A motor drive device for moving a vehicle sliding door is provided. The device includes an electric motor, a force transmission mechanism operationally connectable to the vehicle sliding door and the electric motor to transmit a drive force provided by the motor to the sliding door, sensors at least for determining an instantaneous position of the vehicle sliding door, an electronic control unit for activating at least the motor, and a shift clutch coupled to the force transmission mechanism and couplable to the motor for load-independent coupling of the motor to the force transmission mechanism. The control unit, in the event of application of a sufficient force to the sliding door during a power-driven movement, either elevates a speed of the vehicle sliding door by elevating the transmitted drive force or decouples the force transmission mechanism and the motor with the shift clutch.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

A vehicular rear slider window assembly includes an upper rail and a lower rail and a fixed window panel. The rails are attached at an inner surface of the fixed window panel above and below an opening. First and second movable window panels are movable along the rails. The drive system includes a drive element at the first movable window panel, a gear element rotatably mounted at a rail of the window assembly, and first and second toothed tracks attached at the respective movable window panel and extending toward and overlapping the other movable window panel. When the drive system is operated, the drive element imparts movement of the first movable window panel along the rails. Movement of the first movable window panel causes a corresponding movement of the second movable window panel in an opposite direction along the rails via engagement of the gear element with the toothed tracks.

A motor vehicle door, in particular a motor vehicle sliding door, having a motorized drive and a downstream coupling device for acting on a door leaf, and having a control unit for the drive and the coupling device. The coupling device is generally disengaged and is only engaged for the motorized driving of the door leaf.

A motor vehicle door, in particular a motor vehicle sliding door, having a motorized drive and a downstream coupling device for acting on a door leaf, and having a control unit for the drive and the coupling device. The coupling device is generally disengaged and is only engaged for the motorized driving of the door leaf.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

An actuator includes a motor, a first gear coupled to the motor, a second gear that meshes with the first gear, and a clutch. The clutch includes an outer ring and an inner ring. A plurality of wedge spaces are formed along a circumferential direction between an inner peripheral surface portion of the outer ring and an outer peripheral surface portion of the inner ring. The clutch further includes rolling elements provided in the wedge spaces. While a radial load is not applied to the outer ring, each rolling element does not engage with the outer peripheral surface portion or the inner peripheral surface portion, so that a clearance is generated. While the radial load is applied to the outer ring, each rolling element engages with the outer peripheral surface portion and the inner peripheral surface portion without the clearance.

An actuator includes a motor, a first gear coupled to the motor, a second gear that meshes with the first gear, and a clutch. The clutch includes an outer ring and an inner ring. A plurality of wedge spaces are formed along a circumferential direction between an inner peripheral surface portion of the outer ring and an outer peripheral surface portion of the inner ring. The clutch further includes rolling elements provided in the wedge spaces. While a radial load is not applied to the outer ring, each rolling element does not engage with the outer peripheral surface portion or the inner peripheral surface portion, so that a clearance is generated. While the radial load is applied to the outer ring, each rolling element engages with the outer peripheral surface portion and the inner peripheral surface portion without the clearance.