The invention relates to a strut rod made of composite material for a suspension of a front axle of a vehicle, including: an upper part coupled to a rod and piston assembly connected to a vehicle body; and a U-shaped lower part including two brackets for fixing a knuckle arm of the vehicle. This strut rod includes means for detecting a crack. This detection means includes at least one additional edge positioned so as to project from an outer surface of the U-shaped lower part of the strut rod in a region where a crack possibly occurs in the case of an accidental shock on a wheel of the vehicle.

The control arm assembly includes a control arm body and a socket assembly for connecting the control arm body with a vehicle frame. The socket assembly includes a housing with an inner bore which extends along a vertical axis between opposite open ends. A stud extends past the open ends and has an axially extending through passage. The stud has a pair of end portions on opposite sides of a ball portion that has a curved outer surface which is in sliding contact with a bearing surface for allowing the control arm body to pivot relative to the stud and the vehicle frame. The through passage is eccentrically located in a radial direction on the stud for translating the control arm body relative to the vehicle frame in response to rotation of the stud relative to the housing to adjust a camber angle of the wheel assembly.

An apparatus for coupling a trailing arm may include a carrier having defining an open space on one side thereof, a trailing arm, one end of which includes an extension inclined at a predetermined angle and inserted into the space, and an assist arm, an end of which is inserted into the space and positioned on one side of the extension, in which the extension and the end of the assist arm inserted into the space may be integrally coupled to the carrier.

A method and apparatus for a camber adjustment system for a control arm of the subject matter of the present disclosure which allows the quick change of camber settings of a vehicle by utilizing a pill adjustment component containing several camber settings including a track and street setting.

A transverse link has an inboard side and an outboard side. A steering knuckle has an upper end, a wheel supporting section and a lower end. The lower end is pivotally coupled to the outboard side of the transverse link. A strut has an upper end and a lower end. An upper knuckle breakaway structure attaches the upper end of the steering knuckle to the lower end of the strut. The upper knuckle breakaway structure has a frangible part that releases the upper end of the steering knuckle from the lower end of the strut upon application of a prescribed rearward directed force. A transverse link breakaway structure couples the inboard side of the transverse link to a lower suspension support structure such that upon application of the prescribed rearward directed force the inboard side of the transverse link is released from the lower suspension support structure.

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.

A suspension structure includes a trailing arm that couples a hub support portion supporting a wheel hub to a vehicle body. The trailing arm includes a vehicle body side attachment portion attached to the vehicle body, and a hub side attachment portion attached to the hub support portion. The hub side attachment portion is positioned below a shortest virtual line connecting a center of the vehicle body side attachment portion and a rotation center of the wheel hub.

A vehicle suspension includes and axle. An upper control arm bracket is fixedly positioned relative to the axle and defines a first axis. An upper control arm is rotatably coupled to the upper control arm bracket about the first axis. A lower control arm bracket is fixedly positioned relative to the axle and defines a second axis. A lower control arm is rotatably coupled to the lower control arm bracket about the second axis. An upper control arm relocation bracket is configured to be mounted to the axle and includes a clevis defining a third axis and configured to rotatably couple the upper control arm about the third axis. The relocation bracket includes a first aperture coaxial with the first axis when the relocation bracket is mounted to the axle and a second aperture coaxial with the second axis when the relocation bracket is mounted to the axle.

Methods and systems are provided for an electric heavy-duty vehicle. In one example, a system for the vehicle may include a wheel hub assembly coupled to a frame of the vehicle via a first wishbone arm and a second wishbone arm, and an air spring coupled at opposite ends to a first link and a second link, each of the first link and the second link being pivotably coupled to the frame of the vehicle, the second link further being pivotably coupled to the first wishbone arm. The air spring may be positioned above the wheel hub assembly with respect to the vehicle.

The present invention concerns a wheel suspension 5 for a torsion beam axle 1, whereby a wheel mount 8 rotates about a virtual steering axle 18 as a result of a cornering force. According to the invention, it is further provided that a wheel mount bracket 6 with a yielding element 11 is coupled to the end 4 of a longitudinally extending swing arm 3 of the torsion beam axle 1, so that an additional steering in positive toe occurs as a result of a lateral force effect.