An active liftgate spoiler (10;100;200;300;400) used on a liftgate (8) of a vehicle (6). The liftgate has an upper surface (4) and is typically a rear liftgate or hatch on the rear side of the vehicle. A housing (11;104;202;302;412) is connected to the upper surface of the liftgate. There is a moveable panel (12; 102;204, 208; 306, 308;402,403) connected to the housing using a connection. The connection is formed by a four bar linkage (20,20′; 106, 106′;210,210′; 311,311′;411, 411′) that forms a portion of the connection between the moveable panel and the housing. An actuator (14;110;212;314;414), which in one embodiment is a single rotary actuator is connected to the four bar linkage and causes the movement of the moveable panel.

Provided is a vehicle rear spoiler control method, including the following steps: receiving a rear spoiler operation request; starting an environment perception apparatus of a vehicle, and acquiring environment perception data; performing obstacle detection in a preset range of a position where the rear spoiler of the vehicle is located according to the environment perception data; and controlling operation of the rear spoiler of the vehicle according to a result of the obstacle detection. By using the vehicle rear spoiler control method, the safety of operation of the rear spoiler can be improved. Further provided is an apparatus applying the vehicle rear spoiler control method and the vehicle.

Various disclosed embodiments include illustrative wing assemblies, wing systems, and methods. A wing assembly includes first drive cables, a flexible wing section, and a motor. The flexible wing section includes a flexible surface and frame members. One of the frame members is couplable to the first drive cables. The motor is couplable to a proximal end of the first drive cables and is configured to apply a longitudinal force to the drive cables. The applied force results in the flexible wing section curving in a predefined direction.

The invention relates to a rear closure system (2; 102) of a motor vehicle, comprising: a main body (4; 104), and a module (10; 110) that can be detached from the main body (4; 104) and can receive a device (24; 124),
the main body (4; 104) comprising a free space (12; 112) accessible through an opening (14; 114), the dimensions of the free space (12; 112) and the opening (14; 114) being such that the module (10; 110) can be inserted into, and removed from, the main body (4; 104).

An air conduction device for a motor vehicle including an air conduction element and a movement device with adjustment kinematics. The air conduction element is movable relative to the remaining body as at least part of a tail side part of the vehicle body. The air conduction element moves between an inoperative position and at least one final operating position. The tail side part has a flow guiding area along which air flows which is designed to face an area surrounding the motor vehicle. The air conduction element has a surface which is at least part of the flow guiding area. The air conduction element is configured in its final operating position to lengthen the flow guiding area in the direction of a longitudinal body axis (X) of the body. The adjustment kinematics are configured in the form of multipoint joint kinematics.

A vehicle has a spoiler fastened to an outer skin component of the vehicle. For this purpose, clip elements are provided on the outer skin component and are in engagement with corresponding mating clip elements of the spoiler. The clip elements have an end stop in a z-direction, which is oriented transversely to the surface of the outer skin component. Between the spoiler and the outer skin component there is an intermediate element, which is elastically compressed in the z-direction and presses the spoiler against the end stop. A method is provided for mounting the spoiler on the vehicle.

A system and methods are provided for a wing stabilizer charging system for recharging onboard batteries during operation of an electrically powered vehicle. The wing stabilizer charging system comprises a wing stabilizer configured to be coupled with a rear of the vehicle. One or more air inlets are disposed in the wing stabilizer and configured to receive an airstream during forward motion of the vehicle. Wind turbines are disposed within the wing stabilizer and configured to be turned by the airstream. A circuit box is configured to combine electricity received from the wind turbines into a useable electric current. A power cable extends from the circuit box and is configured to supply the useable electric current to any one or more electronic devices, such as any of an onboard battery for powering the vehicle, mobile phones or smart phones, portable music players, tablet computers, cameras, and the like.

This disclosure relates to an electrified vehicle configured to address an excess braking request, such as a braking request in excess of what can be met by an energy recovery mechanism, by selectively increasing the drag of the electrified vehicle. A corresponding method is also disclosed. An example electrified vehicle includes an energy recovery mechanism, an actuator configured to adjust a position of a moveable component influencing a drag of the electrified vehicle, and a controller. The controller is configured to instruct the energy recovery mechanism to meet a braking request and, when the braking request cannot be met by the energy recovery mechanism, the controller is configured to instruct the actuator to adjust the position of the moveable component to increase the drag of the electrified vehicle.

A dynamic vehicle stability control system for a vehicle may include an active wing extending laterally relative to a longitudinal centerline of the vehicle and configured to be rotatable to change an angle of attack relative to wind passing over the vehicle parallel to the longitudinal centerline, a repositioning assembly operably coupling the active wing to the vehicle, and a controller operably coupled to components and/or a sensor network of the vehicle to receive status information about the vehicle. The repositioning assembly may be operated based on a wing angle command received by the controller responsive to execution of a plurality of control algorithms executed by the controller. The controller may be configured to determine the wing angle command based on respective wing angle requests generated by each of the control algorithms.

A vehicular rear window assembly includes a window panel comprising an inner side and an outer side. A spoiler includes (i) a base portion that is adhesively attached at and along an upper region of the outer side of the window panel and (ii) a cover portion that is attached at the base portion. The vehicular rear window assembly, with the spoiler adhesively attached at and along the upper region of the outer side of the window panel, is configured for mounting at a rear portion of a cabin of the vehicle. With the vehicular rear window assembly mounted at the rear portion of the cabin of the vehicle, the inner side is toward the cabin of the vehicle and the outer side and the spoiler are exterior of the vehicle.