A vehicle bumper assembly may include a fascia, a bumper beam arranged inside of the fascia including an upper portion and a lower portion, and a reinforcement block arranged only on the upper portion of the bumper beam and configured to absorb energy and to eliminate contact of the upper portion with the fascia during a collision.

The bumper reinforcement has a front surface flange, an upper surface web, a lower surface web, an upper lip, and a lower lip. An end of the upper surface web on the upper lip side is thicker than a center. When a collision load is applied to the front surface flange, the upper surface web extending in a direction orthogonal to the front surface flange from vicinity of an upper end of the front surface flange is deformed in an outward opened direction, and the upper lip extending downward from an extension end of the upper surface web is deformed in an inward closed direction.

The bumper reinforcement has a front surface flange, an upper surface web, a lower surface web, an upper lip, and a lower lip. An end of the upper surface web on the upper lip side is thicker than a center. When a collision load is applied to the front surface flange, the upper surface web extending in a direction orthogonal to the front surface flange from vicinity of an upper end of the front surface flange is deformed in an outward opened direction, and the upper lip extending downward from an extension end of the upper surface web is deformed in an inward closed direction.

A bumper device for a vehicle is arranged on one of a front side and a rear side of a vehicle cabin to extend in a vehicle width direction. The bumper device for a vehicle includes: a tubular portion, which is made of metal and integrally formed so as to have a tubular shape extending in the vehicle width direction; and a reinforcing member, which is formed so as to have a plate-like shape extending in the vehicle width direction along an inner surface of the tubular portion. A foamed resin charged into the tubular portion is foamed to be increased in volume, to thereby fix the reinforcing member inside the tubular portion.

A bumper device for a vehicle is arranged on one of a front side and a rear side of a vehicle cabin to extend in a vehicle width direction. The bumper device for a vehicle includes: a tubular portion, which is made of metal and integrally formed so as to have a tubular shape extending in the vehicle width direction; and a reinforcing member, which is formed so as to have a plate-like shape extending in the vehicle width direction along an inner surface of the tubular portion. A foamed resin charged into the tubular portion is foamed to be increased in volume, to thereby fix the reinforcing member inside the tubular portion.

A bumper module for a vehicle includes at least one shaped part that is unitarily deep-drawn from a sheet material. The shaped part has two connecting flanges facing a back side for fastening to side members of the vehicle and an arch which is pre-curved towards a front side connecting the connecting flanges. At least in lateral portions of the arch, the sheet material is laid into folds, which are elongated from the back side towards the front side.

A bumper module for a vehicle includes at least one shaped part that is unitarily deep-drawn from a sheet material. The shaped part has two connecting flanges facing a back side for fastening to side members of the vehicle and an arch which is pre-curved towards a front side connecting the connecting flanges. At least in lateral portions of the arch, the sheet material is laid into folds, which are elongated from the back side towards the front side.

Polymeric shock absorbing element for a vehicle including a substantially honeycomb structure having a plurality of channels which has a lateral external surface extending from a first open frontal end to a second open rear end, the shock absorbing element insertable and securable within an internal lateral cavity of a chassis of said vehicle, the internal lateral cavity being defined by at least two metallic plates. The lateral external surface includes at least one substantially planar face positioned on one side of the polymeric shock absorbing element and the additionally includes at least one metallic fixing element having a central portion which in turn includes a first central wall which is made integral with a corresponding substantially planar face of the lateral external surface, the at least one metallic fixing element additionally includes a plurality of side stiffeners which are weldable or made integral with the two metallic sheets.

Polymeric shock absorbing element for a vehicle including a substantially honeycomb structure having a plurality of channels which has a lateral external surface extending from a first open frontal end to a second open rear end, the shock absorbing element insertable and securable within an internal lateral cavity of a chassis of said vehicle, the internal lateral cavity being defined by at least two metallic plates. The lateral external surface includes at least one substantially planar face positioned on one side of the polymeric shock absorbing element and the additionally includes at least one metallic fixing element having a central portion which in turn includes a first central wall which is made integral with a corresponding substantially planar face of the lateral external surface, the at least one metallic fixing element additionally includes a plurality of side stiffeners which are weldable or made integral with the two metallic sheets.

An energy absorbing cell has a first structural element, a second structural element disposed parallel to and spaced apart from a first structural element, a first intermediate member, and a second intermediate member. Each intermediate member is disposed at an angle between the structural elements. A first end and a second end of each intermediate member are respectively attached to the structural elements. The intermediate members are formed from an elastic material. The angles of the intermediate members are selected such that application of a compressive force to displace the structural elements toward one another triggers a snap-through instability in both intermediate members. The energy absorbing cell is used, singly or in combination with one or more other energy absorbing cells, to form energy absorbing structures, such as vehicle bumpers or highway barriers, adapted to control the deceleration of an object impacting the energy absorbing structure.