Shock absorber assembly structures are disclosed. An example shock absorber disclosed herein includes a shock absorber mount coupled to an end of the shock absorber, the shock absorber mount including a recess to receive a locating rib of a vehicle body, and an aperture to receive a fastener to couple the shock absorber mount to an attachment boss of the vehicle body.

Gas spring end members include an end member wall with a longitudinal axis. The end member wall includes an end wall portion and an outer wall portion. The outer wall portion extends peripherally about an axis and is dimensioned to receivingly engage a flexible spring member. Rib wall portions are spaced around the axis with each of the rib wall portions projecting axially from the end wall portion toward a rib end surface portion. The rib wall portions also include a rib edge surface portion spaced inward from an inner side surface portion of the outer peripheral wall portion such that a gap is formed therebetween. Gas spring assemblies including one or more of such end members, and suspension systems including one or more of such gas spring assemblies are also included.

A mounting apparatus for vehicle suspension ball joints that are firmly affixed for operation, are easily adjustable in a generally vertical direction for precise tuning of suspension geometry for dynamic performance in multiple axes using an array of cylindrical shims tuned to match fastener distance and height with a socket that has mounting bolts that engage a scalloped cap.

Shock absorber assembly structures are disclosed. An example shock absorber disclosed herein includes a shock absorber mount coupled to an end of the shock absorber, the shock absorber mount including a recess to receive a locating rib of a vehicle body, and an aperture to receive a fastener to couple the shock absorber mount to an attachment boss of the vehicle body.

Shock absorber assembly structures are disclosed. An example apparatus disclosed herein includes a body of a vehicle having a first longitudinal structural member adjacent a wheel arch area of the body, a first locating rib integrally formed in the first longitudinal structural member to position a shock absorber of a chassis of the vehicle during assembly of the vehicle body to the chassis, and a first attachment boss integrally formed in the first longitudinal structural member adjacent to the first locating rib to receive a first fastener to fasten the shock absorber to the body.

The invention is directed to a multipoint link (1) for an undercarriage of a vehicle, comprising a core element (5) formed from a foamed material and at least one roving (10) of bundled continuous filaments wound around the core element (5), wherein the at least one roving (10) winding around the core element (5) in at least one layer forms an outer layer of the multipoint link (5), wherein the core element (5) is constructed as a hollow body which comprises at least two shell elements (11, 12).

Shock absorber assembly structures are disclosed. An example apparatus disclosed herein includes a body of a vehicle having a first longitudinal structural member adjacent a wheel arch area of the body, a first locating rib integrally formed in the first longitudinal structural member to position a shock absorber of a chassis of the vehicle during assembly of the vehicle body to the chassis, and a first attachment boss integrally formed in the first longitudinal structural member adjacent to the first locating rib to receive a first fastener to fasten the shock absorber to the body.

A trailing arm manufacturing method includes: preparing a metallic inner plate and a resinous plate member composed of at least two components; heat-crimping the inner plate while sandwiching the inner plate with the plate members in a state in which the inner plate is disposed between the plate members by using a pair of left and right molding dies including a rib molding portion for injection-molding a rib portion having a plurality of ribs; and injection-molding the rib portion on the plate member during the heat-crimping or after the heat-crimping.

A collar includes a tubular portion and a flange portion extending radially outward from an end portion of the tubular portion, first and second corner portions formed by the tubular portion and the flange portion are provided with first and second curved surface portions formed as concave curved surfaces, an end portion of the trailing arm is provided with a collar through-hole into which the collar is inserted, and an edge portion of the collar through-hole is provided with a through-hole side curved surface portion formed as a convex curved surface coming into contact with the first and second curved surface portions.

A fiber-reinforced plastic chassis may include a steering element, where the steering element comprises at least one reinforcement structure formed with continuous fibers, where the steering element comprises at least one stiffening structure formed with short and/or long fibers, where the at least one reinforcement structure is formed integrally with the at least one stiffening structure via a thermosetting matrix material, and where the steering element comprises a plurality of bearing receivers integrated in at least one of the at least one reinforcement structure and the at least one stiffening structure for receiving bearing elements.