An axle mounting unit for commercial vehicles a surrounding element, an end element, at least one fastening element and a securing device, configured for mounting a first chassis part that comprises an axle, with a second chassis part that comprises a control arm, wherein a surrounding element is arranged on the first chassis part, an end element is arranged on the second chassis part, wherein the surrounding element has at least two legs extending in a leg direction, the end element extends between the two legs, the fastening element braces the end element with the surrounding element, the securing device creates a form-fit securing device that limits and/or prevents a displacement of the separated part in the leg direction in a positive-locking manner in the event of mechanical failure.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, respectively, are arranged, and with at least two trailing arms rigidly attached to the axle beam and with at least one air spring bellows assigned to the respective trailing arm. At least one component of an electric drive is placed in the hollow body, the drive shaft of which passes through the axle journal. To form at least one axle journal connection section extending between the two trailing arms, a trailing arm connected thereto and a receptacle for at least one component of an electric drive, two shell elements are formed from sheet metal and connected to one another, in particular welded, to form a hollow body surrounding the receiving space. At least one component of the electric drive is mounted in the receiving space.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, respectively, are arranged, and with at least two trailing arms rigidly attached to the axle beam and with at least one air spring bellows assigned to the respective trailing arm. At least one component of an electric drive is placed in the hollow body, the drive shaft of which passes through the axle journal. To form at least one axle journal connection section extending between the two trailing arms, a trailing arm connected thereto and a receptacle for at least one component of an electric drive, two shell elements are formed from sheet metal and connected to one another, in particular welded, to form a hollow body surrounding the receiving space. At least one component of the electric drive is mounted in the receiving space.

A vehicle suspension assembly includes a trailing axle carried by a frame of the assembly. The frame can retract to a retracted state from an extended state and extend from the retracted state to the extended state. The retraction and extension can occur along a longitudinal axis of the frame. An operator can pivotally raise and lower a free end of frame in the retracted or extended state along an arcuate path when the vehicle suspension assembly connects to a vehicle.

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.

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.

Disclosed herein is an adjustable suspension mount system that includes a first mount link pivotally attached to a mount feature and extending to a device used to support a load on a first wheel, the first mount link pivotally attached to the device. The mount feature is attached to or integrated into the frame of the vehicle. The system further includes a second mount link pivotally attached to at least one of the mount feature and a second mount feature, the second mount link extending to the first mount link, the second mount link pivotally attached to the first mount link. Further disclosed is a vehicle including the system, and a kit including the components to provide the system for a vehicle.

Disclosed herein is an adjustable suspension mount system that includes a first mount link pivotally attached to a mount feature and extending to a device used to support a load on a first wheel, the first mount link pivotally attached to the device. The mount feature is attached to or integrated into the frame of the vehicle. The system further includes a second mount link pivotally attached to at least one of the mount feature and a second mount feature, the second mount link extending to the first mount link, the second mount link pivotally attached to the first mount link. Further disclosed is a vehicle including the system, and a kit including the components to provide the system for a vehicle.

A rocking arm structure includes an arm body, a motive wheel assembly connected to the arm body, a caster wheel assembly connected to the arm body, and a shaft assembly connected to the arm body and disposed between the motive wheel assembly and the caster wheel assembly. The two wheel assemblies are configured to revolve in a same direction around the shaft assembly and for example allow a 4-wheeled vehicle/robot to become a 6-wheeled vehicle for stability as required during changes of terrain.

Axle seat assemblies and methods of manufacturing thereof, are provided for attachment to an axle body (15). The axle seat assembly may be comprised of a first piece (42) and a second piece (50). The first piece (42) may have a first wall, a second wall and a first axle seat piece engagement portion providing a first engagement surface. The second piece (50) may have a third wall and a second axle seat piece engagement portion providing a second engagement surface. The first wall and the second wall of the first piece are oriented to engage a front surface of an axle body and the third wall of the second piece is oriented to engage a rear surface (30) of an axle body. The first and second engagement surfaces of the respective first and second pieces of the axle seat assembly are positioned and configured to engage one another to removably and reversibly secure with the use of a fastener the first piece to the second piece to form an axle seat assembly.