There are provided a vehicle-body member provided at a vehicle-body front portion, a bumper-face support member supporting a bumper face in front of the vehicle-body member, and plural brackets fixedly connecting the vehicle-body member and the bumper-face support member. The bracket comprises an inclination portion which is inclined such that a front side thereof is positioned on an inward or outward side, in the vehicle width direction, of the bracket, a high-rigidity portion, at least part of which is positioned at the inclination portion and which is configured to have high rigidity against an input of a load applied in a vehicle longitudinal direction, and a fragile portion which is configured to be deformable by receiving the input of the load applied in the vehicle longitudinal direction. The high-rigidity portion and the fragile portion are provided adjacently to each other in the vehicle longitudinal direction.

A vehicle is provided that includes a hood outer panel, hood inner panel, and engine compartment. A fender attachment bracket is disposed within the engine compartment, and a headlight assembly includes an attachment portion that couples the headlight assembly to the fender attachment bracket. The headlight assembly also includes a load block or loading block sized and shaped so that when the hood outer panel and hood inner panel are deformed by the impact of an object, the hood inner panel contacts the load block.

A structure of a vehicle disclosed herein may include: a windshield; an instrument panel located below the windshield; in-vehicle equipment disposed such that the in-vehicle equipment projects upward above an upper surface of the instrument panel and is fixed to the instrument panel; and an impact relieving mechanism configured to, when a rearward and downward collision load is applied to the in-vehicle equipment, relieve the collision load by moving the in-vehicle equipment rearward and downward.

A grille assembly for a vehicle is disclosed and includes a forward frame portion, an aft frame portion, and a plurality of spring portions coupling the forward frame portion to the aft frame portion such that the forward frame is movable relative to the aft frame portion. A front end assembly for a vehicle is also disclosed that includes a bolster assembly and an active grille shutter system supported relative to the bolster assembly. The disclosed active grille shutter system includes a plurality of spring portions coupling forward and aft frame portions such that the forward frame is movable relative to the aft frame. Vanes are supported by at least one of the forward and aft frame portions and are rotatable for controlling airflow.

This cowl top cover has a cover body section and a vertical wall section which extends vertically from the front end of the cover body section. The vertical wall section is provided with a vertical wall body, an opening which is formed in the vertical wall body, and a cover section has a cover-side bending promotion section which extends in the width direction of the vehicle and which promotes the bending and deformation of the cover section to one side of the length direction of the vehicle. As a result of this configuration, the cowl top cover can consistently exhibit a sufficient impact absorption function when subjected to an impact.

A front section for a motor vehicle includes a bumper cladding and a bumper stiffening which extends in the vehicle longitudinal direction between the bumper cladding and a supporting body part. A connecting unit including a blind nut and a threaded fastener is inserted from below into an opening of the body part to fix a rear edge region of the bumper stiffening on an underside of the body part. The blind nut has flexible legs which are reversibly splayed apart above the opening.

A hood for a vehicle includes an inner panel having a deformation region on at least a portion of the inner panel. The deformation region defining a plurality of perforations configured to tear at an area between the perforations. The perforations being defined in an array constituting at least a partial outer periphery of the deformation region such that upon impact, the deformation region is configured to break along the outer periphery at the area between the perforations.

A vehicle-hood assembly includes a vehicle hood and an energy absorber fixed to the vehicle hood. The energy absorber is releasable from a compressed position to an uncompressed position. The energy absorber includes a chamber that is sealed and vacuum pressurized in the compressed position. An actuator is configured to unseal the chamber to release the energy absorber from the compressed position to the uncompressed position.

An impact absorbing member is provided below a fascia upper member (upper-face forming member) which forms an upper face of a front end portion of a vehicle. The impact absorbing member comprises a front side part which includes a front wall portion, a top wall portion, and a rear wall portion so as to have a U-shaped cross section opening downward and a flat-plate shaped rear side part which extends rearward from a lower end of the rear wall portion. A rear end portion of the rear side part is held at a radiator shroud as a vehicle-body-side member, and the rear side part is configured to slant obliquely forward and downward.

A mounting assembly for an automotive radiator, a vehicle including such a mounting and a method of mitigating an impact between a vehicle and a pedestrian. The assembly includes a radiator support and one or more brackets. Each bracket is made up of a first end portion that is secured to the radiator support and a second end portion extending forward of the radiator support such that it can be attached to a load-bearing structure within a vehicle. The brackets each include at least one enhanced collapsible zone in order to promote energy absorption relative to energy transmission in situations where a vehicle experiences a front-end impact with a pedestrian or other object. In this way, the added energy absorption by the brackets reduces the amount of impact energy being transmitted to more rigid vehicular structures such as the radiator and its support; this increase in impact energy absorption in turn results in less energy being delivered to the pedestrian.