A cell phone stand has a base and a cell phone mounting bracket rotatably affixed to the base around a horizontal axis. The mounting bracket has a first jaw and a second jaw that is movable in a horizontal direction with respect to the first jaw. The first jaw has a first u-shaped channel with a first upper segment and a first lower segment. The second jaw has a second u-shaped channel with a second upper segment and a second lower segment. By adjusting the position of the jaws, the user may adjust a width between the first and upper segments, thus sizing the mounting bracket to receive a cell phone of a particular width. Even at the smallest such width, inner ends of the first and second lower segments of the u-shaped channels remain spaced from each other so as to permit the cell phone to be connected to an electrical cable while being held by the stand.

A sensor assembly for a vehicle includes a vehicle sensor, a shield panel that is positioned upstream of the vehicle sensor and that is pivotable, and a computer communicatively coupled to the shield panel. The computer is programmed to pivot the shield panel based on data representing a wind speed.

A loading bracket assembly includes a base bracket having an engagement portion that is disposed at an interior area of a composite vehicle structural component and that is accessible through the first wall. A fastener may be attached to the engagement portion of the base bracket and may extend through an intermediate wall of the composite vehicle structural component and a supportive structure of the vehicle. The engagement portion of the base bracket is configured to engage a component or an accessory, such as a tow hook, that applies a loading force to the base bracket that is substantially transferred to the supportive structure and bypasses the composite vehicle structural component.

An energy attenuating vehicle display mount includes an instrument panel support mounted to a dashboard, an instrument panel support bracket coupled to the instrument panel support, a display mount coupled to the instrument panel support bracket, and an energy attenuating fastener connecting the display mount to the instrument panel support bracket. The energy attenuating fastener accommodates movement of the display mount relative to the instrument panel support bracket.

A sensor mount structure, including: a first sensor device that includes a first sensor configured to detect surroundings information for a vehicle, and that is attached to an inner surface of a front windshield glass further toward a vehicle front and upper side than an interior mirror; a second sensor device that includes a second sensor configured to detect surroundings information for the vehicle, and that is attached to the inner surface of the front windshield glass further toward the vehicle front and upper side than the interior mirror and further toward the vehicle front side than the first sensor device; and a view angle hood member that is disposed at a vehicle front and lower side of the first sensor, the view angle hood member overlapping with the second sensor device in a vehicle front-rear direction in side view along a vehicle width direction.

A bracket for holding an in-vehicle device inside a window glass includes a base configured to be fixed to an inside surface of the window glass; right and left side portions protruding downward from the base; a locking member assembled so as to be movable between a first position and a second position; and at least one support portion configured to receive a supported portion provided in the in-vehicle device and inserted between the right and left side portions from a lateral direction while the locking member is located at the first position. When the locking member is moved to the second position while the supported portion is received by the support portion, the locking member is pressed against the supported portion so that the in-vehicle device is held in any of the front to rear direction and the up to down direction without rattling.

A vehicle accessory has an arm extending from a pocket. The arm preferably has sides which can flex and then push outwardly to assist in mechanical retention between seats of a vehicle to locate the pocket in front of a seat. The pocket may have at least three sides extending upwardly relative to a bottom, if not more, and accessory may be manufactured from a single planar sheet bent to shape.

A sensor assembly for a vehicle includes a vehicle sensor, a shield panel that is positioned upstream of the vehicle sensor and that is pivotable, and a computer communicatively coupled to the shield panel. The computer is programmed to pivot the shield panel based on data representing a wind speed.

A multi-tool includes a hollow heavy gauge tubular member having a king pin hook secured to an exterior first end a pair of hammer heads secured to an exterior second end opposite each other. A portion of the tube has a grip surface.

A roof antenna includes a base plate, an outer cover, an inner cover arranged under the outer cover and connected to the base plate, and a fastening device on the base plate arranging and fastening the roof antenna at an intended installation location. The inner cover accommodates at least one antenna element for receiving and/or transmitting high-frequency signals that is arranged on the base plate. The roof antenna includes a camera arranged under the outer cover and accommodated inside the inner cover. At least one of the outer cover and the inner cover has an opening for a recording field of the camera.