A wheel axle suspension of a vehicle, comprises an axle body having a rectangular cross section, a flexible trailing arm extending in a longitudinal direction of the vehicle and crossing the axle body substantially perpendicular, and at least one clamping strap assembly for clamping the axle body and the trailing arm together. The trailing arm has a front spring portion extending in the longitudinal direction of the vehicle and is provided with an axle seating portion adjoining the front spring portion at a rear end thereof. The axle seating portion comprises a longitudinal portion extending substantially in line with the front spring portion, and a downwardly extending portion extending substantially perpendicular to the longitudinal portion. The axle body is received in the axle seating portion with the upper side and rear side facing the longitudinal portion and the downwardly extending portion respectively. The axle seating portion of the trailing arm has an axle body facing surface having three engagement areas engaging the axle body respectively at the front upper corner, the rear upper corner and at a region at or adjacent the lower rear corner of the axle body. Between said engagement areas there is a clearance between the axle body facing surface of the axle seating portion and the upper side and rear side of the axle body.

A wheel axle suspension of a vehicle, comprises an axle body having a rectangular cross section, a flexible trailing arm extending in a longitudinal direction of the vehicle and crossing the axle body substantially perpendicular, and at least one clamping strap assembly for clamping the axle body and the trailing arm together. The trailing arm has a front spring portion extending in the longitudinal direction of the vehicle and is provided with an axle seating portion adjoining the front spring portion at a rear end thereof. The axle seating portion comprises a longitudinal portion extending substantially in line with the front spring portion, and a downwardly extending portion extending substantially perpendicular to the longitudinal portion. The axle body is received in the axle seating portion with the upper side and rear side facing the longitudinal portion and the downwardly extending portion respectively. The axle seating portion of the trailing arm has an axle body facing surface having three engagement areas engaging the axle body respectively at the front upper corner, the rear upper corner and at a region at or adjacent the lower rear corner of the axle body. Between said engagement areas there is a clearance between the axle body facing surface of the axle seating portion and the upper side and rear side of the axle body.

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 chassis arrangement (10), in particular for utility vehicles (1), with at least one axle (3) that extends transverse to the travel direction and carries wheels (4). Movement of the axle (3) is damped by vibration dampers (11) provided with end sections (15), and with at least one stabilizer assembly (12) that has two longitudinally extending sections (13) and a transverse section (14) that connects the longitudinally extending sections. An end section (15) of the vibration damper (11) is held directly on and is connected to the stabilizer assembly (12) on an extension (16, 17) of the transversely orientated section (14) beyond the longitudinal section (13).

A chassis arrangement (10), in particular for utility vehicles (1), with at least one axle (3) that extends transverse to the travel direction and carries wheels (4). Movement of the axle (3) is damped by vibration dampers (11) provided with end sections (15), and with at least one stabilizer assembly (12) that has two longitudinally extending sections (13) and a transverse section (14) that connects the longitudinally extending sections. An end section (15) of the vibration damper (11) is held directly on and is connected to the stabilizer assembly (12) on an extension (16, 17) of the transversely orientated section (14) beyond the longitudinal section (13).

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.

A vehicle electric axle has at least one electric motor and a suspension system including a longitudinal element which is a reaction rod or a leaf spring. The longitudinal element is rotatably mounted at one end around a reaction rod bracket and at the other end around a dampening member. The at least one electric motor includes a power supply routing device to be connected to an electrical power source. The power supply routing device has at least one busbar, a straight portion of which extending longitudinally along the longitudinal element. The at least one busbar includes two curved portions forming two cavities each receiving at least part of a longitudinal end of the longitudinal element.

A vehicle electric axle has at least one electric motor and a suspension system including a longitudinal element which is a reaction rod or a leaf spring. The longitudinal element is rotatably mounted at one end around a reaction rod bracket and at the other end around a dampening member. The at least one electric motor includes a power supply routing device to be connected to an electrical power source. The power supply routing device has at least one busbar, a straight portion of which extending longitudinally along the longitudinal element. The at least one busbar includes two curved portions forming two cavities each receiving at least part of a longitudinal end of the longitudinal element.