Reference Manual

BMW

Technical Training

www.bmwcenternet.com

The Ultimate
Driving Machine®

Chassis Dynamics

BMW of North America, LLC

Technical Training
ST1115

8 / 1/12

Information Status: August 01,2012

Course Code: ST1115 Chassis Dynamics

The information contained in the training course materials is solely intended for partici¬
pants in this training course conducted by BMW Group Technical Training Centers, or
BMW Group Contract Training Facilities.

This training manual or any attached publication is not intended to be a complete and all
inclusive source for repair and maintenance data. It is only part of a training information
system designed to assure that uniform procedures and information are presented to all
participants.

For changes/additions to the technical data, repair procedures, please refer to the current
information issued by BMW of North America, LLC, Technical Service Department.

This information is available by accessing TIS atwww.bmwcenternet.com.

© 2012 BMW of North America, LLC. The BMW name and logo are registered trademarks. All rights reserved.

meeknet.co.uk/e64

Table of Contents

BMW Suspension Systems

Subject Page

Introduction .4

BMW Front Suspension History.6

Single-joint Spring Strut Front Axle.6

E46 / E85 Front Suspension .7

Adjustments .8

Double Pivot Spring Strut Front Axle.9

Double Pivot Operation.11

Double Pivot Front Axle Configurations.12

E38 Front Suspension .13

E6x Front Suspension.14

Current Front Axles.15

Double-pivot Front Axle.15

E8x / E9x Front Suspension.15

E89 Front Suspension .17

Steering Offset on the E89.18

F30 Front Suspension .20

Sport Activity Vehicles (Except E70) Front Suspension.22

F25 Front Axle with EPS.23

E84 Front Suspension.24

Adjustments - Double-Pivot Front Axle .25

Double Wishbone Front Axle .26

E7x Front Suspension.26

FOx/ Fix Front Suspension.28

SAI - Virtual Pivot Point on Double Wishbone Front Axle .30

Adjustments - Double Wishbone Front Axle .32

Rear Suspension History.34

Development of BMW Rear Axles .35

HA1 - Semi-Trailing Arm Axle .36

FIA2 - Semi-Trailing Arm Axle (with Track Link).37

Initial Print Date: 08/12

Revision Date:

Subject Page

HA3 - Central “C” Link.38

E46 Rear Suspension .38

E83 Rear Suspension .39

E85 Rear Suspension .40

Rear Suspension Adjustments (HA3 Central Link Axle).41

Rear Toe.41

Rear Camber .41

Integral Axle (III and IV).42

E31 Rear Suspension (Integral III).42

E38 / E39 Rear Suspension (Integral IV).43

E39 / E53 Rear Suspension (Integral IV).44

E6x Rear Suspension (Integral IV).46

Rear Suspension Adjustments (Integral Rear Axle lll/IV) .47

Current Rear Axles.49

HA3 - Central “C” Link - E89 Rear Suspension.49

HA 5 Rear Axle.50

HA 5 Rear Axle Layout .51

Advantages .53

Manufacturing Costs .53

Light Construction.53

Production.53

Kinematics .53

Crash Reguirements.54

Rigidity / Acoustics .54

Setting.55

F25 Rear Suspension .56

F30 Rear Suspension .57

E84 Rear Suspension .58

Integral IV - E7x Rear Suspension.60

Integral V - FOx / Fix Rear Suspension .63

Design Features.63

Kinematics and Elastokinematics .63

New Challenge for the Integral Rear Axle -

Integral Active Steering .64

Suspension Options (Integral V) .69

BMW Suspension Systems

Model: All

Production: All

After completion of this module you will be able to:

• Identify BMW Suspension Systems.

• Understand BMW Suspension System design.

• Locate suspension adjustments on the front and rear axle.

3

BMW Suspension Systems

Introduction

One of the most overlooked features on a vehicle is the chassis and suspension sys¬
tem. Most of the time, people who buy new vehicles are initially attracted to the style
of the body. Some buyers are interested in the performance of the engine or the
convenience features such as the audio system etc.

BMW vehicles are well known for having “cutting edge” engine technology. However, in
order to be known as the “Ultimate Driving Machine”, it is the chassis that must provide
the driver with comfort, safety and superior “road-holding” performance.

Since the most early development period of the automobile, chassis designs have had
to keep up with the demands of the engine. The chassis and suspension system
designs have also evolved with increasing demands of the driver and the road
conditions.

4

BMW Suspension Systems

As vehicles get more powerful and demands for ride comfort and driving safety rise,
so do the demands placed on the modern chassis.

Requirements of a modern steering system:

• Ensure steerability in accordance with the driving conditions.

• Provide function, comfort and safety.

• Dampen vibration.

• Convey a confident “road feel” by transferring road surface
information to the driver.

• Allow sufficient steering wheel return after cornering.

The focus of this training module will be on BMW steering and suspension systems.
This will include all front and rear axle designs as well as adjustments where applicable.

5

BMW Suspension Systems

BMW Front Suspension History

here are three basic front axle designs used on BMW vehicles:

• Single-Joint Spring Strut Front Axle

• Double-Pivot Spring Strut Front Axle

• Double Wishbone Front Axle

Single-joint Spring Strut Front Axle

The “Single-Joint” design has been in use since the introduction of the E30. It was
used on the E30, E36, E46, E85 and the E86 vehicles. The design includes a steel
axle carrier which allows the mounting of the engine mounts, steering rack, sway bar
and lower control arm mount.

The axle carrier is bolted to the body structure via 4 bolts. There are two locating dow¬
els which provide proper axle location as well as added strength. The “sickle-shaped”
lower control arm is attached to the axle carrier via a ball joint, there is also an additional
rubber mount which is attached to the body. The lower control arm also provides the
“single-pivot” point for the steering knuckle.

The single-joint design has advantages due to it’s low weight and compact design.

The geometry of the single pivot allows for a small positive steering offset, but the
size of the brake rotor is ultimately limited. Flowever, it is ideally suited for smaller
cars (such as the early 3-series).

E46 Single-Joint Spring
Strut Front Axle

Detail of Single-Joint Spring
Strut Front Suspension

6

BMW Suspension Systems

E46 / E85 Front Suspension

The front suspension on the E46 and E85 is based on the single-joint front suspension
used on the previous 3-series models (E30/E36). This suspension includes some design
changes to enhance ride guality and handling characteristics.

The changes to the front suspension are as follows:

• A new forged aluminum lower control arm (except Xi models). The lighter arm
offers a lower unsprung mass.

• The rear lower control arm bushing is hydraulic.

• Hollow strut piston rods for reduced weight.

• The steering knuckles are “press-fit” to the strut tubes.

• The overall caster angle has been increased to improve “straight-line” stability.

• The track has been widened for improved cornering ability.

• The brake dust shields are made from aluminum.

Altogether there is a weight reduction of 5.72 pounds of “un-sprung” weight which
enhances ride comfort and handling.

E46 Front Suspension

©@ ® ®®®©

Index

Explanation

1

Track rod end

2

Steering arm

3

Hub-carrier joint

4

Anti-roll bar link

5

Rubber mounting

6

Control arm

7

Front suspension
subframe

8

Sprint strut

9

Anti-roll bar

10

Rack and pinion
steering gear

11

Track rod

7

BMW Suspension Systems

Adjustments

There are some limited adjustments on the “Single-Joint” front suspension. Front toe
is adjustable on all models via the threaded outer tie rod. This can be achieved using
standard hand tools.

There are no provisions for caster adjustment. However, Caster should always be
checked during the wheel alignment to ensure that there is no damaged components.

Camber is only adjustable on the E46 and E85. There is a slot in the upper strut
tower which will allow small camber changes of up to 0.5 degrees. If the camber
adjustment cannot be achieved, check for proper ride height and inspect for any
suspension damage.

The illustrations above show the camber adjustment slots and special tool. The proper
instructions for the camber adjustment can be found in ISTA and WebTIS Repair
Instructions under Group 32.

To adjust the camber, loosen 2 of the nuts on the upper strut mount and remove the
remaining nut. Drive out the pin in the strut plate. Install special tool # 323 140. Turn the
adjusting nut as needed on the special tool to make camber the adjustment.

It may be necessary to unload the suspension to make the needed
camber adjustment. The weight of the vehicle on the strut plate may
prevent movement while making the adjustment. Damage to special
tool can result.

8

BMW Suspension Systems

Double Pivot Spring Strut Front Axle

The double-pivot front axle configuration has been in use since the earliest 6 and 7
series vehicles were in production (E23/E24). This design is ideally suited for larger
cars due to its rugged construction.

The double-pivot front axle is used on the following vehicles:

• 1 Series - Both the E82 and E88 currently use this type of front axle.

• 3 Series - From E90 through the E93 and most recently the F30.

• 5 Series - From the E28 through the current E60/E61.

• 6 Series - Both the E24 and the new E63/E64.

• 7 Series - All models from the E23 to the current E65/E66.

• 8 Series - E31

• Z Series - The E89 Z4 uses it since start of production.

• X Series - The E83, E53, E84 and F25 use this axle with slight modifications for

xDrive and EPS (E84 sDrive Trailing links and xDrive Leading links).

One of the primary features that separates this design from the single-joint front axle is
the lower pivot point. This suspension design consists of one upper pivot (strut bearing)
and two lower pivot points. The lower pivot is actually two separate points. These two
points together create an imaginary (virtual) pivot point or “axis”.

The design eliminates a single pivot (ball joint), which limits the size of the brake rotor
and the amount of steering offset (scrub radius). The steering offset still remains positive,
but less than that of the single pivot design.

Double Pivot Spring
Strut Front Axle

9

BMW Suspension Systems

Additional advantages of the double pivot system are:

• Ability to reduce body roll while cornering.

• Reduces front end dive tendencies during severe braking situations.

• Utilization of a small positive steering offset, which offers improved handling.
This is more evident when the friction levels differ while braking.

• Improved caster position, improving straight line stability at higher speeds,
plus better steering return after small steering inputs.

Index

Explanation

Index

Explanation

1

Front subframe cross tube

6

Tension strut

2

Wheel hub

7

Anti-roll bar

3

Anti-roll bar link

8

Swivel bearing

4

Control arm

9

Hydro-mount

5

Rack and pinion steering gear

10

Spring strut

10

BMW Suspension Systems

Double Pivot Operation

The true benefits of the double-pivot suspension become more evident during turns.

On a traditional single-pivot design, the camber and caster remain static during steering
maneuvers. On a vehicle with positive caster, the wheels tend to “flop over” during turns.
This situation reduces the tire contact area with the road and increases the effort
reguired for steering wheel return. The steering offset (scrub) also remains fixed which
has a negative impact on steering wheel return as well.

The double-pivot design allows the “imaginary” lower pivot point to change relative loca¬
tion during turns. The tire which is on the outside of the turn is carrying the majority of
the load. Therefore it is the outside tire which must have the most contact area with the
road surface.

On a turn, the double-pivot design causes the caster and camber on the outside wheel
to become closer to zero. This optimizes the “contact patch” between the tire and the
road greatly enhancing handling characteristics.

The body roll is also reduced by the caster change towards zero. One of the other
benefits of this arrangement is the variable steering offset. The variable steering
offset during turns provides for better “returnability” of the steering wheel.

Double-pivot Spring Strut
Front Suspension

detailed view from the front

Index

Explanation

Index

Explanation

1

Spring strut

4

Tension strut

2

Anti-roll bar link

5

Control arm

3

Anti-roll bar

6

Track / Tie rod

11

BMW Suspension Systems

Double Pivot Front Axle Configurations

The double pivot axle features an axle carrier, to which the suspension components are
attached. The carrier also provides the mounting points for the steering rack, stabilizer
bar and engine mounts. The carrier is either steel (on the earlier models), or aluminum.

The aluminum carrier was first used on the E39 six-cylinder (528i) from 1997. The E39
was the first and only models to have both steel and aluminum carriers. The E39 540i
featured a steel carrier with a steering box (instead of a rack and pinion). Aluminum
components were used wherever possible on the 540i, except on the suspension carrier.
On the other hand, the E39 528i was equipped with an aluminum carrier and a steering
rack.

Since then, all vehicles equipped with the double-pivot suspension utilized the aluminum
carrier and steering rack configuration.

Front Axle - E39 540i

LOWER ARM

THRUST

ROD

Front Axle - E39 528i

TENSION

ROD

LOWER ARM

12

BMW Suspension Systems

E38 Front Suspension

The E38 uses an updated version of the double-pivot suspension as compared to the
previous 7 series designs (E23/E32). The features of the E38 suspension are as follows:

• Suspension carrier is made from tubular steel as opposed to stamped steel.

• Suspension carrier is lighter and can be removed as a complete unit.

• Design changes allow for larger front brake rotors.

• Slight difference in the configuration of the lower control arms.

• Lower forward control arms are made from forged aluminum.

• Variable diameter coil springs provide lower profile.

E38 Front
Suspension

SUSPENSION CARRIER

McPherson

STRUT

ASSEMBLY

HUYDRAULIC

RUBBER

BUSHING

LOWER FORWARD ARM
(REAR NOT SHOWN)

13

BMW Suspension Systems

E6x Front Suspension

The double-pivot front suspension has been further enhanced since initially introduced.
The materials used in the front axle carrier offer high tensile strength to support extreme
loads. The front axle carrier is also manufactured entirely from aluminum. It consists of
cast alloy preformed sections which are welded into the extruded sections. The front axle
carrier accommodates the steering gear, control arms and tension struts, engine mounts,
stabilizer bar, heat shield and the underbody panels.

A “thrust zone” panel is bolted on to increase the transverse rigidity of the front of the
vehicle. This reinforcement has a positive effect on the handling, sound level and crash
performance. The benefits as a result of the improved front axle include increased agility,
improved comfort by the reduction of unsprung weight, a reduction in fuel consumption
by lowering the gross vehicle weight and better axle load distribution.

The front double pivot suspension used since the introduction of the E65/66
includes the following:

• Aluminum front axle carrier

• “Thrust zone” panel for increased rigidity

• Aluminum suspension components

• Aluminum strut tubes

The front suspension on the E6x vehicles also includes accommodations
for the Active Roll Stabilization (ARS) system.

Index

Explanation

1

Stabilizer link

2

Hydro-mount

3

Front axle carrier

4

Stabilizer bar

5

Tension strut

6

Swivel bearing

7

Reinforcement

plate

8

Control arm

14

BMW Suspension Systems

Current Front Axles

Double-pivot Front Axle

E8x / E9x Front Suspension

The E9x and E8x vehicles also use the double-pivot front suspension. Traditionally,
the 3-series was equipped with the single pivot design. The E90 marked the first
time that the double-pivot design was used in the 3-series platform.

The E82 has many features in common with the E9x vehicles especially the chassis
and dynamic driving systems. Therefore the double pivot spring strut front axle design
was also installed on the E8x 1 Series vehicles. With the exception of the 135i sport
tuned version the BMW 1 Series front and rear suspensions were all inspired by the
E90 design.

E90 Double-pivot Front suspension

Index

Explanation

1

Front Axle Carrier

2

Wheel Hub

3

Stabilizer Link

4

Control Arm

5

Rack-and-Pinion

Steering

6

Tension Strut

7

Stabilizer Bar

8

Swivel Bearing

9

Hydro-Mount

10

Spring Strut

11

Reinforcing Strut

15

BMW Suspension Systems

The double-pivot system establishes a geometrical “axis” formed by the suspension
links, creating one upper and two lower pivot points. Two lower pivot points (double
pivot) formed by the control arm and tension strut create an “imaginary” pivot point,
that is extended further out on the wheel carrier. This design allows pivot points on
the wheel carrier to be selected in order to effectively accommodate larger brakes.

Additional advantages of double pivot system are:

• Ability to reduce body roll while cornering.

• Reduces front nose dive tendencies during severe braking situations.

• Utilization of a small positive steering offset which offers improved handling
while braking in split “|j” conditions.

• Enhanced caster position, improves straight line stability at higher speeds,
plus better steering return after small steering inputs.

Double-pivot suspension

Index

Explanation

Index

Explanation

1

Spring strut

4

Tension strut

2

Anti-roll bar link

5

Control arm

3

Anti-roll bar

6

Track / Tie rod

16

BMW Suspension Systems

E89 Front Suspension

The E85 was equipped with a single-joint spring strut front axle so to optimize the
suspension properties, the E89 is equipped with a double-pivot (double joint spring
strut) front axle.

An even further modified version of the Double-pivot front axle known from the E8x and
E9x series vehicles is used in the E89. Adaptations were necessary due to the available
space and the modified suspension geometry.

The well-proven principle of the central link rear axle from the E85 is retained
for the rear axle.

Index

Explanation

Index

Explanation

1

Front Axle Carrier

6

Wheel hub

2

Electromechanical power steering

7

Control arm

3

Stabilizer bar

8

Track rod

4

Stabilizer link

9

Tension strut

5

Swivel bearing

10

Engine mount

17

BMW Suspension Systems

Steering Offset on the E89

The steering offset (scrub radius) of the E89 is greater compared to that of the E85.
The reason for this is that the front axle has been adopted from production line 2
(1 Series and 3 Series).

On the single-joint spring strut front axle of the E85 the position of the wheel control
joint largely determines the size of the steering offset. Since the steering offset should
be as small as possible, the wheel control joint must be located as far towards the out-
side as possible. This however results in problems Dctermining , he Lower Pivo , Point
concerning the package space for the brake disc
and brake calliper. On the double-pivot (double-joint
spring strut) front axle the position of the control arm
and tension strut with respect to each other deter¬
mines the size of the steering offset.

The pivot points of the control arm or wishbone and
tension strut at the swivel bearing can therefore be
selected such that no space problems are encoun¬
tered for the brake system.

While these aspects still retain their validity, a larger

steering offset than on the single-joint spring strut front axle is now used. The reason for
this is that common parts from production line 2 are used as far as possible but the track
width has increased compared to the 1 Series and 3 Series. Among other measures,
this was achieved by changing the rim offset, thus, of course, also increasing the
steering offset.

The effects of increased susceptibility to interference caused by a larger steering offset
were eliminated by an optimized and modified elastokinematics system and tuned to
such an extent that an improvement was achieved
compared to the E85. As a result, the response of
the E89 to steering movements is slightly more
indirect at high speeds and very direct at speeds
up to 100 km/h (62 mph). The vehicle handling is
well balanced up to the limit range and therefore
has outstanding control properties.

Index

Explanation

1

Camber

2

Steering Axis Inclination

3

Steering offset

The term “Steering Offset” is also
known as “Scrub Radius”,“Steering
Roll Radius” or “Kingpin Offset”.

Positive Steering
Offset

W'F

18

BMW Suspension Systems

Both tension struts are mounted with hydraulic bushings on the front axle carrier. In addi¬
tion, the distance of the tension strut and control arm pivot points at the swivel bearing
largely determines the vertical force lever arm. The further the joints of the tension strut
and control arm are from each other at the swivel bearing, the greater the recovery force
initiated by the vehicle weight.

On the single-joint spring strut front axle, the distance is zero as the two joints of this
axle have merged to form one. The resulting advantage of the double-joint spring strut
front axle is improved directional stability in the high speed range and a lower tendency
to steering instability in the lower speed range (less susceptible to torsional vibration in
the steering wheel).

Compared to that of the control arm, the ball joint (guide joint) of the tension strut is
raised at the swivel bearing, thus providing effective anti-dive control. A further advan¬
tage of this arrangement is that this tension strut mount on the axle carrier can be
arranged at approximately the same level with respect to the mounting at the swivel
bearing and does not have to be lowered. This is of particular benefit to a large overhang
angle. In addition, it is possible to lower the control arm mount on the axle carrier side,
thus enabling a lower roll center.

The single-joint axle features only one type of cross brace as the axle carrier. The dou¬
ble-pivot (double joint spring strut) front axle on the other hand features a frame which
additionally provides significant stiffening of the front end.

Description

E85

E89

Total toe-in

14.4’

14.0’

Track width

1473.3 mm

1511.1 mm

Camber

-34.8’

-23.3’

Steering Axis Inclination

15.7

14.3

Caster angle

5.9

7.2

Caster offset

17.7 mm

20.7 mm

Steering offset

4.7 mm

9.6 mm

Steering angle, inner

43.1

37.7

Steering angle, outer

35.3

31.2

Rim offset ET/IS

47 mm

29 mm

225/50 R16

225/45 R17

Tire size

225/45 R17

225/40 R18

225/40 R18

225/35 R19

19

BMW Suspension Systems

F30 Front Suspension

The double-pivot front axle with trailing links in the F30 represents the optimum combi¬
nation of driving dynamics and ride comfort. The load-bearing function of the steering
box housing achieves an extremely high degree of rigidity with the lowest possible
weight.

Compared to its predecessor in the E90, the front axle support in the F30 must satisfy
more stringent requirements. A second crash load path has now been integrated above
the front axle support. In order to guarantee optimum crash behavior, a high-strength
welded steel structure has been used instead of an aluminim front axle support.

The Electronic Power Steering EPS (electromechanical power steering) featured in the
F30 makes an important contribution to BMW EfficientDynamics. The F30 is available
with 2 types of EPS (Basic and Variable sport option)

F30 Double Pivot Front Suspension
with Trailing Links and EPS

20

BMW Suspension Systems

Improved acoustic properties and maximum rigidity and accompanying increase
in ride comfort can be achieved within a small installation space.

The ball joints of the front axle have a reduced friction design which results in improved
response characteristics. Also the use of cast aluminim parts (wishbones, trailing links)
and aluminim die-cast parts (swivel bearings) reduces the unsprung masses.

For vehicles with an adaptive M sports suspension (optional equipment 2VF)
the electronic damper control EDC is also integrated.

Front Axle of F30

viewed from below

Camber correction is possible by replacing the swivel bearing
with and off-set part available from the parts department. Refer
to the adjustment section in this chapter for more information.

21

BMW Suspension Systems

Sport Activity Vehicles (Except E70) Front Suspension

The E53, E83, E84 and F25 vehicles use a modified version of the double-pivot
(double joint spring strut) front suspension. There are modifications to accommodate
the front drive axle components. Although most xDrive vehicles use hydraulic rack and
pinion steering the E84 and F25 use EPS. There is an aluminum thrust panel which
helps protect the oil pan and also provides additional stiffening properties for the front
suspension carrier.

E83 Front Suspension

1 ) 8

Index

Explanation

Index

Explanation

1

Swivel bearing

5

Tension arm

2

Anti-roll bar link (attached to strut tube)

6

Anti-roll bar

3

Thrust panel

7

Front axle carrier

4

Control arm

8

Axle carrier rear mounts

22

BMW Suspension Systems

F25 Front Axle with EPS

The Double-pivot front suspension with trailing links in the F25 offers the ideal combina¬
tion of driving dynamics and ride comfort. The supporting function of the rack and pinion
steering housing achieves extremely high rigidity with minimum weight. Low-friction ball
joints are used in the front axle. This has greatly improved the response characteristics
over its predecessor.

The standard Electronic Power Steering (EPS) is a distinctive feature of the F25 and
makes a significant contribution to "EfficientDynamics". (2VL Variable sport steering
is available as an option).

The Electronic Damper Control (EDC) is also available as optional equipment
(SA 223 Dynamic Damper Control).

F25 Double-pivot
Front Axle with
Trailing Links

Index

Explanation

Index

Explanation

1

Front Axle Carrier

7

Track Rod

2

Stabilizer Link

8

Trailing Link

3

Support Bearing

9

EPS Rack-and-Pinion

4

Wheel Hub

10

Stabilizer Bar

5

Spring Strut

11

Swivel Bearing

6

Wishbone (Control Arm)

23

BMW Suspension Systems

E84 Front Suspension

The E84 sDrive (rear wheel drive) uses an aluminim Double-pivot front axle fitted with
trailing links while the E84 xDrive (four-wheel drive) uses a steel a Double-pivot front
axle fitted with leading links.

Index

Explanation

1

Engine mount

2

Stabilizer link

3

Spring Strut

4

Swivel Bearing

5

Wishbone control arm

6

Trailing Links

7

Stabilizer Bar

8

Front axle support

E84 Double-pivot Front Axle
with Trailing Links

E84 Double-pivot Front Axle
with Leading Links

Index

Explanation

1

Engine mount

2

Stabilizer link

3

Spring Strut

4

Swivel Bearing

5

Leading Links

6

Wishbone control arm

7

Stabilizer Bar

8

Front axle support

24

BMW Suspension Systems

Adjustments - Double-Pivot Front Axle

As with all BMW front suspensions, Caster angle is not adjustable. However, during
an alignment, Caster should always be checked to rule out any damage to the chassis
or suspension components.

As with other models, Toe is adjustable via the threaded tie rod assembly.

Camber is adjustable by a slotted strut mounting holes. This adjustment is only
available as from the E53. Vehicles which are capable of this adjustment include,

E53, E6x, E9x, E8x.

On the E84, F25 and F30 the camber can be corrected by using special offset
swivel bearings which are available from the parts department.

Two versions of the swivel bearings are available:

• Version 1: camber correction -0° 30'

• Version 2: camber correction 0° 30'.

Version Identification

Color coding

Standard

No color coding

Plus 30' +

Green dot (1)

Minus 30' -

Blue dot (1)v

These camber correction swivel bearings are used to correct the camber values by
30 minutes. They are only to be used only if the tolerance values are exceeded.

The E83, E53, E84, F25 and F30 vehicles use a modified version of
the Double-pivot front suspension which may also be referred to as
Double-joint spring strut front axle.

25

BMW Suspension Systems

Double Wishbone Front Axle

E7x Front Suspension

The first time a double wishbone front suspension was used on a BMW vehicle was on
the E70. The outstanding driving dynamics, the excellent driving comfort as well as the
stable straight-ahead running properties are factors of this design solution that contribute
to a high degree of driving pleasure and safety while making the vehicle ideal for every
day use.

E70 Double Wishbone
Front Suspension

Index

Explanation

Index

Explanation

1

Ride-height sensor

7

Wheel bearing

2

Mount

8

Stabilizer link

3

Spring strut

9

Tension strut with hydraulic mount

4

Upper control arm (upper wishbone)

10

Lower control arm (lower wishbone)

5

Spring strut support

11

Spring strut fork

6

Swivel bearing

12

Stabilizer Bar

26

BMW Suspension Systems

The upper control arm (wishbone) positively influences front wheel travel by reducing
Camber changes during jounce and rebound events.

The arrangement of the suspension allows the strut assembly to be focused on
dampening duties alone. The strut is no longer part of the steering, but fixed in place
(no upper bearing). The steering axis now rotates by way of the swivel bearing (6).

The arrangement of the front suspension includes bushings at various swivel points.
This allows for reduced friction, which in turn allows the damper to respond to road
surface irregularities in a more sensitive manner.

This design works well in conjunction with the Vertical Dynamics Management
(VDM) system.

Components with special materials (see previous graphic):

• The forged aluminum swivel bearing (6) with the 3rd generation wheel bearing (7)
Semi-trailing arm connected via steel bushes/tapered screw connection to the
swivel bearing.

• The upper control arm (4) is made from forged aluminum and the cylindrical ball
joint pin is clamped in the swivel bearing (6).

• Tension strut with hydraulic mount (9) and lower control arm (10) are forged steel
components while the bottom control arm bears the spring strut (3) by means of
the cast steel spring strut fork (11).

• The front axle subframe is a welded steel structure with an aluminum thrust panel
for maximum lateral stiffness with service openings.

The steering pivot axis of the wheel suspen¬
sion is now formed by a joint at the upper
control arm and the virtual pivot point of the
lower arm level as known from the spring
strut axle.

See “FOx Virtual Pivot Point”
for more information.

Virtual Pivot Point of
Lower Control Arm Level

27

BMW Suspension Systems

FOx / Fix Front Suspension

A double wishbone front axle as known from the E70 and E71 is also fitted on the
FOx/FIx vehicles.

FOx Double Wishbone
Front Suspension

Index

Explanation

Index

Explanation

1

Spring strut

6

Transverse control arm, bottom

2

Transverse control arm, top

7

Stabilizer bar

3

Swivel bearing

8

Tension strut with hydraulic mount

4

Wheel bearing

9

Front suspension, subframe

5

Stabilizer link

28

BMW Suspension Systems

In comparison with the double pivot spring strut front axle on the E65, the FOx/FIx front
axle design offers the following advantages:

• Higher transverse acceleration is reflected in greater vehicle agility.

• Improved cornering/steering and transition characteristics which are particularly
favorable in terms of rolling motion.

• Reduced interference means greater comfort.

• Shock absorbers that are subjected to virtually no transverse forces provide greater
comfort.

• The design layout of the double wishbone front axle facilitates vertical dynamics
control (VDC) and xDrive (as on the E70/E71) without the need to adjust height
and no spring travel loss.

• Double wishbone front axles improve directional stability.

The outstanding driving dynamics, the excellent driving comfort as well as the exception¬
al directional stability are factors of this double wishbone front axle design solution that
contribute to a high degree of driving pleasure and safety while making the vehicle ideal
for every day use and providing the most relaxing drive on long journeys.

The introduction of a second control arm level for wheel control, which is arranged above
the wheel, results in additional degrees of freedom for the kinematics of the front axle as
well as for the suspension/damping compared to other designs such as a spring strut
front axle.

29

BMW Suspension Systems

SAI - Virtual Pivot Point on Double Wishbone Front Axle

As is the case with the E70 the steering axis inclination (1) of the wheel suspension
is formed by a joint at the top A-arm and the virtual pivot point of the lower arm.
This allows the steering pivot axis to be positioned in such a way as to produce
a small steering offset at hub (3) with sufficient weight recoil.

Index

Explanation

1

SAI

2

Perpendicular line in
wheel contact point

3

Steering Offset

i

Description (Front axle data)

E65 / E66

F01 / F02

Steering offset at hub (mm)

88.1

56.3

Track width (mm)

1578

1611

Camber

-0° 20' ±20'

-0° 12' ±15'

Camber difference

0° ±30'

0° ±30'

Total toe-in

10' ±8'

16'±6'

Turning circle (m/ft)

11.92/39.10

12.15/39.86

Kingpin offset (mm)

0

0.5

Toe angle difference (toe out on turns)

1° 27' ±30'

o

C\J

o

C\J

Caster angle

7° 27' ± 30'

-vl

O

O

30

BMW Suspension Systems

This steering offset at hub is a direct influence on the scrub radius which is decisive
for transmitting the irregularities on the road surface to the steering wheel.

The lower and upper arm levels now move simultaneously in response to wheel deflec¬
tion. As a result, as the spring compresses, the wheel pivots in such a way that the
camber does not decrease as much as is the case with a spring strut front axle.

Since the two control arm levels undertake the wheel control, the damper is virtually
no longer subjected to transverse forces and rotational motion.

This makes it possible to do without a roller bearing assembly on the spring strut sup¬
port. Instead of this conventional roller bearing, a damping and support unit is installed
that takes up all three load paths. The load paths are the damper piston rod, the inner
auxiliary spring and the bearing spring. This damping and support unit is still referred
to as the "strut mount".

Due to the lack of transverse forces, the piston rod can be made thinner, resulting in a
similar displacement volume in the push and pull direction of the damper. This serves
to improve the design layout of the damper and is the prerequisite for the innovative
damper control system - vertical dynamics control (VDC).

Due to the substantially lower friction at the circumference of the piston rod, the damper
can respond more sensitively.

By connecting the stabilizer bar via the stabilizer link to the spring strut, the torsion in
response to body roll motion is equivalent to the total wheel lift from the inside to the
outside of the curve (in other suspension setups, the stabilizer bars are connected to
a transverse control arm and therefore achieve only a fraction of the torsion angle).

Despite being highly effective, this high degree of torsion allows the stabilizer bar to
be made relatively thin which has a favorable effect on driving comfort and dynamics
as well as saving weight.

31

BMW Suspension Systems

Adjustments - Double Wishbone Front Axle

The Toe adjustment on the double wishbone front axle is carried out by means
of a tie rod adjustment.

The Camber adjustment, however, can only be adjusted by a replacement of the
upper control arm (wishbone). The control arm is available in three possible part
numbers. One of which is the standard (zero) arm, while the other two are offset
to effect a small Camber change if needed.

Negative (-) Camber

33

BMW Suspension Systems

Rear Suspension History

As requirements for improved performance continue to increase, rear axle technology
must also be continually enhanced. Throughout the development of various BMW
Group vehicles, the rear axle has continually evolved to meet the overall needs of
chassis design.

Throughout the various design changes, rear axles have allowed improvements in
traction and stability. The rear axles have also been “weight optimized” which allows
for an overall balanced chassis.

The rear axle designs have also made it possible to decrease changes in rear camber
and toe during suspension travel. By limiting camber and toe changes, the tire can
maintain a better contact patch, thereby improving rear end stability and improved
tire wear.

E65/E66 Rear Axle (Integral IV)
Shown with ARS and Rear Air Suspension.

Some of the other improvements to rear axle design include the complete isolation of
the rear axle through rubber bushings. This decreases the incidence of the transmission
of road noise into the vehicle’s body and provides superior ride smoothness.

The chart on the next page list the various rear axle designs on BMW vehicles through
the last few decades of production vehicles.

34

BMW Suspension Systems

Development of BMW Rear Axles

Rear Axle Designation

Rear Axle Features

Models

HA 1

Semi-trailing arm axle

El 2, E21, E28, E30, E36/5, E36/7

HA 2

Semi-trailing arm axle
(with track-link)

E23, E24, E32 and E34

HA 3

Central “C” link rear axle

E36 (Except E36/5 and E36/7),

E46, E83, E85 and E89

HA 4

Design Study

Not used in production vehicles

N/A

HA 5

5-link rear axle

(Dispersed double control arm axle)

E90 (E91, E92)

E82, E88, E84

F25, F30

Integral 1

Design Study

Not used in production vehicles

N/A

Integral II

Design Study

Not used in production vehicles

N/A

Integral III

5-link rear axle. Integral design with
multi-link.

E31

Integral IV

Steel carrier, with spring on damper

E38

Integral IV

Aluminum carrier, spring on body,
damper on axle carrier.

E39

Integral IV

Aluminum carrier

E39/2 (Touring)

Integral IV

Steel axle carrier, aluminum link with
steel wheel carrier, spring and damper
separated, but still supported on body.

E53

Integral IV

Aluminum axle carrier, spring and
damper on wheel carrier.

E65/E66

Integral IV

Aluminum axle carrier, spring and
damper on wheel carrier.

E6X

(E60, 61,63 and 64)

Integral V

Aluminum axle carrier, used with con¬
ventional or air springs and spring
struts depending on the vehicle.

E70 ( E71, E72)

FOx (F01, F02, F07, F10, FI 2,

FI 3)

Bold = Current Models

35

BMW Suspension Systems

HA1 - Semi-Trailing Arm Axle

The illustration below shows a semi-trailing arm axle used on some of the early BMW
models. As with all of the rear axle designs covered in this training module, this is a type
of independent rear suspension. The suspension consists of two trailing arms connected
to the rear axle beam (subframe).

The final drive and rear axle beam are connected to the unibody structure via three
rubber mounts. These mounts serve to insulate drivetrain and suspension noises from
the body structure.

There are coil springs which are mounted on the trailing arms. The upper portion of the
coil springs use a rubber insulating pad which rests on the body structure.

The dampers are mounted to the hub carrier and the upper end attaches to the body.
There is an “anti-roll” bar which attaches to the control arms via links.

The trailing arms on this type of suspension travel in a circular path. This causes
changes to rear camber and rear toe as the suspension travels through “jounce
and rebound” motions.

Future variations of BMW suspension system improve this action resulting in less
camber and toe changes.

36

BMW Suspension Systems

HA2 - Semi-Trailing Arm Axle (with Track Link)

This rear suspension design is mostly similar to the previous Semi-trailing arm axle. It is
sometimes referred to as the “screw-link” or “helical-link” axle. The primary change is
the installation of a “track-link”. This limits the total travel arc of the trailing arm from 20
degrees to 13 degrees. This reduces the camber and toe changes.

The spring was moved from the trailing arm to the damper. This rear axle is used on the
E23, E24, E32 and E34. Both versions of the semi-trailing arm axle cannot be adjusted
via standard methods.

If a toe correction is required, there are offset bushings available
through parts. For more information, refer to repair instructions
in WebTIS or the Alignment section of this training course.

37

BMW Suspension Systems

HA3 - Central “C” Link

E46 Rear Suspension

The rear suspension design on the E46 is a further development of the “Central Link”
rear axle. The following modifications were carried out to optimize weight reduction and
improve noise characteristics:

• The upper lateral link is now made from aluminum.

• The subframe (rear axle carrier) is now made from tubular steel.

• The differential is mounted to the frame with an hydraulic mount.

The central link rear axle optimizes the following properties:

• Directional stability

• Alternating load response

• Self-steering response

• Lane change stability

• Transition response from cornering to straight ahead

• Rolling comfort

The designation HA3 does not refer to the three links but rather
is a continuation of the development designation at BMW.

38

BMW Suspension Systems

E83 Rear Suspension

The Central Link rear suspension has been adapted to the E83. The rear suspension
is a further modification of the design used on the E46/16 (AWD/xi Models).

The E46/16 rear suspension has been adapted to the E83 as follows:

• Anti-roll bar secured to the rear axle carrier by clamps.

• Front of rear axle carrier suspension converted to special bolts
with additional thrust washer.

• Thrust brace and tension arms.

• Surface of control arms are galvanized steel plates.

• Anti-roll bar link with ball joint attached directly to the control arm.

• Dampers with three point flange (bolt) plate.

Index

Explanation

1

Tension arm

2

Central arm
(right)

3

Upper lateral
link (right)

4

Rear axle carri¬
er (subframe)

5

Lower lateral
link (left)

6

Thrust brace

When removing or lowering the rear axle, the handbrake cables
(routed through the rear axle carrier and the body console) must
be disengaged before the rear axle is lowered. This is to prevent
shearing of the handbrake cables.

39

BMW Suspension Systems

E85 Rear Suspension

The rear suspension on the E85 is taken from the E46 with some minor changes for the
roadster. The track width has been increased by 30 mm. A reinforcement plate has been
added to increase rigidity. Due to underbody aerodynamics, a duct has been added to
direct airflow to the differential. The differential cover has cooling fins to help keep the
differential within the proper temperature range.

E85 HA3 Rear Axle

Index

Explanation

Index

Explanation

1

Rear subframe section

5

Reinforcement plate

2

Left upper control arm (lateral link)

6

Reinforcement support bracket

3

Central arm (left)

7

Rear subframe mounting bushings

4

Lower lateral link (left)

8

Central arm bushing (right)

40

BMW Suspension Systems

Rear Suspension Adjustments (HA3 Central Link Axle)

Rear Toe

Toe is adjusted by moving the forward central arm bushing mount with a special tool.
The tool part number varies between models. Tool number 32 3 080 is used for the
E36. The E46, E8, E83, E89 use tool # 32 3 030. These tools are not used for the
318ti and Z3 as the rear suspensions on the vehicles are different (HA-1).

Rear Camber

Rear Camber is adjusted by rotating an eccentric bolt located at the outer end of the
rear lower lateral link. No Special tools are required to make the Camber adjustment.

41

BMW Suspension Systems

Integral Axle (III and IV)

The “integral axle” is a multi-link rear suspension which was introduced on the E31.
Subsequent variations of this design have been utilized on the 5 and 7 series vehicles
including the E53 SAV and E39 Sportwagon. These suspensions incorporate what is
called “elastokinematics” that allow each wheel to move and flex individually without
loads and forces through the subframe to the opposing wheel.

The integral axle has been used on the following vehicles:

• E31 (8-series all models)

• E38 (7-series all models)

• E39 (5-series all models)

• E53 (X5 all models)

• E52 (Z8)

• E6x vehicles (including E65, E66, E60, E61, E63 and E64)

• X Series vehicles (including E70, E71, E72)

E31 Rear Suspension (Integral III)

The first BMW vehicle to use the “multi-link” Integral III rear suspension was the E31.
The E31 version of this suspension uses a 5-link design rather than the subsequent
4-link design of later models.

The “fifth-link” was the trailing arm which was deleted as of the E38 and E39 models.
The E31 design placed the rear springs between the body and the upper lateral link.
When introduced, this suspension was very innovative for it’s time and provided
improved directional stability and marked an advance in driving comfort. Future models
reaped many benefits from this suspension design.

Integral III Rear Axle

42

BMW Suspension Systems

E38 / E39 Rear Suspension (Integral IV)

The E38 and E39 models use a modified version of the E31 multi-link rear suspension
system. The system was modified to be more compact yet provide the same handling
and ride characteristics as the E31 system.

The trailing arm was eliminated and all suspension mountings are done to the sub-frame
of the vehicle. The springs were moved to the dampers. The changes from the E31 pro¬
vided further improvements to the integral rear axle including weight savings and
improved noise characteristics.

Integral IV Rear Axle

HEAP LINK

LEADING

LINK

LOWER i R M
(WI3HBONEJ

INTEGRAL LINK

WHEEL-HUS

GATiniEn

43

BMW Suspension Systems

E39 / E53 Rear Suspension (Integral IV)

The E39 Sportwagon/E53 X5 rear suspension is the “integral” multi-link design taken
from the E38/E39 vehicles. Several components are made from aluminum to reduce
the unsprung weight. The X5 has the optional EHC or EHC II dual axle air suspension.

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 hydro-mount in the rear. The wheel bearings are
similar to the E39 but incorporate different seals - designed for off-road use.

Integral IV Rear Axle

The E39 Sportwagon shares the same basic rear suspension design as the E53 X5.

The standard rear suspension of the E39 Sport wagon follows the design characteristics
of the four link elastokinematic system of the E38/E39 sedan vehicles.

The main design difference is the separation of the coil springs and dampers.

• The coil springs are positioned between the perches of the wheel carriers
and the underside of the rear floor pan.

• The shock absorbers are positioned diagonally between the lower lateral
control arm and the rear axle sub frame.

44

BMW Suspension Systems

This configuration provides the wide, uniform load space in the cargo area.

Since the shock absorbers are now mounted directly to the sub frame, the sport wagon
reguires unigue sub frame hydro mounts. The hydro mounts contain a fluid that helps to
suppress road/suspension noise and vibrations from transmitting into the vehicle body.

Integral IV Rear Axle

COIL

The hydro mounts require new special tools for removal and replace
ment. Refer to ISTA for more information special tools section.

45

BMW Suspension Systems

E6x Rear Suspension (Integral IV)

The rear suspension of the E6x vehicles which include the 5, 6 and 7 series vehicles
remained mostly unchanged. The design is a slightly modified version of the Integral
IV rear axle from the previous generation 5 and 6 series.

Provisions have been made to accommodate the Active Roll Stabilization System, the
rear air suspension system (EHC) and the Electronic Damping Control System (EHC).

The subframe assembly continues to be made from aluminum. Otherwise, the rear
suspension is very similar to previous designs.

Index

Explanation

Index

Explanation

1

Rear subframe assembly

3

Front differential mounting

2

Rear differential mounting

4

Thrust plate

46

BMW Suspension Systems

Rear Suspension Adjustments (Integral Rear Axle lll/IV)

The integral rear axles (III and IV) have accommodations for the adjustment of both rear
Toe and rear Camber angle. The adjustments consist of eccentrics that can be adjust¬
ed using standard hand tools. The only exception is the E53 X5, which due to space
limitations needs special wrenches to access the toe eccentric.

E53 Camber Adjustment
(other integral axles similar)

E53 Toe Adjustment
(other integral axles similar)

WS !, 1NJ

E53 Rear Toe Adjustment Tools

47

BMW Suspension Systems

48

BMW Suspension Systems

Current Rear Axles

HA3 - Central “C” Link - E89 Rear Suspension

A version of the rear axle known from the E85 (See Rear Axle History section) with the
development designation HA 3 (Central Link) is fitted in the E89 Z4.

The Central Link rear axle is an intricately constructed, weight and space saving, multi¬
link rear axle. The wheels are controlled by two control arms and one semi-trailing arm
that is mounted at the central point on the body. The precise interaction between the
semi-trailing arm and control arm ensures that the wheels remain in the best possible
position with respect to the road surface, thus providing outstanding directional stability.
The flexible link bushings ensure exceptional driving stability while cornering, providing
the vehicle with excellent rolling and acoustic comfort.

Index

Explanation

1

Semi-trailing arm (right)

2

Upper control arm

3

Lower control arm

4

Thrust brace

5

Stabilizer bar

6

Stabilizer link

7

Rear subframe axle carrier

See Central link axle section for information regarding rear toe and
camber adjustment. Always refer to repair instruction available on
ISTA for specific details.

49

BMW Suspension Systems

HA 5 Rear Axle

The new HA 5 rear axle is the newest development in rear axle technology. Although this
design was first installed on the E87 1 Series (not sold in the US). It was introduced to
the US market with the launch of the E90 3-Series and has since been installed in the
E82, E88, F25, F30 and E84.

Designed as a multi-link independent rear suspension axle with 5 different link arms it
is also referred to as five-link rear axle. The designation "HA 5" does not refer to the five
links but rather represents the consecutive development designation used at BMW.

As compared to the HA 3 and HA 4 rear axle, which were made mostly from aluminum,
the HA 5 rear axle is made primarily from high strength steel. The wheel carrier is cast
from GGG 40.

E90 HA 5 Rear Suspension

Minor differences exist between the HA 5 link rear axle versions depending
on the vehicle:

• On the xDrive versions the wheel carrier is modified slightly as it utilizes
bigger wheel bearings.

• In all variants the rear axle transmission mounting is matched to the
relevant drivetrain.

50

BMW Suspension Systems

HA 5 Rear Axle Layout

HA 5 Rear Axle (iT) ^ 9) iQy

front left view

Index

Explanation

Index

Explanation

1

Rear axle carrier

6

Stabilizer link

2

Thrust rod

7

Toe link

3

Traction strut

8

Semi-trailing arm

4

Wheel hub

9

Camber link

5

Control arm

10

Wheel carrier

HA 5 Axle

view from rear left (top)

51

BMW Suspension Systems

Top View of Left Rear Axle

The two upper links (blue in the
illustration) form a triangle in the
top view as do the two lower links
(purple in the illustration).

The rear link (orange in the illustration)
represents the toe rod.

Index

Explanation

Index

Explanation

1

Semi-trailing arm

4

Toe link

2

Traction strut

5

Camber link

3

Control arm

52

BMW Suspension Systems

Advantages

Compared to previous rear axles the HA 5 offers the following advantages:

Manufacturing Costs

The lower costs are attributed to the fact that the use of high strength steel has
made it possible to reduce the wall thicknesses of the rear axle carrier and the links.

Compared to the Integral IV, a considerable cost saving measure has been utilized
by manufacturing the entire axle from high strength steel plus the weight of the HA 5
rear axle is not excessively high.

Light Construction

A bending moment occurs only in the camber link, as it provides the support function
for the spring and damper. The remaining four links are not subjected to moments of
force thereby enabling a lightweight and rigid design.

Thanks to the straight design of the links and the connection by means of ball joints,
except for the camber link, the wheel control with this axle is subject to only minimal
elasticity and is very precise.

Production

The HA 5 rear axle can be completely pre-assembled and adjusted with the brake
system as well as the suspension and damping.

Kinematics

The very small positive kingpin offset guarantees less sensitivity to longitudinal forces
even in connection with wide tires.

The relatively large caster ensures a defined degree of lateral force understeering and
therefore improves vehicle handling/stabilization and offers faster response.

The change in toe as part of the suspension action enables outstanding directional
stability with a relatively short wheelbase and exceptional self-steering characteristics
while cornering.

The change in camber as part of the suspension action is selected in order to establish
an optimum camber with respect to the road surface while cornering.

The long toe link has a positive effect on the toe-in characteristics over the spring
travel range.

A low roll center has a particularly beneficial effect on the rolling motion.

The "propping" effect while cornering has been largely minimized by improving
the roll center change rate.

53

BMW Suspension Systems

The braking support has been set to 70%. Racing cars generally have a support angle
of 0% in order to constantly achieve maximum contact force. On these vehicles, the
disadvantage of a dive motion while braking and starting off is compensated by the
taut suspension. The braking support (anti-dive) realized on the E90 represents an
optimum compromise between comfort, safety and driving dynamics requirements.

The use of five links enables free selection of the pivot axle for the design layout. This
means that the movement of the wheel in interaction with the suspension can be opti¬
mized without compromise under braking, acceleration and lateral forces. This largely
determines all important variables such as toe, camber, brake support (anti-dive) angle,
roll center and roll center change rate.

Crash Requirements

The HA 5 rear axle permits a considerably more favorable progression of the side
member, resulting in specific advantages particularly at low impact speeds.

Added to this, the large rear axle carrier is connected directly to the rigid frame side
member, allowing it to transmit the applied crash forces more favorably. The semi-trailing
arm features crash beading (in the semi-trailing arm of the HA 5 rear axle) to ensure the
fuel tank is not damaged.

Rigidity / Acoustics

The rear axle carrier of the HA 5 rear axle extends up to the rigid frame side members
of the body with its axle mounting points and even up to the sill with its thrust rods. This
provides a very large support face for the applied forces and moments. The resulting
advantages include, considerably lower stress and strain on the body (rear axle break¬
away) and the option of designing the rear axle bearing mounts relatively soft. This
arrangement and the double flexible mounting, provide outstanding insulation against
road noise and tire rolling noise.

54

BMW Suspension Systems

■ Setting E9X/E82 Rear Axle Adjustments

Toe and Camber adjustment points: rear view of left rear

The two upper links (blue in the illustration)
form a triangle in the top view as do the two
lower links (purple in the illustration). The rear
link (orange in the illustration) represents the
toe rod.

The rear axle carrier and the links are made
from high strength steel. The wheel carrier
is cast from aluminum alloy.

Index

Explanation

1

Toe adjustment eccentric

2

Camber adjustment eccentric

Minor differences exist between the HA 5 versions being used on the E9X and E82
variants. The rear axle of the E82 is fitted with modified wheel hubs. As a result, the
rear track width of the E82 has been widened by 20mm in comparison to the E9X.

The extended rear wheel arches, combined with the wider rear track width emphasizes
this vehicle's rear-wheel drive characteristics.

The springs and dampers differ from those in the E90 in that they have been adapted
to the E82’s vehicle weight. The front axle of the E82 is fitted with a hollow-type anti-roll
bar for weight reduction and a sport tuned suspension is available as an option on the
BMW 128i (standard equipment on BMW 135i).

© © © © ©

Index

Explanation

1

Drive shaft

2

Wheel bearing

3

E90 wheel hub

4

Widening of track width (+10 mm each side)

5

E82 wheel hub

Wheel Hub on the Rear Axle,

Difference between E82 - E90
(Cut away view)

55

BMW Suspension Systems

F25 Rear Suspension

The HA 5 five-link rear axle installed in the F25 is derived from a double wishbone rear
axle with rear mounted track rod. Although the engineering design principle of the rear
axle is based on the one used in the E8x and E9x vehicles, this version is characterized
by its low installation space reguirement and light weight of its components.

Index

Explanation

Index

Explanation

1

Compression strut

6

Toe link

2

Spring strut

7

Upper wishbone

3

Stabilizer bar

8

Wheel hub

4

Rear axle carrier

9

Camber link

5

Lower wishbone

10

Control arm

The terminology has changed due to the design changes implement
ed on the F25 rear axle when compared to the E90 HA 5.

56

BMW Suspension Systems

In addition to a particularly precise wheel control, this design delivers outstanding driving
dynamics in relation to the following:

• Directional stability, accuracy

• Load change response

• Self-steering response

• Lane change stability

• Steering movement (transitional response from cornering to straight-ahead driving).

In contrast to the E84 and E9x series, spring struts are installed at the rear axle instead
of the split arrangement of springs/dampers. A high suspension ratio has been achieved
through the installation of spring struts.

The optimized elastokinematics ensures ride comfort as the use of small but effective
control arms means that the rear axle hardly reacts to interference.

The flat space-saving design of the axle with wide spring struts mounted on the outside
results in a flat luggage compartment floor with generous loading width.

Low unsprung masses have been implemented using innovative sheet-metal control
arm technology.

F30 Rear Suspension

F30 rear suspension is a five-link rear axle (HA5) design which is also based on the E90
now has a steel construction and has been significantly enhanced.

The elastokinematics installed in the five-link rear axle have been coordinated specifically
to the F30 chassis.

Precise and superior wheel control is possible in all driving situations due to the large
spring travel range. Therefore it has been possible to resolve the conflicting objectives
of driving dynamics and comfort by:

• The flexible suspension of rear axle differential at rear axle support and the flexible
bushing of rear axle support at body (2x flexible bushings) have been specifically
coordinated to the F30 chassis.

• Maximum support base width for the rear axle support.

• Significant increase in track width when compared to E90.

• Optimum connection of body suspension and damping.

57

BMW Suspension Systems

E84 Rear Suspension

A five-link rear axle HA 5 as known from the 1 series and 3 Series is also installed
in both E84 models (sDrive/xDrive).

The HA5 in the BMW XI otters enhanced comfort due to a double-elastic bushings
and a large rear axle support base. Furthermore, the design principle of the HA5 is
light weight and very compact.

The five-link rear axle is mainly derived from a twin control arm rear axle with the track
rod located in the rear, whereby the upper and lower A-arms were replaced by two indi¬
vidual arms each. The advantage of this is that, regardless of the installation space situa¬
tion, it is possible to freely specify the effective virtual kinematics point. The result of this
design coordination is elastokinematic properties that permit exact wheel control across
significant spring travel, which is required for the desired driving properties. In addition,
due to small effective lever arms, the rear axle barely reacts to road interferences.

The large support base for toe and camber on the wheel carrier side and the extremely
rigid trailer arms, as well as the stiff rear axle support and the connection to the body by
means of strut rods ensure highly precise wheel control. This is the prerequisite for agile
overall coordination of the BMW XI. The use of high-torque engines and the properties
of the run-flat tires were taken into consideration when designing the large rear axle sup¬
port base resulting in enhanced driving properties as well as superior sound insulation.

The BMW XI uses many of the rear axle components of the BMW 3-Series Touring
(E91). The hub carrier and the upper wishbone were redesigned (due to the height
difference in the BMW XI) as well as the rear axle support rear cross member (with
the connection for camber link and toe link); the remaining components are identical
to the rear axle support in the BMW 3-Series Touring.

The HA5 provides the best prerequisites for the particularly space-saving rear concept
(location of rear seat position, fuel tank, and luggage compartment). Thus, a comparably
large through-loading width as well as ample legroom can be achieved in the rear.

58

BMW Suspension Systems

E84 XI Five-link Rear Axle

Top 3/4 left front view

Index

Explanation

Index

Explanation

1

Thrust Rod

5

Stabilizer bar

2

Toe link

6

Control arm

3

Camber link

7

Traction strut

4

Rear axle carrier

8

Semi-trailing arm

59

BMW Suspension Systems

Integral IV - E7x Rear Suspension

The rear suspension in the E70 is a further-developed integral IV design based on the
E53 rear axle. It is characterized by improved driving dynamics without compromising
comfort and driving safety. With this axle it was possible to increase the width and depth
of the load area compared to the previous design (See Rear Axle History section).

The result is a considerably larger and more functional load space (third row of seats)
particularly through the use of the single-axle air spring (rear axle air suspension). This
design layout guarantees brilliant road handling characteristics irrespective of the vehicle
load and at a constant ride height.

Safety functions are defined by the superior vehicle control characteristics. Effective
de-coupling of the road and drivetrain guarantees outstanding levels of acoustic and
vibration comfort.

E70 Integral IV

left front view

Index

Explanation

Index

Explanation

1

Traction strut / upper radius arm

4

Integral link

2

Control arm

5

Swinging arm

3

Wheel carrier

6

Tension strut

60

BMW Suspension Systems

The dynamic and drive forces applied through the wheel contact point into the suspen¬
sion are taken up by the wheel carrier, rear axle carrier and four control arms. The design
layout reduces the flexible pulling action in the wheel carrier and therefore enables
lengthways damping of the wheel control, which is important for rolling comfort, by
means of soft front link brackets on the rear axle carrier.

Due to the position of the spring on the wheel carrier, it is no longer necessary to sup¬
port the weight of the vehicle on the rubber mounts on the rear axle carrier. The opti¬
mum lengthwise damping and the favorable spring position facilitate effective isolation
of rolling and drive noise while significantly contributing to the refined smooth and guiet
vehicle running characteristics.

E70 Integral IV Rear Suspension

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Index

Explanation

Index

Explanation

1

Traction strut

6

Tension strut

2

Control Arm

7

Front differential mounting

3

Wheel carrier

8

Rear differential mounting

4

Integral link

9

Rear axle carrier

5

Swinging arm

10

Anti-roll bar

61

BMW Suspension Systems

Compared to the E53, the rear axle of the E70 was adapted to the requirements of
the larger dimensions, higher overall weight, increased power/torque, the BMW run
flat safety system and the demanding objectives in terms of driving dynamics and
comfort. The main criteria that governed the selection of materials included:
component weight, production process (cold forming, casting properties, welding
properties), strength and deformation characteristics as well as corrosion resistance
The resulting advantages include:

• Outstanding driving dynamics, further increased compared to the E53,
without compromising comfort and driving safety.

• Distinctly larger and more functional load area by increasing the effective
load width and depth.

• Level control (1 -axis air suspension) ensures constant ride-height and
driving characteristics irrespective of the vehicle load.

These design enhancements have been carried over to all current E7x vehicles
and served as a base for the development of the Integral V rear axle use in current
FOx/FIx vehicles.

See Rear Suspension Adjustments (Integral lll/IV Rear Axle) in the
Rear Axle History section for information regarding rear toe and
camber adjustment. Always refer to repair instruction available
on ISTA for specific details.

62

BMW Suspension Systems

Integral V - FOx / Fix Rear Suspension

The Integral V rear axle design was introduced with the launch of the F01/02 in late
2008. This suspension design differs from the previous 7 Series (E65) which used the
familiar and already proven “Integral IV” (The Integral IV rear axle design was introduced
on the E38 in 1995 and has been in use on subseguent 5, 6 and 7 series models as
well as in X6 and both generations of the X5).

Safety functions are defined by the superior vehicle control characteristics. Effective
decoupling of the road and drive train guarantees outstanding levels of acoustic and
vibration comfort.

The Integral V rear axle has been specifically tuned to the specific reguirements
of the FOx/FIx vehicles like:

• Larger vehicle dimensions

• Greater total weight

• Greater drive output

• Higher drive torgue

• Runflat tires.

Design Features

The demanding objectives related to driving dynamics and comfort have been
correspondingly adapted while integrating the reguired driving dynamics systems.

The Integral V rear axle primarily fulfils the driving dynamics functions of the mechanical
chassis and suspension, i.e. define elastokinematic wheel control in all relevant driving
situations.

The innovative BMW development of the Integral Active Steering (IAL), however, makes
specific demands in terms of the elastokinematics of the integral-V rear axle: To a
certain extent, the wheels on the rear axle must be able to execute steering movements.

Kinematics and Elastokinematics

The spatial arrangement of the pivot points or pivot axes of the arms and links is known
as kinematics. This term applies to components that are assumed to be non-deformable.

Elastokinematics takes into account the flexibility at least of the rubber-metal mounts,
often of the ball joints and rarely of the components.

Various arms define the horizontal plane of the rear axle wheel suspension at the axle
carrier and the wheel carrier. These arms are mounted such that they can rotate about
an approximately horizontal axis of rotation and therefore allow vertical movement of
the wheel carrier.

63

BMW Suspension Systems

Kinematics is primarily of significance in terms of vehicle handling. The kinematics is
arranged in such a way that defined camber and toe-in angles are achieved between
the wheel and road surface in response to the suspension and steering.

Kinematics is superimposed by elastokinematic effects. These elastokinematic effects
occur as the movement points and movement axles are spatially displaced by the effect
of the forces at the wheel.

New Challenge for the Integral Rear Axle - Integral Active Steering

In terms of the F01/F02, the development of integral active steering (IAL) as a BMW
driving dynamics innovation, posed a completely new challenge to the engineers and the
tried and tested integral IV rear axle. The integral active steering is made up of the active
steering and the rear axle slip angle control (HSR).

Components of the Integral V Rear Axle with Integral Active Steering

Index

Explanation

Index

Explanation

1

Actuator, rear axle slip angle control (HSR)

6

Integral link

2

Track rod, left

7

A-arm (swinging arm)

3

Transverse control arm, top

8

Thrust strut

4

Wheel carrier

9

Rear axle carrier

5

Wheel bearing

64

BMW Suspension Systems

The principle of the Integral V rear axle makes it possible to resolve the conflict between
driving dynamics and comfort. The dynamic and drive forces applied through the wheel
contact point into the wheel suspension are taken up by the wheel carrier, rear axle
carrier, three links and an A-arm (swinging arm).

Integral V Rear Axle without Integral Active Steering

Index

Explanation

Index

Explanation

1

Track rod, right

3

Track rod, left

2

Bearing assemblies, track rod

The design layout reduces the flexible pulling action in the wheel carrier and therefore
enables lengthways damping of the wheel control, which is important for rolling comfort,
by means of axially soft front link mounts on the rear axle carrier.

Thanks to the position of the spring on the wheel carrier, it is no longer necessary
to support the weight of the vehicle on the rubber mounts on the rear axle carrier.

This optimum spring position in conjunction with specific lengthways control guarantees
effective isolation of rolling and drive noise while significantly contributing to the refined
smooth and guiet vehicle running characteristics.

65

BMW Suspension Systems

The main criteria that governed the selection of materials included component weight,
production process (cold forming, casting properties, welding properties), strength and
deformation characteristics as well as corrosion resistance.

Two versions of the Integral V rear axle are available. Bearing assemblies are fitted
on the two track rods if the vehicle is not equipped with integral active steering.

The revolutionary further development of the Integral IV rear axle culminates in the BMW
patented Integral V rear axle. The new arrangement of the arms and links as well as the
use of ball joints facilitates a rear axle with steering capabilities.

Arm Arrangement, E65 integral IV Rear Axle

T

Index

Explanation

Index

Explanation

A

Top view (forward direction x)

5

Rubber mount

B

Bottom side view

6

Rubber mount

1

Angle joint

7

Rubber mount

2

Angle joint

8

Rubber mount

3

Rubber mount

9

Ball joint

4

Rubber mount

Viewing the arrangement of the arms and links in the Integral IV rear axle of the E65
(above) it is difficult to imagine that defined steering movement of the rear wheels
about the Z-Axis could be realized.

66

BMW Suspension Systems

Theoretically, i.e. kinematically, the design of the Integral IV rear axle could facilitate
steering capabilities, however a large actuator would’ve been required and it would’ve
required additional engineering design. Ultimately it would’ve also been decisively
heavier and more expensive, hence the Integral V rear axle.

Arm Arrangement, Integral V Rear Axle in the F01/F02

Index

Explanation

Index

Explanation

A

Top view (forward direction X-Axis)

5

Rubber mount

B

Bottom side view

6

Rubber mount

1

Ball joint

7

Rubber mount

2

Ball joint

8

Rubber mount

3

Rubber mount

9

Ball joint

4

Ball joint

67

BMW Suspension Systems

Summary of the design layout:

• The system consists of a wheel carrier that is controlled from below by
a torsionally rigid A-arm (swinging arm).

• At the bottom, the wheel carrier is connected directly by means of a first bearing
mount and indirectly by means of a second bearing mount, in connection with an
integral link arranged vertically with respect to the plane of the A-arm (swinging
arm), to the wheel carrier.

• The two rubber mounts on the inside of the vehicle are connected to the rear
axle carrier such that they are torsionally soft and can be displaced axially.

• The upper transverse control arm lies approximately in the vertical plane
of the drive shaft and therefore also at the center point of the wheel.

• The rear track rod arranged approximately at the center point of the wheel
is either mounted on the rear axle carrier or connected to the actuator of
the integral active steering.

The track and camber at the rear axle can still be adjusted by
means of two eccentric screws, however, a new procedure
must be observed!

68

BMW Suspension Systems

Suspension Options (Integral V)

The standard chassis and suspension system of the F01 features steel springs on
the front and rear axle. The standard chassis and suspension on F02 and F07 has
steel springs on the front axle with the single axle air suspension (EHC) fitted on the
rear axle. The F01/F02, is eguipped as standard with vertical dynamics control
featuring electronically.

F07 Rear Axle with Single Axle Air Suspension (EHC).

Index

Explanation

Index

Explanation

1

Thrust strut

8

Air spring

2

Shock absorber

9

Track link

3

Upper wishbone

10

Rear axle support mount

4

Integral link

11

Rear axle support

5

Wheel carrier

12

Rear axle slip angle control actuator

6

Wheel bearing

13

Air supply system (LVA)

7

Swinging arm

69

BMW Suspension Systems

Depending on the vehicle and optional equipment the following combinations
are available:

• Standard suspension with single axle air spring.

• Dynamic drive with steel springs and VDC dampers.

• Dynamic drive with 2 steel springs and single axle air spring and VDC dampers.

Beginning with the F10 however conventional spring struts on the front and rear axles
are installed as standard equipment with EDC/VDC dampers available as an option.
This configuration is also installed in the FI 2 and FI 3 6 Series models.

© © © ®

Index

Explanation

Index

Explanation

1

Thrust strut

7

Swinging arm

2

Spring strut

8

Air spring Track link

3

Upper wishbone

9

Rubber mount for rear axle

4

Integral link

10

Rear suspension subframe

5

Wheel carrier

11

HSR actuator

6

Wheel bearing

70

BMW Suspension Systems