A suspension linkage for a motor vehicle includes an extruded body having a first wall and a longitudinal length. An extruded feature is disposed on the first wall of the extruded body and extends along the longitudinal length. The extruded feature has a cross-sectional profile configured to control a flexural rigidity of the suspension linkage.

The disclosure comprises a method for producing a sleeve-like passage for a bearing accommodation in a metallic wheel control arm of a vehicle. The method may include placing a wheel control arm end of the wheel control arm onto a pressing plate of a pressing tool; and forming a tapered wall in the wheel control arm end and a circumferential collar around the tapered wall in the wheel control arm end, wherein the forming comprises pressing the wheel control arm end against the pressing plate using a pressing punch, wherein a volume of metal of the wheel control arm end is displaced into a circumferential cavity due to the pressing of the wheel control arm end against the pressing plate,; and perforating the tapered wall to obtain the sleeve-like passage.

The disclosure describes a wheel control arm for a wheel suspension in a vehicle including a flat first profile body including a first narrow end and a second narrow end, the second narrow end extends opposite the first narrow end; broadsides facing one another; a first profile body end and a second profile body end, the first profile body end includes a first bearing seat configured to fasten the wheel control arm to a vehicle component, the second profile body end includes a second bearing seat configured to fasten the wheel control arm to a wheel carrier, the first profile body is curved along a longitudinal axis of a profile body; and a second profile body, including a third profile body end and a fourth profile body end, the third profile body end includes a third bearing seat configured to fasten the wheel control arm to the vehicle component.

A damper assembly includes a housing. A method of forming a damper assembly includes extruding the housing formed of aluminum. The housing defines a first chamber and a first passage spaced from each other, with a first inlet fluidly connecting the first chamber and the first passage. A piston is disposed in the first chamber and is movable in a first direction and a second direction opposite the first direction. A first restrictor valve is disposed in the first passage. The first restrictor valve is configured to restrict a flow of liquid into the first passage from the first chamber and the first inlet as the piston moves in one of the first and second directions which causes the liquid in the first chamber to increase a pressure applied to a first side of the piston to dampen movement of the piston.

The invention concerns a multipiece spring link (100) for a wheel suspension of a vehicle, with: a first profiled side piece (101), forming a first side leg of the multipiece spring link (100), wherein the first profiled side piece (101) has a first bulge (105); a second profiled side piece (103), forming a second side leg of the multipiece spring link (100), wherein the second profiled side piece (103) has a second bulge (107); and wherein the first bulge (105) and the second bulge (107) are arranged one opposite the other and together form a spring receiving region (108) for the receiving of a spring.

A coupling rod comprises a connecting element made of a fiber-reinforced plastic by a pultrusion process, the connecting element having a strut portion with a longitudinal axis and a connecting portion; a joint element; and a carrier element connected to the connecting element and the joint element, the carrier element being made of plastic by overmolding; wherein the matrix of the fiber-reinforced plastic is a thermoset and the connecting portion is formed relative to the strut portion, wherein an interlocking connection is formed between the connecting portion and the carrier element by the overmolded carrier element. A method of producing a coupling rod is further described.

A suspension arm for multi-link suspensions of automotive vehicles, comprising a body formed by a hollow extruded profile the cross-section of which has a closed outer contour formed by side walls and comprising at least one inner partition internally splitting the profile into at least two inner cavities, the extruded profile having the length of the arm to be obtained, according to a longitudinal axis of the arm, where a central section of the arm is machined in at least one side wall having no inner partition extending therefrom without the machining ever reaching an inner partition, and where the side walls having the at least one inner partition extending therefrom comprise an end opening in each end area of the arm, between which the central section is arranged, and a method for making the suspension arm.

A damper assembly includes a housing. A method of forming a damper assembly includes extruding the housing formed of aluminum. The housing defines a first chamber and a first passage spaced from each other, with a first inlet fluidly connecting the first chamber and the first passage. A piston is disposed in the first chamber and is movable in a first direction and a second direction opposite the first direction. A first restrictor valve is disposed in the first passage. The first restrictor valve is configured to restrict a flow of liquid into the first passage from the first chamber and the first inlet as the piston moves in one of the first and second directions which causes the liquid in the first chamber to increase a pressure applied to a first side of the piston to dampen movement of the piston.

A damper assembly includes a tubular member including a sidewall and a shoulder. The damper assembly includes a rod and a piston coupled to the rod. A secondary piston has a second contact surface, an opposing second surface, an inner cylindrical face defining a central aperture that receives the rod, and an outer cylindrical face. The opposing second surface includes one or more surface grooves, extending between the inner cylindrical face and the outer cylindrical face along the opposing second surface, and one or more bypass orifices disposed about the body member. The bypass orifices extend along the inner cylindrical face between the second contact surface and the opposing second surface. The secondary piston defines a channel extending between the inner cylindrical face and an outer periphery of the body member. The channel and bypass orifices form a fluid flow path when the piston contacts the secondary piston.

The present disclosure relates to a chassis component having a base body, wherein the base body has an opening for passing through a fastening means and two guide elements for guiding an eccentric element are arranged on opposite sides of the opening, wherein the guide elements are formed in one piece and using the same material of the base body of the chassis component by mechanical processing and each have a back side and a contact side facing the opening, wherein the contact side is formed orthogonally to the base body. According to the present disclosure, an outer transition region with a radius is formed between the respective contact sides and the base body. The present disclosure further relates to a method for producing a chassis component.