A flexible coupling and an actuator for shaft-driven structures are provided. The flexible coupling includes a first half coupling, a second half coupling and a flexible member connected between the first half coupling and the second half coupling. One end face of the flexible member is provided with at least two connection portions extending along the axial direction. The first half coupling includes a support portion configured to support the radially inner surface of each connection portion and first transmission portions configured to fill circumferential gaps between the connection portions. The second half coupling includes second transmission portions equal in number to the connection portions. The second transmission portions cover radially outer side surfaces of the connection portions in a one-to-one manner. The flexible coupling can prevent the flexible member from being disengaged from between the two half couplings during operation. The actuator includes the preceding flexible coupling.

A flexible coupling and an actuator for shaft-driven structures are provided. The flexible coupling includes a first half coupling, a second half coupling and a flexible member connected between the first half coupling and the second half coupling. One end face of the flexible member is provided with at least two connection portions extending along the axial direction. The first half coupling includes a support portion configured to support the radially inner surface of each connection portion and first transmission portions configured to fill circumferential gaps between the connection portions. The second half coupling includes second transmission portions equal in number to the connection portions. The second transmission portions cover radially outer side surfaces of the connection portions in a one-to-one manner. The flexible coupling can prevent the flexible member from being disengaged from between the two half couplings during operation. The actuator includes the preceding flexible coupling.

An opening and closing body control apparatus for a vehicle includes an assist control portion configured to detect an operation of an opening and closing body of the vehicle by an operator or a user and control voltage applied to a motor serving as a drive source which applies a drive force to the opening and closing body during the operation of the opening and closing body by the operator or the user. The assist control portion applies an assist voltage and an offset voltage alternately to the motor to operate an assist control for applying the drive force to the opening and closing body. The assist voltage for rotating the motor at a rotation speed which corresponds to an operation speed of the opening and closing body and the offset voltage being lower than the assist voltage.

A hinge assembly includes a tailgate bracket securable to a vehicular tailgate, a support bracket securable to a vehicular bed, a torque shaft, and a crank. The tailgate bracket includes a socket. The support bracket includes a support. The torque shaft is supported by the support for axial rotation. The torque shaft includes a tailgate-side head and a crank-side head. The tailgate-side head and the socket are configured to make a head-and-socket connection with one another. The crank-side head includes an external profile. The crank includes a shaft-side base and an actuator-side base, a load arm extending therebetween, and at least one of a dogleg along the shaft-side base, the load arm and the actuator-side base, and an embossed rib extending along the load arm. The shaft-side base includes an internal profile. The external profile and the internal profile are configured to make a shaft-and-hub connection with one another.

A vehicle is disclosed that includes: a vehicle body defining a door frame; a vehicle door that is movably connected to the vehicle body; and an actuation system. The vehicle door includes: an inner panel that is secured to the door frame; an outer panel that is secured to the inner panel; a reinforcement that is secured between the inner panel and the outer panel; and a support bracket that is secured to the reinforcement and which includes a body with a generally planar configuration. In contrast to the door frame, which includes a metallic material, the inner panel and the outer panel each include a non-metallic material. The actuation system is connected to the vehicle door to facilitate opening and closure thereof and extends through the reinforcement and the support bracket.

A system for controlling a vehicle power tailgate includes a latch structured to be movable to a latching position when the latch is engaged with a portion of a tailgate so as to maintain the tailgate in a closed position associated with the latching position of the latch. A latch actuator operably connected to the latch to control operation of the latch. A memory is communicably coupled to the processor and stores a tailgate control module including instructions that when executed by a processor cause the processor to, responsive to receipt of a tailgate opening command, control operation of the latch actuator to attempt move the latch to an over-stroke position of the latch and, responsive to a failure to move the latch to the over-stroke position within a predetermined time period, control operation of the latch actuator to move the latch to a fully-latched position of the latch.

A linkage for opening and closing a lid through actuation of an electric motor 12 includes a base bracket 21 extending in a longitudinal direction of a vehicle, and a driving lever 14 having one end pivotally connected to the bracket 21 and the other end connected to the lid. The driving lever is driven via a pinion 22 by a sector gear 31 driven by the electric motor. The sector gear is attached to the bracket 21. The electric motor is fixed to a motor bracket 11 and attached via the motor bracket 11 to the bracket. Loosening a member supporting a lateral end portion of the motor bracket 11 and a bolt 41 fixing the bracket 11 to the bracket 21 allows the pinion and the sector gear to be axially disengaged from each other.

A method and a device for controlling door movements of a controllable door of a motor vehicle. A control device and a sensor arrangement are assigned to the door and the door has a controllable motion influencing device. A motion of a door wing of the door is controlled and influenced by the motion influencing device to alternate between a closed position and an open position. The motion influencing device includes a driving device with a drive motor. The sensor arrangement includes a current sensor which detects the motor current of the drive motor. While closing the door wing the control device detects an obstacle when the door wing is not yet closed and the power input of the drive motor rises above a predetermined threshold. Then the control device stops the drive motor.

In one form, the invention relates to a door drive for a door, the door drive comprising: a drive motor, a drive shaft drivable and thereby rotatable by the drive motor, a clutch, and a threaded spindle which is drivable and thereby rotatable by the drive shaft via the clutch, wherein the clutch comprises: a catch element, an actuating element which, by rotating the drive shaft, is drivable and thereby rotatable around an actuation rotational axis by the drive shaft, the actuating element comprising at least one first actuation area, and a clutch element which comprises at least one second actuation area corresponding to the first actuation area, wherein the clutch element is translationally movable along the actuation rotational axis relative to the catch element between at least one decoupling position in which the clutch element is decoupled from the catch element, and at least one coupling position in which the clutch element is coupled to the catch element, and wherein a relative rotation between the actuating element and the clutch element, the relative rotation being effectable by rotating the drive shaft, can be converted, by means of the actuation areas, into a translational movement of the clutch element from the decoupling position into the coupling position, the translational movement taking place along the actuation rotational axis, relative to the catch element, relative to the actuating element and in the direction of the catch element.

In one form, the invention relates to a door drive for a door, the door drive comprising: a drive motor, a drive shaft drivable and thereby rotatable by the drive motor, a clutch, and a threaded spindle which is drivable and thereby rotatable by the drive shaft via the clutch, wherein the clutch comprises: a catch element, an actuating element which, by rotating the drive shaft, is drivable and thereby rotatable around an actuation rotational axis by the drive shaft, the actuating element comprising at least one first actuation area, and a clutch element which comprises at least one second actuation area corresponding to the first actuation area, wherein the clutch element is translationally movable along the actuation rotational axis relative to the catch element between at least one decoupling position in which the clutch element is decoupled from the catch element, and at least one coupling position in which the clutch element is coupled to the catch element, and wherein a relative rotation between the actuating element and the clutch element, the relative rotation being effectable by rotating the drive shaft, can be converted, by means of the actuation areas, into a translational movement of the clutch element from the decoupling position into the coupling position, the translational movement taking place along the actuation rotational axis, relative to the catch element, relative to the actuating element and in the direction of the catch element.