A wheel suspension includes an axle limb which supports a wheel. The axle limb includes a first steering axle which provides a first steering angle in a specified range for the wheel, and components for connecting the axle limb to a support structure. At least one of the components includes a second steering axle which provides a second steering angle which is different than the first steering angle provided by the first steering axle. The second steering axle is selectively releasable. The components for connecting the axle limb to the support structure form a double transverse link axle which includes an upper traverse link and a lower traverse link. A support tube is arranged at a chassis-side end portion of each of the upper traverse link and the lower traverse link of the double transverse link axle. The support tube is pivotable about the second steering axle.

A relative guide device (1) for a steering arrangement (31) is arranged on the wheel-carrier side for the spatial guidance and maintenance of the relative spatial orientation of the steering arrangement (31) with respect to a vehicle body (40). At least one telescopic movement apparatus (2) for movably connecting the steering arrangement (31) is arranged on the wheel-carrier side to the vehicle body (40). A steering force transmission device (30) transmits a steering force to a wheel (R) of a vehicle having a relative guide device (1), and to a wheel suspension (50) for a vehicle.

The present invention provides an independent rear suspension system for low-floor bus for reducing the distance between the floor and ground, offering easy access for passengers and offering a wide space between the wheel arches.

An independent suspension for vehicles, in particular for heavy vehicles, includes a steering knuckle developing between an outer portion, defining the axis of rotation of a wheel hub, and an inner portion, having a receiving seat extending transversely to the outer portion along a steering axis and a knuckle-carrier assembly rotatably coupled to the inner portion of the knuckle to allow a relative rotation around the steering axis, and including at least a first and a second supporting portion defining each a substantially horizontal hinge point for one end of a respective cross arm. The knuckle-carrier assembly includes a first and a second body, separate to each other, in which the first body includes a steering pin developing along the steering axis and the first supporting portion, and the second body is partially fitted around the steering pin and includes the second supporting portion.

A front suspension lift kit for a golf cart includes first and second beams mountable to a frame of the golf cart. A first strut is mountable to the frame of the golf cart and a distal end portion of the first beam such that the first strut extends between the frame of the golf cart and the first beam. A second strut is mountable to the frame of the golf cart and a distal portion of the second beam such that the second strut extends between the frame of the golf cart and the second beam. A support bracket is mountable to the first and second beams at the distal end portions of the first and second beams. The lift kit also includes a swing arm, a spindle bracket, and a coil-over shock.

A suspension for a wheel of an axle of a motor vehicle, comprising a wheel support, which is mounted on the vehicle body via a plurality of links and which has a first supporting element and a second supporting element. A vehicle wheel is mounted rotatably on the first supporting element and the first supporting element is rotatable relative to the second supporting element for transmitting a steering torque by a steering actuator arranged on the wheel support. The first supporting element is attached to the vehicle body by an upper wishbone, and the second supporting element is attached to the vehicle body exclusively by a lower wishbone.

A RevoKnuckle-type suspension for a wheeled vehicle has a hub mounted to a bearing carrier for rotation relative thereto about a steering axis, and a shock absorber connected non-rotatably to the bearing carrier. The shock absorber has an outer cylinder having an axially-extending guide hole defined therein, and a piston and attached piston rod retained for axial reciprocation in the guide hole. The guide hole and at least one of the piston and the piston rod retained therein have respective complementary-shaped, non-circular cross-sectional shapes which engage one another to resist axial rotation of the piston and/or the piston rod within the guide hole. The carrier is therefore restrained against rotation relative to the vehicle sprung structure without the need for any additional component(s) such as a control arm or stabilizer, as required in a traditional RevoKnuckle-type suspension.

A wheel carrier for a vehicle suspension, intended for the rotatable mounting of a wheel, having a wheel carrier body made of metal is adapted to provide a stable, weight-optimized wheel suspension. The wheel carrier includes a wheel-attachment section and an extension projecting upwardly therefrom with means at its upper end for attaching an inboard-projecting control arm. A portion of the extension is offset inboard relative to the upper end and includes a hybrid section in which the wheel carrier body is reinforced in sections by a reinforcing element made of a fiber composite material.

A wheel suspension includes an axle limb which supports a wheel. The axle limb includes a first steering axle which provides a first steering angle in a specified range for the wheel, and components for connecting the axle limb to a support structure. At least one of the components includes a second steering axle which provides a second steering angle which is different than the first steering angle provided by the first steering axle. The second steering axle is selectively releasable. The components for connecting the axle limb to the support structure form a double transverse link axle which includes an upper traverse link and a lower traverse link. A support tube is arranged at a chassis-side end portion of each of the upper traverse link and the lower traverse link of the double transverse link axle. The support tube is pivotable about the second steering axle.

The present invention provides an independent rear suspension system for low-floor bus for reducing the distance between the floor and ground, offering easy access for passengers and offering a wide space between the wheel arches.