A suspension apparatus for a vehicle may include: a lower arm having a fastening hole formed therein; and a lower pad mounted on the lower arm, wherein the lower pad comprises: a pad body disposed on the lower arm, and configured to buffer shock; and an insertion protrusion protruding from the pad body, and inserted into the fastening hole, wherein the fastening hole and the insertion protrusion each have an angular shape.

A suspension assembly for a vehicle includes a lower alignment arm, an upper alignment arm, and a linear force element. The lower alignment arm includes a first portion, second portion, a third portion, and a linear force element mount. The linear force element mount includes a bearing for pivotably coupling the linear force element to the lower alignment arm.

A suspension apparatus for a vehicle may include: a lower arm having a fastening hole formed therein; and a lower pad mounted on the lower arm, wherein the lower pad comprises: a pad body disposed on the lower arm, and configured to buffer shock; and an insertion protrusion protruding from the pad body, and inserted into the fastening hole, wherein the fastening hole and the insertion protrusion each have an angular shape.

A front lower suspension connection for a space frame comprises a U-shaped base and upper suspension control arm support sections on the U-shaped base. The U-shaped base can have a cross-beam section and suspension column support beam sections positioned at opposite ends of the cross-beam section, where each suspension column support beam section may include lower suspension control arm pivot joint supports located at opposite ends of the suspension column support beam sections. Each upper suspension control arm support section can have a first support column and a second support column spaced from the first support column, where the first support column may include a first upper suspension control arm pivot joint support, and the second support column may include a second upper suspension control arm pivot joint support and a front mounting surface. A rear mounting may be provided on a rear surface of the front lower suspension connection.

A dump body pivot pin, suspension node, and rear frame connection comprises a dump body pivot pin boss, a rear suspension connection boss, outer and inner upper rear frame tube connection bosses, outer and inner lower rear frame tube connection bosses, upper and lower beams, a beam connection web, and a support tube connection boss. The dump pivot pin boss has a pivot bore, a pin bore center axis, and inner and outer flat surfaces. The rear suspension connection boss includes a suspension connection center axis and inner and outer flat surfaces. The upper beam connects the outer and inner upper rear frame tube connection bosses to the dump body pivot pin boss. The lower beam connects the outer lower rear frame connection boss to the rear suspension connection boss and the dump body pivot pin boss and the inner lower rear frame tube connection boss to the dump body pivot pin boss.

A method for producing a connection element (1, 30), in particular for an articulated connection of components arranged in a chassis. The connection element (1, 30) is formed by a profile element (6, 31) which includes a joint portion (2), for accommodating a joint component (5), a central portion (4), and a connection portion (3). The profile element (6, 31) is formed by an arrangement of at least one first profile section (7, 32) and at least one second profile section (8, 33), which are held in position, with interlock, by at least one fixing element (9, 10), a joint component (5) is inserted, into the joint portion (2) so formed, and the profile element (6, 31) and the joint component (5) are partially overmolded with a plastic material.

A dump body pivot pin, suspension node, and rear frame connection comprises a dump body pivot pin boss, a rear suspension connection boss, outer and inner upper rear frame tube connection bosses, outer and inner lower rear frame tube connection bosses, upper and lower beams, a beam connection web, and a support tube connection boss. The dump pivot pin boss has a pivot bore, a pin bore center axis, and inner and outer flat surfaces. The rear suspension connection boss includes a suspension connection center axis and inner and outer flat surfaces. The upper beam connects the outer and inner upper rear frame tube connection bosses to the dump body pivot pin boss. The lower beam connects the outer lower rear frame connection boss to the rear suspension connection boss and the dump body pivot pin boss and the inner lower rear frame tube connection boss to the dump body pivot pin boss.

A front lower suspension connection for a space frame comprises a U-shaped base and upper suspension control arm support sections on the U-shaped base. The U-shaped base can have a cross-beam section and suspension column support beam sections positioned at opposite ends of the cross-beam section, where each suspension column support beam section may include lower suspension control arm pivot joint supports located at opposite ends of the suspension column support beam sections. Each upper suspension control arm support section can have a first support column and a second support column spaced from the first support column, where the first support column may include a first upper suspension control arm pivot joint support, and the second support column may include a second upper suspension control arm pivot joint support and a front mounting surface. A rear mounting may be provided on a rear surface of the front lower suspension connection.

In order to reduce both the weight and the production costs in the case of vehicle chassis components consisting of at least two parts, a first part is made as a sheet component by press hardening and the second part is produced by a conventional production method, which does not include press hardening. The part produced by press hardening forms a structural component, whereas the other component serves to stiffen the part produced by press hardening.

The disclosure relates to a control arm for a wheel suspension system in a vehicle, including a sleeve-shaped aperture for the receiving of a bearing is formed in an integral control arm body, wherein the integral control arm body comprises a first side wall and a second side wall that is facing the first side wall. The sleeve-shaped aperture penetrates the first side wall and the second side wall. The sleeve-shaped aperture is formed sleeve-shaped with a first circumferential sleeve rim and a second circumferential sleeve rim. The first sleeve rim is formed by an outwardly shaped section of the first side wall that defines the sleeve-shaped aperture.