A torsion beam type of rear suspension comprising a pair of right-and-left trailing arms and a torsion beam connecting the trailing arms is provided. A floor under cover for airflow straightening is attached to a portion of a vehicle body in front of the rear suspension so as to cover a vehicle-body lower face. A arm cover is attached to a lower portion of the trailing arm so as to cover a lower face of the trailing arm. The arm cover is provided with an arm-cover enlarged portion which is configured to protrude outwardly, in a vehicle width direction, from the trailing arm in a vehicle bottom-face view. The floor under cover is provided with a floor-under-cover enlarged portion such that a rear end portion of the floor under cover faces closely to a front edge of the arm-cover enlarged portion.

An arm cover comprises a main part and a front part. These parts are configured such that when the rear suspension takes a standard vehicle-weight position, these parts are respectively inclined rearwardly and downwardly, wherein an angle of inclination of the inclined front part is smaller than that of the inclined main part. When the rear suspension takes the standard vehicle-weight position, a front edge of the front part is located at a higher level than a bottom face portion of a under cover, and when the rear suspension takes a rebound position, the front edge of the front part is located at a position which is higher than a level of the bottom face portion of the under cover and close to a rear end portion of the under cover.

An air spring is configured for use in connection with a motor vehicle. The air spring includes a first end cap. The first end cap is configured to attach to a first vehicle component. The air spring also includes a piston member. The piston member is configured to attach to a second vehicle component. The piston member is movable toward and away from the first end cap in an axial direction during use. The air spring also includes an air sleeve that is coupled to the first end cap at a first end by use of a first crimp ring and to the piston member at a second end by use of a second crimp ring to form a chamber configured to receive pressurized air. The air spring further includes a transition collar that is configured to placed radially outward from either the first or second crimp ring. The transition collar includes a sloped or tapered exterior surface that allows a portion of the air sleeve to engage and roller over the exterior surface of the transition collar to reduce wear to the air sleeve.

A bumper stopper installed on the shock absorber of a vehicle to respond to the impact of a cylinder lifting or lowering in the vertical direction depending on the running state of the vehicle. The bumper stopper is constructed such that a cylindrical dust cover having an opening formed at the lower end thereof is connected to a buffer member formed of peaks and troughs. The buffer member has a through hole through which a cylinder and rod of a shock absorber passes via a connection plate so that the buffer member and the dust cover are integrated with each other. It prevents air from being compressed inside the buffer member, thereby preventing component damage due to high pressure. Also, it prevents abnormal noise from occurring in the process of contact and separation between the cylinder and the connection plate, thereby providing improved ride comfort.

An active roll stabilizer of a motor vehicle including an actuator (8) in the form of a swivel motor arranged so as to rotate about a longitudinal axis of the vehicle. The swivel motor has an essentially cylindrical housing (12) with a cover, first and second stabilizer halves (18, 19) are connected to respective ends of the actuator for the transmission of torque, and a wiring harness (1) has a first end and a second end. The harness includes cables (3, 4, 5) for the transmission of electric power and signals. The first end is connected to the actuator, by way of a plug (2), and the second end is arranged positionally fixed in the vehicle at a cable transfer point (20). The cover forms a dry space and has a plug receiving opening, in its periphery, into which the plug can be inserted, in the radial direction, and secured.

Provided is a damper for a semi-active energy regenerative suspension based on hybrid excitation. The damper includes: an upper lifting lug, a dustcover, a lower lifting lug, a hydraulic shock absorber, and a hybrid excitation mechanism, wherein the hydraulic shock absorber is configured to provide a constant viscous damping coefficient, and wherein the hybrid excitation mechanism is configured to generate an adjustable electromagnetic damping force, to transform the vibration energy into electrical energy, and to storage the electrical energy. Also provided is a method for determining the sizes of the damper. The damper which has a simple structure, balances the vibration isolation property and energy regenerative property of the vehicle suspension, and provides a fail-safe function. Furthermore, the method for determining the sizes of the damper is easy and practical to implement, has definite steps and produces drastically optimized results.

A cover system for a damper includes an outer tube and a piston rod extending from an end of the outer tube. The cover system also includes a dust tube disposed around a portion of the outer tube. The dust tube includes a first end located proximal to the end of the outer tube and a second end opposite to the first end. The dust tube at least partially encloses the piston rod. The cover system further includes a cap connected to the outer tube. The cap is adapted to at least partially cover the first end of the dust tube.

An underbody cladding is provided for a two-track motor vehicle with wheel-controlling links as part of a rear axle for cladding the underbody. The underbody cladding at least partially extends in a substantially horizontal plane and extends in the direction of the outside of the vehicle close to an inner side of a rear wheel. The underbody cladding is divided into three sections, a front section, a central section and a rear section. The central section extends at least over a region below the wheel-controlling links and is connected at least over part of the width thereof to the front section and/or the rear section. The central section is designed in such a manner that the section can at least partially follow and/or yield to a vertical movement of the wheel-controlling links. The front and the rear section of the underbody cladding can in each case be arranged in a positionally fixed manner on the motor vehicle and cannot follow and/or yield to a vertical movement of the wheel-controlling links.

A structural component 1 is provided for a vehicle designed for driving off-road on rough terrain. The component 1, such as the lower control arm of a suspension system, is formed from aluminum, aluminum-alloy or other light-weight material and provided on its underside with a parallel arrangement of chamfered ribs 5 which extend in the direction of travel of the vehicle. The spacing between adjacent ribs 5 is less than or equal to 10 mm so as to prevent underlying rocks and stones 7 from impacting, and thereby abrading the inner surface 3 of the component 1. The ribs 5 are provided as sacrificial elements and will become eroded in use until they no longer provide the desired protection of the inner surface 3. The extent of abrasion of the ribs 5 can be ascertained by a visual inspection of the underlying surface of the vehicle, and, if necessary, the component 1 can be replaced.

A flexible undercover for a suspension system including an undercover panel configured to be disposed inboard of the wheel assembly, the undercover panel being flexible and configured to expand and contract with movement of the wheel assembly, and an undercover mounting plate connected to an outboard edge of the undercover panel, the undercover mounting plate configured to be attached to the suspension system.