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.

There is provided a method for actuating a component of a vehicle. The method may include applying an initial force to the component to actuate the component, and generating a movement indicator based on whether the component moves in response to the initial force. Moreover, the method may include receiving a freezing indicator associated with a likelihood of the component being immobilized due to freezing. If the movement indicator is negative and the freezing indicator is affirmative, the method also includes applying an adjusted force to the component to mobilize the component.

Provided is a vehicle port device that includes a lid (38) that selectively closes an opening (44) of a port accommodating space facing outwardly on a vehicle body, a first display unit (52) positioned in the port accommodating space, and a second display unit (54) configured to indicate a failure in the port module and positioned in the port accommodating space. The lid includes a translucent part (46A) opposing the first display unit and an opaque part (46B) opposing the second display unit in a closed state of the lid.

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 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.

A locking apparatus for covering and releasing a charging interface of a motor vehicle. The locking apparatus comprises a cover element, which is pivotable relative to the charging interface and which can be displaced between a closed position and an open position. The locking apparatus is equipped with a flexible connection element, which is rigidly connected to the cover element at one upper end region of the cover element in the direction of the vehicle along the transverse extent of the cover element. The cover element is at the same time permanently and in every position coupled by the connection element for protecting the charging interface with a part that is stationary relative to the charging interface.

A control method for a charging port cover of a vehicle including a charging end assembly. The charging end assembly includes a charging port having a fast charging port and a slow charging port and a charging port cover having a fast charging port cover and a slow charging port cover. The method includes: when a charging port cover opening signal is received, controlling both the fast charging port cover and the slow charging port cover to be opened; when one of the fast charging port and the slow charging port is detected to be inserted with a plug-in end of a charging device, generating a charging port cover closing instruction; and controlling the charging port cover corresponding to the charging port into which the plug-in end is not inserted to be closed according to the charging port cover closing instruction.

A charging port device includes a charging port driver, a fast charging driver, a slow charging driver, a slow charging port cover, a fast charging port cover, an outer cover, and a mounting housing provided with a mounting hole. A fast charging port and a slow charging port are arranged in the mounting hole. An output terminal of the charging port driver is connected with the outer cover, and the outer cover is configured to cover the mounting hole. An output terminal of the fast charging driver is connected with the fast charging port cover, and the fast charging port cover is configured to cover the fast charging port. An output terminal of the slow charging driver is connected with the slow charging port cover, and the slow charging port cover is configured to cover the slow charging port.

A fuel filler flap module of a motor vehicle includes a carrier, a fuel filler flap which is pivotably mounted on the carrier and is designed to be movable between a closed position and an open position, and a movement mechanism designed to move the fuel filler flap from the closed position into the open position and back into the closed position. The movement mechanism has a mechanical deployment element which is arranged on the carrier and which is designed to exert a deployment force acting into the open position on the fuel filler flap, wherein the movement mechanism has a motor-driven deployment means which is designed to push the fuel filler flap with an auxiliary force from the closed position up to an initial deployment position, which lies between the closed position and the open position, wherein the auxiliary force is greater than the deployment force.

The disclosure relates to a positioning mechanism for holding a lid element of a vehicle in an intermediate position between a fully open position and a fully closed position. The positioning mechanism comprises a base component, a first friction block carrying a first friction surface, a counter surface, and an engagement element. The first friction block is supported on the base component via two pivotable first lever arms such that the two first lever arms, the friction block, and a portion of the base component form a first parallelogram. The counter surface faces the first friction surface and is arranged in parallel to the first friction surface such that the first friction surface and the counter surface define a movement channel extending along a movement channel direction. The engagement element is receivable in the movement channel and the first lever arms are inclined with respect to a movement channel direction.

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.