JP3590527B2 - Gas pressure regulator - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to a gas pressure reducing regulator for reducing the pressure of a gas.
[0002]
[Prior art]
Conventionally, to supply LP gas (liquefied petroleum gas) such as propane or natural gas to gas appliances such as stoves and water heaters connected to indoor gas pipes such as general households and stores, cylinders placed outdoors Generally, there is a gas supply method called a bulk method in which the gas is supplied from a large tank buried underground.
[0003]
The amount of LP gas generated and vaporized varies depending on the vapor pressure, and the gas pressure is not stable due to the temperature and atmospheric pressure. Therefore, the gas pressure is reduced to a predetermined supply pressure between a cylinder or a tank and an indoor gas pipe. By interposing a gas pressure regulator (pressure regulator), the gas is stably supplied at a constant gas pressure.
[0004]
Many gas decompression regulators currently used are of a single-stage decompression type, and a two-stage decompression type is also used in a bulk system.
[0005]
For example, as shown in FIG. 11, a two-stage depressurizing type gas depressurizing regulator includes a primary side depressurizing means 201 for depressurizing a gas supplied from a tank to a predetermined primary side outlet pressure or lower, and a gas depressurizing means on the primary side. A secondary pressure reducing means 202 is provided for reducing the pressure to a predetermined secondary outlet pressure lower than the outlet pressure and supplying the reduced pressure to the indoor gas pipe.
[0006]
The primary side depressurizing means 201 opens and closes a nozzle 203 through which gas flows with a rubber valve body 204, supports the valve body 204 with an openable and closable swing member 205, and attaches the swing member 205 to the valve body. A spring 208 is pressed by a spring 206 in the closing direction of the nozzle 204, and a diaphragm 208 in contact with the swing member 205 is airtightly provided above a gas flow path 207 communicating with the outlet side of the nozzle 203, and the diaphragm 208 is moved downward, that is, the valve body 204. It is configured to be pushed by a spring 209 in the opening direction.
[0007]
Then, when the primary side outlet pressure in the gas flow path 207 received by the diaphragm 208 decreases due to the use of the gas, the diaphragm 208 is pushed downward by the spring 209 and the swing member 205 is opened by the diaphragm 208 in the opening direction (FIG. 11). The valve body 204 is swung clockwise (clockwise), the valve body 204 is opened apart from the nozzle 203, and the gas flows. When a gas at a high pressure flows into the gas passage 207 and the primary outlet pressure in the gas passage 207 received by the diaphragm 208 increases, the diaphragm 208 is pushed upward against the spring 209 by this pressure. The swing member 205 is swung in the closing direction (counterclockwise direction in FIG. 11) by the spring 206, the valve body 204 is pressed against the nozzle 203 and closed, the gas flow is stopped, and the predetermined primary side outlet is opened. Kept at pressure.
[0008]
At present, security equipment incorporating a computer has been used, and this security equipment monitors the secondary outlet pressure of gas guided to indoor gas piping through a gas pressure reducing regulator, When the secondary outlet pressure rises to a predetermined abnormal pressure, a failure of the gas pressure regulator and an abnormality such as a life are detected.
[0009]
[Problems to be solved by the invention]
By the way, foreign matters such as sand particles and dust may enter the pipes and the tank during construction or when filling the tank with gas. When this foreign matter moves with the flow of gas and bites between the nozzle and the valve body closed by the nozzle, the foreign matter is embedded on the surface of the rubber valve body, and the foreign matter is embedded even when the valve body is opened. In this state, the closing performance between the nozzle and the valve element is apt to decrease.
[0010]
As described above, when foreign matter is caught between the nozzle and the valve body on the primary side and the closing performance of the primary side is reduced, the primary side outlet pressure increases, and the secondary side outlet pressure also increases accordingly. , Security equipment is determined to be abnormal.
[0011]
At this time, even when the foreign matter is only temporarily bitten or when the foreign matter is embedded in the valve body, the foreign matter enters the inside of the valve body and the rubber portion comes into contact with the nozzle, so that the closing performance is reduced. When the pressure rises, both the outlet pressure on the primary side and the outlet pressure on the secondary side return to normal, and it is determined that the security equipment is normal.
[0012]
Therefore, when it is determined that the safety equipment is abnormal, the gas decompression regulator may be replaced early even though it is neither a failure nor a service life. Not only can the failure and life of the pressure reducing regulator not be predicted with certainty, but there is also a problem that it is mistaken as a failure of the security device itself.
[0013]
The present invention has been made in view of such a point, and enables the closing performance to be stably maintained for a long period of time against the intrusion of foreign matter into the valve body, stabilizes the outlet pressure, and for example, in a security device. It is an object of the present invention to provide a gas pressure reducing regulator capable of accurately predicting the life by monitoring the outlet pressure of the gas.
[0014]
[Means for Solving the Problems]
The gas pressure reducing regulator according to claim 1 includes a regulator body having a gas inlet and a gas outlet, a nozzle provided between the gas inlet and the gas outlet of the regulator body, A valve that supports a valve element that can be closed and is provided so as to be movable in a direction in which the nozzle opens and closes the valve element, and a communication path that communicates the nozzle side and the gas outlet side by opening the valve element. A support, a spring that pushes the valve support in the opening direction of the valve, and a spring that is provided integrally with the valve support and has one side communicating with the atmosphere and the other side communicating with the gas outlet. And a diaphragm that directly acts so that the pressure of the gas at the gas outlet side pushes the valve support toward the closing direction of the valve body.A stopper for restricting movement of the valve support in the closing direction at a position where the valve bites into the nozzle by a predetermined amount corresponding to the end of life of the valve;Is provided.
[0015]
A valve support that supports the valve body that opens and closes the nozzle and a diaphragm are provided integrally, and the pressure of the gas on the gas outlet side against the diaphragm pushes the valve support body in the closing direction of the valve body. As a result, even if foreign matter is caught between the nozzle and the valve body, the higher the pressure on the gas outlet side, the more strongly the valve body is pressed against the nozzle via the diaphragm, Close the nozzle with the valve. Therefore, the closing performance can be stably maintained for a long time against the foreign matter being caught in the valve body, the outlet pressure on the gas outlet side is stabilized, and the life prediction by monitoring the outlet pressure in a safety device, for example, can be performed. It is possible to perform it accurately.In addition, at the end of the life of the valve element, the closing performance of the valve element is deteriorated, and the valve element is pressed more strongly against the nozzle. By restricting the movement of the valve support in the closing direction at the biting position by the stopper, the outlet pressure can be increased, and for example, the life can be accurately detected by monitoring the outlet pressure with a security device.
[0016]
According to a second aspect of the present invention, there is provided a gas pressure reducing regulator according to the first aspect, wherein a gas inlet, a nozzle, a valve body, a valve support, a spring, a diaphragm, and a gas outlet are coaxially arranged. Things.
[0017]
Since the gas inlet, the nozzle, the valve element, the valve support, the spring, the diaphragm, and the gas outlet are coaxially arranged, the size is reduced.
[0018]
The gas decompression regulator according to claim 3, further comprising a gas inlet and a gas outlet, a regulator main body having a gas flow passage communicating with the gas inlet and the gas outlet, and a gas flow passage from the gas inlet. A primary pressure reducing means for reducing the gas pressure flowing into the gas below a predetermined primary outlet pressure, and a predetermined secondary outlet pressure lowering the gas pressure flowing out of the gas flow passage to the gas outlet through the primary outlet pressure. The apparatus further includes a secondary-side depressurizing unit for depressurizing the nozzle, the primary-side depressurizing unit supporting a nozzle provided between the gas inlet and the gas flow path, and a valve body that can close the nozzle. A valve support provided movably in a direction to open and close the nozzle with the valve body, and provided with a communication path for communicating the nozzle side and the gas flow path side by opening the valve body, Toward opening direction of valve A pressing spring is provided integrally with the valve support, and one side is communicated with the atmosphere and the other side is communicated with the gas flow path. A diaphragm that acts directly to push in the direction of closure of the valveA stopper for restricting movement of the valve support in the closing direction at a position where the valve bites into the nozzle by a predetermined amount corresponding to the end of life of the valve;It has.
[0019]
In the two-stage depressurizing system, the primary side depressurizing means is provided integrally with a valve support for supporting a valve element for opening and closing the nozzle and a diaphragm, and the primary outlet of the gas on the gas flow path side with respect to the diaphragm. Since the pressure directly acts to push the valve support in the closing direction of the valve body, the higher the outlet pressure on the primary side becomes, the more the foreign matter gets caught between the nozzle and the valve body. The valve is strongly pressed against the nozzle via the diaphragm, and the nozzle is securely closed by the valve. Therefore, the closing performance can be stably maintained for a long period of time against the foreign matter being caught in the valve body of the primary pressure reducing means, and the secondary outlet pressure is stabilized, and for example, the secondary outlet pressure in a safety device is improved. It is possible to accurately perform the life prediction by monitoring the data.In addition, at the end of the life of the valve element, the closing performance of the valve element is deteriorated, and the valve element is pressed more strongly against the nozzle. By restricting the movement of the valve support in the closing direction at the biting position by the stopper, the outlet pressure can be increased, and for example, the life can be accurately detected by monitoring the outlet pressure with a security device.
[0020]
The gas pressure reducing regulator according to claim 4 is the gas pressure reducing regulator according to claim 3, wherein the nozzle, the valve element, the valve support, the spring, and the diaphragm of the primary side pressure reducing means are arranged with respect to the gas inlet of the regulator body. And are arranged coaxially.
[0021]
And since the nozzle, valve body, valve support, spring and diaphragm of the primary pressure reducing means are arranged coaxially with respect to the gas inlet of the regulator body, the primary pressure reducing means is reduced in size and this primary pressure reducing means is reduced. Regulator body incorporating side pressure reducing means becomes smaller.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0023]
FIG. 6 shows an example of a usage state of the gas decompression regulator, and a so-called bulk gas supply system is used in which a large tank 2 buried underground 1 supplies a house 3 such as a general home or a store. In the middle of the gas pipe 4 from the tank 2 to the house 3, a valve 5 for opening and closing, a two-stage depressurizing type gas depressurizing regulator 6 for depressurizing the gas in the tank 2 to a predetermined supply pressure, and a gas meter 7 are provided. It is connected. In addition, between the gas decompression regulator 6 and the house 3, there is interposed a security device which is integrated with or separate from the gas meter 7 and incorporates a computer, and is guided to the gas equipment in the house 3 through the gas decompression regulator 6. The outlet pressure of the gas on the secondary side is monitored, and when the outlet pressure on the secondary side rises to a predetermined abnormal pressure, an abnormality such as a failure of the gas decompression regulator 6 or a service life is detected.
[0024]
1 to 3 show the structure of the gas decompression regulator 6, wherein 11 is a regulator main body, which is composed of a main body case 12 and a primary side case 13 integrally attached to the main body case 12. The secondary case 14 is configured.
[0025]
A gas inlet 15 connected to the tank 2 side is formed at one end of the regulator body 11, and a gas outlet 16 connected to the house 3 is formed at the other end. A gas passage 17 is formed between the gas passage 17 and the outlet 16.
[0026]
In the primary case 13, a primary pressure reducing means 18 for reducing the pressure of the gas flowing into the gas flow path 17 from the gas inlet 15 to a predetermined primary outlet pressure or less is provided.
[0027]
In the secondary case 14, a secondary pressure reducing means 19 for reducing the gas pressure flowing out of the gas flow path 17 to the gas outlet 16 to a predetermined secondary outlet pressure lower than the primary outlet pressure is provided. Have been.
[0028]
The primary pressure reducing means 18 has a nozzle body 21, a valve body 22, a poppet 23 as a valve support, a spring 24, and a diaphragm 25, which are disposed coaxially with respect to the gas inlet 15. I have.
[0029]
The nozzle body 21 is screwed and fixed inside the primary case 13, a connecting portion 26 having a gas inlet 15 at one end is formed, and a cylindrical portion 27 projecting into the primary case 13 at the other end. Are formed, and a nozzle 28 is formed between the connecting portion 26 and the cylindrical portion 27. The nozzle 28 has a nozzle hole 29 at the center, and the edge of the nozzle 28 is formed to project in the direction of the cylindrical portion 27. Inside the gas inlet 15, a wire mesh filter 30 for capturing foreign matter such as sand powder and dust is attached.
[0030]
The valve body 22 is made of rubber, formed in a disk shape having a diameter larger than that of the nozzle hole 29, and formed with a locking claw 31 that is locked to the poppet 23 on a surface opposite to the nozzle 28.
[0031]
The poppet 23 is formed in a cylindrical shape, and is kept in an airtight manner in the cylindrical portion 27 of the nozzle body 21 through a plurality of O-rings 32 mounted on the outer periphery thereof while maintaining the airtightness (the nozzle 28 is (Opening / closing direction).
[0032]
At one end of the poppet 23, a concave fitting portion 33 for fitting the valve body 22 is formed, and as shown in FIGS. An engagement hole 34 for inserting and locking the hole is formed, and a spline portion 35 having an uneven shape is formed on the inner peripheral surface of the fitting portion 33. The inner diameter of the convex portion of the spline portion 35 is formed to be substantially the same as the outer diameter of the valve element 22. The concave portion of the spline portion 35 and the outside of the locking hole 34, that is, the portion of the groove portion 36a are formed as a relief portion A which allows the valve body 22 pressed against the nozzle 28 to elastically escape.
[0033]
In the vicinity of one end of the poppet 23, a groove 36a communicating with the inner space of the cylindrical portion 27 on the nozzle 28 side from the O-ring 32 is formed, and a hole communicating with the gas passage 17 from the groove 36a to the other end of the poppet 23. A communication path 37 is formed by the groove 36a and the hole 36b.
[0034]
On the outside of the poppet 23, a stopper portion 38 is formed which abuts on the cylindrical portion 27 at a position where the valve body 22 bites into the nozzle 28 by a predetermined amount to restrict the movement of the poppet 23 in the valve closing direction. A flange portion 39 is formed to project from the other end side of the stopper portion 38.
[0035]
The spring 24 is arranged in a compressed state around the cylindrical portion 27 of the nozzle body 21 and between the primary case 13 and the flange portion 39 of the poppet 23, and is configured to push the poppet 23 in the valve opening direction. I have.
[0036]
The diaphragm 25 is made of, for example, rubber, and has a peripheral portion hermetically sandwiched and fixed between the main body case 12 and the primary side case 13, and a central portion hermetically and integrally formed with the poppet 23 by the washer 40 and the lock nut 41. Installed. One side surface 25a of the diaphragm 25 is communicated with the atmosphere through a vent hole 43 formed in the primary case 13, and the other side surface 25b is communicated with the gas passage 17, and the primary outlet pressure in the gas passage 17 is Is configured to directly act on the poppet 23 in the valve closing direction.
[0037]
Note that a cover 44 is attached so as to cover the outer periphery of the primary case 13.
[0038]
Further, the secondary-side decompression means 19 has a nozzle body 51, which is formed in a cylindrical shape and hermetically inserted into the gas flow path 17 via an O-ring 52 mounted on the outer periphery thereof. It is arranged, and in this state, it is held by a holding body 53 fixedly attached to the main body case 12. A nozzle 54 is formed on the other end surface of the nozzle body 51 facing the gas outlet 16, and a nozzle hole 55 is formed at the center of the nozzle 54 to connect the gas flow path 17 and the gas outlet 16.
[0039]
On the holding body 53, a valve seat body 57 to which a valve body 56 is attached is provided so as to be movable in an opening and closing direction in which the valve 54 opens and closes the nozzle 54. As the valve body 56, the same one as the primary side valve body 22 is used. The valve seat 57 has a fitting part 58 for fitting the valve body 56, and the fitting part 58 is formed similarly to the fitting part 33 of the poppet 23, and has a spline part (not shown). An engagement groove 59 that opens upward is formed in the valve seat body 57.
[0040]
A lever 60 is rotatably supported on the holding body 53 by a pin 61, and one end of the lever 60 is inserted into and engaged with an engagement groove 59 of the valve seat body 57. Then, the swing of the lever 60 causes the valve seat body 57 to move in the opening and closing direction for opening and closing the nozzle 54 with the valve body 56.
[0041]
A peripheral edge of a diaphragm 62 is airtightly clamped and fixed between the main body case 12 and the secondary case 14, a pressure receiving plate 63 is disposed on an upper surface of the diaphragm 62, and a central portion of the diaphragm 62 and the pressure receiving plate 63 The suspension member 64 is inserted from above, a spring 65 is mounted around the suspension member 64, and a spring receiver 66 is attached to the upper end of the suspension member 64.
[0042]
A flange 67 is formed on the suspension member 64 so as to contact the lower surface of the diaphragm 62, and the diaphragm 62 pressed by a spring 65 is pressed against the flange 67 to maintain airtightness. At the lower end of the suspension member 64, a connection hole 68 to which the other end of the lever 60 is connected is formed.
[0043]
A pressure adjuster 69 is screwed into the upper inside of the secondary case 14, and a spring 70 is disposed between the pressure adjuster 69 and the pressure receiving plate 63. The pressure adjuster 69 is vertically moved with respect to the secondary case 14 by a rotation operation from the outside, and the force for pushing the diaphragm 62 downward by the spring 70 is adjusted. A cap 71 is detachably attached to the upper part of the secondary case 14.
[0044]
A union 82 for connecting a connection pipe 81 connected to a gas pipe is screwed to the gas outlet 16. 2 and 3, the connection pipe 81 and the union 82 are omitted.
[0045]
Next, the operation of the present embodiment will be described.
[0046]
In a state where the tank 2 is filled with a gas of a predetermined amount or more and the gas is guided from the tank 2 to the house 3 through the valve 5 and the gas pressure reducing regulator 6, and the gas equipment of the house 3 is not used. The primary-side pressure reducing means 18 and the secondary-side pressure reducing means 19 maintain the primary-side outlet pressure in the gas flow path 17 and the secondary-side outlet pressure on the gas outlet 16 side at predetermined pressures, respectively.
[0047]
In this state, the diaphragm 25 of the primary-side pressure reducing means 18 responds to the valve closing direction against the pressing force of the spring 24 by the action of the primary-side outlet pressure, and the poppet 23 and the valve body 22 move integrally with the diaphragm 25. Then, the valve body 22 is pressed against the nozzle 28 to close the nozzle 28. Also, the diaphragm 62 of the secondary side pressure reducing means 19 responds upwardly corresponding to the valve closing direction against the pressing force of the spring 70 by the action of the secondary side outlet pressure, and the valve seat is integrated via the lever 60. The body 57 and the valve body 56 move, and the valve body 56 is pressed against the nozzle 54 to close the nozzle 54.
[0048]
When the gas equipment of the house 3 is used, the secondary outlet pressure of the secondary side depressurizing means 19 decreases, and the pushing force of the spring 70 exceeds the secondary outlet pressure for operating the diaphragm 62. 62 responds downward corresponding to the valve opening direction, the valve seat 57 and the valve 56 move integrally via the lever 60, and the valve 56 separates from the nozzle 54 to open the nozzle 54. As a result, gas in the gas flow path 17 having a higher pressure than the secondary outlet pressure flows to the gas outlet 16 through the nozzle 54.
[0049]
The primary outlet pressure of the primary pressure reducing means 18 is reduced, and the pressing force of the spring 24 exceeds the primary outlet pressure that causes the diaphragm 25 to respond, the diaphragm 25 moves in the valve opening direction, and the poppet is integrally formed with the diaphragm 25. 23 and the valve body 22 move, the valve body 22 separates from the nozzle 54, and the nozzle 54 opens. As a result, gas on the gas inlet 15 side having a pressure higher than the primary-side outlet pressure is supplied to the gas passage 17 through the nozzle hole 29 of the nozzle 28, the inside of the cylindrical portion 27 of the nozzle body 21, and the communication passage 37 of the poppet 23. Flows.
[0050]
Further, when the use of the gas equipment in the house 3 is stopped, the secondary outlet pressure of the secondary pressure reducing means 19 increases, and the diaphragm 62 resists the pressing force of the spring 70 due to the secondary outlet pressure. In response to the upward direction corresponding to the valve closing direction, the valve seat 57 and the valve 56 move integrally via the lever 60, and the valve 56 is pressed against the nozzle 54 to close the nozzle 54. As a result, the secondary outlet pressure of the secondary pressure reducing means 19 is maintained at a predetermined pressure.
[0051]
When the nozzle 54 of the secondary-side pressure reducing means 19 is closed, the primary-side outlet pressure of the primary-side pressure reducing means 18 increases, and the primary-side outlet pressure causes the diaphragm 25 to close in the valve closing direction against the pressing force of the spring 24. , The poppet 23 and the valve body 22 move integrally with the diaphragm 25, and the valve body 22 is pressed against the nozzle 54 to close the nozzle 54. Thereby, the primary-side outlet pressure of the primary-side pressure reducing means 18 is maintained at a predetermined pressure.
[0052]
By the way, when foreign matter such as sand particles or dust enters the pipe or the tank 2 at the time of construction or when filling the tank 2 with gas, the foreign matter moves along with the flow of the gas and the gas of the gas decompression regulator 6 is removed. When it reaches the inflow port 15, it is captured by the filter 30, but some of the foreign matter passes through the filter 30, and the foreign matter that has passed through the nozzle 30 and the valve element 22 during the closing process of the primary-side decompression means 18. May bite between.
[0053]
As described above, when foreign matter is caught between the nozzle 28 and the valve body 22, the closing performance decreases, gas leaks through a gap around the foreign matter, and the primary outlet pressure increases. The higher the height, the more strongly the valve body 22 is pressed against the nozzle 28 via the diaphragm 25, so that foreign matter is strongly pushed into the valve body 22 and the portion of the valve body 22 around which the foreign matter has been pushed becomes the nozzle. The nozzle 28 comes into contact with the nozzle 28 to improve the closing performance, so that the nozzle 28 can be reliably closed. Therefore, the primary-side outlet pressure is maintained at a predetermined pressure, and the secondary-side outlet pressure is also maintained at a predetermined pressure by maintaining the primary-side outlet pressure at a predetermined pressure. Then, the security device that monitors the secondary outlet pressure of the gas pressure reducing regulator 6 detects that the gas pressure reducing regulator 6 is normal when the secondary outlet pressure is at a predetermined pressure.
[0054]
Further, the original shape of the valve body 22 when the valve body 22 is in the open state close to the closing state of the valve body 22 shown in FIG. 4A and the valve body 22 is in the open state shown in FIG. 4B is shown in FIG. As described above, in the closed state of the valve body 22, the nozzle 28 elastically bites into the valve body 22 and the periphery of the valve body 22 elastically escapes into the concave portion of the spline portion 35 so as to escape from the nozzle 28. At the same time, the locking claw 31 of the valve element 22 elastically escapes into the groove 36a outside the locking hole 34. That is, the fitting portion 33 of the poppet 23 into which the valve body 22 is fitted has the valve body 22 pressed against the nozzle 28 at the concave portion of the spline portion 35 and the outside of the locking hole 34, that is, the groove portion 36a. Since the escape portion A is formed to allow the valve body 22 to escape to the nozzle 28, when the valve body 22 is strongly pressed against the nozzle 28 via the diaphragm 25, a part of the valve body 22 elastically escapes into the concave portion of the spline portion 35, When the body 22 is opened, when the valve body 22 returns to its original shape due to the repulsive force of the elastically escaping portion of the valve body 22, foreign matter that has digged into the valve body 22 can be ejected, and the valve body 22 Can revive the surface. Therefore, it is possible to reduce the possibility that foreign matter is embedded in the valve body 22, and to stably maintain the closing performance for a long period of time.
[0055]
Further, at the end of the life of the valve body 22, foreign matters are buried in the surface of the valve body 22 in a circular shape corresponding to the contact shape with the nozzle 28, and the closing performance is reduced. In this state, the valve body 22 is pressed more strongly against the nozzle 28, but the pressing is regulated by the stopper portion 38 of the poppet 23 coming into contact with the cylindrical portion 27 of the nozzle body 21, and the primary outlet pressure is reduced. And the secondary outlet pressure also increases. When the secondary outlet pressure rises to a predetermined abnormal pressure, the safety device that monitors the secondary outlet pressure of the gas depressurizing regulator 6 detects a failure of the gas depressurizing regulator 6 and an abnormality such as a service life. To inform.
[0056]
As described above, in the two-stage decompression type, the primary side decompression means 18 is provided integrally with the valve body 22 for opening and closing the nozzle 28 and the diaphragm 25, and the gas on the gas flow path 17 side is provided through the diaphragm 25. Adopts a structure in which the primary outlet pressure directly acts to push the poppet 23 toward the closing direction of the valve body 22, so that even if foreign matter is caught between the nozzle 28 and the valve body 22, the primary outlet pressure is The higher the pressure, the more strongly the valve body 22 is pressed against the nozzle 28 via the diaphragm 25, and the nozzle 28 can be securely closed by the valve body 22, so that foreign matter can be caught in the valve body 22 of the primary side pressure reducing means 18. To be able to maintain the closing performance stably for a long time against intrusion, stabilize the secondary outlet pressure, and accurately predict the service life by monitoring the secondary outlet pressure with security equipment. Can be.
[0057]
Furthermore, since the nozzle 28, the valve body 22, the poppet 23, the spring 24, and the diaphragm 25 of the primary-side depressurizing means 18 are arranged coaxially with respect to the gas inlet 15 of the regulator main body 11, the primary-side depressurizing means 18 is The size of the regulator body 11 incorporating the primary pressure reducing means 18 can be reduced while the size can be reduced.
[0058]
Further, in the above-described embodiment, the example in which the two-stage decompression type gas decompression regulator 6 is adopted in the bulk type gas supply system is shown, but as shown in another embodiment of FIG. Or one cylinder 91 is connected to the gas inlet 15 side of the gas decompression regulator 6, and the gas outlet 16 side of the gas decompression regulator 6 is connected to the gas meter 7 via the cock 92. The same operation and effect can be obtained even when the present invention is applied to an example of a gas supply method which is often used in the above.
[0059]
Further, as shown in another embodiment of FIG.Side andThe secondary side may be separated from the gas pressure regulator 6a on the primary side near the cylinder 91, and the gas pressure regulator 6b on the secondary side may be arranged near the gas meter 7.
[0060]
FIG. 9 shows a primary-side gas decompression regulator 6a, which has the same structure as the primary-side decompression means 18 of the above-described embodiment, except that a peripheral part of the diaphragm 25 is provided between the regulator main body 11 and the primary case 13. There is provided a case 101 for keeping the airtight, and in this case 101, a gas outlet 102 is formed. The gas inlet 15, the nozzle 28, the valve body 22, the poppet 23, the spring 24, the diaphragm 25, and the gas outlet 102 are coaxially arranged.
[0061]
FIG. 10 shows a secondary-side gas decompression regulator 6b, which has the same structure as the secondary-side decompression means 19 of the above-described embodiment, but has a hermetic airtightness on the side of the gas passage 17 of the main body case 12 as the regulator main body 11. A gas inlet 112 is formed in the case 111.
[0062]
The primary-side gas pressure-reducing regulator 6a and the secondary-side gas pressure-reducing regulator 6b have the same functions and effects as those of the integrated gas pressure-reducing regulator 6 of the above embodiment.
[0063]
Note that, in the bulk system, the primary-side gas pressure reducing regulator 6a can be disposed near the tank 2 and the secondary-side gas pressure reducing regulator 6b can be disposed near the gas meter 7, which is the gas supply destination.
[0064]
Further, the gas pressure reducing regulator 6a can be used alone for a single-stage pressure reducing type without being used in combination with the gas pressure reducing regulator 6b on the secondary side.
[0065]
【The invention's effect】
According to the gas pressure reducing regulator of the first aspect, the valve support that supports the valve element that opens and closes the nozzle and the diaphragm are integrally provided, and the pressure of the gas on the gas outlet side with respect to the diaphragm supports the valve. The structure that directly acts to push the body in the closing direction of the valve body is adopted, so that even if foreign matter is caught between the nozzle and the valve body, the higher the pressure on the gas outlet side, the larger the diaphragm The valve body is pressed strongly against the nozzle via the valve body, and the nozzle can be reliably closed by the valve body. Therefore, it is possible to stably maintain the closing performance for a long period of time when foreign matter is caught in the valve body, and the gas flow The outlet pressure on the outlet side can be stabilized, and the life can be accurately predicted by monitoring the outlet pressure with security equipment, for example.In addition, at the end of the life of the valve element, the closing performance of the valve element is deteriorated, and the valve element is pressed more strongly against the nozzle. The stopper portion regulates the movement of the valve support in the closing direction at the position where the fixed amount bites, so that the outlet pressure can be increased, and for example, the life can be accurately detected by monitoring the outlet pressure with a security device.
[0066]
According to the gas pressure regulator of the second aspect, in addition to the effect of the gas pressure regulator of the first aspect, the gas inlet, the nozzle, the valve body, the valve support, the spring, the diaphragm, and the gas outlet are coaxial. Since it is arranged above, it can be made compact.
[0067]
According to the gas pressure reducing regulator of the third aspect, a two-stage pressure reducing type, the primary side pressure reducing means of which is integrally provided with a valve support which supports a valve element for opening and closing a nozzle, and a diaphragm, is provided on the diaphragm. On the other hand, since the primary outlet pressure of the gas on the gas flow path side directly acts so as to push the valve support toward the closing direction of the valve body, even if foreign matter is caught between the nozzle and the valve body, The higher the outlet pressure on the primary side, the more strongly the valve body is pressed against the nozzle via the diaphragm, and the nozzle can be reliably closed by the valve body, thus preventing foreign matter from being caught in the valve body of the primary pressure reducing means. On the other hand, it is possible to stably maintain the closing performance for a long time, stabilize the secondary outlet pressure, and accurately predict the life by monitoring the secondary outlet pressure with security equipment, for example. CanIn addition, at the end of the life of the valve element, the closing performance of the valve element is deteriorated, and the valve element is pressed more strongly against the nozzle. The stopper portion regulates the movement of the valve support in the closing direction at the position where the fixed amount bites, so that the outlet pressure can be increased, and for example, the life can be accurately detected by monitoring the outlet pressure with a security device.
[0068]
According to the gas pressure reducing regulator according to the fourth aspect, in addition to the effect of the gas pressure reducing regulator according to the third aspect, the nozzle, the valve element, the valve support, the spring and the diaphragm of the primary side pressure reducing means are connected to the regulator body. Because it is arranged coaxially with respect to the gas inlet, the size of the primary pressure reducing means can be reduced, and the size of the regulator body incorporating the primary pressure reducing means can be reduced..
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a gas pressure reducing regulator showing an embodiment of the present invention.
FIG. 2 is a plan view of the gas pressure reducing regulator.
FIG. 3 is a front view of the gas pressure regulator according to the first embodiment;
4A and 4B show an open state of the valve element, wherein FIG. 4A is a side view of the valve element and a fitting portion, and FIGS. 4B and 4C are cross-sectional views of the valve element.
5A and 5B show a closed state of the valve element, wherein FIG. 5A is a side view of the valve element and a fitting portion, and FIG. 5B is a sectional view of the valve element.
FIG. 6 is an explanatory diagram of a usage state of the gas pressure reducing regulator.
FIG. 7 is an explanatory view of a use state of a gas pressure reducing regulator according to another embodiment of the present invention.
FIG. 8 is an explanatory view of a use state of a gas pressure reducing regulator showing still another embodiment of the present invention.
FIG. 9 is a cross-sectional view of the primary-side gas pressure reducing regulator.
FIG. 10 is a cross-sectional view of the secondary-side gas pressure reducing regulator.
FIG. 11 is a sectional view of a conventional gas decompression regulator.
[Explanation of symbols]
6 Gas decompression regulator
11 Regulator body
15 Gas inlet
16 Gas outlet
17 Gas flow path
18 Primary pressure reducing means
19 Secondary pressure reducing means
22 valve
23 Poppet as valve support
24 spring
25 Diaphragm
28 NozLe
37 connecting passage
38    Stopper section
102 Gas spillmouth

Claims (4)

A regulator body having a gas inlet and a gas outlet,
A nozzle provided between a gas inlet and a gas outlet of the regulator body,
This valve supports a valve body that can close the nozzle, and is provided so as to be movable in a direction in which the nozzle is opened and closed by the valve body, and a communication path that communicates the nozzle side and the gas outlet side by opening the valve body is provided. A valve support,
A spring that pushes the valve support toward the opening direction of the valve,
The valve support is provided integrally, one side is communicated with the atmosphere and the other side is communicated with the gas outlet, and the gas pressure on the gas outlet side causes the valve support to move the valve support in the closing direction of the valve. and the diaphragm, which acts directly to press toward,
A gas stopper comprising a stopper for restricting movement of the valve support in the closing direction at a position where the valve bites into the nozzle by a predetermined amount corresponding to the end of the life of the valve. Decompression regulator. 2. The gas pressure regulator according to claim 1, wherein the gas inlet, the nozzle, the valve body, the valve support, the spring, the diaphragm, and the gas outlet are coaxially arranged. A regulator body having a gas inlet and a gas outlet, and having a gas flow path communicating with the gas inlet and the gas outlet,
Primary pressure reducing means for reducing the gas pressure flowing into the gas flow path from the gas inlet to a predetermined primary side outlet pressure or less,
Secondary pressure reducing means for reducing the gas pressure flowing out from the gas flow path to the gas outlet to a predetermined secondary outlet pressure lower than the primary outlet pressure,
The primary side decompression means,
A nozzle provided between the gas inlet and the gas flow path,
This valve supports a valve element capable of closing the nozzle, and is provided so as to be movable in a direction in which the nozzle is opened and closed by the valve element. A valve support;
A spring that pushes the valve support toward the opening direction of the valve,
The valve support is integrally provided, one side is communicated with the atmosphere and the other side is communicated with the gas flow path, and the primary outlet pressure of the gas on the gas flow path closes the valve support to the valve body. A diaphragm that acts directly to push in the direction ,
A gas pressure regulator comprising a stopper for restricting movement of the valve support in the closing direction at a position where the valve bites into the nozzle by a predetermined amount corresponding to the end of the life of the valve element . 4. A gas pressure regulator according to claim 3, wherein the nozzle, valve body, valve support, spring and diaphragm of the primary pressure reducing means are arranged coaxially with respect to the gas inlet of the regulator body. .

Images