A vehicle body structure includes a side sill having a closed cross-section portion, and a reinforcement body inside the closed cross-section portion and joined to the side sill. The reinforcement body comprises first and second reinforcement portions. The first reinforcement portion has a first bonding surface on the upper side and is joined to an inner wall of the closed cross-section portion at a portion other than the first bonding surface, and the second reinforcement portion has a second bonding surface facing the first bonding surface from above the first bonding surface, and is joined to the inner wall at a portion other than the second bonding surface. The first and second bonding surfaces are bonded together through a damping member made of an adhesive material. The first and second bonding surfaces are disposed at an inclination angle of 30 degrees or less with respect to a horizontal plane.

A body for a vehicle configured for securing safety performance and vehicle rigidity according to a vehicle collision while increasing a battery capacity mounted in the vehicle, may include an internal side member mounted on a top surface of a center floor in a longitudinal direction of the body; a battery cross member mounted in a width direction of the body inside a battery case provided at a lower end portion of the center floor while intersecting the internal side member; and a coupling structure coupled to the battery case, the battery cross member, and the center floor at a point where the internal side member and the battery cross member intersect.

This disclosure relates to a motor vehicle floor assembly configured to facilitate electrical connections and/or airflow within the vehicle, and a corresponding method. An example assembly includes a floor including an electrical line arranged entirely within the floor. In another example assembly, the floor additionally or alternatively includes an air flow path.

A vehicle body structure includes a front floor panel on which a heel of a pedal operator is placed, and a rear floor panel attached to a front seat. The rear floor panel is positioned lower than the front floor panel. At least part of a seat frame of the front seat is positioned lower than an upper surface of the front floor panel.

A vehicle structure includes side sills, pillars, a first battery arrangement portion provided inside the vicinity of the pillars in a vehicle width direction below a floor panel, and a second battery arrangement portion provided at a center portion in the vehicle width direction below the floor panel in a region inside an outer portion of the first battery arrangement portion in the vehicle width direction.

A vehicle body lower structure includes a battery case, a side sill, and a case-mounting frame. The case-mounting frame has a frame main body portion and a battery case reception flange. The battery case reception flange extends to an inward side in a vehicle width direction from the frame main body portion and is joined to a lower surface of a bottom wall of the battery case. A battery support frame extending in a vehicle body forward-rearward direction and supporting a battery is fixed to the bottom wall of the battery case. A recessed portion protruding downward is provided between a joint portion with respect to the battery case reception flange and a joint portion with respect to the battery support frame in the bottom wall of the battery case.

A single-piece, lightweight, energy-absorbing, and impact resistant battery tray for a battery enclosure for a vehicle includes a lower floor including an impact resisting structure, upwardly sloping side walls integrally formed with the lower floor, and a peripheral flange integrally formed with the upwardly sloping side walls and including an energy absorbing structure.

A device for arranging a passenger restraint system in a vehicle to secure a passenger seated in the vehicle, including a support arrangement having a vertical support and a cross strut. When arranged on the vehicle, the vertical support is arranged upright on a vehicle floor. The device includes a fastening element, that when arranged on the vehicle, encompasses a rail of a vehicle chassis, at least laterally and beneath, such that, when the support arrangement is arranged on the vehicle, the fastening element bears against the support arrangement. The support arrangement is held on the vehicle chassis by the fastening element and, when the support arrangement is arranged on the vehicle, the fastening element passes progressively through the vehicle floor, starting from the rail of the vehicle chassis.

A vehicle floor structure includes a center floor panel, a tunnel extending along a central longitudinal axis of the center floor panel, and having a tunnel cavity, a hydrogen tank located in the tunnel cavity of the tunnel, and a tank support frame configured to support the hydrogen tank so that the hydrogen tank is held in the tunnel cavity.

This disclosure relates to a motor vehicle floor assembly configured to facilitate electrical connections and/or airflow within the vehicle, and a corresponding method. An example assembly includes a floor including an electrical line arranged entirely within the floor. In another example assembly, the floor additionally or alternatively includes an air flow path.