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 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 suspension controller includes a target current setting unit, a current limitation setting unit, a current outputting unit, a current detector, and an estimated temperature calculator. The target current setting unit sets a target current value. The current limitation setting unit sets a current limitation value. The current outputting unit supplies a solenoid with a current that is based on the target current value, the current limitation value, and a power supply voltage. The solenoid controls a damping force of a suspension. The current detector detects a current value of the current supplied to the solenoid. The estimated temperature calculator calculates an estimated temperature of the solenoid based on the current value detected by the current detector so that the current limitation setting unit changes the current limitation value based on the estimated temperature.

A ball joint assembly for use in a vehicle suspension system includes a housing including a first end surface and an opposing second end surface. The housing at least one of includes an outer tie rod of a steering assembly and is configured to be coupled to the outer tie rod of the steering assembly. The housing defines a cavity and also includes an opening defined in the second end surface. The ball joint assembly also includes a ball stud coupled to the housing such that a first portion of the ball stud is positioned in the cavity and a second portion of the ball stud extends through the opening. A wire harness is coupled to the first end surface of the housing and extends away from the housing in a direction opposite the second end face surface.

A wheel suspension for a two-track vehicle having at least one stabilizer formed as a stabilizer torsion spring rod, with the stabilizer extending in the vehicle's transverse direction and having a drive lever on at least one vehicle side, which acts upon a wheel guidance element of the wheel suspension, and having at least one suspension spring, which is tensioned with a spring preload between the vehicle body and a wheel guidance element of the wheel suspension. The suspension spring is at least partially formed as a suspension spring/torsion spring rod. The suspension spring/torsion spring rod is arranged radially within the stabilizer torsion spring rod designed as a hollow rod.

A transverse leaf spring arrangement of a chassis axle of a motor vehicle having a transverse leaf spring which is mounted via two outer bearing members on, in each case, one wheel support and via two central bearing members on a vehicle body. The central bearing members have, in each case, one torque generation apparatus, the torque directions of which run parallel to a longitudinal axis of the motor vehicle. The torque generation apparatus capable of generating a torque which is variable at least in a manner which is dependent on a deflection at the outer bearing members.

A transverse leaf spring arrangement of a chassis axle of a motor vehicle having a transverse leaf spring which is mounted via two outer bearing members on, in each case, one wheel support and via two central bearing members on a vehicle body. The outer bearing members, in each case, have an actuator device, which actuator devices act on the respective outer bearing member in such a way that it can be adjusted at least in the direction of the vertical axis of the motor vehicle. The actuator devices are configured in such a way that a respective outer bearing point can be set in the direction of the transverse axis of the motor vehicle.

A vehicle height control system includes an arm including a first end portion connected to a vehicle body and a second end portion coupled to a wheel, a bearing unit fixed to the vehicle body, a crank coupled to the bearing unit, a push rod including a first end portion connected to the crank and a second end portion connected to the arm, and a spring reaction force variable device coupled to the bearing unit and configured to vary reaction force applied to the crank.

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 wheel suspension system (101) with at least one wheel support (103), first and second coupling rods (105, 107) and at least one track rod (109). The first and second coupling rods (105, 107) are connected to one another in an articulated manner. The second coupling rod (107) and the wheel support (103) are connected to one another in an articulated manner. The track rod (109) is designed to apply a steering torque to the first coupling rod (105). The steering torque is transmitted from the first coupling rod (105), via the second coupling rod (107), to the wheel support (103). The wheel suspension system has at least one suspension link (111) which is mounted, in an articulated manner, on a vehicle body or chassis and is articulated to the wheel support (103). The suspension link (111) and the first coupling rod (105) are articulated to one another.