Note: The two switches must be set in such a way that their shift points are identical. A precise adjustment according to the Workshop Manual is therefore necessary. SSP 153/21 SSP 153/20 16 Fuel quantity control Function EDC control unit The EDC control unit process- es the incoming information.<br><br> From this, it calculates the nec- essary injection quantity and sends control signals to the quantity adjuster. Quantity adjuster N146 The quantity adjuster is inte- grated in the distributor injec- tion pump. The task of the quantity adjuster is to generate the cor- rect injection quantity from the control signals.<br><br> The quantity adjuster is a solenoid, a type of electric motor which adjusts the posi- tion of the modulating piston via an eccentric shaft and thus regulates the fuel quan- tity continuously from zero to max. delivery rate. Modulating piston Eccentric shaft Quantity adjuster SSP 153/22 17 The point of commencement of fuel injection influences various engine characteris- tics, such as starting response, fuel consumption and finally, exhaust emissions.<br><br> The task of the injection commencement control is to determine the correct point in time for fuel delivery. The EDC control unit calculates the commencement of injection depending on the influencing factors as detailed below, and issues the corresponding output command to the commencement of injection valve N108 in the injection pump. Overview Injection commencement control EDC control unit J248 Engine speed sender G28 Coolant temperature sender G62 Needle lift sender G80 Calculated fuel mass Commencement of injec- tion valve N108 SSP 153/23 18 Injection commencement control Influencing factors Commencement of injection map A commencement of injection map is stored in the control unit.<br><br> It essentially makes allowance for the engine speed and the fuel quantity to be injected. As a correcting parameter, the coolant temperature also has a bearing on the commencement of injection. The map was determined empirically and represents an optimal compromise between good running characteristics and emission behaviour.<br><br> Calculated fuel mass The point of commencement of injection must be brought forward with increasing injection quantity and engine speed because the injection cycle takes longer. The fuel mass to be injected was calculated by the control unit (refer to chapter "Fuel regulation"). This theoretical value is used in the commencement of injection map.<br><br> Fuel mass Commencement of injection Engine speed SSP 153/24 19 TDC signal and engine speed determined by G28 The engine speed sender, in co-operation with the sender wheel on the crankshaft, supplies a TDC signal to the control unit for each cylinder. Substitute function If engine speed sender G28 is defective, the system activates an emergency running program for which needle lift sender G80 supplies a substitute engine speed signal. In emergency running mode, commencement of fuel injection is controlled in an open loop only (as opposed to a closed con- trol loop), injection quantity is reduced and the charge pressure control is switched off.<br><br> If the substitute engine speed signal also fails, the engine is turned off. Coolant temperature as determined by G62 To compensate for the longer firing delay when the engine is cold, the injection cycle must be advanced. The temperature signal corrects the map accordingly.<br><br> Substitute function If the temperature sender fails, a fixed coolant temperature is defaulted. Point of commencement of injection determined by G80 From the signal supplied by the needle lift sender, the control unit recognises the actual point of commencement of fuel injection and compares this with the setpoint as defined in the commencement of injection map. If deviations from the setpoint occur, the point of commence- ment of injection is corrected via valve N108.<br><br> Substitute function If the signal is missing, no feedback is provided regarding the commence- ment of injection. The system activates an emergency running program in which the commencement of injection is only just controlled. The injection quantity is limited at the same time.<br><br> SSP 153/15 SSP 153/25 20 Injection timing device (schematic diagram) To provide a better overview, the commencement of injection valve N108 is shown here rotated through 90°. The diagram shows the point of commencement of fuel injection adjusted towards "advance". The mechanical injection timing device in the distributor injection pump operates using the speed-dependent fuel pressure inside the pump.<br><br> The injection timing devices works by selectively adjusting the pressure acting on the non- spring-loaded side of the injection timing piston. The pressure is adjusted by means of defined pulse duty factors which are used to control commencement of injection valve N108, i.e. an exact point of commencement of fuel injection is assigned to each pulse duty factor.<br><br> In this way it is possible to continuously regulate the point of commencement of fuel injection between max. advance and max. retard.<br><br> Injection commencement control Fuel pressure inside the pump advance retard To suction side of rotary vane pump Spring Injection timing piston Commencement of injection valve 108 Pressure roller Bolt SSP 153/26 21 EDC control unit From the incoming values, the EDC control unit calculates the setpoint for injection com- mencement and sends a corresponding pulse duty factor to commencement of injection valve N108. Commencement of injection valve N108 The valve converts the pulse duty factor into a change in control pressure which acts on the non-spring-loaded side of the injection timing piston. Substitute function for N108 If the valve fails, the point of commencement of injection is no longer regulated.<br><br> Instead it is permanently defaulted. Lifting plate Pressure roller Injection timing piston Commencement of injection valve N108 22 The exhaust gas recirculation (EGR) system is designed to reduce pollutant emis- sions in the exhaust gas. The direct injection process uses higher combustion temperatures than the chamber process.<br><br> The formation of nitrogen oxides (NOx) increases with higher tempera- tures, provided that sufficient excess air is available. The EGR valve adds a fraction of the exhaust gases to the fresh air supplied to the engine. This reduces the oxygen content in the combustion chamber and slows down NOx formation.<br><br> The exhaust gas recirculation rates are, however, limited by a rise in hydrocarbon (HC), carbon dioxide (CO) and particle emissions. Regulation of exhaust gas recirculation (schematic diagram) Exhaust gas recirculation Exhaust gas Control pressure Electrical signals Air-mass flow meter G70 EDC control unit Atmospheric pressure Vacuum supply Exhaust gas recircula- tion valve N18 EGR valve Charge air cooler Vacuum Atmospheric pressure Intake manifold pressure SSP 153/27 23 Function EGR map An EGR map is stored in the control unit. It contains the necessary air mass for every operating point of the engine; this is dependent on engine speed, injection quantity and engine temperature.<br><br> The control unit recognises from the air-mass flow meter signal whether the intake air mass is too high for the vehicle in its momentary operating state. To compensate for any deviation, more exhaust gas is supplied as required. If the supplied exhaust gas quantity is too high, the intake air mass decreases.<br><br> The control unit then reduces the proportion of the exhaust gases. EGR valve The EGR valve is mounted in a connecting duct between the exhaust gas and the intake pipe. When the valve is subjected to a vacuum, it opens and allows exhaust gas to enter the fresh air flow.<br><br> Exhaust gas recirculation valve N18 Valve N18 converts the signals supplied by the control units into a control vacuum for the EGR valve. It is supplied by the engine's vacuum pump and is opened by signals from the control unit. The pulse duty factor of these signals defines the vacuum which is admitted to the EGR valve.<br><br> Fuel regulation Air mass Fuel mass Engine speed SSP 153/28 SSP 153/30 SSP 153/29 24 The solenoid valve for charge pressure control N75 applies pressure to the charge pressure control valve on the exhaust gas turbocharger (waste gate). Valve N75 receives electrical signals (pulse duty factor) from the EDC control unit. Charge pressure is thus regulated according to a characteristic map.<br><br> Feedback on the actual pressure in the intake pipe is provided along a hose con- nection routed from the intake pipe to a sensor in the control unit. If a deviation from the setpoint occurs, the pressure is corrected accordingly. The charge pressure is also corrected in the control unit by the intake pipe tempera- ture to make allowance for the effect of temperature on the density of the charge air.<br><br> To ensure that the air mass supplied to the engine stays almost constant, the charge pressure specified map is corrected in dependence on the air pressure using the information supplied by the altitude sender F96. The charge pressure is reduced above an altitude of approx. 1500 m to prevent the turbocharger overspeeding in excessively thin air.<br><br> Charge pressure control (schematic diagram) Charge pressure control Atmospheric pressure Intake manifold pressure Intake manifold pressure sender Intake manifold temperature sensor G72 EDC control unit Charge air cooler Solenoid valve for charge pressure control N75 Charge pressure control valve Exhaust gas Control pressure Electrical signals SSP 153/31 The EDC control unit sends output signals to the solenoid valve for charge pressure control N75 according to the charge pressure specified map. By changing the signal pulse duty factor, more or less intake manifold pressure is applied to the charge pressure control valve on the exhaust gas tur- bocharger. The charge pressure can thus be varied between the minimum and maximum permissible values.<br><br> Intake manifold temperature sender G72 The charge pressure is also corrected in the control unit by the intake pipe temperature to make allowance for the effect of temperature on the densi- ty of the charge air. 25 Solenoid valve for charge pressure control N75 Direction of continuity: de-energised: energised: (max. pulse duty factor) Intake mani- fold pressure Atmospheric pressure to charge pressure control valve SSP 153/32 SSP 153/34 26 Glow plug system A glow plug controller is integrated in the EDC control unit of the 1.9-ltr.<br><br> TDI engine. This process is divided into the following phases: ? Glow phase ?<br><br> Afterglow phase Glow phase Thanks to the good starting response of this direct injection diesel engine, a glow phase is only necessary below + 9°C. The control unit receives the corresponding temperature signal from coolant temperature sender G62. The duration of the glow period is dependent on the size of this temperature signal.<br><br> The warning lamp for glow period K29 on the instrument panel indicates to the driv- er when the glow phase is in progress. Please note: The warning lamp for glow period has dual functions. If it comes on during vehicle operation, it serves as a fault warning lamp and pro- vides the driver with information regarding a fault in the engine man- agement system.<br><br> Afterglow phase The glow phase follows the afterglow phase after starting the engine. This improves combustion efficiency shortly after the engine is started, and dampens engine noise, improves idling quality and reduces hydrocarbon emissions. The afterglow phase always takes place irrespective of glow phase.<br><br> The afterglow phase is interrupted at an engine speed of 2,500 rpm. Glow plugs Engine speed determined by G28 Coolant temperature determined by G62 EDC control unit Relay for glow plugs Fuse SSP 153/35 27 Minimising environmental pollution demands a great deal of co-ordination and design work. This frequently involves reconciling conflicting demands such as low nitrogen oxide emission and high engine performance.<br><br> The 1.9-ltr. TDI engine easily achieves the 1998 EU exhaust emission limits and offers high fuel efficiency at the same time. Pollutants in the exhaust gas The pollutants which mainly occur in the exhaust gases of diesel engines are ?<br><br> carbon dioxide (CO) ? gaseous hydrocarbons (HC) ? particles ?<br><br> nitrogen oxides (NOx). Other noxious components such as sulphur hydrides also occur in small- er quantities. Carbon dioxide, particles and hydrocarbons in exhaust gas are primarily due to incomplete combustion of the fuel.<br><br> Nitrogen oxides - chemical compounds of oxygen and nitrogen - form at high combustion chamber temperatures, provided that sufficient excess air is available. Pollution control The proportion of nitrogen oxides (NOx) normally increases due to the measures to reduce particle and HC formation. Reducing nitrogen oxide emission means accepting higher emissions of other exhaust gas con- stituents, and possibly even higher fuel consumption.<br><br> It is also necessary to find the best possible compromise. The components involved in the combustion process, e.g. injectors, pis- ton recess, combustion chamber shape, etc, were designed with a view to minimising exhaust emissions in particular.<br><br> The complete engine management system has been adapted in such a way as to optimise the combustion process. Above all the point of commencement of injection and the exhaust gas recirculation affect the composition of the exhaust gas. Emission characteristics 28 Effect of the point of commencement of injection To reduce the proportion of nitrogen oxides in the exhaust gas, the injection cycle commences slightly later than would otherwise be necessary to develop maximum power output.<br><br> This causes an increase in HC and particle formation. Fuel consump- tion increases by approx. 4% because of the delay in commencement of the injec- tion cycle.<br><br> Effect of the exhaust gas recirculation The supply of exhaust gases to the combustion chamber reduces the oxygen com- ponent in the combustion chamber. This reduces the emission of nitrogen oxides, but it increases particle emission in certain operating states. The addition of the recirculated exhaust gas quantity is therefore adapted precisely.<br><br> 29 In the control unit, several auxiliary functions take place continuously dur- ing vehicle operation Idling speed control From the engine speed signal, which is supplied 4 times per revolution, the control unit recognises deviations from the set idling speed at an early stage. The quantity adjuster in the injection pump then receives a signal immediately. The idling speed is thus kept constant in every oper- ating state, e.g.<br><br> when electrical current consumers are switched on. Even running control To ensure the engine runs very evenly, the injection quantity of every cylinder is regulated in such a way that the engine speed signal is uni- form. Shudder damping To avoid shudder, which occurs when marked load changes occur, the information regarding the accelerator pedal position is electronically "damped" when the pedal is moved too quickly.<br><br> Maximum speed cut off When the maximum engine speed is reached, the control unit reduces the injection quantity to protect the engine against overspeeding. Starting quantity regulation The injection quantity necessary for starting the engine is dependent on the coolant temperature. The control unit determines the correct quantity to keep the exhaust emissions low.<br><br> Signal monitoring The control unit monitors itself and the functions of sensors and actuators during vehicle operation. The glow plug warning lamp indicates when major faults occur. Internal functions in the control unit SSP 153/39 30 Self-diagnosis The self-diagnosis and safety concept of the EDC (Electronic Diesel Control) The control unit assumes the following functions during vehicle operation: ?<br><br> It continuously cross-checks the measured values supplied by the sen- sors for plausibility. ? It monitors the electrical and mechanical functional capability of the final control elements (actuators) by observing system reactions.<br><br> The self- diagnosis carries out actual value/setpoint comparisons; the results of these comparisons must meet the given requirements (maps). ? The self-diagnosis monitors the electrical connectors and cable connec- tions for cable breakage (open circuit) and short circuit.<br><br> Stage 1: Should any sensors with a correcting function fail, the EDC uses default substitute values or accepts information from other sensors. The actions of this correcting function usually stay unno- ticed by the driver. Stage 2: Major faults - i.e.<br><br> faults leading to the failure of subfunc- tions - result in a reduction in performance, and a warning is issued to the driver via the fault warning lamp. Stage 3: If the drive can no longer control engine power output with the accelerator pedal, the EDC switches the engine to high idling speed mode. In this way, servo functions of the vehicle are preserved and vehicle operability is retained.<br><br> Stage 4: If reliable engine operation can no longer be ensured, the quantity adjuster turns the engine off. If this is not possi- ble on account of the fault, the engine is turned off via the fuel cut off valve (redundant system). If faults occur in the system, the EDC reacts according to the significance of the fault.<br><br> Fault detection D I A G N O S I S R E A C T I O N 31 Engine performance and torque The maximum power output of the new 1.9-ltr. TDI industrial engine is 60 kW (84 bhp) at 3,300 rpm. The engine is notable for its very good torque curve.<br><br> Maximum torque is 205 Nm at only 1800 rpm. Performance diagram 50 60 70 80 90 100 110 120 130 140 150 160 170 180 190 200 210 1300 1500 1700 1900 2100 2300 2500 2700 2900 3100 3300 3500 Engine speed / rpm Tq. red.<br><br> Nm 0 4 8 12 16 20 24 28 32 36 40 44 48 52 56 60 64 P red. kW

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