A fuel door opener assembly for a push type fuel door includes a pop-up part installed inside a housing and a locking part installed inside the housing. The pop-up part includes a plunger installed to be slidable inside the housing in a state of being elastically supported, a door catch connected to the fuel door, installed to pass through the housing, disposed coaxially with the plunger, brought into contact with an end portion of the plunger, and configured to pop up the fuel door, a cam being selectively restrained by the locking part and configured to restrain sliding of the door catch when restrained by the locking part, and a plunger spring configured to elastically support the plunger toward the door catch inside the housing.

A fuel door opener assembly for a push type fuel door includes a pop-up part installed inside a housing and a locking part installed inside the housing. The pop-up part includes a plunger installed to be slidable inside the housing in a state of being elastically supported, a door catch connected to the fuel door, installed to pass through the housing, disposed coaxially with the plunger, brought into contact with an end portion of the plunger, and configured to pop up the fuel door, a cam being selectively restrained by the locking part and configured to restrain sliding of the door catch when restrained by the locking part, and a plunger spring configured to elastically support the plunger toward the door catch inside the housing.

The disclosure relates to an overload coupling for an actuating mechanism for actuating a charging, fueling, or service flap on a charging, fueling, or service compartment that is or can be received on or in a body component of a vehicle. The overload coupling includes a drive-side coupling element and an output-side coupling element and, in an engaged state by means of a form-fit and/or force-fit lock, transfer a torque and thus a drive movement from the drive-side coupling element to the output-side coupling element. When a critical torque to be transferred is reached or exceeded in the event of an overload, to lift the form-fit and/or force-fit lock between the drive-side coupling element and the output-side coupling element.

The disclosure relates to an overload coupling for an actuating mechanism for actuating a charging, fueling, or service flap on a charging, fueling, or service compartment that is or can be received on or in a body component of a vehicle. The overload coupling includes a drive-side coupling element and an output-side coupling element and, in an engaged state by means of a form-fit and/or force-fit lock, transfer a torque and thus a drive movement from the drive-side coupling element to the output-side coupling element. When a critical torque to be transferred is reached or exceeded in the event of an overload, to lift the form-fit and/or force-fit lock between the drive-side coupling element and the output-side coupling element.

In the lid opening and closing device, the rotating body at the initial position rotates to one side in the rotation direction, so that the lock member is disengaged from the first link. Further, the first link and the rotating body are provided with a differential connecting mechanism, and the differential connecting mechanism connects the rotating body and the first link to operate the link mechanism at the retracted position after the lock member is disengaged from the first link, when the rotating body is rotating. As a result, the differential connecting mechanism imparts a time difference between the two operations of the rotating body. Therefore, the lock member and the link mechanism can be operated by rotationally driving the rotating body by a single actuator.

In the lid opening and closing device, the rotating body at the initial position rotates to one side in the rotation direction, so that the lock member is disengaged from the first link. Further, the first link and the rotating body are provided with a differential connecting mechanism, and the differential connecting mechanism connects the rotating body and the first link to operate the link mechanism at the retracted position after the lock member is disengaged from the first link, when the rotating body is rotating. As a result, the differential connecting mechanism imparts a time difference between the two operations of the rotating body. Therefore, the lock member and the link mechanism can be operated by rotationally driving the rotating body by a single actuator.

The forward/backward movement device includes: a case; a forward/backward member, and a drive mechanism. In the forward/backward movement device, the drive mechanism includes: a drive section including a drive section main body and a drive shaft; a gear section; an arm section; and a lock portion including a conversion mechanism and an engaging section. In the forward/backward movement device, the forward/backward member and the drive section are housed in the case such that respective axes of the forward/backward member and the drive section are substantially parallel to each other, and the arm section includes a rotation axis, in which a plane containing a rotation direction of the arm section with the rotation axis is substantially parallel with respect to a plane containing an axial direction of the drive section and an axial direction of the forward/backward member.

The forward/backward movement device includes: a case; a forward/backward member, and a drive mechanism. In the forward/backward movement device, the drive mechanism includes: a drive section including a drive section main body and a drive shaft; a gear section; an arm section; and a lock portion including a conversion mechanism and an engaging section. In the forward/backward movement device, the forward/backward member and the drive section are housed in the case such that respective axes of the forward/backward member and the drive section are substantially parallel to each other, and the arm section includes a rotation axis, in which a plane containing a rotation direction of the arm section with the rotation axis is substantially parallel with respect to a plane containing an axial direction of the drive section and an axial direction of the forward/backward member.

An actuating mechanism for actuating a charging or fueling flap on a charging or fueling compartment received on or in a body component of a vehicle, wherein the charging or fueling flap is reversibly movable between a closed position and an open position, wherein a flap lock is provided for locking the charging or fueling flap in its closed position. The actuating mechanism includes a drive having a drive shaft, which is operatively connectable to the charging or fueling flap such that, upon rotation of the drive shaft, the charging or fueling flap is movable relative to the charging or fueling compartment. The actuating mechanism further includes a mechanical control or switching mechanism, which is configured such that, upon rotation of the drive shaft to manipulate the flap lock, a rotational movement of the drive shaft can be tapped with the aid of the mechanical control or switching mechanism.

A lid system includes: a lid for a vehicle, the lid being configured to be opened when the vehicle is supplied with energy; a lid locking device for the lid; a control device configured to control the lid locking device; and a switch operable by a user. When the switch is turned on, the control device interlocks a locked state and an unlocked state of the lid locking device with a locked state and an unlocked state of a door locking device for a door of the vehicle. When the switch is turned off, the control device does not interlock the locked state and the unlocked state of the lid locking device with the locked state and the unlocked state of the door locking device.