A wheel suspension (1) for a motor vehicle, having a wheel carrier (3) which is mounted so that the wheel carrier (3) can pivot relative to a wheel-guiding control arm (4) that includes a longitudinal control arm section (4a), with a forward body-side bearing (11), and a transverse control arm section (4b), with a rear body-side bearing (12). The rear body-side bearing (12) is axially orientated parallel to a rotational axis (20) of the wheel-guiding control arm (4) that extends through the body-side bearings (11, 12).

A suspension linkage for a motor vehicle includes an extruded body having a first wall and a longitudinal length. An extruded feature is disposed on the first wall of the extruded body and extends along the longitudinal length. The extruded feature has a cross-sectional profile configured to control a flexural rigidity of the suspension linkage.

A wheel suspension for a motor vehicle, including a wheel carrier (2) for holding a wheel (3), a wheel-guiding control arm (4) for articulating the wheel carrier (2) to a structure, and steering member (23) for steering the wheel (3). For steering the wheel (3), the wheel carrier (2) and the wheel-guiding control arm (4) are articulated to one another in such manner that the wheel carrier (2) can pivot relative to the wheel-guiding control arm (4) about a steering axis. The wheel carrier (2) is connected indirectly to the control arm (4) in a first connection zone (20) by an integral link (5).

A wheel suspension for a vehicle, comprising: at least one wheel guiding element which connects a steering knuckle to a vehicle bodywork, and a spring-based and/or vibration-based damping element functioning like a shock-absorber strut or a suspension strut or a spiral spring, wherein the spring-based and/or vibration-based damping element is connected to the steering knuckle, wherein the wheel guiding element has a through-opening in the vehicle vertical direction, and wherein the spring-based and/or vibration-based damping element is located such that it protrudes through the through-opening.

A motor-vehicle wheel suspension includes a lower oscillating arm, a damper unit, an upper oscillating rod and a vertical articulated rod. The suspension includes a toe control oscillating rod having an inner end pivotally connected to a supporting structure and an outer end pivotally connected to a wheel support. An articulation of the outer end of the toe control rod to the wheel support and the upper end of the vertical rod includes an articulation axle connected to the vertical rod. An eccentric cylindrical member is rotatably mounted on the articulation axle within a cylindrical cavity in the support and has an axis eccentric relative to the articulation axle. The articulation axle is connected to an adjustment ring, whose rotation determines a variation in the position of the wheel support and a resulting variation of the wheel toe angle.

A wheel suspension for a motor vehicle with an auxiliary frame connected through auxiliary frame bearings with the vehicle body. A support spring is arranged between the vehicle body and a spring link at the auxiliary body, and exerts spring forces on the spring link and thus indirectly on the auxiliary frame. The support spring is arranged near the auxiliary bearings which act in the vehicle direction between the auxiliary frame and the vehicle body. Due to the proximity of the auxiliary bearings to the support spring, a part of the spring forces exerted by the support spring is directly guided through the support bearings into the vehicle body.

A suspension includes a knuckle to which a wheel of a vehicle is fastened, a steering drive portion connected to the knuckle, a lower arm positioned at a lower end portion of the steering drive portion and including a first end portion connected to the knuckle and a second end portion connected to a vehicle body frame, a connecting link including a first end portion connected to an upper end portion of the steering drive portion, an upper arm connected to a second end portion of the connecting link, a damper connecting the upper arm and the vehicle body frame, and a push rod including a first end portion connected to the upper arm and a second end portion connected to the lower arm.

A vehicle has a body, a flat component arranged under the body, and at least one axle carrier arrangement for two front or two rear wheel suspensions. The axle carrier arrangement includes a left-hand suspension arm bracket for connecting at least one suspension arm of the left-hand wheel suspension, a right-hand suspension arm bracket for connecting at least one suspension arm of the right-hand wheel suspension, and a center suspension arm bracket for connecting at least one suspension arm of the lefthand wheel suspension and at least one suspension arm of the right-hand wheel suspension. The three suspension arm brackets are each mounted on the body and the flat component, wherein the three suspension arm brackets are three separate components that are not directly connected, and wherein at least one of the suspension arm brackets has a bearing for an electric machine that drives the vehicle.

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.

The disclosure relates to the technical field of vehicles, and particularly provides a multi-link independent suspension for a vehicle that includes a subframe and a steering knuckle. In order to solve the problem of reduced adjustment efficiency caused by mutual restraining of linkages of an existing multi-link independent suspension when a camber angle is adjusted, the multi-link independent suspension includes a spring control arm that is configured to adjust a camber angle of a wheel center. The multi-link independent suspension also includes a front upper control arm and a rear upper control arm. A central axis of the front upper control arm intersects with a central axis of the rear upper control arm at a Q point, and the Q point has the same coordinate as the wheel center in an X direction; and a motion centerline between the front upper control arm and the rear upper control arm coincides with a projection of a central axis of the spring control arm on an XY plane, so that a movement of the spring control arm has no effect on an upper control arm system when the camber angle is being adjusted. The steering knuckle only rotates about an X axis so as to drive a tire to rotate about the X axis, so that a camber angle of the tire can be adjusted without changing a toe-in angle, thereby reducing the number of affected linkages and simplifying the adjustment in the camber angle of the tire.