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 vehicle body structure including: a pair of left and right first vehicle body frame members manufactured by die casting, and are provided at vehicle transverse direction outer sides of a vehicle, and are provided so as to extend in a vehicle longitudinal direction; a pair of left and right second vehicle body frame members that are made of steel plates, and are joined to front end portions of the first vehicle body frame members from substantially vehicle transverse direction inner sides, and are provided so as to extend in the vehicle longitudinal direction; and projecting portions that are provided at the first vehicle body frame members at further toward a vehicle rear side than positions where the second vehicle body frame members are joined to the first vehicle body frame members, and that project-out toward a vehicle cabin inner side with respect to the first vehicle body frame members.

A structure for an upper part of vehicle body includes: right and left side rail members extending in a vehicle front-rear direction; a roof member having right and left end portions in a vehicle width direction supported by the right and left side rail members, respectively; and gussets connected at one ends thereof to the respective side rail members, each extending from one end upwardly and inwardly in the vehicle width direction, and connected at the other end thereof to the roof member.

A vehicle includes a vehicle body, a power storage device, and a joining unit. The power storage device includes a power storage module and a power storage case. The power storage case includes a case body and a plurality of bottom surface reinforcing members. The joining unit includes a first bracket joined to a first end of a first bottom surface reinforcing member, a second bracket joined to a second end of a second bottom surface reinforcing member, and a third bracket joined to a second end of a third bottom surface reinforcing member. No joining unit is provided at a second end of the first bottom surface reinforcing member.

A vehicle body structure includes an inner sill member, an outer sill member and a first reinforcement bracket. The inner sill member has an inner upper flange, a horizontally extending section and an inner lower flange extending downward from the horizontally extending section. The outer sill member has an outer upper flange and an outer lower flange. The inner upper flange and the outer upper flanges are fixedly attached to one another. The inner lower flange and the outer lower flanges are fixedly attached to one another defining a sill structure with hollow interior. The first reinforcement bracket is disposed within the hollow interior and has an outboard portion fixedly attached to the outer sill member and an inboard portion fixedly attached to the horizontally extending section of the inner sill member.

Disclosed is a wheelhouse structure of a vehicle, including an inner panel with an inner flange that includes a straight portion, and an outer panel with an outer flange sized and shaped to interface with the inner flange along at least the straight portion. The outer panel includes a stiffening bead situated forward from, or proximate to a forward portion of, the straight portion. The wheelhouse structure also includes a plurality of joins coupling the inner flange to the outer flange, and a gap in the plurality of joins that is aligned with the first stiffening bead. When a rear portion of the wheelhouse structure is subjected to a loading force in a forward direction, the outer panel bends in locations proximate to the stiffening bead more easily than in locations remote from the stiffening bead.

A vehicle body frame includes a first vertical bead portion (38) adjacent to an inner ridge line (54), a first strain development region (39) defined by an arc (67) of a minimum distance (L1) between the first vertical bead portion (38) and an outer ridge line (55), a second vertical bead portion (41) adjacent to the outer ridge line (55), and a second strain development region (42) defined by an arc (68) of the minimum distance (L1) between the second vertical bead portion (41) and the inner ridge line (54).

A vehicle body structure using carbon fiber reinforced plastics (CFRP) may include a cowl member extending along a width direction of a vehicle, a front pillar extending along a height direction of the vehicle, and a cowl side member of which an inner side is coupled to a front end of the cowl member and an outer side is coupled to the front pillar member.

Aspects of the disclosure relate to passenger or cargo vans. Features include the structure and assembly process using a framing structure which defines and supports a rearward compartment. In certain embodiments, the framing structure can be formed as modular subpanels which can be easily assembled while also providing superior strength and weight characteristics. In certain embodiments, specialized joints are arranged to connect the subpanels. Exterior shell portions and optionally windows can be mounted to the framing structure to form a rearward compartment.

A node to panel interface structure for use in a transport structure such as a vehicle is disclosed. In an aspect, the node includes a base, first and second sides protruding from the base to form a recess for receiving a panel, ports for adhesive injection and/or vacuum generation, one or more adhesive regions disposed on a surface of each side adjacent the panel, and at least one channel coupled between the first and second ports and configured to fill the adhesive regions with an adhesive, the adhesive being cured to form a node-panel interface. The node may be additively manufactured. In an exemplary embodiment, the node may use sealant features for including sealants that border and define the adhesive regions, and that may hermetically seal the region before and after adhesive injection. In another embodiment, the node may include isolation features for including isolators for inhibiting galvanic corrosion. In another aspect, adhesive may be filled serially on the adhesive regions on the first side and then on the adhesive regions on the second side. Adhesive may alternatively may be filled in parallel, or concurrently, on the adhesive regions of both sides.