A drivable axle for a vehicle, in particular a rigid axle. The drivable axle has an axle body designed to accommodate an axle shaft and a receiving structure for receiving a vehicle element which is integrated into a drive-train of the vehicle. The receiving structure is connected to the axle body and is designed to receive a drive unit of the vehicle and has openings for connection to the axle shaft. The receiving structure has at least one fixing area for fixing the drive unit to the receiving structure.

A drivable axle for a vehicle, in particular a rigid axle. The drivable axle has an axle body designed to accommodate an axle shaft and a receiving structure for receiving a vehicle element which is integrated into a drive-train of the vehicle. The receiving structure is connected to the axle body and is designed to receive a drive unit of the vehicle and has openings for connection to the axle shaft. The receiving structure has at least one fixing area for fixing the drive unit to the receiving structure.

A driving device for an electric truck which can obtain good ride quality by decreasing the unsprung weight while achieving the adequate fuel efficiency performance by improving the power transmission efficiency and which can improve the mountability of a battery. The driving device includes a driving unit that accommodates therein a motor, a gearbox, and a differential device. The driving unit is supported by a first support part with respect to a ladder frame. Drive shafts coupled to the differential device are accommodated in hollow members. The hollow members are elastically supported by a second support part with respect to the ladder frame.

A driving device for an electric truck which can obtain good ride quality by decreasing the unsprung weight while achieving the adequate fuel efficiency performance by improving the power transmission efficiency and which can improve the mountability of a battery. The driving device includes a driving unit that accommodates therein a motor, a gearbox, and a differential device. The driving unit is supported by a first support part with respect to a ladder frame. Drive shafts coupled to the differential device are accommodated in hollow members. The hollow members are elastically supported by a second support part with respect to the ladder frame.

A clamping system for mating an I-Beam frame to an undercarriage is disclosed. The clamping system utilizes clamping brackets to secure the undercarriage to the trailer frame. The undercarriage has adapter sides oriented perpendicular to the undercarriage adapter bottom. The clamping brackets have two portions oriented perpendicular to each other. Holes are located in the clamping brackets to receive bolts or screws. The trailer frame is aligned onto the undercarriage and positioned such that proper tongue weight is applied. The clamping brackets are rigidly installed on the clamping bracket sides. Clamping screws are installed into the clamping brackets and torqued to a value such that a compressive force is applied between the bottom of the I-Beam and the undercarriage adapter bottom. The compressive force applied prevents unwanted relative motion between the I-Beam frame and the undercarriage during use.

A clamping system for mating an I-Beam frame to an undercarriage is disclosed. The clamping system utilizes clamping brackets to secure the undercarriage to the trailer frame. The undercarriage has adapter sides oriented perpendicular to the undercarriage adapter bottom. The clamping brackets have two portions oriented perpendicular to each other. Holes are located in the clamping brackets to receive bolts or screws. The trailer frame is aligned onto the undercarriage and positioned such that proper tongue weight is applied. The clamping brackets are rigidly installed on the clamping bracket sides. Clamping screws are installed into the clamping brackets and torqued to a value such that a compressive force is applied between the bottom of the I-Beam and the undercarriage adapter bottom. The compressive force applied prevents unwanted relative motion between the I-Beam frame and the undercarriage during use.

A rear suspension apparatus of a vehicle includes: a transverse helper leaf spring connected to a rear axle and disposed in a transverse direction; and a first stopper mechanism and a second stopper mechanism contacting the transverse helper leaf spring when the vehicle moves. The rear suspension apparatus is capable of improving riding quality by using a new spring constant value generated by the transverse helper leaf spring when freight is loaded and a vehicle body frame moves downwardly, and restricting rolling movement of the vehicle when rolling is caused, thereby increasing roll stiffness and improving driving stability.

A silencer for a leaf spring for a commercial vehicle is provided. The silencer includes an upper rubber body having defined therein a fitting hole into which a second leaf spring is press-fitted, with a top surface of the upper rubber body serving as a contact surface in contact with a first leaf spring, and a lower rubber body having defined therein an accommodation space, with a first buffering protrusion being provided on a bottom surface of the lower rubber body such that a third leaf spring is able to be in contact with the first buffering protrusion.

An oblong cantilevered support includes a pair of latitudinally spaced apart oblong resilient members connected by a pair of longitudinally spaced apart blocks. The longitudinal spacing between the blocks can be adjusted. One or both of the members can have a tapered profile causing the stiffness of the member to vary along its length. Adjusting the spacing between the blocks and/or sliding a variable stiffness member longitudinally with respect to the blocks can adjust the stiffness of the overall support. Each member can be made from a unitary piece of fiber composite material such as a carbon fiber infused polymer wherein the orientations of the fibers are varied to provide both bending and torsional strength and stiffness that varies along the length of the member. The tapered geometry can be formed by a pair of parallely spaced apart oblique trapezoidal truncated pyramids interconnected by a webbing strip.

An oblong cantilevered support includes a pair of latitudinally spaced apart oblong resilient members connected by a pair of longitudinally spaced apart blocks. The longitudinal spacing between the blocks can be adjusted. One or both of the members can have a tapered profile causing the stiffness of the member to vary along its length. Adjusting the spacing between the blocks and/or sliding a variable stiffness member longitudinally with respect to the blocks can adjust the stiffness of the overall support. Each member can be made from a unitary piece of fiber composite material such as a carbon fiber infused polymer wherein the orientations of the fibers are varied to provide both bending and torsional strength and stiffness that varies along the length of the member. The tapered geometry can be formed by a pair of parallely spaced apart oblique trapezoidal truncated pyramids interconnected by a webbing strip.