A closure system for a motor vehicle cargo bed includes a closure panel having a plurality of slats moveable between a deployed position and a retracted position, with each adjacent pair of the slats being pivotably connected to one another by a hinge unit for pivotal movement of the adjacent slats about a hinge axis. First and second guide track units are configured to be mounted to one side of the cargo bed to extend adjacent opposite side edge portions of the closure panel. A plurality of roller units, each having first and second rollers, are supported along the opposite side edge portions of the cover panel for rolling movement along the first and second guide track units, with each roller unit rolling about a roller axis that is coaxially aligned with one of the hinge axes.

A pop-up apparatus for a camera mirror system disposed inside a panel of a body of a vehicle includes a camera mirror assembly to provide a rear view of a vehicle, a camera mirror housing disposed to enclose the camera mirror system and configured to move to an outside of the panel, and a camera mirror frame configured to receive a driving force from a driving unit. The driving unit opens a cover of the panel while driving the camera mirror assembly to move to the outside of the panel through an opened portion of the panel in linkage with the camera mirror frame.

The present application relates to an automotive cargo or a tray area cover assembly. The cover assembly includes a cover for covering a cargo or a tray area of an automobile. One or more rib supports are provided for moving over the cargo or the tray area and supporting the cover.

A step device for a vehicle includes a movable step and a coupling member. The movable step includes a guide rail. The coupling member is configured to cause the movable step to move from a deployed position to a retracted position as a engaging part comes into sliding contact with a side wall of the guide rail that is located on an inner side in a vehicle width direction and, while pressing the side wall, moves inside the guide rail in a direction of closing a sliding door. The guide rail is configured such that a terminal end region on a closing side including a terminal end position at which the engaging part is located when the sliding door is fully closed constitutes a closing-side free running zone in which the engaging part does not press either of the side walls.

An actuator for motor vehicle applications, in particular for motor vehicle closing devices, comprising an electric motor, an actuating element which can be directly or indirectly acted upon via a drive train, and, arranged on a drive shaft of the electric motor, a drive wheel with an evoloid toothing, the drive train having at least one crown gear stage.

A variable air hole covering flap device is provided and selectively opens or closes an air hole formed in a wheel deflector or a wheel cover to allow air to be introduced toward a brake. The air hole is opened only when brake cooling of a vehicle is more necessary than aerodynamic performance of the vehicle to properly control the aerodynamic performance and the brake cooling performance of the vehicle as necessary.

A device for controlling a vehicle is provided. The device includes an input device for receiving a user input, a state sensing device for sensing a vehicle state change in response to the user input, and a controller configured to determine whether to apply a driving current of an actuator to a switching device based on the vehicle state change.

A robotic vehicle includes: a robotic vehicle body defining a storage compartment; a lid for closing the storage compartment; and an opening mechanism installable on an exterior of the robotic vehicle body connecting the lid to the robotic vehicle body for actuating the lid between an open configuration and a closed configuration, the opening mechanism comprising: a semi-tubular body coupled to an outer surface of the lid, the semi-tubular body including a first rotational plate disposed at a first edge thereof; and an actuator disposed inside of the semi-tubular body and coupled to the exterior of the robotic vehicle body, the actuator being operatively coupled to an inner surface of the first rotational plate, the actuator being configured to impart a torque onto the first rotational plate, thereby causing the semi-tubular body to pivot and actuate the lid for providing access to the storage compartment.

A tonneau cover comprising: (a) a slat; (b) a drive system adapted to move the slat; and (c) a disconnect connected to the slat and in communication with the drive system, wherein the disconnect is adapted to release from communication with the drive system so that the slat manually moves independently from the drive system.

A gas pressure spring is provided including a working cylinder which, together with a slidably mounted compensating piston, encloses a working chamber filled with a working medium. A slidably mounted working piston is fastened to a working rod. In the event of a temperature increase, a compensating medium in a compensating chamber expands. The compensating piston is acted upon by the pressure of the working medium and the pressure of the compensating medium) such that the volume of the working chamber is increased. The temperature dependency of the gas spring force should be reduced by a design which is as simple as possible. For this purpose, the compensating chamber is at least partially surrounded by the working rod. Thus, the compensating medium can be compactly accommodated, and the assembly of the gas spring is simplified.