A wheel steering system includes: a rear suspension mechanism inclusive of a knuckle member for rotatably holding a right rear wheel; a first cam and a second cam that are rotatably supported; a first cam follower 18 that follows the first cam; a second cam follower 20 that follows the second cam 16; cam grooves 48 respectively provided in the first and second cams; a first engaging pin and a second engaging pin that engage with the respective cam grooves; and a rotational driving force transmitter that transmits a rotational driving force of an electric motor to the first and second cams, wherein the first cam and the first cam follower are arranged on a front side in the vehicle front-rear direction of an axle, and the second cam and the second cam follower are arranged on a rear side in the vehicle front-rear direction of the axle.

A vehicle suspension assembly including a suspension control arm pivotally coupled to a vehicle frame member by a bushing assembly. The bushing assembly includes a bushing bracket, a bushing, and a cam adjustment mechanism that couples the bushing bracket to a connection interface of the vehicle frame member. The cam adjustment mechanism includes a cam plate rotatably retained on a first fastener such that the cam plate is rotatable relative to the bushing bracket independent of rotation of the first fastener. The cam plate is rotatable relative to the first fastener and the bushing bracket about an axis of rotation that is spaced from a centerline of the bushing at a nonparallel orientation. Rotation of the cam plate relative to the first fastener adjusts the position of the bushing bracket and therefore the bushing relative to the vehicle frame member to provide alignment adjustment.

An offset washer for adjusting the camber angle in a vehicle is disclosed. The offset washer includes a body having an upper surface and a lower surface, an aperture extending through the body, and a protrusion having a longitudinal width different than the body thickness. The protrusion is configured to be inserted into a receiving aperture on a flange of a vehicle suspension system. The protrusion is defined by a formed upset defining a step in the material along a portion of the edge of the aperture, which is formed by upsetting the portion of the edge of the aperture when forming the aperture.

Provided is a vehicular holding device that, in an ON state, holds a vehicle component in a state where displacement of the vehicle component in an axial direction is restrained, and that, in an OFF state, holds the vehicle component in a state where displacement of the vehicle component in the axial direction is possible. The vehicular holding device includes at least one engagement part, a cam mechanism, and an axial direction restraining part. The at least one engagement part is at a position where the engagement part engages with an engaged part in the ON state, and is at a position where the engagement part is separated from the engaged part in the OFF state. The cam mechanism displaces the at least one engagement part from the OFF-state position to the ON-state position. The axial direction restraining part receives axial-direction force acting on the at least one engagement part.

An elastomer coupling for an electromechanical actuator, having a drive part and a driven part, wherein either the drive part or the driven part has multiple radially outwardly extending webs arranged so as to be distributed about an axis of rotation, and the respective other part has radially inwardly extending webs arranged on the inner side of a tubular body, wherein a radially inwardly and a radially outwardly extending web engage into one another and form a pocket in which there is received an elastic molded body produced from an elastomer, wherein, in at least one pocket, there is received a spring element which generates a pretensioning force, which spring element is attached either to an inwardly extending or to an outwardly extending web and is spring-loaded against an adjacent web.

An inerter device for a wheel suspension of a vehicle, having an inerter mass and a mechanical inerter drive which is operatively connected to the inerter mass via a coupling device. The coupling device has a control disk connected to the inerter mass and a contour disk connected to the inerter drive. The control disk and contour disk are frictionally in contact with each other via coupling surfaces. The inerter mass is reversibly movable relative to the inerter drive from an operating position into a securing position. The control disk has a contact element which, during the movement of the inerter mass into the securing position, interacts with a mating contact element of the contour disk and therefore reversibly moves the control disk from a coupling position relative to the contour disk into a release position in which the coupling surfaces are separated.

A method for producing a mounting arrangement for a link of a motor vehicle suspension that is or can be pivotably mounted on a subframe of the motor vehicle, having the following steps: providing the subframe, which has a first and a second mounting flange for mounting the link; providing at least one intermediate product of a bracket; integrally joining the intermediate product to a mounting flange of the subframe by welding; forming an elongated hole in the intermediate product by punching of the same; and forming at least one stop on the intermediate product for an adjusting eccentric for chassis adjustment by stamping the intermediate product.

A ball joint assembly includes a ball stud, a cylindrical bearing, a housing and a retainer. The bearing has an upper end, a lower end, a exterior sidewall, an upper flange located between the upper end and a ring groove formed in the exterior sidewall, a lower flange proximate the lower end and extending outwardly and a socket cavity that opens toward the lower end. A ball portion of the ball stud is retained within the socket cavity. The bearing is secured within a bore within the housing by virtue of the working of the lower flange and the upper flange and retainer located in the ring groove. The ball joint assembly is able to resist a pull-out force of up to 1200 lbs. It may also be sealed by incorporation of a dust boot which extends between the housing and a stud portion of the ball stud.

A wheel steering system includes: a rear suspension mechanism inclusive of a knuckle member for rotatably holding a right rear wheel; a first cam and a second cam that are rotatably supported; a first cam follower 18 that follows the first cam; a second cam follower 20 that follows the second cam 16; cam grooves 48 respectively provided in the first and second cams; a first engaging pin and a second engaging pin that engage with the respective cam grooves; and a rotational driving force transmitter that transmits a rotational driving force of an electric motor to the first and second cams, wherein the first cam and the first cam follower are arranged on a front side in the vehicle front-rear direction of an axle, and the second cam and the second cam follower are arranged on a rear side in the vehicle front-rear direction of the axle.

A fastening arrangement of a vibration damper of a vehicle includes a rubber bearing with a first bush and a second bush, a fastener where via the fastener one of the first bush and the second bush of the rubber bearing is fixed in three degrees of longitudinal freedom with regard to a wheel support of the vehicle or the body of the vehicle, and a measure disposed on the second bush and on the wheel support or on the body of the vehicle where via the measure a degree of rotational freedom of the second bush about an axis of the fastener is blocked by a positively locking block. The positively locking block is formed by a convexly curved cylinder segment of the second bush and a concavely curved cylinder segment of the wheel support or the body of the vehicle that are engagable into one another.