A link and ball socket assembly for a vehicle position sensor comprising a first molded member including a link and a first socket and a second molded member including a second socket coupled to the first molded member. The first socket is molded to and integral with a first end of the link and the second socket is coupled to and rotatable relative to a second opposed end of the link. The first socket defines an interior ball receiving pocket. The interior pocket defines a first back pocket portion which opens into a second front ball shaped pocket portion. The ball is received in the first back pocket portion and slid and snapped into the second front pocket portion. A locking pin is inserted into the interior pocket into a relationship abutting against the ball for retaining the ball in the socket.

A compliant mechanism is provided for monitoring the position of a suspension of a vehicle. The compliant mechanism can include a body for coupling to both an angle sensor and the suspension of the vehicle. The body can have at least two first portions and at least one second portion. The second portion is coupled to both of the two first portions and is more flexible than the two first portions.

An air suspension system of a commercial vehicle comprises an electronic control device with a level control valve device. A valve element is coupled to a drive element mechanically coupled to a vehicle wheel or axle. In a first relative position of the valve element and a counter valve element, a port for an air suspension bellow is blocked. In a second relative position, the port for the air suspension bellow is connected to a port for an aeration device. In a third relative position, the port for the air suspension bellow is connected to a port for a deaeration device. Control logic generates a control signal for an actuator which, when a level change is set by an operator, correspondingly changes the relative position of the valve element and the counter valve element or the relative position of the counter valve element and a valve housing.

An elastic support for on-board suspension systems of a motor-vehicle includes at least one body formed of polymeric elastomeric material supplemented with carbon-based nanofillers. An outer surface is provided with one or more piezo-resistive areas where a polymeric material supplemented with carbon-based nanofillers has been made locally piezo-resistive by laser irradiation so as to define one or more electric deformation sensors configured to detect the load applied on the elastic support.

Methods and apparatus to calibrate height sensors of a vehicle suspension are described herein. An example method includes measuring a first voltage output of a height sensor coupled to a control arm of a suspension when the control arm is at a first position, associating the first voltage output to the first position of the control arm, measuring a second voltage output of the height sensor when the control arm is at a second position, associating the second voltage output to the second position of the control arm, measuring a third voltage output of the height sensor when the control arm is in a third position, and associating the third voltage output to the third position of the control arm.

A height control linkage for a vehicle cab suspension comprising upper and lower linkage members which are adjustably joined by a barrel assembly including first and second barrel members which are selectively joined together. The upper linkage member includes a laterally facing socket and a shaft portion which extends therefrom with the shaft portion having a plurality of alternating and spaced-apart annular grooves and ridges which are rotatably secured to the upper ends of the barrel members. The lower linkage member includes a laterally facing socket and a threaded shaft extending upwardly therefrom which is adjustably threadably secured to the lower ends of the barrel members. The length of the height control linkage may be changed by threadably rotating the barrel assembly with respect to the lower linkage member.

A steering system includes an arm, a knuckle, a joint, and a steering sensor. The arm defines a first passage. The knuckle has a knuckle arm defining a second passage. The joint has a ball portion and a shaft portion extending. The ball portion is disposed within the first passage and the shaft portion is disposed within the second passage. The ball portion defines a conical recess that has an opening at an upper end of the ball portion and terminates inside the ball portion with a pocket. The steering sensor has a driveshaft extending along a longitudinal axis into the conical recess. The driveshaft includes a head that engages with the pocket. The ball portion is configured to pivot within the first passage relative to the longitudinal axis and the head. The joint and the driveshaft are configured to rotate together about the longitudinal axis as the knuckle is turned.

A central joint device for chassis components (2), particularly three-point link, is suggested. The central joint device comprises at least one housing unit (3), at least one joint pin unit (4) which is movably supported at least partially inside of the housing unit (3), and at least one sensor unit (5), particularly a magnetic sensor unit, which is provided for contactless detection of roll motions and pitch motions of the housing unit (3) and of the joint pin unit (4) relative to one another. The sensor unit (5) comprises at least one encoder element (6) and at least one sensor element (7). The encoder element (6) and the sensor element (7) are arranged to be spaced apart from one another and movable relative to one another.

A ball joint having a ball pin and a housing. The ball pin together with the ball is accommodated in the housing to move in a rotational and pivotal manner. The ball is at least partially surrounded by a structural component. The structural component is essentially formed from a fiber-plastic composite structure and at least partially forms the housing.

A rolling vehicle includes a pair of left and right front wheels and a pair of left and right arm members swingably supported by the vehicle body on inner sides in the transverse direction and which support the left and right front wheels in a steerable manner on outer sides in the transverse direction. As viewed from the direction along the axis of a support shaft which supports the left and right arm members on the vehicle body, the base portions of the left and right arm members rotatably supported on the vehicle body side overlap with each other, whereas the swinging center axis of the base portion of the left arm and the swinging center axis of the base portion of the right arm, of the base portions of the left and right arm members, are out of alignment with each other.