Table of Contents

Cooling Systems

Subject Page

Introduction .5

Cooling System N54.5

Layout .7

Radiator.7

Electric Coolant Pump (EWP) .8

Cooling System N55 .10

Engine Cooling Circuit Diagram (N55).14

Cooling System N63 .16

Coolant Pumps N63 .18

Main coolant pump .18

Auxiliary coolant pump for turbocharger cooling.18

System Protection .18

Cooling System N74 .19

Coolant Pumps N74 .20

Main coolant pump .20

Auxiliary water pump for exhaust turbochargers .20

Expansion Tank .21

Charge Air Cooling .23

Charge Air Cooling N63.23

Intercoolers .24

Electric Coolant Pump.24

Venting.24

Charge Air Cooling N74.24

Auxiliary Coolant Pump for Charge Air Cooling .24

Charge-air Cooler.24

Engine Oil Cooling.27

Engine Oil Cooling (N54).27

Oil Pump and Pressure Control (N55).28

Oil Pressure.31

Oil Pressure Sensor.31

Electronic Oil Condition Monitoring.31

Function of the Oil Condition Sensor.33

Faults/Evaluation.33

Initial Print Date: 03/11

Revision Date:

Subject Page

Electronic Oil Level Indicator .34

Static Oil Level Measurement at Engine OFF .34

Dynamic Oil Level Measurement During Vehicle Operation.36

Display Options.37

Heat Management.39

Intelligent Heat Management Options .41

System Protection.42

Measures and Displays for Engine Oil Temperature .42

Measures and Displays for Coolant Temperature.43

Subject

Page

Cooling Systems

Model: All
Production: All

■iiicmiis

After completion of this module you will be able to:

• Understand the operation of the main components in the cooling system

• Understand the different charge air cooling systems

• Understand the principles of Heat Management

• Understand the difference between static and dynamic oil measurement

• List the advantages of EWP

4

Cooling Systems

Introduction

Cooling System N54

The cooling system of the N54 engine consists of a radiator circuit and an isolated
oil cooling circuit. The fact that there is an isolated oil-cooling circuit ensures that heat
is not introduced via the engine oil into the engine's coolant system.

There is a significantly greater guantity of heat on account of this engine's increased
power of 75.5 kW/l in comparison with the N52.

This boundary condition is satisfied by the engine cooling system with its increased
performance. This increase in power was to be realized in spite of some factors less
advantageous to cooling.

Factors to be mentioned here are:

• Approximately 15% less flow area is available on account of the intercooler located
below the radiator.

• The already small amount of space provided by the engine compartment is further
limited by the accommodation of further components.

• Because the exhaust turbochargers are cooled by the coolant, an additional guanti¬
ty of heat is introduced into the system via these turbochargers.

Measures for increasing cooling-system performance:

• Coolant pump with increased power 400 W/9000 l/h

• Separation of water and engine-oil cooling

• Radiator with increased power

• Electric fan with increased power 600W for all gearbox variants
Charge-air cooling is described in the section dealing with air-intake ducting.

5

Cooling Systems

—■I

N54 Cooling System

6

Cooling Systems

Index

Explanation

Index

Explanation

1

Radiator

9

Heat exchanger

2

Gear-box oil cooler

10

Outlet temperature sensor, cylinder head

3

Outlet temperature sensor

11

Thermostat, engine oil cooler

4

Engine oil cooler

12

Coolant expansion tank

5

Thermostat for gearbox oil cooler

13

Vent line

6

Map thermostat

14

Gearbox oil cooler

7

Electric coolant pump

15

Fan

8

Exhaust turbocharger

Layout

The structure of the coolant circuit on the N54 is the same as that of the N52 engine.
The engine is flushed through with coolant in accordance with the cross-flow concept.
Cooling output can be influenced as a function of load by activating the following com¬
ponents:

• Electric fan

• Electric coolant pump

• Map thermostat

It is also possible in an N54 engine in conjunction with an automatic gearbox to utilize
the lower area of the radiator to cool the gearbox by means of the gearbox-oil cooler.
This is achieved as in the N52 engine with control sleeves, which are introduced into
the radiator tank.

Radiator

Design measures have been used to increase the performance of the radiator itself.
The performance of a radiator is dependent on its radiation surface. However, the
intercooler still had to be installed underneath the radiator, and this meant that is was
necessary to compensate for the smaller flow area available.

Compared with the N52 engine, the radiator used in the N54 engine has a block depth
which has been increased to 32 mm. In addition, the water pipes are situated closer
together than in previously used radiators. The upshot of this is an increase in the
utilizable radiation surface.

7

Cooling Systems

Electric Coolant Pump (EWP)

The coolant pump of the N54 engine is an electrically driven centrifugal pump with a
power output of 400W and a maximum flow rate of 9000 l/h. This represents a signifi¬
cant increase in power of the electric coolant pump used in the N52 engine, which has
a power output of 200 W and a maximum flow rate of 7000 l/h.

Index

Explanation

Index

Explanation

1

Pump

3

Electronics for coolant pump

2

Motor

The power of the electric wet-rotor motor is electronically controlled by the electronic
module (3) in the pump. The electronic module is connected via the bit-serial data
interface (BSD) to the ECM engine control unit.

The engine control unit uses the engine load, the operating mode and the data from the
temperature sensors to calculate the reguired cooling output. Based on this data, the
engine control unit issues the corresponding command to the electric coolant pump.

The electric coolant pump regulates its speed in accordance with this command.

The system coolant flows through the motor of the coolant pump, thus cooling both
the motor as well as the electronic module. The coolant lubricates the bearings of the
electric coolant pump.

The same rules apply to all Electric Coolant Pumps (EWP). The pump
must be filled with coolant when removed for service to prevent any
corrosion. Also, the pump impeller must be turned by hand before
installation to ensure the pump is not seized.

8

Cooling Systems

Particular care must be taken when performing servicing work to ensure that
the pump does not run dry. When the pump is removed, it should be stored
filled with coolant. The bearing points of the pump could stick fast if the pump
were not filled with coolant. This could jeopardize subseguent start-up of the
pump thus rendering the entire heat management system inoperative (the
pump not starting up could cause serious engine damage). If the pump
should ever run dry, the pump wheel should be turned by hand before finally
connecting the coolant hoses. The system should then be immediately filled
with coolant.

Particular care must be taken during assembly to ensure that the
connector is clean and dry and the connections are undamaged.

Diagnosis should be performed only with the approved adapter cables.
The information provided in the repair instructions must be observed.

Due to this coolant pump, a special filling and bleeding procedure
must be implemented for servicing:

1. Fill system with coolant via the expansion tank (AGB).

Top up coolant level to lower edge of expansion tank.

2. Close expansion tank.

3. Switch on ignition.

4. Set heating to maximum (temperature), switch on blower
(lowest stage).

5. Press accelerator pedal module right down for at least
10 seconds. The engine must NOT be started.

6. Bleeding via EWP takes approx. 12 minutes. Then check coolant
level in expansion tank, top up to MAX marking if necessary.

7. Check cooling circuit and drain plugs for leaks.

8. If the procedure needs to be repeated several times, allow DME
to completely de-energize (remove ignition key for approx.

3 minutes) and then repeat procedure as from Point 3.

Connect battery charger if battery charge level is low.

9

Cooling Systems

Cooling System N55

The cooling system of the N55 is enhanced with additional oil cooling.

Two different types of oil cooling systems are used depending on the model and appli¬
cation. In the “hot climate” version, heat transfer from the engine oil to the engine
coolant is avoided by separating the oil cooler from the engine coolant circuit. The other
version uses an auxiliary radiator in combination with an oil to coolant heat exchanger
bolted to the oil filter housing. The auxiliary radiator enhances cooling efficiency by
adding surface area to the cooling system.

N55 Cooling System

10

Cooling Systems

Index

Explanation

1

Radiator

2

Engine oil to air cooler (hot climate version)

3

Heater coil

4

Characteristic map thermostat

5

Electric coolant pump

6

Exhaust turbocharger

7

Heating heat exchanger

8

Coolant valve

9

Oil-to-coolant heat exchanger

10

Coolant temperature sensor

11

Engine oil thermostat (hot climate version)

12

Expansion tank

13

Coolant level switch

14

Equalization line

15

Auxiliary radiator

16

Electric fan

11

Cooling Systems

N55 Cooling System

Index

Explanation

Index

Explanation

A

Auxiliary radiator

7

Bypass line for small cooling circuit

B

Coolant feed line to auxiliary radiator

8

Thermostat

C

Oil-to-coolant heat exchanger

9

Electric coolant pump

D

Coolant feed line to oil-to-coolant heat exchanger

10

Exhaust turbocharger supply line

E

Coolant return line from auxiliary radiator

11

Thermostat for transmission oil cooling

1

Zone 1 feed line, heating heat exchanger

12

Coolant feed line to engine block

2

Zone 2 feed line, heating heat exchanger

14

Transmission oil-to-coolant heat exchanger

3

Coolant valve

15

Connection, transmission oil line

4

Expansion tank

16

Connection, transmission oil line

5

Equalization line

17

Return, heating heat exchanger

6

Radiator

12

Cooling Systems

The following graphic shows the connection of the auxiliary radiator to the cooling sys¬
tem. The auxiliary radiator is connected to the radiator by means of parallel coolant lines,
thus increasing the cooling surface area. This system is combined with an

oil-to-coolant heat exchanger mounted on the oil filter housing.

(See component “C” in page 12.)

N55 Auxiliary Radiator

Index

Explanation

1

Radiator

2

Auxiliary Radiator

3

Feed connection to the auxiliary radiator

4

Feed connection at the auxiliary radiator

5

Return connection to the auxiliary radiator

6

Return connection from the auxiliary radiator

If a separate oil to air cooler is not installed, an auxiliary radiator in
conjuction with an oil to coolant heat exchanger is used to cool the
engine oil.

13

Cooling Systems

Engine Cooling Circuit Diagram (N55)

©

14

Cooling Systems

Index

Explanation

1

Instrument cluster

2

Central Gateway Module

3

Coolant level switch

4

Coolant temperature sensor

5

Electric fan

6

Mechanical air flap control

7

Electric air flap control

8

Digital Motor Electronics

9

Front power distribution box

10

Junction box electronics

11

Junction box

12

Electric fan relay

14

Rear power distribution box

15

Electric fan relay (only for 850 Watt and 1000 Watt electric fan)

15

Cooling Systems

Cooling System N63

Due to the exhaust turbocharging system and the compact arrangement of the tur¬
bochargers in the V-space, the heat output of the N63 engine is very high.
Correspondingly, great significance is attached to the cooling system. In addition, an
indirect charge air cooling system has been developed for the first time where the
charge air is cooled by an air-to-coolant heat exchanger. There are two separate cooling
circuits for engine and charge air cooling.

N63 Cooling System

16

Cooling Systems

Index

Explanation

Index

Explanation

1

Radiator

12

Vent line

2

Radiator for transmission cooling

13

Coolant temperature sensor at engine outlet

3

Coolant temperature sensor at radiator outlet

14

Expansion tank

4

Electric fan

15

Vent line

5

Characteristic map thermostat

16

Transmission fluid-to-coolant heat exchanger

6

Electric auxiliary coolant pump
for turbocharger cooling

17

Auxiliary coolant radiator

7

Coolant pump

A

Electric coolant pump for charge air cooling

8

Exhaust turbocharger

B

Vent line

9

Heating heat exchanger

C

Intercooler

10

Duo-valve

D

Expansion tank for charge air cooling

11

Electric auxiliary coolant pump
for vehicle heating

E

Radiator for charge air cooling

17

Cooling Systems

The engine cooling system undertakes the classic task of carrying heat away from the
engine and maintaining a defined operating temperature as constant as possible. As on
the N54 engine, the two turbochargers are also cooled.

Coolant Pumps N63
Main coolant pump

The N63 engine features a conventional coolant pump that is driven by the belt drive.
This pump cannot be used to continue cooling the turbochargers after the engine has
been shut down. For this reason the N63 is also eguipped with an auxiliary coolant
pump.

Auxiliary coolant pump for turbocharger cooling

The electric coolant pump on the N54 engine features an after-running function to carry
away the heat build-up from the turbochargers after the engine has been shut down.

For this function, the N63 engine is eguipped with an additional electrically operated
coolant pump with an output of 20 W. This pump is also used during engine operation to
assist turbocharger cooling.

The auxiliary electric coolant pump cuts in, taking the following factors into consideration:

• Coolant temperature at engine outlet

• Engine oil temperature

• Injected fuel guantity

The heat input into the engine is calculated based on the injected fuel guantity. This
function is similar to the heat management function on 6-cylinder engines.

The after-running period of the auxiliary electric coolant pump can extend up to 30 min¬
utes. The electric fan also cuts in to improve the cooling effect.

n As in previous systems, the electric fan runs for a maximum
( ! of 11 minutes, however, it now operates more frequently.

System Protection

As on the N54 engine, the N63 in the event of the coolant or engine oil being subject to
excessive temperatures, certain functions in the vehicle are influenced in such a way that
more energy is made available to the engine cooling system, i.e. temperature increasing
loads are avoided.

18

Cooling Systems

Cooling System N74

Because of the turbocharging and indirect charge air cooling, the N74 engine has the
same cooling reguirements as the N63 engine. Conseguently it too has two separate
cooling circuits. One is for cooling the engine and exhaust turbochargers, the other is for
charge air cooling and for cooling the two engine control units.

The engine cooling system performs the task of drawing heat off the engine and
maintaining the operating temperature as constant as possible. As on the N54 and N63
engines, the two exhaust turbochargers are also cooled.

On the N74 engine, the coolant passages have been integrated mainly in the engine
block. Optimizations to the engine cooling circuit have enabled a significant reduction in
the coolant guantity for the bypass mode, thus shortening the warm-up phase.

The coolant feed line downstream of the coolant pump is routed directly beside the
engines main oil duct. The oil in the main oil duct flows in the opposite direction to the
coolant. This enhances the heat exchange between the two media, and has a positive
effect on the engine oil temperature. The overall cooling effect is comparable with that
of an engine oil-coolant heat exchanger.

The coolant passages in the cylinder heads are similar to the N63 engine. The coolant
flows through the cylinder heads diagonally from the outside to the inside, whereby it
flows in at the rear (outside) and flows out at the front (inside). This is also known as
diagonal cooling.

As on the N63 engine, an additional electric coolant pump is used
f which supplies the bearings of the exhaust turbochargers with
* coolant.

19

Cooling Systems

N74 Cooling System

® ®

® ® ® @® © ® ® s

Coolant Pumps N74
Main coolant pump

The main coolant pump is a conventional coolant pump driven mechanically by the belt
drive.

Auxiliary water pump for exhaust turbochargers

Like the N63 engine, the N74 engine has an electric auxiliary water pump which allows
heat to be dissipated from the exhaust turbochargers even after the engine has been
switched off. This coolant pump has an electrical power output of 20 W. It is also used
during engine operation to support exhaust turbocharger cooling. The electric auxiliary
coolant pump is activated based on the following factors:

• Coolant temperature at the engine outlet

• Engine oil temperature

• Injected volume of fuel

20

Cooling Systems

Index

Explanation

1

Radiator

2

Radiator for transmission cooling

3

Coolant temperature sensor at radiator outlet

4

Electric cooling fan

5

Characteristic map thermostat

6

Electric auxiliary coolant pump for turbocharger cooling

7

Coolant pump (mechanical)

8

Exhaust turbocharger

9

Heater core

10

Duo Heater valve

11

Electric auxiliary coolant pump for vehicle heating

12

Coolant temperature sensor at engine outlet

13

Filling canister

14

Expansion tank

15

Vent line

16

Transmission fluid thermostat and the fluid-to-coolant heat exchanger

The injected volume of fuel is used to calculate the heat contribution to the engine.
Operation is similar to that of the heat management system on the 6-cylinder engines.
The after-running period of the electrical auxiliary coolant pump can last up to 30
minutes.

To improve the cooling effect, the electric fan is also switched on.

| As in previous systems, the electric fan runs for a maximum of
*— 11 minutes, however, it now operates more frequently.

Expansion Tank

For space reasons, the expansion tank is located in the front fender behind the wheel
arch. A separate filling canister bolted to the front of the engine enables filling. The
expansion tank and filling canister are interconnected by an expansion and tank ventila¬
tion line.

21

Cooling Systems

22

Cooling Systems

Charge Air Cooling

Charge Air Cooling N63

With the introduction of the N63 engine, indirect charge air cooling is used for the first
time at BMW. Heat is taken from the charge air by means of an air-to-coolant heat
exchanger. This heat is then given off via a coolant-to-air heat exchanger into the ambi¬
ent air. For this purpose, the charge air cooling system has its own low temperature
cooling circuit, which is independent of the engine cooling circuit.

N63 Charge Air Cooling System

©®

Index

Explanation

Index

Explanation

A

Electric coolant pump for charge air cooling

D

Expansion tank for charge air cooling

B

Vent line

E

Radiator for charge air cooling

C

Intercooler

23

Cooling Systems

Intercoolers

The intercoolers are installed on the end faces of the cylinder heads. They operate in
accordance with the counterflow principle and cool the charge air by up to 80°C.

Electric Coolant Pump

The coolant circuit for charge air coolant is operated with a 50 W pump. This pump
does not run automatically when the engine is turned on.

Pump actuation depends on the following values:

• Outside temperature

• Difference between charge air temperature and outside temperature

Venting

A separate venting routine is provided for the purpose of venting the low-temperature
circuit of the charge air cooling system. This venting is initiated in the same way as for
the cooling circuit on 6-cylinder engines.

The venting test module can be found in the “Service Functions” section of the diagnos¬
tic program.

Charge Air Cooling N74

The N63 engine was the first BMW engine to use indirect charge air cooling; this has
now also been adopted for the N74 engine. The heat is extracted from the charge air by
means of an air to coolant heat exchanger. This heat is then released to the ambient air
across a coolant to air heat exchanger. To achieve this, the charge air cooling has its own
low-temperature cooling circuit. This is independent of the engine cooling circuit.

Auxiliary Coolant Pump for Charge Air Cooling

The cooling circuit for charge air cooling is operated with a 50 W pump. It does not run
automatically when the engine is switched on.

The following parameters are used for the auxiliary pump activation:

• Outside temperature

• Difference between charge-air temperature and outside temperature.

Charge-air Cooler

The charge air coolers (intercoolers) are attached to the intake system near the rear of
the cylinder heads. They enable efficient cooling of the charge air by extracting heat
energy from the air charge and carrying it away to the coolant to air heat exchanger
located in the front of the vehicle.

24

Cooling Systems

N74 Charge Air Cooling System

Index

Explanation

1

Radiator for charge air cooling

2

Electric coolant pump for charge air cooling

3

Engine control unit

4

Expansion tank

5

Charge-air cooler

25

Cooling Systems

26

Cooling Systems

Engine Oil Cooling

One of the main purposes of the ECM is to monitor and control the Engine-Oil Cooling
which includes the actuation of several components. In the following pages you will find a
generic explanation on how this system works. For more detailed information please
access BMW Training Reference Manuals found on-line.

Engine Oil Cooling (N54)

The N54 engine is equipped with a high performance engine-oil cooler. The pendulum-
slide pump delivers the oil from the oil sump to the oil filter. A thermostat flanged to the
oil-filter housing admits the oil to the engine-oil cooler. The engine-oil cooler is located
in the right wheel arch. The thermostat can reduce the resistance opposing the oil by
opening the bypass line between the feed and return lines of the engine-oil cooler. This
ensures that the engine warms up safely and quickly.

27

Cooling Systems

Oil Pump and Pressure Control (N55)

The oil pump has been redesigned with regard to the functionality and durability of the
Duroplast reciprocating slide valve. The oil pump used in the N55 engine is a further
development of the shuttle slide valve volume control oil pump. The activation of the oil
pump is adapted by the engine management and controlled through an oil pressure
control valve.

The delivered oil volume is controlled by means of the oil pressure, based on specific
reguirements. The modifications, compared to previous pumps, are primarily in the pump
activation system. The oil pressure no longer acts directly on the control piston but
rather directly on the slide valve. The engine management activates the electrohydraulic
pressure control valve, which affects the oil pressure at the slide valve control mecha¬
nism within the oil pump, altering the pump output. This has the advantage of avoiding
power losses by running the oil pump only when needed.

The electrohydraulic pressure control valve controls the pump output and is bolted to
the front of the engine block. It is operated based on a characteristic map within the
DME (ECM) which in turn is based on feedback from the oil pressure sensor. The N55
uses a special oil pressure sensor for this purpose which functions in the similar way as
the HPI fuel pressure sensor.

Characteristic map-controlled oil pressure (N55)

1000 2000 3000 4000 5000 6000 7000

Index

Explanation

Index

Explanation

A

Oil pressure (bar)

3

Characteristic map-controlled
oil pressure, no load

B

Engine speed (rpm)

4

Saving potential, full load

1

Oil pressure control, hydraulic/ mechanical

5

Saving potential, no load

2

Characteristic map-controlled
oil pressure, full load

28

Cooling Systems

The oil pressure generated by the oil pump (2) is delivered to the engine’s lubricating
points and hydraulic actuators. This system uses oil pressure feed back to control the
desired operating oil pressure. For this purpose, the oil pressure downstream of the oil
filter (7) and engine oil-to-coolant heat exchanger (9) is adjusted by the DME (map-con¬
trolled) via the pressure control valve (4) to the pressure control valve (3).

The actual generated oil pressure is registered by the oil pressure sensor (10) and
recognized by the engine management.

In the event of an electrical malfunction, the oil pressure is set to the default control
setting. The pump compression springs are allowed to expand, moving the slide valve
to its maximum oil pressure position.

Hydraulic diagram of the N53 engine oil circuit with electronic pressure control

Index

Explanation

Index

Explanation

1

Oil Pan

8

Filter By-pass valve

2

Volume controlled oil pump

9

Engine oil to coolant heat exchanger

3

Pressure regulating valve

10

Oil Pressure sensor

4

Electro-hydraulic pressure regulating valve

11

Lubricating points, cylinder head

5

Non-return valve

12

Lubricating points, engine block

6

Outlet valve at the filter

13

Oil spray nozzles, piston crowns

7

Oil filter

Note: The N53 hydraulic circuit diagram shown is for explanation of the oil
pressure control only, and does not apply directly to the N55 engine.

29

Cooling Systems

N55, oil pump and pressure control valve

Index

Explanation

1

Oil pressure control valve

2

Oil pump

3

Oil pressure sensor

30

Cooling Systems

Oil Pressure

Since the N55 engine has an oil pump with electronic volumetric flow control, it is nec¬
essary to measure the oil pressure precisely. For this reason, a new oil pressure sensor
is installed.

Advantages of the new oil pressure sensor:

• It now measures absolute pressure (previous measured relative pressure).

• It is characteristic map control in all speed ranges.

Oil Pressure Sensor

The new oil pressure sensor can now determine the
absolute pressure.

The sensor delivers a more accurate pressure reading which
is reguired for the electronic volume control oil pump func¬
tion.

The sensor design is identical to that of the (high) fuel pres¬
sure sensor. The DME supplies a voltage of 5 Volt to the oil N55, oil P ressure sensor
pressure sensor.

Electronic Oil Condition Monitoring

The oil guality sensor is used for measuring the oil level as on previous BMW engines.

No oil dipstick is used in most BMW NG Engines.

There is no dipstick including the guide tube on most BMW NG engines. This repre¬
sents a convenience function for the customer while enabling more accurate recording
of the engine oil level.

The engine oil level is measured by an oil condition/guality sensor and indicated in the
central information display (CID) or KOMBI. The engine oil temperature and the oil condi¬
tion are also registered or calculated by the oil condition sensor. The signal from the oil
condition sensor is evaluated in the ECM. The evaluated signal is then routed via the
proper Bus to the instrument cluster and to the CID.

Registering the engine oil level in this way ensures the engine oil level in the engine does
not reach critically low levels thus protecting the engine from the associated damage. By
registering the oil condition, it is also possible to determine when the next engine oil
change is due. Overfilling the engine with oil can cause leaks - a corresponding warning
is therefore given.

31

Cooling Systems

Oil condition sensor

Index

Explanation

Index

Explanation

1

Housing

6

Oil Condition Sensor

2

Outer Metal Tube

7

Sensor Electronics

3

Inner Metal Tube

8

Oil Pan

4

Engine Oil

9

Temperature Sensor

5

Oil Level Sensor

32

Cooling Systems

Function of the Oil Condition Sensor

The sensor consists of two cylindrical capacitors arranged one above the other. The oil
condition is determined by the lower, smaller capacitor (6). Two metal tubes (2 + 3),
arranged one in the other, serve as the capacitor electrodes. The dielectric is the engine
oil (4) between the electrodes. The electrical property of the engine oil changes as the
wear or aggiing increases and the fuel additives break down.

The capacitance of the capacitor (oil condition sensor) changes in line with the change in
the electrical material properties of the engine oil (dielectric). This means that this capaci¬
tance value is processed in the evaluation electronics (7) integrated in the sensor to form
a digital signal.

The digital sensor signal is transferred to the ECM as an indication of the status of the
engine oil. This actual value is used in the ECM to calculate the next oil change service
due.

The engine oil level is determined in the upper part of the sensor (5). This part of the
sensor is located at the same level as the oil in the oil pan. As the oil level drops (dielec¬
tric), the capacitance of the capacitor changes accordingly. The electronic circuitry in the
sensor processes this capacitance value to form a digital signal and transfers the signal
to the ECM.

A platinum temperature sensor (9) is installed at the base of the oil condition sensor for
the purpose of measuring the engine oil temperature.

The engine oil level, engine oil temperature and engine oil condition are registered
continuously as long as voltage is applied at terminal KL_15. The oil condition sensor is
powered via terminal KL_87.

Faults/Evaluation

The electronic circuitry in the oil condition sensor features a self-diagnosis function. A
corresponding error message is sent to the ECM in the event of a fault in the oil condi¬
tion sensor.

33

Cooling Systems

Electronic Oil Level Indicator

The oil level is measured in two stages:

• Static oil level measurement while the vehicle is stationary

• Dynamic oil level measurement during vehicle operation

Static Oil Level Measurement at Engine OFF

This is only a reference measurement as the oil condition sensor
(OZS) is flooded when the engine is turned off and can only detect
the minimum oil level. The oil level is measured correctly only when
the engine is running (see Dynamic oil level measurement).

After switching on the ignition, the static oil level measurement provides the driver with
the opportunity of checking whether there is sufficient engine oil for safely and reliably
starting the engine.

1. It is important that the vehicle is parked horizontally otherwise the oil level
measurement may be incorrect.

2. Select on-board computer function "Service" -> "Oil level".

If there is sufficient engine oil for safe and reliable engine start, a graphic appears in the
CID in the form of an engine with a green oil sump.

Text fur Zustand:

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Messung moglich

IW p '."—M
■ •

Olstand in

Grefnung

34

Cooling Systems

If the oil level is close to minimum, the
graphic appears with a yellow oil sump
and an oil dipstick that represents the low
oil level in yellow.

A top-up request +1 liter additionally
appears as a text message. The display
will not change if less than 1 liter of oil is
topped up. MAX is indicated only after top¬
ping up a quantity of 1 liter.

If the oil level drops below minimum, the
graphic appears with a red oil sump and
an oil dipstick that represents the low oil
level in red.

A top-up request +1 liter will additionally
appear as a text message.

The display will not change if less than 1
liter of oil is topped up. MAX is indicated
only after topping up a quantity of 1 liter.

If the oil level is above maximum, the
graphic appears with a yellow oil sump and
an oil dipstick that represents the high oil
level in yellow.

A text message is also displayed for the
driver.

35

Cooling Systems

Dynamic Oil Level Measurement During Vehicle Operation

Always perform the dynamic oil level measurement (approx. 5 min¬
utes driving time) after an oil change. The oil level could be misinter¬
preted as the oil level last stored is initially displayed after an oil
change. No oil level is initially stored after replacing or reprogram¬
ming the engine control unit. "Oil level below min" is therefore dis¬
played. The correct oil level is indicated after running the engine for
approx. 5 minutes.

1. Start engine.

2. Select on-board computer
function - “Check oil level".

3. The oil level is measured. A clock
symbol may appear while the level
measurement is running. The clock
symbol appears for up to 50 sec¬
onds after starting the engine when
there is no measured value or the
long-term value last stored is not
within the tolerance range of the cur¬
rently measured oil level.

Dynamic oil level measurement begins when following values are reached:

• Engine temperature > 60°C

• Engine speed > 1000 rpm

• Transverse and longitudinal acceleration < 4-5 m/s2.

The transverse acceleration signal is supplied by the DSC. The longitudinal acceler¬
ation is calculated from the speed and time factors.

• Increase < 5% after covering a distance of approx. 200 m. The increase value is
detected by the ambient pressure sensor in the ECM.

On reaching this value, the oil level indicator is updated approx. 5 minutes after starting
vehicle operation. The oil level is then continuously measured. The indicator is updated
at 20 minute intervals. The "Check oil level" menu in connection with the dynamic oil
level measurement is exited while driving (vehicle speed > 0) approx. 15 seconds after
the oil level is displayed.

36

Cooling Systems

Display Options

Significance

Remark

Display

Oil OK with engine
stationary

The oil level appears in the CID in the
form of a graphic together with the "OK"
message, indicating that the oil level is in
the safe operating range.

Text fur Zustand:
Koine gcnaue
Messung moglich
Olstand in
Ordnung

Oil level OK at idle speed

The oil level appears in the CID in the
form of a graphic together with the "OK"
message, indicating that the oil level is in
the safe operating range.

A further graphic showing a dipstick
appears above the displayed graphic. It
shows the oil level in green.

max

min

Oil level too low

The oil level appears in the CID in the
form of a graphic together with the
request to top up with 1 liter of oil.

If the oil is not topped up, this request is
repeatedly indicated until the minimum oil
level is exceeded.

max

min

Oil level too high

The oil level appears in the CID in the
form of a graphic together with the indica¬
tion that the maximum oil level has been
exceeded. The excess engine oil must be
extracted in the workshop down to the
maximum limit.

If no oil is extracted, this request will be
repeated until the oil level drops below the
maximum limit. This represents an
advantage that extends beyond the user
friendliness of the monitoring system.

Over filling of the engine that can cause
leaks is indicated as a warning in the
instrument cluster.

max

min

There is a problem with the measurement
system if SERVICE appears in the display.
In this case, the oil level is forecast from
the oil consumption last measured and
shown in the display. It is not necessary to
immediately visit a workshop. The remain¬
ing kilometers are shown in the service
menu. In the event of the instrument clus¬
ter failing, the oil level can also be read out
with the diagnosis tester.

37

Cooling Systems

38

Cooling Systems

Heat Management

The engine control unit of the N54 engine controls the coolant pump according to
requirements:

• Low output in connection with low cooling requirements and low outside
temperatures

• High output in connection with high cooling requirements and high outside
temperatures

The coolant pump may also be completely switched off under certain circumstances,
e.g. to allow the coolant to heat up rapidly during the warm-up phase. However, this
only occurs when no heating is required and the outside temperature is within the per¬
mitted range.

The coolant pump also operates differently than conventional pumps when controlling
the engine temperature. To date, only the currently applied temperature could be
controlled by the thermostat.

The software in the engine control unit now features a calculation model that can take
into account the development of the cylinder head temperature based on load.

In addition to the characteristic map control of the thermostat, the heat management
system makes it possible to use various maps for the purpose of controlling the coolant
pump. For instance, the engine control unit can adapt the engine temperature to match
the current operating situation.

This means that four different temperature ranges can be implemented:

• 108°C ECO mode

• 104°C Normal mode

• 95°C High mode

• 90°C High + map-thermostat mode

The control system aims to set a higher cylinder-head temperature (108°C) if the
engine control unit determines ECO (economy) mode based on the engine perfor¬
mance.

The engine is operated with relatively low fuel consumption in this temperature range as
the internal friction is reduced.

39

Cooling Systems

An increase in temperature therefore favors slower fuel consumption in the low load
range. In HIGH and map-thermostat mode, the driver wishes to utilize the optimum
power development of the engine. The cylinder-head temperature is reduced to 90°C
for this purpose. This results in improved volumetric efficiency, thus increasing the
engine torque. The engine control unit can now set a certain temperature mode adapted
to the respective operating situation. Consequently, it is possible to influence fuel
consumption and power output by means of the cooling system.

The temperatures specified only ever represent a target value, the attainment of which is
dependent on many factors. These temperatures are first and foremost not attained
precisely.

The consumption-reducing and power increasing effects arise in each case in a
temperature spectrum. The function of the cooling system is to provide the optimal
cooling output according to the boundary conditions under which the engine is being
operated.

The temperatures specified only ever represent a target value, the attainment of which is
dependent on many factors. These temperatures are first and foremost not attained
precisely.

The consumption-reducing and power increasing effects arise in each case in a
temperature spectrum. The function of the cooling system is to provide the optimal
cooling output according to the boundary conditions under which the engine is being
operated.

40

Cooling Systems

Intelligent Heat Management Options

The previous section dealt with the various temperature ranges in which heat
management is effected. However, an electrically driven coolant pump makes available
even further options. For instance, it is now possible to warm up the engine without
recirculating the coolant or to allow the pump to continue to operate after turning off the
engine to facilitate heat dissipation. The advantages offered by this type of pump are
listed in the following table:

Consumption

• Faster warm-up as coolant is not recirculated
until needed

• Increased compression ratio due to greater
cooling output all full load as compared to simi¬
lar engines without this option

Emissions

• Faster engine warm-up by drastically reduced
pump speed and the lower volumetric flow of
coolant

• Reduced friction

• Reduced fuel consumption

• Reduced exhaust emissions

Power Output

• Component cooling independent of engine
speed

• Reguirement controlled coolant pump output

• Avoidance of power loss

Comfort

• Optimum volumetric flow

- Heating capacity reduced as reguired

- Residual heat with engine stationary

Component Protection

• After-running of electric coolant pump =
improved heat dissipation from engine switch
off point. Allows protection of turbochargers
by reduced oil “coking” during heat soak.

41

Cooling Systems

System Protection

In the event of the coolant or engine oil being subject to excessive temperatures while
the engine is running, certain functions in the vehicle are influenced so that more energy
is made available to the engine-cooling system, i.e. temperature-increasing loads are
avoided. These measures are divided into two operating modes:

• Component protection

• Emergency

Measures and Displays for Engine Oil Temperature

Engine oil
temp
(T-oil C)

Operating

mode

Display in
Cluster

Power output
reduction,

Air conditioning

Power output
reduction,
Engine

Torque
converter
clutch lockup

148

Start 0 %

Start 0 %

149

-

150

Component

Protection

-

151

Component

Protection

-

From here =
clear reduction

152

Component

Protection

End - 100%

153

Component

Protection

154

Component

Protection

155

Component

Protection

156

Component

Protection

157

Component

Protection

n

End @ 90 %

158

Emergency

Active

159

Emergency

Active

160

Emergency

Active

161

Emergency

Active

162

Emergency

Active

163

Emergency

Active

42

Cooling Systems

Measures and Displays for Coolant Temperature

Coolant

(T-Coolant)

Operating

mode

Display in
Cluster

Power output
reduction,

Air conditioning

Power output
reduction,
Engine

Torque
converter
clutch lockup

115

116

117

Component

Protection

Start 0 %

Start 0 %

118

Component

Protection

-

From here =
clear reduction

119

Component

Protection

-

-

120

Component

Protection

PH

End - 100%

-

121

Component

Protection

-

122

Component

Protection

-

Active

123

Component

Protection

-

Active

124

Component

Protection

End @ 90 %

Active

125

Emergency

Active

126

Emergency

Active

127

Emergency

Active

128

Emergency

Active

129

Emergency

Active

43

Cooling Systems

44

Cooling Systems