A front bumper includes a bumper fascia, an upper panel, and a shock absorbing member and a rigidity member in the interior of the upper panel. The shock absorbing member is formed in a hat shape in cross section by a front wall, an upper wall (a front-side upper wall and a rear-side upper wall), a rear wall, and a lower wall. The rigidity member includes an upper end portion fixed to the upper wall, a lower end portion fixed to the lower wall, and an intermediate portion connecting the upper end portion and the lower end portion in the vehicle up-down direction. The intermediate portion is spaced apart from the rear wall in the vehicle front-rear direction.

In some embodiments, an energy absorber element can comprise: a first support wall and a second support wall, a crush wall joining the first and second support walls together to define a deformable zone; a connection mechanism configured to connect the first and/or second support wall to a vehicle. In one embodiment, a method for using an energy absorber element in a vehicle can comprise: detachably connecting an energy absorber element to a vehicle at a support location for a vehicle component, once the energy absorber element has absorbed energy, detaching the energy absorber element from the vehicle; and separately replacing the energy absorber element from the vehicle component. In some embodiments, the vehicle component is not replaced.

A hood panel is provided. The hood panel includes a plurality of first layers formed of a reinforced fiber and a resin and a plurality of second layers including a complex portion formed of a reinforced fiber and a resin and a resin portion formed of a resin. The first layer and the second layers form a multilayer structure. A reinforced area is formed by the first layers and the complex portions of the second layers and a shock absorption area is formed by the first layers and the resin portions of the second layers.

A vehicle structure comprising a body including a wheel house, a fender and an energy absorption member. The fender has an exposed A-side surface and an opposed B-side surface, with the fender including a laterally inner edge extending fore-and-aft that defines a portion of a hood opening, and the B-side surface adjacent to the laterally inner edge spaced from the wheel house in a vertical direction to define a crush gap. The energy absorption member is located in the crush gap between the wheel house and the fender, with the energy absorption member having a fender attachment flange secured to the B-side surface of the fender adjacent to the laterally inner edge, a body attachment flange secured to the wheel house, and an energy absorbing portion extending between the fender attachment flange and the body attachment flange, with the energy absorbing portion being curved in the vertical direction.

The technology relates to vehicle panels. The vehicle panel may comprise a top layer and a bottom layer. The top and bottom layers may be bonded together. The bond of the top and bottom layer may be a weld. One or more energy absorbing layers may be positioned between the top layer and the bottom layer. The one or more energy absorbing layers may be comprised of one or more energy absorbing materials. The energy absorbing layers may be aluminum honeycomb and polyurethane foam.

Present application discloses side chassis structure. Side chassis structure includes: apron reinforcement member; fender panel covering outside of the apron reinforcement member; and brackets connected to the fender panel. At least one of the brackets includes: main body including support portion supporting fender panel; front leg portion extending downward from front end of inner portion of main body in vehicle width direction, front leg portion being attached to apron reinforcement member; and rear leg portion which extends downward from rear end of the main body, rear leg portion being attached to apron reinforcement member. Front leg portion has inner slotted hole having long axis extending in vehicle width direction, and outer slotted hole which is formed outside inner slotted hole in vehicle width direction, outer slotted hole having long axis longer than long axis of inner slotted hole.

Provided is a vehicle hood capable of improving pedestrian protection performance by suppressing an increase in acceleration secondary peak while increasing an acceleration primary peak. A vehicle hood includes an outer panel, an inner panel, and a deformable part that deforms with the outer panel when the outer panel deforms toward the inner panel, in which the inner panel includes a bottom, an upright wall, and an opposed part, and the deformable part includes a joint part joined to an intermediate wall of the upright wall or the opposed part, and a displaceable part that is close to or in contact with the outer panel above the bottom and is capable of being downward displaced with the outer panel to below the joint part when the outer panel deforms toward the inner panel.

A vehicle hood assembly includes a hood outer panel, a hood inner panel coupled to and positioned below the hood outer panel in a vehicle vertical direction, where at least a portion of the hood inner panel is spaced apart from the hood outer panel in the vehicle vertical direction such that the hood outer panel and the hood inner panel define a gap between the hood outer panel and the hood inner panel, and a reinforcement strap coupled to at least one of the hood outer panel and the hood inner panel, the reinforcement strap including a base portion and a rippled portion that extends outward from the base portion in the vehicle vertical direction.

A front carriage for a motor vehicle includes a bumper covering and a support structure, which supports the bumper covering. At least one support device supports the bumper covering against the support structure in the direction of the vehicle height (z) and enables a deformation movement of the bumper covering relative to the support structure in longitudinal vehicle direction (x) in the event of a crash.

A vehicle front-end stiffener includes a hinge bracket pivotally coupled to a support bracket. The hinge bracket supports a stiffener beam. A spring engages the support bracket and the hinge bracket biasing the stiffener beam in a deployed position. A moving element in a locking mechanism can retractably interlock the hinge bracket when a vehicle exceeds a threshold speed to maintain the stiffener beam in the deployed position.