A hood assembly for a vehicle includes an inner hood, an outer hood, and a plurality of deployable devices. The outer hood is fixed relative to the inner hood. The plurality of deployable devices are spaced apart from each other between the inner hood and the outer hood. The deployable devices each define an inflation chamber and are formed of thermoplastic elastomer. Upon detection of impact between the vehicle and a pedestrian, the deployable devices are deployed to separate the outer hood and the inner hood. As such, during impact of the pedestrian with the outer hood, the outer hood may deform and/or the outer hood may space the pedestrian from relatively hard components under the hood assembly.

A stud assembly is coupled between an underhood propulsion system and an underhood cover in order to manage energy from an external force applied to the underhood cover. The underhood cover is coupled over the underhood propulsion system. The stud assembly is coupled between the underhood propulsion system and the underhood cover and includes a polymeric isolator and a stud coupled to the polymeric isolator. The stud includes a shank and a head coupled to the shank. The head is coupled to the polymeric isolator. The stud assembly includes a boss coupled to the underhood cover. The boss is disposed adjacent the polymeric isolator. The shank includes a bending initiator feature in order to allow the shank to bend when the underhood cover is subjected to an external force.

A vehicle front portion structure comprising: a bumper reinforcement disposed at a vehicle front end portion side such that a longitudinal direction of the bumper reinforcement is aligned with a vehicle transverse direction; a pedestrian collision detection sensor comprising a pressure tube and outputting signals based on pressure changes in the pressure tube, the pressure tube comprising: a main tube disposed at a vehicle front side of the bumper reinforcement and extending along the bumper reinforcement from one end portion in the longitudinal direction of the bumper reinforcement to another end portion in the longitudinal direction thereof; and a pair of outer side tubes provided continuously with the main tube and, as viewed from a vehicle front-rear direction, extending respectively towards a vehicle lower side from positions of the one end portion and the other end portion of the main tube; and an absorber.

A vehicle front structure is provided that can absorb collision energy with respect to not only a load from above but also a lateral load. A vehicle front structure includes a cowl side panel, a front hood, a fender panel forming a seam with the front hood, a fender upper cover disposed extending in a vehicle front-rear direction, and a bracket connecting the cowl side panel and the fender upper cover to each other and serving to dispose the fender upper cover at a predetermined position. The fender upper cover has an attachment wall to which the bracket is fixed and an inclined wall extending upward from an end of the attachment wall on an outward side with respect to a vehicle width direction while being inclined inward with respect to the vehicle width direction, and covering the seam from inside a vehicle.

A hinge for a hood of a vehicle includes a first bracket, a member coupled to and rotatable relative to the first bracket, and a second bracket coupled to and rotatable relative to the member. An actuator includes a base connected to the first bracket and a rod moveable relative to the base. The rod moves from a retracted position to an extended position in contact with the second bracket.

A vehicle hood assembly includes an outer hood panel and an inner hood panel coupled to and positioned below the outer hood panel in a vehicle vertical direction. A hood reinforcement strap is coupled to at least one of the outer hood panel and the inner hood panel. The hood reinforcement strap includes a strap base and lobe structures spaced-apart along a length of the strap base that extend outward from the strap base in the vehicle vertical direction.

A motor vehicle comprising an aerodynamic underbody flap (1) rotating about a transverse axis (10) and a lower transverse structure (4) arranged at the rear of the lower part of a front bumper (6). The rear part of the lower transverse structure (4) comprises guide means (41, 42) which, in the event of a frontal impact, guide the backward movement of the lower transverse structure (4) such that the rear face of the lower transverse structure (4) comes into contact with the axis (10) of the aerodynamic underbody flap (1).

A deformable bracing rod is disclosed for holding a lower crossmember of a windshield opening of a motor vehicle. The deformable bracing rod (200) has rigid end portions (203, 204), respectively attached to the windshield opening lower crossmember (301) and to another element (102) of the body of the vehicle, and a flexible central portion (203) connecting the two rigid end portions. It makes it possible to design a collapsible lower crossmember of a windshield opening which yields in the event of an impact so as to damp the impact experienced by the head of a pedestrian, while maintaining the level of acoustic and vibrational performance.

A cowl top structure is provided along a lower edge of a front glass in a vehicle width direction. The cowl top structure includes a raised section, a fragile section and a drainage passage. The raised section is formed on a left end portion of a cowl top. The fragile section is formed on the raised section. The drainage passage is provided in a surrounding of the raised section and formed to drain water to an outer side of a vehicle body.

A system includes a vehicle body which further includes a front beam. The system also includes an energy absorber that may be coupled to the front-end beam of the vehicle body. In an example, the energy absorber includes a first edge and a second edge that may be opposite to the first edge along a first direction. The energy absorber also includes a first exterior surface that extends between the first edge and the second edges of the energy absorber. Further, the first exterior surface includes a plurality of openings therein. The system also includes a grille having a first edge and a second edge which may be opposite to the first edge of the grille. In one example, the second edge of the grille may be coupled to the first edge of the energy absorber. The grille includes a plurality of extensions that may extend from the second edge in such a way that the plurality of extensions are positioned in the plurality of openings in the energy absorber.