A module (49, 149, 249) for use in a vehicle fuel system, said module comprising a housing (7) having a first port (9), a second port (41) and a passage (57) between the first port and the second port; a closure body (11) that is moveably arranged in said housing; wherein said closure body is configured for closing the passage between the first port and the second port in a first position of the closure body and for allowing access to the passage in a second position of the closure body; and a pump (13) that is integrated in said housing (7), wherein said pump (13) communicates with the first port (9) and is configured for pumping fluid into or out of the first port (9) while the closure body (11) is in the first position, characterized in that the module (49, 149) further comprises a motor (15) and a closure body actuator (67) configured for positioning the closure body (11, 111) in at least the first position and the second position, wherein said closure body actuator is driven by said motor (15), and said motor is configured for driving the pump (13) while the closure body is in the first position.

A hydrogen station operation method capable of adjusting pressure in a reservoir to the pressure suitable for liquid hydrogen replenishment while cutting hydrogen waste is for replenishing liquid hydrogen into the reservoir in a hydrogen station including: a gasification path partially gasifying liquid hydrogen out of the reservoir and returning it; and a gas delivery path delivering gasified hydrogen in the reservoir into a path between a vaporizer and a compressor or the vaporizer, when the remainder of liquid hydrogen in the reservoir becomes a first threshold or less, by reducing the liquid hydrogen amount flowing through the gasification path by a valve therein, reducing the gasification amount of liquid hydrogen in the reservoir, and increasing the hydrogen gas amount delivered through the gas delivery path from the reservoir by a valve therein, pressure in the reservoir is reduced, thereby performing operation where suction pressure of the compressor is reduced.

The systems and methods of fuel vapor recovery and use comprise a cryogenic condensation module and a fuel tank of a service station. The cryogenic condensation module comprises a cryogenic vaporizer that lowers the temperature of fuel vapors via condensation. The cryogenic condensation module also comprises a processing element that processes the fuel vapors that have not been condensed via the cryogenic vaporizer. The fuel tank is connected to the cryogenic condensation module by a ventilation pipe and a return pipe. The ventilation pipe is capable of displacing the fuel vapors to the cryogenic condensation module. The return pipe is capable of returning condensed fuel vapors to the fuel tank.

An object is to enhance the assembly of a breather pipe which is accommodated in a filler pipe. A nozzle guide (10, 10a, 10b) that is arranged within a filler pipe (110) includes: a main body portion (20, 20b) that guides the insertion and removal of a refueling nozzle (150); and a connection member (50, 50a to 50c) that is provided on an outer circumferential surface (27) of the main body portion (20, 20b) and in which an upper end portion (51) of the connection member is located, in a tank direction (TD) extending from a refueling port (FC) toward a fuel tank (FT), on a downstream side with respect to a tip end portion (152) of the refueling nozzle (150), and the connection member (50, 50a to 50c) includes: a connection portion (52, 52a) connected to a breather pipe (120) that is arranged within the filler pipe (110); and a vapor flow path formation portion (55, 55b, 55c) that forms part of a vapor flow path (220) for the fuel vapor that flows in through the breather pipe (120) and the connection portion (52, 52a).

The system of fuel vapor recovery and use comprises a condensation module (10) that can connect to a fuel tank (2) of a service station by means of ventilation pipe (1), through which the fuel vapors are displaced to the cryogenic condensation module (10), wherein they are condensed, further comprising the cryogenic condensation module (10) and a return pipe (18) for the condensed vapors to the fuel tank (2), wherein that said cryogenic condensation module (10) comprises a cryogenic vaporizer (11) that lowers the temperature of the vapors by condensing them and a processing element (22) that processes the vapors that have not been condensed in said cryogenic vaporizer (11).

Methods and systems are provided for refueling a vehicle configured with an onboard refueling vapor recovery (ORVR) system, such that a loading of a fuel vapor canister configured to capture and store fuel vapors, is reduced. In one example, during the refueling, a rate at which fuel vapors are routed to the fuel vapor canister is adjusted responsive to an indication that the vehicle is refueling at a gas station equipped with offboard fuel vapor recovery infrastructure. In this way, loading of the fuel vapor canister may be reduced which may prevent undesired bleedthrough emissions resulting from a canister loaded with fuel vapors, particularly in examples where the vehicle is a hybrid vehicle and where engine runtime is limited, thus limiting potential opportunities for purging of the fuel vapor canister.

An electromechanically operated fuel nozzle having continuously adjustable flow rate settings between a closed position and maximum flow. The fuel nozzle includes a fuel dispensing pipe for dispensing fuel; an electromechanical valve device to control a flow of fuel in the fuel dispensing pipe, comprising an inlet pipe and an outlet pipe. The electromechanical valve device comprises at least one continuously variable flow electromechanical valve to control the flow of fuel; an electronic board for operating the at least one continuously variable flow electromechanical valve; and electric accumulator means for electrically powering the at least one variable flow electromechanical valve and the electronic board such that the predetermined portions provide the particular one of the flow rate settings. The electromechanical valve preferably comprises a servomotor controlled ball valve.

An example fuel cap assembly includes a fuel cap, a sensor element extending from the fuel cap, and a fuel tube extending from the fuel cap next to the sensor element. The fuel tube includes an outlet end having at least one side-diverting fuel outlet that extends through a sidewall of the fuel tube. A fuel cap assembly kit and method of filling a fuel tank are also disclosed.

An object is to enhance the assembly of a breather pipe which is accommodated in a filler pipe.

A nozzle guide (10, 10a, 10b) that is arranged within a filler pipe (110) includes: a main body portion (20, 20b) that guides the insertion and removal of a refueling nozzle (150); and a connection member (50, 50a to 50c) that is provided on an outer circumferential surface (27) of the main body portion (20, 20b) and in which an upper end portion (51) of the connection member is located, in a tank direction (TD) extending from a refueling port (FC) toward a fuel tank (FT), on a downstream side with respect to a tip end portion (152) of the refueling nozzle (150), and the connection member (50, 50a to 50c) includes: a connection portion (52, 52a) connected to a breather pipe (120) that is arranged within the filler pipe (110); and a vapor flow path formation portion (55, 55b, 55c) that forms part of a vapor flow path (220) for the fuel vapor that flows in through the breather pipe (120) and the connection portion (52, 52a).

A vehicle fueling control system according to an exemplary aspect of the present disclosure includes, among other things, a fuel inlet conduit configured to receive a fuel dispensing nozzle, and a blocking assembly. The blocking assembly is configured to move back and forth between a fill blocking position that blocks airflow through a port of the fuel dispensing nozzle and a fill permitting position that permits airflow through the port of the fuel dispensing nozzle.