Please substitute the new Abstract submitted herewith for the original Abstract:

A front-end structure for a vehicle has a wheelhouse, a rocker panel, a support carrier which is connected to the wheelhouse and the rocker panel and which extends at an angle, an A-pillar, a door flange and a connecting portion connecting the A-pillar to the door flange. The connecting portion extends, at least in portions, substantially parallel to the support carri er.

Please substitute the new Abstract submitted herewith for the original Abstract:

A front-end structure for a vehicle has a wheelhouse, a rocker panel, a support carrier which is connected to the wheelhouse and the rocker panel and which extends at an angle, an A-pillar, a door flange and a connecting portion connecting the A-pillar to the door flange. The connecting portion extends, at least in portions, substantially parallel to the support carri er.

A front part assembly for a mobility device, a front-part-integrated assembly including the same, and a process of assembling the same are disclosed. The front part assembly includes a bumper, a fender, and a hood, which are integrally formed, wherein the bumper and the fender are connected to each other to define an internal space therebetween, and the hood is rotatably connected at a front end thereof to the bumper such that a rear end of the hood is rotated vertically to open and close the internal space. The front-part-integrated mobility device includes the front part assembly and a frame, which is coupled to the front part assembly and is coupled to a cowl and a rear fender. The method includes rotating the hood to open the internal space, coupling the front part assembly to the frame, and rotating the hood to close the internal space.

A structural component serves as a container for a vehicle. The structural component comprises a trough-shaped container section, an edge region, and fastening elements that are provided in the edge region. The container section forms a compartment and defines a bottom region and two or more wall regions, which are at least sectionally inclined with respect to the bottom region. The two or more wall regions are arranged between the bottom region and the edge region. The fastening elements are arranged and distributed around the container section. The container section and the edge region are formed of an injection moldable fiber reinforced thermoplastic material. The structural component at least sectionally has a porous internal structure that is formed by foaming the thermoplastic material.

A vehicle body rear structure of an electric vehicle may include: a high-voltage device arranged in a rear portion of the electric vehicle, wherein the high-voltage device is included in an electric powertrain of the electric vehicle or is electrically connected to the electric powertrain, and the high-voltage device is operable on a voltage over AC 30 or DC 60 volts; a low-voltage device arranged rearward of the high-voltage device at a same height level as the high-voltage device, wherein the low-voltage device is operable at a voltage lower than AC 30 or DC 60 volts; and a crossmember passing between the high-voltage device and the low-voltage device.

A vehicle body rear structure of an electric vehicle may include: a high-voltage device arranged in a rear portion of the electric vehicle, wherein the high-voltage device is included in an electric powertrain of the electric vehicle or is electrically connected to the electric powertrain, and the high-voltage device is operable on a voltage over AC 30 or DC 60 volts; a low-voltage device arranged rearward of the high-voltage device at a same height level as the high-voltage device, wherein the low-voltage device is operable at a voltage lower than AC 30 or DC 60 volts; and a crossmember passing between the high-voltage device and the low-voltage device.

A lightweight cowl crossbar includes: a first cowl crossbeam located on a first side frame disposed at a first side of a vehicle body; a second cowl crossbeam fastened to the first cowl crossbeam and fixed to a second side frame disposed at a second side of the vehicle body; a support leg located on the second cowl crossbeam and configured to be supported by the vehicle body, and a drawing block part located on a region where the first cowl crossbeam and the second cowl crossbeam overlap.

A rear vehicle-body structure is provided that can absorb a rear-end collision load by a short frame region on a vehicle-body rear side. Embodiments include a rear side frame having a rear-side breaking frame section including a rear-side breakage starting portion on a rear side among breakage starting portions disposed at intervals in a front-rear direction, a front-side breaking frame section including a front-side breakage starting portion on a front side and at which the direction of breakage is opposite from the direction of breakage at the rear-side breakage starting portion, and a middle frame section between the rear-side breakage starting portion and the front-side breakage starting portion. The axial proof stress of the rear-side breaking frame section is lower than the axial proof stress of the front-side breaking frame section; and the middle frame section includes beads at a predetermined interval in an axial direction.

A rear vehicle-body structure is provided that can absorb a rear-end collision load by a short frame region on a vehicle-body rear side. Embodiments include a rear side frame having a rear-side breaking frame section including a rear-side breakage starting portion on a rear side among breakage starting portions disposed at intervals in a front-rear direction, a front-side breaking frame section including a front-side breakage starting portion on a front side and at which the direction of breakage is opposite from the direction of breakage at the rear-side breakage starting portion, and a middle frame section between the rear-side breakage starting portion and the front-side breakage starting portion. The axial proof stress of the rear-side breaking frame section is lower than the axial proof stress of the front-side breaking frame section; and the middle frame section includes beads at a predetermined interval in an axial direction.

A reinforcement frame (1) for a battery pack (2) of an electric or hybrid vehicle (37), the battery pack including a plurality of battery cells lying on and secured to a shield element, the reinforcement frame including at least: a reinforcement frame fastening portion (3) provided to be secured to both the battery pack and the body of the vehicle, and a reinforcement frame hollow portion (4) provided to surround at least the battery cells.