A configurable bumper for a vehicle may include a center body, one or more telescoping end assemblies adapted to slide in a direction parallel to the axis of the center body and perpendicular to the axis of vehicle, and a locking mechanism for each telescoping end assembly. The telescoping end assemblies may be secured in at least two different axial positions on the center body. A method for manufacturing a bumper may include forming bumper components in near-net shape by a profile extrusion process and sizing to length.

A configurable bumper for a vehicle may include a center body, one or more telescoping end assemblies adapted to slide in a direction parallel to the axis of the center body and perpendicular to the axis of vehicle, and a locking mechanism for each telescoping end assembly. The telescoping end assemblies may be secured in at least two different axial positions on the center body. A method for manufacturing a bumper may include forming bumper components in near-net shape by a profile extrusion process and sizing to length.

Provided is a vehicle body structure capable of preventing separation between a bumper beam and a bumper beam mounting member on the non-collision side at the time of an offset collision. The vehicle body structure includes a bumper beam, a pair of bumper beam mounting members, and a pair of holding members. The holding member includes an outer mounting portion for mounting an outer side in the vehicle width direction of the holding member on the bumper beam mounting member, and a front mounting portion for mounting an inner side in the vehicle width direction of the holding member on the front surface portion of the bumper beam. The front mounting portion extends to a position corresponding to a vehicle width direction inner end portion of the bumper beam mounting member in a front-rear direction at least on the front surface portion of the bumper beam.

A magnetic collision damping device for vehicles is disclosed, in one embodiment of which a first trough 3 and a second trough 4 are slidably connected to a vehicle frame, and electromagnets 7, 8 whose like poles are arranged to face each other are fixed inside the first trough 3 and the second trough 4. This invention can prevent the electromagnets from being damaged when being subject to an impact, and can demonstrate its collision damping function regardless of whether a collision force comes from a vehicle front or a vehicle rear. All electromagnets are arranged close to the vehicle rear, effectively protecting the safety of passengers.

An upper side joint section that extends inward in a vehicle width direction from a vicinity of a rear side frame and a lateral side joint section that extends downward from the upper side joint section and that is separated in the vehicle width direction from the rear side frame are provided on a rear floor panel of a vehicle body rear part structure. The rear panel has: a frame joint part to which the rear side frame is joined; a first floor joint part to which the upper side joint section of the rear floor panel is joined; and a second floor joint part to which the lateral side joint section of the rear floor panel is joined. A longitudinal bead is provided on a part of the rear panel between the frame joint part and the second floor joint part. The longitudinal bead extends to a lower end of the rear panel and is opened downward.

A first shock absorption member between a frame forming a framework of a vehicle and an outer structure positioned outside of the frame in the vehicle, the first shock absorption member being installed in a manner that the outer structure is deformed preferentially over the frame in a shock-receiving situation in which the outer structure is displaced or deformed toward the frame side due to a shock load against the outer structure, a second shock absorption member between the frame and the outer structure, and a switching unit to switch an installation state of the second shock absorption member between a first installation state in which the second shock absorption member avoids the shock load in the shock-receiving situation and a second installation state in which the second shock absorption member receives the shock load and deforms together with the first shock absorption member in the shock-receiving situation are provided.

An off-center impact structure (a frame protrusion rupture mitigating structure) has a first end section, a mid-section and a second end section. The first end section is fixedly attached to an attachment section of a vehicle front side member. The mid-section extends laterally outward and defines an arcuate shape curving forward from the first end section and laterally outboard. The second end section of the off-center impact structure is located forward of the attachment section. The mid-section has a forward-facing surface formed with a plurality of vertically oriented recesses. In response to an off-center impact event where impacting force is applied to a distal end of the second end section, the off-center impact structure deforms bending along the mid-section with at least a portion of the vertically oriented recesses expanding in a bellows-like manner absorbing impact energy such that the second end section is moved rearward.

An off-center impact structure (a frame protrusion rupture mitigating structure) has a first end section, a mid-section and a second end section. The first end section is fixedly attached to an attachment section of a vehicle front side member. The mid-section extends laterally outward and defines an arcuate shape curving forward from the first end section and laterally outboard. The second end section of the off-center impact structure is located forward of the attachment section. The mid-section has a forward-facing surface formed with a plurality of vertically oriented recesses. In response to an off-center impact event where impacting force is applied to a distal end of the second end section, the off-center impact structure deforms bending along the mid-section with at least a portion of the vertically oriented recesses expanding in a bellows-like manner absorbing impact energy such that the second end section is moved rearward.

To improve the safety of passengers of a motor vehicle and road users in the case of a head-on collision, a deformation element is provided and includes a crossmember holder for mounting to a crossmember and a bumper plate that can be positioned next to a bumper of a motor vehicle. The deformation element is characterized in that a centrifugal force-operated release element for adjusting and locking the distance of the crossmember holder from the bumper plate is provided between the bumper plate and the crossmember holder. A first distance of the bumper plate from the crossmember holder, starting from a normal position, is greater in a first position than a distance in a second position.

To improve the safety of passengers of a motor vehicle and road users in the case of a head-on collision, a deformation element is provided and includes a crossmember holder for mounting to a crossmember and a bumper plate that can be positioned next to a bumper of a motor vehicle. The deformation element is characterized in that a centrifugal force-operated release element for adjusting and locking the distance of the crossmember holder from the bumper plate is provided between the bumper plate and the crossmember holder. A first distance of the bumper plate from the crossmember holder, starting from a normal position, is greater in a first position than a distance in a second position.