A joint (10) with first and second joint components (12, 26; 19) are movably connected to one another. The first joint component (12, 26) has a spherical joint body (14, 28) and the second joint component (19) rotatably and pivotably holds the joint body (14, 28). A sensor device, for determining the position of the first and second joint components (12, 26; 19) relative to one another, is arranged on the joint (10). The sensor device has at least one sensor element (21, 31) which can be integrated in a housing (18) that is produced by an assembly overmolding process. The joint housing (18) forms the second joint component (19) in which the joint body (14, 28) is directly supported.

The invention relates to a sealing apparatus for sealing the ball joint of a kingpin comprising at least one holding ring and at least one seal ring, wherein the seal ring is provided at least partially within a groove of the holding ring, and wherein the groove is provided in a radially inwardly disposed region of the holding ring.

A vehicle support structure including: a main body portion (2) for axially supporting an axle rotatably; and a vehicle part attachment portion (3) extended from the main body portion. The vehicle part attachment portion has a first boss portion (4), a second boss portion (5), and a third boss portion (6) placed in a triangular form when viewed in a direction along the axle, a first connection portion (7) connecting the first boss portion with the third boss portion, and a second connection portion (8) connecting the second boss portion with the third boss portion, and is a cast of aluminum or an aluminum alloy. The first and second connection portions are tilted in such a manner that center portions in a longitudinal direction are reduced in thickness. A sprue mark is formed on a side portion of the third boss portion on an opposite main body portion side.

System (100) for checking the presence of thickness restrictions on at least one mechanical component (1), comprising at least one base (2) for fixing said mechanical component (1) coming from a production line (200) to a plurality of fixing points (L1, L2, L3), and measuring means (3) to measure the thickness of said mechanical component (1) next to at least one control point (P) of said mechanical component (1) to be checked, characterized in that said measuring means (3) comprise at least one mechanical robotic arm (30) adapted to be moved in the direction of said at least one control point (P), wherein said mechanical robotic arm comprises at least one ultrasonic probe (31) for the ultrasonic measurement of the thickness of said mechanical component (1) next to said at least one control point (P), said ultrasonic probe (31) being positionable in the proximity of said at least one control point (P) so that the ultrasonic wave emitted by said ultrasonic probe (31) travels along a direction (Q) substantially orthogonal to the plane (T) tangent to the surface (S) of said mechanical component (1) next to said at least one control point (P) to be checked.

A utility vehicle includes a rear suspension assembly which has a trailing arm generally extending longitudinally. Also, the rear suspension assembly includes an upper radius rod extending in a generally lateral direction relative to a centerline of the vehicle. Additionally, the rear suspension assembly includes a lower radius rod extending in a generally lateral direction relative to the centerline of the vehicle. The rear suspension assembly further includes a suspension member configured to control toe of the at least one rear ground-engaging member.

A vehicle including a chassis; a seat; a motor; an endless drive track; a suspension assembly supporting the endless drive track. The suspension assembly includes at least one slide rail and at least one suspension arm pivotally connected to the slide rail and the chassis, the arm including a top bar extending laterally and a shock absorber. A first support assembly connecting a first end portion to a first chassis side and a second support assembly connecting a second end portion to a second chassis side. Each support assembly includes a bracket connected to the chassis at a top portion of the bracket; and a connector disposed on an end portion of the top bar, the connector including an arm portion, the end portion extending through a connector passage, and a flange portion defining a slot therein, a bottom portion of the bracket being received in the slot.

A bushing includes a body that is cylindrical; a bore through the body; a channel extending along an inner face of the bore; and a groove on a substantially planar surface of the bushing and including a first end intersecting with an end of the channel and a second end extending radially from the bore.

An axle sleeve assembly includes a bushing with a first through hole, and an adjusting shaft jammed in the first through hole capably of being rotated by external force and having a second through hole whose central axis is parallel deviated from the central axis of the first through hole. A control arm device includes a control arm and two aforementioned axle sleeve assemblies. The control arm includes a front end portion for being installed with a joint, and two rear end portions each having an installation hole. The installation holes are coaxial with each other, and the bushings are disposed therein in a tight fit manner respectively. The axle sleeve assembly and the control arm device are applicable to an upper control arm of a double A-arm suspension system for adjusting the camber angle of a wheel, and have high structural strength.

A rod-end front suspension is provided for an off-road vehicle. The rod-end front suspension comprises a spindle assembly that is pivotally coupled with an upper suspension arm by way of a first rod-end joint and pivotally coupled with a lower suspension arm by way of a second rod-end joint. A steering rod-end joint coupled with the spindle assembly pivotally receives a steering rod. An axle assembly coupled with the spindle assembly conducts torque from a transaxle to a wheel coupled with the spindle assembly. Each of the first and second rod-end joints comprises a ball rotatably retained within a casing. The ball is fastened within a recess between parallel prongs extending from the spindle assembly. A threaded shank extending from the casing is threadably fixated with the suspension arm, such that the spindle assembly may be moved with respect to the casing and the suspension arm.

A fixing system for a rocker arm of a vehicle suspension has a threaded rod having a first thread, a second thread and a locking cavity. The fixing system has a first cam, integral for rotation with the threaded rod by shape-fitting coupling, a second cam integral for rotation with the threaded rod by shape-fitting coupling, a first nut, screwed onto the first thread to lock position of the first cam, and a second nut, screwed onto the second thread to lock position of the second cam and having a locking portion having a circumferential groove and a positioning hole passing through the circumferential groove. An elastic clip shaped as an open ring is accommodated in the circumferential groove for retaining a pin in the positioning hole. In a screwed position of the second nut, the pin fits into the locking cavity and locks the position of the second nut.