A wheel suspension arrangement is provided for a vehicle having a longitudinal direction, a transverse direction and a vertical direction. The wheel suspension arrangement includes a wheel holder for supporting a vehicle wheel. A first vertical end region of the wheel holder is pivotally attached to a vehicle support structure by a rigid control arm and a second vertical end region of the wheel holder is attached to the vehicle support structure by a leaf spring. A longitudinal direction of the leaf spring is arranged substantially in the transverse direction of the vehicle. The leaf spring is pivotally attached to the vehicle support structure at a transverse centre region of the vehicle, and a centre of the leaf spring in the transverse direction is located vertically offset from a pivotal attachment location of the leaf spring. The pivotal attachment location of the leaf spring is vertically offset towards the side of the rigid control arm.

A method of mounting to an A-arm suspension system a wheel spindle configured for use with a multi-link suspension system may involve the steps of: Removing at least one suspension link mount on the wheel spindle; mounting a ball joint bracket to the wheel spindle, the ball joint bracket being configured to mount to the A-arm suspension system, the removing and mounting steps producing a modified wheel spindle; and mounting the modified wheel spindle to the A-arm suspension system.

A wheel suspension for a motor vehicle including a wheel carrier supporting a wheel. The wheel carrier connected via at least one upper camber link, a lower control arm, and a lateral toe link to the vehicle body or subframe. A stabilizer rod connects to the wheel carrier. The wheel suspension including a damper unit and a spring unit wherein the stabilizer rod and the damper unit connect to the wheel carrier at a common connecting point.

A pivot bearing for independent wheel suspension of a steerable front wheel of a vehicle having at least one upper bearing with a connection to a spring strut for attachment to the body. To improve the safety of the passenger cell in the event of a frontal collision, the connection has a separating device that brings about separation of the attachment of the pivot bearing to the spring strut and to the body of the vehicle at the upper bearing in the event of a frontal impact.

The invention relates to a single-shell spring control arm formed of sheet metal for a wheel suspension of a motor vehicle, with upwardly directed side limbs connected to one another by a base, with a first end section for connection to a chassis girder, with a second end section for wheel-side connection, with a spring receiving section, which is located between the two end sections and has a spring support surface formed on the base, and with a damper receiving section formed between the spring receiving section and the second end section for connecting a shock absorber. In order to achieve at relatively low component weight and favorable manufacturing costs improved stiffness with respect to high axle loads, the invention provides that a U-shaped constriction is formed between the spring support surface and the damper receiving section, which constriction extends in the base and in the side limbs.

A bushing for a wheel suspension adapted to connect a control bar to a structure of a vehicle, where the bushing comprises a first rotational center for the control bar having a first angular rotation range, where the bushing comprises a second rotational center for rotational angles outside of the first angular rotation range.

A locator (150) for positioning a male element (144) relative to a female element (142) in a joint (132), the male element (144) having a smaller footprint than the female element (142) and the locator (150) comprising an aperture (156) for receiving the male element (144), the aperture (156) having a smaller footprint than the female element (142) and locating means (164) for positioning the locator (150) relative to the female element (142) of the joint (132) such that the aperture (156) of the locator (150) selectively exposes only a part of the female element (142) to ensure location of the male element (144) within the female element (142) in a desired position. The locator (150) further comprises attachment means for attaching the locator (150) to the joint (132), wherein the attachment means is configured to detach on application of a threshold force. The invention therefore provides a simple means of reliably positioning a male element (144) in a desired position relative to a female element (142) in a joint during an initial installation stage without the need to visualise the joint (132). The invention is particularly applicable to a joint (132) in a vehicle suspension system between a frame (132) and a bolt (145) that supports a control arm (16).

A utility vehicle with ergonomic, safety, and maintenance features is disclosed. A vehicle is also disclosed with improved cooling, suspension and drive systems. These features enhance the utility of the vehicle.

An apparatus and a method are provided for a camber adjustment assembly, comprising: first and second end plates coupled to a substantially planar center portion, wherein the first and second end plates comprise a generally triangular configuration; a chassis element coupled to a trailing arm and the camber adjustment assembly, and wherein a force may be applied to the camber adjustment assembly so as to desirably induce a positive or negative camber condition.

A suspension arm has an elongated shape. The suspension arm is shaped such that a line defining an outer shape of the suspension arm does not coincide with a line of force transmission, but a line extending through a shearing center point of each of a plurality of cross sections of the suspension arm coincides with the line of force transmission.