A vehicle comprising a rear seat arrangement for a rear seat row and comprising a spare wheel recess arranged in the rear region of the vehicle—relative to a vehicle longitudinal axis—a spare wheel for the vehicle being received in said spare wheel recess. A rigid carrier portion, which is fixed to the body, of a supporting structure of the rear seat arrangement is located with a lower face facing the cover of the spare wheel recess above a reference plane or extends along a reference plane, wherein the reference plane runs at an angle α to the wheel plane on the front face of the spare wheel and the wheel plane intersects a cutting line which is located in a vertical plane running perpendicular to the vehicle longitudinal axis and tangential to the running surface of the spare wheel received in the spare wheel recess.

A chassis for a passenger car includes two main longitudinal chassis beams which are connected to one another via a bumper cross member. A support arrangement extends between the two beams and is supported on a central tunnel. The support arrangement forms a load path in an event of a collision-related force being applied to the passenger car where above and/or below the support arrangement an installation space region is provided for accommodating a component or unit in need of protection. The support arrangement includes a strut which extends in a region of a center of the passenger car between the two beams and which forms a protective device which transmits impact forces forwards to the central tunnel. The strut has a first longitudinal section that is deformable in a targeted energy-absorbing manner and a second longitudinal section which functions as a rigid beam.

A vehicle body rear part structure for a vehicle includes a side frame, a subframe disposed below the side frame, and a vehicle body frame member disposed on a middle side in the vehicle body front-rear direction with respect to the subframe. The vehicle body frame member includes: a vertical frame offset outwardly in the vehicle width direction with respect to the subframe; and a lateral frame extending inwardly in the vehicle width direction from the vertical frame. A connecting portion is provided on the subframe. The connecting portion includes: an inclined portion extending while being inclined outwardly in the vehicle width direction, to face the vertical frame; and a widening portion widening inwardly in the vehicle width direction up to a position where the connecting portion linearly extends in the vehicle body front-rear direction from the inclined portion, to face the lateral frame.

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.

An embodiment component integration type rear lower includes a body frame having an end portion of a first side and an end portion of a second side and having a predetermined length, a front-rear connection member connecting a side sill at the end portion of the first side and connecting a rear side member at the end portion of the second side, a bush mounting member coupling a bush to the end portion of the first side, and a coupled torsion beam axle (CTBA) mounting member coupled to at least one of a CTBA, a chassis spring, or a shock absorber, the at least one of the CTBA, the chassis spring, or the shock absorber being engaged with the end portion of the second side.

A boarding/deboarding support structure includes a lower door having an upper end configured to be rotated and opened with respect to a bottom surface of a vehicle body, a lower trim located inside the lower door, the lower trim having an upper end configured to be rotated and opened with respect to a floor of the vehicle body, and an absorbing member having at least a portion supported by the lower door and a rear surface of the lower trim, the absorbing member being configured to absorb energy, wherein the lower trim is located between the floor of the vehicle body and an inner surface of the lower door, and wherein, when the lower door is opened, the absorbing member is deployed to be located between the lower trim and the lower door.

This vehicle body structure includes a power storage device which is disposed in a recessed part formed in a floor part of a vehicle, in which the power storage device includes a laminate in which a plurality of cells are laminated, a pair of side plates provided at both end portions of the laminate in a vehicle width direction, a rear plate disposed on a vehicle rear side in the laminate, and a support member fixing the power storage device to the vehicle and supporting it in a suspending manner, and the rear plate includes a protection part extending from a lower side thereof toward a vehicle front side and positioned below the laminate and the side plates.

A vehicle includes a vehicle body, and a reinforcement member extending along a vehicle cabin-side side portion to vehicle cabin-side peripheral portion of a rear wheel housing of the vehicle body to an opening edge of the vehicle body. The opening edge receives a rear lower portion of a rear door. The reinforcement member includes a projecting portion that defines two or more closed-section spaces respectively extending toward different locations of the opening edge.

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 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.