A component, which may be an automotive chassis structure, includes first and second sub-part main bodies. The first sub-part main body is formed of a first material, and the second sub-part main body is formed of a second material. The first material is a steel alloy, and the second material is aluminum or an aluminum alloy. A transition layer is attached to and contacts the first sub-part main body. The transition layer is formed of a third material, where the third material contains at least a majority of copper. A mixed layer is disposed between the transition layer and the second sub-part main body, and the mixed layer is formed of a mixture of the second material and the third material. A disclosed method includes forming the component by friction stir welding the transition layer to the second sub-part main body.

A vehicle support member that is die-cast includes a fixing portion configured to fix a device arranged in a power unit room, and a fixing-portion connecting rib connecting the fixing portion and an outer peripheral wall supported on a pair of front side members constituting a vehicle body and located on an outer side of the power unit room in a width direction of a vehicle.

A motor vehicle includes a floor subassembly and a storage cell subassembly. The floor subassembly is an integral part of a body of the motor vehicle. In other words, the floor subassembly is part of the body shell. The storage cells of the storage cell subassembly are disposed in the floor subassembly. The storage cells are accommodated in hollow-cylinder chambers of a multi-chamber hollow cylinder structure extending in the vertical direction of the vehicle.

In an automobile hood, sufficient panel rigidity and dent resistance are secured while achieving weight reduction. Automobile hood 1 has a panel 2, a reinforcing member 3, and a joint 4 that joins the panel 2 and the reinforcing member 3. The reinforcing member 3 includes a structure formed from a plurality of units 7 having a hexagonal annular shape disposed in a close-packed arrangement. Unit 7 has a floor 11, inclined wall 12 and top plate 13. The floor 11 is adjacent to the panel 2. Top plate 13 and panel 2 are separated from each other. The inclined wall 12 is arranged between the floor 11 and the top plate 13. A hexagonal annular first ridge line 31 of the unit 7 is located between the inclined wall 12 and the floor 11. A length L1 of one side of the first ridge line 31 is 40-75 mm.

A vehicle floor board includes a first plate, a second plate, a main body material, a projection, and an anti-slipping member. The first plate and the second plate are substantially flat and are disposed substantially parallel to each other with an interval therebetween. A space between the first plate and the second plate is filled with the main body material. The projection is provided on the first plate and projects in a direction away from the second plate. The anti-slipping member is provided on a surface of the first plate and at least partially covers the projection. The surface of the first plate races away from the second plate.

A tailgate system, comprising: (i) a tailgate door configured to pivotally engage a rear cargo area of a body of a vehicle in between a closed position and an open position; and (ii) a bed extension pivotally engaged to the tailgate door and configured to pivot from a closed position to one or more open positions, wherein the bed extension includes a plurality of removable panels.

A structural assembly for a pickup truck sidewall includes, among other things, a C-pillar, a belt rail extending rearward from the C-pillar, and a truss spanning from the belt rail to the C-pillar. A method of structurally supporting a sidewall of a pickup truck includes the steps of securing a first end portion of a truss to a belt rail that extends rearward from a C-pillar of the pickup truck, and securing an opposite, second end portion of the truss to a C-pillar.

A vehicle component for a vehicle has a component body which extends longitudinally in a longitudinal direction, wherein the component body has deformation zones which are spatially distributed in the longitudinal direction and are formed in the component body of sheet metal material. At least two locally distributed and spaced-apart deformation zones have different tensile strengths configured to influence a deformation course of the component body upon a force acting on the component body.

A chassis platform module for an electric vehicle may include: a frame part having a battery module coupled thereto, and including a plurality of members assembled to each other; a first support part extending from one side of the frame part in a longitudinal direction thereof, having a front wheel chassis module mounted thereon, and including a connection member assembled to the frame part; a second support part extending from another side of the frame part in the longitudinal direction thereof, and having a rear wheel chassis module mounted thereon; and a connector part including a plurality of connector members assembled between the plurality of members of the frame part or assembled to the frame part and the first support part so as to connect the plurality of members to the connection member.

The disclosure relates to the technical field of vehicle body structures, and in particular provides a vehicle and a front longitudinal beam rear section member of the vehicle. The front longitudinal beam rear section member comprises a base part, and a first part and a second part which are located on two sides of the base part in a width direction of the vehicle, the vehicle is provided with a traction battery, and the traction battery is at least connected to the base part; the vehicle comprises a cross beam located behind the front longitudinal beam rear section member in a length direction of the vehicle, and the base part is connected to the cross beam; and the vehicle comprises two rocker panels separately arranged in the width direction of the vehicle, and each of the first part and the second part is connected to the rocker panel on a corresponding side, wherein at least some of the base part, the first part and the second part are of an integrally-formed structure. With such a configuration, difficulties in the manufacture of different parts themselves and in matching between parts are reduced, and the product consistency of front longitudinal beam rear section members is improved.