It is provided an adjustment mechanism, comprising a closure flap for at least partially closing a closure opening on a vehicle, via which, when the closure flap is opened, a connection element for connecting a line and/or a port for topping up a liquid, in particular a fuel, is accessible, a drive for adjusting the closure flap by external force in response to an operator control event, and an electronic control unit which is coupled to the drive and by means of which the drive is activated to open the closure flap in response to an operator control event which is detected in a contactless manner, and, on the other hand, is automatically stopped or reversed in so far as, when the closure flap closes, a possible obstacle is detected in a contactless manner in the adjustment path of the closure flap by means of an anti-pinch mechanism.

A charging connection device for a vehicle includes a junction box disposed in a recess, a junction box cover flap, and a cover flap. The junction box cover flap and the cover flap are each pivotable into an open position and a closed position. The junction box cover flap covers the junction box in the closed position and the recess is coverable by the cover flap. When the cover flap is displaced from the open position into the closed position the cover flap entrains the junction box cover flap. The junction box cover flap has a first element of a junction box connecting device and the junction box or a component that defines the recess has a second element of the junction box connecting device. In the closed position of the junction box cover flap, the junction box cover flap is held magnetically releasably by the junction box connecting device.

The present disclosure relates to an actuating assembly and a fuel filler or charging inlet flip assembly. The actuating assembly comprises a driving gear and a transmission gear. The transmission gear is configured to be capable of rotating in a first direction to open the flip and in a second direction to close the flip, driven by the driving gear. An outer periphery of the driving gear is provided with a first outer periphery portion and a second outer periphery portion, the first outer periphery portion is provided on one side of the second outer periphery portion in a circumferential direction, the first outer periphery portion comprises a plurality of driving teeth, the second outer periphery portion comprises a driving gear abutting portion. The actuating assembly can allow for a reduced machining accuracy, and thus allow for a smoother engagement of the driving gear and the transmission gear.

The disclosure relates to a motor vehicle flap system, including a lateral wall having an inner side surface, an outer side surface and a through-opening, a flap which is mounted on the inner side surface such that it can move between a closed position closing the through-opening, in which the flap lies within the through-opening and runs perfectly flush with the outer side surface, and an open position releasing the through-opening, and having an actuation lever which is mounted on the inner side surface such that it can swivel between a starting position and an end position, and, with a movement into the end position, the actuation lever is designed to move the flap into the open position, wherein the flap and the actuation lever are swivellably mounted on a guide axis arranged on the inner side surface.

Methods and systems are provided for conducting remote refueling events of a passenger vehicle, and for coordinating said remote refueling events with a fuel tank fill level prior to the remote refueling event, a loading state of a fuel vapor storage device, and current and predicted fuel tank pressure. In one example, an amount of fuel that can be added to the fuel tank without overwhelming a capacity of the fuel vapor storage device is increased responsive to scheduling the remote refueling event to take place at a time when the fuel tank is at a negative pressure, thus resulting in partial purge of the fuel vapor storage device prior to commencing refueling. In this way, environmentally friendly refueling events may be enabled, thus reducing the potential for undesired evaporative emissions during refueling events.

A covering device (100) for a vehicle, includes: a cover (10); a drive element (40a, 40b) formed to enable a movement of the cover, wherein the drive element brings about a force which acts on the cover. The covering device has a force-limitation apparatus (30a, 30b) which limits the force brought about by the drive element to a limit force so that the covering device is protected in the event of an overload acting on the covering device and/or a user is protected when using the covering device. An actuator (200) has a drive apparatus (210) with a drive element (211); an output drive element (290); and a force-decoupling apparatus (230). The force-decoupling apparatus is formed so that it at least temporarily does not output a force taken up by the drive element or at least temporarily outputs it in a delayed manner to the output drive element.

A system having a cover for a motor vehicle, in particular a fuel cap or a charging port cover, an electromotive actuator with an output and an electric motor, and an electric motor controller, wherein the electric motor of the actuator can be controlled via the motor controller as a function of an electric actuation signal such that the output of the actuator transfers the cover to an open position or a closed position. In order to realize the automatic opening or closing of a cover for a motor vehicle using simple circuit technology, it is proposed that the actuation signal can be generated by an external movement of the output. Furthermore, a method for automatically actuating a cover is provided.

A sealing device for sealing a through opening in a vehicle chassis includes a sealing element that can be shifted between an open position, in which the through opening is released, and a closed position, in which the through opening can be closed. The sealing device has an adjusting device which includes a guide housing that can be arranged in a spatially fixed manner on the vehicle chassis, in which guide housing a carrier element is translationally and pivotably guided, where the carrier element has the sealing element. A slide guide is provided, via which the carrier element can be translationally shifted and pivoted in relation to the guide housing. A traction element is translationally entrainably connected to the carrier element, and simultaneously connected in a rotationally decoupled manner, via a pivot bearing. The traction element is translationally shiftable by the drive.

A vehicle lid lock device includes a locking member for locking a lid provided on a vehicle, a housing member in which an insertion hole is formed into which the locking member is inserted and which houses the locking member enabled to move backward and forward; and an annular seal member that is housed in a housing portion of the housing member and that seals a gap between an inner surface of the insertion hole of the housing member and an outer surface of the locking member. The seal member includes a main body including an inner peripheral surface with an inner diameter larger than an outer diameter of the locking member, and a lip portion that protrudes radially inward from the inner peripheral surface of the main body and that is in slide contact with the outer surface of the locking member.

A locking system for locking a lid of a vehicle including: a lid, a movement actuator for moving the lid, a lock having a roto-translating pin with a head suitable for being engaged in a seat of the lid, and an actuator of the lock that moves the roto-translating pin. The actuator has an electric motor and a motion reducer. The electric motor is suitably configured so as to rotate in a first rotational direction to move the roto-translating pin from a retracted position to an extracted position, and in a second rotational direction to move the roto-translating pin from the extracted position to the retracted position.