JP7122205B2 - fuel supply - Google Patents

Description

The present disclosure relates to a fuel supply system used in a fuel supply facility such as a gas station, and for supplying fuel such as gasoline or light oil to a fuel tank of a vehicle.

At a gas station as an example of a fuel supply facility, depending on the type of service, a gas station attendant or the customer himself/herself operates a fuel supply device (fuel supply device) as a worker to refuel vehicles (fuel supply work). . At that time, the worker takes out a fuel supply nozzle (fuel supply nozzle) that is housed in a nozzle hook of the fuel supply device body and is connected to a fuel supply hose (fuel supply hose), and attaches it to the fuel supply opening of the vehicle. Then, by opening the nozzle lever of the fuel nozzle to open the main valve (on-off valve) in the nozzle body, fuel is started to be discharged to the fuel tank (to be refueled) of the vehicle. After that, when the desired amount of fuel has been supplied, the operator closes the nozzle lever to end the fuel discharge from the fuel nozzle, and retracts the fuel nozzle into the nozzle hook of the fuel supply device main body. In addition, the refueling device is provided with a safety joint in the middle of the refueling hose, and when the vehicle leaves the vehicle with the refueling nozzle inserted into the refueling port of the vehicle, the safety joint separates and the built-in valve By closing the valve of the mechanism, it is possible to prevent fuel from flowing out due to breakage of the refueling hose or the like.

JP-A-10-167400

However, when the fuel discharge from the fuel nozzle is terminated, the nozzle lever of the fuel nozzle is suddenly closed or the automatic valve closing mechanism provided in the fuel nozzle is activated, causing the fuel discharge from the fuel nozzle to stop suddenly. When this happens, the fuel fluid that has been discharged is abruptly blocked by the refueling nozzle, causing an instantaneous and rapid pressure rise starting from the refueling nozzle in the fuel supply passage to the refueling nozzle.

Since the instantaneous and abrupt pressure rise starting from the fuel nozzle propagates from the fuel nozzle to the fuel supply passage on the upstream side, the sudden stop of the fuel discharge from the fuel nozzle is frequently repeated every time fueling work is performed. As a result, the increased pressure suddenly acts on the safety joint, and there is a problem that the durable life of the safety joint is shortened.

An object of the present disclosure is to provide a fuel supply device that prevents a momentary and sudden increase in pressure starting from a nozzle from being propagated to a safety joint.

In order to solve the above-described problems, the fuel supply device according to the present disclosure includes an in-body fuel supply path provided in the device body and provided with a liquid feeding means, and a fuel supply hose extending from the device body. a fuel supply nozzle that is connected to the internal fuel supply path via the external fuel supply path and has an on-off valve that discharges and stops the discharge of fuel to a fuel supply target; A fuel supply device comprising a safety joint that separates and cuts off a fuel supply path to a fuel supply nozzle when a tensile force of a predetermined value or more acts on the fuel supply hose, the safety joint or the safety joint downstream of the safety joint provided in the fuel supply passage outside the main body on the side, and the pressure rise generated in the fuel on the side of the fuel supply nozzle due to the closing of the opening and closing valve of the fuel supply nozzle propagates to the upstream fuel supply passage including the separation part of the safety joint. It is characterized by providing an auxiliary valve mechanism that prevents the

According to the present disclosure, in the fuel supply device, even if a momentary and rapid pressure rise originating from the fuel supply nozzle occurs, the safety joint or the auxiliary valve mechanism provided in the fuel supply passage downstream from the safety joint The operation prevents the increased pressure from propagating to the fuel supply passage on the upstream side including the separated portion of the safety joint, so the durability life of the safety joint can be extended, the maintenance interval of the fuel supply device itself can be extended, and the maintenance cost can be reduced. can also be measured.

1 is an overall configuration diagram of an embodiment of a fuel supply system provided at a gas station as an embodiment of a fuel supply system; FIG. FIG. 3 is a cross-sectional view showing the configuration of an auxiliary valve mechanism provided in the fuel supply system; FIG. 3 is a structural cross-sectional view of the auxiliary valve mechanism shown in FIG. 2 in a state in which an oil liquid is discharged from an oil supply nozzle; FIG. 4 is a configuration cross-sectional view of a hose joint unit in which a safety joint and an auxiliary valve mechanism are integrally formed; FIG. 5 is a configuration cross-sectional view of the hose joint unit shown in FIG. 4 in a state in which an oil liquid is discharged from an oil supply nozzle; FIG. 5 is a structural sectional view of the hose coupling unit shown in FIG. 4 when the safety coupling is separated; FIG. 5 is a configuration cross-sectional view of a modified example of the hose coupling unit shown in FIG. 4; FIG. 5 is a configuration cross-sectional view of another modification of the hose coupling unit shown in FIG. 4; FIG. 9 is an enlarged structural sectional view of an auxiliary valve mechanism portion in the hose coupling unit shown in FIG. 8; FIG. 9 is a configuration cross-sectional view of the hose joint unit shown in FIG. 8 in a state in which an oil liquid is discharged from an oil supply nozzle; FIG. 9 is a configuration cross-sectional view of the hose coupling unit shown in FIG. 8 when an instantaneous and rapid pressure rise originating from the fuel nozzle occurs. FIG. 9 is a structural sectional view of the hose coupling unit shown in FIG. 8 when the safety coupling is separated;

Hereinafter, the fuel supply device according to the present disclosure will be described based on the drawings, taking as an example a fuel supply device provided at a gas station.

FIG. 1 is an overall configuration diagram of an embodiment of a fuel supply system provided at a gas station as an embodiment of the fuel supply system.

The fueling device 1 has a fueling device main body (fueling device housing) 10 , a fueling hose 20 led out from the fueling device main body 10 , and a fueling nozzle 30 provided at the tip of the fueling hose 20 .

A fuel supply device main body 10 includes a pump 12 driven by a pump motor 11 and a flow meter 13 for measuring the amount of oil discharged from a fuel supply nozzle 30 to a fuel supply target such as a fuel tank of a vehicle. The flowmeter 13 is provided with a flow rate transmitter 15 that generates a flow rate pulse corresponding to the flow of the oil per unit amount.

In this case, the pump 12 is generally provided integrally with pump-equipped equipment such as an air separator and a filter in one housing unit provided with an inflow port and an outflow port, and is configured as a pump unit. . The pump unit consists of a strainer, an inflow side check valve, a pump 12, an air separator, a filter, and an outflow side check valve, from the upstream side (the underground oil storage tank side of the inflow port) to the downstream side (the flow meter 13 side of the outflow port). The valves are arranged in sequence. In addition, in the pump unit, a gas-liquid separator is arranged so as to communicate between the outflow side of the air separator and the inflow side (suction side) of the pump 12, and the outflow side of the filter and the inflow side of the pump 12 are arranged. (suction side) is provided with a relief passage provided with a relief valve.

A suction port of the pump 12 is connected to an underground oil storage tank (not shown) through a suction port pipe 14 and an underground pipe (not shown). A discharge port of the pump 12 is connected to an inflow port of the flow meter 13 . The outflow port of the flow meter 13 is connected via an outflow pipe 16 to a swivel joint 17 to which the base end of the oil supply hose 20 is connected to the other end.

As a result, in the illustrated fueling device 1 , the inlet piping 14 , the pump 12 , the flow meter 13 , and the outlet piping 16 constitute an internal fuel supply path for the fueling nozzle 30 , and the fueling hose 20 connects the fueling nozzle 30 to the fueling nozzle 30 . A fuel supply passage outside the main body of the fueling device 1 is configured.

A hose coupling unit 21 having an auxiliary valve mechanism, which will be described later, is provided in the middle of the oil supply hose 20 , and the oil supply hose 20 is divided into a body side hose portion 22 and a nozzle side hose portion 23 . Although the illustrated example shows an embodiment in which the hose coupling unit 21 is provided in the middle of the oil supply hose 20, the arrangement position of the hose coupling unit 21 is not limited to this. may be provided in

The fuel nozzle 30 is connected to the distal end of the fuel hose 20 and can open and close a main valve (not shown) inside the nozzle body 32 in response to the operation of the operating lever 31 . In the nozzle body 32, when the oil surface reaches the tip of the discharge pipe 33, the main valve is closed to discharge oil from the discharge pipe 33 regardless of the valve opening operation state of the operation lever 31. It has a built-in automatic valve closing mechanism that stops the

The fueling nozzle 30 is housed in a nozzle housing (nozzle holder) 18 provided in the fueling device main body 10 when the fueling nozzle 30 is not used for fueling work and is on standby. A nozzle switch 19 for detecting the extraction and storage of the fuel nozzle 30 is provided in the nozzle housing portion 18 .

On the other hand, on the fueling device body 10, a fueling information display 41 for displaying fueling information such as the amount of fuel supplied to the fuel tank of the vehicle by operating the fueling nozzle 30 is mounted on the fueling device main body 10. It is set up facing the

In addition, in the fueling device main body 10, the drive/stop of the pump motor 11 is controlled based on the nozzle removal/storage detection signal from the nozzle switch 19, and the fuel supply amount for the fuel supply target is controlled based on the flow rate pulse from the flow rate transmitter 15. is calculated and displayed on a fuel supply information display 41 to control the operation of each part of the fuel supply system 1 .

Then, the operator uses the illustrated fueling device 1 to perform the fueling operation for the fueling object as follows.

The operator removes the fuel nozzle 30 from the nozzle housing 18, inserts the discharge pipe 33 into the fuel filler port to be refueled, and operates the operation lever 31 to open the main valve in the nozzle body. , start discharging fuel to the refueling target. At that time, the pump motor 11 , that is, the pump 12 is driven by the oil supply control device 40 based on the output of the nozzle extraction detection signal from the nozzle switch 19 . The amount of fuel discharged from the refueling nozzle 30 to the refueling target, that is, the refueling amount is calculated by the refueling control device 40 based on the flow rate pulse output from the flow rate transmitter 15 and displayed on the refueling information display 41 . Discharge of fuel from the fuel nozzle 30 to the fuel supply target is interrupted or terminated by closing the main valve in the nozzle body by the valve closing operation of the operation lever 31 by the operator or by operating the automatic valve closing mechanism. . When the desired amount of fuel has been supplied to the fuel supply target, the operator closes the operation lever 31 if the operation lever 31 has not been closed by the operation of the automatic valve closing mechanism, and then closes the fuel nozzle. 30 is stored in the nozzle storage portion 18 . The oil supply control device 40 stops driving the pump motor 11 , that is, the pump 12 based on the output of the nozzle accommodation detection signal from the nozzle switch 19 .

FIG. 2 is a structural sectional view of the auxiliary valve mechanism included in the hose coupling unit 21 in the oil supply device 1 of this embodiment.
FIG. 3 is a structural cross-sectional view of the auxiliary valve mechanism shown in FIG. 2 in a state in which the oil is discharged from the oil supply nozzle.

In the illustrated example, the auxiliary valve mechanism 50 includes a valve seat member 51 having a valve seat portion 51a formed thereon, a valve body supporting member 52 to which a valve body 54 is displaceably mounted, and a valve body supporting the valve body 54. and a holding member 53 for fixing and holding the body supporting member 52 to the valve seat member 51 .

The valve seat member 51 has a cylindrical casing in which a through hole 51c is formed. An inner peripheral portion on the other end side along the direction serves as a mounting portion 51 e of the holding member 53 . In addition, in the inner peripheral portion of the through hole between the external connection portion 51d and the mounting portion 51e along the hole axis direction, from the side of the external connection portion 51d toward the mounting portion 51e, an annular valve seat portion 51a, The abutted step portion 51b of the valve body support member 52 is formed sequentially.

The valve body support member 52 is formed with a cylindrical casing that can be inserted into the through hole 51c of the valve seat member 51 from the mounting portion 51e side of the valve seat member 51 . A valve shaft 54a of the valve body 54 is inserted into the shaft portion of the through hole 52c, and a guide tube portion 52a for slidably guiding and supporting the valve shaft 54a is erected from the inner peripheral surface of the cylindrical casing. A valve shaft 54a of the valve body 54 is supported by the leg portion 52b so as to be coaxial with the annular valve seat portion 51a. The valve body support member 52 has an annular end surface on one end side that forms an engaging portion 52d with the abutted stepped portion 51b of the valve seat member 51, and an annular end surface on the other end side that abuts on the holding member 53. 52e.

The holding member 53 has a cylindrical casing in which a through hole 53c is formed, and an outer peripheral portion on one end side along the direction of the hole axis serves as a mounting portion 53a for the mounting portion 51e of the valve seat member 51. An outer peripheral portion on the other end side along the direction serves as an external connection portion 53 b on the other end side of the auxiliary valve mechanism 50 .

The valve body 54 is housed in the through hole 51c of the valve seat member 51 so that the valve shaft 54a thereof is guided and supported by the valve body support member 52 and can be seated on and removed from the valve seat portion 51a. A spring member 55 is contracted between the valve body 54 and the joint portion between the guide tube portion 52 a and the leg portion 52 b of the valve body support member 52 . The valve element 54 is always urged in the seating direction by the spring member 55 .

In the case of the present embodiment, the magnitude of the biasing force of the spring member 55 is determined, for example, by the amount of oil that is sent from the fuel supply passage in the main body to the external connection portion 51d on the one end side of the auxiliary valve mechanism 50. In this case, the valve body 54 is separated from the valve seat portion 51a to open the valve, and if oil is not being sent from the fuel supply passage in the main body to the external connection portion 51d of the auxiliary valve mechanism 50, The magnitude of the urging force is set so that the valve body 54 can be seated on the valve seat portion 51a to close the valve.

As a result, in the illustrated example, the auxiliary valve mechanism 50 operates as shown in FIG. When the flow path between the external connection portion 51d on the upstream side and the external connection portion 53b on the downstream side of the valve body 54 is in communication, and the oil liquid is not sent from the fuel supply path in the main body. 2, the flow path between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 is cut off.

In addition, even when the valve body 54 is in the closed state where the valve body 54 is seated on the valve seat portion 51a, the flow rate is throttled between the external connection portion 51d side and the external connection portion 53b side of the valve body 54. A pressure relief passage 56 communicating with a small flow rate is formed therethrough. In the illustrated example, the pressure relief passage 56 is formed in the valve body 54, but the pressure relief passage 56 is formed between the external connection portion 51d side, which is the upstream side of the valve body 54, and the external connection portion 53b side, which is the downstream side. It is also possible to form it in the valve seat surface of the valve seat portion 51a or in the peripheral wall portion of the valve seat member 51 as long as it is configured to communicate with a small flow rate.

The hose coupling unit 21 including such an auxiliary valve mechanism 50 liquid-tightly connects the body side hose portion 22 to its external connection portion 51d, and liquid-tightly connects the nozzle side hose portion 23 to its external connection portion 53b. It is connected and arranged in the middle or at the end (tip) of the oil supply hose 20 .

Next, the operation of the auxiliary valve mechanism 50 during the oil supply operation in the oil supply device 1 provided with the hose coupling unit 21 including the auxiliary valve mechanism 50 configured as described above will be described.

An operator removes the fuel nozzle 30 from the nozzle storage portion 18, the pump 12 is driven to send the oil, and the oil is sent to the fuel hose 20, which is the fuel supply channel outside the main body, through the fuel supply channel inside the main body. When started, the valve body 54 of the auxiliary valve mechanism 50 receives the flow of oil (liquid transfer) from the external connection portion 51d side, and is separated from the valve seat portion 51a against the biasing force of the spring member 55. . As a result, the flow path between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 is communicated, and the oil supply to the oil supply nozzle 30 is started.

After that, the main valve in the nozzle body 32 remains closed until the operator operates the operation lever 31 of the fuel nozzle 30 to open the valve. The hydraulic pressure will gradually rise to a predetermined pressure (for example, the relief pressure of the pump 12). The valve element 54 of the auxiliary valve mechanism 50 receives the pressure of the oil flow from the internal fuel supply passage until the pressure in the entire oil supply hose 20, which is the fuel supply passage outside the main body, reaches the predetermined pressure. Therefore, the passage between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 remains open.

Then, when the operator operates the operation lever 31 of the fuel nozzle 30 to open the fuel nozzle 30 and the fuel discharge from the fuel nozzle 30 is started, the fuel supply path on the fuel nozzle 30 side which is downstream with respect to the auxiliary valve mechanism 50 is opened. The internal fluid pressure decreases, and the pressure in the entire refueling hose 20 also decreases. During fuel discharge, the flow path between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 remains open.

On the other hand, the desired amount of fuel is supplied to the fuel supply target, and the operator closes or closes the operation lever 31 of the fuel supply nozzle 30, which has been operated until then, without throttling the fuel discharge amount. When the automatic valve closing mechanism provided in the nozzle 30 is actuated and the fuel discharge from the refueling nozzle 30 is suddenly stopped, the fuel fluid that has been discharged so far is suddenly blocked by the refueling nozzle 30, thereby refueling. A momentary and rapid pressure rise occurs starting from the nozzle 30 . Then, this instantaneous and rapid pressure rise tends to propagate through the fuel supply hose 20, which is the fuel supply passage outside the main body, from the fuel nozzle 30 side toward the upstream side of the fuel supply passage inside the main body. .

When such an instantaneous and rapid pressure rise is propagated from the external connection portion 53b of the auxiliary valve mechanism 50, the valve body 54 of the auxiliary valve mechanism 50 absorbs the sudden pressure rise and the biasing force of the spring member 55. By receiving it, it is immediately seated on the valve seat portion 51a and blocks the flow path between the external connection portions 51d and 53b of the auxiliary valve mechanism 50. As shown in FIG. As a result, it is possible to prevent a momentary and rapid pressure rise originating from the refueling nozzle 30 from propagating into the fuel supply passage on the upstream side of the auxiliary valve mechanism 50, including the fuel supply passage in the main body. can.

As a result, even if a momentary and rapid pressure rise originating from the refueling nozzle 30 occurs, the fuel supply passage provided between the refueling nozzle 30 and the fuel supply passage in the main body, that is, in the embodiment, By the operation of the auxiliary valve mechanism 50 provided in the middle of the fuel supply hose 20, structural members provided in the fuel supply path on the upstream side of the auxiliary valve mechanism 50 (for example, sealing members of piping connection parts, etc.) and components in the structural equipment It is possible to suppress the strength deterioration and damage of the parts (for example, the seal member in the swivel joint 17, the packing of the flow meter 13 and the pump 12, etc.), and also prevent oil leakage from these constituent members and constituent devices. As a result, the endurance life of the constituent members of the fuel supply path on the upstream side and the parts in the constituent equipment can be extended, the maintenance interval of the oil supply device 1 itself can be extended, and the maintenance cost can be reduced.
Furthermore, since the auxiliary valve mechanism 50 is provided in the fuel supply hose 20, which is the fuel supply passage outside the main body, the nozzle 30 is the starting point rather than providing the auxiliary valve mechanism 50 in the outflow pipe 16, which is the fuel supply passage inside the main body. It is possible to reduce the range of influence in the fuel supply passage by the instantaneous and abrupt increase in pressure. Further, since the auxiliary valve mechanism 50 is provided in the fuel supply passage outside the main body, the installation and removal of the auxiliary valve mechanism 50 by the operator can be easily performed.

In addition, due to the operation of the auxiliary valve mechanism 50, a momentary and rapid pressure rise originating from the fuel supply passage on the external connection portion 53b side, i.e., the fuel supply nozzle 30 confined in the nozzle-side hose portion 23, Even if the nozzle 30 is not opened for a long period of time, a small flow of oil is maintained between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 through the pressure relief passage 56 provided in the valve element 54 of the auxiliary valve mechanism 50. can flow, the fuel is gradually released to the fuel supply passage on the upstream side of the auxiliary valve mechanism 50 . As a result, the oil that is confined in the nozzle-side hose portion 23 due to the blockage of the auxiliary valve mechanism 50 and that causes a momentary and rapid pressure rise starting from the oil supply nozzle 30 will Furthermore, the pressure rise does not occur, and the parts in the components downstream of the auxiliary valve mechanism 50 (for example, the seal member of the elbow joint 34 that connects the nozzle side hose portion 23 and the fuel nozzle 30, the fuel nozzle 30, etc.) It is also possible to suppress deterioration in strength and damage to seal members, etc. provided in the main body.

Next, in the fuel supply device 1 of this embodiment, the hose coupling unit 21 includes the auxiliary valve mechanism 50 and the safety coupling 60, that is, the auxiliary valve mechanism 50 and the safety coupling 60 are integrated. The hose coupling unit 21 will be described with reference to FIGS. 4 to 6. FIG. In order to facilitate technical understanding, the auxiliary valve mechanism 50 having the configuration shown in FIGS. 2 and 3 is applied to the auxiliary valve mechanism 50, and redundant description of the configuration of the auxiliary valve mechanism 50 is omitted. .

FIG. 4 is a structural sectional view of a hose joint unit in which a safety joint and an auxiliary valve mechanism are integrally formed.
FIG. 5 is a structural cross-sectional view of the hose joint unit shown in FIG. 4 in a state of discharging oil liquid from the oil supply nozzle.
FIG. 6 is a structural sectional view of the hose coupling unit shown in FIG. 4 when the safety coupling is separated.

The safety joint 60 includes an upstream side joint valve portion 61 that prevents oil from flowing out and is contained in the body side hose portion 22 side, and is contained in the nozzle side hose portion 23 side. As shown in FIGS. 4 and 5, the downstream side joint valve portion 62 for preventing the outflow of the oil is integrally connected in a liquid-tight manner. In the illustrated example, the safety joint 60 has a configuration in which the auxiliary valve mechanism 50 is integrally connected to the downstream joint valve portion 62 thereof.

The upstream joint valve portion 61 of the safety joint 60 has a cylindrical casing in which a through hole 61c is formed. The portion 61 a is formed, and the outer peripheral portion on the other end side along the direction of the hole axis becomes the mounting portion 61 b for the downstream joint valve portion 62 . Further, in the hole on the mounting portion 61b side along the hole axial direction of the through hole 61c, a housing portion 61e for the ball valve body 61d, and A valve seat portion 61f on which the ball valve body 61d accommodated in the valve 61e is seated and disengaged is sequentially formed. One end of the ball valve body 61d in the housing portion 61e is supported by the stepped boundary between the housing portion 61e in the through hole 61c and the external connection portion 61a, and the other end is engaged with the ball valve body 61d. By the biasing force of the spring member 61g, it is always biased in the seating direction with respect to the valve seat portion 61f.

On the other hand, the downstream joint valve portion 62 has a cylindrical casing in which a through hole 62c is formed. The outer peripheral portion on the other end side along the direction of the hole axis becomes the mounted portion 62a, and the external connection portion 62b on the other end side of the safety coupling 60 serves as the external connection portion 51d on the one end side of the auxiliary valve mechanism 50. It can be worn tightly. In addition, a ball valve body 62d is seated and disengaged from one end side toward the other end side along the axial direction of the through hole 62c in the hole on the other end side of the mounted portion 62a along the axial direction of the hole. A valve seat portion 62e and an accommodating portion 62f for the ball valve body 62d are formed in this order. The ball valve body 62d in the housing portion 62f is a spring member whose other end side is supported by a stepped portion formed in the through hole 62c on the side of the external connection portion 62b, and whose one end side is engaged with the ball valve body 62d. By the biasing force 62g, it is always biased in the seating direction with respect to the valve seat portion 62e.

Then, the upstream joint valve portion 61 and the downstream joint valve portion 62 are liquid-tightly fitted to the mounting portion 61b of the upstream joint valve portion 61 with the mounted portion 62a of the downstream joint valve portion 62, thereby A shear pin 63 is used to prevent them from slipping out, and they are integrally connected. Further, in connecting the upstream joint valve portion 61 and the downstream joint valve portion 62, upstream The ball valve body 61d of the side joint valve portion 61 is positioned away from the valve seat portion 61f in the housing portion 61e against the biasing force of the spring member 61g, and the ball valve body 62d of the downstream side joint valve portion 62 is positioned. An engaging member 64 that is positioned against the biasing force of the spring member 62g is sandwiched and arranged at a location away from the valve seat portion 62e in the housing portion 62f. When the upstream joint valve portion 61 and the downstream joint valve portion 62 are connected, the through hole 61c of the upstream joint valve portion 61 and the through hole 62c of the downstream joint valve portion 62 form a joint flow path. The safety joint 60 is a joint flow path portion between the upstream side joint valve provided with the ball valve body 61d and the valve seat portion 61f and the downstream side joint valve provided with the ball valve body 62d and the valve seat portion 62e. The joint valve portion 61 and the downstream side joint valve portion 62 are separable.

Further, the external connection portion 51d of the auxiliary valve mechanism 50 is attached to the external connection portion 62b of the safety coupling 60, and the hose coupling unit 21 in which the safety coupling 60 and the auxiliary valve mechanism 50 are integrally formed is obtained. It is configured. 1, the external connection portion 61a of the safety joint 60 in the hose joint unit 21 is connected to the body side hose portion 22, and the external connection portion 53b of the auxiliary valve mechanism 50 in the hose joint unit 21 is connected to Connected to the nozzle side hose portion 23 , the hose coupling unit 21 is arranged in the middle of the oil supply hose 20 . In addition, the auxiliary valve mechanism 50 is arranged downstream of the safety joint 60 in the fuel supply passage outside the main body. The specific configuration of the safety coupling 60 integrated with the auxiliary valve mechanism 50 is not limited to the configuration described above. good.

According to the fuel supply device 1 of the present embodiment, the auxiliary valve mechanism 50 operates as shown in FIG. The flow path between the external connection portion 51d on the upstream side of the valve body 54 and the external connection portion 53b on the downstream side of the valve body 54 communicates with each other, while oil is fed from the fuel supply channel in the main body. If not, as shown in FIG. 4, the passage between the external connection portions 51d and 53b of the auxiliary valve mechanism 50 is cut off.

In addition, the safety coupling 60 does not operate unless a tensile force of a predetermined value or more acts on the nozzle side hose portion 23 to break the shear pin 63 and disconnect the upstream side coupling valve portion 61 and the downstream side coupling valve portion 62 . , the coupled state of the joint valve portions 61 and 62 is maintained, and the ball valve body 61d of the upstream side joint valve portion 61 and the ball valve body 62d of the downstream side joint valve portion 62 are both opened by the engagement member 64. The safety coupling 60 is held so that oil can flow therethrough.

In this state, even if a momentary and rapid pressure rise originating from the refueling nozzle 30 occurs, the auxiliary valve mechanism 50 of the hose joint unit 20 provided in the middle of the refueling hose 20 operates to The channel between 51d and 53b is cut off. As a result, a momentary and rapid increase in pressure is propagated starting from the refueling nozzle 30 into the fuel supply passage on the upstream side of the auxiliary valve mechanism 50, including the safety joint 60 and the internal fuel supply passage. You can prevent it from slipping.

Therefore, it is possible to prevent the service life of the safety joint 60 from being shortened due to the momentary and abrupt increase in pressure acting on the safety joint 60 . Specifically, the instantaneous and rapid pressure rise repeatedly acts on the safety joint 60, causing the safety joint 60 to malfunction due to the tensile force during normal work that is lower than the set value at which the safety joint 60 originally operates ( For example, even though there is no abnormal situation such as when the vehicle leaves the vehicle with the fuel nozzle 30 inserted into the fuel filler port due to accelerated deterioration of the shear pin 63 over time, safety is ensured. separation of the upstream joint valve portion 61 and the downstream joint valve portion 62 of the joint 60 can be prevented. Further, it is possible to prevent deterioration of the flow of fuel in the safety joint 60 due to a change in the opening degree of the joint valve portions 61 and 62 due to deformation of the engaging member 64 or the like.

Furthermore, constituent members provided in the fuel supply path on the upstream side (for example, seal members of piping connection parts, etc.) and parts in constituent equipment (for example, seal members in the swivel joint 17, the flow meter 13 and the pump 12 It is possible to suppress the deterioration and damage of the strength of the packing, etc.) and prevent oil leakage from these constituent members and constituent equipment. As a result, the endurance life of the constituent members of the upstream fuel supply path and the parts in the constituent equipment can be extended, the maintenance interval of the oil supply device 1 itself can be extended, and the maintenance cost can be reduced.

Further, when a tensile force of a predetermined value or more acts on the nozzle-side hose portion 23, the safety coupling 60 receives a tensile force of a predetermined value or more on the nozzle-side hose portion 23 before the refueling hose 20 breaks. The shear pin 63 is broken, the connection between the upstream joint valve portion 61 and the downstream joint valve portion 62 is released as shown in FIG. and the ball valve body 62d of the downstream joint valve portion 62 are both closed. As a result, oil can be prevented from flowing out due to breakage of the oil supply hose 20 .

FIG. 7 is a structural sectional view of a modified example of the hose coupling unit shown in FIG.

In the hose coupling unit 21 shown in FIG. 7, the ball valve element 62d of the downstream coupling valve portion 62 of the safety coupling 60 is eliminated from the hose coupling unit 21 shown in FIG. The ball valve body 62d of the downstream joint valve portion 62 of the joint 60 is also used. In this case, in the auxiliary valve mechanism 50, tensile force of a predetermined value or more acts on the nozzle-side hose portion 23, the share pin 63 is broken, and the connection between the upstream joint valve portion 61 and the downstream joint valve portion 62 is released. Even in this case, the valve body 54 is closed by the biasing force of the spring member 55, and the outflow of the oil liquid due to breakage of the oil supply hose 20 can be prevented.

In the example shown in FIG. 7, the hose coupling unit 21 is configured to have the downstream coupling valve portion 62 of the safety coupling 60. By constructing the mounted portion 62a, the downstream side joint valve portion 62 itself can be eliminated, and the size of the hose joint unit 21 including the auxiliary valve mechanism 50 and the safety joint 60 can be reduced.

FIG. 8 is a structural sectional view of another modification of the hose coupling unit shown in FIG.
FIG. 9 is an enlarged structural cross-sectional view of a shared valve mechanism portion in the hose coupling unit shown in FIG.

The hose coupling unit 21 shown in FIG. 8 is different from the hose coupling unit 21 shown in FIG. This corresponds to a configuration provided with a regulating valve that opens to reduce the differential pressure between the two when the pressure is higher than the pressure of the fuel on the separation portion side of the safety joint 60 .

In addition, the hose coupling unit 21 shown in FIG. 8 is similar to the hose coupling unit 21 shown in FIG. 7 in the hose coupling unit 21 shown in FIG. The valve body 54 of the auxiliary valve mechanism 50 also serves as the ball valve body 62d of the downstream joint valve portion 62 of the safety joint 60 without the ball valve body 62d.

In FIG. 8, the hose coupling unit 21 has a configuration in which an upstream coupling valve portion 71 and a downstream coupling valve portion 72 are integrally connected in a liquid-tight and separable manner. The upstream joint valve portion 71 functions as the upstream joint valve portion 61 of the safety joint 60 shown in FIG. 4, and the downstream joint valve portion 72 functions as the downstream joint valve portion of the safety joint 60 shown in FIG. In addition to functioning as the portion 61, it is configured to function as the auxiliary valve mechanism 50 shown in FIG. Therefore, the connecting portion between the upstream joint valve portion 71 and the downstream joint valve portion 72 corresponds to the separated portion of the safety joint 60 shown in FIG.

As a result, in the hose coupling unit 21, the upstream coupling valve portion 71 and the downstream coupling valve portion 72 are separated, and the upstream coupling valve portion 71 includes the upstream intra-body fuel supply passage. Outflow of the oil contained in the side hose portion 22 side is prevented, and the downstream joint valve portion 72 prevents outflow of the oil contained in the nozzle side hose portion 23 side. Further, the hose coupling unit 21 is in a state in which the upstream coupling valve portion 71 and the downstream coupling valve portion 72 are connected, that is, in a non-separated state as the safety coupling 60, and the downstream coupling valve portion 72 is connected to the fuel nozzle. It prevents the instantaneous and rapid pressure rise generated from 30 from propagating to the fuel supply passage on the upstream side.
The hose coupling unit 21 will be described in detail below.

The upstream joint valve portion 71 of the hose joint unit 21 has a cylindrical casing in which a through hole 71c is formed, and the inner peripheral portion on the one end side along the hole axis direction is the one end side of the hose joint unit 21. It becomes the external connection part 71a, and the outer peripheral part on the other end side along the hole axial direction becomes the mounting part 71b for the downstream joint valve part 72. As shown in FIG. Further, in the hole on the mounting portion 71b side along the hole axial direction of the through hole 71c, there are provided a housing portion 71e for the ball valve body 71d and a housing portion 71e for the ball valve body 71d from one end side toward the other end side along the hole shaft direction. A valve seat portion 71f on which a ball valve body 71d housed in 71e is seated and disengaged is sequentially formed. One end of the ball valve body 71d in the housing portion 71e is supported by the stepped boundary between the housing portion 71e in the through hole 71c and the external connection portion 71a, and the other end is engaged with the ball valve body 71d. By the biasing force of the spring member 71g, it is always biased in the seating direction with respect to the valve seat portion 71f.

On the other hand, the downstream joint valve portion 72 of the hose joint unit 21 has a cylindrical casing in which a stepped through hole having a boundary portion 72c having a diameter smaller than that of the mounting portion 71b is formed in the intermediate portion. is sandwiched, the inner peripheral portion on the one end side along the hole axis direction is a mounting hole 72a in which the mounting portion 71b of the upstream joint valve portion 71 is mounted, and the inner peripheral portion on the other end side is as shown in FIG. 4 of the safety joint 60 and the shared valve mechanism 80 serving as the auxiliary valve mechanism 50 are provided.

Then, the upstream joint valve portion 71 and the downstream joint valve portion 72 of the hose joint unit 21 fit the mounting portion 71b of the upstream joint valve portion 71 into the mounting hole 72a of the downstream joint valve portion 72 in a liquid-tight manner. A share pin 73 is used to prevent the two parts from slipping out, and the parts are integrally connected. Further, in connecting the upstream joint valve portion 71 and the downstream joint valve portion 72, upstream An engaging member 74 for positioning the ball valve body 71d of the side joint valve portion 71 against the urging force of the spring member 71g is sandwiched and disposed at a location away from the valve seat portion 71f in the housing portion 71e. It's becoming The engaging member 74 has the same configuration as the engaging member 64 shown in FIGS. 8, the engaging member 74 appears on the drawing in a state in which the engaging member 64 shown in FIGS. 4 and 5 is rotated by 90 degrees.

In the illustrated example, the shared valve mechanism 80 includes a valve body support member 82 to which a valve body 84 is displaceably mounted, and a housing portion of the downstream joint valve portion 72 that supports the valve body support member 82 on which the valve body 84 is supported. The valve seat portion 81 is formed by an open edge portion on the other end side of the boundary portion 72c of the downstream joint valve portion 72 .

The valve body support member 82 is formed with a tubular casing that can be inserted from the other end side of the downstream joint valve portion 72 into the accommodating portion 72b of the stepped through hole. A valve shaft 84a of a valve body 84 is inserted into the shaft portion of the tubular casing, and a guide tubular portion 82a for slidably guiding and supporting the valve shaft 84a is erected from the inner peripheral surface of the tubular casing. It is supported by the leg 82b. As a result, the valve shaft 84a of the valve body 84 supported by the guide cylinder portion 82a is supported so as to be coaxial with the annular valve seat portion 81 formed by the boundary portion 72c of the downstream joint valve portion 72 and guided. A plurality of through passages 82c are formed around the tubular portion 82a. The valve body support member 82 has an annular end surface on one end side that forms an engaging portion 82d with a contact stepped portion 72d formed on the inner peripheral surface of the accommodating portion 72b of the downstream joint valve portion 72, and an engaging portion 82d on the other end side. The annular end surface serves as a contacted portion 82 e with the holding member 83 .

The holding member 83 has a cylindrical casing in which a through hole 83 c is formed, and the outer peripheral portion of the one end side along the axial direction of the hole is formed on the inner peripheral surface of the accommodating portion 72 b of the downstream joint valve portion 72 . A mounting portion 83a for the mounted portion 72g is provided, and an outer peripheral portion on the other end side along the hole axis direction is an external connection portion 83b on the other end side of the hose coupling unit 21. As shown in FIG.

The valve body 84 is housed in the housing portion 72b of the downstream joint valve portion 72 so that the valve shaft 84a thereof is guided and supported by the valve body support member 82 so as to be separable from and seated on the valve seat portion 81 . A spring member 85 is contracted between the valve body 84 and the joint between the guide tube portion 82a of the valve body support member 82 and the leg portion 82b. The valve element 84 is always urged in the seating direction by the spring member 85 .

In the illustrated example, the magnitude of the biasing force of the spring member 85 is, for example, , the valve body 84 is separated from the valve seat portion 81 to open the valve, and when oil is not being sent from the fuel supply passage in the main body to the upstream joint valve portion 71 of the hose joint unit 21, the valve The magnitude of the urging force is set so that the body 84 can be seated on the valve seat portion 81 to close the valve.

In addition, in the illustrated example, the downstream joint valve portion 62 of the safety joint 60 shown in FIG. A pressure relief mechanism 90 including a pressure relief passage 91 and a regulating valve 92 provided in the pressure relief passage 91 is provided.

In the example shown in FIGS. 8 and 9, the pressure relief passage 91 is constructed such that a valve body support member passage portion 91a formed in the valve body support member 82 and a valve body passage portion 91b formed in the valve body 84 communicate with each other. It has become. The valve body passage portion 91b is constituted by a through hole formed in the valve body 84 along the extending direction of the valve shaft 84a. The hole portion on the facing side is a stepped through hole having a larger diameter than the hole portion on the valve shaft 84a side.

A large-diameter portion of the stepped through-hole including the stepped portion of the valve body passage portion 91b forms a regulating valve accommodating portion 91c, in which the regulating valve 92 is provided. The regulating valve 92 includes a valve seat ring 92a provided on a stepped portion, a ball valve body 92b that can be seated on and away from the valve seat ring, and a spring member that biases the ball valve body 92b in the direction of seating on the valve seat ring 92a. 92c and a support member 92d that supports the ball valve body 92b in the adjustment valve housing portion 91c via a spring member 92c. It is held within the portion 91c.

The regulating valve 92 adjusts the hydraulic pressure of the hydraulic fluid in the nozzle-side hose portion 23 on the downstream side of the hose coupling unit 21 to the hydraulic pressure of the hydraulic fluid in the main body-side hose portion 22 on the upstream side. When the pressure rises above a predetermined value set based on the force, the ball valve element 92b leaves the valve seat ring 92a to open the valve. As a result, a small amount of oil having a high hydraulic pressure in the nozzle-side hose portion 23 on the downstream side of the hose coupling unit 21 flows through the pressure relief passage 91 consisting of the valve element support member passage portion 91a and the valve element passage portion 91b. It takes an appropriate amount of time to flow and open the main body hose portion 22 on the upstream side where the hydraulic pressure is low. Further, the regulating valve 92 operates when the pressure difference between the oil in the nozzle-side hose portion 23 on the downstream side of the hose coupling unit 21 and the oil in the main body-side hose portion 22 on the upstream side becomes smaller than a predetermined value. The valve body 92b is seated on the valve seat ring 92a to close the valve. In the illustrated embodiment, the pressure relief passage 91 is divided into the valve support member passage portion 91a and the support member passage portion 91a. Alternatively, it is possible to form the peripheral wall portion of the downstream joint valve portion 72 so that the downstream side and the upstream side of the valve body 84 communicate with each other. Also, the configuration of the regulating valve 92 is not limited to the illustrated configuration using the ball valve body 92b.

Next, in the oil supply device 1 of this embodiment, an embodiment in which the hose coupling unit 21 has a common valve mechanism 80 will be described with reference to FIGS. 8 and 9 and FIGS.
FIG. 10 is a structural cross-sectional view of the hose joint unit shown in FIG. 8 in a state of discharging oil from the oil supply nozzle.
FIG. 11 is a structural cross-sectional view of the hose joint unit shown in FIG. 8 when an instantaneous and rapid pressure rise originating from the fuel nozzle occurs.
FIG. 12 is a structural cross-sectional view of the hose coupling unit shown in FIG. 8 when the safety coupling is separated.

In the lubricating apparatus 1 shown in FIG. 1, the external connection portion 71a of the upstream joint valve portion 71 in the hose joint unit 21 is connected to the main body hose portion 22, and the external connection portion 83b of the downstream joint valve portion 72, that is, the downstream The external connection portion 83b of the holding member 83 of the common valve mechanism 80 provided in the housing portion 72b of the side joint valve portion 72 is connected to the nozzle side hose portion 23, and the hose joint unit 21 is arranged in the middle of the fuel supply hose 20. It has a configured configuration.

According to the refueling apparatus 1 of this embodiment, the common valve mechanism 80 is configured so that the valve element 84 is positioned at the valve seat as shown in FIG. It is separated from the portion 81 to open the valve, and communicates with the flow path formed by the stepped through-hole of the downstream joint valve portion 72 . On the other hand, in the common valve mechanism 80, when the oil liquid is not being sent from the fuel supply passage in the main body, the valve body 84 is seated on the valve seat portion 81 to close the valve as shown in FIG. It is designed to block the flow path formed by the stepped through hole of the side joint valve portion 72

Further, the hose coupling unit 21 does not operate unless the shear pin 73 is broken due to the tensile force of a predetermined value or more acting on the nozzle side hose portion 23 and the connection between the upstream side coupling valve portion 71 and the downstream side coupling valve portion 72 is released. , the coupled state of both the joint valve portions 71 and 72 is maintained, the ball valve body 71d of the upstream side joint valve portion 71 is maintained in the valve open state by the engagement member 74, and oil is discharged from the fuel supply passage in the main body. When liquid is being sent, the oil can flow through the nozzle-side hose portion 23 .

Even if a momentary and rapid pressure rise originating from the fuel nozzle 30 occurs while the oil is being fed from the fuel supply path in the main body, the hose joint provided in the middle of the fuel hose 20 The common valve mechanism 80 of the unit 20 operates, the valve body 84 is seated on the valve seat portion 81 as shown in FIG. Cut off. As a result, the pressure instantaneously and rapidly rising starting from the refueling nozzle 30 is propagated to the safety joint 60 in the fuel supply path on the upstream side of the common valve mechanism 80, including the fuel supply path in the main body. You can prevent it from being lost.

Therefore, the instantaneous and abrupt increase in pressure acts on the upstream side joint valve portion 71 including the separation portion of the hose joint unit 20, shortening the service life of the hose joint unit 20 as the safety joint 60. can be prevented. Specifically, the momentarily and rapidly rising pressure repeatedly acts on the upstream side joint valve portion 71 including the separation portion of the hose joint unit 20, so that the hose joint unit 20 as the safety joint 60 is originally operated. The tensile force during normal work below the set value may cause malfunction (for example, aging deterioration of the shear pin 63 is accelerated, etc.), and the vehicle is started with the fuel nozzle 30 inserted into the fuel filler port of the vehicle. It is possible to prevent the upstream side joint valve portion 61 and the downstream side joint valve portion 62 from being separated in spite of not being in an abnormal situation such as the case of rolling. Further, it is possible to prevent deterioration of the flow of fuel in the hose coupling unit 21 due to a change in the valve opening of each coupling valve portion 61 due to deformation of the engaging member 74 or the like.

Furthermore, constituent members provided in the fuel supply path on the upstream side (for example, seal members of pipe connection parts, etc.) and parts in constituent equipment (for example, seal members in the swivel joint 17, flow meters 13, pumps 12, etc.) It is possible to suppress the deterioration and damage of the strength of the packing, etc.) and prevent oil leakage from these constituent members and constituent equipment. As a result, the endurance life of the constituent members of the fuel supply path on the upstream side and the parts in the constituent equipment can be extended, the maintenance interval of the oil supply device 1 itself can be extended, and the maintenance cost can be reduced.

A momentary and rapid pressure rise starting from the fuel nozzle 30 is prevented from propagating upstream by the shared valve mechanism 80 of the hose coupling unit 20, and the pressure rises downstream of the shared valve mechanism 80. Hydraulic pressure of the nozzle side hose portion 23 is released little by little over time through the pressure relief passage 91 by the pressure relief mechanism 90 provided in the common valve mechanism 80, and the pressure is reduced to the main body side on the upstream side where the hydraulic pressure is low. It is open for flow in the hose section 22 .

Therefore, the hydraulic pressure in the nozzle-side hose portion 23 on the downstream side of the common valve mechanism 80, which has risen due to the momentary and rapid pressure rise starting from the fuel nozzle 30, is gradually reduced, and the pressure rises. Since the state is not maintained as it is, as a result, components provided in the fuel supply path on the downstream side (for example, sealing members of pipe connection parts, etc.) and parts in the components (for example, the fuel supply nozzle 30 It is also possible to suppress deterioration in strength and damage to internal sealing members, packing, etc.).

Further, when a tensile force of a predetermined value or more acts on the nozzle side hose portion 23, the hose joint unit 20 applies a tensile force of a predetermined value or more to the nozzle side hose portion 23 before the fuel supply hose 20 breaks. 12, the coupling between the upstream joint valve portion 71 and the downstream joint valve portion 72 is released, the engaging member 74 is disengaged, and the ball valve body of the upstream joint valve portion 71 is released. 71d and the valve element 84 of the downstream joint valve portion 72 are both closed. As a result, oil can be prevented from flowing out due to breakage of the oil supply hose 20 .

In addition, in the downstream side joint valve portion 72 separated from the upstream side joint valve portion 71, the regulating valve 92 of the pressure relief mechanism 90 is pressed against the valve seat ring by the ball valve body 92b receiving the biasing force of the spring member 92c. Since it is seated on 92a to cut off the communication of the pressure relief passage 91, leakage of the oil liquid from the nozzle side hose portion 23 through the pressure relief passage 91 can be prevented.

The fuel supply device according to the present disclosure is not limited to the ground-type fuel supply device shown in FIG. Further, the specific structures of the auxiliary valve mechanism 50, the pressure relief mechanism 90, and the like are also the specific structures of the above-described embodiments, as long as they are capable of preventing the propagation of instantaneous and rapid pressure rise starting from the fuel supply nozzle. is not limited to

4 to 7, the auxiliary valve mechanism 50 is connected to the safety joint 60. However, the structure is not limited to this, and the nozzle side hose portion 23 on the downstream side of the safety joint 60 Needless to say, it may be provided in the middle of or connected to the tip.

1 refueling device,
10 lubricating device body (lubricating device housing), 11 pump motor, 12 pump,
13 flow meter, 14 suction port piping, 15 flow rate transmitter, 16 outlet piping,
17 swivel joint, 18 nozzle housing, 19 nozzle switch,
20 lubricating hose 21 hose coupling unit 22 body side hose portion
23 nozzle side hose portion, 30 refueling nozzle, 31 operation lever,
32 nozzle body, 33 discharge pipe, 34 elbow joint,
40 refueling control device, 41 refueling information indicator, 50 auxiliary valve mechanism,
51 valve seat member 51a valve seat portion 51b abutted stepped portion 51c through hole
51d external connection portion 51e mounted portion 52 valve support member
52a guide tube portion 52b leg portion 52c engaging portion 52d abutted portion
53 holding member 53a mounting portion 53b external connection portion 53c through hole
54 valve body 54a valve shaft 55 spring member 56 pressure relief passage
60 safety joint 61 upstream joint valve portion 61a external connection portion
61b Mounting portion 61c Through hole 61d Ball valve element 61e Accommodating portion
61f valve seat portion 61g spring member 62 downstream joint valve portion
62a attached part 62b external connection part 62c through hole
62d ball valve body 62e valve seat portion 62f housing portion 62g spring member
63 Shear pin 64 Engagement member 71 Upstream joint valve portion
71a external connection portion 71b mounting portion 71c through hole 71d ball valve body
71e housing portion 71f valve seat portion 71g spring member 72 downstream joint valve portion
72a Mounting hole 72b Accommodating portion 72c Boundary portion 72d Abutted stepped portion
73 share pin 74 engagement member 80 shared valve mechanism 81 valve seat portion
82 valve support member 82a guide tube portion 82b leg portion 82c through-flow passage,
82d engaging portion 82e contacted portion 83 holding member 83a mounting portion
83b external connection portion 83c through hole 84 valve body 84a valve shaft
85 spring member 90 pressure relief mechanism 91 pressure relief passage
91a valve support member passage portion 91b valve passage portion 91c regulating valve housing portion
92 regulating valve 92a valve seat ring 92b ball valve body 92c spring member
92d support member, 92e retaining ring.

Claims (4)

an in-body fuel supply channel provided in the device body and provided with a liquid feeding means;
A fuel provided with an on-off valve that communicates with the internal fuel supply passage through an external fuel supply passage including a fuel supply hose extending from the device main body and that discharges and stops the discharge of fuel to a fuel supply target. a feed nozzle;
a safety joint provided in the fuel supply path outside the main body, which separates and shuts off the fuel supply path to the fuel supply nozzle when a tensile force of a predetermined value or more acts on the fuel supply hose ;
It is provided in the safety joint or the fuel supply passage outside the main body downstream of the safety joint, and the pressure rise caused by the fuel on the side of the fuel supply nozzle due to the closing of the opening/closing valve of the fuel supply nozzle causes the safety joint to an auxiliary valve mechanism that prevents propagation to the upstream fuel supply path including the separation part of
The auxiliary valve mechanism has a check valve that closes when the pressure of fuel on the downstream side of the auxiliary valve mechanism is higher than the pressure of fuel on the upstream side of the auxiliary valve mechanism. a pressure relief mechanism for releasing the increased fuel pressure on the side of the fuel supply nozzle when the valve is closed to the upstream side of the check valve;
The safety joint has an upstream joint valve portion and a downstream joint valve portion configured to be separable, and the downstream joint valve portion disconnects the fuel supply path when separated from the upstream joint valve portion. A fuel supply device having a shutoff valve . The fuel supply device according to claim 1,
A fuel supply device in which the upstream joint valve portion and the downstream joint valve portion are integrally connected by an engaging member . The fuel supply device according to claim 2,
The pressure relief mechanism is
A fuel supply device that is a stepped through hole that communicates between the upstream side and the downstream side of the check valve and that has a variable inner diameter . The fuel supply device according to any one of claims 1 to 3,
The fuel supply device, wherein the auxiliary valve mechanism is formed integrally with the safety joint when the auxiliary valve mechanism is provided in the safety joint.

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