The saddle-riding motor vehicle (1; 107; 207) comprises a rear driving wheel (5; 105; 205) and a front steered wheel (7; 107; 207). The front steered wheel (7; 107; 207X, 207Y) is connected to a rotatable arm (9; 109; 209X, 209Y) provided with a rotary motion about a steering axis (A-A). A wheel support (37; 137) is connected to the rotatable arm (9; 109; 209) with the interposition of a suspension (17; 117; 217X, 217Y) comprising a shock absorber (22; 122). The suspension (17; 117) comprises a Watt four-bar linkage.

A strut mount and bearing assembly includes a strut mount having upper and lower ends, a central bore for receiving a shock absorber end and an annular upper race surface between the upper and lower ends and extending circumferentially about the bore. The upper end is fixedly connectable with a vehicle body and has a flat attachment surface disposeable against a vehicle surface of the vehicle body. A first bearing race is disposed on the mount and a spring seat having a second bearing race is movably coupled with the strut mount. The seat also has a lower end with spring engagement surface and a second bearing race is disposed on the seat spaced axially from the first bearing race. Rolling elements are disposed between the first and second bearing races to form a bearing. The various components are formed and sized to make an axially compact assembly.

A structure for the rear part of the body of a vehicle is provided with a suspension tower section to which a suspension is mounted. The suspension tower section has: a tower upper wall section which is formed in a fan-like shape, in a plan view, having an circular arc-shaped outer peripheral edge section located inside in the vehicle width direction, and which has a suspension fastening section to which the upper end of the suspension is fastened and affixed; a tower bend section which is a portion of the outer peripheral edge section, the portion bending downward; a tower outer peripheral wall section which extends downward from the tower bend section; and a first tower vertical wall section which is raised along the suspension tower section and extends downward from an end in the peripheral direction of the tower bend section to the tower outer peripheral wall section.

A front lifting system for vehicle comprises a threaded pipe, an annular hydraulic unit, and a fixing base. When the threaded pipe covers a shock absorber, a spring covers a damper of the shock absorber and two ends of the spring are respectively abutted against the annular hydraulic unit and the damper. At this time, the annular hydraulic unit does not act. When the annular hydraulic unit acts, it pushes the spring upwardly and further the spring pushes the damper upwardly so that the front of the vehicle may be lifted up to prevent the front of the vehicle with lower chassis from damage while going uphill or downhill.

A strut mount and bearing assembly includes a strut mount having upper and lower ends, a central bore for receiving a shock absorber end and an annular upper race surface between the upper and lower ends and extending circumferentially about the bore. The upper end is fixedly connectable with a vehicle body and has a flat attachment surface disposeable against a vehicle surface of the vehicle body. A first bearing race is disposed on the mount and a spring seat having a second bearing race is movably coupled with the strut mount. The seat also has a lower end with spring engagement surface and a second bearing race is disposed on the seat spaced axially from the first bearing race. Rolling elements are disposed between the first and second bearing races to form a bearing. The various components are formed and sized to make an axially compact assembly.

In one embodiment, a vehicle suspension assembly is described having a spring tube with a spring component disposed within the spring tube. A damper tube is slidably coupled to an interior of the spring tube, and a through shaft is disposed within the spring tube and also the damper tube. A damper piston is disposed within the damper tube and the damper piston is coupled to the through shaft. A damper valve assembly including an adjustable valve is also coupled to the through shaft. The vehicle suspension assembly further includes a pressure compensation feature coupled to the damper valve assembly.

A suspension device for a non-steered driving wheel in which an in-wheel motor for driving the driving wheel is incorporated in a wheel carrier and which includes suspension arm pivotally supported on a vehicle body at one end and connected at the other end to the wheel carrier via at least two elastic bushing devices. A principal elastic axis which is determined by the at least two elastic bushing devices and extends vertically passes through a grounding area of the driving wheel.

The invention relates to a link element (1) for a motor vehicle, comprising a connecting rod (2) and a coupling element (3) for coupling the connecting rod (2) to a subassembly of the motor vehicle, wherein the coupling element (3) comprises a housing (5) with a passage (6) through which the connecting rod (2) extends into the housing (5); characterized by a stop plate (7) for supporting forces transferred to the coupling element (3) by the connecting rod (2).

A damper spring support includes: a first angle adjustment mechanism configured for being fixed to a vehicle body; a support base configured for supporting a damper spring; and a connection structure configured for detachably fixing the support base to different positions of the first angle adjustment mechanism. If the support base being fixed to different positions of the first angle adjustment mechanism, a damper spring support surface of the support base facing different directions. A vehicle axle having the same is also included.

An axle-to-beam connection for an axle/suspension system of a heavy-duty vehicle that includes an axle, a beam with an alignment assembly, and an axle mount assembly. The alignment assembly is integrally formed with or is rigidly attached to the beam. The axle mount assembly intimately contacts and captures the axle. The axle is rigidly secured to the axle mount assembly without line welds. The axle mount assembly is removably connected to the alignment assembly to secure the axle to the beam.