An energy-absorbing device includes a beam having a longitudinal axis and a plurality of lobes attached to and positioned sequentially along the beam. The lobes are spaced from each other, deformable relative to the beam, and configured to contact adjacent lobes when deformed. The size and spacing of the lobes is such that if a single lobe is deformed, the lobe will not contact adjacent lobes, but if adjacent lobes are deformed, the lobes will contact each other.

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.

A crash impact attenuator is adapted for deployment on a vehicle, and includes a cartridge portion having at least one energy absorbing module, as well as a backup system having a backup frame, which is adapted to attach the cartridge portion to the vehicle. The backup system includes an actuator configured to pivot the cartridge portion between a deployed orientation and a stored orientation about a pivot axis disposed on a lower half of the backup system. The backup system further includes a lockout frame member having a contact surface on one end thereof, the lockout frame member being actuatable between a deployed orientation wherein the contact surface engages a portion of the backup frame to support the backup frame against vehicular impact forces and a stowed orientation wherein the contact surface is not engaged with the backup frame.

A vehicle bumper assembly is provided having an energy absorber, a bracket, a step pad and a bumper fascia. The energy absorber includes an upper horizontal surface wherein the upper horizontal surface may define a deformable structure. The deformable structure may be in the form of flexible fins. The bracket may be mounted to the vehicle frame on a first end of the bracket and the energy absorber affixed to a second end of the bracket. The step pad may be affixed to the energy absorber. The bumper fascia may be affixed to either or both the step pad and the energy absorber.

A bumper includes a carrier having a wall extending along a longitudinal axis, and a first leg and a second leg extending away from the wall in a first direction. A plurality of fins are movably attached to the carrier between the first leg and the second leg, and are spaced from each other the longitudinal axis. The fins may be moved to a deployed position to reinforce the bumper to improve low-speed damageability of the bumper, and may be moved to an inactive position, which may allow a fascia to more easily deform relative to the deployed position to provide energy absorption for pedestrian impacts.

A protective member includes outer and inner layers interconnected by multiple connectors under tension along their longitudinal axis. The connectors absorb energy from an impact force by resisting further tension along their longitudinal axis, can elongate along their longitudinal axis and allow the layers to move relative to each other. The protective member can be used in numerous applications and environments, including for participants in sports, in applications including bumpers, passenger cabins, car seats, beds, torso protection, ships, gloves, footwear and items.

The present invention relates to an improved vehicle bumper in which a plurality of panel units are connectable through one reinforcing part and a method of manufacturing the same. The vehicle bumper includes a panel unit including a first panel forming a main protection area and a second panel coupled to the first panel and forming an additional protection area at one side of the main protection area, and a reinforcing panel disposed on non-exposed surfaces of the first panel and the second panel and fixing the first panel and the second panel to each other.

A vehicle front end includes a bumper and a carrier attached to the bumper. A plurality of fins are movably attached to the carrier and are spaced from each other. The fins taper in a direction transverse to the bumper. The fins may be moved to a deployed position to reinforce the bumper to improve low-speed damageability of the bumper, and may be moved to an inactive position, which may allow a fascia to more easily deform relative to the deployed position to provide energy absorption for pedestrian impacts.

An energy absorbing system includes a carrier having a wall extending along a longitudinal axis. The energy absorber has a first leg and a second leg extending in a first direction away from the wall. A plurality of fins are fixed to and extend from the wall in the first direction, at approximately 60 to 65 degrees relative to the wall.

A bumper assembly includes an elongated beam and a pair of crush cans. The elongated beam includes a plurality of reinforcing walls extending horizontally that define a gap in a central portion of the beam. The pair of crush can assemblies is attached to the beam at transversely spaced locations relative to the central portion of the beam. The central portion of the beam is structured to have less bending resistance than the right and left sides. The reinforcing walls span the crush can assemblies so that the gap facilitates bending the central portion of the beam. A method of making a bumper is also disclosed that includes the steps of selecting a bumper beam and partially removing an upper/central portion and a lower/central portion of the bumper beam.