A vehicle body structure includes an interior side wall, a floor structure and an airbag support member. The interior side wall defines a first door opening. The floor structure at least partially defines a passenger compartment of a vehicle along with the interior side wall. The floor structure defines seat supporting section adjacent to the first door opening. The airbag support member has an upper end and a lower end and an airbag attachment portion. The lower end is attached to the interior side wall at a first location above the floor structure between the first door opening and the seat supporting section, the upper end being attached to the interior side wall structure at a second location above the first location.

A vehicle body includes a structural member having an inner surface defining an elongated cavity. The structural member includes an outer panel member joined to an inner panel member. A tension web secured in the cavity separates the outer and inner panel members. A reinforcement member is positioned in the cavity of the structural member. The reinforcement member contacts the transverse web and a gap is provided between the reinforcement member and the inner surface of the structural member. The reinforcement member including a base member having a plurality of bumpers extended in a width direction of the reinforcement member. The plurality of bumpers face one of the inner surface and the tension web. An adhesive secured to the reinforcement member is activatable to expand toward the inner surface to define a joint between the reinforcement member and the structural member and to at least partially fill the gap.

A side body structure of a vehicle can include: a hinge pillar; a front pillar that is coupled to an upper end portion of this hinge pillar via a bent section, extends upward to the rear, and is coupled to a front end portion of a roof side rail via a connected section; and an apron rein that extends forward from a position below the bent section in the hinge pillar, where the bent section can include an energy absorption section that is subjected to out-of-plane deformation in a longitudinal orthogonal direction of the front pillar and thereby can absorb collision energy when the collision energy, which can be directed rearward, is applied to the apron rein. The energy absorption section can be configured to include an outer bead section and an inner bead section respectively provided in an outer member and a lower inner member.

An embodiment vehicle body coupling structure of a vehicle that includes an underbody and an upper body coupled to the underbody includes a front back beam assembly provided on a front side of the underbody, a first mounting part provided on a front side member of the upper body and coupled with the front back beam assembly, and a first body coupling part provided on the front back beam assembly and engaged with the first mounting part.

Provided is a vehicle body structure in which when a load acts on an impactor, the impactor is moved toward an inner wall, a slider is moved along the inner wall by means of direction-changing unit, and in the case where the load acting on a crushing member via the slider exceeds a set value, the moving slider crushes the crushing member.

A vehicle side structure (102; 202) comprising a side portion (104; 204) extending in a longitudinal direction (106; 206), wherein the side portion (104; 204) comprises a first member (108; 208) extending in the longitudinal direction (106; 206) and a second member (110; 210) extending in the longitudinal direction (106; 206). The first member (108; 208) is configured to face an inside (112; 212) of a vehicle, and the second member (110; 210) is configured to face an outside (114; 214) of the vehicle. The first and second members (108, 110; 208; 210) are attached to one another to form a substantially closed space (116; 216) between them. The side portion (104; 204) comprises two wave-shaped reinforcement members (118, 120; 218, 220) located in the substantially closed space (116; 216). The reinforcement members (118, 120; 218, 220) are attached to one another.

An under body structure of an automobile enabling batteries to be mounted on an automobile by a simple configuration and efficiently transferring load at the time of a collision, that is, an under body structure 100 of an automobile provided with a body floor 110 forming a floor part of the automobile and batteries 50 (battery cells or battery modules) directly suspended from and fastened to a bottom side of the body floor 110.

A vehicle includes a body including a first frame rail and a second frame rail and a cross-brace directly connected to the first frame rail and the second frame rail. A powertrain-electrification component is supported by the cross-brace. A vehicle subframe is directly connected to the cross-brace. A vehicle-steering gear is connected to the subframe. The direct connection of the subframe to the cross-brace dampens vibration, e.g., road vibration and noise, in the subframe to reduce noise, vibration, and harshness transferred to a vehicle occupant through the vehicle-steering gear.

An electric vehicle structure may include a floor panel; a center tunnel disposed at a center of the floor panel in a vehicle width direction, extending along a vehicle front-rear direction, and projecting upward from the floor panel; a dash panel disposed at front ends of the floor panel and the center tunnel; and a front reinforcement attached to an inner surface of a peripheral wall of the center tunnel and extending rearward from the dash panel through the center tunnel.

A method and an apparatus, according to an exemplary aspect of the present disclosure includes, among other things, a battery pack supported by at least one vehicle frame member, a side frame member positioned adjacent to an edge of the battery pack, and a cross-member extending away from the side frame member and above the battery pack. The cross-member is spaced from the battery pack by a gap. At least one bracket is mounted to at least one of the side frame member and cross-member within the gap such that in response to an impact load, the bracket prevents the cross-member from direct contact with the battery pack.