We disclose a chassis for a vehicle, comprising an interconnected framework comprising a plurality of tubular sections, and at least one sheet bonded to the framework, wherein the tubular sections are of a non-ferrous metallic composition. The non-ferrous tubular sections have a very thin wall; generally, these sections are made by extrusion, which currently allows for wall thicknesses no thinner than about 2.5 mm. We prefer the wall thickness to be about this level, and ideally no greater than 3 mm. Such a thin-walled tube would usually imply a lower resistance to buckling, but as part of the structural element defined above, we have found that the tube does not buckle and in fact has an impact response that is superior to other alternatives. We therefore prefer that the tubular sections have a profile for which the ratio of the minimum area moment of inertia of its cross section to the square of the unsupported length of the section is less than 2 mm.sup.2. Another way of expressing this approach is to consider the aspect ratio of the tubular section, i.e. the ratio of its length to its wall thickness. Sections with a high aspect ratio will be more prone to buckling. Given the low elastic modulus of Aluminium, a low aspect ratio has been preferred, but according to the present invention a higher aspect ratio of more than about 100 or 150 is feasible.

Provided is a vehicle hood that allows a reduction in thickness of an outer panel while providing stiffness of the outer panel. A vehicle hood includes an outer panel, an inner panel, and a plurality of adhesive components. The inner panel has a plurality of beads. Each bead has a support part that supports each adhesive component. The adhesive components are provided on the support parts so as to be intermittently aligned along a specific direction. A support-part interval between the support parts adjacent to each other in an intersecting direction is smaller than an adhesive-component interval between the adhesive components adjacent to each other on the support parts.

In a method for connecting an attachment part to a structural part of a bodywork, a wall of the structural part is formed to at least partly encircle a region of the structural part. A form element is arranged to a main body of the attachment part. The attachment part is placed in the region of the structural part such that the form element touches the wall of the structural part, and the attachment part is pushed into the region, thereby causing the form element to move in relation to the main body of the attachment part until reaching an aperture in the wall of the structural part so that the form element moves into the aperture and is arranged therein to thereby position the attachment part in the region of the structural part.

A vehicle pillar structure includes a pillar upper portion that extends along a vehicle height direction on a vehicle width direction outer side and is made of a transparent resin, and a pillar lower portion that is disposed on a the vehicle height direction lower side of the pillar upper portion, is made of metal, and is joined to the pillar upper portion at a joint portion. The joint portion between the pillar upper portion and the pillar lower portion includes an outer joint portion positioned on the vehicle width direction outer side, and an inner joint portion positioned on a vehicle width direction inner side. A height of the outer joint portion and a height of the inner joint portion are different.

An assembly for a vehicle body includes the following components: a sill, roof frame, hinge pillar, outer shell and inner shell. The assembly is characterized by being very rigid and very firm, and having a high degree of structural possibilities whilst being relatively light in weight. The sill and the roof frame are formed by hollow profiles. The hinge pillar is made from an extruded fibrous composite. The sill, the roof frame and the hinge pillar are surrounded on the outer side and the inner side, at least partially, by the outer shell and the inner shell, such that the assembly components form a composite unit.

Three structural components meet at a structural node for a motor vehicle bodywork. The structural components are fitted together from at least one outer part and one an inner part in each case. A reinforcement part is arranged in a hollow space formed in one of the structural components and is fixed to the inner part of at least a first structural part and the outer part of at least a second structural part.

A workpiece includes a plurality of knots and webs, which are formed in one piece, of a sheet metal, in particular a steel plate. Each web extends between two openings from one knot to another knot, and at least three webs meet at each knot. A plurality of the webs has a cross section, which includes at least one hardened and one unhardened area.

A modular trailer system comprising a plurality of curved panels, where each panel is elongate and has a first side with an angled projection and an opposing second side with an angled slot such that the angled projection of one panel is capable of fitting into the angled slot of another panel, allowing the panels to join together to form a continuously curved surface. The modular trailer system may further comprise a first top rail with an angled slot capable of receiving the angled projection of one of the plurality of curved panels and a second top rail with an angled projection capable of fitting into the angled slot of another of the plurality of curved panels. The plurality of curved panels, first top rail, and second top rail may be assembled together to form an elongate trailer body with a partially circular cross section, such that the trailer body has a continually rounded bottom and sides and an open top.

A vehicle body with a shell-type design includes at least one lateral frame, a tailgate frame which is connected to a node of the vehicle body by the lateral frame, and a reinforcing component which extends from the tailgate frame into the lateral frame. The tailgate frame and the lateral frame are each composed of an upper shell and a lower shell, and the reinforcing component is arranged between the upper and lower shells of the tailgate frame and the lateral frame. A hinge reinforcement for a hinge of a tailgate is formed in the reinforcing component in the region of the tailgate frame.

A motor vehicle includes a body, which body has at least two rear longitudinal members each forming a primary load path for collision forces, wherein the motor vehicle has a rear-end module that can be pre-assembled as a sub-assembly, which rear-end module can be connected to the body as part of the vehicle assembly after the completion of the body-in-white and has at least a supporting structure for fastening chassis components of a rear wheel suspension and a beam structure extending from the supporting structure toward the motor-vehicle rear for absorbing collision forces, wherein the supporting structure and the beam structure form at least one second load path for collision forces.