TABLE OF CONTENTS

Subject Page

Introduction .2

Body.3

Specifications.4

Hood/Front Grille .6

Doors/Mirrors.7

Interior .9

Climate Control Systems .15

Cargo Area.22

Tailgate.25

D rivet rain .28

Front Suspension .31

Rear Suspension .33

EHC Control System and EHC 2 .35

Steering .60

Brakes .61

Wheels & Tires .62

Fuel Supply System .63

Exhaust System .64

Power Distribution .65

Component Locations

66

Introduction

The X5 marks BMW’s introduction into the luxury “Sports Activity Vehicle (SAV)” niche seg¬
ment of the Sport Utility Vehicle market. While carrying the designation X5, the vehicle is not
based on the 5 Series but it is its own new car-like platform. The X5 is offered with two
engine variants:

• The 4.4 liter M62 TU engine equipped with the A5S 440 Z automatic transmission.

• The 3 liter M54 engine with either the GM 5 automatic (A5S360R) or 5 speed manual
transmission (S5D280Z).

The X5 incorporates the following
features:

• Four wheel independent sus¬
pension (BMW tradition)

• Full time - all wheel drive
(planetary gear transfer case)

• All road vehicle (ON/OFF road
capabilities)

• High ground clearance

• Unitized body and Chassis
(car like ride and handling)

• Double pivot front suspension

• “Integral Link” rear suspen¬
sion with air spring self level¬
ing

• X5 specific traction control
system

Two different suspension options are offered (standard and sport) with different springs,
shock absorbers and stabilizers.

The X5 has 180 mm ground clearance, for both suspensions to allow off road travel.
However, the suspension travel is the same as the E39 which allows the X5 to retain a car
like feel when driven every day.

2

Body

The design of the X5 originated in California at BMW’s Design Works. The SAV look was
further developed and refined in Munich. Traditional BMW features such as the Kidney
grilles, quad headlights, reverse link rear side window trim and typical rear tail light treat¬
ment allow the X5 to assume a BMW identity. Yet the unique side and hood treatments as
well as the large wheel house openings and high ground clearance set the X5 apart as its
own distinctive vehicle.

The design criteria for the X5 was to develop a vehicle with the superb handling and sporty
driving characteristics that are typically BMW, yet produce an all wheel drive vehicle that can
also be used off-road. This was achieved through the use of independent front suspension
and multi-link rear suspension components that are taken from the E38/E39 vehicle design
and expanded by the addition of front drive components.

The entire body shell/frame assembly of the
X5 is reinforced to ensure optimized body
rigidity.

In addition to the cross bracing on the front
suspension/engine carrier, an additional
panel is installed between the bulkhead and
transmission tunnel.

The floor pan of the X5 is reinforced with
additional ribbing and cross braces to
increase the lateral rigidity. A continuous seat
cross brace is connected to the floor pan
and side sill for reinforcement.

3

Specifications

00530011-1

4

Specifications

Dimensions:

X5 3.0i

X5 4.4i

X5 4.6is

Doors

5

5

5

Length

4666 mm

4666 mm

4666mm

Width

1872 mm

1872 mm

1872mm

Height

1717 mm

1717 mm

1717mm

Engine:

X5 3.0i

X5 4.4i

X5 4.6is

Designation

M54B30

M62 TU B44

M62 TU B46

Engine Management Syst.

MS 43

ME 7.2

ME 7.2

Horsepower (HP)

225@5900RPM

282@5400RPM

340@5700RPM

Torque

214@3500RPM

324@3600RPM

350@3700

Bore

84mm

92mm

93mm

Stroke

89.6mm

82.7mm

85mm

Compression

10.2:1

10.0:1

10.5:1

Vechicle Weigth withTransmission:

X5 3.0i

X5 4.4i

X5 4.6is

Automatic 2015 Kg

Manual 1990 Kg

2085 Kg

Not Available

2188 Kg

Not Available

General

X5 3.0i

X5 4.4i

X5 4.6is

Fuel

921

921

921

Drag Coefficient

0.35

0.36

0.38

Payload

610 kg

555 kg

N/A

Roof Load

150 kg

150 kg

150 kg

Gross Weight

Manual Trans.

2600 kg

Not Available

N/A

Gross Weight

Auto Trans.

2625kg

2650kg

N/A

Cargo Volume

16.1/54.4 cu ft.

16.1/54,4 cuft.

16.1/54,4 cuft.

Towed Weight Braked
Manual

1600 kg

Not Available

N/A

Towed Weight Braked
Automatic

1700 kg

750 kg

N/A

Turning Circle

39.7 ft.

39.7 ft.

39.7 ft.

5

Hood/Front Grille

The hood on the X5 is distinctive, with two IHKA air intake hood scopes in the center lead¬
ing down to the traditional BMW twin grilles.

Workshop Hint:

Hood prop tool number 90 88 6 512 170

Hood Scoops

The grilles are integrated into the hood with
the secondary hood latch springing out from
the grille when the hood is opened.

The four round headlights complete the front
end with Xenon low beans as an option for
the X5. The fog lights as well as the headlight
washers are integrated into the bumper.

6

Doors/Mirrors

The doors on the X5 incorporate side bars which serve as side impact protection without
the use of the metal hooks found on the sedans. The mirrors are aero style that includes
cascade lighting at the bottom of the mirror for vehicle entry at night. The lights are switched
on when the vehicle is unlocked to light the ground around the door. The cascade lighting
is optional. Control relay for the cascade lighting is located in the electrical carrier above the
glove box.

Running boards, integrated into the rocker panels, provide ease of entry on the left
and right sides.

7

Door Handle

The door handles are similar in design to the
E46 and pull out and upward for opening.
Removal of the handles is also similar to the
E46.

There are no serviceable components on the
lock/latch. The assembly must be replaced as
a unit.

The lock cylinder is removed by removing the
torx screw through the access hole in the door.
Once the screw is removed, the lock cylinder
can be pushed out of the handle assembly.

The handle is removed by loosening the hex
nut holding the handle to the latch mechanism.

The handle is then removed by pulling it out
and down to release it from the latch. The han¬
dle is turned down to the left to release it from
the door latch assembly.

8

Interior/Seats

The instrument cluster and dashboard layout is similar to other BMW models with all of the
controls in easy reach of the driver. The instrument cluster variations (high and base) are
taken from the E39 as are all driver information electronic systems.

High Cluster

Base Cluster

62530012

62530013

The center console contains the radio or navigation system and the climate control panel
along with the central switch panel (SZM).

64530003

9

Interior

Located above the windshield in the center is the overhead console that contains the uni¬
versal remote switch panel, interior lighting/map panel, sunroof switch and grille for the tele¬
phone hands-free microphone. The light panel contains a single bulb which is controlled by
the ZKE, as well as two map reading lamps. The switch provides a ground signal which the
GM recognizes as a request to either turn the interior lights on or off. If the switch is held >
3 seconds, the lights are switched off in the work shop mode as on other models.

Left Map Light

Interior Light

Right Map Light

Universal Remote

Incorporated into the overhead con¬
sole, behind the universal remote
switch, is a sunglass storage com¬
partment

63530002

Sunglass Holder

10

Interior/Seats

Two interior seat options (comfort and sport) are available for the X5. The seats are mount¬
ed high in the cabin for good visibility and offer 8-way power, memory adjustments with
lumber support. The seat/mirror memory control module and switch assembly is located on
the side of the driver’s seat.

11

Rear Seats

The rear seating area on the X5 offers 1472mm width and 977mm of head room for com¬
fortable seating for the rear passengers. Rear cup holders are installed in the center con¬
sole below the IHKA outlet grilles which incorporates a separate blower fan for the rear
seating area.

The rear seats have a 60/40 split with the fold down center arm rest on the left seat back.
The center arm rest also includes the optional folding ski bag.

60 Split

40 Split

12

Rear Seat Backrest Adjustment

Electric rear seat backrest adjustment is
available on the X5 as optional equipment.
Each backrest can be adjusted individually
up to 20 degrees, the backrest adjustment
option consists of the following:

• Left/Right adjusting motors with gear
drive and seat back hooks - located
behind the seat backs on the shock
towers. The rear seat backs lock into
the “D" shaped hooks on the backrest
adjustment linkage.

Left/Right adjusting switches - located
in the interior light housing in the head¬
liner panel.

• Left/Right adjusting switches - located
in the rear on the left and right sides of
the “D” pillar behind the upper tailgate.

13

System Operation

The seat backs are adjusted from the two different locations as follows:

• The switches in the interior light housing receive operating power through the seat back
relay when the ignition is switched on KL 15. The GM controls the operation of the relay
and the switches provide the ground.

• The switches in the “D” pillar receive KL 30 and allow seat back adjustment whenever
the rear tailgate is opened to gain access to the switches.

• The adjustment motors receive power and ground directly from the switches.

KL30

14

Climate Control Systems (IHKR/IHKA)

Two climate control systems are offered on the X5, the manual IHKR system is standard
equipment on the 3 liter X5 and the IHKA system is available as an option. The IHKR is a
new system for US production and the IHKA is taken from the E39 vehicles.

Condenser/Receiver Dryer

The X5 incorporates a new design air conditioning condenser/receiver dryer for both the
manual (IHKR) and the automatic (IHKA) systems. The dryer cartridge and condenser are
one component with the dryer integrated on the left side. The dryer cartridge contains a
replaceable filter screen and dryer unit.

The condenser is partitioned which divides the condenser into cooling sections. The hot
refrigerant flows across the condenser and into the dryer through inlet holes at the lower
1/3 section of the cooling fins. After the refrigerant passes through the dryer it returns to
the evaporator through the outlet hole and bottom 1/3 section of the condenser.

Condenser Side View

64530000

15

Climate Control System (IHKR)

The manual system is controlled through the use of bowden cables for air distribution and
electronic control for temperature regulation and blower speed. One stepper motor is used
for the fresh/recirculated air intake.

The IHKR incorporates the following features:

• Fresh air intake grilles integrated into the hood - the fresh air passes through the single
micro filter installed in the center of front bulkhead.

Intake
Fresh Air

The air then passes through the air duct, which is bolted to the bulkhead, and enters the
heater - A/C unit through the non-return flaps.

16

IHKR Control Unit

• Integrated control module with oper¬
ating panel.

• IHKR heater/air conditioner unit with

- 1 heat exchanger temperature sensor

- 1 evaporator temperature sensor

- 1 footwell temperature sensor

- Blower motor

- 1 stepper motor (high speed fresh/rcirc air)

17

IHKR Operation

IHKR system operation is as follows:

• Temperature Control - The desired interior temperature is set with the rotary knob on the
control panel. Control of the interior temperature is carried out electronically by the con¬
trol module’s cycling of the water valve to regulate coolant flow through the heat
exchanger.

• Air Distribution - Air distribution is set mechanically through the use of gear linkages and
bowden cables. The air can be set for:

- Footwell or blended between footwell/face vent or footwell and defrost

- Defrost or blended between footwell/defrost or defrost/face vent

- Face vent or blended between face vent/footwell or face vent/defrost

• Blower Control - Blower fan speed is controlled through a final stage with infinitely vari¬

able speed control.

The push buttons on the control panel are used to:

• Switch between fresh air and recirculating air inlet modes

• Request for A/C activation

• Activation of the rear window defogger

18

IHKR IPO

KL31

KL30

eiiiih

Fan Speed

Request

A/C Compressor

Recirculation

nwmm=,

Rear Defrost

Temperature
^T^Control

Evaporator
Temperature Sensor

Refrigerant Pressure Sensor

WATER

OUTLET

A

TEMP

SENSOR

IHKR

Blower Relay

Washer Jet Heater

Blower

Blower Motor Ouput Stage

Rear Window Defoger Relay

iiP

Aux. Fan Speed Relay Control

Fresh Air Flap Motor

Water Valve

DIS & Modic

64530006.cdr

19

Climate Control System (IHKA)

The IHKA is standard equipment on the X5 with the M62 engine and optional equipment
on the M54 version. The IHKA system is taken from the E39 sedan and includes all func¬
tions and features of the IHKA currently installed in the E39.

Features of the IHKA system include:

• Integrated control panel/module.

• Separate temperature control for the driver and front passenger.

• Air flap control through the use of bussed stepper motors.

• Automatic Recirculation Control (AUC).

• Recirculation air flap control from the MFL.

• “REST” function for residual heat when vehicle is stopped.

• Service station feature that closes the water valves when stopped to prevent hot water
circulating into the heater cores.

• A/C compressor clutch activation through a final stage control.

• Center face vent stratification control through a bowden cable.

• Separate blower motor for rear passenger compartment

The rear blower motor is located below the center storage box behind the center air outlet
grilles. The blower speed control is mounted in the panel below the outlets. Cool or strati¬
fied air is available at the center outlets.

20

IHKA Air Flow

The micro filter for the IHKA system is installed in the engine compartment in the center of
the engine bulkhead.

64530005

21

Cargo Area

The cargo area of the X5 offers 450 liters/15.9 cuff of space and has a load capacity of 440
pounds. The retractable, removable cargo cover is standard equipment. Storage com¬
partments are located on the left and right sides in the rear.

The left side storage compartment contains the NAV
computer when installed and the telephone transceiv¬
er and CD changer.

The right side storage compartment
contains the rear power distribution
fuse box as well as the sub-woofer
for the stereo system. Mounted in
front of the right side storage com¬
partment are two 12 volt accessory
power sockets.

22

Cargo Area

The sliding load floor is available as an option on the
X5. It is mounted through two sliding bushing on two
steel rails

51530000

The load floor is held in position by the
locking bowden cable mechanism that
latches when closed to prevent the
floor for sliding while the vehicle is
moving. The load floor incorporates a
shear point that will cause the floor to
collapse upward in a rear collision.

51520002

23

Cargo Area

The full size spare tire is mounted
below the load floor with the LVA air
supply system for the air springs
located beneath the spare.

The battery is mounted below the LVA
in a molded plastic battery box, along
with the EHC control module and the
PDC control module. If the optional
trailer towing package is installed, the
trailer module is also installed in the
module carrier.

24

Tailgate

The tailgate on the X5 is two sections that
open up and down. The upper section has a
fixed bonded rear glass that incorporates the
rear window wiper and motor assembly. Two
gas strut pistons are used on the upper sec¬
tion for opening. An electric actuator is incor¬
porated in the upper section with the micro
switch for operation located between the two
license plate lights. The actuator locks into
the lower tailgate section when closed.

A micro-switch positioned in the center console switch
panel is used to open the tail gate from inside the
vehicle.

Operation of the upper tail gate is con¬
trolled from the GM which locks the
operation of the gate when the vehicle
speed is over 5 MPH. A dealer installed
class three trailer hitch is available as an
option with a towing capacity of 6000
pounds.

25

Tailgate

The lower tailgate section also uses an electric actuator for its operation. The actuator is
positioned in the center of the tailgate and operates two latches though bowden cables.
The latches are positioned on the left and right sides of the tailgate. Two springs are used
to dampen the operation of the lower tailgate section.

51530003

51530005

Adjustments of the rear tailgate are car¬
ried out at the tailgate body latch on the
left and right sides.

26

Tailgate (Emergency Opening)

Both sections of the tailgate incorporate emergency release mechanisms for opening the
tailgate in the event of electrical or component failures.

The upper tailgate release is a plastic pull tab positioned on the right side of the inner trim
cover. Pulling the release tab will mechanically release the upper actuator.

Emergency Release

The lower tailgate emergency release is accessed by removing the trim cover on the tail¬
gate section. With the gate closed, only the top section will be able to be loosened. The
mechanical release is actuated by inserting a small screwdriver into the opening and press¬
ing the latch to the left.

Emergency Release

27

Drivetrain

The transfer case, driveshafts, final drives and half shafts make up the drivetrain assembly.
The transfer case is always mounted in the same position on the X5. This applies to other
markets and future models that will utilize different transmissions for different engine con¬
figurations. With these models, the transmission tail shafts will be modified to match up with
the transfer case.

The rear driveshaft is a two piece unit using a center bearing, while the front drive shaft is
a single piece that is splined to the transfer case and bolted to the front differential.

The breather vents for both differentials and the transfer case are mounted higher up on the
chassis to prevent water from entering if the vehicle is driven off road through water. The
front breather passes up into the engine compartment and is mounted under the left side
ignition coil cover. The rear breather passes along the under side of the body and is mount¬
ed behind the left side wheel arch cover. The breather vent for the transfer case is mount¬
ed up high in the driveshaft tunnel.

28

Drivetrain-Transfer Case

The transfer case is manufactured by New Process Gear Division of New Venture Gear
Company. It is identified as model NV 125.

It incorporates a planetary gear set and chain to provide the torque split and all wheel drive.
The output torque of the transmission is applied to the planetary carrier of the gear set. The
rear drive shaft is connected to the annulus gear and the front drive shaft is connected to
the sun gear through the chain drive.

As the output shaft of the transmission turns, the planetary carrier rotates, causing the
planetary gears to drive the sun gear and annulus gear.

A torque split of 68% rear/ 32% front is provided through the gearing of the planetary set.

68°/c

32°/c

26530004

29

Drivetrain-Final Drives

The final drives for the front and rear axles are conventional differentials. The DSC system
provides anti-spin/slip control for both the front and rear axles on the X5.

The rear differential is the HAG 188K
(compact) unit with a ratio of 3.64 : 1

The front differential is the VAG 174
unit with a ratio of 3.64 : 1.

30

Front Suspension

The front suspension design is taken from the E38/E39 double pivot system. The compo¬
nents are larger in size and made from all steel for the expected harder use that the X5 sus¬
pension will receive. This includes the sub-frame which is also larger in size and supported
by two hydraulic mounts for vibration absorbion. The front suspension carrier incorporates
an aluminum stiffening plate that is bolted to the carrier. It adds to the front axle kinematics
by reducing flex in the front suspension. It also provides protection for the oil pan and front
end components when off-road and improves the Cd by providing a smooth surface for air
flow under the vehicle.

Front Axle Technical Data

TRACK: 1576mm
TOE-IN: 18’ +/-10’

CAMBER: -12’ +/- 20’

S.A.I: 12 Degree’s 48 Feet
CASTER: 7 Degree’s 8 Feet

31

Front Suspension Alignment

The front suspension is adjustable for
toe-in and camber. The camber cor¬
rection is limited to +/- 12 minutes
through the elongated slots at the top
of the strut towers.

The locating pin at the strut mount is
pressed in place and must be pried out
for removal in order to make any cam¬
ber corrections.

32

Rear Suspension

The rear suspension is the “intragal” multi-link design taken from the E38/E39 vehicles.
Several components AER made from aluminum to erduce the unsprung weight. The X5
with the M62TU engine uses the EHC (air spring) suspension system. The EHC functions
the same as the E39 Sport Wagon with only minor differences to the components and lay¬
out of the system. The X5 with the M54 engine will use standard springs in the rear with the
EHC system as an option. The rear struts on the X5 are mounted to the body instead of the
sub-frame.

The rear axle sub-frame is mounted to the body through four bushings (larger than E38) for
increased load and comfort. The rear differential is mounted through three rubber bushings
two in the front and one hydromount in the rear. The wheel bearings are similar to the E39
but incorporate different seals - designed for off-road use.

Rear Axle Technical Data

Track: 1576mm

Toe In: 18 Feet

Camber 1 Degree 50 Feet

New special tools are available for adjusting the rear suspension due to the limited space,

33

Rear Suspension Alignment

As with other BMW multi-link suspensions, the X5 rear suspension is adjustable for Camber
and Toe-in. Due to the limited space, special tools have been produced for aligning the rear
suspension.

The Camber is adjusted through the eccentric bushings at the upper control link arm.

v

Camber Eccentric

-32530002

The toe-in is adjusted at the lower control arm mount.

34

Overview of EHC Control System

The control philosophy of EHC is to "Initiate a control sequence only when necessary".
The system offers the following advantages:

• The control system operates independently from the vehicle’s engine (no engine driven
hydraulic pump system as per previous self leveling systems).

• Individual control of the rear wheels is possible

• An uneven load is identified and compensated for

• Uneven road surfaces are identified and not compensated for

• Automatic control is interrupted when cornering

• The system is diagnosable using the DIS or MoDiC

The air suspension system consists of the following components:

37530000

35

EHC System Components

Control Module

The Control Module is mounted in the module carrier box in the luggage compartment on
the right side. It contains the processing electronics and final stages for operation of the
EHC system.

The control module receives the follow¬
ing inputs for its processing functions:

• KL 30 & 31 (Power/Ground)

• KL 15

• Left & Right Ride Height Sensors

• K Bus for;

- Vehicle speed

- Engine running

- Door/tailgate - open/closed

The control module incorporates two filters (slow/rapid) for processing the input signals
from the ride height sensors. Depending on the operating mode, either the slow or rapid fil¬
ter is used to check the need for a regulating sequence.

The slow filter is used during the normal operation mode to prevent normal suspension trav¬
el from causing the system to make adjustments.

The rapid filter is used during the pre-run and tailgate (LID) modes to ensure that the sus¬
pension is adjusted quickly while the vehicle is being loaded or checked prior to operation.

36

Air Springs

The air spring is made from a flexible rubber material. It
forms an air tight cavity which provides the calculated spring
rate required for the sport wagon.

As the spring compresses downward the bottom edge of
the rubber material rolls along the vertical surface of the
base mount cylinder.

Air is added or removed from the air spring through its top
port. The top port of each spring is connected to a reser¬
voir and the air supply pipes. The reservoirs are required to
hold additional air due to the compact design of the springs.

Rear Axle Level Sensors

Hall effect sensors are mounted on the left
and right sides of the rear suspension for ride
height detection. They are pivoted by a cou¬
pling rod through the rear axle swing arms.

The hall sensors produce a varying voltage
input to the control module as the suspension
height changes.

If the vehicle is equipped with Xenon head¬
lights the right side sensor contains an addi¬
tional sensor for the automatic headlight level
adjustment system.

Warning Display

If the system is faulted and off-line or set in the transport mode, the following is displayed:

High Cluster: A message is posted in the high cluster matrix display.

37

Air Supply System (LVA)

The air supply system is identified as the LVA in the diagnosis program and in the repair
manual. It is mounted in the spare tire well compartment. The components are housed in
a sound deadening carrier, through rubber bushings, to prevent operating noises from
being transmitted through the vehicle’s interior.

With the exception of the compressor relay, individual replacement parts for the air supply
system are not available. If diagnosis determines a defect in any of the other air system
components, complete replacement is necessary.

The air supply system consists of the following components:

Compressor assembly with;

- Piston compressor

- Electric motor

- Air dryer (desiccator)

- Pressure relief solenoid valve

- Pressure maintenance valve

- Check valves

Compressor Relay (Replaceable)

Solenoid Valve Block (2 - two way valves)

37530001

Securing block
— - — Soundproofing

Solenoid valve block

Compressor relay
(replaceable)

— — Air desiccator

Pressure relief valve

Compressor

Electric motor

Housing

37530002

38

Air Supply System (LVA) Operation

The single stage piston compressor produces a maximum pressure of 13.5 Bar. The com¬
pressor is maintenance free - provided it is used in a dust free environment. This includes
the compressor’s intake air filter.

The compressor is driven by a DC motor that is controlled by the compressor relay through
the control module.

When the compressor is activated, the pressure builds up to a working pressure of 11.4
Bar (+0.8/-1.5 Bar). This is controlled through the pressure maintenance valve. The air
under pressure is fed through the dryer and check valve to the solenoid valve block for the
air springs.

There is one solenoid valve in the valve block for each air strut. This allows the system to
compensate for uneven loads in the vehicle and maintain the vehicles ride height at all
times.

Pressure is drained through the left or right solenoid valve (energized open) the pressure
relief solenoid valve, restricter, check valve and dryer back to the inlet side of the compres¬
sor pump.

39

LEFTAIR SPRING

40

RESERVOIRS

RIGHTAIR SPRING

EHC System Operation

A fully functional EHC system is controlled by one of three different modes of operation.
The operation mode is selected by the control module based on current conditions provid¬
ed by the monitored input signals. The main modes of operation are:

• Pre-Run/Post-Run Mode

• Normal Mode

• Tailgate Mode

Two special operating modes are also included in the control module programming.

• New/replacement mode (pre ZCS encoded). This mode provides basic operation.

• Transport Mode - Transport mode is set at the factory and raises the vehicle 30mm to
prevent vehicle damage during transportation. It must be deactivated with the DIS/
MoDiC prior to customer delivery.

Pre-Run/Post-Run Mode

The Pre-Run mode is activated when the vehicle is parked and the control module is in the
sleep mode. Opening a door or the tailgate initiates a system wake up and the control mod¬
ule comes on-line.

The control module performs a self-check of the control electronics and sensors. If no fault
is found, the system will check the ride height and institute a rapid regulation if the height
varies by more than 40mm.

KL 30 KL31

22

•Control module
in sleep mode
•Tailgate or Door
opened
•KL 15 - OFF
•Engine - Off

L LEVEL
SENSOR

R LEVEL
SENSOR

OOOOOOO.

OOOOOOO.

i

SIGNALS

1

i

MODE OF OPERATION
- PRE/POSTRUN MODE

1. K-Bus signaling provides
control module wake up and
vehicle data status. Control
module checks fault memory.

2. EHC control module
determines the vehicle
height and compares it
with stored values.

3. Control module will rapidly raise the vehicle if the monitored vehicle height is lower
than the stored value by more than 40mm. If the monitored level is not correct but
less than 40mm the control module will adjust the vehicle level once the engine is
running to prevent unnecessary battery loads.

41

Normal Operation Mode

Once the rear lid is closed, KL 15 switched ON and the engine started, the system switch¬
es into the normal operation mode. In the normal mode, the control module will constantly
monitor the input signals from the ride height sensors and will activate a correction if the
ride height deviates by at least 10mm.

GM III

KL 30 KL31

D

O

I-

3 10

•Tailgate closed
•KL 15 - ON
•Engine - ON

L LEVEL R LEVEL
SENSOR SENSOR

MODE OF OPERATION
- NORMAL MODE

1. K-Bus signaling provides
changed vehicle data status

2. EHC control module
continually monitors
the vehicle height
through the slow filter.

3. Control module will raise or lower the vehicle height if it deviates more than 10mm
fora long duration of time. The constant rapid signal changes caused by uneven road
surfaces are filtered out.

Tailgate Operating Mode

The tailgate operating mode is activated if the gate is opened with KL - 15 On and the
engine running. The difference between this mode and the normal operating mode is the
response time is rapid instead of slow .

GM III

KL 30 KL31

D

o

t

« 10

•Tailgate OPENED
•KL 15 - ON
•Engine - ON
•Roadspeed = 0

L LEVEL
SENSOR

R LEVEL
SENSOR

\

SIGNALS

1

i

MODE OF OPERATION

-TAILGATE MODE

1. K-Bus signaling provides
changed vehicle data status.

2. EHC control module
switches from the slow
filter to the rapid filter for
vehicle height monitoring

3. Control module will rapidly raise or lower the vehicle height if it deviates more than
10mm. The rapid signal change from loading or unloading the cargo area causes the
control module to rapidly respond to the change in vehicle height.

42

Special Operation Mode

• Assembly Line Mode (New control module)

The assembly line mode refers to control module manufacturing. New control modules
are stored in a deactivated state. The control programming is not active and must first
be ZCS encoded.

After installing a replacement control module, it must be coded using the DIS or MoDiC.
The instrument cluster fault display will remain illuminated until the control module is
coded.

Control Interrupts

Cornering

To prevent unnecessary suspension adjustments while driving through corners, a “control
interrupt” is built into the system. Above 30MPH the control module monitors the left/right
ride height sensors for a difference of 30mm. Exceeding this difference will put the system
into a control interrupt and no adjustment will take place. The control interrupt last for a
duration of 5 minutes.

Vehicle Lifting

The ride height control is interrupted when the vehicle is raised on a lift or with a jack. The
system monitors the ride height sensor inputs and when the height limit of 90 mm is
exceeded, the control is switched OFF until the vehicle is lowered again.

43

EHC Service Information

Diagnosis / Coding

• The EHC control module is connected to the diagnostic link. The EHC control module
activates the fault display in the instrument cluster to alert the operator of the off-line sta¬
tus of the system. The EHC control module stores up to three electrical/electronic
faults.

• Diagnosis/troubleshooting of EHC is carried out using the fault symptom troubleshoot¬
ing program of the MoDiC or DIS. The EHC system has an extensive diagnosis program.

• Replacement control modules are shipped in the factory mode. The control modules
must be ZCS encoded using the DIS or MoDiC to activate the operating parameters.

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BMW Diagnosis FAULT SYMPTOMS

U Fault display in instrument cluster
f§ Leakage in system

§ Car positioned too high/too low on
one/both side(s)

§ Compressor running noise too loud
[f Compressor does not start up,

compressor runs continually or too often

PI None of the fault symptoms indicated
is applicable.

Do you want to continue troubleshooting?
s Yes
1 No

A

V

Quick test

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#

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BMW Diagnosis TEST MODULES

[E Control unit

§ Voltage and earth supply of control
unit

§ Height sensor, left
§ Wire, height sensor, left
i§ Height sensor, right
j§ Wire, height sensor, right
Wire, consumer-cutout signal
jf K bus

P Air-supply system (LVA)

@j| Voltage and earth supply of
air-supply system (LVA)

@3] Wire, drain valve
pljj Wire, compressor relay
3 Wire, valve, left
EH Wire, valve, right
i!| Compressor relay
ill Pneumatic springs, air pipework,
screw connections

A

V

Quick test

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#

Function

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System

\l

selection

Schedule

\i i>

o

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BMW Diagnosis DIAGNOSIS REQUESTS

Ignition lack in position 2*

Terminal 15: ON
Engine status:OFF
Warning lamp/message:OFF
Journey detection:MO
Cornering: MO

Lifting platform/wheel change:

YES

Inclination:NO

Mode, end of assembly line:NO
Transportation mode:NO
Valve, rear right:OFF
Valve, rear left:OFF
Compressor relay:OFF
Drain valve:OFF

System voltages:

Sensor supply: 5.Ovolts

Function

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-^

selection

Is

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A

M

System

BMW Diagnosis Mechanical components

n

Additional information:

Leaks in the screw joints between LVA,
pneumatic lines or air spring strut can
result in excessively long control times.

Possible effects of a leakage:

During a control process or the attempt to
correct the car height for the purposes of
height offset, the fault of control-time
monitoring can be set.

Observe fault memory.

In this case, the compressor inside the LVA
is deactivated so as to prevent overheating
caused by excessive compressor running time.
The LVA is able to respond only
after an extended period of waiting.

V

Function

Document

Test

selection

Lr

Schedule

DIS/Modic Service Funnction Program

The Service Functions program of the DIS/MoDiC provides the Transport Mode activa¬
tion/deactivation and Ride Height Offset functions (see next page).

Once the transport mode has been released, or if the system requires left to right side
height adjustment, the ride height "OFFSET" must be carried out to ensure that the vehi¬
cles suspension has a base ride height level starting point.

The "HEIGHT OFFSET" is adjusted using the DIS or MoDiC. The procedure is as follows:

• Place the vehicle on a level surface unloaded.

• Access the Height Offset program in the service function menu.

• Measure the base ride height from the lower edge of the wheel housing to the center of
the wheel hub.

• Check measured height against the specifications listed

• Use the DIS/MoDiC to correct the ride height if the value differs from the listed specifi¬
cation.

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BMW Diagnosis HEIGHT OFFSET

Press the appropriate keys to move the
car to the correct position
(measurement with tape measure?).

Each key actuation changes the car ride
level by 5 to 10 ram.

Dimensions apply from lower edge of wheel
house to centre of wheel.

Specified ride levels:

E39 saloon : 360 mm +/- 3mm

E39 touring : 360 mm +/- 3mm

E39 touring with

sports chassis : 345 ram +/- 3mm

<1

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selection

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BMW Diagnosis HEIGHT OFFSET

Additional information:

Car must be in the normal position,
i.e. in a compensated state.

Car must be standing on a level surface.

Instruction;

One-sided loading and parking
on uneven surfaces must be avoided?

If necessary, wait until vehicle has
corrected itself.

Measure distance from lower edge of wheel
house to wheel centre with tape measure.

Specified ride levels:

E39 saloon : 360 mm +/- 3mm

E39 touring : 360 mm +/- 3mm

E39 touring with

◄

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selection

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<1 l>

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BMW Diagnosis HEIGHT OFFSET

sports chassis : 345 nun +/- 3mm
Check:

Is the vehicle height in the specified
range?

360 mm +/- 3ram
360 mm +/- 3nmt

Specified ride levels
E39 saloon
E39 touring
E39 touring with

sports chassis : 345 mm +/- 3mm

S Yes
1 No

<]

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selection

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BMW Diagnosis HEIGHT OFFSET

U Left A
§ Left V
§ Right A
| Right V

m Height O.K.

◄

Function

selection

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< >

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□

System

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#

o

45

Two Axle Air Suspension

Purpose of the System

The two axle air suspension system (EHC2) offers advantages over the single-axle air sus¬
pension with respect to ride comfort and off-road capability.

Lowering the entire body makes it easier to enter, exit, load and unload the vehicle.

The vehicle's off-road capability was improved by providing the possibility for increasing the
ground clearance of the body.

The driver can now choose between three different ride levels which can be set with a rock¬
er switch, as required. Automatic ride-height control for payload compensation and
automatic inclination compensation continue to be fitted.

Deficits of the old system

The automatic payload compensation facility for the single-axle air suspension did not per¬
mit driver control. The driver could not actively control the system to make it easier to enter
and exit or load the vehicle.

Ride level was compensated via the rear axle only.

Advantages of the new system

The new system allows the ride-height control system to be controlled actively by the dri¬
ver.

The twin axle air suspension allows both axles to be lowered evenly and in parallel.

As a result, it is easier for the occupants to enter, exit, load and unload the vehicle.

History

BMW previously supplied ride-height control systems as both optional equipment and, in
part, as standard equipment on the 7 Series - E23/E32(not in the US market), 6 Series -
E24 (L6/M6) and 5 Series - E28 (M5). On the E39, the load of the complete rear axle was
born for the first time by air suspension in combination with the optional ride height control
system. The system was controlled automatically under all operation conditions, and there
was no possibility for driver intervention on the X5, the rear axle previously had single axle
air suspension only. The air supply unit and the control unit were adopted from the E39. The
air springs were adapted to the X5.

There is a standard version and a sports version.

The ride-height control system (EHC) was supplied as standard in combination with the
M62 engine and is available as an optional extra in combination with the M54 engine.

EHC2 is optional on both the M62 and M54 versions of the X5 and not available on the
4.6is X5.

46

System components

The X5 Two Axle Air Suspension System (EHC2) utilizes the air supply unit from EHC
mounted in the luggage compartment, with the following components added or modified:

• Air Supply Unit (with redesigned compressor and drier)

• Pressure Accumulator

• Valve Unit

• Ride Height Sensor

• Air Suspension Strut

• Control Unit

• Switch Assembly

Pneumatic System of EHC2

1. Air Supply Unit

2. Rear Axle Air Bellows

3. Ride Height Sensors

4. Pressure Accumulator/
Valve Unit

5. Front Axle Air Bellows

6. Control Unit

Air Supply Unit

As on vehicles with single axle air suspension, the air supply unit is located in the luggage
compartment under the spare wheel. As with the single axle air suspension, the auxiliary
tanks for the rear air spring bellows are located in the luggage compartment.

The air supply unit is configured similarly to the single axle air supply unit for the ride-height
control system of the E39, which is currently in production.

The functions are implemented by activating a compressor and various valves in the air
supply unit and on the air accumulator valve unit.

The maximum pressure of the air supply unit is 21 bar.

47

6 1

2

6 3

6 5 4 7

1. Pneumatic Drain Valve

2. Electric Pilot Control Valve

3. High Pressure Vent Valve

4. Air Drier

5. Compressor

6. Sintered filter

7. To Pressure AccumulatorA/alve Unit
NW Size of opening/tubing in mm.

Air Supply Unit
Pneumatic Drain Valve

The Pneumatic Drain Valve is activated pneumatically by pressure from the control valve.
This causes the drain valve to open allowing the pressure supply line to vent to atmosphere.
This design allows for large air volumes to be discharged quickly and eliminates the need
for a solenoid valve with high current consumption.

The 21 bar pressure limiting valve is integrated in the drain valve.

Electric Pressure Relief Valve

The electrically activated pressure relief valve controls normal system pressure. The con¬
trol valve performs this function in conjunction with the drain valve.

High Pressure Vent Valve

The High Pressure Vent Valve serves as a comfort valve and is used to release system pres¬
sure after the accumulator has closed and the compressor is still running. When the high
pressure vent valve has opened the compressor can be stopped quietly.

Air Drier

In the air drier, the air which is drawn in passes over a water absorptive filter material in the
form of filter nodules which extract moisture from the air. As long as the air contains more
moisture than the filter material, the individual nodules absorb and accumulate the mois¬
ture. When the air flows back, it is drier than the filter material, with the result that the air is
re-humidified and the moisture is discharged into the open air. The maximum
water storage capacity of the filter is 30 g.

48

Compressor with Drier

Ni p,. Ni (j,

H. C

Top: Air Drying

Bottom: Dissipation of water to air

Compressor

Compressor operation is the same as in EHC with the following technical improvements:

• Addition of a temperature sensor (Located on the compressor cylinder head)
Temperature sensor switches off the compressor at temperatures above 110°C.

• Extended compressor ON time (180 seconds)

• Redesigned air drier to compensate for additional air volume.

Pressure Accumulator

The twin axle air suspension system now features a pressure accumulator which forms an
air accumulator valve unit in combination with the valve. The air accumulator valve unit is
located beneath the vehicle floorpan in the right-hand sill area.

Pressure Accumulator Unit which
includes:

Pressure Accumulator
Pressure Sensor
Valve Unit

Front

49

The pressure accumulator decreases the load on the compressor and significantly reduces
the time required for large changes in ride height.

The EHC 2 control module monitors system pressure via a pressure sensor mounted on
the accumulator. Normal system pressure is 15.7 +/- 0.7 bar. Minimum system pressure
is 9 bar.

The pressure accumulator's charge is sufficient to fill the four suspension struts once from
the Access position to the normal position and compensate for vehicle load up to maximum
gross weight.

Accumulator/Valve Unit Valve Unit

1. Air Lines 1. Connections for Air Lines

Yellow-Black Front 2. Pressure Accumulator valve

Red-Blue Rear

2. Pressure Accumulator

3. Connecting Cable

4. Pressure Sensor

5. Valve Unit

Valve Unit

In the valve unit, four bellows valves and the pressure accumulator valve are activated.

The bellows valves and the pressure accumulator valve are solenoid valves which are
closed under spring pressure when de-energized.

50

Ride Height Sensor

The control unit obtains information about the ride height of the vehicle via a ride height sen¬
sor attached to each of the four wheels.

60° Rear Axle

Ride Height Sensor

The ride height sensor is an angle Hall sensor which is activated by a ring magnet. The ring
magnet is polarized vertically from north to south.

The magnetic field line of the ring magnets intersect a Hall cell. The Hall cell is arranged in
such a way that only the horizontal components of the field lines are evaluated. This results
in different field line strengths at different positions of the ring magnet. The Hall cell mea¬
sures the field strength of the magnetic flux and converts it into an analog signal with a volt¬
age level between 0.5 and 4.5 V.

1

Sensor Principle of
Operation

1. Ring Magnet

2. Hall Cell

3. Longitudinal magnetic
field lines, low voltage
0.5V

4. Transverse magnetic
field lines, high voltage
4.5V

51

Air Suspension Strut
Rear

Minor modifications were made to the rear axle air springs. The air springs and the dampers
are configured separately at the rear axle.

Front

The air suspension replaces the steel suspension at the front axle, i.e. the spring bellows is
attached to the damper. The front air suspension strut and the impact absorber form a
complete unit.

Air Suspension Strut

1. Auxiliary Spring

2. Air Bellows

3. Damper

Control Unit

The EHC2 Control Unit is located behind the glovebox adjacent to the General Module.
The connector is a black 54 pin connector.

Inputs received directly into the control unit are:

Ride Height Level Sensor (X4) Up and Down requests from the switch assy.

General Module (Load cutout signal) CAN Bus Inputs
K Bus Inputs Pressure Sensor

Compressor Temperature

Outputs include:

Air Unit Control (Activation) Front and Rear Axle Valves

LED’s for Switch Unit Compressor Relay

Pressure Accumulator

52

Switch Assembly

The dash mounted switch assembly supplies a momentary switched ground to the EHC2
Control Unit requesting a ride height change in the up or down direction. Three LED’s pro¬
vide current ride level selected and target ride level if a request for change has been made.
The LED for the current ride height will always be illuminated. The LED for the target ride
level will flash until the new ride level is reached.

Notes:

53

Principle of Operation

Ride Height Control Operations

In addition to the automatic ride-height control system for payload compensation, the dri¬
ver can set three different vehicle ride heights.

• Off-road (+25 mm), high ground clearance to a max. speed of 50 km/h

• Standard (0 mm), normal ride level

• Access (-35 mm), for entry and exit, loading and unloading to a max. speed of 35 km/h
or can be activated in Standard mode at road speeds < 25 km/h

The various heights are selected by scroll rocker. Light emitting diodes indicate the present
ride height setting.

Ride height can be adjusted from terminal 15 and with the doors closed. The hood and tail¬
gate may be open.

The system also controls inclination automatically, like the single axle air suspension.

All control operations are executed without stopping at intermediate levels. The vehicle is
configured pneumatically in such a way that the front and rear axles can be lowered in par¬
allel in any load situation. Depending on the load situation, either the front axle or the rear
axle is slightly quicker. On account of the different control speeds, a difference in height
between the two axles is possible during all control operations. If a max. permissible thresh¬
old is exceeded, the quicker axle is stopped briefly.

The various levels can be preselected while travelling. Changeover between ride levels is
effected at the speed threshold values defined in the control unit. The control unit monitors
the change-over.

As soon as the driver sets a new target ride level by pressing a button or when a change¬
over is initiated automatically by a specific driving condition, the LED for the current ride
level remains lit and the LED for the target ride level begins to flash.

When the new level is reached, the LED for the previous level goes out and the LED for the
new level reached stays lit permanently.

54

Down button
or

>50km/h

Off-Road
(+25 mm)

Down Button and
<80km/h
and

Accumulator pressure
^threshold
and/or
compressor temperature
threshold

Standard
(0 mm)

Access
(-35 mm)

<25km/h

Up button
and

<50km/h

Up button
or

>35km/h

The various levels can be preselected while travelling. Changeover between ride levels is
effected at the speed threshold values defined in the control unit. The control unit monitors
the change-over.

As soon as the driver sets a new target ride level by pressing a button or when a change¬
over is initiated automatically by a specific driving condition, the LED for the current ride
level remains lit and the LED for the target ride level begins to flash.

When the new level is reached, the LED for the previous level goes out and the LED for the
new level reached stays lit permanently.

If a ride level selection is not allowed, the LED indicating the momentary ride level of the
vehicle flashes for 3 seconds.

A special case is preselection of Access levels while travelling. The Access LED flashes and
the LED for the original ride level is lit permanently. However, this does not mean that a con¬
trol operation has already begun. The control operation does not actually begin until the
speed threshold which the Access level allows is reached or undershot.

55

In addition to the LED indicator, the following text messages can
be displayed in the instrument cluster:

• TRAILER MODE

A coupled trailer is identified via the trailer connector. To avoid damaging the trailer and
the vehicle, changes of vehicle level are generally avoided. The standard level is "frozen."
If the trailer is coupled at a level other than the Standard level, the vehicle ride level is
not changed to Standard unless a button is pressed or the speed threshold for auto¬
matic change-over is reached. The standard level is then "frozen" until the trailer con¬
nector is disconnected.

• RIDE HEIGHT CONTROL INACTIVE

Faults in the system and on the control unit which are only identified by the instrument
cluster, e.g. control unit disconnected

• RIDE HEIGHT CONTROL INACTIVE + MAX. 60 km/h

For safety-critical faults (vehicle is too high or at inclination)

Control Modes
Sleep mode

If the vehicle is parked, it enters Sleep mode after 16 minutes. No further control opera¬
tions are executed. A "watch dog" wakes up the control unit for a few minutes every 6
hours (wakeup mode) in order to compensate for possible inclination of the vehicle. (Vehicle
height may only be corrected once as air supply unit only operates with engine running.)

Wake-up

In wake-up mode, the control unit is woken up for a set period of time in order to com¬
pensate for possible inclination of the vehicle. Inclination of the vehicle can be caused by
large temperature differences or by minor leaks. Adjustments to the front and rear axles
ensure that the vehicle is visually level. To minimize power consumption, the vehicle is low¬
ered only. The nominal level of the lowest wheel serves as the nominal level for all other
wheels. The lowest nominal level to which the vehicle is lowered is the Access level (-35
mm).

Exception: if the vehicle is parked at Access level, the vehicle is lowered to max. -50 mm
in wake-up mode. If the vehicle is parked for a prolonged period of time and there is a leak
in the system, further loss of pressure does not produce a change of ride level since the
weight of the body is born by the auxiliary suspension and the residual tire pressure.

Advance /Overrun

When the vehicle is woken out of sleep mode by the load-cutout signal (VA), it normally
enters advance / overrun mode. Since the engine is not (no longer) running in this mode,
however, there are restrictions on the control operations that can be performed in order to
conserve the battery. Ride level compensation is restricted to tolerance ranges of 20 mm
and 25 mm in the up and down directions respectively. This serves to reduce the frequen¬
cy of control operations.

56

All control operations in advance / overrun mode are executed as long as pressure is avail¬
able in the accumulator. When the accumulator is empty and the engine is turned off, con¬
trol operations are directly driven by the compressor. User-activated changes of ride level
and filling of the accumulator are not possible.

Terminal 15

As soon as the ignition is turned on (terminal 15), the user is allowed to lower the ride level
as required.

However, it is still not possible to raise the ride level or fill the accumulator.

Ride level is compensated outside a narrow tolerance range of 10 mm upwards and 10 mm
downwards.

Engine "on"

Ride level compensation, raising and lowering the vehicle's ride height as well as filling the
accumulator are permitted when the engine is running. The compressor also starts up dur¬
ing every control operation.

Ride level is still compensated outside the narrow tolerance range of ±10 mm.

As long as the vehicle is stationary, high speed filtered ride level signals are used to detect
a change of load. This allows the system to react immediately to changes in ride level.

As soon as the vehicle is travelling, it changes over to low speed filtered ride-level signals.
The system no longer reacts to bump movements caused by road surface unevenness. A
mean value is formed over a prolonged period of time, i.e. payload is only altered by the
progressive emptying of the fuel tank.

The high speed filter is not used until the vehicle is stationary again and a lid is opened. If
no lid is opened, the vehicle logically cannot be loaded or unloaded.

57

Workshop Hints

If a threshold level is exceeded on all 4 wheels when the vehicle is stationary, the control
unit assumes that the vehicle has been raised on a workshop platform.

There are three possible reset conditions for workshop platform recognition:

• The original level values are undershot at all four wheels,

• A selection is made by button,

• A speed of >40 km/h is recognized for 3 s.

Vehicle jack

If the lowering speed at a wheel is too low during the lowering operation, the system
assumes that the wheel is jacked up. However, the downward velocity must be less than
a certain preprogrammed speed threshold. If the system detects a jacked wheel, it stores
the height of this wheel.

Car jack recognition is reset when the stored ride height is again undershot. When a trav¬
elling speed of 40 km/h is maintained for at least 3 s, another control attempt is performed.
The carjack recognition can also be reset by button selection.

Please note that the system also controls ride height in diagnostic mode. For this reason,
Belt Mode must be activated before carrying out work on the system or before setting the
vehicle ride height.

Belt Mode:

Heights are fixed and are not compensated. If Belt Mode is set, the function LED is off. The
text message "ride-height control system inactive" appears in the instrument cluster.

Transport Mode:

The Transport Mode setting is for transportation purposes. When the ignition is turned on,
the message "ride-height control system inactive" appears. Heights are increased or
decreased depending on ignition key status, e.g. ride height is reduced when the vehicle is
lashed to a ship or train and raised when the "Engine on" signal is generated and when the
vehicle is transported on a transporter truck.

The correct ride height is set to ± 5 mm via "Activate components." The left and right ride
levels are set separately at the rear axle. The ride levels are then set at the front axle. The
left and right air springs are adjusted jointly for this purpose.

Following this, the new ride height for the front and rear axles is stored via the "Offset func¬
tion."

Before replacing components, the system must be depressurized! This is done in the diag¬
nostics via "control unit functions," "Component activation," "Pressure-relieve front axle/rear
axle." Repeat the activation procedure 6 times.

58

If the fabric of the bellows is visible, then the bellows must be replaced.

Upon completion of repair work, the air suspension system of the vehicle raised on the
workshop platform must be refilled with air via the diagnostics. The activation procedures
must also be repeated 6 times. This prevents the bellows from being folded incorrectly.
The vehicle must with be set down on its wheels when the suspension struts are depres¬
surized!

Important Workshop Hint

Similarly, a defective vehicle with leaky pneumatic system must not be raised on the work¬
shop platform. If depressurized, the bellows would contract under suction forming incorrect
folds. These folds could result in malfunctions later on.

Areas on the air bellows which can possibly become leaky are the O-ring at the piston rod
and the seal carrier on the roll piston.

The connectors attached to all cables are identical to the connections on the single-axle air
suspension. 6 mm cable is used. The tightening torque is 3+1 Nm throughout the system.
Special care must be taken when handling breakage-prone plastic parts of air suspension
elements.

Upon completion of repair work, Belt mode must be deactivated via the diagnostics. The
function LED on the button comes on. No text message appears in the instrument cluster.
The system is OK and ready for operation.

59

Steering

The X5 utilizes a power assisted rack and pinion steering system due to all wheel drive con¬
siderations. The power steering pump is a vane cell design.

The turning radius of the X5 is 12.2 meters.

The steering column is electrically adjustable for length and height that includes the mem¬
ory function incorporated into the seat/mirror memory system.

60

Brakes

The X5 brake system is the dual circuit (black/white) division with Electronic Brake Force
distribution (EBV) through DSC control. The system is similar to the E38 with:

Front Brakes

Brake Rotor - 332mm diameter - 30 mm thick
Caliper - single piston 60mm diameter
Pads - asbestos free

Vacuum booster with tube jet amplifier

Tandem master cylinder with two central valves for DSC operation
Brake fluid reservoir with reed contact
Vented front rotors/Solid rear
Single piston calipers
DSC hydraulic unit with integrated control
module

Pre-load pump for DSC operation

Rear Brakes

Brake Rotor - 324mm diameter - 12mm thick
Caliper - single piston 42mm diameter

61

Wheels and Tires

Light alloy wheels are standard equipment on the X5.
The wheels sizes include:

3 Liter version

• Standard Wheel - 7.5J xl 7 SEH2

• Standard Tires - 235/65R - 17 H rated all season
Front and Rear

4.4 Liter version standard suspension

• Standard Wheel - 8.5J x 18 EH2

• Standard Tires - 255/55R - 18 H rated all season
Front and Rear

4.4 Liter version sports suspension

• Standard Wheels - 9J x 19 EH2 FRONT

10J x 19 EH2 REAR

• Standard Tires - 255/50R -19 Front/285/45R - 19
Rear V rated

The X5 uses a two piece lug bolt that incorporates a spacer wash¬
er and features anti-corrosion coating. The tightening torque on the
lug bolts is 130Nm +/- lONm. Advantages of using the spacer
washer include:

• Longer expansion length for the bolt.

• A better fit to the wheel

• The spacer washer is fixed to the wheel when tightening and
the lug bolt turns relative to it.

62

Fuel System Supply

The fuel tank is constructed from molded plastic and is mounted under the rear seat and
extends along the left side of the vehicle. It is the saddle tank design with a siphon jet pump
in the right side to transfer fuel to the left side where the fuel pump is mounted.

The fuel filter/pressure regulator is
mounted in front of the tank along with
the charcoal canister. The components
are covered by a plastic plate to protect
them when driving off-road.

The liquid/vapor separator is mounted
on the right side up in the wheel arch
opening next to the filler neck.

The Leak Diagnosis Pump (LDP) is
mounted in the left rear side wheel arch
opening behind the wheel housing
cover. Operation of the LDP will be cov¬
ered in the engine electronic section of
this program.

63

Exhaust System

The exhaust system of the X5 is made from stainless steel and consists of three main
pieces after the exhaust manifolds. The front section consists of two monolith catalytic con¬
verters with pre and post-oxygen sensors. The two converters converge into one center
muffler on the right side of the vehicle.

The two rear sections consists of the tail pipes and main mufflers that are mounted at the
rear of the vehicle.

The front and rear exhaust components are bolted together with spring bolts

64

Power Distribution

The maintenance free 90 AH battery
in the X5 is mounted in the rear below
the spare tire and EHC compressor
unit. The battery box is formed of
molded plastic and the positioning of
the battery aids in weight distribution.
As with all BMW vehicles, the battery
is equipped with the BST on the pos¬
itive battery cable.

Power distribution for the vehicle and
systems is through two fuse carriers
mounted in the right storage com¬
partment in the rear and above the
glove box in the front.

The battery jump/charge point is
located in the engine compartment on
the left side of the fire wall.

61530013

65

Component Location

Sunroof

Module

FZV/FM2

Antenna

Amplifier

PDC

Door Module
Switchblock

FZV/FM2

Radio / NAVComp Ante ^ a
Electronics Amplifier

(when NAV equipped)

66