A vehicle door hinge that has a desorption function while enabling weight reduction and increasing production efficiency. The vehicle door hinge comprises a base member (2U) fixed to the door-side of the vehicle, a base member (3U) fixed to the vehicle body side; a hinge shaft (4U) rotatably connects the base members (2U, 3U) to each other; a screwed body (5U) that is detachably screwed in the axial direction to the hinge shaft (4U) so that the base member (3U) and the hinge shaft (4U) rotate integrally; bushes (6U, 7U) fitted into a shaft holes (22U) of the base member (2U) so that the base member (2U) and the hinge shaft can rotate relative to each other; and a retaining portion (8U) for preventing the hinge shaft (4U) from coming off from the shaft hole (22U) of the base member. The base members (2U, 3U) are cast from aluminum alloy.

An insulating element for insulating a structural element in a vehicle including a base element, an additional element and a fixing element. The base element has a first coupling element and expandable material. The additional element has a second coupling element and expandable material. The base element and the additional element are connected to one another by the coupling elements.

The present invention is directed to a closed structural component and process for preparing the same.

Disclosed is a gear driving device for automotive movable parts. The gear driving device comprises a motor (100) and a driver gearbox (200). The driver gearbox comprises multiple stages of planetary gear assemblies (1, 2) connected in series and a gear assembly (3) with few teeth number difference. A first-stage planetary gear assembly in the multiple stages of planetary gear assemblies is connected to the motor; and the last-stage planetary gear assembly in the multiple stages of planetary gear assemblies is connected to the gear assembly with few teeth number difference. The gear driving device has the advantages of small volume, light weight and high working efficiency.

The invention relates to a bumper arrangement for a motor vehicle, with a crossmember, a body element, a crash box arranged between crossmember and body element. The invention is distinguished in that a) a front axis of rotation is formed by a structural element, and a rear axis of rotation by a further structural element in the region of an inner wall of the crash box, and b) a tension relief element or a tension delay element is arranged in the region of an outer wall of the crash box.

A glass sealing system includes a glass portion and a first adhesive layer disposed along an exterior surface of the glass portion. The glass sealing system also includes a cover with a first surface secured to the first adhesive layer and a second surface opposing the first surface. The glass sealing system includes a second adhesive layer disposed on the second surface and configured to secure the cover to a support structure. The cover obscures the second adhesive layer from view of a user looking through the glass portion toward the support structure.

A vehicle structural member includes an elongate hollow member having an integrated structure, and supporting members joined to the elongate hollow member. The elongate hollow member includes: a first portion that includes a first pipe, a second pipe disposed outside the first pipe and extending along the first pipe, and a connection portion extending along the first pipe and the second pipe, formed integrally with the first pipe and the second pipe, and connecting the first pipe and the second pipe; and a second portion that includes the first pipe continuing from the first portion, and does not include the second pipe.

A vehicular energy absorbing member that is disposed between a bumper reinforcement and a framework of a vehicle includes an energy absorbing portion that has a tubular shape and is configured to absorb impact energy by being plastically deformed to be compressed in an axial direction. An outer circumferential surface of the energy absorbing portion has a circular tubular shape and an inner circumferential surface of the energy absorbing portion includes a ridge portion having a shape extending in the axial direction of the energy absorbing portion.

A vehicle flow influencing assembly includes, among other things, a downforce generator that extends laterally outward from an area of a vehicle, and that extends longitudinally from a leading edge portion to a trailing edge portion, the trailing edge portion aligned along a longitudinal axis of the vehicle with a side mirror of the vehicle, the downforce generator configured to influence flow to reduce buffeting.

There is provided an active drag-reduction system having first 22 and second 24 fluid outlets located on a vehicle 10 adjacent to a low pressure (drag) region 12, wherein fluid ejected from the second fluid outlet 24 is at a higher pressure/ejection velocity than from the first fluid outlet 22. Turbulent and/or low pressure regions adjacent to vehicles are not uniform, but rather have a varying intensity. For instance, the centre of a region may have a lower pressure and/or more turbulent nature than the periphery of the region. The system may inject relatively higher pressure air (or relatively higher speed air) into the relatively lower pressure/more turbulent part of the low pressure/turbulent region, and relatively lower pressure air (or relatively lower speed air) into the relatively higher pressure/less turbulent part of the low pressure/turbulent region, compared to each other.