An object of the present invention is to provide an innovative and highly practical connection member for a vehicle structure. The present invention is a connection member for a vehicle structure equipped with at least two connection sections (2) that are used in the vehicle structure and that connect appropriate sites within the vehicle structure, the connection member for a vehicle structure being characterized in having a layered structure section (1) configured by impregnating a layered body (4) in which a plurality of fiber bodies (3) have been layered with a matrix resin and curing the impregnated layered body, and employing, as the fiber bodies (3), bodies in which bundles of unidirectionally aligned carbon fibers (5) have been interwoven with thermally fusible fibers (6).

This vehicle of monocoque construction is formed by fastening together resin parts which are an upper body integrally made of a transparent thermoplastic resin composition, a lower body integrally made of a thermoplastic resin composition and a floor integrally made of a thermoplastic resin composition, wherein the vehicle is characterized in that the lower body is provided with a flange part rising up from the entire perimeter of the bottom surface and, in the center of the bottom surface, a convex rib part that continues rearward from the front of the vehicle, and the upper body and the floor being fastened to the flange part and the convex rib part of the lower body. In so doing, there can be provided a vehicle which is lightweight, affords a good field of view during driving, is simple in construction, and has the necessary rigidity.

The invention relates to a process for the production of multishell composite-material components, comprising the following steps: a) insertion of at least one first component (1) into an injection mold and optionally subjecting the first component (1) to a forming process, b) injection of at least one fixing element (4) onto at least one side (5) of the first component (1), c) insertion of at least one second component (2) into the injection mold and optionally subjecting the second component (2) to a forming process, d) bonding of the first component (1) to the second component (2) by way of the side (5) which has the fixing element (4), where a matrix material (6) is injected through the second component (2) onto and/or into the fixing element (4).

An assembly of vehicle components includes first and second components abutting each other. At least one of the first and second components includes a non-metallic material. The first and second components respectively include overlapping first and second apertures. The assembly further includes a joining component extending through the first and second apertures. The joining component has a support body and an outer body at least partially encasing the support body. The outer body includes a polymeric material. The joining component clamps the first and second components between first and second flanges of the outer body, and the support body extends into at least one of the first and second apertures.

An automobile vehicle body and an automobile vehicle body manufacturing method is provided in which a metal joint is divided into an upper joint and a lower joint. The upper joint includes an upper wall which is fitted into a side member, a vehicle width direction inner wall and a vehicle width direction outer wall, and a lower joint includes a lower wall which is joined to a lower face and an outside face of a vehicle body floor, and the vehicle width direction outer wall, and therefore, the vehicle width direction outer wall of the upper joint is fastened to the vehicle width direction outer wall of the lower joint by a first bolt, and the vehicle width direction inner wall of the upper joint is fastened to an inside face of the side member by a second bolt.

A fiber-reinforced vehicle body structure includes a first frame made of fiber-reinforced plastic or carbon fiber-reinforced plastic and having multiple sections, and a second frame that continuously extends from any one of the multiple sections of the first frame.

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.

An additively manufactured node is disclosed. A node is an additively manufactured (AM) structure that includes a feature, e.g., a socket, a channel, etc., for accepting another structure, e.g., a tube, a panel, etc. The node can include a node surface of a receptacle extending into the node. The receptacle can receive a structure, and a seal interface on the node surface can seat a seal member between the node surface and the structure to create an adhesive region between the node and the structure, the adhesive region being bounded by the node surface, the structure, and the seal member. The node can also include two channels connecting an exterior surface of the node to the adhesive region. In this way, adhesive can be injected into the adhesive region between the node and the structure, and the adhesive can be contained by the seal member.

A structural member (10) comprising: (i) a first carrier (12A) and a second carrier (12B), each carrier including a plurality of interconnecting ribs (16), each carrier further including one or more projections (28) extending from exterior walls (30) of each carrier; (ii) one or more secondary members (14) secured to one or more surfaces of each carrier; and (iii) an adhesive material (32) disposed on the first carrier (12A), the second carrier (12B), or both, wherein the first carrier (12A) and the second carrier (12B) are bonded to each other via the adhesive material (32).

A vehicle load-bearing structure includes a cell made of composite materials and composed of a plurality of components joined to each other by at least one joining system to form a single structure; the cell is made up of a number n of components between 3 and 8, that is 3<n<8.