An electric vehicle includes a charge port configured to selectively lock a charge plug to the charge port, a charge port door configured to provide access to the charge port, a charge port door lock configured to selectively lock the charge port door in a closed position, a primary manual release cable operably coupled to the charge port to manually unlock the charge plug from the charge port, and a secondary tension cable system coupled between the primary manual release cable and the charge port door lock. Actuation of the primary manual release cable simultaneously unlocks the charge plug from the charge port and actuates the secondary tension cable system to unlock the charge port door lock.

A fuel tank includes a tank panel in which a storage space of a fuel is formed, a tank inlet fixed to the tank panel, and a tank cap that allows the tank inlet to be opened and closed. The tank inlet includes a bottomed cylindrical inlet plate to which the tank cap is attached, an inlet pipe that protrudes from a bottom wall of the inlet plate into the storage space, and a separator configured to separate the fuel entering from the storage space into a liquid component and a gas component. The separator is supported by the bottom wall of the inlet plate in the storage space, and the separator is disposed on an outer side of the inlet pipe and on an inner side relative to an outer edge of the inlet plate in a bottom view of the tank inlet.

This disclosure relates to an electrified vehicle having remote terminals accessible via a charging port door. An example electrified vehicle a charging port configured to couple to a plug to charge the electrified vehicle, and remote terminals. The electrified vehicle can be jump started via the remote terminals. Further, the electrified vehicle includes a charging port door moveable between a closed position, a normal open position in which the charging port is accessible such that a plug may couple to the charging port to charge the electrified vehicle, and an extended open position in which the charging port door has moved beyond the normal open position. The remote terminals are accessible when the charging port door is in the extended open position.

An actuating apparatus for a flap which is mounted on a component for movement has a first actuating element, fastenable fixedly to the flap so as to rotate with it, and a second actuating element, fastenable to the component, and rotatable about a first rotational axis, the second actuating element has a first end and a second end, the first end configured to interact with a drive, the second end has a first locking or release geometry, the first actuating element has a second locking or release geometry, the second actuating element can be rotated between a first orientation and a second orientation, wherein the first and second locking or release geometry are configured to interact such that, in the first orientation, the first actuating element is locked to the second actuating element and, in the second orientation, the first actuating element is released from the second actuating element.

A charging flap system for electrically propelled vehicles has a charging socket bracket and a charging socket fastened therein having an outer wall, an inner wall and a cavity therebetween, including a DC power connection, and a charging flap, which is connected for rotation via an articulation joint with a return spring to the charging socket bracket and covers the DC power connection in a first position and reveals the power connection in a second position. An undercut is arranged on the articulation joint. A retaining hook has a socket pin, the bottom of which can be displaced on the charging socket bracket and which includes a tip which points towards the DC power connection. The retaining hook has a joint pin, which is connected to an end region opposite the tip and leads away from the charging socket bracket at a predefined angle, wherein the free end of the joint pin has a retaining lug matching the undercut. A spring is arranged on the joint pin such that the joint pin is pressed towards the charging socket. A recess is arranged in the outer wall of the charging socket such that the tip of the socket pin can be guided through the recess. The undercut of the articulation joint and the retaining hook are arranged such that, in the closed state of the charging socket cover, the retaining lug bears on a region of the articulation joint, which does not have an undercut, such that the tip of the socket pin extends through the outer wall but not into the cavity, and, in the opened state of the charging socket cover, the undercut is arranged such that the retaining lug engages in the undercut and the tip of the socket pin extends into the cavity.

An actuating device for opening and closing a cover in or on a vehicle includes a housing, a rotatable plunger, a spring that preloads the plunger into a discharge position, and an actuating sleeve into which the plunger can be introduced. At least one actuating groove extends helically around the longitudinal axis of the actuating sleeve and is formed on the inside of the sleeve. At least one actuating projection of the plunger engages into the actuating groove when the plunger is introduced into the actuating sleeve causing the plunger to rotate about its longitudinal axis during an axial relative movement between the actuating sleeve and the plunger. A blocking device blocks plunger movement into the discharge position to hold the plunger in a locked position. A spring element preloads the blocking device into a blocking position, and an actuator disengages the blocking device from the blocking position.

A locking system for a fuel compartment assembly of a work vehicle, the locking system having a housing at least partially defining a fuel access compartment, a door pivotally coupled to the housing and movable between an opened position, at which the door provides access to the fuel access compartment, and a closed position, at which the door blocks access to the fuel access compartment, and a locking assembly configured to lock the door at the closed position. The locking assembly includes a catch fixed to the housing and positioned within the fuel access compartment, and a latch arm pivotably coupled to the door at a pivot point defined between first and second ends of the latch arm, the pivot point defining a first pivot axis, where the latch arm is configured to be pivoted about the first pivot axis to be selectively engaged and disengaged with the catch.

A closure cap for an operating medium tank is provided with a closure device projecting into a fill socket of the operating medium tank. The closure device has a first cap element, a second cap element, and a sealing ring arranged between the first and second cap elements. A lifting assembly axially moves by an axial travel the first and second cap elements relative to each other for opening and closing the fill socket. The lifting assembly has a pressure member acting axially on one of the first and second cap elements. A grip member is provided that is rotatable about a hub and actuates the lifting assembly. A cover disk covering at least partially the fill socket relative to an exterior is connected fixedly to the pressure member of the lifting assembly. The cover disk rotates, together with the pressure member, about the hub.

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.

Example methods and apparatus to ensure grounding between vehicles during a vehicle-to-vehicle refueling operation are described herein. An example vehicle described herein is to receive fuel from a refueling vehicle via a vehicle-to-vehicle refueling operation. The example vehicle includes a fuel door to cover an inlet nozzle of a fuel tank, a lock to lock or unlock the fuel door, and a controller to cause the lock to unlock the fuel door if the vehicle and the refueling vehicle are electrically coupled.