A structural member for a vehicle includes an outer panel defining a U-shaped channel. The outer panel is formed from a first material. The structural member further includes a reinforcement panel defining a U-shaped channel. The reinforcement panel is formed from a second material different than the first material and is formed to attach to the outer panel. The structural member also includes an inner panel defining a U-shaped channel. The inner panel is formed from a third material different than the first and second materials and is formed to attach to the reinforcement panel such that the outer panel, reinforcement panel, and the inner panel are oriented along an axis and span an entire length of each of the U-shaped channels.

A vehicle body structure includes: a first frame that is formed of a first material and has a closed cross section; and a second frame that is formed of a second material and has a closed cross section. The first frame and the second frame are aligned with each other in a vehicle longitudinal direction. The second frame has higher tensile strength and is lighter than the first frame. In a front cross-sectional view of the vehicle, a second center associated with the second frame is located on an outer side in a vehicle width direction from a first center associated with the first frame with respect to vehicle center.

A door hinge mount of a side external panel for a vehicle, may provide the door hinge mount, capable of being formed of a material, requiring low initial investment expenses, and securing the same level of rigidity as in the case where a steel material is used.

The invention concerns a method for producing a hybrid-structure part of a motor vehicle, comprising shaping of a sheet of metallic material, the provision of a sheet of composite material, application of a layer of connecting material on a face of said metallic material sheet or on a face of said composite material sheet, the shaping of a hybrid element by shaping said composite material sheet to the shape of said metallic material sheet and joining the composite material sheet to the metallic material sheet by means of said connecting material layer, and the production of ngidification elements by overmoulding using a polymer material.

A composite material with an insert-molded attachment steel is provided. The composite material includes a plurality of burring apertures, each of which has a flange in one direction on the attachment steel and is inserted between fibers. A resin is then introduced between the fibers in each burring aperture and external to the flange.

An axle carrier for a motor vehicle is disclosed having at least two attachment points, a metallic upper shell and a lower shell of fiber composite material coupled to the metallic upper shell. A first load path extending through the metallic upper shell between the at least two attachment points in an edge region, and a second load path shorter that the first load path extending through the lower shell.

A thermally insulated floor for a trailer includes a layer of parallel support beams. Each support beam is oriented in a direction substantially perpendicular to a forward direction of the trailer. A substantially planar panel of thermally insulating material is disposed on and supported by the layer of parallel support beams. A substantially planar layer of extruded aluminum is disposed on and supported by the panel of thermally insulating material. The support beams, the panel of thermally insulating material, and the layer of extruded aluminum are secured together.

A metallic joint 18 having a substantially T-shaped cross section configured to join an inner surface in a vehicle width direction of a FRP side wall member 13 extending in a front-rear direction and an outer end in the vehicle width direction of a FRP standing wall member 14 extending in the vehicle width direction includes left-right joining surfaces 18b and 18c joined to an inner surface in the vehicle width direction of the side wall member 13, and a front-rear joining surface 18a which extends inward in the vehicle width direction from an intermediate portion in the front-rear direction of the left-right joining surfaces 18b and 18c and is joined to a front surface or a rear surface of the outer end in the vehicle width direction of the standing wall member 14.

Since a recess 11f configured to house an in-vehicle component 37 is formed on an outer surface of a first wall portion 11c of a FRP vehicle body panel 24, a metallic reinforcing member 32 is fitted to the recess 11f and is fixed by adhesive, the reinforcing member 32 can compensate for a decrease in strength of the first wall portion 11c caused by the recess 11f. Since an outer peripheral portion of the reinforcing member 32 is mechanically fastened to the vehicle body panel 24 with rivets 33 and 35, the outer peripheral portion serving as a starting point of peeling of an adhesive is reinforced by mechanical fastening so that the vehicle body panel 24 and the reinforcing member 32 can be firmly integrated.

A roof frame for a motor vehicle is disclosed. At least one partial element of the roof frame is massive-formed, preferably forged, from a light metal blank.