A dual-mode suspension system using hydraulic dampers is disclosed. One or more dampers on each side of the four-wheel suspension system are coupled to a respective damper on the other side via a damper valve. One or more leaf springs may be arranged between the leading links coupled to some of the dampers, and trailing links coupled to other of the dampers. The suspension system may advantageously engage, lock, or partially disengage the respective dampers connected by the valve on each side of the system. Manipulating the valve to control engagement of the dampers, which may depend on the speed and related issues, provides control over whether heave motions should be separated from roll. In another embodiment, one or more single or double acting hydraulic cylinders may be used to engage dampers.

Automotive leaf springs are produced from low-hardenability and specified hardenability steel, with identical and different length, width and thickness and constant or variable cross section profile, that are subjected to through-surface hardening and low tempering. The ideal critical diameter of hardening, carbon content and hardened layer depth depend on the thickness of constant cross section profile leaf and maximum and minimum thicknesses of variable cross section profile leafs. Adherence to the optimum correlations of parameters indicated make it possible to produce leaf springs with the best mechanical properties and longevity.

An electric vehicle includes a frame module carrying an electric motor unit and a suspension including, for each wheel, upper and lower oscillating arms connected to a wheel support by swivel joints which define a steering axis of the wheel. The suspension includes two shock absorber devices arranged in horizontal positions and along directions transversal with respect to a vehicle longitudinal direction, which is carried by the frame module centrally on the vehicle. Each shock absorber cylinder is operatively connected to a respective oscillating arm by an oscillating linkage member. Brake discs are arranged at remote positions with respect to the wheels, on two output shafts at two opposite sides of the motor unit, which, in one example, includes two electric motors and two respective gear reducer units from which project the output shafts carrying the brake discs; the latter connected to wheel hubs by respective drive shafts.

A vehicle spring for a spring system, includes a spring body (20) and is produced, in particular rolled, from a profiled bar (1) made of a flat steel bar, in particular spring steel, in a hot deformation process. The profiled bar (1) or the spring body (20) has at least one material recess (6) which is provided over the length of the profiled bar or the spring body at least in some regions. The cross-sectional shape of the profiled bar (1) can be the same over the entire length of the profiled bar, whereas the cross-sectional shape in the spring body (20) can vary over the length of the spring body.

A motor vehicle suspension having a leaf spring, a control, and a connector formed of a monolithic piece of elastomer. The connector has a blind-hole cavity receiving an end of the leaf spring and a through-hole cavity through which the control arm extends. The connector is bonded to the leaf spring and to the control arm by vulcanization. The control arm has at least one hole formed through a flat connection portion thereof, and the connector extends through the at least one hole. At least one stiffener plate is embedded in the connector and is arranged substantially parallel to the flat connection portion of the control arm received by the through-hole cavity.

A suspension interconnection assembly comprises first and second saddle brackets and a fastener. Each saddle bracket comprises a base, a pair of arms spaced apart and have the base disposed therebetween, and a pair of shoulders. Each shoulder is disposed between the base and a respective arm. Each shoulder has a first beveled surface. The pair of shoulders cooperates with the base and the pair of arms to at least partially define a U-shaped pocket. The U-shaped pockets of each saddle bracket are sized to partially receive an axle housing. The fastener interconnects the saddle brackets to couple the saddle brackets and a spring to the axle housing. The beveled surfaces of each saddle bracket are adapted to operatively engage the peripheral wall. The pairs of arms of each saddle bracket are adapted to operatively engage one another after the beveled surfaces operatively engage the peripheral wall.

The present invention relates to a method for determining a functional status of a vehicle shock absorber arrangement (100). The method determines a difference between force values during compression and expansion of the vehicle shock absorber arrangement (100), whereby the shock absorber arrangement (100) can be determined to be degraded if the difference is below a predetermined threshold.

An adjustable spring mounting assembly includes an adjustment plate, including a receiver, an elongated axle alignment slot and at least one height adjustment aperture, and an alignment correction insert received and held in said receiver. The alignment correction insert includes a plurality of alignment correction apertures wherein a selected one of the plurality of alignment apertures is aligned with the elongated axle alignment slot to correct axle alignment of the vehicle.

A leaf spring assembly for a wheel suspension of a motor vehicle including a leaf spring resiliently supporting of a wheel carrier on a vehicle body of the motor vehicle. The leaf spring has a first end portion, and a diametrically or longitudinally, opposite second end portion fastened, pivotably mounted, to the vehicle. The leaf spring includes a suspension portion extending between the two end portions. The leaf spring includes two spring leaves held pressed one against the other by a first clamp in the suspension portion and are held pressed one against the other by a second clamp distanced or longitudinally spaced from the first clamp. The position of the second clamp, its position on the leaf spring, is variable in the direction of the longitudinal axis of the leaf spring.

A suspension system for a vehicle is provided. The suspension system includes a first chassis rail extending longitudinally in an axial direction of the vehicle. The suspension system also includes a second chassis rail extending longitudinally in the axial direction of the vehicle. The suspension system further includes a transverse beam coupled to the first chassis rail and the second chassis rail. The suspension system yet further includes at least one leaf spring extending in a transverse direction of the vehicle, the at least one leaf spring having a spring rate that is actively variable. The suspension system also includes a fulcrum locator operatively coupled to the at least one leaf spring and to the transverse beam, the fulcrum locator in a sliding relationship with the at least leaf one spring.