A bumper for a vehicle, including at least one profile, in particular an open profile, from a first material, having at least one ribbed structure formed from ribs from a second material, the ribbed structure being disposed along the profile at least in portions and at least in portions being connected to the profile in a force-fitting, form-fitting and/or materially integral manner in order for the profile to be reinforced. The bumper meets the requirements set in the event of collision loads and can be optimized in terms of load is achieved in that the ribbed structure is formed from fiber-reinforced plastic and has at least one first region and one second region, which differ from one another in terms of at least one property.

A shock absorbing structure for a vehicle 1 is provided which includes a bumper beam 67 connecting together a pair of shock absorbing members 61, 61 made of a fiber-reinforced resin. The shock absorbing member 61 includes an upper wall portion 62a, a lower wall portion 62b, a side wall portion 62c having a recess 63, an upper flange portion 62d, and a lower flange portion 62e, and a vehicle-width-direction outer side is open. An outer edge portion 62o extends in a front-rear direction, an inner edge portion 62i extends in an inclined manner, and a width of each of the upper wall portion 62a and the lower wall portion 62b is wider on a rear side than a front side. Step portions 64 make an interval between the upper wall portion 62a and the lower wall portion 62b become narrower on a vehicle-width-direction inner side than the vehicle-width-direction outer side.

A load distribution device for a vehicle configured to distribute loads in the event of a collision involving the vehicle, the load distribution device comprises: an upper beam extending in a transversal direction and connectable to at least one upper load path of the vehicle; a lower beam extending in the transversal direction and arrangeable at at least one lower load path of the vehicle; and an interconnecting portion connecting the upper beam and the lower beam, wherein the upper beam, the lower beam, and the interconnecting portion are made in a single piece.

A back beam for a vehicle having a charge and discharge function utilizing carbon fiber used as a reinforcing material in a back beam of a vehicle, may include a reinforced negative electrode portion formed of carbon fiber and formed to extend in the width direction of the vehicle, a positive electrode portion disposed opposite to at least a portion of the reinforced negative electrode portion, a solid electrolyte portion disposed between the reinforced negative electrode portion and the positive electrode portion to be in contact with the reinforced negative electrode portion and the positive electrode portion, and a molding portion formed of resin and surrounding the reinforced negative electrode portion, the positive electrode portion and the solid electrolyte portion.

A bumper for a vehicle, including at least one profile, in particular an open profile, from a first material, having at least one ribbed structure formed from ribs from a second material, the ribbed structure being disposed along the profile at least in portions and at least in portions being connected to the profile in a force-fitting, form-fitting and/or materially integral manner in order for the profile to be reinforced. The bumper meets the requirements set in the event of collision loads and can be optimized in terms of load is achieved in that the ribbed structure is formed from fiber-reinforced plastic and has at least one first region and one second region, which differ from one another in terms of at least one property.

A bumper reinforcement includes a body portion joined to a vehicle body front end portion through portions of the body portion on a first direction side and a second direction side in the vehicle width direction, and a reinforcing member joined to the body portion along the body portion. The body portion includes a first standard rigidity region, a high rigidity region, and a second standard rigidity region arrayed next to each other in this order in the vehicle width direction. The high rigidity region has rigidity higher than rigidity of the first standard rigidity region and rigidity of the second standard rigidity region and is positioned in a center of the body portion in the vehicle width direction. The reinforcing member is provided so as to at least partially overlap the high rigidity region and the first standard rigidity region through a first boundary position.

Disclosed is a polyolefin resin, a method for preparing the same, and a vehicle rear bumper beam using the same. The polyolefin resin is characterized by being composed of a thermoplastic resin composite including a polymer base including a polypropylene homopolymer, which has a molecular weight distribution of 2 to 10, and a colorant; and a fiber reinforcing material that is impregnated into the polymer base and has a length of 5 to 20 mm, wherein 10 to 50 wt % of the fiber reinforcing material is included with respect to the polyolefin resin. The method is characterized in that a thermoplastic resin composite is formed by impregnating a molten mixture including a polypropylene homopolymer, which has a molecular weight distribution of 2 to 10, and a colorant with a fiber reinforcing material having a length of 5 to 20 mm.

Apparatus and methods for additively manufactured structures with augmented energy absorption properties are presented herein. Three dimensional (3D) additive manufacturing structures may be constructed with spatially dependent features to create crash components. When used in the construction of a transport vehicle, the crash components with spatially dependent additively manufactured features may enhance and augment crash energy absorption. This in turn absorbs and re-distributes more crash energy away from the vehicle's occupant(s), thereby improving the occupants' safety.

A method to prepare a composite laminate object containing an extrusion grade 7xxx Al substrate and a fiber-reinforced polypropylene layer adhesively laminated to the substrate; is provided. The process includes shaping and cutting an extruded 7xxx aluminum to a profile, assembling a layered arrangement of the 7xxx Al profile as substrate, an adhesive film and a fiber reinforced polypropylene preform, heating the layered arrangement to a temperature of 160-175 C. to melt the polypropylene and activate the adhesive film, applying pressure to at least a surface of the fiber reinforced polypropylene preform to mold the preform to the shape of the extruded 7xxxAl substrate and obtain a semi-finished laminate object, cooling the semi-finished laminate object to 90 C., optionally, cooling the semi-finished laminate object to room temperature for inventory storage; heat treating the semi-finished laminate object at 90 C. for 2 to 8 hours; and then heat treating the semi-finished laminate object at 130 C. to 150 C. for 8 to 16 hours; and cooling the heat treated object to obtain the composite laminate object.

Disclosed are a vehicle back beam capable of maximizing impact performance and reducing product weight; and a vehicle including same. According to one embodiment of the present invention, provided is a vehicle back beam which includes: a back beam body; and a back beam reinforcing part which is formed in at least one section of the back beam body and composed of a highly deformable composite material.