In order to absorb collision energy so as to prevent an increase in reaction force against a pedestrian to a level higher than or equal to a certain level during collision, a bumper absorber of the present invention includes: a trunk part that extends in an X direction and that is simply compressed in the X direction in response to an impact; and a branch part that branches off from the trunk part toward a rear of a vehicle body, the branch part having a branching part in which the branch part branches off from the trunk part and which is provided with a breakage inducing part that causes breakage between the trunk part and the branch part in response to the impact.

An impact-absorbing structure includes: a bumper face; a bumper beam; and an impact-absorbing member interposed to be compressively deformed between the exterior member and the movable-body-side rigid member. The movable-body-side rigid member, in an up-and-down direction of the movable-body-side rigid member, includes: a plurality of recesses recessed toward the movable body; and a protrusion protruding forward the movable body to be formed between the plurality of recesses. The plurality of recesses each have a vertical width gradually tapering toward the movable body, and the impact-absorbing member is fitted into at least two of the plurality of recesses.

A vehicle front end structure includes a front bumper assembly, an overrider bracket, and a vehicle sensor. The front bumper assembly has a reinforcement bracket and a first energy absorbing member attached to forward portions of a vehicle body structure. The reinforcement bracket is located rearward of and spaced apart from a forward section of the first energy absorbing member defining a space therebetween. The first energy absorbing member further has a first lateral portion and a second lateral portion with a central gap defined therebetween. The overrider bracket is installed to the reinforcement bracket and is located within the central gap between the first lateral portion and the second lateral portion. The overrider bracket defines a pocket area with a second energy absorbing member installed within the pocket area. The vehicle sensor is supported to vehicle body structure and positioned above the second energy absorbing member.

[Problem]

To increase rigidity.

[Solution]

Provided is a structure including a main body portion, a plurality of reinforcement members arranged on the main body portion, each of the reinforcement members including a base material formed of resin or metal. Provided is a manufacturing method of a structure which includes a main body portion having a hollow configuration surrounding an internal space thereof. The manufacturing method includes a preparation step of preparing a plurality of reinforcement members each including at least a base material formed of resin or metal, a carrying-in step of carrying the plurality of reinforcement members into the internal space from an opening arranged at the main body portion, and a step of arranging a fixing portion which fixes the plurality of reinforcement members into the main body portion.

An apparatus for outputting a virtual engine sound includes: an output device that outputs the virtual engine sound; a bumper beam connected to a rear surface of the output device; and a bumper foam connected to the output device and the bumper beam while opening left and right side surfaces of the output device. The apparatus for outputting a virtual engine sound may improve a virtual engine sound output efficiency by utilizing a sound pressure radiated from a side surface of the virtual engine sound output device.

An increased amount of absorption of a load from the diagonally upper front side is achieved even in, for example, a vehicle having a high vehicle height. A first shock absorbing member is provided inside a bumper face upper to absorb a load from the diagonally upper front side, a second shock absorbing member is mounted on a front face portion of a bumper beam, and a third shock absorbing member is disposed below the first shock absorbing member and between a bumper face and the bumper beam to absorb a load from the diagonally upper front side. The rigidity of the first and third shock absorbing members in the up-down direction is higher than rigidity of the second shock absorbing member in the front-rear direction.

A vehicle front end structure includes a front bumper assembly, an overrider bracket, and a vehicle sensor. The front bumper assembly has a reinforcement bracket and a first energy absorbing member attached to forward portions of a vehicle body structure. The reinforcement bracket is located rearward of and spaced apart from a forward section of the first energy absorbing member defining a space therebetween. The first energy absorbing member further has a first lateral portion and a second lateral portion with a central gap defined therebetween. The overrider bracket is installed to the reinforcement bracket and is located within the central gap between the first lateral portion and the second lateral portion. The overrider bracket defines a pocket area with a second energy absorbing member installed within the pocket area. The vehicle sensor is supported to vehicle body structure and positioned above the second energy absorbing member.

A self-diagnosing sensor system for a vehicle is provided. The vehicle has a bumper with fascia material. The sensor system includes an elongated, deflectable cable disposed in the bumper generally adjacent to the fascia material. A tensioning and sensing unit is coupled to each end of the cable and fixed to the vehicle. Each unit includes a tension sensor electrically connected with an ECU of the vehicle such that the ECU receives signals from the tension sensors regarding tension in the cable, indicative of 1) whether the bumper has been impacted based on deflection of the cable from a sensing position, or 2) whether damage to the cable or a tensioning and sensing unit has occurred.

A vehicle bumper assembly (12) that includes a first energy absorbing member (22), a second energy absorbing member (24) and a vehicle facia member (26). The first energy absorbing member (22) is made of non-expanded polypropylene and is configured to directly attach to a vehicle body structure (14). The second energy absorbing member (24) is made of expanded polypropylene and is directly attached to a portion of the first energy absorbing member (22) spaced apart from the vehicle body structure (14). The vehicle facia member (26) is shaped and contoured for a predetermined vehicle body style. Further, the vehicle facia member (26) is configured to attach to the vehicle body structure (14). The vehicle facia member (26) covers and at least partially conceals the first energy absorbing member (22) and the second energy absorbing member (24).

An increased amount of absorption of a load from the diagonally upper front side is achieved even in, for example, a vehicle having a high vehicle height. A first shock absorbing member is provided inside a bumper face upper to absorb a load from the diagonally upper front side, a second shock absorbing member is mounted on a front face portion of a bumper beam, and a third shock absorbing member is disposed below the first shock absorbing member and between a bumper face and the bumper beam to absorb a load from the diagonally upper front side. The rigidity of the first and third shock absorbing members in the up-down direction is higher than rigidity of the second shock absorbing member in the front-rear direction.