JP6537247B2 - Gas stopper with overspill prevention mechanism - Google Patents

Description

  The present invention relates to a gas plug with an overspill prevention mechanism provided with a fuse valve that automatically closes the gas passage when the flow rate of gas flowing in the gas passage of the gas plug exceeds a predetermined flow rate.

  Generally, as described in Patent Document 1 below, a conventional gas stopper with an excess outflow prevention mechanism has a plug main body in which a gas passage through which gas flows is formed, and an excess outflow provided in the gas passage. And a prevention mechanism. The plug body has a pipe-side cylinder connected to the primary gas pipe and an apparatus-side cylinder connected to the secondary gas pipe.

  The excessive outflow prevention mechanism includes a fuse valve, a receiving member for supporting the fuse valve movably in the flow passage direction of the gas passage, a fuse valve seat provided on the downstream side of the fuse valve in the gas passage, the fuse valve And a biasing member provided between the members for biasing the fuse valve away from the fuse valve seat. When the flow rate of the gas flowing in the gas passage exceeds a predetermined flow rate, the fuse valve moves against the biasing force of the biasing member by the pressure of the gas and sits on the fuse valve seat to shut off the gas passage.

JP, 2013-213541, A

  In the conventional gas valve with the excess outflow prevention mechanism, the fuse valve, the receiving member, the biasing member and the like are assembled from the primary side of the pipe side tubular portion, and the fuse valve seat and the like are assembled from the secondary side of the pipe side tubular portion. Therefore, there is a problem that the assembly is troublesome and it takes time to replace the parts.

The present invention has been made to solve the above problems, and in a gas plug with an excess outflow prevention mechanism, a plug body in which a gas passage through which gas flows is formed, and the inside of the gas passage. Equipped with over spill protection mechanism,
The excess outflow prevention mechanism includes a fuse valve, a receiving member for supporting the fuse valve movably in the flow direction of the gas passage, and a fuse valve seat provided on the downstream side of the fuse valve in the gas passage And a biasing member provided between the fuse valve and the receiving member for biasing the fuse valve away from the fuse valve seat, and the flow rate of the gas flowing in the gas passage is a predetermined flow rate. When it exceeds, the fuse valve moves against the biasing force of the biasing member by the pressure of the gas, sits on the fuse valve seat, and blocks the gas passage,
The excessive outflow prevention mechanism has a holding member for holding the receiving member, and a fuse valve unit is constituted by the holding member, the fuse valve, the receiving member and the biasing member, and the plug main body is a primary A piping side cylinder connected to the side gas pipe, and an equipment side cylinder connected to the secondary side gas pipe and detachably connected to the piping side cylinder;
The holding member of the fuse valve unit is detachably attached to the primary side portion of the device-side tubular portion, and the device-side tubular portion attached with the fuse valve unit is connected to the pipe-side tubular portion. The fuse valve unit is housed in the plug body.

  According to the above configuration, since the main part of the excessive outflow prevention mechanism can be handled integrally as the fuse valve unit, the gas plug can be easily assembled. Further, the fuser unit can be easily replaced by removing the device side tubular portion from the piping side tubular portion to expose the fuse valve unit from the inside of the plug body. Therefore, it is possible to easily change the working flow rate of the gas passage cut-off operation of the excess outflow prevention mechanism or the repair in the case where the fuse valve or the biasing member of the excess outflow prevention mechanism is defective.

Preferably, the device-side cylindrical portion has a support cylindrical portion which is inserted into the pipe-side cylindrical portion and detachably connected to the secondary-side opening of the pipe-side cylindrical portion, and the fuse valve unit It is characterized in that it is inserted into the support cylindrical portion from the primary side opening of the support cylindrical portion, and the holding member is detachably attached to the primary side opening of the support cylindrical portion .
According to the above configuration, the fuse valve unit is accommodated inside the support cylinder portion of the device side cylinder portion, and the support cylinder portion accommodating the fuse valve unit is accommodated inside the pipe side cylinder portion. Can be shortened.

Preferably, the device-side cylindrical portion is provided with a primary-side support cylindrical portion detachably connected to the pipe-side cylindrical portion, and a valve seat provided inside, and a gas connector for the secondary side gas pipe is provided. The valve body is accommodated on the downstream side of the fuse valve in the device-side cylindrical portion, and has a secondary-side connecting cylindrical portion which is connected and detachably connected to the supporting cylindrical portion. The valve body is seated on the valve seat by the biasing force of another biasing member to close the gas passage, and in use, the valve body is pushed by the gas connector to open the gas passage, and the support cylinder The fuse valve unit is attached to the primary side portion of the unit.
According to the above configuration, the connection cylinder, the valve body and the fuse valve unit are incorporated in the support cylinder, and the device side is unitized. Therefore, if the support cylinder is removed from the pipe side cylinder, the valve The main parts such as the fuse valve can be collectively removed from the gas plug. Therefore, it is easy to find out the cause at the time of failure and to replace parts. If the gas plug breaks down, it is sufficient to replace the parts and there is no need to replace the entire gas plug.

  According to the present invention, since the parts that constitute the gas plug are unitized, it is possible to easily assemble the gas plug and replace the parts.

FIG. 1 is a longitudinal sectional view showing the first embodiment of the present invention in a state where the gas valve is in the closed position and the fuse valve is in the open position. FIG. 2 is a cross-sectional view taken along the line X-X of FIG. FIG. 3 is a cross-sectional view similar to FIG. 1 showing the same embodiment with the gas valve in the first open position and the fuse valve in the second open position. FIG. 4 is a cross-sectional view similar to FIG. 1 showing the same embodiment with the gas valve in the first open position and the fuse valve in the second closed position. FIG. 5 is an exploded perspective view showing the entire configuration of the embodiment in an exploded manner. FIG. 6 is an exploded perspective view showing a part of the configuration of the embodiment assembled and unitized. FIG. 7 is a front view showing the holding member used in the embodiment. FIG. 8 is a cross-sectional view taken along line XX in FIG. FIG. 9 is a plan view of the support member used in the embodiment, as viewed from the X direction in FIG. FIG. 10 is a bottom view of the support member. FIG. 11 is a view seen from the X direction of FIG. FIG. 12 is a cross-sectional view taken along the Y-Y plug of FIG. FIG. 13 is a cross-sectional view showing a second embodiment of the present invention.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
1 to 12 show a first embodiment of the present invention. As shown in FIGS. 1 to 5, the gas plug 1 with the excessive outflow prevention mechanism of this embodiment has a plug body 2, a gas valve 3, a holding member 4, a receiving member 5 and a fuse valve 6.

  The plug body 2 has an outer cylindrical portion 2A, which is a pipe side cylindrical portion, and an inner cylindrical portion (supporting cylindrical portion) 2B, which is an apparatus side cylindrical portion, and a connecting cylindrical portion 2C. Each of the outer cylindrical portion 2A, the inner cylindrical portion 2B and the connection cylindrical portion 2C is formed as a straight cylindrical body whose both ends are open. The insides of the outer cylindrical portion 2A, the inner cylindrical portion 2B, and the connection cylindrical portion 2C constitute a gas passage 2D through which gas flows. Each of the cylindrical portions 2A to 2C does not necessarily have to be circular in cross section, and may be non-circular in cross section.

One end of the outer cylindrical portion 2A (the end on the upstream side; the right end in FIG. 1. Hereinafter, for convenience of the description, the configuration of the gas plug 1 with the excess outflow prevention mechanism will be described using the left and right in FIG. Of course, the present invention is not limited to such a directionality.) The tapered male thread portion 2a is formed on the outer peripheral surface. A gas pipe (not shown) on the primary side is screwed and fixed to the tapered male screw 2a. Then, gas is supplied from the primary side gas pipe to the right end portion inside the outer cylinder portion 2A. Therefore, the right end portion inside the outer cylindrical portion 2A is the most upstream side of the gas passage 2D. Instead of the tapered male screw portion 2a, a straight male screw portion may be formed, or a tapered female screw portion or a straight female screw portion may be formed at the end of the inner peripheral surface of the outer cylindrical portion 2A on the opening side.

  On the right end side of the inner cylindrical portion 2B, a small diameter portion (inner pipe portion) 2b which occupies most of the inner cylindrical portion 2B is formed, and at the other end, the outer diameter and the inner diameter are larger than the outer diameter and the inner diameter of the small diameter portion 2b. Large diameter portions 2c each having a large diameter are formed. The small diameter portion 2 b and the large diameter portion 2 c are coaxially arranged. A stepped surface 2d is formed between the inner peripheral surface of the small diameter portion 2b and the inner peripheral surface of the large diameter portion 2c. A flange portion 2e is annularly formed at the left end portion adjacent to the large diameter portion 2c of the small diameter portion 2b. The outer diameter of the flange portion 2e is larger than the outer diameter of the large diameter portion 2c.

The small diameter portion 2b is inserted into the outer cylindrical portion 2A from its left end opening. The left end portion of the small diameter portion 2b is screwed into the left end opening portion of the outer cylindrical portion 2A. Then, the inner cylindrical portion 2B is fixed to the outer cylindrical portion 2A by being screwed until the flange portion 2e abuts on the left end surface of the outer cylindrical portion 2A. In addition, although the screwing location of the small diameter part 2b and the outer cylinder part 2A is sealed by the adhesive agent, you may seal by seal members, such as an O-ring.

The small diameter portion 2b is disposed coaxially with the outer cylinder portion 2A. In addition, the portion of the small diameter portion 2b excluding the screwing portion with the outer cylindrical portion 2A is smaller in diameter than the inner diameter of the outer cylindrical portion 2A. As a result, an annular gap 2E is formed between the outer peripheral surface of the small diameter portion 2b and the inner peripheral surface of the outer cylindrical portion 2A. Of course, this gap 2E also constitutes a part of the gas passage 2D.

In the peripheral wall portion of the small diameter portion 2b, a communication hole 2f which penetrates the radial direction is formed. The communication hole 2f is disposed adjacent to a screwing portion between the small diameter portion 2b and the outer cylinder portion 2A. Therefore, the opening on the outside of the communication hole 2 f faces the left end of the gap 2 E. That is, the communication hole 2 f communicates with the gap 2 E. Therefore, the gas supplied to the outer cylindrical portion 2A flows into the inner cylindrical portion 2B through the communication hole 2f. As will be described later, the right end opening in FIG. 1 of the small diameter portion 2 b is closed by the holding member 4. Therefore, the gas which has flowed into the outer cylindrical portion 2A flows into the inner cylindrical portion 2B only through the communication hole 2f.

The large diameter portion 2c is protruded leftward from the outer cylinder portion 2A. The right end portion of the connection cylindrical portion 2C is screwed and fixed to the inner periphery of the large diameter portion 2c. Therefore, the gas flowing into the inner cylindrical portion 2B flows into the connecting cylindrical portion 2C from the opening at the other end of the inner cylindrical portion 2B. On the outer peripheral surface on the left end side of the connection cylindrical portion 2C, a plug portion 2g having a size and a shape defined by Japanese Industrial Standard (JIS S 2135) is formed. When the gas plug 1 is used, a socket (not shown) defined in the same standard is extrapolated and connected to the plug portion 2g. Therefore, the gas which has flowed into the outer cylinder 2A flows into the socket through the inside of the inner cylinder 2B and the connection cylinder 2C, and further to the gas device (not shown) through the gas pipe connected to the socket. Supplied. In addition, although the screwing location of the large diameter part 2c and 2 C of connection cylinder parts is sealed by the adhesive agent, you may seal by seal members, such as O ring. Also, the structure of the socket is well known, and the relationship with the present invention is also low, so the description thereof is omitted.

As described above, the small diameter portion 2 b is provided at the longitudinal middle portion of the gas passage 2 D. As a result, the gas passage 2D is divided into an upstream portion 2F located upstream of the small diameter portion 2b and a downstream portion 2G located downstream of the small diameter portion 2b. In the gas plug 1, the inside of the outer cylindrical portion 2A is the upstream side, and the inside of the connecting cylindrical portion 2C is the downstream side. The upstream side portion 2F and the downstream side portion 2G are communicated with each other by the inside of the communication hole 2f and the small diameter portion 2b.

  A straight hole 2h extending from the right end to a substantially central portion is formed inside the connection cylindrical portion 2C. The straight hole portion 2 h is disposed with its axis aligned with the axis of the connecting cylindrical portion 2 C. Therefore, the axis of the straight hole 2h also coincides with the axis of the inner cylindrical portion 2B. The inner diameter of the straight hole 2h is larger than the inner diameter of the small diameter portion 2b. An annularly extending recess is formed at the right end of the inner circumferential surface of the straight hole 2h. The recess is open at the right side in FIG. 1, but the open side is closed by the step surface (first contact portion) 2d. As a result, a mounting recess 2i having a U-shaped cross section whose left and right sides are closed is formed by the recess and the step surface. The sealing member 7 is mounted in the mounting recess 2i.

  The seal member 7 is made of rubber or other flexible resin, and is formed in a circular ring shape. The seal member 7 has a substantially V-shaped cross section, and the width (the dimension in the axial direction of the seal member 7) increases in the radially inward direction. The cross-sectional shape of the seal member 7 is not limited to the "V" shape, and may be a "U" cross section, or a hollow or solid circular shape. The outer diameter of the seal member 7 is preferably larger than the diameter of the bottom surface of the mounting recess 2i so that the outer peripheral portion is in pressure contact with the bottom surface of the mounting recess 2i, but the same or larger than the inner diameter of the straight hole 2h The diameter may be slightly smaller than the diameter of the bottom surface of the mounting recess 2i as long as it has a diameter. The inner diameter of the seal member 7 is smaller than the inner diameter of the straight hole 2 h. Therefore, the inner peripheral portion of the seal member 7 protrudes inward from the mounting recess 2i. The width of the seal member 7 may be determined so as to be able to move in the axial direction of the straight hole 2h with respect to the mounting recess 2i, or may be determined so as not to move. In the latter case, one side of the seal member 7 in the axial direction of the straight hole 2h always contacts the step surface 2d, and the other side always contacts one side (left side in FIG. 1) of the mounting recess 2i. Do.

A valve seat 2j is formed on the inner peripheral surface of the connection cylindrical portion 2C. The valve seat 2j is disposed on the left side of the straight hole 2h (downstream of the gas passage 2D). The valve seat 2j is constituted by a tapered surface which becomes smaller in diameter toward the left, and is disposed coaxially with the straight hole 2h. The maximum inside diameter of the valve seat 2j is smaller than the inside diameter of the straight hole 2h. The valve seat 2j may be configured by a curved surface such as a circular arc surface or the like instead of the tapered surface.

The gas valve 3 is inserted into the inner cylindrical portion 2B and the connecting cylindrical portion 2C so as to be movable in the longitudinal direction (longitudinal direction of the gas passage 2D) of the inner cylindrical portion 2B and the connecting cylindrical portion 2C. The gas valve 3 has an upstream side valve portion (cylindrical member; second valve body) 3A on the right side and a downstream side valve portion (valve body) 3B on the left side. The upstream valve portion 3A and the downstream valve portion 3B are configured separately from each other. However, both move integrally, except in the case described later. Therefore, the upstream valve portion 3A and the downstream valve portion 3B may be integrally formed.

  The upstream side valve portion 3A is formed of a metal cylinder whose both ends are open. As shown in FIGS. 5 and 6, a slit 3a extending from one end to the other end in the longitudinal direction is formed on one side of the upstream side valve portion 3A in the circumferential direction. As a result, the upstream valve portion 3A is formed in a C-shaped cross section, and can be elastically expanded and contracted. The outer diameter of the upstream side valve portion 3A is set larger than the inner diameter of the inner cylindrical portion 2B by a predetermined dimension. Therefore, the upstream side valve portion 3A is inserted into the inner cylindrical portion 2B in a state where the diameter thereof is elastically reduced, and the outer peripheral surface of the upstream side valve portion 3A is the inner cylindrical portion by the elastic force of the upstream side valve portion 3A itself. It is pressed against the inner peripheral surface of 2B. Moreover, the upstream side valve portion 3A is slidably inserted into the inner cylindrical portion 2B in the longitudinal direction (longitudinal direction of the gas passage 2D). The upstream side valve portion 3A is movable (slidable) between the first closed position shown in FIG. 1 and the first open position shown in FIG.

  The upstream side valve portion 3A is inserted into the inner cylindrical portion 2B in a state where the slit 3a is separated by 180 ° in the circumferential direction of the inner cylindrical portion 2B with respect to the communication hole 2f. A recess 2k is formed at a position facing the slit 3a on the inner peripheral surface of the inner cylindrical portion 2B. The spherical body 8 is inserted into the recess 2 k in a state in which a part of the sphere 8 is protruded inside the inner cylindrical portion 2B. A part of the spherical body 8 which protrudes inside the inner cylindrical portion 2B is inserted in the slit 3a so as to be relatively movable in its longitudinal direction and immovable in the circumferential direction of the upstream side valve portion 3A. As a result, the upstream side valve portion 3A can move in the longitudinal direction with respect to the inner cylindrical portion 2B, but the position is fixed in the circumferential direction.

  A notch 3 b is formed at the left end (the end on the downstream side) of the upstream-side valve 3 A. The notch 3b is disposed at the same position as the communication hole 2f in the circumferential direction of the inner cylindrical portion 2B, and as shown in FIG. 3, when the upstream valve portion 3A is positioned at the first open position, the communication hole Opposite 2f. Moreover, the notch 3b has a size larger than the communication hole 2f, and when the upstream valve 3A is in the first open position, the peripheral edge of the notch 3b surrounds the communication hole 2f. Located on the outside. Therefore, when the upstream side valve portion 3A is positioned at the first open position, the gas flowing into the communication hole 2f passes through the notch 3b and does not collide with the peripheral wall portion of the upstream side valve portion 3A. Flow into the left end (downstream end).

As shown in FIG. 1, the notch 3b is located on the left side of the communication hole 2f when the upstream valve 3A moves to the first closed position. Therefore, when the upstream side valve portion 3A moves to the first closed position, the right end portion of the peripheral wall portion of the upstream side valve portion 3A faces the communication hole 2f and closes it. Moreover, as described above, since the outer peripheral surface of the upstream side valve portion 3A is in pressure contact with the inner peripheral surface of the inner cylindrical portion 2B by the elasticity of the upstream side valve portion 3A itself, the opening inside the communication hole 2f is , And is reliably closed by the upstream valve portion 3A. Therefore, when the upstream side valve portion 3A is located at the first closed position, the space between the outer cylinder 2A and the inner cylinder 2B is shut off. That is, the gas passage 2D is closed, and the gas plug 1 is closed.

Next, for convenience of explanation, the holding member 4 will be described before the downstream side valve portion 3B will be described. The holding member 4 has a bottom 4a at its right end as shown in FIGS. Is open. That is, the holding member 4 is formed in a bottomed cylindrical shape. As shown in FIGS. 1 to 4, the holding member 4 is inserted into the inside of the small diameter portion 2 b from the right end opening with the opening thereof first, and the right end is the right end opening of the small diameter portion 2 b It is screwed on. As a result, the right end opening of the small diameter portion 2 b is closed by the holding member 4. Therefore, the gas in the outer cylinder 2A flows into the inner cylinder 2B only through the communication hole 2f. In addition, although the screwing location of the holding member 4 and the small diameter part 2b is sealed by the adhesive agent, you may seal by seal members, such as an O-ring.

The outer diameter of the portion of the holding member 4 excluding the bottom 4a is smaller than the inner diameter of the inner cylindrical portion 2B. As a result, an annular gap 9 is formed between the outer peripheral surface of the holding member 4 and the inner peripheral surface of the inner cylindrical portion 2B. The right end portion of the upstream side valve portion 3A is inserted in the left end portion of the annular gap 9 so as to be movable in the left-right direction. A main spring 10 as biasing means comprising a coil spring is disposed between the upstream side valve portion 3A and the bottom portion 4a. The right end of the main spring 10 is in contact with the bottom 4 a of the holding member 4, and the left end is in contact with the upstream side valve portion 3 A via the ring 11. Therefore, the upstream side valve portion 3A is biased leftward from the first open position to the first closed position by the main spring 10, and is positioned at the first closed position when the gas plug 1 is not used. There is.

  As shown in FIG. 3, when the upstream valve 3A is in the first open position, the left end of the holding member 4 is in the notch 3b (hereinafter, the upstream valve 3A is in the open position). The notched portion 3b is extended to the left side beyond the "notched portion 3b in the open position". Therefore, the left end portion of the peripheral wall portion of the holding member 4 faces the notch 3 b in the open position. A window hole 4b (see FIG. 7) is formed in the peripheral wall portion of the holding member 4 facing the notch 3b in the open position. The window hole 4b has a size larger than the notch 3b, and is disposed so as to surround the notch 3b in the open position. Therefore, the gas that has passed through the communication hole 2 f and the notch 3 b immediately flows into the window hole 4 b and flows into the holding member 4 from the window hole 4 b. The gas that has flowed into the holding member 4 flows from the left end opening of the holding member 4 into the left end of the upstream valve portion 3A. In addition, two window holes 4 b are formed at 180 ° intervals in the circumferential direction. This is to ensure that any one of the two window holes 4b always faces the notch 3b in the open position. Only one window hole 4b may be formed.

The downstream side valve portion 3B has a cylindrical portion 3c having a cylindrical shape. The outer diameter of the cylindrical portion 3c is set to be substantially the same as the inner diameter of the small diameter portion 2b. The right end (upstream end) of the cylindrical portion 3c is slidably inserted into the left end of the inner peripheral surface of the small diameter portion 2b. The right end surface of the cylindrical portion 3c is abutted against the left end surface of the upstream valve portion 3A. Therefore, the downstream side valve portion 3B is biased leftward by the main spring 10 via the upstream side valve portion 3A, and normally moves together with the upstream side valve portion 3A. Therefore, when the upstream side valve portion 3A moves to the first closed position, the downstream side valve portion 3B also moves to the first closed position, and when the upstream side valve portion 3A moves to the first open position, the downstream side valve portion 3B also moves. Move to the first open position.

The inside of the cylindrical portion 3c is a passage hole 3d. The passage hole 3d passes through the center of the cylindrical portion 3c from the right end face to the left end face. The gas flowing out to the left from the upstream valve portion 3A flows into the right end opening of the passage hole 3d. In particular, in this embodiment, since the right end surface of the cylindrical portion 3c is in contact with the left end surface of the upstream valve portion 3A, the gas in the upstream valve portion 3A directly flows into the passage hole 3d. A ring or the like may be interposed between the cylindrical portion 3c and the upstream valve portion 3A. The gas flowing into the passage hole 3d flows out from the left end opening of the passage hole 3d and flows into the straight hole portion 2h of the connection cylindrical portion 2C. That is, the gas flowing out from the left end opening of the passage hole 3d flows into the gas passage 2D downstream of the valve seat 2j, inside the gas passage 2D located downstream of the cylindrical portion 3c.

The downstream portion of the cylindrical portion 3c is inserted into the straight hole portion 2h of the connection cylindrical portion 2C. The inner diameter of the straight hole 2h is larger than the inner diameter of the small diameter portion 2b. Therefore, an annular gap 12 is formed between the outer peripheral surface of the cylindrical portion 3c and the inner peripheral surface of the straight hole 2h.

An annular projecting portion (first contact portion) 3 e is formed at the downstream end of the outer peripheral surface of the cylindrical portion 3 c. The outer diameter of the annular projection 3e is equal to or slightly smaller than that of the straight hole 2h, and is inserted into the inner circumferential surface of the straight hole 2h so as to be movable in the left-right direction. As shown in FIG. 3, when the upstream side valve portion 3A and the downstream side valve portion 3B move to the first open position, the annular projecting portion 3e strikes the seal member 7 and pushes it in the axial direction of the connecting cylindrical portion 2C. The step surface 2d is pressed and brought into contact. In other words, when the upstream side valve portion 3A and the downstream side valve portion 3B move to the first open position, the left and right side portions in FIG. 3 of the seal member 7 press and contact the annular projecting portion 3e and the step surface 2d. As a result, the space between the step surface 2d and the annular projection 3e is sealed by the seal member 7, and the space between the inner peripheral surface of the straight hole 2h (gas passage 2D) and the outer peripheral surface of the downstream valve portion 3B is It is sealed by the seal member 7. In addition, when the seal member 7 is crushed, the seal member 7 elastically deforms and expands in diameter, and the outer peripheral portion of the seal member 7 is more strongly in pressure contact with the bottom surface of the mounting recess 2 i. Thereby, the space between the inner peripheral surface of the straight hole 2 h and the outer peripheral surface of the downstream side valve portion 3 B is sealed more reliably.

A fuse valve seat 3f is formed on the inner peripheral surface of the passage hole 3d. The fuse valve seat 3f is disposed in the middle of the passage hole 3d in the longitudinal direction, but may be disposed in contact with the left opening of the passage hole 3d. The fuse valve seat 3f is formed by a tapered surface whose axis is aligned with the axis of the cylindrical portion 3c, and has a smaller diameter toward the left. The fuse valve seat 3f may be configured by an outwardly convex spherical surface or other curved surface instead of the tapered surface.

  On the left end surface of the cylindrical portion 3c, two support arm portions 3g extending toward the left side are formed. The two support arm portions 3g are disposed apart by 180 ° in the circumferential direction of the cylindrical portion 3c. A valve 3h is formed at the tip of the support arms 3g, 3g. The valve portion 3h is separated to the right (upstream side) with respect to the valve seat 2j when the downstream side valve portion 3B is positioned at the first open position, but the upstream side valve portion 3A and the downstream side valve portion When 3B is moved to the first closed position by the main spring 10, it seats on the valve seat 2j. In other words, when the valve portion 3h is seated on the valve seat 2j, the first closed position of the upstream valve portion 3A and the downstream valve portion 3B is determined. When the valve portion 3h is seated on the valve seat 2j, the gas passage 2D is closed and the gas plug 1 is closed. The gas flowing out of the cylindrical portion 3c flows into the inside of the connection cylindrical portion 2C (inside of the straight hole 2h) without resistance through the gap formed between the two support arms 3g and 3g.

  When the socket is externally inserted into the plug portion 2g in a state where the upstream valve portion 3A and the downstream valve portion 3B are located at the first closed position, as shown in FIG. 3, a push rod R provided in the socket Makes contact with the left end surface of the valve portion 3h, and moves the downstream side valve portion 3B and the upstream side valve portion 3A to the right (upstream side) against the biasing force of the main spring 10. When the socket is extrapolated to the predetermined connection position with respect to the plug portion 2g, the downstream valve portion 3B and the upstream valve portion 3A move to the predetermined position. The position (position of the valve 3) of the downstream side valve part 3B and the upstream side valve part 3A at this time is a 1st open position. When the downstream side valve portion 3B and the upstream side valve portion 3A are positioned at the first open position, the tip end of the holding member 4 is in the cylindrical portion 3c of the downstream side valve portion 3B. Therefore, the gas flowing from the communication hole 2f into the holding member 4 through the notch 3b and the window hole 4b does not enter the upstream valve 3A, and the inside of the passage hole 3d of the downstream valve 3B. And directly into the straight hole portion 2h of the connection cylindrical portion 2C through the passage hole 3d. And it flows in into a socket from 2C of connection cylinder parts, and is supplied to a gas instrument.

  When the socket is removed from the plug portion 2g, the push rod R moves to the left. As a result, the upstream valve portion 3A and the downstream valve portion 3B are moved to the left (downstream side) by the main spring 10. When the valve portion 3h is seated on the valve seat 2j, the upstream valve portion 3A and the downstream valve portion 3B can move further to the left side and stop. That is, it stops at the first closed position. When the upstream side valve portion 3A and the downstream side valve portion 3B stop at the first closed position, the communication hole 2f is closed by the upstream side valve portion 3A and the downstream end of the gas passage 2D is closed by the valve portion 3g. . As a result, the gas plug 1 is closed.

  Between the left end portion of the holding member 4 and the downstream side valve portion 3B, there is provided a sub spring 13 as biasing means comprising a coil spring. The sub spring 13 biases the downstream side valve portion 3B to the left (downstream side). Therefore, even if the upstream valve 3A is stopped due to an accident while moving from the first open position to the first closed position, the downstream valve 3B is moved to the first closed position by the sub spring 13. And the gas passage 2D is closed. Thereby, the safety of the gas plug 1 is improved.

  As shown in FIGS. 1 and 2, when the upstream valve 3A and the downstream valve 3B are in the first closed position, the tip of the holding member 4 is located on the right side of the downstream valve 3B. And only enter the inside of the upstream valve portion 3A. As shown in FIG. 3, when the upstream valve 3A and the downstream valve 3B are located at the first open position, the holding member 4 is relatively leftward with respect to the upstream valve 3A and the downstream valve 3B. As a result of the movement, the tip end of the holding member 4 passes through the upstream valve portion 3A and enters the downstream valve portion 3B. However, it is not always necessary to configure in this manner, and the tip end portion of the holding member 4 may be always positioned inside the upstream side valve portion 3A or inside the downstream side valve portion 3B.

  A receiving member 5 is fixedly provided inside the distal end portion of the holding member 4, and the fuse valve 6 is supported by the receiving member 5.

  That is, as shown in FIG. 5 and FIGS. 9 to 12, the receiving member 5 has a cylindrical portion 5 a having a circular cross section whose both ends are open. The cylindrical portion 5 a is fitted and fixed to the tip of the inner peripheral surface of the holding member 4 in a state where the axis of the cylindrical portion 5 a coincides with the axis of the holding member 4. The right end surface of the cylindrical portion 5a is disposed on the left side (downstream side) of the window hole 4b. Accordingly, the gas flowing into the inside of the holding member 4 through the window hole 4b flows into the cylindrical portion 5a, and flows into the passage hole 3d of the downstream side valve portion 3B through the cylindrical portion 5a.

  On the right end face of the cylindrical portion 5a, a plurality of (three in this embodiment) support arm portions 5b extending toward the right side are provided. The support arms 5 b are disposed apart from each other in the circumferential direction. Therefore, a gap is formed between the support arms 5b and 5b, and the gas flowing into the holding member 4 from the window hole 4b passes through the gap and enters the cylindrical portion 5a.

  A support cylinder 5c is provided at an intermediate portion in the longitudinal direction of the support arm 5b. The support cylinder 5c is disposed with its axis aligned with the axis of the cylinder 5a. The left end surface of the support cylindrical portion 5c is disposed at substantially the same position as the left end surface of the upstream side valve portion 3A when located in the first open position, as shown in FIGS. 3 and 4 There is. Therefore, the left end surface of the support cylindrical portion 5c is located slightly to the left (downstream side) from the left end of the communication hole 2f, and is located slightly to the right from the left end surface of the window hole 4b. The right end face of the support cylindrical portion 5c is disposed to coincide with the approximate center of the communication hole 2f in the left-right direction, but may be disposed upstream of the center of the communication hole 2f, or disposed downstream It is also good.

  The fuse valve 6 is supported movably in the left-right direction by the support cylindrical portion 5c. The fuse valve 6 has a long stem-like mushroom-like shape, and a substantially hemispherical fuse valve portion 6 a curved to bulge toward the left side, and from the center portion of the right end face of the fuse valve portion 6 a to the right And a guide shaft 6b extending toward the end.

  The position shown in FIG. 4 where the right end face of the fuse valve 6a abuts against the left end face of the support cylinder 5c and the fuse valve seat 3f of the downstream side valve 3B located at the first open position It is movable between and. The position of the fuse valve 6 when the right end surface of the fuse valve portion 6a abuts against the left end surface of the support cylindrical portion 5c is the second open position, and the fuse valve portion 6a is seated on the fuse valve seat 3f. The position of the fuse valve 6 is the second closed position. When the fuse valve 6 is positioned at the second open position, the right end of the fuse valve portion 6a is positioned slightly to the left (downstream side) from the center of the communication hole 2f. The fuse valve portion 6a may be arranged such that the entire fuse valve portion 6a is located downstream of the communication hole 2f when the fuse valve 6 is located at the second open position. However, when the gas in the holding member 4 flows into the cylindrical portion 5 a of the receiving member 5, it is necessary to consider that the fuse valve portion 6 a does not have a large resistance to the flowing gas.

  The guide shaft portion 6b has a length sufficiently longer than the support cylindrical portion 5c, and is inserted in the support cylindrical portion 5c so as to be movable in the left-right direction. By inserting the guide shaft 6b into the support cylinder 5c, the fuse valve 6 can move on the axes of the upstream valve 3A and the downstream valve 3B.

A snap ring 14 is fixed to the right end of the guide shaft 6b. A return spring (biasing means) 15 formed of a coil spring is provided on the guide shaft portion 6b located between the snap ring 14 and the support cylindrical portion 5c. The return spring 15 biases the guide shaft 6b to the right, which in turn biases the fuse valve 6 from the second closed position toward the second open position. The fuse valve 6 is normally positioned at the second open position by the return spring 15. The fuse valve 6, the receiving member 5, the fuse valve seat 3f, the return spring 15, and the holding member 4 form an overdraft prevention mechanism. The overspill prevention mechanism shuts off the gas passage 2D when the flow rate of gas flowing in the gas passage 2D exceeds a predetermined flow rate.

  The biasing force of the return spring 15 prevents the fuse valve 6 from moving from the second open position to the second closed position when the flow rate of the gas flowing in the gas passage 2D is within the normal range or less, When the flow rate exceeds a normal range, the fuse valve 6 is sized to allow the gas to move from the second open position to the second closed position. Therefore, when the flow rate of the gas flowing in the gas passage 2D is normal in the state where the socket is connected to the plug portion 2g, that is, in the state where the gas plug 1 is open, the biasing force of the return spring 15 It is pressed against the left end surface of the support cylindrical portion 5c and is positioned at the second open position. On the other hand, if the flow rate of gas flowing in the gas passage 2D becomes excessive, for example, if the gas pipe connected to the socket is detached from the socket or gas appliance and the flow rate of gas flowing in the gas passage 2D becomes excessive The fuse valve 6 is moved from the second open position to the second closed position against the biasing force of the return spring 15 by the pressure of the gas, and the fuse valve portion 6a is seated on the fuse valve seat 3f. As a result, the passage hole 3d of the downstream side valve portion 3B is closed, and the gas passage 2D is closed. Therefore, an accident such as a gas leak can be prevented in advance.

  As apparent from FIG. 4, when the downstream side valve portion 3B is located at the first open position and the fuse valve 6 is located at the second closed position, if the seal member 7 is not provided, the flow passage is A slight gap between the inner peripheral surface of the inner cylindrical portion 2B and the outer peripheral surface of the cylindrical portion 3c of the downstream side valve portion 3B, and the inner peripheral surface of the straight hole 2h and the outer peripheral surface of the cylindrical portion 3c Flow through the gap 12 (see FIG. 1) between the inner circumferential surface of the straight hole 2h and the outer circumferential surface of the annular protrusion 3e into the straight hole 2h downstream of the cylindrical portion 3c. , There is a risk of leaking to the outside through the socket. However, when the downstream valve portion 3B is located at the first open position and the fuse valve 6 is located at the second closed position in the gas plug 1 with the excessive outflow prevention mechanism, the outer periphery of the downstream valve portion 3B A seal member 7 seals between the surface and the inner peripheral surface of the straight hole 2 h. Therefore, the gas can be prevented from leaking when the fuse valve 6 is in the second closed position.

  When the socket is connected to the plug 2g and the fuse valve 6 is in the second closed position, and the socket is removed from the plug 2g, the upstream valve 3A and the downstream valve 3B are main springs. Moved to the left by 10 At the beginning of movement of the two valve parts 3A and 3B, the fuse valve 6 moves to the left together with the downstream side valve part 3B, but when the fuse valve 6 moves slightly to the left, the retaining ring 14 forms the support arm 5b. At the end, the fuse valve 6 can not move further to the left. Therefore, when the downstream side valve portion 3B moves further to the left, the fuse valve 6 moves to the right relative to the downstream side valve portion 3B, and the fuse valve portion 6a separates from the fuse valve seat 3e. Then, the fuse valve 6 is returned to the second open position by the return spring 15. Further, the upstream valve portion 3A and the downstream valve portion 3B are moved by the main spring 10 to the first closed position.

  As apparent from the comparison between FIG. 5 and FIG. 6, the gas plug 1 with the above-described configuration can be assembled as follows. First, the inner cylindrical portion 2B, the connecting cylindrical portion 2C, the seal member 7 and the downstream side valve portion 3B are assembled into a unit. Further, the holding member 4, the receiving member 5, the fuse valve 6, the return spring 15, and the snap ring 14 are assembled into a unit (fuse valve unit).

  When unitizing the inner cylindrical portion 2B, the connecting cylindrical portion 2C, the seal member 7, and the downstream side valve portion 3B, the seal member 7 and the downstream side valve portion 3B are firstly opened from the left end opening of the large diameter portion 2c of the inner cylindrical portion 2B. Then, the connection cylindrical portion 2C is screwed and fixed to the large diameter portion 2c. As a result, the inner cylindrical portion 2B, the connection cylindrical portion 2C, the seal member 7 and the downstream valve portion 3B can be unitized.

  At the time of unitization of the holding member 4, the receiving member 5, the fuse valve 6, the return spring 15 and the retaining ring 14, that is, the unitization of the fuse valve unit, first, the cylindrical portion 5 a of the receiving member 5 Insert 6b. Thereafter, the return spring 15 is extrapolated to the guide shaft 6b protruding rightward from the cylindrical portion 5a, and the snap ring 14 is fixed to the right end of the guide shaft 6b. Thus, the fuse valve 6, the return spring 15 and the retaining ring 14 are assembled to the receiving member 5. Thereafter, the receiving member 5 on which the fuse valve 6, the return spring 15 and the snap ring 14 are assembled is inserted from the left end opening of the holding member 4, and the cylindrical portion 5a of the receiving member 5 is fitted to the left end opening of the holding member 4 Lock together. Thus, the holding member 4, the receiving member 5, the fuse valve 6, the return spring 15 and the retaining ring 14 can be unitized.

  Thereafter, the auxiliary spring 13, the upstream valve portion 3A, the ring 11, and the main spring 10 are sequentially inserted into the unitized inner cylindrical portion 2B from the right end opening thereof, and the unitized holding member 4 is further inserted. . Then, the holding member 4 is screwed and fixed to the inner cylindrical portion 2B. Thereafter, the small diameter portion 2b of the inner cylindrical portion 2B is inserted into the outer cylindrical portion 2A and fixed by screwing. This completes the assembly of the gas plug 1 with over spill protection. As apparent from this, when assembling the gas plug 1 with the excess outflow prevention mechanism, it is possible to easily handle the assembly because several parts can be handled as a unit.

  In the gas plug 1 with the excessive outflow prevention mechanism described above, the main part of the excessive outflow prevention mechanism can be handled integrally as a fuse valve unit, so that the gas plug 1 can be easily assembled. Further, the fuse valve unit can be easily replaced by removing the inner cylinder 2B from the outer cylinder 2A and exposing the fuse valve unit from the inside of the plug body 2. Therefore, it is possible to easily repair the case where the fuse valve 6 or the return spring 15 or the like of the excessive outflow preventing mechanism has a problem. When it is desired to change the operation flow rate of the gas passage 2D shut off by the overspill prevention mechanism according to the equipment connected to the gas plug 1, replacing the fuse valve unit makes it easy to change the operation flow rate of the overspill prevention mechanism You can

  In the gas plug 1 with the excessive outflow prevention mechanism described above, the fuse valve unit is housed inside the inner cylinder portion 2B, and the inner cylinder portion 2B housing the fuse valve unit is housed inside the outer cylinder portion 2A. Therefore, the length of the plug body 2 can be shortened.

  In the gas plug 1 configured as described above, the connection cylindrical portion 2C, the downstream valve portion 3B, and the fuse valve unit are incorporated in the inner cylindrical portion 2B, and the device side is unitized. If removed from the portion 2A, the main components such as the downstream valve portion 3B and the fuse valve 6 can be collectively removed from the gas plug 1. Therefore, it is easy to find out the cause at the time of failure, and it is easy to replace parts. If the gas plug 1 breaks down, it is sufficient to replace parts, and there is no need to replace the entire gas plug 1.

  Even when the failure location can not be identified at the time of failure, it can be coped with by replacing a part of the plurality of unitized parts. For example, when a gas leak occurs on the downstream side of the gas plug 1, the unitized part including the downstream side valve portion 3B may be replaced.

  In the gas plug 1 with the excessive outflow prevention mechanism described above, the fuse valve seat 3f is provided inside the passage hole 3d of the downstream side valve portion 3B, so when the fuse valve 6 is seated on the fuse valve seat 3f, the valve At least the downstream end of the fuse valve 6 including the portion 6a enters the downstream valve portion 3B. The length of the gas passage 2D can be shortened by the amount by which the fuse valve 6 enters the downstream side valve portion 3B, and the length of the plug body 2 can be shortened. Therefore, the length of the gas plug 1 with the excess outflow prevention mechanism can be shortened.

  In particular, in this embodiment, since the gas passage 2D is closed by the upstream valve portion 3A and the downstream valve portion 3B, the gas passage 2D can be reliably closed. Moreover, since the fuse valve 6 is inserted inside the upstream side valve portion 3A, the length of the plug body 2 is shorter than when the two valve portions 3A, 3B and the fuse valve 6 are arranged in a line. can do. Therefore, the certainty of the closed state of the gas plug 1 with the excess outflow prevention mechanism can be improved, and the length of the gas plug 1 can be shortened.

FIG. 13 shows a second embodiment of the present invention. In the gas plug 1 'with the excessive outflow prevention mechanism of this embodiment, an outer cylinder 2A' is used instead of the outer cylinder 2A of the above embodiment. The outer cylindrical portion 2A 'is bifurcated on the downstream side, and two branched cylindrical portions 2H and 2I are formed at the downstream end. The two branch cylindrical portions 2H and 2I extend in parallel with each other, and are also parallel to the upstream end of the outer cylindrical portion 2A '. The two branch cylinder parts 2H and 2I do not necessarily have to be parallel to each other. For example, the two branch cylinder portions 2H and 2I may be inclined to be separated from each other as they go downstream, and may be inclined to the upstream end of the outer cylinder portion 2A ' . The side parts adjacent to each other among the upstream end portions of the two branch cylindrical portions 2H and 2I are in communication with the upstream end portion of the outer cylindrical portion 2A '.

Inner tubular portions 2B and 2B are screwed and fixed to the downstream end portions of the branched tubular portions 2H and 2I, respectively. A connection cylindrical portion 2C is screwed and fixed to each inner cylindrical portion 2B. Then, in the inner cylindrical portion 2B and the connecting cylindrical portion 2C, the respective components such as the gas valve 3, the holding member 4, the receiving member 5 and the fuse valve 6 are accommodated as in the above embodiment. The main part of the excess outflow prevention mechanism is unitized as a fuse valve unit, and is configured in the same manner as the above embodiment. Therefore, regarding those configurations, the same symbols as the reference numerals given to the corresponding configurations of the above embodiment are given, and the description thereof is omitted.

  In the gas plug 1 ′ with over spill prevention mechanism of the above configuration, which is a two-port gas plug, problems occur in parts such as the fuse valve 6 and the return spring 15 on either side of the branch cylindrical portions 2H and 2I. In this case, it is not necessary to replace the entire gas plug 1 'because the parts on one side can be replaced. Further, by changing the fuse valve unit, it is possible to change the operating flow rate of the overspill prevention mechanism, so it is possible to change the operating flow rate of only one of the two gas plugs. In the case of a two-port gas plug, the restriction of the space for replacing parts etc. becomes large. However, if the inner cylindrical portion 2B is removed from the outer cylindrical portion 2A, the main parts such as the downstream valve portion 3B and the fuse valve 6 Can be collectively removed from the gas plug 1 ', so parts can be easily replaced even in a narrow space.

The present invention is not limited to the above embodiment, and various modifications can be adopted without departing from the scope of the invention.
For example, in the above embodiment, although the flange portion 2e and the large diameter portion 2c of the inner cylindrical portion 2B are protruded from the outer cylindrical portion 2A to the outside, for example, the left end surface of the inner cylindrical portion 2B is the outer cylindrical portion 2A. The entire inner cylindrical portion 2B may be inserted into the outer cylindrical portion 2A so as to coincide with the left end face of the second. Also in this case, the connection cylindrical portion 2C is screwed and fixed to the left end opening of the inner cylindrical portion 2B.
In the above embodiment, the gas valve 1 with the excess outflow prevention mechanism is opened and closed, the gas passage 2D is opened and closed, the communication hole 2f is opened and closed by the upstream valve portion 3A, and the valve portion 3h of the downstream valve portion 3B. Of the valve seat 2j by opening and closing by separation, but the former may be omitted.
Furthermore, in the above embodiment, the holding member 4 is provided in the inner cylindrical portion 2B, and the fuse valve 6 is movably held by the holding member 4, but the fuse valve 6 is directly held in the inner cylindrical portion 2B. You may
For example, the holding member 4 may be provided with the fuse valve seat 3f, and the fuse valve seat 3f may be included in the fuse valve unit.

1 gas stopper with overspill prevention mechanism 1 'gas stopper with overspill prevention mechanism 2 plug body 2A outer cylinder portion (pipe side cylinder portion)
2A 'Outer cylinder (pipe side cylinder)
2B Inner cylinder (Support cylinder; Equipment side cylinder)
2C Connection tube (Device side tube)
2D gas passage 2j valve seat 3 gas valve 3B downstream side valve part (valve body)
3f fuse valve seat (overflow prevention mechanism)
3h Valve part 4 Holding member (Fuse valve unit; Overflow prevention mechanism)
5 Receiving member (fuse valve unit; over spill prevention mechanism)
6 Fuse valve (Fuse valve unit; Overflow prevention mechanism)
6a fuse valve 10 main spring (other biasing means)
13 Secondary spring (other biasing means)
15 Return spring (biasing member; fuse valve unit; over spill prevention mechanism)

Claims (3)

A plug body in which a gas passage through which gas flows is formed;
An excess outflow prevention mechanism provided inside the gas passage;
The excess outflow prevention mechanism includes a fuse valve, a receiving member for supporting the fuse valve movably in the flow direction of the gas passage, and a fuse valve seat provided on the downstream side of the fuse valve in the gas passage And a biasing member provided between the fuse valve and the receiving member for biasing the fuse valve away from the fuse valve seat, and the flow rate of the gas flowing in the gas passage is a predetermined flow rate. When it exceeds, the fuse valve moves against the biasing force of the biasing member by the pressure of the gas to be seated on the fuse valve seat, thereby blocking the gas passage,
The excessive outflow prevention mechanism has a holding member for holding the receiving member,
A fuse valve unit is constituted by the holding member, the fuse valve, the receiving member and the biasing member,
The plug body has a pipe-side cylindrical portion connected to the primary-side gas pipe, and an equipment-side cylindrical portion connected to the secondary-side gas pipe and detachably connected to the pipe-side cylindrical portion. And
The Rukoto primary end of the holding member of the fuse valve unit is detachably attached to the primary opening of the appliance-side cylindrical portion, the fuse valve of the fuse valve unit, the receiving member and the biasing means, Housed in the above-mentioned equipment side cylinder part,
The fuse valve unit is accommodated in the plug body by connecting the device side tubular portion to which the fuse valve unit is attached to the pipe side tubular portion, so that the gas plug with over spill prevention mechanism is characterized. . The device-side cylindrical portion has a support cylindrical portion which is inserted into the pipe-side cylindrical portion and detachably connected to the secondary-side opening of the pipe-side cylindrical portion.
The primary side opening is formed in the support cylinder,
The holding member of the fuse valve unit is excessive according to claim 1, characterized in that the primary-side opening of the supporting cylinder unit is inserted into the supporting cylinder unit, it is attach to the primary-side opening Gas plug with spill prevention mechanism. A plug body in which a gas passage through which gas flows is formed;
An excess outflow prevention mechanism provided inside the gas passage;
The excess outflow prevention mechanism includes a fuse valve, a receiving member for supporting the fuse valve movably in the flow direction of the gas passage, and a fuse valve seat provided on the downstream side of the fuse valve in the gas passage And a biasing member provided between the fuse valve and the receiving member for biasing the fuse valve away from the fuse valve seat, and the flow rate of the gas flowing in the gas passage is a predetermined flow rate. When it exceeds, the fuse valve moves against the biasing force of the biasing member by the pressure of the gas to be seated on the fuse valve seat, thereby blocking the gas passage,
The excessive outflow prevention mechanism has a holding member for holding the receiving member,
A fuse valve unit is constituted by the holding member, the fuse valve, the receiving member and the biasing member,
The plug body has a pipe-side cylindrical portion connected to the primary-side gas pipe, and an equipment-side cylindrical portion connected to the secondary-side gas pipe and detachably connected to the pipe-side cylindrical portion. And
The Rukoto primary end of the holding member of the fuse valve unit is detachably attached to the primary opening of the appliance-side cylindrical portion, the fuse valve of the fuse valve unit, the receiving member and the biasing means, Housed in the above-mentioned equipment side cylinder part,
The fuse valve unit is accommodated in the plug body by connecting the device-side tubular portion to which the fuse valve unit is attached to the pipe-side tubular portion.
The device-side cylindrical portion is provided with a primary-side support cylindrical portion detachably connected to the pipe-side cylindrical portion, and a valve seat provided inside, and is connected to the gas connector of the secondary-side gas pipe And a secondary-side connection cylinder part detachably connected to the support cylinder part,
The valve body is accommodated on the downstream side of the fuse valve in the device-side cylindrical portion, and when not in use, the valve body is seated on the valve seat by the biasing force of another biasing member to close the gas passage, In use, the valve body is pushed by the gas connector to open the gas passage,
A primary side opening of the device side cylindrical portion is formed in the primary side of the support cylindrical portion, and the fuse valve unit is attached to the primary side opening. Gas plug.

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