An opening/closing apparatus for a fuel tank of a vehicle includes: a fuel passage forming portion; an insertion-side opening/closing valve mechanism; a fuel tank-side opening/closing valve mechanism; a liquid discharge path; and an opening/closing valve mechanism that opens and closes the liquid discharge port by a valve body disposed in the fuel passage forming portion, and that includes a moving body movable from a first position where a closing force exerts on the valve body to close the liquid discharge port to a second position where the closing force decreases, the moving body positioned at the first position in a state where the vehicle is stopped, and moving from the first position to the second position when receiving an inertial force due to traveling of the vehicle.

A refueling portion structure of a fuel tank has: a refueling pipe that has a refueling port; an opening/closing valve that is provided on a flow path within the refueling pipe; an accommodating portion that is provided at an outer side of the refueling pipe, that accommodates at an interior thereof an adsorbing material that adsorbs vapor fuel that has formed due to the liquid fuel evaporating, that communicates with the flow path further toward the refueling port side than the opening/closing valve, and into which the liquid fuel can flow; an atmospheric air passage, by which the accommodating portion communicates with atmospheric air; and a vapor movement passage, by which the accommodating portion communicates with an engine, and that is for moving vapor that is within the accommodating portion to the engine due to negative pressure from the engine.

To prevent fuel from leaking to outside even when the fuel flows back at the time of an automatic stop operation during refueling. A fuel supply portion structure of a fuel supply pipe, including a tubular portion having a filler port and a connection port, a first flap mechanism which is provided on the filler port side of the tubular portion, a drain hole, and a drain hole on-off valve, wherein the drain hole on-off valve is disposed on a placement surface located at the lowermost side of a vehicle on an inner wall of a first inner diameter member, the placement surface is made of an inclined surface falling from the filler port side toward the connection port with respect to a horizontal plane of the vehicle, and a wall portion rising toward the filler port is provided on the filler port side of the inclined surface.

Disclosed is an opening and closing device including a closing member which is turned to an opening position by inserting a fuel-filling nozzle to open a fuel-filling aperture. The closing member includes a pair of flap bodies and a biasing device which positions each of the flap bodies in a closing position by a biasing force. The pair of flap bodies each includes a turning assembly portion as the center of the turning and an abutment portion with respect to the other flap body and is each configured to press its front surface portion against a hole edge portion of a passage hole of the fuel-filling nozzle by the biasing force and presses the abutment portion against the abutment portion of the other flap body.

A capless filler neck closure for use with a vehicle fuel tank filler neck is disclosed. The capless filler neck closure includes an outer dust cover and an inner closure door each movable from a closed position to an opened position in response to insertion of a fuel nozzle into the capless filler neck closure for refueling of an associated vehicle fuel tank.

An opening/closing apparatus for a fuel tank of a vehicle includes: a fuel passage forming portion forming a fuel passage guiding a liquid fuel to the fuel tank; an insertion-side opening/closing valve mechanism opening and closing a filler port of the fuel passage; a liquid discharge path allowing an internal region of the fuel passage forming portion to communicate with the outside through a liquid discharge port formed in a portion of the fuel passage forming portion, the portion closer to the fuel tank than the insertion-side opening/closing valve mechanism; an opening/closing valve mechanism opening and closing the liquid discharge port by a valve body; and a valve body regulating mechanism regulating the valve body to close the liquid discharge port when the insertion-side opening/closing valve mechanism opens the filler port.

A capless refueling mechanism attached to a vehicle fuel tank is disclosed. In one example, the capless refueling mechanism includes a guide plate, main opening, misfueling inhibitor mechanism with a first and second pendulum arm mounted within the main opening, and a sealing door pivotably coupled to the refueling mechanism. The first and second pendulum arm of the misfueling inhibitor may be adjusted to move from a first position to a second position, allowing a fuel nozzle sized to fit the main opening to open the sealing door and dispense fuel into the fuel tank.

Methods and systems are provided for indicating restrictions in a fuel system vapor recirculation line. In one example, a fuel tank is evacuated responsive to a fuel level below a threshold, and if the vacuum is relieved via a negative pressure relief valve in a capless fuel filler system, the negative pressure relief valve is indicated to be functional such that, responsive to a fuel level greater than a threshold, the fuel system may be evacuated and a restriction may be indicated in the vapor recirculation line responsive to the negative pressure valve not relieving the applied vacuum. In this way, restrictions in the vapor recirculation line may be rapidly diagnosed and excessive loading of a fuel vapor canister may be prevented, thus reducing the potential for evaporative emissions being released to the atmosphere and prolonging fuel vapor canister function.

Methods and systems are provided for opening a refueling door. In one example, a method may include gradually opening the refueling door in proportion to a fuel tank depressurization rate.

A fluid dispensing apparatus is provided and is configured to dispense two fluids to a vehicle. A rigid diesel spout delivers diesel, while a urea spout is slidably disposed on the diesel spout and configured to deliver urea to the vehicle. The urea spout includes a guide that cooperates with a rail on the diesel spout such that insertion of the diesel spout into the vehicle can slide the urea spout relative the diesel spout. A valve in the urea spout includes an area for receiving a projection member on the vehicle to open the urea spout when inserted into the vehicle. The vehicle correspondingly includes a diesel intake and a urea intake. A projection or pin is provided to cooperate with the dispensing apparatus to open the valve and allow urea to flow into the vehicle.