A rear vehicle-body structure comprises a rear-floor front part on which a rear seat is placed and which is inclined such that a front side thereof is located at a higher level than a rear side thereof, a right-and-left reinforcing extension having a rear end that is positioned on both sides, in a vehicle width direction, of the rear-floor front part. The right-and-left reinforcing extension extends forwardly and inwardly, in the vehicle width direction, from the rear end. The rear vehicle-body structure further includes a right-and-left second reinforcing extension provided on an outward side in the vehicle width direction of the right-and-left first reinforcing extension, and is configured to extend forwardly and outwardly in the vehicle width direction from a vicinity of the rear end of the right-and-left first reinforcing extension.

The present disclosure relates to a vehicle rear body structure in which a meeting section is constructed at an upper corner of a rear gate opening that is opened rearward in a body rear portion, and in the meeting section, a roof side rail that extends in a vehicle longitudinal direction in a body side portion and a rear header that extends in a vehicle width direction in the body rear portion meet. The vehicle rear body structure that improves rigidity of the body rear portion while suppressing relative displacement between the rear header and the roof side rail.

A vehicle rear structure includes: a rear sideframe disposed on either side in a rear of a vehicle body; and a rear subframe disposed under the rear sideframe, wherein a rear end of the rear subframe is disposed at the same position in the longitudinal direction as, or at a position posterior to, a rear end of the rear sideframe. The vehicle rear structure has better performance in transmitting an impact load at a rear impact with a vehicle than ever, to further improve performance in absorbing impact energy.

A subframe structure includes: a pair of right and left vehicle body side frames disposed at side portions of a vehicle body; a pair of right and left longitudinal members extending along the pair of right and left vehicle body side frames at positions centrally spaced apart in a vehicle width direction for a predetermined distance from the vehicle body side frames; and a rear cross-member extending in the vehicle width direction between longitudinally rear portions of the pair of right and left longitudinal members. The rear cross-member has a first attachment portion, an extension portion, and a second attachment portion. The first attachment portion is attached to the longitudinal member, the extension portion extends from the first attachment portion in a laterally outward and upward direction, and the second attachment portion is attached to the vehicle body side frame at a laterally outer end portion of the extension portion.

A vehicle side member includes: a main member portion which extends in a longitudinal direction of a vehicle; a front-side mounting portion which is one-piece construction with a front portion of the main member portion; a rear-side mounting portion which is one-piece construction with a rear portion of the main member portion; and a damper mounting portion which is one-piece construction with the main member portion, and in which a top end of a damper is received and mounted.

Shock absorber assembly structures are disclosed. An example shock absorber disclosed herein includes a shock absorber mount coupled to an end of the shock absorber, the shock absorber mount including a recess to receive a locating rib of a vehicle body, and an aperture to receive a fastener to couple the shock absorber mount to an attachment boss of the vehicle body.

A vehicle having a reinforcement brace includes, among other things, an aft structure, a passenger side strut, a driver side strut, a passenger side load transfer frame coupling the aft structure to the passenger side strut and being configured to transfer a load applied to the aft structure from a rear of a vehicle to the passenger side strut, and a driver side load transfer frame coupling the aft structure to the driver side strut and being configured to transfer a load applied to the aft structure from the rear of the vehicle to the driver side strut.

A vehicle body lower part structure includes: a floor panel; and a vehicle body frame member including a frame body, an inner side wall, a joint flange projecting inward in a vehicle width direction from an inner surface of the inner side wall in the vehicle width direction, and having a joining surface on which an end of the floor panel in the vehicle width direction is stacked and to which the end of the floor panel in the vehicle width direction is joined, and a recess provided to the frame body, recessed outward in the vehicle width direction from the inner surface of the inner side wall in the vehicle width direction, and having a surface that is continuous and flush with the joining surface of the joint flange.

A hybrid vehicle having an improved arrangement structure is provided. The hybrid vehicle includes a fuel tank which provides fuel to an engine, and is disposed in a first area which is recessed upward from the under surface of the exterior of a vehicle body. A battery provides an electric driving force to a vehicle, and is disposed in a second area which is recessed downward between the bottom of the interior of the vehicle body and a rear seat. The first area is disposed further forward than the second area in a longitudinal direction of the vehicle body.

A vehicle body structure of an electric vehicle is provided, including a floor panel and a battery pack anti-collision structure. A battery pack and a motor are disposed below the floor panel, and the motor is located behind the battery pack. The battery pack anti-collision structure is disposed between the battery pack and the motor, and is configured to prevent the motor from crashing into the battery pack when a rear collision occurs to the electric vehicle.