Air spring strut for a motor vehicle comprising an air spring with a shock damper for the spring-cushioning and damping of oscillations of a motor vehicle chassis, wherein the air spring comprises an air spring cover and a rolling piston, wherein a rolling bellows of elastomer material is clamped in an airtight manner between the air spring cover and the rolling piston. The air spring cover comprises a damper bearing receptacle in which a damper bearing of the shock damper is arranged, and the air spring cover comprises a clamping base to which a first end of the rolling bellows is attached. At least the damper bearing receptacle of the air spring cover is produced completely from a plastic material, and the plastic material is a thermoplastic.

A clamp including: a holding portion configured to hold a wire harness; and a fixing portion that is provided in a portion of an outer circumferential surface of the holding portion and is to be fixed to a fixed portion; wherein the fixing portion includes: a base that includes a first surface that faces a holding portion side and a second surface located opposite to the first surface, a support shaft that extends from the second surface of the base in a direction away from the holding portion, a lock that is provided at a leading end of the support shaft and is formed to be able to be locked to the fixed portion, and a vibration suppressor that is made of a material whose elastic modulus is lower than that of the base and protrudes from the second surface of the base toward a lock side.

An illustrative example composite leaf spring includes first and second bushing tubes near longitudinal ends. A ribbon of base material is wrapped at least partially around the first and second bushing tubes. The base material has a width that defines a width of the leaf spring. First portions of the base material are near the longitudinal ends and a second portion is between the first portions. The second portion is thicker than the first portions. A plurality of layers of a ribbon of tension material are wrapped around the base material. The tension material defines an outermost layer of the leaf spring. The tension material has warp strands in a longitudinal direction between the first and second longitudinal ends of the leaf spring and weft strands transverse to the warp strands. The warp strands establish a majority of a composition of the tension material.

Apparatus and methods for additively manufactured structures with augmented energy absorption properties are presented herein. Three dimensional (3D) additive manufacturing structures may be constructed with spatially dependent features to create crash components. When used in the construction of a transport vehicle, the crash components with spatially dependent additively manufactured features may enhance and augment crash energy absorption. This in turn absorbs and re-distributes more crash energy away from the vehicle's occupant(s), thereby improving the occupants' safety.

A curved support structure for a non-pneumatic tire and a tire incorporating such support structure. A support membrane extends continuously between a radially-inner end and a radially-outer end and defines opposing sides. A radially-outer joint may be provided on one of the opposing sides while a radially-inner joint may be provided on the other side of the membrane. An annular band may be incorporated with the radially-outer joint. A wheel, hub, or other structure may be incorporated with the radially-inner joint.

A shock absorbing member is provided having a sequential destruction capability and protection against electrolytic corrosion on fastening-fixing portions thereof to be fastened to a bumper reinforcement or a vehicle body. Embodiments include a shock absorbing member between a bumper reinforcement and a vehicle body, including a distal end portion fastened to the bumper reinforcement; a base end flange portion fastened to the vehicle body; and an absorbing member body extending in a vehicle front-rear direction and connecting the distal end portion and the base end flange portion. The absorbing member body includes a carbon fiber-glass reinforced plastic layer. Fastening-fixing portions of the distal end portion and the base end flange portion are composed of glass fiber reinforced plastic layers.

A spring assembly for a non-rail wheeled or tracked vehicle is provided. The spring assembly includes a piston, and a sleeve with variable thickness. The sleeve is made from an unreinforced synthetic elastomeric material and being free of reinforcing fibers. The sleeve is coupled with a plurality of end components and defines a deformable pressure vessel, and the deformable pressure vessel supplies a support force.

A wave spring comprises fiber in a thermoplastic resin matrix, and includes one or more annular wave-springs elements, or one or more curvilinear wave-spring elements. The annular wave-spring elements, which are arrayed in a stack, are not coupled to one another. A wave spring comprising annular wave-spring elements includes an alignment feature for establishing and maintaining the alignment of the wave spring elements. In a wave spring including curvilinear wave-spring elements, a first end of each curvilinear wave-spring element is attached to a first member and a second end of each curvilinear wave-spring element is attached to a second member, the plurality of curvilinear wave-spring elements being disposed between the two members. The plurality of curvilinear wave-spring elements in the array are positioned side by side, the array extending laterally along a length of the first member and second member, and providing a low-profile wave spring.

A method for forming an air spring for a vehicle including a frame coupled to the air spring includes heating an elastomeric base material to a melting point of the elastomeric base material, thereby forming a melted elastomeric base material, forming a sleeve from the melted elastomeric base material, the sleeve being substantially free of textile reinforcing fibers, and engaging the sleeve with end components, the sleeve and the end components defining a deformable pressure vessel, where the deformable pressure vessel supplies a supporting force.

Provided herein are a flexible organic light-emitting display (OLED) and a spring component. The film layers are pulled one on one by spring components to make the film layers flat when being unfolded and free of irreversible deformation when being folded. A lubricating layer is disposed between adjacent film layers so that the action force between the adjacent film layers is reduced, thereby making the flexible organic light-emitting display (OLED) flat and free of creases when being unfolded.