A device that enables the correct ergonomic adjustment, by means of preset longitudinal positions, of the advancement and retreat of the motor vehicles seats, to guarantee comfort and safety of the driver as well as of the passengers. The device is made up by two rails (special and differentiated profiles), the upper rail (1) having a flat base (10) with flaps at tangent arcs (11 to 15) and the lower base (2) having tangential curved flaps (21 to 27), being fit and inserted in the inner spaces of the flaps by bearing balls (3). It further includes stops (16 and 28) of longitudinal movement and a position lock (4) activated by a bi-articulated mechanism (5) through a tubular lever (6), with vertical activation.

An impact absorbing structure includes an impact absorbing member made of CFRP, and the impact absorbing member includes a pair of left and right side wall portions and upper and lower coupling wall portions each coupling the side wall portions. Each of the pair of side wall portions includes a plurality of curved portions. Each of the curved portions is formed such that a leftward/rightward direction depth thereof decreases toward a front side. Each of the pair of side wall portions includes: a plurality of first carbon fibers arranged to extend in a forward/rearward direction and constituting most of reinforced fibers contained in the side wall portion; and a plurality of second carbon fibers arranged to extend in a direction intersecting with the first carbon fibers. The plurality of second carbon fibers are arranged at both thickness direction end vicinity parts of each of the side wall portions.

A battery box for an electric vehicle includes an Al casting that extends between and joins to a BIW or chassis rails of the electric vehicle. The Al casting includes a bottom wall, a side wall with a pair of rails that are securely attached to the BIW or chassis rails of the vehicle, and a plurality of cross members. The bottom wall, the side wall, and the plurality of cross members define a structural enclosure with a plurality of battery compartments and at least one crush zone, and the structural enclosure is load bearing member of the electric vehicle.

A pre-buck apparatus for a vehicle body assembling system comprises a pre-buck section and a main buck section that are set along a transfer path of a floor assembly. The pre-buck apparatus is formed in the pre-buck section, and while the side assembly is disposed in each of opposite sides of the transfer path in the pre-buck section, the pre-buck apparatus controls a lower portion of the side assembly, and the lower portion of the side assembly is pre-assembled to the floor assembly using a first welding robot.

A hybrid arm according to an embodiment of the present disclosure may include: a first body made of a metal material and formed with a plurality of end portions; a second body formed so as to fill an inner side of the first body by being insert-injection-molded to the first body; and a ball joint formed integrally at a first end portion among the plurality of end portions of the first body. The ball joint may include: a reinforcement member coupled to the first end portion; a bearing member formed with a space therein; a ball stud including a ball rotatably inserted into the space of the bearing member and a rod extending upward of the ball; and a housing interposed between the reinforcement member and the bearing member and formed integrally with the second body.

A lightweight vehicle pan assembly and for attachment to a vehicle frame via welding includes at least one metal flange and a molded pan body. The at least one metal flange has a weld portion adapted for welded attachment to the vehicle frame and an interface portion extending from the weld portion. The molded pan body has a base wall and at least one side wall extending upward from the base wall. The interface portion of the at least one metal flange is embedded in the at least one side wall of the molded pan body. The interface portion includes at least two rows of apertures defined therein for increasing a bond strength between the at least one metal flange and the molded pan body.

To provide a lighter weight and more robust component for use on a concrete mixer truck, a collector is formed of a non-metallic material which has more desirable characteristics. The collector is further strengthened by providing internal reinforcing structures and reinforced mounting structures so the collector can be effectively coupled to the concrete mixer truck. Additionally, the non-metallic material has desirable characteristics, such as low surface friction levels, high strength to weight ratios, and desirable puncture resistance. All of these characteristics combine to provide a lighter weight, more effective collector.

An embodiment floor structure of a vehicle includes a pair of side seals disposed to face each other in a vehicle width direction, and respectively disposed in a vehicle length direction, a floor frame disposed between the pair of side seals and including a pair of longitudinal frames respectively arranged along the pair of side seals and at least one transverse frame mounted between the pair of longitudinal frames in the vehicle width direction, and at least one core structural member disposed in a space provided by the floor frame and including a material for absorbing impact.

A rotary electric machine unit includes a rotary electric machine, a case accommodating the rotary electric machine, a power control unit configured to control the rotary electric machine and mounted on the case by directly connecting a unit-side connector provided on a bottom surface of the power control unit to a case-side connector provided on an upper surface of the case; and a sound absorbing member provided between the upper surface of the case and the bottom surface of the power control unit.

An object of the present invention is to provide a structure body, which allows the obtaining of superior impact performance while suppressing increases in thickness and weight of a plastic plate and reducing cost, and a method for manufacturing that structure body. Provided is a structure body (1) provided with a structure (10) made of a metal or a thermosetting resin, a plastic plate (14) attached to a surface (10a) of the structure (10) with double-sided tape (12), and a non-foamed plastic sheet (A) having a glass transition temperature of 20 C. or lower arranged between the structure (10) and the plastic plate (14). Also provided is a method for manufacturing the structure body (1) that includes arranging the plastic sheet (A) between the structure (10) and the plastic plate (14) when attaching the plastic plate (14) to the surface (10a) of the structure (10) with the double-side tape (12).