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 multi-plate spring suspension of composite material for a vehicle includes: a first bracket unit mounted to a rubber spring; a second bracket unit mounted to a trunnion base; and a plurality of composite springs manufactured by impregnating reinforcing fibers with resin, coupled to the first bracket unit and the second bracket unit at opposite ends thereof, respectively, and being vertically spaced apart from each other.

Composite suspension components are disclosed. The components are made from resin containing elongated fibers (8). The arms of the suspension components may receive reinforcement (40) using different devices and methods. A composite torque rod also incorporates a tunable compliance feature.

A suspension for a wheeled vehicle includes a leaf spring extending longitudinally relative to the vehicle and having first and second lugs protruding downward therefrom. The lugs are spaced from one another a length of the leaf spring to define a pocket therebetween. An axle passes perpendicularly beneath the leaf spring such that a portion of the axle is disposed in the pocket and is clamped between the lugs. The lugs may be fabricated integrally with 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.

A suspension spring unit can be positioned between a vehicle body and a wheel support. The suspension spring unit may form a constituent part of the vehicle chassis, configured with spring bodies made from a fiber composite material. At least two ring bodies arranged in series may be made from a fiber composite material and may have a respectively closed contour. The two ring bodies may be connected to one another via at least one connecting element.

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.

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 spring leaf for a leaf spring (1) has an upper side (13), a lower side (14), two lateral sections extending between the upper side (13) and the lower side (14), a longitudinal axis (15), a section plane (III) extending perpendicularly to the upper side (13) and lower side (14) and through the longitudinal axis (15), two end sections (3a, 3b), and a middle section (4) extending between the end sections (3a, 3b). The middle section (4) has a clamping region (5). A main tension region (6a, 6b) is provided between at least one of the end sections (3a, 3b) and the clamping region (5), the thickness (S) of which decreases in the direction from the clamping region (5) to the end section (3a, 3b), in particular decreases parabolically. The width (B) of the main tension region (6a, 6b) extending between the section plane (III) and a lateral section of the spring leaf (2) increases over a part of its length or over its entire length in the direction from the end section (3a, 3b) toward the clamping region (5) according to a quadratic function.