JP2017083981A - Self-operated adjustment valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly accurate self-operated adjustment valve eliminating deterioration of secondary side pressure without increasing the size of the valve.SOLUTION: Since auxiliary pressure according to secondary side pressure can be supplied from an auxiliary pressure supply part 3 to a spring chamber 40 of spring protective parts 35, 150, a valve body 15 is separated from a valve seat 14 by increment of the auxiliary pressure through a diaphragm 30 thereby to enlarge valve opening. Consequently, deterioration of secondary side pressure at the time when fluid flows from a primary side flow passage 12a to a secondary side flow passage 12b in a valve body 2 is eliminated, and a highly accurate self-operated adjustment valve can be attained without increasing the size thereof.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a self-regulating valve, and more particularly to a direct-acting pressure reducing valve or back pressure valve with a simple structure, and a pilot operated pressure reducing valve or back pressure valve that operates a main valve using a pilot valve. is there.

Conventional pressure reducing valves or back pressure valves, which are self-adjusting valves, operate simply by installing them between pipes and do not require external power such as electricity or air pressure. It is used as a valve (for example, refer to Patent Document 1).
However, compared to other force control valves that operate using external power such as electricity or air pressure, self-control valves have the disadvantage of being significantly inferior in control accuracy. It is used exclusively.

Here, the control accuracy will be described by taking the pressure reducing valve of the self-adjusting valve as an example.
The pressure reducing valve is configured to detect the secondary side pressure of the secondary side flow path and to keep the secondary side pressure constant at a preset pressure.
In the pressure reducing valve, when the flow rate from the primary flow path to the secondary flow path is changed from a small flow rate to a rated high flow rate, the secondary pressure in the secondary flow path decreases as shown in FIG. Therefore, the opening of the main valve of the pressure reducing valve is automatically increased to prevent a decrease in the secondary pressure.

  However, the drop in the secondary pressure cannot be completely reduced to zero, and a certain pressure drop (for example, a pressure drop of about 10% at the rated flow rate) occurs. This pressure drop is called an offset (adjustment error or control deviation). It is ideal that the offset is as close to 0 as possible because the pressure reducing valve has high control accuracy and high performance.

  Further, when the fluid flowing from the primary flow path to the secondary flow path in the pressure reducing valve is changed from a small flow rate to a large flow rate, the valve opening of the main valve changes from small to large as shown in FIG. However, when the process is viewed microscopically, the vibration of the main valve is attenuated and eventually converges to a certain valve opening that is stopped.

  Self-powered pressure reducing valves operate purely mechanically without using external power such as electricity or air pressure. The time required for the transient response until the valve opening of the main valve stabilizes depends on various conditions. However, with a small-diameter main valve, it is a very short time of about 0.1 to 1.0 seconds.

Therefore, if the offset can be made as small as possible, the self-reducing pressure reducing valve can have high performance. Here, the offset of the secondary side pressure includes the pressure receiving area A of the diaphragm that detects the secondary side pressure, the spring constant K of the adjustment spring that biases the valve opening of the main valve, and the valve of the main valve. It is expressed by the following (Equation 1) using the movement amount L that determines the opening degree.
Offset = (K × L) / A ………………………………………………………… (Formula 1)

Japanese Patent Application Laid-Open No. 2007-51730.

By the way, in order to obtain high control accuracy by reducing the offset of the secondary pressure in the pressure reducing valve of such a self-adjusting type adjusting valve, if the direct acting type is used, the pressure receiving area A of the diaphragm is increased, and the spring constant of the adjusting spring It is necessary to reduce K.
Moreover, if it is a pilot operation type, there exists a method of making a pilot valve highly accurate, for example. However, both the direct acting type and the pilot acting type have drawbacks such as an increase in the size of the main valve.

  Since the self-reducing pressure reducing valve is an automatic control device that performs feedback control, if the control accuracy is made higher than necessary (higher gain or gain), it will be more sensitive to changes in the secondary pressure of the detection target. Thus, as shown in FIG. 11, the main valve vibrates (oscillates) and the operation becomes unstable, so that there is a problem that the offset cannot be made extremely small.

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a high-precision self-regulating valve that eliminates a decrease in secondary pressure without increasing the size.

  In order to achieve this object, the present invention is disposed opposite to the valve seat (14) provided between the primary flow path (12a) and the secondary flow path (12b) of the valve box (11). By driving the diaphragm (30) in which the valve body (15) is integrated through the valve rod (17) with the secondary side pressure of the secondary side channel (12b), the primary side channel (12a ) And the diaphragm (30) for urging the valve body (15) away from the valve seat (14). And an adjustment spring (34, 152) integrated with the above-mentioned diaphragm (30), and a spring protection part that houses the adjustment spring (34, 152) in the spring chamber (40) of its internal space (35, 150) and the spring chamber (4 of the spring protection part (35, 150)) ), An auxiliary pressure corresponding to the secondary pressure is generated using an auxiliary pressure fluid supplied from the upstream fluid passage including the primary flow path (12a) via the pressure reducing valve (6). And an auxiliary pressure supply unit (3, 130) to be supplied.

  In the present invention, the auxiliary pressure supply unit (3, 130) includes a pressure detection path (74) communicating with the secondary flow path (12b) for detecting the secondary pressure, and the auxiliary pressure. A supply path (65) for supplying an auxiliary pressure fluid for generation, a discharge path (68) for discharging the auxiliary pressure fluid supplied to the supply path (65), and the supply path (65) An output path (66) for outputting the auxiliary pressure fluid from the spring protection section (35) to the spring chamber (40), the supply path (65), the output path (66), and the discharge path ( 68) and a valve portion (72a) for opening and closing a through hole (69) communicating with the valve portion (72), and the valve portion (72a) for detecting the secondary side pressure via the pressure detection path (74). An integrated pressure detection diaphragm (76) and the pressure sensor And an adjustment spring (85) which is integrated with the diaphragm (76) and urges the valve portion (72a) to close the through hole (69), and is provided via the pressure detection diaphragm (76). The degree of opening of the valve portion (72a) with respect to the through hole (69) is changed according to the detected secondary side pressure, and the auxiliary pressure by the auxiliary pressure fluid corresponding to the change is changed to the spring protection portion. (35) is supplied to the spring chamber (40).

  In the present invention, a throttle (67) for generating the auxiliary pressure is provided between the supply path (65) and the output path (66).

  In the present invention, a throttle valve (7) for generating the auxiliary pressure is provided outside the supply passage (65).

  In the present invention, the auxiliary pressure supply unit (3, 130) is separately installed outside the spring protection unit (35, 150).

  In the present invention, the auxiliary pressure supply part (3, 130) is integrally installed on the upper part of the spring protection part (35, 150).

  According to the present invention, the auxiliary pressure corresponding to the secondary pressure can be supplied from the auxiliary pressure supply unit (3) to the spring chamber (40) of the spring protection unit (35, 150). The valve opening (15) can be increased by separating the valve element (15) from the valve seat (14) via the diaphragm (30) by an increase, and thus the primary flow path (12a) in the valve body (2). Therefore, it is possible to realize a highly accurate self-regulating valve that does not increase in size and eliminates the decrease in the secondary pressure when the fluid flows from the secondary to the secondary flow path (12b). Further, in this case, the valve body (15) can be brought closer to the valve seat (14) through the diaphragm (30) by the amount corresponding to the decrease in the auxiliary pressure.

  According to the present invention, the auxiliary pressure supply unit (3) has the valve part (72a) for the through hole (69) communicating between the supply path (65) and the output path (66) and the discharge path (68). Since the opening degree is changed according to the secondary pressure detected through the pressure detection diaphragm (76), the auxiliary pressure corresponding to the change is applied to the spring chamber (40) of the spring protection part (35, 150). Can be supplied.

  According to the present invention, since the throttle (67) for generating the auxiliary pressure is provided between the supply path (65) and the output path (66), the pressure of the supply path (65) is reduced (67). ) Can be supplied to the spring chamber (40) of the spring protection part (35) as the auxiliary pressure further reduced via Thereby, the pressure increase of the spring chamber (40) can be gradually changed with time by the auxiliary pressure, so that the valve body (15) can be gradually separated from the valve seat (14).

According to the present invention, since the throttle valve (7) for generating the auxiliary pressure is provided outside the supply passage (65), the pressure to the supply passage (65) is reduced via the throttle (67). As a further reduced auxiliary pressure, it can be supplied to the spring chamber (40) of the spring protection part (35, 150).
Thereby, the pressure increase of the spring chamber (40) can be gradually changed with time by the auxiliary pressure, so that the valve body (15) can be gradually separated from the valve seat (14).

  According to the present invention, since the auxiliary pressure supply part (3, 130) is separately installed outside the spring protection part (35, 150), it can be externally attached to the main body part (2) later. It becomes possible.

  According to the present invention, since the auxiliary pressure supply part (3, 130) is integrally installed on the upper part of the spring protection part (35, 150), the overall size can be reduced.

It is sectional drawing which shows the whole structure of the direct-acting pilot controller isolation | separation installation type pressure reducing valve in 1st Embodiment. It is sectional drawing which shows the structure of the pressure-reduction valve main body of the pilot controller separation installation type pressure-reduction valve in 1st Embodiment. It is sectional drawing which shows the structure of the pilot controller of the pilot controller separation installation type pressure reducing valve in 1st Embodiment. It is a graph which shows the time change of the valve opening degree in 1st Embodiment. It is a graph which shows a state without a pressure fall with respect to the increase in the flow volume in 1st Embodiment. It is sectional drawing which shows the whole structure of the direct-acting pilot controller integrated installation pressure reducing valve in 2nd Embodiment. It is sectional drawing which shows the whole structure of the pilot actuated pilot controller separation installation type pressure reducing valve in 3rd Embodiment. It is sectional drawing which expands and shows a part of pilot controller which has a throttle valve for producing | generating an auxiliary pressure. It is a graph which shows the state with a pressure drop with respect to the increase in the conventional flow volume. It is a graph which shows the time change of the conventional valve opening degree. It is a graph which shows the state which the conventional self-powered type adjustment valve oscillates.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<First Embodiment>
<Overall configuration of pilot controller separation installation type pressure reducing valve>
As shown in FIG. 1, the pilot controller separation installation type pressure reducing valve 1 (hereinafter simply referred to as “separation type pressure reducing valve”) as a self-regulating valve in the first embodiment includes an upstream pipe H1 and It is arrange | positioned between the downstream piping H2.

  The separation-type pressure reducing valve 1 includes a pressure reducing valve body 2 that allows a fluid supplied from the upstream side pipe H1 through the primary side flow path 12a to flow out from the secondary side flow path 12b to the downstream side pipe H2, and the pressure reducing valve body. 2 and a pilot controller 3 for supplying auxiliary pressure that is separately installed on the outer peripheral side surface.

<Configuration of pressure reducing valve body>
As shown in FIGS. 1 and 2, the pressure reducing valve main body 2 includes a valve box 11 connected between the upstream pipe H1 and the downstream pipe H2, and a spring fixed to the upper part of the valve box 11 in the arrow B direction. And a protective cylinder 35.
The valve box 11 has an upstream pipe H1 connected to a flange part 11a provided on the inlet side (upstream side) of the flow path 12, and a flange part provided on the outlet side (downstream side) of the flow path 12. A downstream pipe H2 is connected to 11b. For this reason, the fluid passage 4 in the upstream pipe H1 is connected to the primary flow path 12a of the valve box 11, and the fluid path 5 in the downstream pipe H2 is connected to the secondary flow path 12b of the valve box 11. Is done.

The primary side flow path 12 a and the secondary side flow path 12 b of the valve box 11 are separated by a partition wall 13 provided in the valve box 11, and a cylindrical shape is formed in a through hole formed in a central portion of the partition wall 13. A valve seat 14 having a shape is fixed.
An annular valve body 15 is provided at a position facing the valve seat 14, and the valve body 15 is fitted and fixed in a recess on the upper end surface of the annular valve body receiver 16. Therefore, the flow rate of the fluid flowing from the primary side flow path 12a to the secondary side flow path 12b is adjusted by narrowing or widening the gap between the valve seat 14 and the valve body 15.

A valve rod 17 that passes through the center of the valve seat 14 and protrudes in the vertical direction of the valve seat 14 is integrally fixed to the valve body receiver 16. In this case, the valve rod 17 is fixed in a state of being penetrated through the central through hole of the valve body receiver 16.
A lower end portion 17 b of the valve rod 17 projecting downward from the valve body receiver 16 is slidably supported in a guide hole 21 b of the valve rod guide portion 21 a in the lower lid 21 attached to the bottom portion of the valve box 11. .

A hexagonal nut 18 is attached to the lower end portion 17b of the valve stem 17 on the lower surface of the valve stem receiver 16 at a position facing the valve stem guide portion 21a. The support 16 is fixed at a position in the figure in the direction of arrow AB.
An annular recess 21c is formed on the bottom surface of the lower lid 21 around the valve rod guide 21a, and the lower end of the valve spring 19 is supported by the recess 21c. The upper end of the valve spring 19 is supported on the lower surface of the valve receiver 16 so as to surround the hexagon nut 18. In addition, the valve body spring 19 urges the valve body receiver 16 in the direction of arrow B that causes the valve body 15 to contact the valve seat 14.

A substantially cylindrical liner 22 is attached to the upper opening of the valve box 11. A valve rod 17 protruding above the valve body receiver 16 is supported in the through hole 22a below the liner 22 so as to be slidable in the arrow AB direction.
A balance piston 23 is slidably supported in the through hole 22 b above the liner 22. An O-ring 31 for sealing between the liner 22 and the balance piston 23 is attached to the inner peripheral portion of the through hole 22b.

The valve rod 17 and its upper end 17a are integrally fixed in a through hole provided in the balance piston 23. An annular stepped portion is formed on the outer peripheral end surface of the flange portion 23a on the flange portion 23a at the upper end portion of the balance piston 23, and a donut-shaped diaphragm 30 made of synthetic rubber, for example, is placed on the stepped portion. Yes.
A diaphragm receiver 24 is placed on the upper end surface of the diaphragm 30. The upper end 17a of the valve rod 17 is passed through the through hole 24a of the diaphragm receiver 24, and a hexagon nut 26 is screwed into the upper end 17a.

That is, in this case, the diaphragm 30 is tightened by the hexagon nut 26 while being sandwiched between the flange portion 23 a of the balance piston 23 and the diaphragm receiver 24. Thus, the diaphragm 30 is integrated with the valve body 15 via the valve rod 17.
The outer peripheral edge of the diaphragm 30 is placed on a step provided in the opening of the valve box 11. The outer peripheral edge of the opening of the valve box 11 is brought into contact with the outer peripheral edge of the spring protection cylinder 35 facing each other, and the outer peripheral edge of the valve box 11 and the outer peripheral edge of the spring protection cylinder 35 are integrally attached by a bolt 41. It is done.

The adjustment spring 34 has one end and a lower end with respect to the step 24b formed on the upper end surface of the diaphragm receiver 24 and the step 39b formed on the lower surface of the spring receiver 39 provided in the inner space of the spring protection cylinder 35. Supported.
A recess 39 a provided at the center of the upper end surface of the spring receiver 39 is fitted with a tip end portion 36 a of an adjustment screw 36 screwed into a female screw portion 35 b formed on the top portion 35 a of the spring protection cylinder 35.
The adjustment spring 34 biases the diaphragm receiver 24 and the diaphragm 30 in the direction of arrow A that separates the valve body 15 from the valve seat 14.

The adjustment screw 36 can be pushed into the spring protection cylinder 35 by the rotation of the head 36b. A hexagon nut 38 is attached to the adjustment screw 36, and is used to fix the adjustment screw 36 in a state of being pushed into the spring protection cylinder 35.
Therefore, the adjustment spring 34 can be compressed by moving the spring receiver 39 in the direction of arrow A through the tip 36a of the adjustment screw 36. Further, the adjustment spring 34 can be extended by moving the spring receiver 39 in the direction of arrow B through the tip 36a of the adjustment screw 36. Thereby, the valve opening degree by the valve body 15 and the valve seat 14 can be adjusted by the set pressure of the adjustment spring 34.

  A sealed spring chamber 40 is formed in the space inside the spring protection cylinder 35 and above the diaphragm 30. In the valve box 11, a diaphragm chamber 50 is formed below the diaphragm 30. A communication hole 32 communicating with each other is formed between the diaphragm chamber 50 of the valve box 11 and the secondary side flow path 12b.

  As a single operation in the pressure reducing valve body 2 having such a configuration, a state in which a faucet (not shown) on the secondary side flow path 12b side is closed, that is, the secondary pressure in the secondary side flow path 12b is set. When the height is high, an upward force acting on the diaphragm 30 in the direction of arrow B through the communication hole 32 and the diaphragm chamber 50 is large. For this reason, the valve body 15 is lifted upward together with the valve rod 17, and the valve body 15 and the valve seat 14 come into contact with each other to close the valve.

  After that, when the tap on the secondary flow path 12b side is opened and the secondary pressure in the secondary flow path 12b is reduced, the pressure reducing valve body 2 has the diaphragm 30 via the communication hole 32 and the diaphragm chamber 50. The upward force acting on the is reduced. For this reason, the valve element 15 is pushed downward together with the valve rod 17 by the biasing force of the adjustment spring 34, and the valve element 15 is separated from the valve seat 14 to open.

  Thus, the pressure-reducing valve body 2 has a valve opening force by the adjustment spring 34 downward through the diaphragm 30 and the valve body 15 through the diaphragm 30 due to the secondary side pressure of the secondary flow path 12b. The flow rate of the fluid flowing from the primary side flow path 12a to the secondary side flow path 12b by changing the position of the valve body 15 with respect to the valve seat 14 in the arrow AB direction due to the difference between the two force and the valve closing force upward Is controlled.

<Configuration of pilot controller>
As shown in FIGS. 1 and 3, the pilot controller 3 according to this embodiment includes an upstream sub-pipe H1a branched from the upstream pipe H1, and a downstream downstream sub-pipe H2a branched from the pipe H2. The pilot controller 3 is connected to an auxiliary pressure supply pipe H3 for generating and supplying an auxiliary pressure to the spring chamber 40 of the pressure reducing valve body 2.

The pilot controller 3 includes a main body portion 60 that has a substantially rectangular parallelepiped shape as a whole, and an upper lid portion 80 that closes an upper opening of the main body portion 60.
The main body portion 60 is configured by laminating a lower step portion 61, a middle step portion 62, and an upper step portion 63 from below in the direction of arrow A. In a state where the upper lid portion 80 is further laminated on the upper step portion 63 of the main body portion 60, the upper lid portion 80, the upper step portion 63, the middle step portion 62 and the lower step portion 61 are integrally fixed by the bolts 81. An O-ring 61 a is mounted between the middle step portion 62 and the lower step portion 61.

  A supply path 65 having a diameter W <b> 1 is formed in the middle step portion 62 placed on the lower step portion 61 of the main body portion 60 from the side surface in the arrow D direction toward the inward direction in the arrow C direction. An upstream side sub-pipe H1a is connected to the supply port 65a of the supply path 65. As shown in FIG. 1, the upstream side sub pipe H <b> 1 a is provided with a pressure reducing valve 6 in the middle, and the fluid passage in the upstream side pipe H <b> 1 and the supply path 65 communicate with each other via the pressure reducing valve 6. .

  The pressure reducing valve 6 reduces the pressure of the fluid in the upstream pipe H1 to a predetermined pressure. This predetermined pressure is a pressure at which an auxiliary pressure described later can be obtained. Hereinafter, the fluid that is decompressed by the decompression valve 6 and supplied to the pilot controller 3 is simply referred to as auxiliary pressure fluid. For this reason, in this embodiment, the auxiliary pressure fluid is supplied from the fluid passage 4 in the upstream pipe H1 to the pilot controller 3 via the pressure reducing valve 6.

Further, an output path 66 having a diameter W1 for supplying auxiliary pressure to the spring chamber 40 of the pressure reducing valve body 2 via the auxiliary pressure supply pipe H3 is provided in the middle stage 62 from the side face in the arrow C direction in the arrow D direction. It is formed inward. An auxiliary pressure supply pipe H3 is connected to the output port 66a of the output path 66.
A diaphragm 67 having a diameter W2 (W2 <W1) is formed between the supply path 65 and the output path 66 of the middle stage 62. An auxiliary chamber 70 is configured between the output port 66 a and the throttle 67.

  Further, a discharge path 68 is formed above the supply path 65 in the middle stage 62 from the side surface in the arrow D direction toward the inward direction in the arrow C direction. In this embodiment, a discharge pipe H4 is connected to the discharge port 68a of the discharge path 68. When the fluid flowing through the upstream pipe H1 is a liquid or a gas that cannot be released into the atmosphere, although not shown, a processing device that processes these fluids, a tank that stores these fluids, etc. Is connected to the discharge pipe H4.

When the fluid flowing through the upstream pipe H1 is a gas that can be discharged into the atmosphere, the discharge port 68a or the discharge pipe H4 is opened into the atmosphere.
A through hole 69 for discharging the auxiliary pressure fluid supplied from the upstream side sub-pipe H1a to the supply path 65 is formed above the auxiliary chamber 70 in the middle stage 62 in the arrow B direction. Therefore, the auxiliary chamber 70 and the discharge path 68 are communicated with each other through the through hole 69 of the middle step portion 62.

Further, a valve seat 64 slightly projecting in the direction of arrow B is formed on the peripheral edge of the upper opening of the through hole 69 formed in the middle step 62.
A lower diaphragm 71 is placed on the upper end surface of the middle stage 62, and a valve body 72 is passed through a central through hole of the lower diaphragm 71. The valve body 72 has a valve portion 72 a disposed to face the valve seat 64, and the valve portion 72 a is positioned below the lower diaphragm 71 in the direction of arrow A and is disposed in the discharge path 68.

  The shaft portion 72b of the valve body 72 is positioned above the lower diaphragm 71 in the direction of the arrow B, and a substantially cylindrical valve body receiver 73 is integrally fixed to the shaft portion 72b.

  An upper step portion 63 is placed on the upper end surface of the lower diaphragm 71, and a valve body receiver 73 is positioned in a diaphragm chamber 75 formed in the upper step portion 63. In addition, a secondary side pressure detection path 74 communicating with the secondary side flow path 12b of the pressure reducing valve main body 2 via the downstream side sub pipe H2a is provided in the upper stage portion 63 from the side face in the arrow D direction inwardly in the arrow C direction. It is formed toward. The downstream side sub pipe H2a is connected to the pressure detection port 74a of the secondary side pressure detection path 74.

  An upper diaphragm 76 is integrally fixed to the upper end surface of the upper stage portion 63. A diaphragm receiver 82 is integrally fixed to the upper diaphragm 76. The rear end portion of the shaft portion 72b of the valve body 72 in the direction of arrow B passes through the central through hole of the diaphragm receiver 82, and a hexagon nut 83 is screwed to the male screw portion at the rear end portion. . Thus, the valve body 72 is integrated with the lower diaphragm 71, the valve body receiver 73, the upper diaphragm 76, and the diaphragm receiver 82.

  In a state where the upper diaphragm 76 is sandwiched between the upper lid portion 80 and the upper step portion 63, the upper lid portion 80 is attached to the upper step portion 63. Therefore, since the upper diaphragm 76 and the lower diaphragm 71 are configured integrally with the valve body 72, the valve body 72 moves up and down in conjunction with the vertical movement of the upper diaphragm 76 and the lower diaphragm 71 in the arrow AB direction. Thereby, the valve opening degree of the valve part 72a of the valve body 72 and the valve seat 64 changes.

  A diaphragm receiver 82 is disposed in an inner space formed by the upper lid portion 80 and the upper diaphragm 76, a stepped portion 82 b formed around the convex portion 82 a on the upper end surface of the diaphragm receiver 82, and the diaphragm receiver 82 One end and the lower end of the adjustment spring 85 are supported with respect to the step portion 84b formed on the lower surface of the spring receiver 84 provided in the inner space of the upper lid portion 80 so as to face each other. The adjustment spring 85 urges the diaphragm receiver 82 and the upper diaphragm 76 in the direction of arrow A that presses the valve body 72 against the valve seat 64.

The recess 84 a provided at the center of the upper end surface of the spring receiver 84 is in contact with the tip end portion 86 a of the adjustment screw 86 screwed to the female screw portion 80 b formed on the top portion 80 a of the upper lid portion 80.
The adjustment screw 86 can be pushed into the internal space of the upper lid portion 80 by rotation of the head portion 86b. A hexagon nut 87 is attached to the adjustment screw 86 at the top 80 a of the upper lid 80. The hexagon nut 87 is used to fix the state in which the adjusting screw 86 is pushed into the upper lid portion 80.

  Therefore, the adjustment spring 85 can be compressed by moving the spring receiver 84 in the direction of arrow A via the tip 86a of the adjustment screw 86. Further, the adjustment spring 85 can be extended by moving the spring receiver 84 in the direction of arrow B through the tip 86a of the adjustment screw 85. Accordingly, the valve opening degree of the valve body 72 with respect to the through hole 69 of the valve portion 72 a can be adjusted by the set pressure of the adjustment spring 85.

A through-hole 80c is formed in the peripheral side surface of the upper lid portion 80, and when the spring receiver 84 moves in the direction of arrow A, the space inside the upper lid portion 80 is introduced from the outside via the through-hole 80c of the upper lid portion 80. Take in air.
On the other hand, when the spring receiver 84 moves in the arrow B direction, the air in the inner space of the upper lid 80 is exhausted from the through hole 80c. Accordingly, the spring receiver 84 is smoothly moved in the arrow AB direction.

  The single operation of the pilot controller 3 having such a configuration will be described below on the assumption that a fluid of a predetermined pressure is constantly supplied from the upstream side sub-pipe H1a to the supply path 65.

  When the faucet (not shown) on the secondary flow path 12b side is closed, that is, when the secondary pressure in the secondary flow path 12b is high, the pilot controller 3 is connected to the downstream side sub pipe H2a and the secondary sub pipe H2a. Since the upward force acting on the upper diaphragm 76 in the direction of arrow B via the side pressure detection path 74 is large, the valve body 72 is pushed upward together with the upper diaphragm 76 and the lower diaphragm 71, and the valve portion 72 a is moved to the valve seat 64. The valve opens away from the valve.

Here, a fluid having a predetermined pressure is supplied from the upstream side sub-pipe H1a to the supply passage 65. However, since the valve portion 72a is opened away from the valve seat 64, the auxiliary chamber 70 is connected via the restrictor 67. Most of the fluid supplied to the gas is discharged through the discharge path 68.
That is, the fluid supplied to the auxiliary chamber 70 through the throttle 67 is not supplied from the output path 66 to the spring chamber 40 of the pressure reducing valve body 2 via the auxiliary pressure supply pipe H3.

Thereafter, when the faucet (not shown) on the secondary channel 12b side is opened and the secondary pressure in the secondary channel 12b gradually decreases, the pilot controller 3 causes the downstream sub-pipe H2a and the secondary The upward force acting on the upper diaphragm 76 in the direction of arrow B via the side pressure detection path 74 is reduced.
Accordingly, the valve body 72 is pushed down in the direction of arrow A together with the upper diaphragm 76 and the lower diaphragm 71 by the biasing force of the adjustment spring 85, and the valve portion 72 a gradually approaches the valve seat 64.

  That is, the pilot controller 3 balances the force that lifts the upper diaphragm 76 due to the secondary side pressure of the pressure reducing valve body 2 in the direction of arrow B and the force that pushes the upper diaphragm 76 against the upper diaphragm 76 in the direction of arrow A against each other. ing. In this state, when the secondary pressure of the secondary flow path 12b in the pressure reducing valve body 2 increases or decreases, the opening degree of the valve portion 72a of the valve body 72 and the valve seat 64 changes.

  At this time, the pressure of the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 is larger than the pressure when the fluid is discharged from the discharge path 68. The pressure of the fluid flowing through the restrictor 67 and flowing into the auxiliary chamber 70 is smaller than the pressure of the fluid supplied from the upstream side sub-pipe H1a to the supply path 65, but when discharged from the discharge path 68. Greater than pressure. Therefore, the fluid in the auxiliary chamber 70 is supplied as an intermediate pressure from the output path 66 to the spring chamber 40 of the pressure reducing valve body 2 via the auxiliary pressure supply pipe H3.

  Thereafter, when the flow rate of the secondary side flow path 12b in the pressure reducing valve body 2 becomes maximum and the secondary side pressure becomes the lowest, the upper diaphragm 76 is connected via the downstream side sub pipe H2a and the secondary side pressure detection path 74. Since the acting upward force is the smallest, the valve body 72 is pushed down together with the upper diaphragm 76 and the lower diaphragm 71 by the biasing force of the adjusting spring 85, and the valve portion 72a and the valve seat 64 are brought into contact with each other. And close completely.

At this time, the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 is not discharged from the discharge path 68, so that the fluid that has passed through the throttle 67 and flowed into the auxiliary chamber 70 is supplied from the output path 66 to the auxiliary pressure supply pipe. It is supplied to the spring chamber 40 of the pressure reducing valve body 2 via H3.
Therefore, the intermediate pressure of the auxiliary chamber 70 supplied from the output path 66 to the spring chamber 40 of the pressure reducing valve body 2 via the auxiliary pressure supply pipe H3 is the pressure reducing valve body 2 with respect to the lower surface of the upper diaphragm 76 in the pilot controller 3. Decreases when the secondary side pressure increases, and increases when the secondary pressure of the pressure reducing valve body 2 with respect to the lower surface of the upper diaphragm 76 decreases.

  Thus, as the secondary pressure of the secondary flow path 12b in the pressure reducing valve body 2 gradually decreases, the pilot controller 3 reduces the gap between the valve portion 72a and the valve seat 64 and passes through the throttle 67. The intermediate pressure is gradually increased and supplied to the spring chamber 40 of the pressure reducing valve body 2 as an auxiliary pressure.

<Operation of pressure reducing valve>
The overall operation of the separated pressure reducing valve 1 having such a configuration will be described.
In the separation type pressure reducing valve 1, communication is performed when a faucet (not shown) on the side of the secondary side flow path 12 b is closed, that is, when the secondary side pressure of the secondary side flow path 12 b in the pressure reducing valve body 2 is high. The upward force acting on the diaphragm 30 via the hole 32 and the diaphragm chamber 50 is large, and the valve body 15 is lifted upward together with the valve rod 17, so that the valve body 15 and the valve seat 14 come into contact with each other to close the valve. .

At this time, since the upward force acting on the upper diaphragm 76 via the secondary side flow path 12b of the pressure reducing valve body 2, the downstream side sub pipe H2a, and the secondary side pressure detection path 74 of the pilot controller 3 is large, The valve body 72 is lifted upward together with the upper diaphragm 76 and the lower diaphragm 71, and the valve portion 72a of the valve body 72 is opened away from the valve seat 64.
In this case, most of the fluid supplied to the supply path 65 of the pilot controller 3 from the upstream side sub pipe H1a is discharged through the discharge path 68, and the fluid in the auxiliary chamber 70 is discharged from the output path 66 and the auxiliary pressure supply pipe. It is not supplied to the spring chamber 40 of the pressure reducing valve body 2 via H3. That is, at this time, there is no change from the conventional pressure reducing valve body 2 when the pilot controller 3 is not installed.

  Thereafter, when the faucet on the secondary flow path 12b side in the pressure reducing valve body 2 is opened to increase the flow rate of the fluid in the flow path, and the secondary pressure in the secondary flow path 12b decreases, the communication hole The upward force acting on the diaphragm 30 via the diaphragm 32 and the diaphragm chamber 50 is reduced. As a result, the valve body 15 is pushed down together with the valve rod 17 by the urging force of the adjustment spring 34, so that the valve body 15 separates from the valve seat 14 and opens.

Thereby, in the pressure-reducing valve body 2, fluid starts to flow from the primary side flow path 12a to the secondary side flow path 12b. That is, since the pressure-reducing valve body 2 operates mechanically in this way, when the faucet on the secondary side flow path 12b side is opened, the valve body 15 instantaneously performs a response operation.
At this time, the upward force acting on the upper diaphragm 76 via the secondary side flow path 12b of the pressure reducing valve body 2, the downstream side sub pipe H2a, and the secondary side pressure detection path 74 of the pilot controller 3 is gradually reduced. Therefore, in the pilot controller 3, the valve body 72 is pushed down together with the upper diaphragm 76 and the lower diaphragm 71 by the urging force of the adjustment spring 85, and the valve portion 72 a of the valve body 72 gradually approaches the valve seat 64. .

Then, the fluid that has flowed from the upstream side sub-pipe H1a to the auxiliary chamber 70 via the supply path 65 and the restriction 67 gradually decreases the amount discharged from the discharge path 68. To the spring chamber 40 of the pressure reducing valve body 2 through the auxiliary pressure supply pipe H3.
Here, since the valve diameter of the valve seat 64 built in the pilot controller 3 is very small, the pressure of the fluid supplied from the output path 66 to the spring chamber 40 of the pressure reducing valve body 2 is very small from the discharge path 68. Is precisely controlled by exhaust air.

That is, a predetermined time is required to change the pressure of the spring chamber 40 of the pressure reducing valve body 2 by the intermediate pressure fluid from the auxiliary chamber 70 of the pilot controller 3.
For this reason, the intermediate pressure of the fluid supplied from the auxiliary chamber 70 of the pilot controller 3 to the spring chamber 40 of the pressure reducing valve main body 2 gradually increases with time.

Thus, the intermediate pressure supplied to the spring chamber 40 of the pressure reducing valve body 2 is supplied to the spring chamber 40 while gradually increasing, so that the diaphragm 30 of the pressure reducing valve body 2 is gradually pushed downward by this intermediate pressure.
The valve body 15 is separated from the valve seat 14 by the amount that the diaphragm 30 of the pressure reducing valve body 2 is further pushed downward by the intermediate pressure of the fluid supplied from the pilot controller 3. As shown in FIG. The valve opening degree of the valve body 15 with respect to the valve seat 14 gradually increases as compared with FIG.

  As described above, the pilot controller 3 reduces the restriction 67 because the distance between the valve portion 72a and the valve seat 64 becomes narrower as the secondary pressure of the secondary flow path 12b in the pressure reducing valve body 2 becomes lower. The intermediate pressure of the fluid that has passed through is gradually increased and supplied to the spring chamber 40 of the pressure reducing valve body 2 as an auxiliary pressure.

Thereafter, when the flow rate of the secondary side flow path 12b in the pressure reducing valve body 2 becomes maximum and the secondary side pressure becomes the lowest, the downstream side sub pipe H2a and the secondary pressure detection path 74 of the pilot controller 3 are used. The upward force acting on the upper diaphragm 76 is the smallest.
Then, the valve body 72 is pushed down together with the upper diaphragm 76 and the lower diaphragm 71 by the biasing force of the adjustment spring 85, and the valve portion 72a of the valve body 72 and the valve seat 64 are brought into contact with each other, and the pilot controller 3 is closed. I speak.

At this time, the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 of the pilot controller 3 is not discharged from the discharge path 68, and the fluid that has passed through the throttle 67 and flows into the auxiliary chamber 70 is supplied from the output path 66 to the auxiliary pressure. It is supplied to the spring chamber 40 of the pressure reducing valve body 2 via the supply pipe H3.
When the valve portion 72a of the valve body 72 in the pilot controller 3 contacts the valve seat 64 and closes, the intermediate pressure of the fluid from the auxiliary chamber 70 becomes maximum, and the valve body 15 and the valve of the pressure reducing valve body 2 after that time The valve opening between the seats 14 is constant (FIG. 4).

Accordingly, the valve opening between the valve body 15 and the valve body 14 of the pressure reducing valve body 2 is made larger and constant than before due to the fluid (auxiliary pressure) supplied from the pilot controller 3 to the spring chamber 40 of the pressure reducing valve body 2. As shown in FIG. 5, it is possible to prevent the secondary side pressure of the secondary side flow path 12b from being lowered and to eliminate the offset.
Thereafter, when the secondary pressure in the secondary flow path 12b increases, the pilot controller 3 gradually opens, so that the fluid (auxiliary pressure) supplied from the pilot controller 3 to the spring chamber 40 of the pressure reducing valve body 2 is increased. ) Also decreases, the valve opening between the valve body 15 and the valve seat 14 of the pressure reducing valve body 2 is reduced, and the valve is eventually closed.

<Effect>
Thus, in the separation type pressure reducing valve 1, the valve opening between the valve body 15 and the valve seat 14 when the secondary side pressure of the secondary side flow path 12b of the pressure reducing valve body 2 is reduced is stabilized within several seconds. (FIG. 4).
During this time, even if the fluid from the auxiliary chamber 70 of the pilot controller 3 is supplied to the spring chamber 40 of the pressure reducing valve body 2, the valve opening between the valve body 15 and the valve seat 14 is not stable and an offset occurs. Because it is thought that it is, it is not highly accurate.

However, as the intermediate pressure of the fluid supplied from the pilot controller 3 to the spring chamber 40 of the pressure reducing valve body 2 increases with time, the valve opening between the valve body 15 and the valve seat 14 of the pressure reducing valve body 2 is increased. Can be gradually increased (FIG. 4).
Thus, in the separation type pressure reducing valve 1, after the valve opening between the valve body 15 and the valve seat 14 is stabilized, correction control can be performed so as to eliminate the offset while further increasing the valve opening.

  As a result, the separation type pressure reducing valve 1 prevents a decrease in the secondary side pressure of the secondary side flow path 12b in the pressure reducing valve body 2 while maintaining operational stability without causing vibration or the like in the valve body 15. It can be made accurate. Thus, the separation-type pressure reducing valve 1 can be controlled with high precision that is not compared with a conventional direct-acting pressure reducing valve without increasing its size.

  In the separation type pressure reducing valve 1, the pilot controller 3 is separated and installed outside the spring protection part 35, so that the pilot controller 3 can be externally installed on the pressure reducing valve body 2 later.

<Second Embodiment>
<Overall configuration of pilot controller integrated pressure reducing valve>
As shown in FIG. 6 in which parts corresponding to those in FIG. 1 are given the same reference numerals, a pilot controller integrated pressure reducing valve 100 (hereinafter referred to simply as “integrated pressure reducing valve” as a self-acting regulating valve in the second embodiment). Is arranged between the upstream pipe H1 and the downstream pipe H2.

  The integrated pressure reducing valve 100 includes a valve box 11, a spring protection cylinder 150 fixed to the upper part of the valve box 11 in the direction of arrow B, and an auxiliary pressure supply fixed integrally to the upper end surface of the spring protection cylinder 150. And a pilot controller 130. Here, since the valve box 11 and its internal structure are the same as those of the pressure reducing valve body 2 in the first embodiment, the description thereof is omitted here for convenience.

<Configuration of spring protection cylinder>
The spring protection cylinder 150 is integrally attached to the upper end portion of the valve box 11 with a bolt 41. The spring protection cylinder 150 has a through hole 151a at its upper end. The spring protection cylinder 150 is supported at one end and the other end of the adjustment spring 152 with respect to the lower surface 151b of the upper end portion and the step portion 24b of the diaphragm receiver 24.

  The spring protection cylinder 150 is not provided with the adjusting screw 36 (FIGS. 1 and 2) of the pressure reducing valve body 2 in the first embodiment, so that the lower surface 151b of the upper end portion of the spring protection cylinder 150 and the diaphragm receiver 24 are provided. The adjustment spring 152 supported by the step portion 24b is adjusted to a predetermined set pressure. The valve rod 17, the diaphragm receiver 24, and the hexagon nut 26 disposed inside the spring protection cylinder 150 are the same as those of the pressure reducing valve main body 2 in the first embodiment.

<Configuration of pilot controller>
The pilot controller 130 is configured to be integrally fixed to the upper end surface of the spring protection cylinder 150 in a state where the lower step portion 61 of the pilot controller 3 of the separation type pressure reducing valve 1 in the first embodiment is removed. . That is, the pilot controller 130 has the same basic configuration as the pilot controller 3 except that the lower stage portion 61 does not exist. Although not shown, the output path 66a of the pilot controller 3 is closed with a plug or the like.

In this case, instead of attaching the lower step portion 61 to the middle step portion 62, the middle step portion 62 is integrally fixed to the upper end surface of the spring protection cylinder 150, so that the auxiliary chamber 70 of the pilot controller 130 and the spring protection cylinder 150 are fixed. The spring chamber 40 communicates with the spring chamber 40 through a through hole 151 a of the spring protection cylinder 150.
The operation of the integrated pressure reducing valve 100 having such a configuration will be described. In the integrated pressure reducing valve 100, when the secondary side pressure of the secondary flow path 12b in the pressure reducing valve body 2 is high, the upward force acting on the diaphragm 30 via the communication hole 32 and the diaphragm chamber 50 is large. Since the valve body 15 is lifted upward together with the rod 17, the valve body 15 and the valve seat 14 are brought into contact with each other to close the valve.

  At this time, the force that is transmitted from the secondary side flow path 12b of the pressure reducing valve body 2 to the pilot controller 130 via the downstream side sub pipe H2a and acts upward on the upper diaphragm 76 from the secondary side pressure detection path 74. Since it is large, the valve body 72 is lifted upward together with the upper diaphragm 76 and the lower diaphragm 71, and the valve portion 72a of the valve body 72 is opened away from the valve seat 64.

In this case, most of the fluid supplied to the supply path 65 of the pilot controller 130 from the upstream side sub-pipe H1a is discharged through the discharge path 68, and passes from the auxiliary chamber 70 through the through hole 151a of the spring protection cylinder 150. Thus, no fluid is supplied to the spring chamber 40.
Thereafter, in the integrated pressure reducing valve 100, when the secondary pressure of the secondary flow path 12b decreases, the upward force acting on the diaphragm 30 via the communication hole 32 and the diaphragm chamber 50 decreases.

As a result, the valve body 15 is pushed down together with the valve rod 17 by the biasing force of the adjustment spring 152, so that the valve body 15 separates from the valve seat 14 and opens, and the secondary side flow path 12a opens. Fluid begins to flow to 12b.
At this time, the upward force transmitted from the secondary side flow path 12b to the pilot controller 130 via the downstream side sub pipe H2a and acting on the upper diaphragm 76 from the secondary side pressure detection path 74 is gradually reduced. The valve body 72 is pushed downward together with the upper diaphragm 76 and the lower diaphragm 71 by the urging force of the spring 85, and the valve portion 72 a of the valve body 72 gradually approaches the valve seat 64.

As a result, the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 passes through the restriction 67 and flows into the auxiliary chamber 70, and the fluid in the auxiliary chamber 70 serves as an intermediate pressure (FIG. 3), and the spring protection cylinder 150. Is supplied to the spring chamber 40 through the through hole 151a.
Therefore, as the intermediate pressure of the fluid from the auxiliary chamber 70 of the pilot controller 130 increases (with the passage of time), the pressure of the spring chamber 40 is gradually increased.
That is, since the intermediate pressure supplied to the spring chamber 40 is supplied while gradually increasing, this intermediate pressure becomes an auxiliary pressure, and the diaphragm 30 is further pushed downward.

  As a result, the valve body 15 is separated from the valve seat 14 as much as the diaphragm 30 is further pushed downward, and the valve opening is increased as compared with the conventional case. As described above, the pilot controller 130 reduces the distance between the valve portion 72a of the valve body 72 and the valve seat 64 as the secondary pressure of the valve box 11 decreases, and thus the auxiliary chamber that has passed through the throttle 67. The intermediate pressure 70 is supplied to the spring chamber 40 as an auxiliary pressure while gradually increasing.

  Thereafter, when the flow rate of the secondary flow path 12b becomes maximum and the secondary pressure becomes the lowest, the upward flow acting on the upper diaphragm 76 via the downstream sub pipe H2a and the secondary pressure detection path 74 is increased. The force becomes the smallest, and the valve body 72 is pushed down together with the upper diaphragm 76 and the lower diaphragm 71 by the urging force of the adjustment spring 85, and the valve portion 72a and the valve seat 64 are brought into contact with each other to close the valve.

At this time, the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 is not completely discharged from the discharge path 68, and all of the fluid that has passed through the restriction 67 and flowed into the auxiliary chamber 70 penetrates the spring protection cylinder 150. It is supplied to the spring chamber 40 via the hole 151a.
When the valve portion 72a of the valve body 72 of the pilot controller 130 comes into contact with the valve seat 64 and closes, the intermediate pressure of the fluid from the auxiliary chamber 70 becomes maximum, so that the valve body 15 of the pressure reducing valve body 2 after that time is reached. And the valve opening degree between the valve seats 14 becomes constant (FIG. 4).

  Therefore, since the valve opening between the valve body 15 and the valve body 14 becomes larger than the conventional valve opening due to the fluid (auxiliary pressure) supplied from the pilot controller 130 to the spring chamber 40, as shown in FIG. A decrease in the secondary pressure of the passage 12b can be prevented and the offset can be eliminated.

<Effect>
Also in the integrated pressure reducing valve 100, the valve body 15 is increased along with an increase in fluid (auxiliary pressure) supplied from the pilot controller 130 to the spring chamber 40 when the secondary pressure in the secondary flow path 12b gradually decreases. The valve opening between the valve seat 14 and the valve seat 14 can be gradually increased.
In this way, the integrated pressure reducing valve 100 performs correction control by gradually increasing the valve opening between the valve body 15 and the valve seat 14, so that operation stability is maintained without causing vibration or the like in the valve body 15. Further, the secondary side pressure of the secondary side flow path 12b can be prevented from being lowered and the accuracy can be improved. Thus, the integrated pressure reducing valve 100 can perform control with high accuracy that is not compared with a conventional direct acting pressure reducing valve without increasing the size.

  Since the integrated pressure reducing valve 100 has the pilot controller 130 integrally installed above the spring protection unit 150, the overall pressure reducing valve 100 is reduced in size as compared with the separate pressure reducing valve 1 in the first embodiment. be able to.

<Third Embodiment>
<Overall configuration of pilot operated pressure reducing valve>
As shown in FIG. 7 in which parts corresponding to those in FIG. 1 are assigned the same reference numerals, the pilot operated pressure reducing valve 200 as a self-acting regulating valve in the third embodiment is provided between the upstream pipe H1 and the downstream pipe H2. However, as a point different from the conventional one, the pilot controller 3 (see FIG. 3) is installed separately.

The pilot controller 3 has the same configuration as that of the first embodiment, and an upstream side sub-pipe H1a, a downstream side sub-pipe H2a, and an auxiliary pressure supply pipe H3 are connected. The auxiliary pressure supply pipe H <b> 3 is electrically connected to the spring chamber 240 of the pilot valve 230.
In this case, when the secondary pressure in the secondary flow path 202b decreases, the pilot operated pressure reducing valve 200 is transmitted from the secondary flow path 202b to the pilot controller 3 via the downstream sub pipe H2a. The valve portion 72 a of the third valve body 72 gradually approaches the valve seat 64.

At this time, the fluid supplied from the upstream side sub-pipe H1a to the supply path 65 passes through the restriction 67 and flows into the auxiliary chamber 70, and the fluid in the auxiliary chamber 70 serves as an intermediate pressure to the spring chamber 240 of the pilot valve 230. The pressure is gradually increased while being supplied.
Therefore, as the intermediate pressure of the fluid from the auxiliary chamber 70 of the pilot controller 3 increases (with time), the pressure of the spring chamber 240 of the pilot valve 230 gradually increases, so that the pilot valve 230 is opened. The degree is increased.

As a result, the degree of opening of the pilot valve 230 becomes larger than before, so that a large amount of fluid flows from the diaphragm chamber 216 of the main valve 201 to the ejector 220, the pilot valve 230, and the secondary side flow path 202b.
Thus, in the pilot operated pressure reducing valve 200, the valve element 211 of the main valve 201 is opened larger in the direction of the arrow B than in the conventional case by the extent that the degree of opening of the pilot valve 230 is larger than in the prior art. The pressure drop of the secondary side channel 202b can be prevented with respect to the pressure of the channel 202a, and the offset can be eliminated.

<Other embodiments>
In the first and second embodiments described above, the case where the pilot controllers 3 and 130 are installed in a separate or integrated manner with respect to the direct acting pressure reducing valves 1 and 100 has been described. The present invention is not limited to this, and the pilot controllers 3 and 130 may be installed in a separate type or an integrated type with respect to the direct acting back pressure valve.

  Further, in the above-described third embodiment, the case where the pilot controller 3 is separately installed with respect to the pilot valve 230 has been described. However, the present invention is not limited to this, and the second embodiment is the same as the second embodiment. Similarly, the pilot controller 3 may be integrally installed above the pilot valve 230.

  Furthermore, in the first to third embodiments described above, the case where the aperture 67 is provided inside the pilot controllers 3 and 130 has been described, but the present invention is not limited to this. When supplying the auxiliary pressure fluid to the auxiliary chamber 70, as shown in FIG. 9, a throttle valve 7 is provided outside (upstream) of the supply path 65 of the pilot controllers 3 and 130, and this throttle valve 7 and the supply path The fluid in the upstream side sub-pipe H1a may be supplied to the auxiliary chamber 70 via 65.

  In addition, in the first to third embodiments described above, the upstream end of the upstream side sub pipe H1a is connected to the upstream side pipe H1, and the fluid in the upstream side pipe H1 serves as the auxiliary pressure fluid from the fluid passage 4. The example supplied to the pilot controllers 3 and 130 via the pressure reducing valve 6 was shown. However, the self-regulating valve according to the present invention can also adopt a configuration in which the auxiliary pressure fluid is supplied from the primary flow path 12a of the valve box 11 to the pilot controllers 3 and 130 via the pressure reducing valve 6. When adopting this configuration, the upstream end of the upstream sub-pipe H1a is connected to the valve box 11. That is, the fluid used as the auxiliary pressure fluid can be obtained from any fluid passage as long as it is an upstream fluid passage including the primary passage 12a, in other words, a fluid passage upstream from the valve body 15. is there.

  DESCRIPTION OF SYMBOLS 1 ... Separate type pressure reducing valve, 2 ... Pressure reducing valve main body (valve main body), 3, 130 ... Pilot controller (auxiliary pressure supply part), 4 ... Fluid passage, 6 ... Pressure reducing valve, 7 ... Throttle valve, 11 ... ...... Valve box, 12..., Flow path, 12 a... Primary side flow path, 12 b... Secondary side flow path, 13 ... partition wall, 14 ...... valve seat, 15 ...... valve body, 17. ... Hex nut, 19 ... Valve spring, 21 ... Lower lid, 22 ... Liner, 23 ... Balance piston, 24 ... Diaphragm receiver, 26, 38, 83, 87 ... Hex nut, 30 ... Diaphragm, 31 ...... O-ring, 34, 85, 152... Adjustment spring, 35... Spring protection cylinder (spring protection part), 36, 86... Adjustment screw, 39, 84. ... Bolt, 50 ... Diaphragm chamber, 60 ... Main body, 61 ... Lower stage, 62 ... Step part 63 ... Upper stage part 64 ... Valve seat 65 ... Supply path 66 ... Output path 67 ... Restriction 68 ... Exhaust path 69 ... Through hole 70 ... Auxiliary chamber, 71: Lower diaphragm, 72: Valve body, 72a: Valve part, 73: Valve body receiver, 74: Secondary pressure detection path (pressure detection path), 75: Diaphragm chamber, 76: Upper Diaphragm (diaphragm for pressure detection) 80: upper lid, 81: bolt, 82: diaphragm receiver, 100: integrated pressure reducing valve, 150: spring protection cylinder, 151a: through hole, 200: pilot operation Pressure reducing valve, 201 ... main valve, 220 ... ejector (throttle valve), 230 ... pilot valve, 240 ... spring chamber, H1 ... upstream piping, H1a ... upstream sub piping.

Claims (6)

A diaphragm in which a valve element disposed opposite to a valve seat provided between a primary side flow path and a secondary side flow path is integrated through a valve rod is formed with a secondary side pressure of the secondary side flow path. A valve box that causes fluid to flow out from the primary side flow path to the secondary side flow path by driving; and
An adjustment spring integrated with the diaphragm for urging the valve body to move away from the valve seat;
A spring protection part provided above the diaphragm, wherein the adjustment spring is housed in a spring chamber of the internal space;
The auxiliary pressure fluid is installed outside the spring protection portion and supplied to the spring chamber of the spring protection portion from a fluid passage on the upstream side including the primary flow path via a pressure reducing valve. A self-acting regulating valve comprising: an auxiliary pressure supply unit that generates and supplies an auxiliary pressure corresponding to the secondary pressure. The auxiliary pressure supply unit includes:
A pressure detection path communicating with the secondary side flow path for detecting the secondary side pressure;
A supply path through which the auxiliary pressure fluid for generating the auxiliary pressure is supplied;
A discharge path for discharging the auxiliary pressure fluid supplied to the supply path;
An output path for outputting the auxiliary pressure fluid from the supply path to the spring chamber of the spring protector;
A valve portion that opens and closes a through hole communicating between the supply path and the output path and the discharge path;
A pressure detecting diaphragm provided integrally with the valve portion for detecting the secondary pressure via the pressure detecting path;
An adjustment spring that is integrated with the pressure detection diaphragm and urges the valve portion to close the through hole;
The opening degree of the valve portion with respect to the through hole is changed according to the secondary pressure detected through the pressure detecting diaphragm, and the auxiliary pressure by the auxiliary pressure fluid corresponding to the change is protected by the spring. The self-acting regulating valve according to claim 1, wherein the self-acting regulating valve is supplied to the spring chamber of a portion.   The self-regulating valve according to claim 2, wherein a throttle for generating the auxiliary pressure is provided between the supply path and the output path.   The self-regulating valve according to claim 2, wherein a throttle valve for generating the auxiliary pressure is provided outside the supply path.   5. The self-acting regulating valve according to claim 1, wherein the auxiliary pressure supply unit is separately installed outside the spring protection unit. 6.   5. The self-adjusting regulating valve according to claim 1, wherein the auxiliary pressure supply unit is integrally installed on an upper portion of the spring protection unit.

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