A structural reinforcement device for insertion into a cavity of a structure and method for making the same including a first reinforcement section that has at least one projection of a first expandable polymeric material secured to it; and a separate second reinforcement section mated with the first reinforcement section, the second reinforcement section being configured to include at least one cavity, into which the at least one projection penetrates upon mating, and at least one aperture defined therein through which the expandable material flows during expansion and where it will remain upon curing of the material, thereby causing the first reinforcement section to be coupled with the second reinforcement section.

A vehicle frame structure includes a pair of side members located on both right and left sides of a vehicle, each of the pair of side members extending both forward and rearward of a cabin along a respective side of the cabin. As each of the pair of side members extends in a longitudinal direction at a substantially uniform height, a load applied to one end can be transferred toward the other end.

The present invention relates to a sandwich plate element connection system (1, 2, 3, 4, 5), comprising two sandwich plate elements (100) and a connection element (200, 400, 500, 600, 700) connecting said two sandwich plate elements (100) by means of an adhesive joint (250) and defining two recesses (210, 220, 410, 420, 510, 520, 530, 610, 620, 630, 640). The connection element (200, 400, 500, 600, 700) comprises a first part (200:1, 400:1, 500:1, 600:1, 700:1) and a second part (200:2, 400:2, 500:2, 600:2, 700:2) connected to each other by a snap fit joint (270, 470, 570, 670, 770), for formation of at least one of said two recesses (210, 220, 410, 420, 510, 520, 530, 610, 620, 630, 640). The adhesive joint (250) comprises an adhesive (260). A chassis (10) for a vehicle comprising a sandwich plate element connection system (1, 2, 3, 4, 5) and a method (20) for connecting two sandwich plate elements (100) are also provided.

A component comprising a sheet-like reinforcing component having a first stiffness and a sheet-like attachment made of an attachment material having a second stiffness, wherein the first stiffness is higher than the second stiffness, wherein the planar reinforcing component has an upper and lower side and the attachment is connected at least to the upper or lower side of the planar reinforcing component in a first partial area of the planar reinforcing component.

A cowl cross bar assembly of reduced weight and increased stiffness. The cowl cross bar assembly includes a first pipe and a second pipe which are hollow and disposed laterally inside a chassis, pipe caps coupled to one end of the first pipe and the second pipe, and pipe stiffeners accommodated in the first pipe and the second pipe and configured to absorb collision energy generated in a collision of a vehicle.

A trim component for an interior of a motor vehicle has a film and has a carrier from a thermoplastic plastics material. The film has a relief structure, the carrier has a lattice structure having lattice members, and the carrier is back-molded on a rear side of the film such that the lattice members are connected in a materially integral manner to the rear side of the film.

The present disclosure is directed to a tailgate protector for a vehicle, wherein the protector comprises a pressure absorbent material which has been attached to a body of the protector with an adhesive, wherein the material having pressure absorbent property is a fabric or rubber and provides a soft padded area for protecting a user from injury or discomfort, and the adhesive is a pressure sensitive adhesive comprising styrene, and the body is formed from a resin.

A support structure in a framework construction is provided. The support structure includes a first and a second rod of an axle support of a motor vehicle, a positioning element, and a first and a second fiber winding. The positioning element fixes an alignment of the first rod relative to an alignment of the second rod. A first support section of the positioning element is drawn by the first fiber winding in the direction of a support section of the first rod, and a second support section of the positioning element is drawn by the second fiber winding in the direction of a support section of the second rod in order to hold the first and second rods in the fixed alignment relative to each other by a frictional connection.

A vehicle energy absorbing system for a high-speed, small-overlap impact, comprising: lobes (12) spaced intermittently along a vehicle rail (1), wherein the lobes (12) include an impact arm (14), a reactionary arm (16), and a base (22), wherein a shape of the base (22) is complimentary to a shape of the vehicle rail (1) and wherein the impact arm (14) and the reactionary arm (16) protrude outwardly from the base (22) and the vehicle rail (1), wherein a channel (20) is formed in the space between the base (22), the impact arm (14), and the reactionary arm (16), wherein the channel (20) extends through the lobe (12) from end to end.

An electric drive unit for a wheel of a motor vehicle, including an electric motor for driving a drive shaft joined to the wheel in a manner resistant to rotation. The drive shaft is disposed coaxial to the rotor of the electric motor and is joined thereto in a rotation-resistant manner. The drive shaft is joined to the rotor of the electric motor in a rotation-resistant and axially moveable manner via a bearing.