JP2006146832A - Pressure-reducing valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform a pressure resistance test in a state where a pressure-reducing valve is attached to a duct without using a bypass pipe or a substitution pipe. <P>SOLUTION: In the pressure-reducing valve, a partition wall 24 partitioning a pressure-reducing chamber 7 arranged to communicate with a secondary side-pressure chamber 3 and a primary side-pressure chamber 2 is formed so as to oppose a bottom part 2a of the primary side-pressure chamber 2, in a pressure-reducing mechanism part 6 which controls the opening degree of a main valve 5 in response to the pressure change of the secondary side pressure chamber 3. A spindle 31 to be freely movable relative to the partitioning wall 24 is put through into the primary side pressure chamber 2 from the outer part of the bottom part 2a. The spindle 31 includes a valve body 33 which is arranged in the partitioning wall 24 so as to open/close a communication port 32 for communication between the pressure-detecting chamber 7 and the primary side pressure chamber 2. In the pressure resistance test, the communication port 32 is opened with the use of the valve body 33 by the operation of the spindle 31, so as to constitute a bypass for communication with the secondary side pressure chamber 3 from the primary pressure chamber 2 by way of the communication port 32 and the pressure detecting chamber 7. Then water passage is kept from the primary side pressure chamber 2 to the secondary side pressure chamber 3. After the pressure resistance test, the valve body 33 closes the communication port 32, so that the pressure-reducing mechanism part 6 functions as the normal pressure-reducing valve. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a pressure reducing valve for door-to-door water supply such as an apartment house building.

Conventionally, this type of pressure reducing valve is required to perform a pressure test of the pipe after the pipe construction.
This pressure test is performed to check the presence of abnormalities such as water leakage by applying test pressure to the entire piping.
In order to prevent the pressure reducing valve in the piping from functioning, connect a bypass pipe in parallel to the pressure reducing valve, or remove the pressure reducing valve and attach a substitute pipe only during the test.After the test, remove the bypass pipe or replace the substitute pipe. It was necessary to replace the pressure reducing valve.
Since the work before and after the pressure test as described above is time-consuming and time consuming, the pressure test should be carried out without using a bypass pipe or substitute pipe and in a pipe completion state, that is, with a pressure reducing valve attached to the pipe. A pressure reducing valve as shown in Patent Document 1 has been developed.
This pressure reducing valve is provided in a pressure detecting flow path in which a pressure detecting chamber provided in a pressure reducing mechanism that controls the opening degree of the valve body in accordance with a pressure fluctuation of the secondary side pressure chamber and a secondary side pressure chamber communicated with each other. A ball valve is provided, and an operation part of the ball valve is provided outside the pressure reducing valve, and the ball valve is operated from outside the valve body,
During the pressure test, the flow between the pressure detection chamber and the secondary side pressure chamber is shut off and the pressure reducing function is not activated. In this state, the pressure reducing function is activated by circulating the pressure detection chamber and the secondary pressure chamber after the pressure resistance test.
JP 2001-147724 A (FIGS. 1 to 4)

However, in the pressure reducing valve configured as described above, in the pressure test, when the ball valve is operated to block the flow between the pressure detection chamber and the secondary pressure chamber so that the pressure reducing function does not act,
When the primary side pressure rises above a certain value, the piston attached to the valve rod together with the valve body is pushed up in the valve closing direction to close the valve body, which may cause a problem that water cannot pass.
Also, since the ball valve is provided in the pressure detection flow path that connects the pressure detection chamber arranged vertically within the valve body and the secondary pressure chamber, the ball valve is opened and closed outside the valve body. The operation rod inevitably protrudes from either the left or right side of the valve body, so the operation rod is close to or close to other piping / equipment, walls, etc., installed near the pressure reducing valve mounting position of the piping. When it is assumed that it is difficult to operate the ball valve or attach the pressure reducing valve itself, it is inconvenient to consider the position of the pressure reducing valve attached to the pipe.

In the pressure reducing valve, the pressure detecting chamber provided in the pressure reducing mechanism for controlling the opening degree of the main valve according to the pressure fluctuation of the secondary pressure chamber so as to communicate with the secondary pressure chamber, and the primary side A partition with the pressure chamber is formed opposite to the bottom of the primary pressure chamber, and a spindle that can be moved back and forth with respect to the partition is inserted from the outside of the bottom into the primary pressure chamber. By installing a valve body that opens and closes the communication port between the chamber and the primary pressure chamber, it is possible to operate the spindle that protrudes outward from the bottom of the primary pressure chamber (valve body) without having to consider the mounting position on the piping. In the pressure test, the valve body is separated from the communication port and opened to constitute a bypass that communicates from the primary side pressure chamber to the secondary side pressure chamber through the communication port and the pressure detection chamber. Maintain the water flow from the secondary to the secondary pressure chamber, and after the pressure test Is a by closing the communication port in the valve body, in the manner to function properly decompression mechanism as a normal pressure reducing valve, to solve the above problems.
In addition, the bottom open end of the cylindrical strainer is fixed to the bottom portion, and a strainer cap that is inserted through a spindle passing through the strainer in the axial direction thereof is detachably provided, and the strainer cap can be removed by removing the strainer cap. At the same time, the spindle is detached from the valve body.

In short, since the invention according to claim 1 has the above-described configuration, the pressure detection chamber is configured to open the communication port by detaching the valve body provided on the spindle by operating the spindle during the pressure resistance test. The primary side pressure chamber and the secondary side pressure chamber can be configured to communicate with each other through this, and water can be passed from the primary side pressure chamber to the secondary side pressure chamber through this bypass. Even if a high pressure is applied to the primary side, the water flow during the bypass can be maintained without any trouble, and thus the conventional problems can be completely solved.
In addition, after the pressure resistance test, the communication port can be closed by the valve body by operating the spindle, so that the pressure reducing mechanism can function normally.
Furthermore, since the spindle for operating the valve body protrudes outward from the bottom of the primary pressure chamber, that is, the bottom of the valve body, when installing the valve body to the pipe, other pipes and walls, etc. The valve body can be attached without difficulty even if the
Further, according to the present invention, as described above, since the structure is simple and complicated processing is not required, the manufacturing cost can be reduced, and the opening and closing of the communication port by the valve body can be simply advanced and retracted. There is no misoperation because it is simple.

According to the invention of claim 2, since the spindle is attached to the strainer cap together with the strainer, the spindle including the valve body together with the strainer can be detached from the valve body by removing the strainer cap at the time of maintenance of the strainer. It can be maintained easily, and the work can be performed easily.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a longitudinal sectional view of a pressure reducing valve according to the present invention. This valve body 1 is incorporated in a valve box 4 provided with a primary pressure chamber 2 and a secondary pressure chamber 3, and the valve box 4. A pressure reducing mechanism 6 that controls the opening of the main valve 5 according to the pressure fluctuation of the secondary pressure chamber 3 and a secondary pressure chamber 3 that communicates with the secondary pressure chamber 3 to detect the pressure of the secondary pressure chamber 3 The pressure detecting chamber 7 of the pressure reducing mechanism 6 and the flow path changing means 8 for connecting or disconnecting the pressure detecting chamber 7 and the primary pressure chamber 2 are configured.

The valve box 4 has an inlet 9 and an outlet 10 on the left and right sides thereof, and a primary pressure chamber 2 and a secondary pressure chamber 3 communicating with the inlet 9 and the outlet 10, respectively. Provided.
In the illustrated example, a pipe connecting union nut 11 is attached to the outlet 10.
In the center of the valve box 4, a partition wall 12 is provided that divides the primary pressure chamber 2 and the secondary pressure chamber 3 vertically,
A valve port 13 is opened in the partition wall 12 so that the pressure chambers 2 and 3 communicate with each other.

The pressure reducing mechanism 6 is formed by joining and fixing a circular concave portion 14 having a peripheral wall standing on the upper portion of the valve box 4 and a funnel-shaped bonnet 15 via a diaphragm 16. An adjustment spring 17 is disposed in the space (inside the bonnet 15), and the lower space (inside the recess 14) forms the pressure detection chamber 7.
The adjustment spring 17 is composed of a compression coil spring (square spring in the illustrated example). It is compressed and interposed between a spring receiver 21 that is pressed downward by an adjusting screw 20 made of a bolt screwed in more.
Then, the adjustment screw 20 is moved up and down to adjust the elastic force of the adjustment spring 17, and the displacement of the diaphragm 16 below it is adjusted.
The cap 19 is provided with a sealing cap 22 that is internally fitted with an O-ring that prevents water leakage from the screw hole into which the adjusting screw 20 is screwed and is fitted on the adjusting screw 20. Is provided with a lock nut 23 screwed onto the adjusting screw 20.

The lower part of the pressure detection chamber 7 corresponding to the upper part of the valve box 4 is a partition wall 24 with the primary pressure chamber 2 formed opposite to the bottom of the valve box 4, and the central part corresponding to the valve port 13 in the partition wall 24. The pressure detection chamber 7 and the primary pressure chamber 2 are communicated with each other by providing a circular opening, and a cylindrical portion 25 having a predetermined length continuous in the vertical direction is provided at the periphery of the opening.
The lower peripheral wall of the cylindrical portion 25 is suspended so as to be continuous with the partition wall 12 between the primary side pressure chamber 2 and the secondary side pressure chamber 3, and a part of a portion of the lower peripheral wall facing the primary side pressure chamber 2 is provided. Is opened so as to communicate with the primary pressure chamber 2, and in the partition walls 12, 24, a portion adjacent to the cylindrical portion 25 facing the bottom of the secondary pressure chamber 3 is opened to open the secondary pressure chamber 3. And the pressure detection chamber 7 are communicated with each other.
In the center of the diaphragm 16, a valve rod 26 inserted through the cylindrical portion 25 and the valve port 13 is suspended,
A main valve 5 for opening and closing the valve port 13 is provided at the lower end of the valve rod 26.

The main valve 5 is detachably provided on the valve seat 27 provided at the lower opening end of the valve port 13 so as to receive the primary pressure in the valve opening direction, and the opening degree is controlled by the displacement of the diaphragm 16. It is made up of.
A piston 28 that slides on the inner wall of the tubular portion 25 is provided outwardly in the middle of the valve stem 26, and an O-ring 29 is provided around the piston 28 so that the primary pressure chamber 2 and the pressure are provided. The detection chamber 7 is partitioned in a watertight manner.
The effective pressure receiving area of the piston 28 is set slightly larger than the effective pressure receiving area on the primary side of the main valve 5.
A diaphragm retainer 30 made of a nut joined to the lower surface of the diaphragm 16 is formed to have a diameter larger than that of the cylindrical portion 25, and the diaphragm retainer 30 is in a state where the diaphragm 16 is displaced to the lowest limit.
Is seated at the upper opening end of the tubular portion 25 and restricts the lift of the main valve 5 in this state.

The flow path changing means 8 is provided in the partition wall 24 and a spindle 31 that is slidably inserted into the primary pressure chamber 2 from the outside of the bottom portion 2a of the primary pressure chamber 2 into the partition wall 24 facing the bottom portion 2a. It comprises a communication port 32 between the pressure detection chamber 7 and the primary pressure chamber 2, and a valve body 33 provided at the tip of the spindle 31 so as to open and close the communication port 32.
The communication port 32 is formed in a paper shape that is gradually reduced in diameter toward the pressure detection chamber 7, and the valve body 33 is formed with a reduced diameter so that the tip of the spindle 31 corresponds to the minimum diameter of the communication port 32. An annular seal member such as an O-ring or packing corresponding to the maximum diameter of the communication port 32 is externally fitted to the reduced diameter portion on the annular step portion formed by the reduced diameter.
On the bottom 2a, a lower open end of a cylindrical strainer 34 is fixed, and the strainer
A strainer cap 35 in which the base end side of the spindle 31 vertically passing through the shaft 34 is screwed in a watertight manner is screwed in a watertight manner so that it can be attached to and detached from the valve box 4.
The upper open end of the strainer 34 is a receiving port 36 of the strainer 34 provided in the primary pressure chamber 2.
Is inserted in a watertight manner.
Accordingly, the fluid flows from the inlet 9 through the strainer 34 into the primary pressure chamber 2.
Then, in the spindle 31, by rotating the base end projecting outward from the strainer cap 35, the valve body 33 at the tip thereof opens and closes the communication port 32, and the valve body 33 is separated from the communication port 32. The primary pressure chamber 2 and the pressure detection chamber 7 are communicated with each other, and a bypass is formed in which the primary pressure chamber 2 and the secondary pressure chamber 3 communicate with each other through the pressure detection chamber 7.
The spindle 31 has a base end face provided with a groove 31a in the diametrical direction, and the tip of a minus driver is aligned with the groove 31a to rotate the spindle 31. However, a handle may be provided at the proximal end of the spindle 31.

Next, the operation of the pressure reducing valve will be described.
First, in the pressure resistance test, the spindle 31 is rotated as shown in FIG. 2 to disengage the valve element 33 at the tip of the spindle 31 from the communication port 32 and open the communication port 32.
As a result, a bypass is formed which communicates from the primary side pressure chamber 2 to the secondary side pressure chamber 3 via the communication port 32 and the pressure detection chamber 7.
By configuring this bypass, the primary pressure chamber 2, the pressure detection chamber 7, and the secondary pressure chamber 3 have the same pressure. Therefore, the pressure reducing mechanism 6 does not function and the main valve 5 is closed. Yes.
Therefore, the bypass in the valve box 4 functions as a water passage that communicates from the primary pressure chamber 2 to the secondary pressure chamber 3, and the primary pressure is maintained even if a high pressure is applied to the primary pressure chamber 2 during the pressure resistance test. Room 2
From the water to the secondary pressure chamber 3 is maintained by bypass.

Further, after the pressure resistance test, as shown in FIG. 1, the valve element 33 closes the communication port 32 in a watertight manner by rotating the spindle 31 in the opposite direction.
As a result, the bypass is disabled, and the pressure reducing mechanism 6 functions normally like a normal pressure reducing valve.
That is, the upward force (valve closing direction) force to the diaphragm 16 due to the secondary pressure in the pressure detection chamber 7 communicating with the secondary pressure chamber 3 and the downward force (valve opening direction) force due to the adjustment spring 17 are balanced. Thus, the opening degree of the main valve 5 is controlled, and the secondary pressure is kept at a certain pressure lower than the primary pressure.

When the spindle 31 including the valve element 33 and the strainer 35 are maintained, the strainer cap 35 is removed from the bottom 2a of the valve box 4 (primary side pressure chamber 2) by removing the strainer cap 35 from the strainer cap 35. 34 and the spindle 31 are separated from the valve box 4 and work together at the same time. After that work, the strainer cap 35 is screwed onto the valve box 4 and the spindle 31 is rotated to close the communication port 32 with the valve body 33. To do.

It is a longitudinal cross-sectional view of a pressure reducing valve. It is a longitudinal cross-sectional view of the pressure reducing valve at the time of a pressure test.

Explanation of symbols

2 Primary pressure chamber
2a Bottom 3 Secondary pressure chamber 5 Main valve 6 Pressure reducing mechanism 7 Pressure detection chamber
24 Bulkhead
31 spindle
32 communication port
33 Disc
34 Strainer
35 Strainer cap

Claims (2)

In the pressure reducing valve, a pressure detection chamber provided to communicate with the secondary pressure chamber in a pressure reducing mechanism that controls the opening of the main valve according to the pressure fluctuation of the secondary pressure chamber, and a primary pressure chamber A partition wall is formed opposite to the bottom of the primary pressure chamber, and a spindle that is movable forward and backward with respect to the partition wall is inserted from the outside of the bottom into the primary pressure chamber. The spindle includes a pressure detection chamber and a primary side provided in the partition wall. A pressure reducing valve provided with a valve body that opens and closes a communication port with a pressure chamber. 2. The decompression according to claim 1, wherein the bottom portion is provided with a strainer cap which is fixed to a lower open end of a cylindrical strainer and which is detachably provided with a spindle passing through the strainer in the axial direction. valve.

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