A drive assembly for motorized adjustment of an adjusting element of a motor vehicle. The drive assembly includes a drive having a rotational motor unit and a feed gearing drivingly arranged downstream of the motor unit for generating drive movements along a feed gearing axis in first and second adjusting directions, the drive includes a clutch having a first clutch element, rotationally fixed to a driveshaft of the drive, and a second clutch element, rotationally fixed to an output shaft of the drive, in a state in which they are drivingly coupled to one another, the clutch elements transmit rotational movements from the driveshaft to the output shaft, to generate the drive movements of the feed gearing. The clutch is designed as a curved tooth coupling.

A drive assembly for motorized adjustment of an adjusting element of a motor vehicle. The drive assembly includes a drive having a rotational motor unit and a feed gearing drivingly arranged downstream of the motor unit for generating drive movements along a feed gearing axis in first and second adjusting directions, the drive includes a clutch having a first clutch element, rotationally fixed to a driveshaft of the drive, and a second clutch element, rotationally fixed to an output shaft of the drive, in a state in which they are drivingly coupled to one another, the clutch elements transmit rotational movements from the driveshaft to the output shaft, to generate the drive movements of the feed gearing. The clutch is designed as a curved tooth coupling.

An opening/closing mechanism for a tail gate includes a hinge device configured to rotate the tail gate relative to side walls, and a latch device configured for engagement with a striker provided on the side wall to hold the tail gate in a closed state. The hinge device includes an electric driving device provided on the tail gate and configured to rotate the tail gate by means of a motor, and a coupling configured to couple a body-side engagement portion provided on the side wall and an output shaft of the electric driving device together. The output shaft of the electric driving device fits in a fitting hole portion in a first cylindrical portion formed at one end side of the coupling, and the body-side engagement portion fits in a fitting recessed portion in a second cylindrical portion formed at the other end side of the coupling.

An opening/closing mechanism for a tail gate includes a hinge device configured to rotate the tail gate relative to side walls, and a latch device configured for engagement with a striker provided on the side wall to hold the tail gate in a closed state. The hinge device includes an electric driving device provided on the tail gate and configured to rotate the tail gate by means of a motor, and a coupling configured to couple a body-side engagement portion provided on the side wall and an output shaft of the electric driving device together. The output shaft of the electric driving device fits in a fitting hole portion in a first cylindrical portion formed at one end side of the coupling, and the body-side engagement portion fits in a fitting recessed portion in a second cylindrical portion formed at the other end side of the coupling.

An automatic door opening apparatus for a vehicle. Two and three hinge joint embodiments with motors at each hinge joint to control motion of the door opening apparatus relative to the vehicle at that hinge joint. The motors are individually programmable to customize the door opening apparatus and movement to different vehicles. The motors can be in alignment or out-of-alignment with the hinge joints, but in either case the motor controls motion of the hinged components at the associated hinge joint. When a motor is out-of-alignment with the hinge joint it controls, then pulley wheels and belts can be used to connect the motor to the hinge joint. The door opening apparatus can also include a floor track, and a door arm that connects the door to the floor track.

A passage barrier includes two guide elements that cooperate such that they define a gate region, through which a person passes from an entrance region into a passage region. At least one of the guide elements includes a vertically running profile, on which a locking apparatus is arranged. The locking apparatus has a torque transmission toothing, which engages into a complementary torque reception toothing of a hollow shaft of a drive. A circular stop disc is also provided and has a toothing engagement, which is engaged with the torque transmission toothing. The stop disc has a circumferential surface with a stop lug, which protrudes radially from the stop disc circumferential surface, and cooperates with a stop element arranged on the vertically running profile such that a rotation of the stop disc is delimited by the engagement of the stop lug against the stop element.

A tailgate control system for a vehicle includes a spindle and a coupling member fixedly coupled to a tailgate of the vehicle, the coupling member having a slot formed therein. A portion of the spindle is coupled to the coupling member via the slot so as to enable relative movement between the portion of the spindle and the coupling member along the slot, and such that extension of the spindle causes a force on the coupling member which causes a closing motion of the tailgate. The portion of the spindle is also coupled to the coupling member such that a manually-generated closing motion of the tailgate causes a change in a position of the portion of the spindle along the slot.

A tailgate control system for a vehicle includes a spindle and a coupling member fixedly coupled to a tailgate of the vehicle, the coupling member having a slot formed therein. A portion of the spindle is coupled to the coupling member via the slot so as to enable relative movement between the portion of the spindle and the coupling member along the slot, and such that extension of the spindle causes a force on the coupling member which causes a closing motion of the tailgate. The portion of the spindle is also coupled to the coupling member such that a manually-generated closing motion of the tailgate causes a change in a position of the portion of the spindle along the slot.

A retrofit module configured for use with a door closer having a pinion. The retrofit module generally includes a case, an output shaft, a motor, and a control assembly. The output shaft is rotatably mounted in the case, and is configured for rotational coupling with the pinion. The motor is mounted to the case, and is operable to rotate the output shaft in a door-opening direction. The control assembly is mounted to the case, and is configured to operate the motor to drive the output shaft in the door-opening direction in response to an actuating signal.

A retrofit module configured for use with a door closer having a pinion. The retrofit module generally includes a case, an output shaft, a motor, and a control assembly. The output shaft is rotatably mounted in the case, and is configured for rotational coupling with the pinion. The motor is mounted to the case, and is operable to rotate the output shaft in a door-opening direction. The control assembly is mounted to the case, and is configured to operate the motor to drive the output shaft in the door-opening direction in response to an actuating signal.