A vehicle rocker assembly includes an outer sill member and an inner sill member attached longitudinally along the outer sill member to define a hollow space along and between the inner and outer sill members. A tubular insert is disposed in the hollow space so as to extend longitudinally along the hollow space. The tubular insert has a crush control feature extending longitudinally along a wall of the tubular insert, such as upper and lower walls at opposing sides of the interior volume. The tubular insert is configured for side impact forces at the outer sill member to laterally deform the tubular insert at the crush control feature to provide an accordion-style lateral crush to absorb the side impact forces.

An accident safety device for a motor vehicle includes two separate accident safety bodies which are spaced apart from each other by a predetermined distance and are fastenable opposite each other to a motor vehicle bodyshell. One of the accident safety bodies is fastenable to an underbody element of the motor vehicle body shell. Another of the accident safety bodies has a catch element which corresponds to the one accident safety body and is designed to block the two accident safety bodies from avoiding each other in the event of an accident of the motor vehicle. A motor vehicle is equipped with such an accident safety device and a method controls the conversion of impact energy into work of deformation by use of the accident safety device.

An embodiment center pillar structure for a vehicle includes a center pillar including a lower connection portion, a side sill including an intermediate connection portion to which the lower connection portion of the center pillar is joined, a pillar reinforcement joined to an inboard surface of the center pillar, and a side sill reinforcement joined to an inboard surface of the side sill, wherein the pillar reinforcement and the side sill reinforcement are joined to the intermediate connection portion of the side sill.

A vehicle rocker assembly includes a sill inner and a sill outer. An upper flange portion of the sill inner is coupled with an upper flange portion of the sill outer, and a lower flange portion of the sill inner is coupled with a lower flange portion of the sill outer to enclose a hollow interior of the vehicle rocker assembly. One of the sill inner or the sill outer includes a reinforcement structure integrated in the sill wall of the respective still inner or sill outer. The reinforcement structure includes walls that each laterally span the hollow interior and form a multi-hollow cross-sectional shape with the sill inner and sill outer.

The disclosure provides a vehicle body capable of suppressing the occurrence of cracks in a center pillar at the time of a side collision. A center pillar stiffener forms a hollow structure with a closed cross section by including a side wall which faces the outer surface of a pillar inner, a front wall which is formed by bending from a front end of the side wall to form a first ridge with the side wall and which is joined to the outer surface of the pillar inner, and a rear wall which is formed by bending from a rear end of the side wall to form a second ridge with the side wall and which is joined to the outer surface of the pillar inner. The pillar stiffener is provided with a bead recessed toward the pillar inner and orthogonal to the first and second ridges.

An energy absorbing device includes a honeycomb body having two or more tubes stacked transversely with one another along a longitudinal axis. The honeycomb body includes an inboard portion and an outboard portion. The inboard portion of the honeycomb body is arranged along the longitudinal axis and has an inboard portion bending stiffness. The outboard portion of the honeycomb body is arranged outboard of the longitudinal axis, is coupled to the inboard portion of the honeycomb body, and has an outboard portion bending stiffness. The outboard portion bending stiffness of the outboard portion is greater than the inboard portion bending stiffness of the inboard portion. Structural members for vehicle bodies and vehicle bodies are also described.

A vehicle battery pack frame for a vehicle comprising: a base having a length and a width; side members on opposite sides of the base, extending along the length of the base, and attached to a periphery of the base; and crossbeams extending across the width of the base, between the side members; wherein each of the side members comprises a profiled body comprising a sidewall having a first surface facing the cross beams, and an opposite second surface; and a polymer reinforcement attached to the profiled body and facing the second surface of the sidewall of the profiled body.

The present teachings generally relate to a carrier and method of making the carrier, the carrier comprising: a periphery having: an outer edge, arranged distally along a transverse axis of the carrier, configured to be oriented away from a frame enclosure of a vehicle, an inner edge, arranged distally along the transverse axis, configured to be oriented toward the frame enclosure of the vehicle, and distal ends arranged opposite each other along a longitudinal axis of the carrier; one or more series of ribs having: a cross-sectional pattern, and an orientation along the longitudinal axis, the transverse axis, or both.

A frame structure for maintaining energy storage devices of a vehicle in position which is deformed in a controlled way in the event of a side-impact, in such a way to avoid deforming into the location of the vehicle seats. The proposed frame structure is adapted to deform controllably in a centre position align with a location between the vehicle seats. In this way are occupants of the vehicle kept safe since no or less deformation occur in the vehicle seat location. The above advantages are provided by that lateral support members of the frame includes a deformation zone adapted to deform in response to a lateral force exerted on the lateral support member. The deformation zone is located such that, when the frame structure is installed in the vehicle, the deformation zone is aligned with a location between seats of the vehicle.

This vehicle body side structure includes: side sills provided at both end portions of a floor section in a width direction of a vehicle and extending in a forward/rearward direction of the vehicle; a pillar extending upward from each of the side sills and having a pillar outer provided on an outside in the width direction of the vehicle; a crushing member provided on an inside in the width direction of the vehicle with respect to the pillar outer, having a lower portion joined to the side sill, and extending upward; an impactor which is provided above the crushing member, which is joined to an inside of the pillar outer in the width direction of the vehicle, and in which the impactor and the crushing member at least partially overlap in an upward/downward direction; and a seatbelt winding device provided on the outside in the width direction of the vehicle with respect to the crushing member and disposed inside an accommodation concave section formed in the impactor.