A manufacturing method for a joined body, includes: bringing a first member and a second member into contact with each other, at least one of the first member and the second member being made of thermoplastic resin, and the second member having a recessed portion on a joining surface to be joined to the first member; and welding the first member and the second member together, including welding a contact portion of the first member and the second member by melting the thermoplastic resin by frictional heat generated in the contact portion by relative movement of the first member and the second member, in a state in which the first member and the second member are in contact with each other.

An impact energy absorbing member includes an energy absorbing portion and an attachment portion. The attachment portion is fastened to the bumper reinforcement using a fastener, the fastener extending through the attachment portion and a wall of the bumper reinforcement and including an axis that extends in a direction intersecting an axial direction of the energy absorbing portion. The attachment portion and the energy absorbing portion are in a positional relationship in which the energy absorbing portion does not overlap the fastener when the impact energy absorbing member is viewed in a direction from the bumper reinforcement toward the energy absorbing portion in a vehicle front-rear direction.

A bumper beam formed of fiber reinforced resin containing continuous fibers oriented at least in the vehicle width direction sufficiently absorbs the collision energy of a high-speed collision in the fiber reinforced resin. The bumper beam also has a center portion positioned in the center in the vehicle width direction and protruding outward in the front-back direction, and right and left outer portions inclined from the respective ends of the center portion seen in the vehicle width direction toward the inner side in the front-back direction. The outer portions each have a resin foam member protruding outward in front-back direction. Thus, at the time of a low speed collision, the resin foam member is crushed to absorb part of the collision energy so that the energy is absorbed and distributed over the center and outer portions, protecting the car body frame from deformation.

An energy absorber for a vehicle, comprising: a continuous beam to extend across a width of vehicle, the beam defining a plurality of inward facing cavities in a center section, with adjacent inward facing cavities separated from one another by an inward facing rib, and at each end portion a plurality of outward facing cavities, with adjacent outward facing cavities separated from one another by an outward facing rib, wherein the center section includes a panel that is continuous on its outward side, and that forms a relative bottom of each of the plurality of inward facing cavities with its inward face.

An energy-absorbing structure includes first and second components. The first component includes a polymer and a plurality of reinforcing fibers disposed therein. The first component includes first bumper and crush member portions respectively defined by first and second walls. The second wall projects from and is integrally formed with the second wall. At least some of the fibers continuously extend between the first and second walls. The second component includes the polymer and a plurality of reinforcing fibers. The second component includes second bumper and crush member portions respectively defined by third and fourth walls. The fourth wall projects from and is integrally formed with the third wall. At least some of the fibers continuously extend between the third and fourth walls. The first and second components are joined. The first and third walls cooperate to define a bumper. The second and fourth walls cooperate to define a crush member.

A bumper for a vehicle includes a bumper crossbeam and two crash boxes extending away from a back of the bumper crossbeam. A one-piece blank made of fiber-reinforced sheet material extends from a wall section of the bumper crossbeam connecting the crash boxes, right into the crash boxes.

A structural component, in particular for a vehicle, includes a beam and at least one energy absorption device which is disposed on a portion of the outer surface of the beam. The beam is profiled and has at least one inner chamber.

A method is disclosed for manufacturing a bumper structure. A blank made out of fiber-reinforced composite material is deep drawn in a molding tool to form a bumper cross member having a first groove. A first rib structure is molded in the first groove onto the bumper cross member in the molding tool.

The present invention relates to a bumper system for a vehicle, and provides a bumper system for a vehicle, the system comprising: a bumper beam which has a fastening hole formed through each end thereof in the forward and backward direction; a crash box which is inserted into the fastening hole of the bumper beam; and a bracket which is fastened to the bumper beam so as to be able to prevent the crash box from being separated. Thereby, the system can meet both low speed crash regulations and RCAR performance.

The present disclosure discloses a bumper beam for a motor vehicle including a center portion free of mobility-specificity and side portions that may be altered according to design and specification of the mobility to secure collision performance so that the bumper back beam of which collision performance is secured and which satisfies various mobilities may be flexibly applied. Accordingly, it is possible to configure the back beam satisfying various mobilities based on a standardized model to secure collision performance so that manufacturing cost is reduced by assembling and producing the back beams with minimum molds.