A filler pipe bracket of an aluminum pickup truck includes a two-tiered body, a first side member, and a second side member. The two-tiered body includes a first layer defining a first pipe aperture and a second layer defining a second pipe aperture. The first side member extends from the first layer and includes a first mount flange oriented for securing to a portion of an inner pickup box frame. The second side member extends from the second layer and includes a second mount flange for fastening to another portion of the inner pickup box frame. The first pipe aperture may be sized to receive a diesel fuel pipe and the second pipe aperture may be sized to receive a diesel exhaust fluid pipe.

There is provided a closing device for a filler port. This closing device for the filler port comprises a fuel passage forming portion configured to include a first engagement element; a first open-close mechanism configured to include a first cover that is opened toward an upstream side; and a second open-close mechanism configured to open and close a second opening and include a second cover that is opened toward the upstream side. The first open-close mechanism further comprises a disengagement portion located on the upstream side of a second engagement element when the second engagement element is engaged with the first engagement element, and configured to disengage the second engagement element from the first engagement element when receiving a force in a closing direction from the second cover.

A drainage portion extending from one to the other of a bottom wall of a recess and a lid is provided at least above a hydrogen filling port in the recess when the lid is in a closed state. Therefore, water, which has entered the recess from a gap (parting) when the lid is in a closed state, reaches an upper surface of the drainage portion and flows along the upper surface of the drainage portion, and then, the water flows down from the drainage portion while avoiding the hydrogen filling port. Accordingly, it is possible to suppress the water having entered the recess while the lid is in a closed state from adhering to the hydrogen filling port.

An automatic opening and closing device for a fuel inlet of a vehicle may include a cap cover mounted at the fuel inlet of the vehicle, a fuel cap pivotably mounted at the cap cover and configured to selectively open or close the fuel inlet by being pivoted inside the fuel inlet, and a fuel cap operating mechanism mounted in the fuel inlet and configured, when the fuel door is closed, to pivot the fuel cap by being pressed by the fuel door to close the fuel inlet, and, when the fuel door is opened, pivot the fuel cap to open the fuel inlet according to release of pressing by the fuel door.

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.

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.

This disclosure relates to a fuel or charging port door assembly of a motor vehicle. In particular, this disclosure relates to a fuel or charging port door assembly configured to permit a door to open when an override force is applied using an assist tool, for example. An example vehicle includes a door configured to move relative to a body of the vehicle between open and closed positions. The door is a fuel door or a charging port door. The vehicle also includes a lock assembly including a base and a tip. The base is configured to hold the tip during normal operating conditions, and the base and tip are configured to separate upon application of an override force to the door.

A door assembly that includes a pocket having a biasing bore configured to accommodate a biasing member; a bezel attached to the pocket; and a door having a cam and at least one axle. The bezel has at least one axle slot. The at least one axle is received into the at least one axle slot and the biasing member is configured to apply an urging force onto the cam.

A motor vehicle has at least one pressure vessel for storing storage medium, preferably fuel, at least one pressure relief device for pressure relief of the at least one pressure vessel, and at least one opening through which storage medium flows out during a pressure relief.

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.