In a vehicle body structure configured to place a battery in a lower part of a cabin, the loading of a frontal crash and a rear end crash that may be applied to the battery is minimized. The vehicle body structure (1), comprises a pair of side sills (3) extending in a fore and aft direction on either side of a vehicle (2), a pair of front side frames (4) extending in the fore and aft direction along either side of a front part of the vehicle, and connected to front ends of the side sills at rear ends thereof, respectively, a pair of rear side frames (71) extending in the fore and aft direction along either side of a rear part of the vehicle, and connected to rear ends of the side sills at front ends thereof, respectively, a front subframe (6) attached to the front side frames, a rear subframe (72) attached to the rear side frames, and a battery (140) positioned in a region surrounded by the side sills, the front subframe and the rear subframe in plan view.

The four wheel vehicle uses an electric motor (142) for driving the vehicle and a battery unit (160) for supplying electric power to the electric motor. The lower chassis (5) of the vehicle includes a pair of front side frames (10) extending linearly in a fore and aft direction with an upward slant and a progressively increasing lateral mutual spacing from a front part thereof to a rear part thereof, a pair of rear side frames (12) connected to rear ends of the respective front side frames, and extending linearly in a fore and aft direction with an upward slant from a front part thereof to a rear part thereof in continuation of the corresponding front side frames in a mutually parallel relationship, and a plurality of cross members (14, 16, 18, 20, 22) connecting the side frames to each other.

A vehicle front structure includes: a front side member; a fender apron member having a front end portion connected to a front end portion of the front side member; a subframe mounting bracket assembly mounted to the front end portion of the front side member and the front end portion of the fender apron member; and a first subframe disposed under the front side member. In particular, the front end portion of the front side member and the front end portion of the fender apron member are connected side-by-side in a width direction of a vehicle.

A panel assembly structure for preventing a column dive, which includes a center floor panel including a center floor tunnel curved upward in a longitudinal direction of a vehicle, and a dash panel having an inclined lower end to be fastened to the center floor panel and including a dash tunnel formed at the inclined lower end of the dash panel, the dash tunnel being curved upward in a longitudinal direction of the vehicle to be connected to the center floor tunnel, may include a center floor tunnel upper member mounted on an upper surface of the center floor tunnel and expanded bilaterally from the center floor tunnel on an upper surface of the center floor panel.

A chassis frame module for an electric vehicle may include a chassis frame including a pair of side frames, a pair of inclined frames connected to front ends of the respective side frames, respectively, and a distance between the pair of inclined frames decreases toward the front, a front frame connected to the inclined frames, and a rear frame connected to rear ends of the pair of side frames, a battery disposed between the pair of side frames, and a plurality of wire assemblies disposed between the side frame and the battery and in a longitudinal direction of the side frame, and being configured to house a wire in an internal space thereof.

A vehicle frame may comprise a plurality of interlocking tab and slot frame members forming a three-dimensional structure. A custom vehicle frame construction may be specified, designed and built based on a purchaser's selection. The three-dimensional structure may comprise a tab and slot panel to which additional tab and slot frame members are attached. The tab and slot frame members may have an attachment device disposed thereon for attachment of a vehicle component selected by the purchaser of the vehicle frame.

In a vehicle, a floor member reinforcing member extends in a vehicle longitudinal direction within a closed cross-section portion that is formed by a floor member and a floor panel. The floor member reinforcing member intersects a second floor cross member as seen in plan view. Namely, a portion, that is reinforced by the floor member reinforcing member, of the floor member extends in the vehicle longitudinal direction so as to include a portion, that intersects the second floor cross member, of the floor member. Further, occurrence of bending due to collision load at the portion, that is reinforced by the floor member reinforcing member, of the floor member is suppressed. The reinforced portion of the floor member is displaced toward a vehicle obliquely upper front side following displacement of the second floor cross member toward a vehicle obliquely upper front side.

An automobile body and a method for manufacturing the same is provided in which a substantially rectangular windshield joining face is formed by a front roof arch, a front portion of roof side rails and a dash panel upper of a lower skeleton. Since the upper skeleton and the lower skeleton can be separated, there is the problem that a gap occurs between lower ends of the roof side rails of the upper skeleton and the vehicle width direction outer ends of the dash panel upper of the lower skeleton, and the windshield joining face is discontinuous. Extension parts are provided inward in the vehicle width direction from the lower ends of the roof side rails, and the vehicle width direction inner ends of the extension parts are connected to the vehicle width direction outer ends of the dash panel upper, thereby eliminating discontinuity of the windshield joining face.

An electric vehicle frame strut tower to body structure interface bracket is disclosed. An example electric vehicle disclosed herein includes a frame, a battery pack supported by the frame, a body coupled to the frame, a strut tower coupled to the frame to support the body and absorb road surface impacts on the electric vehicle, and a strut tower interface bracket to couple the strut tower to the body.

An active air curtain apparatus is provided. The apparatus includes a duct that is formed with a suction port, a discharge port, and an air flow path from the section port to the discharge port and that is mounted to the inner surface of a bumper of the vehicle. A flap having a plate shape is operated by being supported and guided by the duct and is configured to open and close the discharge port.