2401076 - Introduction - PETROL INJECTION SYSTEM

GENERAL CHARACTERISTICS

The Bosch Motronic ME73H4 system (microhybrid control unit) with a motorized throttle belongs to the category of ignition systems integrated with sequential timed electronic injection system.The fuel system is returnless.The control unit electronically controls the air flow rate (flow meter) at the rotation speed set through the electronic butterfly, it regulates the fuel injection so that the (air/fuel) ratio is always within the optimum values, calculating the moment of ignition, in order to allow the smooth operation of the engine as the environmental parameters and loads applied vary.The ignition system is the static advance type with one coil with four outlets. The power modules are located inside the control unit.The engine control system, which is the auto-adjusting type, is capable of recognizing the changes which take place in the engine and compensates for them according to auto-adjustment functions which correct the carburation and air flow rate plans stored in the control unit.There are also two auto-adjustment functions for the carburation according to the anti-evaporation solenoid valve (see appropriate paragraph) and an idle adjustment plan: the latter is capable of effectively compensating for any air seepage.The continuous auto-adjustment of the carburation makes it possible to have the correct quantity of fuel in all temperature and altitude conditions.As a result of this, after each operation it is necessary to drive the vehicle for at least 15 minutes in the various operating conditions, in order to ensure that the control unit memorizes any changes which have taken place in the system and end the adjustment.

The main operating principles of the system are basically as follows:

  • regulation of injection times;
  • adjustment of ignition advance values;
  • control of cold starting;
  • control of enrichment during acceleration;
  • fuel cut-off during deceleration;
  • management of the idle speed (also according to the battery voltage);
  • limiting the maximum engine speed;
  • control of combustion using the Lambda sensor;
  • fuel vapour recovery;
  • control of the electric fans;
  • attachment/detachment of the climate control system;
  • self test.

There is also a special function that manages the connection with the body computer through a two-way signal for the Can line which includes:

  • engine temperature for instrument panel (output);
  • battery voltage (output);
  • engine rpm (output) for instrument panel;
  • max engine temperature warning light for instrument panel (output)
  • engine oil pressure warning light for control panel (output);
  • car speed (input) + mileometer (input);
  • Fiat code anti-theft device (input/output);
  • key status;
  • fuel consumption meter signal (output) for trip computer;
  • fuel level gauge signal (input);

Fuel injection system

The essential conditions that must always be met in the preparation of the air-fuel mixture for the correct operation of controlled-ignition engines are mainly:

  • the 'metering' (air/fuel ratio) must constantly be kept as close as possible to the stoichiometric ratio, so as to ensure the necessary rapidity of combustion, avoiding unnecessary fuel consumption
  • the 'homogeneity' of the mixture, consisting of petrol vapours, diffused as finely and evenly as possible in the air.
The injection/ignition system uses an indirect measuring system known as the 'SPEED DENSITY LAMBDA' type.In other words the angular rotation speed, density of the intake air and control of the mixture strength (retroactive control).In practice the system uses data on the ENGINE SPEED (rpm) and AIR DENSITY (pressure and temperature) to measure the quantity of air drawn in by the engine.The quantity of air drawn in by each cylinder, for each engine cycle depends not only on the density of the intake air, but also on the unit displacement and the volumetric efficiency.The density of the air refers to that of the air drawn in by the engine and calculated according to the absolute pressure and the temperature, both detected in the inlet manifold.Volumetric efficiency refers to the parameter relating to the coefficient for filling the cylinders measured on the basis of experimental tests carried out on the engine throughout the entire operating range and then stored in the electronic control unit memory.Having established the quantity of intake air, the system has to provide the quantity of fuel according to the desired mixture strength.The end of injection pulse or supply timing is contained in a map stored in the control unit memory and varies according to the engine speed and the pressure in the inlet manifold. In practice, it involves processing which the electronic control unit carries out to command the sequential, phased opening of the four injectors, one per cylinder, for the length of time strictly necessary to form the air/petrol mixture which is closest to the stoichiometric ratio. The fuel is injected directly into the manifold near the inlet valve at a pressure of around 3.5 bar. The speed (number of revs per minute) and the density of the air (pressure and temperature) are used to measure the quantity of intake air which, when established, enables the quantity of fuel to be metered according to the desired mixture strength. The other system sensors (coolant temperature, throttle valve position, battery voltage, etc.) allow the control unit to correct the basic strategy for all particular engine operating conditions. It is vital for the air/fuel ratio to be around the stoichiometric value for the correct and prolonged operation of the catalytic silencer and for the reduction of pollutant emissions.

Ignition system

The ignition is of the inductive discharge type, breakerless with power modules located in the electronic injection/ignition control unit. The primary winding for each coil is connected to the power relay (thereby receiving the battery voltage) and to the pins for the electronic control unit for connection to earth.

After the starting stage, the electronic unit manages the basic advance taken from a special map according to the:

  • engine rpm
  • absolute pressure value (mmHg) measured in the inlet manifold.
This advance value is corrected according to the temperature of the engine coolant, the intake air, the detonation and the butterfly position.. The cylinder spark plugs are connected directly to the coil secondary terminals (one per spark plug).

Diagram of input/output info to/from control unit

The diagram below shows the information entering/leaving the control unit.
1, Engine control unit 2, Battery 3, Ignition switch 4, Engine control system relay 5, Fuel pump relay 6, Fuel pump 7, Radiator fan relay/s 8, Radiator fan 9, Compressor activation relay 10, Compressor 11, Ignition coils 12, Spark plugs 13, Injectors 14, Carbon filter flushing solenoid 15, Lambda sensor (pre-catalyzer) 16, Lambda sensor (post-catalyzer) 17, Coolant temperature sensor 18, Detonation sensor 19, Throttle and throttle position sensor control actuator 20, Engine rpm and TDC sensor 21, Injection timing sensor 22, Air temperature and absolute pressure sensor 23, Oil pressure switch 24, Body computer 25, CODE control unit (via CAN) 26, Tester connection (via CAN network) 27, Rev counter (via CAN network) 28, System failure bulb (via CAN) 29, Speedometer (via CAN) and ABS control unit 30, City button for power assisted steering (via CAN)

SELF-LEARNING

The control unit implements the self-learning mode in the following conditions:

  • removing-refitting or replacement of the injection control unit
  • removing-refitting or replacement of the throttle body
The values memorized by the control unit are preserved if the battery is disconnected.

SELF-ADAPTATION OF THE SYSTEM

The control unit has a self-adaption function which recognizes changes in the engine which occur as a result of bedding-in and ageing processes of both components and the engine itself. These changes are stored in the form of modifications to the basic mapping, and their purpose is to adapt the operation of the system to the gradual alterations in the engine and components compared with their characteristics when new.This self-adaptation function also makes it possible to even out inevitable differences (due to production tolerances) in any replaced components. From the exhaust gas analysis, the control unit changes the basic mapping in relation to the original characteristics of the new engine. The self-adaptation parameters are not cancelled if the battery is disconnected.

AUTODIANOSIS AND RECOVERY

The control unit autodiagnostic system controls the correct operation of the system and signals any faults by means of an (MIL) warning light in the instrument panel which has a standardized European colour and ideogram. This warning light signals both engine management faults and problems detected by the EOBD strategies.The (MIL) warning light operating logic is as follows:With the ignition key in the ON position, the warning light comes on and remains on until the engine has been started up. The control unit's self-test system checks the signals coming from the sensors, comparing them with the permitted limits:

Signalling of faults during engine starting:

  • the failure of the warning light to go out once the engine has been started up means that there is an error memorized in the control unit.

Fault indication during operation

  • the warning light flashing indicates possible damage to the catalyzer due to misfire.
  • the warning light constantly on indicates the presence of engine management errors or EOBD errors.
From time to time, the control unit defines the type of recovery according to the components which are faulty.The recovery parameters are managed by those components which are not faulty.

RECOGNITION OF FIAT CODE

When the control unit receives the ignition 'ON' signal, it communicates with the body computer to obtain starting enablement.Communication takes place via a two-way CAN line which connects the two control units.

CONTROL OF COLD STARTING

The following occurs during cold starting:

  • a natural weakening of the mixture because of poor turbulence of the fuel particles at low temperatures
  • reduced fuel evaporation
  • condensation of the fuel on the inner walls of the inlet manifold
  • increased viscosity of the lubricant oil.

The electronic control unit recognizes this condition and corrects the fuel injection time in accordance with:

  • coolant temperature
  • intake air temperature
  • battery voltage
  • engine rpm.
The ignition advance depends solely on the engine rpm and the coolant temperature. The rpm is made to decrease in proportion to the increase in temperature of the engine until the optimum value with the engine up to temperature is obtained.

CONTROL OF COMBUSTION - LAMBDA SENSORS

In EOBD systems the Lambda sensors, which are all the same type, are located upstream of the catalyzer and downstream of the catalyzer.The pre-catalyzer sensor carries out the check on the mixture strength called 1st loop (closed loop of the upstream sensor).The post-catalyzer sensor is used for the catalyzer diagnosis and for finely modulating the 1st loop control parameters. With this in mind, the adjustment of the second loop is designed to recover both production differences and those in the response of the pre-catalyzer sensors which may occur as a result of ageing and pollution. This control is known as the 2nd loop (post-catalyzer sensor closed loop).

CONTROL OF DETONATION

The control unit detects the presence of knocking by processing the signal coming from the relevant sensor. The control unit continuously compares the signals coming from the sensor with a threshold value, which, in turn, is continuously updated to take account of background noise and ageing of the engine. The control unit is therefore capable of detecting the presence of detonation (or the onset of detonation) in each individual cylinder and reduces the ignition advance for the cylinder concerned (in steps of 3 degrees up to a maximum of 6 degrees) until the phenomenon disappears. The advance is then gradually restored to the basic value (in steps of 0.8 degrees). Under acceleration conditions, a higher threshold is used to take account of the increased engine noise under such conditions.The knock control strategy also has a self-adaptation function, which memorizes the reductions in advance that may be repeated continuously, so as to adjust the mapping to the different conditions now affecting the engine.

CONTROL OF ENRICHMENT DURING ACCELERATION

During this stage, the control unit increases the quantity of fuel requested by the engine as appropriate (to achieve maximum torque) according to the signals coming from the following components:

  • accelerator pedal potentiometer and throttle position.
  • rpm and TDC sensor
The 'basic' injection time is multiplied by a coefficient which depends on the temperature of the engine coolant, the opening speed of the accelerator butterfly and the increase in pressure in the inlet manifold. If the sharp variation in the injection time is calculated when the injector is already closed, the control unit reopens the injector (extra pulse) in order to compensate the mixture strength extremely quickly; the subsequent injections are already increased on the basis of the coefficients mentioned previously.

CONTROLLING FUEL SUPPLY - FUEL PUMP

The control unit supplies the electric pump:

  • when the ignition is ON for 0.8 s
  • with the ignition in the START position and the engine speed > 22.8 rpm

The control unit cuts off the supply to the electric pump:

  • with ignition in OFF position
  • with engine speed < 22.8 rpm.
The returnless fuel supply system ensures a constant petrol pressure of 3.5 bar.

CONNECTION WITH THE CLIMATE CONTROL SYSTEM

The control unit controls the engine torque directly (torque based) and when the compressor is turned on and power is required, the control unit drives the motorized throttle to increase the air flow.

The control unit momentarily interrupts the supply to the compressor:

  • during starting
  • by switching it off if the engine temperature > 115°C
  • during pick-up with accelerator fully depressed.

RECOGNITION OF CYLINDER POSITION

The engine timing signal, together with the engine rpm and top dead centre (TDC) signal, allows the control unit to recognize the succession of cylinders to implement phased injection.This signal is generated by a Hall-effect sensor, positioned on the cylinder head near the phonic wheel on the inlet camshaft.

FUEL CUT-OFF DURING OVERRUNNING

During release of the accelerator pedal, and beyond a pre-established threshold, the control unit:

  • cuts off the supply to the fuel injectors
  • reactivates the supply to the fuel injectors at 1300-1500 rpm.
As there is no fuel supply, the rpm decreases more or less rapidly depending on the vehicle's driving conditions. Before idle speed is reached, the trend of the fall in rpm is checked.If it exceeds a certain value, the fuel supply is partially reactivated so that the engine can 'gently accompany' the drop towards idle speed.

The thresholds for reactivation of the fuel supply and for fuel cut-off vary depending on:

  • engine coolant temperature
  • vehicle speed
  • engine rpm

FUEL VAPOUR RECOVERY

The (polluting) fuel vapours, collected in an activated-charcoal filter (canister), are sent to the inlet ducts to be burnt. This takes place via a solenoid controlled by the control unit only when the engine's operating conditions so permit.The control unit compensates for the additional quantity of fuel by reducing the delivery to the fuel injectors.

CONTROLLING MAXIMUM RPM

The maximum rpm is controlled by the control unit, limiting the engine torque through the motorized throttle.

ADJUSTING INJECTION TIMES

The control unit calculates the injector opening times and controls them extremely quickly and precisely on the basis of:

  • engine load (rpm and air flow)
  • battery voltage
  • engine coolant temperature.
Fuel injection is sequential and phased for each cylinder, and takes place at the optimum 'start-of-injection' point, while the 'end-of-injection' point remains fixed.

ADJUSTING IGNITION ADVANCES

Thanks to the mapping stored in its memory, the control unit can calculate the ignition advance in accordance with:

  • engine load (idling, choke, full load depending on the rpm and air flow)
  • intake air temperature
  • engine coolant temperature.
The ignition can be selectively delayed at the required cylinder, which is recognized by means of the combination of the values recorded by the knock and cam angle sensors.

CONTROL OF THE IDLE SPEED

The control unit recognizes the idle condition from the accelerator pedal being in the 'released' position. According to the consumers switched on and the brake/clutch pedal signals, the control unit controls the position of the motorized butterfly. The idle speed when warm is 750 ± 50 rpm.

CONTROLLING RADIATOR COOLING FAN

The control unit controls the switching on of the electric fan in accordance with the coolant temperature:

  • temperature for switching on 1st speed 97°C
  • temperature for switching on 2nd speed 102°C
There is a further check (4 stage pressure switch signal) which engages the 1st or 2nd fan speed, according to the pressure of the refrigerant gas, with the air conditioning system switched on. In the absence of the coolant temperature signal, the control unit activates the recovery function and switches on the fan 2nd speed until the error disappears.

VIEW OF ASSEMBLY

The diagram below shows the main components of the system.
1, Speedometer (via CAN network) 2, System failure bulb (via CAN network) 3, CITY button (via CAN network) 4, Engine management control unit 5, Throttle control actuator and throttle position sensor 6, Ignition coils 7, Coolant temperature sensor 8, Radiator fan 9, Lambda sensor (upstream) 10, Lambda sensor (downstream) 11, Injection timing sensor 12, Spark plugs 13, Engine rpm and TDC sensor 14, Knock sensor 15, Injectors 16, Air temperature and absolute pressure sensor 17, Charcoal filter solenoid valve 18, Active charcoal filter 19, Holder (including pump, pressure regulator, filter, level sensor) 20, Inertia switch 21, Battery 22, Ignition switch 23, Engine management system relay 24, Fuel pump relay 25, Radiator fan relay(s) 26, Climate control system connection 27, CODE connection (via CAN) 28, Diagnostic equipment connection (via CAN) 29, Rev counter (via CAN)

Specifications

The control unit is mounted in the engine bay over the throttle body and withstands high temperatures. The control unit memory is the 'flash EPROM' type, i.e. reprogrammable from the outside without intervening on the hardware.The replacement of the injection control unit or the throttle body means that the self-learning procedure has to be carried out.

CONTROL UNIT PIN-OUT

The diagram below shows
ENGINE SIDE connector (1) 1, Not connected 2, Cylinder 3 injector control 3, Not connected 4, Not connected 5, Not connected 6, Air pressure sensor signal 7, + 5 V air pressure sensors/timing sensor 8, Lambda sensor signal (+) upstream of catalyzer 9, Engine timing/engine coolant temperature sensors earth 10, Engine rpm sensor 11, Throttle valve actuator earth 12, Not connected 13, Not connected 14, Not connected 15, Cylinder 4 coil operation 16, Cylinder 2 coil operation 17, Heated Lambda sensor signal (-) downstream of catalyzer 18, Cylinder 2 injector control 19, Not connected 20, Possible rapid programming of control unit 21, Knock sensor 1 signal 22, Not connected 23, Throttle 1 potentiometer signal input 24, Not connected 25, Lambda sensor earth upstream of catalyzer 26, Air temperature and pressure sensor earth 27, Not connected 28, Throttle valve actuator (positive) 29, Not connected 30, Not connected 31, Cylinder 3 coil operation 32, Cylinder 1 coil operation 33, Canister scavenging solenoid valve operation 34, Cylinder 4 injector control 35, Not connected 36, Engine timing sensor signal 37, Knock sensor earth 38, Engine coolant temperature sensor signal 39, Throttle 2 potentiometer signal input 40, Not connected 41, Lambda sensor signal (-) downstream of catalyzer 42, Engine rpm sensor 43, Throttle valve actuator earth 44, Not connected 45, Not connected 46, Not connected 47, Not connected 48, Not connected 49, Heated Lambda sensor negative signal (-) upstream of catalyzer 50, Not connected 51, Cylinder 1 injector control 52, Not connected 53, Not connected 54, Air conditioning linear sensor signal 55, Air temperature sensor signal 56, Throttle potentiometers 1 and 2 supply (+5V) 57, Lambda sensor signal downstream of catalyzer 58, Throttle 1 and 2 potentiometers earth 59, Not connected 60, Throttle valve actuator positive 61, Not connected 62, Not connected 63, Not connected 64, Not connected VEHICLE SIDE connector (2) 1, Not connected 2, Body computer line k 3, Not connected 4, Accelerator pedal 2 potentiometer supply (+5V) 5, Accelerator pedal 2 potentiometer earth 6, Not connected 7, Clutch switch signal 8, Cruise Control deceleration signal 9, Cruise Control acceleration signal 10, Not connected 11, CAN network (HIGH) 12, Not connected 13, Not connected 14, 1st fan speed relay feed 15, Not connected 16, Not connected 17, Power supply from main relay 18, Direct supply (+30) 19, Main relay feed 20, Rev counter signal 21, Accelerator pedal 1 potentiometer supply (+5V) 22, Accelerator pedal 1 potentiometer earth 23, Not connected 24, 2nd fan speed switch engagement (quadrinary) 25, Signal from brake pedal switch N.A. contact 26, Not connected 27, Not connected 28, Not connected 29, Not connected 30, 2nd fan speed relay feed 31, MIL warning light on signal 32, Not connected 33, Main relay power supply 34, Not connected 35, Cooling fan 2 control output 36, Not connected 37, Accelerator 2 potentiometer signal input 38, Not connected 39, Not connected 40, Air conditioning engagement request 41, Cruise Control resume 42, Engine oil pressure signal 43, CAN network (LOW) 44, Not connected 45, Not connected 46, Air conditioning compressor engagement relay control 47, Not connected 48, Not connected 49, Direct supply from main relay 50, Not connected 51, Signal from ignition switch (15/54) 52, W line from body computer 53, Accelerator 1 potentiometer signal input 54, Accelerator 1 potentiometer signal input 55, Fuel gauge sensor 56, 1st fan speed switch operation (quadrinary) 57, Signal from brake switch N.C. contact 58, Cruise Control on control 59, Vehicle speed sensor 60, CAN network (HIGH) 61, Coolant temperature warning light 62, Petrol pump relay feed 63, Not connected 64, Not connected

Specifications

The twin jet injectors (with the spray at an angle in relation to the injector axis) are specifically designed for engines with 4 valves per cylinder, making it possible to direct the jets towards the two inlet valves.The injector is top-feed, i.e. fuel is fed in from the upper part of the body, which houses the electrical winding connected to the terminals of connector (3). When the current passes through the winding, the magnetic field which is produced attracts the shutter, opening the injector and the flow of fuel.Two rings ensure a seal on the fuel manifold side (1) and intake manifold side (2).Notch (4) determines angular injector position and directs the jets correctly in relation to the intake valves.

Electrical characteristics

Injector resistance may be measured by disconnecting the connector and connecting an ohmmeter as shown in the figure.Resistance value: 14.5 ± 5% ohm.

OPERATION

The jets of fuel, at a differential pressure of 3.5 bar, come out of the injector and are instantly atomized forming two cones. The control logic for the injectors is the sequential, phased type, in other words the four injectors are operated according to the engine cylinder inlet sequence, whilst the supply for each cylinder can already start during the expansion stroke and continue until the inlet stroke has already started.

FUEL MANIFOLD

The function of the fuel manifold is to distribute fuel to the injectors. It incorporates seats for the injectors and air bleed valve.The fuel intake is secured by a quick-release fitting.No recirculation pipe is present because the system is returnless.
1, Fuel manifold 2, Injector 3, Fuel inlet connection 4, Bleed valve

Specifications

It is fitted on the thermostatic cup and measures the temperature of the coolant by means of an NTC thermistor which has a negative resistance coefficient.The table shows the variation in the resistance value according to the temperature
°CO
-2015971
-109620
05975
103816
202502
252044
301679
401152
50807
60576
70418
80309
90231
100176

Operation

The reference voltage for the NTC element for the injection system is 5 Volt; As the input circuit into the control unit is designed as a voltage divider, this voltage is divided between a resistor located in the control unit and the sensor's NTC resistor. The control unit is thus able to assess the changes in the sensor's resistance via the changes in voltage, and thus obtain the temperature information.

Components

The diagram illustrates the composition of the sensor
1, NTC resistor 2, Sensor body 3, Electrical connector

Specifications

The piezoelectric type detonation sensor is fitted on the cylinder block/crankcase and detects the intensity of the vibrations caused by the detonation in the combustion chambers.This phenomenon produces a mechanical repercussion on a piezoelectric crystal which sends a signal to the control unit; on the basis of this signal, the control unit reduces the ignition advance until the phenomenon has disappeared. The advance is then gradually restored to the basic value. Electrical specifications: resistance 4.9 MO ± 20%. The detonation sensor tightening torque is 2 daNm.

Operation

The molecules of a quartz crystal feature electrical polarization. In rest conditions (A) the molecules do not have a particular direction. When the crystal is subjected to pressure or an impact (B), they are directed - the higher the pressure to which the crystal is subjected, the more marked their direction. This direction produces a voltage at the ends of the crystal.
A. Rest position B. Under pressure position

Specifications

It is mounted on the engine block and 'faces' the phonic wheel located on the crankshaft. It is of the inductive type, i.e. it functions by means of the variation in the magnetic field generated by the passage of the teeth of the flywheel (60-2 teeth).

The fuel injection control unit uses the rpm sensor to:

  • determine the speed of rotation
  • determine the angle of the crankshaft.
Electrical specifications: resistance:The distance (gap) for obtaining correct signals, between the end of the sensor and the flywheel, should be between 0.5 and 1.5 mm.

Composition

The sensor consists of a tubular casing (1) which contains a permanent magnet (3) and an electrical winding (2).

Operation

As the flywheel teeth go past, the magnetic flow produced by the magnet (3) undergoes fluctuations due to the change in the gap.These fluctuations induce an electromotive force in the winding (2), at the ends of which there is a voltage which alternates between positive (tooth opposite sensor) and negative (gap opposite sensor).
1, Sensor 2, Output signal 3, Signal corresponding to the two missing teeth 4, Crankshaft pulley with flywheel

Operation

The peak value of the output voltage from the sensor, provided other factors remain the same, depends on the distance between the sensor and tooth (gap). The phonic wheel comprises sixty teeth, two of which have been removed to create a reference: the pitch of the wheel thus corresponds to an angle of 6° (360° divided by 60 teeth). The synchronization point is recognized at the end of the first tooth after the space created by the two missing teeth: when this passes under the sensor, the pair of pistons 1-4 of the engine are at 114 degrees before TDC.

SPECIFICATIONS

The accelerator pedal is fitted with two integrated potentiometers:

  • one main one
  • one safety one.

The injection control unit implements the following 'recovery' strategies in the following conditions:

  • if there is a fault with one of the two potentiometers, the control unit uses the remaining track, without restricting the torque, and checks the plausibility with the brake switch.
  • if both of the potentiometers fail completely, the throttle opening is excluded.

Operation

The sensor consists of a casing, secured to the accelerator pedal mount, which contains a shaft, in an axial position, connected to the twin track poteniometer.There is a coil spring on the shaft which guarantees the correct resistance to the pressure whilst a second spring ensures the return on release. Operating range from 0° to 70°; mechanical stop at 88°.

SPECIFICATIONS

It is fitted on the inlet chamber and regulates the quantity of air drawn in by the engine. According to the signal coming from the accelerator pedal potentiometer, the injection control unit controls the opening of the throttle by means of a direct current motor integrated in the throttle casing. The throttle opening takes place between 0° and 80° therefore including the idle adjustment. The throttle body actuator is equipped with two potentiometers integrated so that one controls the other and viceversa.

If both the potentiometers fail or there is no supply, depending on the position of the accelerator pedal, the control unit reduces the drive torque:

  • fully depressed, it cuts off the supply to one or more pistons, until a maximum speed of 2500 rpm is reached
  • in intermediate positions, it cuts off the supply to one or more pistons, until a speed below 1200 rpm is reached.
If the throttle body or the injection control unit or the air chamber is replaced then the self-learning procedure must be carried out.

OPERATION

The throttle opening is managed by an electronic motor. /p>The ME7.3H4M system operates the motorized throttle according to the accelerator pedal request; a potentiometer is connected to it which sends a voltage signal to the control unit where it is processed and the more or less accentuated opening laws are produced. In six-speed versions, the system is able to govern throttle movement in accordance with two modes: one more sporty and the other more comfortable.The driver can modify the response of the engine to the action of the accelerator pedal via a switch in the console near the gear lever.

In particular:

  • with the 'CITY' function switched on, the response of the throttle movement is smoother.
  • with the 'CITY' function switched off, the throttle movement response is faster.

Activation mode:

  • press the CITY button;
  • release the accelerator pedal.
The control unit activates the management.The graph illustrates the throttle opening law.

Specifications

The intake air temperature and pressure sensor is a component which is designed to measure the pressure and the temperature of the air inside the inlet manifold. Both pieces of information are used by the injection control unit to define the quantity of air drawn in by the engine; this information is then used to calculate the injection time and the point of ignition. The sensor is fitted on the inlet manifold.

COMPOSITION

The air temperature sensor consists of an NTC thermistor (Negative Temperature Coefficient). The resistance of the sensor decreases as the temperature increases. The control unit input circuit divides the 5 Volt reference voltage between the sensor resistance and a fixed reference value, obtaining a voltage which is proportional to the resistance and therefore to the temperature. The sensitive element of the pressure sensor consists of a Wheatstone bridge on a ceramic diaphragm. On one side of the diaphragm is the absolute reference vacuum, whilst on the other side there is the vacuum from the inlet manifold. The (piezoresistive) signal from the distortion suffered by the diaphragm, before being sent to the engine control unit, is amplified by an electronic circuit in the support which also houses the ceramic diaphragm. When the engine is off, the diaphragm bends in accordance with the atmospheric pressure; the altitude information is thus obtained.When the engine is running, the effect of the vacuum produces a mechanical action on the sensor diaphgram, which bends, altering the resistance value. Since the supply is kept rigorously constant (5V) by the control unit, altering the resistance alters the voltage output value.

Electrical characteristics

The diagram below illustrates the electrical specifications of the sensor.
1, Air temperature sensor 2, Intake air pressure sensor

COMPOSITION

The coils are connected directly to the spark plugs and are the closed magnetic circuit type with a core made from silicon steel with a thin gap containing both windings. The windings are covered by a pressed plastic container and are insulated through immersion in an epoxy resin and quartz compound which gives them exceptional dielectric, mechanical and thermal properties enabling them to withstand high temperatures. The proximity of the primary winding to the magnetic core reduces the magnetic flow losses optimizing the coupling with the secondary winding.

Electrical specifications:

Primary circuit resistance: 0.5 O ± 10% at 23°C Secondary circuit resistance: 6300 O ± 10% at 23°C.

SPECIFICATIONS

The vehicle speed signal is generated by the ABS control unit and is sent to the engine management control unit via the CAN.