A torsion spring assembly for a wheel suspension of a motor vehicle, including two torsion bars arranged coaxially one inside another and also a spring element, which is arranged axially-parallel to the two coaxial torsion bars, and can be mounted on the motor vehicle body via a bearing position, wherein the radial outer hollow-cylindrical torsion bar can be mounted on the motor vehicle body side and is connected in a rotationally-fixed manner to an output lever fastenable on a wheel guiding element and the radial inner torsion bar is connected in a rotationally-fixed manner to the outer torsion bar and is connected in a rotationally-fixed manner via a coupling to the spring element.

A variable rate leaf spring vehicle suspension system is provided. The system includes a vehicle frame. The system also includes a single leaf spring extending from a first end to a second end. The system further includes a shackle operatively coupled to the vehicle frame and defining a channel, the second end of the leaf spring disposed within the channel of the shackle.

A suspension system of a vehicle includes: an unsprung mass of a vehicle; a sprung mass of the vehicle; at least one transverse leaf spring coupled between the unsprung mass of the vehicle and the sprung mass of the vehicle; and a linear actuator coupled in parallel with the at least one transverse leaf spring between the unsprung mass of the vehicle and the sprung mass of the vehicle and configured to modify vibrational characteristics of the vehicle.

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.

A leaf spring device for a suspension system for a vehicle a including a leaf spring unit, an impact absorbing unit connected to the leaf spring unit and configured to absorb an impact generated by a motion of the leaf spring unit, and a lower arm support unit configured to accommodate the impact absorbing unit, the lower arm support unit being mounted on a lower arm.

The disclosure relates to a leaf spring retaining element for rotationally and elastically mounting a leaf spring end of a leaf spring on a vehicle structure. The leaf spring retaining element includes a leaf spring mounting part having a receiving recess to accommodate the leaf spring end; an elastomer molded part configured to rotationally and elastically mount the leaf spring end, wherein the elastomer molded part is arranged in the receiving recess and shaped to at least partially enclose the leaf spring end; and a bearing configured to support the leaf spring mounting part on the vehicle structure.

The invention relates to a tracked vehicle (V1, V2) comprising a vehicle body (20; 120), at least one track assembly (10) and a suspension device (S). Said track assembly (10) is arranged to be supported by said vehicle body (20; 120) by means of said suspension device (S). Said track assembly comprises a track support beam (12) for supporting a plurality of road wheels (16), an endless track (14) being disposed around said road wheels. Said suspension device (S) comprises a leaf spring arrangement (30; 130, 142, 144) having portions transversally arranged relative to the longitudinal extension of the vehicle. Said leaf spring arrangement comprises L-shaped leaf spring members (30; 130), each leaf spring member (30; 130) having a first portion (32; 132) attached to said vehicle body (20; 120), a second portion (34; 134) attached to said track support beam (12) and a transition portion (36; 136) there between, so that compressive and tensile stresses are located to said transition portion (36; 136) for generating a compressive action in said transition portion.

A vehicle axle arrangement of a vehicle wheel suspension system which has a spring arrangement which runs in the vehicle transverse direction in the installed position, steers wheels, and has bearings at the ends which are directed toward the wheels. The bearings are connected via respective bearing arrangements to transverse links which are in turn connected to wheel supports. The transverse links are coupled to a vehicle body. The spring arrangement have two leaf springs of identical configuration which are connected to one another via a coupling member.

A vehicle suspension having a first load-bearing component assembly and a second load-bearing component assembly. The first and second load bearing component assemblies are adapted to be transversely positioned across from each other on a vehicle chassis. Each load-bearing component assembly comprises a wheel hub, an upper control arm having an apex portion and a base portion, and a lower control arm having an apex portion and a base portion, and each wheel hub is supported between the apex portions of the upper control arm and the lower control arm of the respective load-bearing component assemblies. The base portion of each of the upper and lower control arms of the respective load-bearing component assemblies is adapted to be pivotally secured to a vehicle chassis to permit upward and downward vertical movement of each wheel hub, relative to a rest state, in response to load variations. A directionally-dependent heave spring assembly is adapted to be transversely secured to a vehicle chassis, the heave spring assembly is coupled to the first load-bearing component assembly and to the second load-bearing component assembly and exhibits resiliency in opposition to upward vertical movement of both wheel hub assemblies relative to their rest states, and exhibits substantially no resiliency in opposition to downward vertical movement of both wheel assemblies relative to their rest states.

A wheel alignment mechanism having a control arm connector, which is adapted for connection to a vehicle suspension control arm positioned between a vehicle chassis and a vehicle wheel, and which has an elongate portion; an inner support frame having a first surface and a second surface on a side of the inner support frame opposing the first surface, the elongate portion of the control arm connector positioned against the first surface at a select one of a first set of plural mounting locations on the first surface, with the first set of plural mounting locations being disposed in a first direction; and an outer support frame adapted to receive a wheel mounting, the connector having a third surface, the second surface of the inner support frame being positioned against the third surface at a select one of a second set of plural mounting locations on the third surface, and with the second set of plural mounting locations being disposed in a second direction approximately perpendicular to the first direction. Means are provided for securing the control arm connector to the inner support frame and the inner support frame to the outer support frame.