A device for reinforcing, sealing, or damping a structural element in a motor vehicle including a support which has multiple cells, wherein each cell surrounds a cavity. Each cavity is at least partially delimited by walls in each direction, wherein each cell has an extension in length, height, and width between 5 mm and 100 mm. An outer surface of the support can be connected to the structural element by an adhesive.

A vehicle includes a first pillar and a second pillar spaced from the first pillar along a vehicle-longitudinal axis. A rotational actuator is disposed at the first pillar. The rotational actuator is fixed relative to the first pillar. A cable is engaged with the rotational actuator and is elongated along the vehicle-longitudinal axis to the second pillar. The cable is moveable to a deployed position by the rotational actuator and is under tension in the deployed position.

A vehicle includes a first pillar and a second pillar spaced from the first pillar along a vehicle-longitudinal axis. A rotational actuator is disposed at the first pillar. The rotational actuator is fixed relative to the first pillar. A cable is engaged with the rotational actuator and is elongated along the vehicle-longitudinal axis to the second pillar. The cable is moveable to a deployed position by the rotational actuator and is under tension in the deployed position.

A method for manufacturing a unitary body side structural frame for a vehicle is provided. The method comprises providing a plurality of blanks, joining the blanks to each other to form a composite blank wherein joining the blanks includes forming one or more overlapping regions formed by partially overlapping two blanks and deforming the composite blank to form the unitary body side structural frame. A unitary body side structural frame as obtained by any of the methods herein described is also provided.

A method for manufacturing a unitary body side structural frame for a vehicle is provided. The method comprises providing a plurality of blanks, joining the blanks to each other to form a composite blank wherein joining the blanks includes forming one or more overlapping regions formed by partially overlapping two blanks and deforming the composite blank to form the unitary body side structural frame. A unitary body side structural frame as obtained by any of the methods herein described is also provided.

A body for a passenger car has a body-in-white structure which is located behind a wheel well for a front wheel of the passenger car and which has a transverse member that extends on the outside of a longitudinal beam of the body-in-white structure in front of a front end wall of the body-in-white structure in the vehicle transverse direction. The transverse member has a catch element which is designed to catch a rim of the front wheel that has moved backwards in the vehicle longitudinal direction in the event of an accident and is turning in rearward towards the vehicle center. The body-in-white structure has an A-pillar located behind the catch element, a lateral sill located behind the catch element, and a support element which is located in the A-pillar and via which the catch element that has moved backwards in the event of an accident and, via the catch element, the rim that has moved backwards in the event of an accident, can be supported towards the rear on the lateral sill.

A body for a passenger car has a body-in-white structure which is located behind a wheel well for a front wheel of the passenger car and which has a transverse member that extends on the outside of a longitudinal beam of the body-in-white structure in front of a front end wall of the body-in-white structure in the vehicle transverse direction. The transverse member has a catch element which is designed to catch a rim of the front wheel that has moved backwards in the vehicle longitudinal direction in the event of an accident and is turning in rearward towards the vehicle center. The body-in-white structure has an A-pillar located behind the catch element, a lateral sill located behind the catch element, and a support element which is located in the A-pillar and via which the catch element that has moved backwards in the event of an accident and, via the catch element, the rim that has moved backwards in the event of an accident, can be supported towards the rear on the lateral sill.

A body front-end structure for a two-track vehicle, having an A-pillar from which an upper wheel well longitudinal member projects toward the front of the vehicle in the longitudinal direction of the vehicle, and from which a lower body longitudinal member that is offset toward the inside of the vehicle with respect to the upper wheel well longitudinal member projects toward the front of the vehicle in the longitudinal direction of the vehicle. In a head-on crash with small lateral overlap, a suspension strut dome is loaded with a crash force in the longitudinal direction of the vehicle. The body front-end structure has a sheet-metal tension strip that connects the suspension strut dome to the lower body longitudinal member in a force-transmitting manner. In the event of a head-on crash, the sheet-metal tension strip provides a load path through which a tensile force opposing the crash force acts on the suspension strut dome.

A body front-end structure for a two-track vehicle, having an A-pillar from which an upper wheel well longitudinal member projects toward the front of the vehicle in the longitudinal direction of the vehicle, and from which a lower body longitudinal member that is offset toward the inside of the vehicle with respect to the upper wheel well longitudinal member projects toward the front of the vehicle in the longitudinal direction of the vehicle. In a head-on crash with small lateral overlap, a suspension strut dome is loaded with a crash force in the longitudinal direction of the vehicle. The body front-end structure has a sheet-metal tension strip that connects the suspension strut dome to the lower body longitudinal member in a force-transmitting manner. In the event of a head-on crash, the sheet-metal tension strip provides a load path through which a tensile force opposing the crash force acts on the suspension strut dome.

The present disclosure provides a body structure for a vehicle capable of improving a vibration damping effect by a damping member while preventing an increase in an application amount of the damping member and a shape change of a component. Embodiments include a body structure for a vehicle in which a first bonded surface of a first body component and a second bonded surface of a second body component are bonded via a damping member, with which a portion between the first bonded surface and the second bonded surface is filled. The first bonded surface of the first body component has a vertical wall extending toward the second bonded surface or away from the second bonded surface. The portion between the first bonded surface and the second bonded surface is filled with the damping member such that the damping member contacts the vertical wall.