The invention relates to a running gear structure (4) for a commercial vehicle. The running gear structure comprises a lower transverse strut (8) and an upper transverse strut (9). The lower transverse strut (8) and said upper transverse strut (9) are fixedly connected to each other. The upper transverse strut (9) comprising two recesses (12, 13) which limit a space (14) located above the lower transverse strut (8). The space (14) is open at least in upper direction and dimensioned for accommodating a suspension spring (6). Preferably, an axle body and longitudinal swinging arms (22, 23) of the running gear structure (4) have a skeletal design with a plurality of struts (5). It is possible that the running gear structure (4) is L-shaped in a side view. Here, one leg of the L is formed by a horizontal structure part forming the longitudinal swinging arms (22, 23) whereas the other leg of the L is formed by a vertical structure part forming the axle body.

A vehicle suspension is provided, including an axle having an axle body with an exterior surface, a main trailing arm shell portion having a first axle engagement surface configured for engaging a first portion of the exterior surface, and a second trailing arm shell portion having a second axle engagement surface configured for engaging a second portion of the exterior surface. Upon assembly to the axle, the main trailing arm shell portion and the second trailing arm shell portion engage more than 180° of a curvature of the exterior surface.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, are arranged, and trailing arms rigidly attached with a spring bracket for supporting an air-suspension bellow, and a method for manufacturing the vehicle rigid axle. An axle beam section extending between the trailing arms, a trailing arm adjoining the axle beam section and the spring bracket are formed by two shell elements connected to each other, which form a hollow body. In an embodiment, the spring bracket is formed by a lower shell element forming an axle beam section extending between the two trailing arms, and the spring bracket is arranged so that the air-suspension bellow mounted on the spring bracket is penetrated by the central longitudinal axis of the axle beam section. Two shell elements made of sheet metal are formed and joined together to form a hollow body.

A telescoping axle includes an elongated center tubular base axle section for supporting a farm implement and receiving in telescopic relation an elongated tubular outer axle section which receives in telescopic relation an elongated tubular inner axle section. Each axle section is preferably rectangular or square in cross section with the outer and inner axle sections each supporting a horizontal wheel axle. An elongated actuator connects the inner axle section to the outer axle section for moving the inner axle section and outer axle section between a retracted position within the base axle section and an extended position projecting from opposite ends of the base axle section. The axis of each axle is preferably above the base axle section, additional axle sections may be used and the axles may be made steerable.

This disclosure details electrified vehicle drive systems equipped with electric machine integrated axle assemblies. An exemplary electrified vehicle drive system includes a leaf spring assembly and an axle assembly mounted to the leaf spring assembly. The axle assembly may include a cradle and an electric machine mounted within the cradle. Shocks and stabilizer bar assemblies may extend between the cradle and a vehicle frame of the electrified vehicle.

In a pressing step, a first forged product is pressed by a first die, and thereby, a second forged product including a rough flange having a thickness-changing portion is produced. The thickness-changing portion includes a front part protruding frontward from a side of a rough web part and a rear part protruding rearward from the side of the rough web part. Each of the front part and the rear part includes a first part, and a second part that is thicker than the first part and is located farther from the rough web part than the first part. In the pressing step, at least a part of the rough flange that is above or below the web part (thick part) is pressed by the first die, whereby the material of the first forged product in the part is caused to flow frontward and rearward, and the thickness-changing portion is formed.

A steering knuckle of a utility vehicle has a main body, a steering knuckle bearing for receiving in a rotating articulated manner a vehicle axle, a hub-type, cup-shaped receiving portion, open towards a rim of a vehicle wheel, in which portion an anti-friction bearing and a bearing journal can be received. The main body has an opening for receiving a drive shaft. The opening leads into the hub-type receiving portion. An axle assembly and a vehicle axle of a utility vehicle are also provided.

The invention relates to an assembly (1) of a frame member (2) for an electric vehicle comprising a transverse member (14) with at each end a housing (10,10) connected to the transverse member (14) and two in-wheel motors (3,3) connected to a respective housing. Each motor comprises a brake drum (35) connected to a rotor (24), extending coaxially within the housing (10,10) near an inner surface a circumferential wall (8) of the housing. A brake shoe assembly (51,52,55,56) is movable in a radial direction R against the brake drum (35), and an actuator (18,18) is placed on an outer surface (17,17) of the circumferential wall (8,8) of the housing (10,10), connected to the brake shoe assembly (51,52,55,56). The assembly provides a low-floor portal frame member, with two in-wheel motors and a brake system that has relatively small axial dimensions and provides a reduced space envelope at the vehicle side.

A vehicle suspension is provided, including an axle having an axle body with an exterior surface, a main trailing arm shell portion having a first axle engagement surface configured for engaging a first portion of the exterior surface, and a second trailing arm shell portion having a second axle engagement surface configured for engaging a second portion of the exterior surface. Upon assembly to the axle, the main trailing arm shell portion and the second trailing arm shell portion engage more than 180 of a curvature of the exterior surface.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, are arranged, and trailing arms rigidly attached with a spring bracket for supporting an air-suspension bellow, and a method for manufacturing the vehicle rigid axle. An axle beam section extending between the trailing arms, a trailing arm adjoining the axle beam section and the spring bracket are formed by two shell elements connected to each other, which form a hollow body. In an embodiment, the spring bracket is formed by a lower shell element forming an axle beam section extending between the two trailing arms, and the spring bracket is arranged so that the air-suspension bellow mounted on the spring bracket is penetrated by the central longitudinal axis of the axle beam section. Two shell elements made of sheet metal are formed and joined together to form a hollow body.