A cowl panel comprises an upper face portion where a windshield is joined, a forward protrusion portion extending downwardly from the upper face portion, protruding forwardly, a rearward protrusion portion extending downwardly from a rear lower end of the forward protrusion portion, protruding rearwardly, and a lower face portion extending forwardly from a lower end of the rearward protrusion portion. A reinforcing member which is positioned on a forward side of the forward protrusion portion and the rearward protrusion portion of the cowl panel and joined to the forward protrusion portion and the lower face portion is provided. The reinforcing member comprises a straight portion which substantially straightly extends downwardly from a joint part where the reinforcing member is joined to the forward protrusion portion, and the straight portion is provided with a fragile part.

Apparatuses, systems, and methods for absorbing energy in a hinge are provided. An apparatus may include a first portion, a second portion coupled to the first portion to move relative to the first portion, and a tab configured relative to the first and second portions to absorb energy imparted to the second portion during a collision. The tab may be bendable via rotation as the second portion moves towards the first portion during the collision. The first portion may be a hinge bracket securable to a vehicle body. The second portion may be a hinge arm securable to a vehicle hood. The tab may be positioned at least partially between the first portion and the second portion for selective interference of the tab with one of the first portion and the second portion.

A pedestrian protection device of a vehicle includes a first body element mounted to the vehicle and having a connecting section. The pedestrian protection device includes a second body element that includes a hollow profile section. The first body element is movably received in the hollow profile section. The pedestrian protection device includes an elastically deformable exterior component connected to the second body element. The hollow profile section of the second body element is displaced from a rest position to a crash position upon the application of force against exterior component. The pedestrian device includes a latching device that releasably latches the connecting section of the first body element with the hollow profile section of the second body element when set in the crash position.

In at least some implementations, an energy absorbing member for a vehicle includes an engine cover adapted to be mounted beneath a vehicle hood and to overlie at least part of an engine, and an upper member coupled to the engine cover. The upper member is cantilevered to the engine cover wherein the upper member has a base coupled to the engine cover and a free end spaced from the base, and the upper member is flexible and a first portion of the upper member spaced from the base and including the free end is movable relative to the base.

A vehicle front structure that absorbs a shock load applied to immediately under a front grille by using a structure at a position higher than a bumper beam as a support. The vehicle front structure includes a shock absorbing member at an interior of a bumper face below a front grille. The shock absorbing member includes a load receiving portion that receives a load, an abutting portion abutting against a structure above a bumper beam during receding of the shock absorbing member, an upper-side connecting portion connecting the load receiving portion and the abutting portion, a locking portion deformed while being locked to the bumper beam during receding of the shock absorbing member, and a lower-side connecting portion connecting the load receiving and locking portions. A bending facilitating portion extending in the vehicle width direction is formed on the side of a rear portion of the upper-side connecting portion.

An energy absorber for interposition between a cover and a covered object includes a generally planar matrix of cells. Each of the cells includes a plurality of generally elongate micro-elements interconnected to form a cell micro-structure, with each cell having a respective energy absorption capacity such that an energy absorption capacity of the energy absorber varies across at least one direction. The cells are configured such that impulse of an object with the cover with the energy absorber sandwiched between the cover and the covered object causes a deceleration vs. time response in the object, beginning with a generally linear rise in the deceleration to a peak deceleration within 5 ms after the beginning of the impulse event, followed by a generally nonlinear decrease in the deceleration over a period of not greater than 15 ms to a final target deceleration of not greater than 10% of the peak deceleration.

A hinge assembly for an engine hood of a motor vehicle, having a hinge substructure, which can be attached to a body component of the motor vehicle, and having a hinge upper part, which can be attached to the engine hood. The hinge upper part is retained on the hinge substructure so as to pivot about a pivoting axis. The hinge assembly includes at least one support element, which enables deformation of the hinge substructure in a first direction, in which the hinge substructure can be moved away from a limit stop area of the at least one support element. The at least one support element limits deformation of the hinge substructure in a second direction opposite the first direction by means of the limit stop area. Furthermore, the invention relates to a motor vehicle having at least one such hinge assembly.

A hood assembly for a vehicle comprises an outer panel, an inner panel disposed inwardly of the outer panel and defining a lower, sealing surface, a crush volume defined between the outer panel and the inner panel; and a bridging member disposed within the crush volume and configured to extend supportively between the outer panel and the inner panel. The bridging member comprises a support surface that is in supportive contact with the outer panel and support members that extend from the support surface toward the inner panel for structural support of the hood assembly.

An automobile hood 1 has an inner panel 2, an outer panel 3, and a plurality of linear sealer regions A in which joints 21 are arranged. A region which includes the linear sealer region A and in which both ends in a longitudinal direction L of the linear sealer region A reach the outer circumferential edge of the inner panel 2 is defined as an end-to-end region B. Each of three longest linear sealer regions A2, A4 and A3 among the plurality of linear sealer regions A is a length that is 40% or more of the length of an end-to-end region B2, B4 or B3 to which the linear sealer regions A2, A4 or A3 belongs, respectively. These three end-to-end regions B2, B4 and B3 do not intersect with each other within a region surrounded by the outer circumferential edge of the inner panel 2.

A bumper-face support member extending in a vehicle width direction in front of a vehicle-body member provided at a vehicle-body front portion and having an attachment portion where a bumper face is attached, plural brackets fixedly connecting the vehicle-body member and the bumper-face support member, a bumper beam extending in the vehicle width direction below the bumper-face support member, and a stay connecting the bumper-face support member and the bumper beam in a vertical direction are provide. The stay has a deformation promotion portion configured to be bent so as to promote deformation of the stay when a collision load is downwardly inputted to the bumper-face support member.