A locking device enables locking a charging, fueling, or service flap on a compartment. The flap is reversibly movable between a closed position and an open position. The locking device includes a flap lock for locking the flap in its closed position. The flap lock has a locking position, in which the flap lock locks the flap, and a release position in which the flap is moveable in relation to the flap lock. A first transfer shaft is connected to the flap lock such that the flap lock is moveable by a movement of the first transfer shaft between the locking position and the release position. A pushing element is connected to the first transfer shaft and configured so as to push the flap out of its closed position away from the charging compartment after the flap lock is transferred into its release position.

A closure device for closing an access opening in a motor-vehicle body. An inner chamber is accessible via the access opening and the access opening can be closed by a cap element. The cap element is connected to a guide device, which is arranged in the inner chamber and via which the cap element can be adjusted between a closed position and an open position. The guide device is configured such lo that the cap element executes a pushing movement and a lifting movement as it moves between the closed position and the open position. The cap element, in the open position, is arranged in the inner chamber.

The invention relates to a filling system on a motor vehicle, having at least two storage tanks for liquid or gaseous operating materials, comprising a tank closure cover which closes an opening in the body of the motor vehicle and can be brought from a first position that closes the opening into a second position that releases the opening, wherein at least two filling openings of the storage tanks are arranged below the tank closure cover, which are concealed in the first position of the tank closure cover; a filler trough that forms an enclosure of the filling opening, wherein the filler trough closes the opening in the body of the motor vehicle on the vehicle side and is fixed to the body of the motor vehicle; and at least one filler head, wherein the filling openings are formed as a part of the filler head, the filler head defining at least two mouth-hole necks which are combined to form a common component and are integrally connected to each other, each mouth-hole neck forming a filling opening for another storage tank.

The present application discloses at least a method, apparatus, and system for automatic refueling of a driverless vehicle. A specific implementation of the method includes: sending refueling request information when a fuel amount is lower than a preset value and a refueling condition is satisfied; receiving preselected gas station information corresponding to the refueling request information; determining, from the preselected gas station information, destination gas station information and driving route information of a destination gas station; sending refueling request information after arriving at the destination gas station based on the driving route information of the destination gas station; turning off an engine and/or an electric motor after receiving refueling permission information corresponding to the refueling request information, opening a fuel tank cap, and sending refueling confirmation information; and closing the fuel tank cap after receiving refueling completion information. This implementation improves the refueling efficiency.

A charging port door is provided. The charging port door includes a door panel for opening and closing a charging housing that accommodates a charging port therein, an optical unit included within the door panel for irradiating light to an exterior of the door panel, and a controller for controlling the optical unit. In particular, the controller is configured to control the optical unit in response to a predetermined condition being satisfied, the predetermined condition including at least one of open/closed status of the door panel, charging status, driving state, detection of a driver, or detection of a motion of an external object.

A mechanism (1) for pivoting a charging or tank flap (2) on a charging or filler neck housing (3), which is accommodated or can be accommodated in a body component of a motor vehicle, wherein the mechanism (1) is configured, by superposing at least two at least temporarily simultaneous circular rotational movements having different rotation radii or at least one at least temporarily simultaneous circular rotational movement and at least one linear movement, to pivot the charging or tank flap (2) reversibly between a first orientation, in particular a closed position of the charging or tank flap (2), and a second orientation, in particular an open position of the charging or tank flap (2).

Vehicle fuel fill control systems may anticipate vehicle refueling events in order to control the timing of fuel tank depressurization sequences. In a first embodiment, a global positioning system (GPS) is utilized to anticipate the vehicle refueling event prior to initializing the depressurization sequence. In another embodiment, a camera system is utilized to anticipate the refueling event prior to initializing the depressurization sequence. In yet another embodiment, both the GPS and the camera system may be utilized to anticipate the refueling event. By anticipating refueling events, customer wait time for gaining refueling access may be reduced.

An actuation assembly for a refueling port or charging port flip cover assembly is rotatably mounted on a base and includes a locking means, a flip cover rotating shaft, a transmission gear, a drive gear and a drive member. The locking means is movably disposed on the base and configured to lock or release a flip cover. The flip cover rotating shaft is configured to rotate the flip cover and includes a fitting portion. The transmission gear includes a receiving portion and is installed around the fitting portion. The drive gear and the drive member are configured to synchronously rotate. The drive gear is meshed with the transmission gear and the drive member is configured to drive the locking means. In moving the locking means from a release position to a locking position, the drive gear blocks the rotation of the transmission gear and prevents the flip cover from opening.

A flip cover actuation assembly for actuating a flip cover is movably mounted on a base. The flip cover actuation assembly has a locking means, a hinge means, a drive shaft and a drive member. The drive shaft has a fitting portion. The hinge means is installed around the fitting portion. An engagement structure is provided on a receiving portion of the hinge means. The engagement structure enables the receiving portion and the fitting portion to rotatably engage or separate such that the drive shaft moves the flip cover relative to the hinge means. The locking or releasing of the flip cover and the opening and closing of the flip cover is achieved by the drive shaft with the drive member. In addition, the releasing and the opening of the flip cover are achieved at different times to avoid any interferences.

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.