A front subframe structure includes front and rear cross members, a pair of left and right side members, and a vehicle body mounting portion disposed on front ends of the side members. The side member has a lateral widening portion at a front end thereof, wherein the lateral widening portion bulges outward in a vehicle width direction. The front cross member has a front widening portion at an end portion thereof in the vehicle width direction, wherein the front widening portion bulges forward of the vehicle. A portion of the front cross member excluding the front widening portion is disposed on the rear side with respect to the vehicle body mounting portion, and on the front side with respect to a rear end of the lateral widening portion.

A rear subframe structure is provided with a rear subframe configured such that a front cross member, a rear cross member, a pair of left and right upper side members, and a pair of left and right lower side members are connected; and a vehicle-body mounting portion formed. The rear subframe further includes a lower-arm support portion. The front cross member has a closed section, and a front portion of the closed section extends downwardly by forward and downward inclination of a left lateral portion and a right lateral portion of the front cross member. The lower-arm support portion is formed on a lower rear portion of the left lateral portion and the right lateral portion of the front cross member. The upper side member is connected to an upper rear portion of the left lateral portion and the right lateral portion of the front cross member.

A cargo vehicle includes a composite floor assembly configured to support cargo, at least one wheel assembly configured to transport the cargo on the composite floor assembly, a suspension assembly associated with the at least one wheel assembly, and an intermediate adapter assembly. The intermediate adapter assembly is permanently coupled to the composite floor assembly and removably coupled to the suspension assembly such that the composite floor assembly is removably coupled to the suspension assembly.

A vehicle has a frame and left and right suspension assemblies connected to the frame. Each suspension assembly has a lower control arm having an inner end pivotally connected to the frame, a first outer end and a second outer end; an upper control arm having an inner end pivotally connected to the frame and an outer end; a knuckle pivotally connected to the outer ends of the lower and upper control arms, the outer ends are pivotally connected to the knuckle separately from one another; and a shock absorber having an upper end pivotally connected to the frame and a lower end pivotally connected to one of the lower and upper control arms. The vehicle also has a left and right wheels rotationally connected to the knuckles of the left and right suspension assemblies.

In an embodiment, the present invention provides a stop device for limiting a vertical spring deflection of a motor vehicle leaf spring that is mounted on an axle member, the stop device including: a stop which limits a vertical movement of the leaf spring; a support structure for supporting and mounting the stop on a vehicle support; and a guiding device for receiving and guiding at least one of a cable, a line, and/or a holder. The guiding device is fastened to the support structure.

The invention relates to a front axle support for a motor vehicle, including side members and a crossmember interconnecting the side members, the crossmember being in the form of a hollow body and being provided with at least one attachment device for attaching a steering system housing.

Aspects of the present invention relate to a system for a vehicle comprising: a hydraulic suspension actuator comprising a piston, a first upper fluidic chamber and a second lower fluidic chamber, the first and second fluidic chambers separated by the piston; at least one actuator system module mounted to a subframe and laterally separated from the hydraulic suspension actuator, the at least one actuator system module comprising one or more actuator system components; a longitudinal beam located laterally between the hydraulic suspension actuator and the at least one actuator system module; and at least one conduit fluidly connecting the hydraulic suspension actuator and the at least one actuator system module, wherein the at least one conduit passes over the longitudinal beam.

A sub-frame arrangement (1) in a vehicle and method thereof wherein the sub-frame arrangement comprises a sub-frame (2), a first body member, and rear attachment means for attaching said sub-frame to the first body member. The sub-frame is a dual part sub-frame comprising a lower sheet section (2b) formed in a single piece wherein said lower sheet section extends the entire length of said sub-frame. The lower sheet section is further formed with two rear portions (21) each extending backwards in the travel direction of said vehicle and the rear portions are adapted to host the rear attachment means.

A sub-frame and method in a sub-frame arrangement in a vehicle wherein said sub-frame arrangement comprises a sub-frame, a body member, and a first and second attachment socket. Each attachment socket is adapted to host a fastening means arranged in a through going apertures of each attachment socket and adapted to fasten said sub-frame to the body member. The fastening means are adapted to fasten a front section of said sub-frame, first and second attachment sockets each comprises a weakened portion arranged at an angle separated from the vehicle deformation direction during a front collision, and the weakened portions are adapted to give way releasing the sub-frame in the event of deformation of the vehicle.

An electric-propulsion vehicle includes a motor-driven front axle assembly (10); and a motor-driven rear axle assembly (20); wherein the above assemblies each include a supporting frame (110), two wheel-suspension units (30), an electric motor (40) for driving the wheels in rotation, a control unit (45) for controlling the aforesaid motor, a differential transmission unit (55) with one or more gear ratios, and a steering device (50) for regulating the angular position of the wheel supports of the aforesaid suspension units with respect to the aforesaid frame; the motor, the suspension units, and the steering device being mounted on the aforesaid supporting frame. The two axle assemblies have altogether corresponding configurations, and constitute in themselves independent modules, already pre-assembled in their operating configuration.