change pcm FORD KUGA 2011 1.G User Guide

Calculation of valve timing adjustment
angle
The 2.5L Duratec (VI5) engine has two camshaft
adjustment units which work independently of each
other.
One camshaft adjustment solenoid is installed for
each intake camshaft and exhaust camshaft.
This allows the PCM to continuously adjust the
intake and exhaust-side camshaft adjustments
independently of one another. The timing is
adjusted by the PCM using curves; adjustment is
primarily done as a function of engine load and
engine speed.
In this way the engine performance is increased
and internal exhaust gas recirculation is realized.
The advantages of camshaft adjustment are as
follows:
• Higher torque and improved torquecharacteristics
• Reduced fuel consumption
• Improved emissions performance
The camshaft adjustment solenoids are actuated
by the PWM by means of a PCM signal.
Continuous adjustment of the camshafts by the
PCM is achieved by means of the camshaft
adjustment solenoids, the camshaft adjustment
units and two CMP sensors. A defined quantity of
engine is oil is supplied to or drained from the
adjustment units via the camshaft adjustment
solenoids. The existing EOP (engine oil pressure)
is taken into account in the process. In this way
the valve timings are adjusted according to the
operating condition of the engine. The camshaft
adjusters work according to the vane-cell principle.
On starting the engine, both camshafts are
mechanically locked in their starting positions. The
intake camshaft is in the maximum late position
and the exhaust camshaft in the maximum early
position.
Control is divided into four main areas:
• Low engine speed and low load
• Partial load
• Low engine speed and high load
• High engine speed and high load
At low engine speed and low load, the exhaust
valves open early and the intake valves open late.
The result is reduced fuel consumption and more
uniform idling. In the partial load range, the exhaust valves and
the intake valves open late. The late opening of
the exhaust valves results in a good utilization of
the expanding gases in the cylinder. Closing the
exhaust valves after Top Dead Center allows
internal exhaust gas recirculation through aspiration
of exhaust gases into the combustion chamber.
Moreover, the intake valves close after Bottom
Dead Centre, allowing the fresh air/fuel mixture
and exhaust gases to flow back into the intake
tract. The result is reduced fuel consumption and
low emissions.
At low engine speed and high engine load, the
exhaust valves open late and the intake valves
open early. Due to the resulting valve opening
overlap at Top Dead Centre, the pulsating gas
column within the combustion chamber is utilized
to achieve better charging of the combustion
chamber. The result is increased torque at lower
RPM.
At high engine speeds and high engine load, the
exhaust valves open early and the intake valves
close late. Because a rapid gas exchange must be
achieved at high engine speeds, the early opening
of the exhaust valves achieves better expulsion of
the exhaust gas and the late closing of the intake
valves improves cylinder charge efficiency.
Optimum power output is achieved.
Many other camshaft positions are possible in
addition to these settings.
In order to avoid a malfunction in the camshaft
adjustment units at excessively low ambient or
engine-oil temperatures, they are activated by the
PCM with a time delay via the camshaft adjustment
solenoids. The PCM receives the information
required for this from the ECT sensor and the
outside air temperature sensor.
When idling and during deceleration, the camshaft
adjustment solenoids are activated repeatedly by
the PCM in order to remove any dirt which may be
on the bore holes and ring grooves.
Boost pressure control
Optimum regulation is achieved by means of an
electronically-controlled solenoid valve, the boost
control solenoid valve.
Refer to:
Turbocharger (303-04 Fuel Charging and
Controls - Turbocharger - 2.5L Duratec
(147kW/200PS) - VI5, Description and
Operation).
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voltage signal to the PCM corresponding to the
aspirated air mass.
This analogue voltage signal is between 0.5V and
5V. Low mass of intake air produces a low voltage
signal. A high mass of intake air produces a
correspondingly high voltage signal.
The MAF sensor is also capable of detecting the
backflow of the intake air. A sensor element is
heated electrically on the integrated chip and then
cooled by the air flowing through. The regulating
switch supplies the heating current in such a way
that it attains a constant excess temperature in
comparison to the intake air. The mass air flow and
the direction of flow can be derived from this
heating current (given in the form of a signal
voltage). Below a certain voltage value there is a
return flow. The direction is flow is registered by
two sensors pointing in different directions. The
measurement does not require a great deal of
software processing effort, even with a strongly
pulsating mass air flow.MAPT
E96146
The MAPT sensor combines two sensors in one
housing. These are the MAP sensor and the IAT
sensor. They take the form of a piezoelectric
resistor and an NTC resistor.
The MAP sensor receives a reference voltage of
5V from the PCM. The output signal from the MAP
sensor element is an analog voltage signal which
changes proportionately to the prevailing pressure
in the intake manifold.
The IAT sensor records the temperature of the
intake air downstream of the intercooler.
APP sensor
00
E96668
1
2
43
AV
56
7
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Description
Item
Coil-on-plug ignition coil
1
Spark plug connector
2
Low-voltage connection
3
Laminated soft-iron core
4Description
Item
Primary winding
5
Secondary winding
6
Spark plug
7
High-voltage connection via spring contact
8
In an ignition system with coil-on-plug ignition coils,
each cylinder is actuated individually and only once
per cycle (working stroke). The coil-on-plug ignition
coils are mounted directly on the spark plugs,
therefore no ignition cables are required between
the ignition coils and the spark plugs.
Each individual ignition coil is actuated on the
low-voltage side by the PCM. The power
end-stages are incorporated into the coil-on-plug
ignition coils. Only the actuating current for these
power end-stages is controlled by the PCM.
Fuel pressure/fuel temperature sensor
E73531
The fuel pressure/fuel temperature sensor is a
combination of two sensors, one for the fuel
absolute pressure and one for the fuel temperature.
The sensors register the fuel values in the fuel
injection supply manifold. The sensor is supplied
with a 5V voltage by the PCM.
The fuel pressure sensor is a piezoresistor and
works using an analog signal. The change in output
voltage mirrors the change in pressure in the fuel
rail. If the pressure is low, the output voltage is also
low.
The fuel temperature sensor is an NTC resistor.
When the fuel pressure/fuel temperature sensor is
disconnected, the resistance of the fuel
temperature sensor between connections 1 and 2
of the sensor can be measured.
Resistor
Temperature
5896 Ohm
0° C
3792 Ohm
10° C
2500 Ohm
20° C
1707 Ohm
30° C
1175 Ohm
40° C
The values of the fuel pressure/fuel temperature
sensor can be read out with IDS. The displayed
values are absolute values (fuel pressure +
atmospheric pressure).
Wastegate control valve
E73539
The boost control solenoid valve is a 2/3-way valve
that is actuated with a PWM signal. This allows the
valve opening to be steplessly adjusted.
Power (battery voltage) is supplied via the
Powertrain Control Module relay in the BJB. The
solenoid coil resistance is around 23 ohms at 20°
C.
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Engine oil level, temperature and quality
sensor
E95312
The sensor is a combined oil level and oil
temperature sensor.
The sensor consists of:
• Electrical connector
• Integral electronics
• PTC resistor
• Capacitive element consisting of two tubes witha space between them. The one tube represents
the positive side, the other the negative. The oil
between the tubes creates the capacitive
properties.
The sensor receives a 5V voltage from the PCM.
The sensor generates a PWM signal that is sent
to the PCM.
Exterior aor temperature sensor
The outside air temperature sensor is a NTC
resistor and is supplied with a 5V voltage by the
PCM.
The resistance of, and consequently the voltage
from, the outside air temperature sensor changes
as a function of temperature.
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E112322
The TCM adapts the gear changing to ensure that
the correct gear is selected for the style of driving,
the engine load, driver requirements, vehicle speed
etc. This leads to lower fuel consumption together
with improved comfort through smoother gear
changes and lower noise levels.
The TCM receives information on the driver's
desired transmission range and type of driving
mode. In contrast to a transmission which is only
controlled hydraulically, the control module can
calculate the best times to shift gear and activate
torque converter lockup by using the signals from
the sensors in the transmission and the engine
management system.
The control module enables small changes in the
operating conditions to be made and adapts thevarious transmission functions to ensure that the
correct gear is always selected in relation to the
type of driving mode.
The TCM has adaptive capabilities. This ensures
smooth gear changes throughout the whole service
life of the transmission.
To exactly determine the activation points of the
gear shifts and torque converter lockup on the
basis of the type of driving mode chosen, the TCM
receives the following information:
• Transmission range chosen (TR sensor).
• Type of driving mode chosen
(normal/sport/select-shift).
• Transmission input shaft speed (TSS sensor).
• Transmission output shaft speed (OSS sensor).
• Transmission fluid temperature (TFT sensor).
• The engine speed and the torque as well as the throttle plate opening - from the PCM via the
CAN data bus.
• Actuation of the accelerator pedal - from the PCM via the CAN data bus.
• Coolant temperature - from the PCM via the CAN data bus.
• Vehicle speed - from the ABS via the CAN data bus.
• Actuation of the brake pedal - from the ABS via the CAN data bus.
Pin assignment for TCM connector 'A' (connection to vehicle)
11
E125669
Description
Item
Battery (+)
1
not assigned
2Description
Item
not assigned
3
not assigned
4
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To exactly determine the activation points of the
gear shifts and torque converter lockup on the
basis of the type of driving mode chosen, the TCM
receives the following information:
• Selected transmission range (TR sensor)
• Selected driving mode (normal/sport/select-shift)
• Transmission input shaft speed (TSS sensor)
• Transmission output shaft speed (OSS sensor)
• Transmission fluid temperature (TFT sensor)
• The engine speed and the torque as well as thethrottle plate opening - from the PCM via the
CAN databus
• Actuation of accelerator – from the PCM via the CAN databus
• The coolant temperature – from the PCM via the CAN databus
• Road speed – from the ABS module via the CAN databus
• Actuation of brake pedal – from the PCM via the CAN databus
Gearshift control
Adaptation
The TCM monitors every shift operation in all
driving conditions to make even and smooth gear
shifts possible. This is done by the control module,
which either lowers or increases the hydraulic line
pressure during gearshifts.
The changed pressure values are stored in the
control module memory after the engine is switched
off and retrieved during engine starting. This
improves the shift comfort and extends the service
life.
Full adaptability occurs when the following criteria
are met:
• Throttle plate opening is constant.
• Transmission fluid temperature between 65 °Cand 110 °C.
Shifting from 'P' to another transmission
range
To be able to move the selector lever from 'P' into
another transmission range, the ignition must be
switched on and the brake pedal pressed (stoplamp
switch on). The TCM detects the position of the
brake pedal via the CAN data bus and the engaged
transmission range from the TR sensor. Based on this information, the TCM transmits a
signal to the select-shift switch module. This
activates the brake shift interlock actuator in the
selector lever assembly.
When the brake shift interlock actuator is activated,
the locking pin is retracted so that another
transmission range can be selected.
The brake shift interlock actuator is deactivated
when the ignition is switched off. It is mechanically
locked when the gear selector lever is in 'P'.
Automatic transmission, selector lever in
position "D".
The TCM adapts the shift points to match the
driving conditions. Normally the TCM is in adaptive
mode and gear changes take place adapted to the
driving conditions. If special driving conditions are
detected, the TCM switches to predefined
characteristics.
When driving with normal acceleration, the TCM
uses a preset shift program which is optimized for
economical driving.
This shift program is suitable for "normal" driving
and delivers early upward changes and torque
converter lockup. Furthermore, the transmission
fluid pressure is adapted to make smooth
engagement of the gears possible.
Sport mode, selector lever in position "S"
The transmission switches from automatic
operation into sport mode. In this mode the TCM
switches to another set of characteristic curves.
These characteristic curves for control of the gear
changes are adapted to sporting calculations (e.g.
gear change at higher engine speed).
In the sport mode shift program the shift points are
set so that good performance is offered. Changing
down occurs at lower engine speeds.
Manual gear changes (select-shift mode) can be
made in sport mode by moving the selector lever
in the (+) or (-) direction.
Changing gear in select-shift mode
If you move the selector lever to 'S', the automatic
transaxle remains hydraulically in 'D' position. If
you move the gear selector lever forwards (-), the
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select-shift switch module transmits a downshift
signal to the TCM.
If you move the gear selector lever backwards (+),
an upshift signal is transmitted to the TCM. In the
instrument cluster, the symbol when the selector
lever is in the 'S' position changes from 'D' to the
current gear, for example 3.
The TCM transmits a signal to the select-shift
switch module to switch on the light emitting diode
for 'S' and to switch off all other light emitting
diodes. The TCM decides whether the shift process
is possible.
If the shift process is permitted, then the various
valves are activated according to the intended
combination for each gear.
In certain situations however, the TCM determines
the gear shifting. The following applies:
• If the vehicle is stationary, only 1st, 2nd and 3rdgears can be selected. 4th gear can be selected
at speeds over 30 km/h and 5th gear at speeds
over 40 km/h.
• The kickdown function is only available in the automatic transmission range 'D'
• Automatic gear changes into the next higher or next lower gear occur at fixed vehicle speeds
and fixed engine speeds
• The permitted engine speed for manual change down agree with that for the kickdown change
up, i.e. an engine speed of approximately 6000
rpm.
• If the temperature inside the transmission rises too high, the TCM takes control of the shift
decisions in order to select a gear in which
activation of torque converter lockup at the
current speed is possible
• Torque converter lockup is possible in 3rd, 4th and 5th gear. (1st and 2nd gears do not have
torque converter lockup)
The signal that specifies the position of the lever
to the select-shift switch module is generated as
follows in the selector lever position 'S': there is a
Hall sensor at the printed circuit board for the
module for each of the three selector lever
positions. A permanent magnet on the cover in the
selector lever affects the output signals to the
control module from the sensors. The control
module recognizes the position of the lever by the
differences in the signal properties.Selector lever from 'N' to 'R' position
The TCM only permits shifting to reverse gear if
the vehicle speed is less than 4.35 mph.
If the vehicle speed is greater than 7 km/h (approx.
4.35 mph), the clutch (C2) and the multi-plate brake
(B3) are not activated and the gearshift is thus
prevented.
Self-test and Diagnosis
The TCM monitors all the transaxle sensors and
electronic components including the PCM. If a fault
occurs, the driver is informed via a warning
indicator and a text message in the instrument
cluster. Faults are stored as DTCs in the fault
memory of the TCM and can be read out and
cleared using the IDS.
Temperature controlled torque converter
lockup
If heavy load and high ambient temperatures cause
an abnormal rise in the transmission temperature,
torque converter lockup is activated as often as
possible (temperature controlled lockup).
This reduces the slip and the heat developed in
the transmission. When the temperature drops
below +20 °C, torque converter lockup is not used.
Slip locking
When changing gear this function makes it possible
for the gears to engage more smoothly with
reduced vibration and less noise. In this mode, the
torque converter clutch is activated but not fully
locked.
The following conditions must be met for the
function to activate:
• Gear selector lever in position D or S.
• Gear 3, 4 or 5.
• The transmission input speed is 1100 rpm or more and the throttle plate opening 20 - 35%.
• The transmission fluid temperature is 40 - 120 °C.
Hill climbing
The TCM can change the shift pattern slightly when
driving uphill to avoid changing gear too often.
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The TCM detects uphill driving by comparing the
engine load transmitted by the PCM with the engine
speed. If the engine load increases and the engine
speed falls, then the TCM causes the transaxle to
shift to a lower transmission range in order to
increase the traction force.
Downhill driving
The TCM detects downhill driving by comparing
the engine load and engine speed values
transmitted by the PCM with the OSS sensor
signal. In order to prevent overloading of the
vehicle brakes, the TCM causes the transaxle to
shift to a lower transmission range.
Hill-hold function
If the vehicle is stopped on an uphill incline, the
TCM detects this through the faster drop in engine
speed compared with the drop in engine speed
when stopping on the flat. In this situation, the
hydraulics are actuated by the TCM in such a way
that the vehicle is prevented from rolling back. This
function is not used on steep inclines.
If the vehicle is parked on an uphill incline (ignition
switched off), the hill-hold function is not active
when pulling away.
Altitude correction
Lower air density results in reduced engine
performance. In order to compensate for this
operating situation, the TCM changes the shift
points.
Selector lever lock
To prevent the selector lever being accidentally
moved from the P or N position, the vehicle also
has an electrically operated selector lever lock.
This blocks the locking pin in the locking segment
and thus locks the selector lever in the P or N
position.
Shifting from P into another transmission
range
To be able to move the selector lever from P into
another transmission range, the ignition must be
switched on and the brake pedal must be
depressed (stop light switch on). The TCM detects
the position of the brake pedal via the CAN data
bus and the engaged transmission range from the
TR sensor.
The signal is then transferred from the TCM to the
select-shift switch module in order to activate the
solenoid valve in the selector mechanism
assembly.
In position P, the solenoid valve is activated and
the locking pin is pulled in so that the lock button
on the selector lever can be pressed as usual to
engage another transmission range.
In the selector mechanism assembly there is a Hall
sensor which is affected by a permanent magnet
on the gate of the selector mechanism assembly.
If the selector lever is moved from the P position,
both the Hall sensor and the selector lever lock
solenoid are simultaneously deactivated, to prevent
the selector from being kept in the N position.
If the ignition is set to "I" or "0" the solenoid valve
is deactivated. When the selector lever is in the P
position, it is mechanically locked because it has
no voltage.
Shifting from N into another transmission
range
The conditions are the same as for shifting from P
into another transmission range.
However, the lock button on the selector lever must
be pressed to be able to select R or P.
Power flow through the transmission
Clutches and brakes
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Description
Item
ABS5
Cruise control
6
Select-shift switch module
7
PCM
8
Selector lever lock
9
PWM solenoid valve – shift pressure (SLS)
10
PWM solenoid valve for main line pressure
(SLT)
11
PWM- solenoid valve – TCC (SLU)
12Description
Item
Shift solenoid S1 (open when dormant)
13
Shift solenoid S2 (closed when dormant)
14
Shift solenoid S3 (closed when dormant)
15
Shift solenoid S4 (open when dormant)
16
Shift solenoid S5 (closed when dormant)
17
The TSS sensor
18
The OSS sensor
19
The TFT sensor
20
TR sensor in TCM
21
Input signals
Hard wired
• Item 18: ISS (input shaft speed) sensor
– Supplies information on the transmissioninput shaft speed. Used for calculations, for
instance the shift process, checking the
torque converter lockup and for diagnosis of
the hydraulic/mechanical operations in the
transmission.
• Item 19: OSS sensor – Supplies information on the transmissionoutput shaft speed. Used for calculations, for
instance the vehicle speed and for diagnosis
of the hydraulic/mechanical operations in the
transmission.
• Item 20: TFT sensor – Supplies information on the transmission fluidtemperature. This information is used to
adjust the shift times and the fluid pressure.
• Item 21: TR sensor – Supplies the TCM with the information on thechosen transmission range. Starting is only
possible when the selector lever is in the P
or N position. The sensor is a permanent
magnet which creates a magnetic field over
the different Hall sensors and in this way
creates a specific voltage for each shift
operation.
Via the LIN data bus
• Item 7: Selector lever module (select-shift module)
– Indicates that the selector lever is locked inposition P and supplies information on the
sport mode status. Also transmits a control
signal during select-shift gear changes and
supplies information on the fault status in the selector lever module, so that the fault codes
in the module can be stored as required.
Via the CAN data bus
• Item 4: PCM – Stop light switch ON/OFF, is used by theTCC.
– Coolant temperature, used for diagnosis of the transmission temperature sensor and for
activating the catalytic converter.
– Engine speed >400 rpm = engine running. Used for starting the transmission fluid
pressure and diagnosis functions.
– Engine rpm. Used for checking the torque converter slip and the pressure build-up,
which have an effect on the shift comfort.
– Kickdown. If the accelerator pedal is pressed down and the throttle plate is wide open, the
PCM transmits a kickdown signal to the TCM.
– Current engine speed, used to check the line pressure of the transmission.
– Throttle plate opening, used to calculate the gear changes. During sport mode and
kickdown.
– Accelerator pedal position, used to calculate the shift threshold timings.
• Item 5: ABS module – Supplies information on the vehicle speedand also on the difference in speed between
the left-hand and right-hand wheels. Prevents
changing up if the speed difference is greater
than 40 km/h, to protect the differential in the
transmission.
• Item 6: Vehicle speed control system – Is used to calculate the acceleration,depending on the position of the resume and
set buttons.
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Output signals
Hard wired
• Item 8: PCM– Start inhibitor. Supplies the PCM with a signalthat indicates whether the engine can be
started or not.
• Item 9: Selector lever module (select-shift module)
– Controls the solenoid switch in the selectorlever unit.
• Position 10: PWM solenoid valve – shift pressure (SLS)
– Matches the line pressure to a shift pressureand is activated for certain gears.
• Position 11: PWM solenoid valve – main line pressure (SLT)
– Adjusts the linear line pressure for gearchanges without jolts.
• Position 12: PWM- solenoid valve – TCC (SLU) – Matches the line pressure to a torqueconverter lock-up pressure. Is also used for
certain gearshifts.
• Items 13 - 17: Shift solenoids S1 – S5 – The TCM checks which gear is engaged asthe solenoids become active in different
patterns.
Via the LIN data bus
• Item 7: Selector lever module (select-shift module)
– The TCM transmits a signal to the selectorlever module which activates the LED (light
emitting diode) in the selector mechanism
assembly according to the selector lever
position. Via the CAN data bus
• Item 2: GEM
– The selector lever module transmits a signalvia the TCM, which indicates that the selector
lever is locked in position P. The GEM uses
this information to control the ignition switch
key inhibit function.
– The TCM transmits a signal via the GEM to activate the back-up lamps.
• Item 3: Instrument Cluster – Current selector lever position. Used toindicate the selector lever position in the
instrument cluster.
– Check the warning lamps via the GEM. In the event of a fault, the general warning lamp
lights.
– Text messages in the instrument cluster via the GEM. The driver receives various
malfunction messages from the TCM.
– The TCM transmits signals on the CAN data bus to the PCM so that the MIL lights up in
the event of emissions-related faults.
• Item 4: PCM – Transmission fluid temperature, used tocompensate for increased loads at low fluid
temperatures.
– Gear selected, used by the engine so that it can compensate for different loads.
– Torque converter lockup, used by the engine so that it can compensate for different loads.
– Next gear planned by the TCM, used by the engine to compensate for different loads.
– Requirement for a reduced engine torque during gear shifts, the engine reduces the
engine torque during gear shifts.
– Torque limiting requirement, the engine limits the engine torque according to the gear
engaged.
• Item 5: ABS module – Current gear, used to transmit a signal, notfor shift control.
– Vehicle speed, used as reserve.
Control valve assembly
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