An impact absorption unit provided between an inside member and an outside member that form a vehicle body and configured to absorb an impact may include: a first absorption body which includes composite material and protrudes from an inside surface of the inside member toward the outer member, with an open receiving space formed in the first absorption body; and a second absorption body which includes composite material and protrudes from an inside surface of the outside member toward the inside member such that the second absorption body is inserted into the open receiving space.

A passenger compartment module block assembly is provided. The passenger compartment module block assembly includes a center block which is made of composite material and disposed within a central portion of a crash pad and provided with assembly components formed on opposite sides of the center block, a driver block which is made of composite material and coupled to a first-side assembly component of the center block and disposed adjacent to a driver seat. A passenger block which is made of composite material and is coupled to a second-side assembly component of the center block and disposed adjacent to a passenger seat. The center block, the driver block and the passenger block are assembled integrally with each other and are disposed between a dash panel and a crush pad of a vehicle and to improve torsion and bending stiffness of the vehicle.

A decklid (12) for an automobile (10) has an integral aerofoil (24) providing an aero duct (26) between the aerofoil (24) and an upper face section (16) of the decklid (12), the aerofoil (24) being produced hollow using a mandrel (106) to consolidate workpiece material (133) of the (aerofoil 24) inside a void (132) within mould parts (102), (104), the method and apparatus providing the decklid (12) with smoothly merging and continuous A surfaces, as well as smoothly merging B surfaces.

A vehicle pillar structure comprising a pillar portion extending in parallel with an outer end portion of a windshield and the pillar portion having a hollow structure, the pillar portion comprising an outer side wall at a vehicle exterior side of the pillar portion; an inner side wall at a vehicle cabin side of the pillar portion; and a pair of side walls linking the outer side wall and the inner side wall. At least a portion of the outer side wall is an outer side transparent portion, at least a portion of the inner side wall is an inner side transparent portion and, as viewed from a driver position, overlaps with the outer side transparent portion, and a tensile strength of the outer side wall is lower than that of the inner side wall.

A vehicle pillar structure comprising: a pillar member configuring a skeleton of a vehicle; a reinforcement member disposed inside the pillar member, bridging a pair of side portions of the pillar member, and reinforcing the pillar member; and an infrared transmission inhibition member, the infrared transmission inhibition member covering the reinforcement member at least from a design surface side of the pillar member and inhibiting transmission of infrared radiation.

A refrigerated composite semi-trailer is disclosed that may improve thermal efficiency, fuel efficiency, and costs of manufacturing.

A vehicle is disclosed having a composite cargo body. A floor of the cargo body is constructed of a first composite material. A roof, a right sidewall, a left sidewall, and a nose of the cargo body are constructed of a second composite material different from the first composite material. Various components of the composite cargo body are bonded together with an adhesive. Mechanical fasteners also may be used to join other components of composite cargo body.

In a method of manufacturing a front pillar, a resin layer is formed by discharging a transparent resin from first nozzles of a 3D printer and discharging a supporting material from second nozzles of the 3D printer, while moving the first nozzles and the second nozzles in a direction corresponding to a length direction of a front pillar. Afterwards, the first nozzles and the second nozzles are moved relatively in a direction corresponding to a transverse direction of the front pillar and in a direction of moving away from the resin layer. By repeating the forming of the resin layer and the relative moving of the first nozzles and the second nozzles, the resin layers are layered in the direction corresponding to the transverse direction of the front pillar such that the front pillar is manufactured.

An assembly for a vehicle body includes the following components: a sill, roof frame, hinge pillar, outer shell and inner shell. The assembly is characterized by being very rigid and very firm, and having a high degree of structural possibilities whilst being relatively light in weight. The sill and the roof frame are formed by hollow profiles. The hinge pillar is made from an extruded fibrous composite. The sill, the roof frame and the hinge pillar are surrounded on the outer side and the inner side, at least partially, by the outer shell and the inner shell, such that the assembly components form a composite unit.

A cargo vehicle is disclosed having a composite floor assembly with at least one conduit extending along a length of the composite floor assembly. The at least one conduit may include a first internal cavity and a second internal cavity. The first internal cavity may be configured to route at least one vehicle component. The second internal cavity may be configured to receive at least one vehicle component or a plurality of mechanical fasteners. The mechanical fasteners may be used to couple a base rail to the composite floor assembly.