Provided is a vehicle structure including: a pipe member forming a part of a frame of a vehicle; and a wire-shaped body having flexibility, in which the pipe member includes a pipe portion forming a pipe shape and a flange portion formed to protrude from the pipe portion, and is formed of one member in which the pipe portion and the flange portion are continuous with each other, and the wire-shaped body is disposed in at least one of a first state where the wire-shaped body is disposed along the flange portion and a second state where the wire-shaped body strides over the flange portion.

An apparatus, system and method capable of providing a bumper capable of providing decreasing reversionary impact forces upon an impacting collider as the bumper is compressed. The apparatus, system and method may include at least a bumper cover; and a scissor mechanism housed within the bumper cover. The scissor mechanism may comprise a forward extension member proximal and having a parallel axis that is at least substantially parallel to a parallel tangential axis of the bumper cover; a rear extension member substantially parallel to the forward extension member, and distal from the flexible bumper; at least left and right long scissor members that are rotatably and slidably associated with respective slots in the forward extension member, and that, are rotatably associated with the rear extension member; and at least left and right short scissor members that are rotatably associated with the front extension member, and that are rotatably associated with a respective one of the left and right long scissor members.

An energy-absorbing impact assembly for an electric vehicle includes a bumper assembly. The bumper assembly includes an elongated center beam that extends laterally from a first end to a second end and longitudinally between a front side and a rear side. The energy-absorbing impact assembly includes a tubular support positioned on the rear side of the elongated center beam. The energy-absorbing impact assembly includes a crash box positioned on the rear side of the elongated center beam. The energy-absorbing impact assembly includes a ring assembly positioned on the rear side of the elongated center beam. The ring assembly includes a ring body and a plurality of struts that extend from the ring body. The bumper assembly, the tubular support, the crash box, or the ring assembly are configured to deform upon impact.

A vehicle front structure includes side frames in pairs, a bumper beam, a pair of lower frames, a lower beam, and wheels in pairs. Each of outer end parts of the bumper beam in a vehicle width direction and a corresponding one of outer end parts of the lower beam in the vehicle width direction overlap a corresponding one of the wheels as seen from the vehicle front side. In the vehicle width direction, a position of each of vehicle-width-direction outer ends of the bumper beam and a position of a corresponding one of vehicle-width-direction outer ends of the lower beam substantially coincide with a position of a mounting part of a corresponding one of brake devices that are disposed radially inside the wheels respectively.

A vehicle front structure includes side frames in pairs, a bumper beam, lower frames in pairs, and a lower beam. The lower beam extends in a vehicle width direction on a vehicle lower side of the bumper beam. The lower beam is coupled to vehicle-front-side end parts of the lower frames. The lower beam includes a front lower beam member and lower beam members in pairs. The front lower beam member constitutes a vehicle-front-side part of the lower beam. The front lower beam member extends in the vehicle width direction. Longitudinal-direction end parts of the front lower beam member are disposed outward in the vehicle width direction, as seen from the lower frames. The rear lower beam members constitute a vehicle-rear-side part of the lower beam. The rear lower beam members are joined respectively to both of the longitudinal-direction end parts of the front lower beam member.

A beam structure for a body of a motor vehicle includes at least two shock-absorbing beam elements, which extend substantially in a longitudinal direction and each have a first outer wall, a second outer wall running substantially parallel to the first outer wall, and an inner wall running substantially parallel to the first outer wall and to the second outer wall. At least one cross-beam extends substantially in a transverse direction running perpendicularly to the longitudinal direction, and is disposed at a first end of the shock-absorbing beam elements and is connected both to the first outer wall and to the second outer wall and/or the inner wall. At least two structure elements are respectively disposed at the first end of one of the shock-absorbing beam elements and are connected to the second outer wall and/or the inner wall of the shock-absorbing beam element in question and/or to the cross-beam.

A vehicle beam assembly includes a hollow tubular member configured to be formed with steel tube air forming. The tubular member includes a varied cross section along a length of the tubular member. For example, the hollow tubular member includes a center portion having a first cross-sectional shape, a pair of end portions that extend past corresponding crush cans in a direction away from the center portion, where the pair of end portions extend at an angle of 40-70 degrees, and at least one transition portion disposed between the center portion and one of the pair of end portions. A cross-sectional shape of the center portion, a cross sectional shape of one of the end portions, and a cross-sectional shape of the transition portion are all different cross-sectional shapes.

A beam assembly includes a first beam that has a first tubular portion and a first projecting portion that extends from the first tubular portion. A second beam has a second tubular portion and a second projecting portion that extends from the second tubular portion. The elongated interior of the first tubular portion defines a first hollow area and the elongated interior of the second tubular portion defines a second hollow area. The first beam is attached to the second beam with the first projecting portion attached to the second tubular portion and the second projecting portion attached to the first tubular portion to define a third hollow area between the first and second projecting portions.

There is provided a reinforcement member for a vehicle which includes a cylindrical body section having a continuously closed cross section intersecting with a longitudinal direction. The cylindrical body section has a first surface, a second surface, and a third surface. The third surface has a fourth surface extending away from the second surface, and a fifth surface connecting the fourth surface and the first surface to each other. In a sectional view when viewed in the longitudinal direction, in a case where a virtual line connecting a first intersection portion where the first surface and the third surface intersect with each other and a second intersection portion where the second surface and the third surface intersect with each other is set, a third intersection portion where the fourth surface and the fifth surface intersect with each other protrudes outward with respect to the virtual line.

A bumper cross member designed as a hollow chamber profile for a motor vehicle having an upper component and a lower component joined to the upper component. Both components are each designed as a half shell having two legs spaced apart from one another and a web connecting the legs. An insert plate is joined to the legs of the half shells. The insert plate is arranged between the joints of the legs of the half shells facing toward one another and bridges the joint spacing between the legs of the two half shells.