A suspension arrangement for passenger car, an SUV or light truck is provided. The suspension arrangement includes a frame for said vehicle and an axle with rotatably mounted wheels. A leaf spring is provided connected with the frame and connected with the axle. The leaf spring has a contribution to the total axle ride frequency less than 80% of the total axle ride frequency. An air spring acting in parallel with the leaf spring is also provided.

An axle unit, includes a control arm and a clamping unit that surround a tube region, wherein a first side of the control arm faces away from the tube region, and a second side of the control arm forms a boundary face on the control-arm side of the tube region, wherein the clamping unit can be brought into supporting abutment with the first side of the control arm and has a boundary face on the clamp side, which face defines the tube region, wherein the clamping unit has a first and second clamping parts each having a wedge portion, wherein the wedge portions are formed in such a way that a displacement of the clamping parts substantially in parallel with a clamping axis toward one another results in a narrowing of the tube region transversely to the clamping axis.

A clamp group for a vehicle leaf spring suspension is disclosed. The clamp group secures a longitudinally disposed, leaf spring at separate and distinct locations, between which the leaf spring is undamped and spaced away from the top and bottom pads of the clamp group. Shear stress is reduced and the spring remains active throughout its length.

A suspension arrangement for passenger car, an SUV or light truck is provided. The suspension arrangement includes a frame for said vehicle and an axle with rotatably mounted wheels. A leaf spring is provided connected with the frame and connected with the axle. The leaf spring has a contribution to the total axle ride frequency less than 80% of the total axle ride frequency. An air spring acting in parallel with the leaf spring is also provided.

A combined spring compensation suspension device for a vehicle includes a free spring, a compensation spring, a compensation spring pre-tightening device, a vibration isolation block, a light damping shock absorber and a guide mechanism. The compensation spring pre-tightening device is installed at an upper end of the compensation spring. The guide mechanism is used to connect a wheel with a vehicle body. An elastic element on the suspension device of the vehicle is composed of the free spring and the compensation spring. A suspension load has a compensation interval nearby a static deflection stroke of a suspension. When the suspension load is changed in the compensation interval, the stroke is not changed or is slightly changed. Only when the suspension load exceeds the compensation interval, the suspension stroke can be changed. Controllability and comfort of the vehicle adopting the design can be simultaneously improved.

Energy storing suspension components having an end configured to include an eye are disclosed in combinations with bushings for use in suspension systems for wheeled vehicles and trailers. The energy storing suspension components include an axle seat portion, an end, and a limb extending between the axle seat portion and the end. The limb includes a first taper wherein the limb decreases in width as the limb extends toward the end, a second taper wherein the limb decreases in thickness as the limb extends toward the end, wherein along the limb there is at least a portion where both the first taper and second taper are present, and a third taper that is further from the axle seat portion than the first taper and wherein the limb increases in width as the limb extends toward the end.

Energy storing suspension components having an end configured to include an eye are disclosed in combinations with bushings for use in suspension systems for wheeled vehicles and trailers. The energy storing suspension components include an axle seat portion, an end, and a limb extending between the axle seat portion and the end. The limb includes a first taper wherein the limb decreases in width as the limb extends toward the end, a second taper wherein the limb decreases in thickness as the limb extends toward the end, wherein along the limb there is at least a portion where both the first taper and second taper are present, and a third taper that is further from the axle seat portion than the first taper and wherein the limb increases in width as the limb extends toward the end.

Energy storing suspension components for use in suspension systems for wheeled vehicles and trailers are disclosed. The energy storing suspension components include an axle seat portion, an end, and a limb extending between the axle seat portion and the end. The limb includes a first taper wherein the limb decreases in width as the limb extends toward the end, a second taper wherein the limb decreases in thickness as the limb extends toward the end, wherein along the limb there is at least a portion where both the first taper and second taper are present, and a third taper that is further from the axle seat portion than the first taper and wherein the limb increases in width as the limb extends toward the end. Also disclosed are combinations of bushings and energy storing suspension components having an end configured to include an eye.

A vehicle includes a chassis having a frame member, and a suspension system carried by the chassis. One or more air spring assemblies are associated with the suspension system, with each air spring assembly having an air bag, an air line and an air valve. An inflation valve bracket includes a channel and a flange depending from the channel. The channel is at least partially wrapped around the frame member. The flange has one or more openings with a corresponding air valve in each opening.

A lift axle suspension system incorporating a lift paddle is disclosed. The lift paddle comprising a first pad, a second pad and a rigid support arm securing the first pad and the second pad in fixed relation to one another. The first pad is attached to a lift spring, the second pad is secured to the bottom surface of the main support member/leaf spring. Actuation of the lift spring causes the axle to be lifted out of contact with the ground surface.