An all-terrain vehicle includes a frame, a transmission, an axle support, a driving shaft and a rear suspension assembly. The transmission is mounted on the frame. The driving shaft is coupled between the transmission and the axle support. The rear suspension assembly includes left and right rear suspension subassemblies symmetrically arranged at left and right sides of the frame. Each of the left and right rear suspension subassemblies includes an upper control min and a lower control arm, the upper control arm has a first end pivotally coupled to the frame and a second end pivotally coupled to the axle support, the lower control arm has a first end pivotally coupled to the frame and a second end pivotally coupled to the axle support, and a junction of the first end of the upper control arm and the frame is located behind the driving shaft.

A connecting arrangement for a stabilizer of a vehicle, with at least one lever that extends transversely to a longitudinal direction. The lever has a bearing eye provided with a non-circular inner circumferential contour. A torsion-bar spring with a rotation axis extends in the longitudinal direction. The torsion-bar spring has an outer circumferential contour, at least at one end, that matches the inner circumferential contour of the bearing eye and which fits into the bearing eye. The wall of the bearing eye is cut through by at least one slit extending in the longitudinal direction, by which two opposite wall sections of the wall are separated from one another. The two wall sections are pressed against the non-circular outer circumferential contour of the torsion-bar spring by at least one releasable clamping element.

A chassis link for a motor vehicle having load introduction elements connected by a straight profile portion of fiber-reinforced plastic. The profile portion and load introduction elements are connected via an adhesive connection in a common connection portion in which an end portion of the load introduction element and an end portion engage another in positive engagement. On both sides of a profile portion neutral fiber plane, the adhesive connection has longitudinal adhesive layers extending in a longitudinal direction of the profile portion and parallel to one another in a vertical. In vertical direction of the profile portion the longitudinal adhesive layers have a cross-sectional area becoming larger with increasing distance from the neutral fiber plane so that a relief is brought about in regions of the adhesive connection which have a relatively large distance from the neutral fiber plane in vertical direction of the profile portion.

A ball joint relocation kit including a ball stud having a ball end, a threaded end, and a shaft with a straight outer diameter, and a sleeve having a tapered outer diameter and a straight inner diameter, wherein the sleeve is adapted to be received in a tapered hole through a steering knuckle from a bottom side, and the ball stud is adapted to be received through the tapered hole and the sleeve from the top side. The ball joint relocation kit can be used to replace an OEM ball stud to relocate the ball joint from below the steering knuckle to above the steering knuckle in suspension lifted vehicles.

A wheel suspension (1) for a wheel (23) of a vehicle, in particular the rear wheel of a utility vehicle, driven by an electric or pneumatic motor (2), having a swing arm (3) which is mounted pivotably around a pivot axis (7) on the vehicle in a first region (4) and is supported on the vehicle in a second region (8), wherein a third region (10) of the swing arm (3) carries a part of the motor (2) which is rotationally fixed in relation to the swing arm (3) in order to transmit a torque to the wheel using a rotating part of the motor (2).

The support link arm according to the invention has an elongate link arm member. A ball joint socket is disposed on a first longitudinal and of the link arm member. The link arm member in a sheet-metal shell construction mode is formed from sheet metal and has a cavity portion. The ball joint socket is a forging or casting from metal and possesses a fastening appendage which is configured in a materially integral manner so as to be in one piece with said ball joint socket. The ball joint socket by way of the fastening appendage engages in the cavity portion of the link arm member and is joined to the link arm member.

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 link rod for a motor vehicle, with a connecting rod (4) designed with an open profile that extends in an axial direction (x), which comprises a back (8) and two opposed sidepieces (9, 10) which are connected to one another by the back (8), extending away from the back so as to enclose an angle (a) of less than 180° between them. Two joints (2, 3) are connected to one another by the connecting rod (4), each joint comprises a joint housing (5) and an inner joint component (6) that is fitted and able to move in the housing and extends outwardly therefrom. The connecting rod (4) is embedded, at its respective axial ends, in one of the joint housings (5), and the sidepieces (9, 10) enclose an angle (α) of at least 90° between them.

The improved dust boot includes a dust boot body which is made as one integral piece of an elastomeric material and extends from a first end portion to a second end portion. The second end portion of the dust boot body includes a first sealing portion and a second sealing portion which is spaced from the first sealing portion. The first sealing portion includes a plurality of ribs that are spaced circumferentially from one another by a plurality of grooves and includes a plurality of relief valves that are located in the grooves and extend away from the first end portion for allowing a lubricant to pass the first sealing portion in one direction and for restricting the passage of contaminants past the sealing portion in an opposite direction.

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.