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 housing and trailer system comprising a trailer and a housing. The housing includes a lower housing and an upper housing and may be positioned on friction-reducing members that reduce friction between the housing and trailer. The reduction of friction facilitates the housing to slide more efficiently on the trailer. A safety lever and linkage system operates to safely move roof support structures and raise/lower the upper housing. An adjustable cargo system is attached to a roof on the housing. The adjustable cargo system is adjustable to receive and/or secure different sizes of cargo.

A housing and trailer system comprising a trailer and a housing. The housing includes a lower housing and an upper housing and may be positioned on friction-reducing members that reduce friction between the housing and trailer. The reduction of friction facilitates the housing to slide more efficiently on the trailer. A safety lever and linkage system operates to safely move roof support structures and raise/lower the upper housing. An adjustable cargo system is attached to a roof on the housing. The adjustable cargo system is adjustable to receive and/or secure different sizes of cargo.

A load impact management system for a vehicle includes a plurality of cross-vehicle support members extending from a first side of the vehicle to a second side of the vehicle opposite the first side of the vehicle, a shock tower spaced apart from the plurality of cross-vehicle support members and fixed to the vehicle frame rail, a first structural member extending along a first plane, a second structural member extending along a second plane separate from the first plane, and a third structural member extending along a third plane separate from the first and second planes. The first structural member defines a first load path between the center tunnel and the shock tower, the second structural member defines a second load path between the center tunnel and the shock tower, and the third structural member defines a third load path between the center tunnel and the vehicle frame rail.

A method is provided for connecting hollow profiles (1-4) in a joint (10) to produce a load-bearing structure (5). The method includes placing ends of hollow profiles (1-4) in a mold and pressing the ends together with at least one semi-finished product to connect the ends of the hollow profiles to the semi-finished product.

A vehicle outer plate panel includes: a transparent resin plate that is formed into a prescribed shape through pressure molding and is attached to a vehicle so as to constitute an outer wall of a body; and a decorative layer that is formed on at least a part of the transparent resin plate through screen printing such that the transparent resin plate is decorated therewith. A method of producing an vehicle outer plate panel is also disclosed.

A method for fabricating a joint designed to connect tubes for a space frame, where a space frame may be a vehicle chassis, is provided. The method may generate joints with variable geometry and fine features which may reduce production costs, reduce production time, and generate joints configured for highly specific applications. The joint may include centering features which may create a space between a surface of the tube and a surface of the joint through which adhesive may flow.

A vehicle chassis is provided. The vehicle chassis may comprise one or more vehicle chassis modules or chassis substructures that are formed from a plurality of customized chassis nodes and connecting tubes. The customized chassis nodes and connecting tubes may be formed of one or more metal and/or non-metal materials. The customized chassis nodes may be formed with connecting features to which additional vehicle panels or structures may be permanently or removeably attached. The vehicle chassis modules or chassis substructures may be interchangeably and removeably connected to provide a vehicle chassis having a set of predetermined chassis safety or performance characteristics.

A structural part for a body in white of a vehicle includes a frame formed by at least two branches connected to one another in at least one connecting zone and separated from each other by at least one gap in a zone of least stress. The frame is made of a first composite material comprising a plurality of continuous fibers impregnated with a first polymeric material. A body is integral with the frame extending in the gap and connecting the two branches in the zone of least stress. The body is made of a second material that is different from the first composite material and comprises at least a second polymeric material, wherein the body is integral with the branches.

A vehicle body structure satisfies at least one of the following (A), (B), and (C): (A) an adhesive amount per unit area of a first adhesive in a second adjacent part is smaller than an adhesive amount per unit area of the first adhesive in a first adjacent part; (B) an adhesive amount per unit area of a panel adhesive in a second panel adjacent part is smaller than an adhesive amount per unit area of the panel adhesive in a first panel adjacent part; and (C) an adhesive amount per unit area of a second adhesive in a stacking adjacent part is smaller than an adhesive amount per unit area of the second adhesive in a non-stacking adjacent part.