KR101551761B1 - Butterfly Valve impulse pressure testing apparatus - Google Patents

Abstract

The present invention relates to a butterfly valve impulse pressure testing apparatus which comprises a pressurizing part connected to one side of a butterfly valve, and receiving a pressurized fluid; a pump connected to the pressurizing part, and supplying the pressurized fluid to the pressurizing part; and a pressure supplement part connected to the pressurizing part, and supplying the pressurized fluid to the pressurizing part, thereby reducing the size of a pump by rapidly supplying pressure to the pressurizing part after opening and closing the butterfly valve, and improving reliability of a test by making a pressure increasing curve similar to a design spec of an impulse pressure test.

Description

[0001] The present invention relates to a butterfly valve impulse pressure testing apparatus,

The present invention relates to an apparatus for testing an impact pressure of a butterfly valve, in which the size of the pump can be miniaturized by allowing the pressure portion to quickly fill the pressure portion after opening and closing the butterfly valve, The present invention relates to a butterfly valve impact pressure tester capable of improving the reliability of a test.

In general, valves have been used to control the flow of fluid from a very long time ago and regulate the pressure, temperature and velocity, or flow, expressed in physical properties of the fluid. Valves are the most common and important control element to control the flow of fluid in the final stages of each control step to match the flow conditions of the fluid in the piping system to the physical conditions and amount of fluid required in each process.

A wide variety of valves are used to control fluid flow in the piping. Of these, butterfly valves are used to regulate opening and closing and flow rate, including the large flow of fluid at relatively low pressure, by rotating a cylindrical body and a circular disk installed therein. Butterfly valve has a simple structure because its flow rate is controlled by the rotation of the rotating disk about the shaft, and it is light in weight compared to other valves, so it does not need any additional support, small size, cheap price, .

Currently, there are ISO 10631, ANSI / ASME B16.34, ANSI / AWWA C504 and KS B 2333 for domestic and international standards for butterfly valves used in industrial applications. These standards specify the pressure ratings for valve use, and ISO 5208, IEC 60534-4, and KS B 2304 provide for valve inspection and pressure testing.

Performance and life testing are required when improvements are made to the various factors under study in the industry. However, in Korea, companies that are above a certain size are carrying out simple performance tests and putting them on the market.

Butterfly valves are widely used in apartment complexes, dams, drainage pumping stations, and water piping. Therefore, the external environment and the conditions of use are used in various conditions. The flow rate and pressure range of the flow rate should be set differently according to the application.

The main component of the butterfly valve is mainly composed of a body, a seat, a disk and a stem. In the configuration of such a valve, leakage is a major failure mode, and more than 60% of the faults are confirmed as leakage from the seat portion. However, since these valves must be used for more than 10 years in the case of general plant equipment, there is a desperate need to develop a test equipment capable of reproducing failure modes that may occur in the field conditions.

In addition, the conventional butterfly valve test equipment developed for this purpose is as follows. When a pipe is connected to the butterfly valve using steel material on both sides of the butterfly valve, the butterfly valve is closed using various actuators, The pressure is supplied to the inside of the butterfly valve.

However, it is difficult to apply the pressure fluid instantly to the butterfly valve by using only the pump as in the conventional equipment, so it is difficult to perform the impact pressure test of the butterfly valve. In order to make the pressure waveform similar to the design specification of the impact pressure test, There is a problem that the cost of the pump becomes very high.

KR 10-2010-0113275 (2010.10.21)

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a pressure regulating device, The present invention provides a butterfly valve impact pressure test apparatus which can be similar to the design specifications of the impact pressure test and can improve the reliability of the test.

In order to accomplish the above object, there is provided an apparatus for testing an impact pressure of a butterfly valve, comprising: a pressure unit connected to one side of a butterfly valve to supply a pressurized fluid; A pump connected to the pressurizing portion to supply the pressurized fluid to the pressurizing portion; And a pressure replenishing portion connected to the pressurizing portion and supplying the pressurized fluid to the pressurizing portion; And a control unit.

The pressure replenishing unit is a pressure replenishing tank provided on the upper side of the pressure unit and supplying the fluid to the pressure unit by the weight of the fluid.

A check valve is provided in the second pressurizing passage to which the fluid is supplied from the pressure replenishing tank to the pressurizing portion so that the fluid can flow only from the pressure replenishing tank to the pressurizing portion by the check valve .

A pilot check valve is installed in the second pressurizing passage to which the fluid is supplied from the pressure replenishing tank to the pressurizing portion.

In addition, a supplementary flow passage is formed in the pump, one end of which is connected to the first pressure passage through which fluid is supplied to the pressurization portion, and the other end of which is connected to the pressure supplement tank so as to supply the fluid to the pressure supplement tank.

A direction switching valve is provided in the first pressure passage and the supplementary flow passage so that the fluid can be selectively supplied to the pressure portion or the pressure supplement tank by the direction switching valve.

In addition, the pressure replenishing tank is characterized in that a drain portion is formed to maintain a constant level of the fluid filled in the pressure replenishing tank.

Further, a main reservoir connected to the other side of the butterfly valve and disposed at an end of a drain passage through which a fluid is discharged, a suction passage through which the fluid is sucked by the pump, and a drain passage through which the drain is connected, And the like.

The butterfly valve impact pressure test apparatus of the present invention is capable of reducing the size of the pump by making it possible to quickly replenish the pressurized portion after the opening and closing of the butterfly valve. The pressure rising curve is similar to the design specification of the impact pressure test The reliability of the test can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a butterfly valve impact pressure test apparatus of the present invention. FIG.
Figure 2 is a graph of the pressure versus time of a fluid showing the design specifications of a waveform for a butterfly valve impact pressure test according to the present invention.
3 is a graph comparing the fluid pressure rising waveform of the present invention with that of the prior art.
4 is a schematic view showing a butterfly valve impact pressure test apparatus showing an embodiment in which a pilot check valve is installed in a second pressurizing passage according to the present invention.

Hereinafter, the butterfly valve impact pressure testing apparatus of the present invention as described above will be described in detail with reference to the accompanying drawings.

≪ Example 1 >

FIG. 1 is a schematic view showing a butterfly valve impact pressure test apparatus according to the present invention, FIG. 2 is a graph showing a time dependent pressure of a fluid showing a design specification of a waveform for a butterfly valve impact pressure test according to the present invention, Is a graph comparing the present invention with the fluid pressure rising waveform of the prior art.

As shown in the drawings, an apparatus 1000 for testing an impact pressure of a butterfly valve according to an embodiment of the present invention includes: a pressing unit 100 connected to one side of a butterfly valve 10 to supply a pressurized fluid; A pump 200 connected to the pressure unit 100 to supply a fluid pressurized by the pressure unit 100; And a pressure replenishing unit 300 connected to the pressure unit 100 to supply the fluid pressurized by the pressure unit 100; . ≪ / RTI >

First, the butterfly valve 10 is provided so that a disc-shaped disc can be rotated inside a cylindrical body formed so as to be opened at both sides thereof, and the disc is rotated by the actuator 11 to form a disc on the inner peripheral surface of the body So that the flow path can be closed or opened. The butterfly valve 10 is fixed to the fixing bracket 130 so that the fixing bracket 130 can be firmly fixed to a separate base or frame.

The pressurizing unit 100 is a portion to which the pressurized fluid is supplied so that the fluid can pass through the pressurizing unit 100. The pressurizing unit 100 is coupled to an open side of the butterfly valve 10 to be tested. That is, the pressurizing portion 100 is a space in which one side of the butterfly valve 10 can be filled with the fluid pressurized at a specific pressure to be tested. An inspection unit 110 may be formed on the other side of the butterfly valve 10. An inspection window 111 made of a transparent material is formed on the inspection unit 110 so that the inside of the butterfly valve 10 And can be configured to be identified. That is, it is possible to visually confirm the inside of the butterfly valve 10 through the check window 111, so that it can be confirmed that the fluid leaks inside the butterfly valve 10. The discharge port 120 is formed below the inspection unit 110 so that the fluid filled in the pressure unit 100 can be discharged through the discharge port 120 when the butterfly valve 10 is opened.

The pump 200 is connected to the pressurizing unit 100 and is configured to supply the pressurized fluid to the pressurizing unit 100 at a specific pressure. One end of the first pressurizing flow channel 210 is connected to the pump 200, And the other end of the first pressurization passage 210 may be connected to the first portion 100. At this time, the pump 200 may be various kinds of pumps that can supply test fluid such as water or hydraulic oil.

The pressure replenishing unit 300 is connected to the pressurizing unit 100 and is configured to supply the pressurized fluid to the pressurizing unit 100 at a specific pressure so that the fluid pressurized by the pressurizing unit 100 together with the pump 200 As shown in FIG. That is, the pressure replenishing unit 300 is formed so that the fluid pressurized by the pressurizing unit 100 is basically supplied from the pump 200, but the insufficient pressure and flow rate can be quickly replenished. At this time, one end of the second pressurizing passage 310 may be connected to the pressure replenishing section 300, and the other end of the second pressurizing passage 310 may be connected to the pressurizing section 100.

Here, in the impact pressure test of the butterfly valve, a pressure rising curve closest to the design specifications of the impact pressure test can be obtained as shown in FIG. 2, if the pressurizing portion 100 is quickly and instantaneously filled with the pressurized fluid. That is, the pressure inside the pressurizing portion 100 should rise almost vertically to reach a specific pressure. 3, when the butterfly valve is closed, the pressure is instantaneously pressurized to a specific pressure, the pressurized state is maintained for a predetermined time, and then the butterfly valve And the fluid is discharged so that the pressure is instantaneously zero, so that an impact pressure test is performed so that the pressure graph becomes a square wave.

 Thus, when the butterfly valve is subjected to the impact pressure test, the fluid filled in the pressure unit 100 is discharged through the discharge port 120 by opening the butterfly valve 10, and the pressure inside the pressure unit 100 is lowered. At this time, when the butterfly valve 10 is closed, the fluid is filled in the pressure part 100 by the pump 200 and the pressure is increased. Here, the pressure is increased from the pressure supplement part 300 to the pressure part 100 As the fluid is being supplied, the fluid is quickly filled in the pressurizing portion 100, so that a specific pressure can be instantaneously reached. That is, it is possible to accurately test the reliability of the butterfly valve, such as the durability of the butterfly valve and the occurrence of water leakage, as the impact pressure repeatedly acts by repeated opening and closing of the butterfly valve.

The pressure replenishing unit 300 may be a pressure replenishing tank 300 provided above the pressure unit 100 and supplying fluid to the pressure unit 100 by the weight of the fluid.

That is, the pressure replenishing unit 300 may be formed of the pressure replenishing tank 300 so that the fluid of a specific pressure can be supplied to the pressing unit 100 by the self weight of the fluid. Thus, even if the butterfly valve 10 becomes large, a small capacity pump can be used instead of a large capacity pump, and the deficient pressure and flow rate can be supplied from the pressure supplement tank. Since a large amount of fluid can be stored in the pressure replenishing tank 300, a large amount of fluid can be quickly supplied to the pressurizing portion 100, so that the small capacity pump 200 can be used.

As described above, the butterfly valve impact pressure testing apparatus of the present invention can quickly reduce the size of the pump by enabling the pressure portion to be quickly filled in after the butterfly valve is opened and closed. There is an advantage in that the reliability of the test can be improved.

A check valve 320 is provided in the second pressurizing passage 310 through which the fluid is supplied from the pressure replenishing tank 300 to the pressurizing portion 100. The check valve 320 is provided in the pressure replenishing tank 300 may be formed so that fluid can flow only toward the pressing portion 300.

That is, in the pressure replenishing tank 300, since the fluid pressure is formed by the self weight of the fluid, when the fluid in the pressure replenishing tank 300 is supplied to the pressurizing portion 100, Since the pressurized fluid supplied from the pump 200 is supplied to the interior of the pressurizing unit 100 at this time, if the fluid pressure in the second pressurizing passage 310 becomes lower than the pressure inside the pressurizing unit 100, A check valve 320 may be installed in the second pressure passage 310 to prevent the fluid from flowing back to the supplement tank 300.

Thus, the reliability of the butterfly valve impact pressure test can be improved by allowing the pressure in the pressurizing portion 100 to continuously rise without lowering.

≪ Example 2 >

4, a pilot check valve 330 may be installed in the second pressurizing passage 310 through which the fluid is supplied from the pressure replenishing tank 300 to the pressurizing portion 100.

As described above, when the fluid pressure in the second pressure passage 310 becomes lower than the pressure inside the pressure unit 100, the fluid can flow back to the pressure supplement tank 300. Therefore, And a pilot check valve 330 is installed in the fuel tank 310. At this time, the pilot check valve 330 can be operated in the same manner as a normal check valve when no pressure is supplied to the pilot port. When the pilot port is supplied with pressure, the valve is kept open, The fluid may flow to the pressure replenishing tank 300 side.

Thus, by controlling the operation of the pilot check valve 330, the pressure in the pressurizing portion 100 can be continuously increased without lowering, thereby improving the reliability of the butterfly valve impact pressure test. So that the pilot check valve 330 is opened so that the fluid pressurized by the pump 200 is supplied to the pressure replenishing tank 300 through the second pressure path 310 and then returned to the pressure replenishing tank 300, So that the fluid can be filled.

One end of the pump 200 is connected to the first pressure passage 210 through which the fluid is supplied to the pressure unit 100 and the other end of the pressure tank 300 is connected to the pressure supplement tank 300, A supplementary flow path 240 can be formed.

This is because it is not necessary to supply any further pressurized fluid into the pressurizing part 100 when the pressurizing part 100 is filled with the fluid and reaches a specific pressure. At this time, since the pump 200 can be maintained in a continuously operated state, The fluid that is pressurized by the pressurizing unit 200 may be supplied to the pressure replenishing tank 300 through the replenishing passage 240 so that the fluid is filled in the pressure replenishing tank 300 where the fluid is reduced.

Thus, the fluid can be filled in the pressure replenishing tank 300 during the time when the fluid is not supplied to the pressure unit 100 through the pump 200, so that the pump 200 can be efficiently used. It is not necessary to provide a fluid supply means such as a separate pump for filling the fluid.

At this time, a direction switching valve 230 is provided to the first pressure passage 210 and the supplementary channel 240, and the direction switching valve 230 is connected to the pressure unit 100 or the pressure supplement tank 300 And may be configured to selectively supply fluid.

That is, when the fluid is filled in the pressurizing part 100 and reaches a specific pressure, the first valve 231 of the directional control valve 230 is closed and the second valve 232 is opened so that the pressure inside the pressurizing part 100 is further increased So that the fluid can be supplied to the pressure replenishing tank 300 at this time. Conversely, when it is necessary to increase the pressure by filling the fluid into the pressure unit 100, the first valve 231 of the directional control valve 230 is opened and the second valve 232 is closed, so that the fluid pressurized by the pump 200 The pressure inside the pressurizing portion 100 can be increased by supplying only the pressurizing portion 100.

In addition, the pressure replenishment tank 300 may be formed with a drain portion 340 so as to maintain a constant level of the fluid to be filled therein.

That is, as shown in the drawing, the drain portion 340 may be formed in the form of a hole penetrating to one side of the pressure replenishing tank 300 so as to discharge the fluid, and the pressure replenishing tank 300 may be formed through the drain portion 340, The pressure of the fluid that can be supplied to the pressing portion 100 can be maintained at a specific pressure by preventing the fluid to be filled inside from rising to a certain level or more.

At this time, the drain portion 340 may be formed so that the height of the drain portion 340 can be adjusted so that the level of the fluid filled in the pressure replenishing tank 300 can be adjusted. That is, the height of the drain portion 340 may be adjusted according to the pressure of the fluid to be supplied to the pressing portion 100.

The discharge port 121 connected to the other side of the butterfly valve 10 to discharge the fluid, the suction flow path 220 through which the fluid is sucked by the pump 200, and the drain port 340 are connected And a main reservoir 400 in which an end of the drain channel 350 is disposed and in which the fluid is received.

This is because the main reservoir 400 is provided below the butterfly valve 10 and the end of the flow path for sucking and discharging the fluid used for the test is connected to the main reservoir 400, The impact pressure test of the butterfly valve can be performed. At this time, the discharging flow path 121 is connected to the discharging port 120 formed on the lower side of the checking unit 110 coupled to the other side of the butterfly valve 10 so that the end of the discharging flow path 121 is connected to the main reservoir 400 An end of the suction passage 220 connected to the pump 200 may be connected to the main reservoir 400 and an end of the drain passage 350 connected to the drain portion 340 may be connected to the main reservoir 400 have.

The butterfly valve 10 to be tested may be a valve capable of controlling opening and closing by an actuator 11 that operates by pneumatic, hydraulic, and electric power. The butterfly valve 10 may be a valve have.

A general centrifugal pump can be used to prevent the pulsation of the fluid to be pressurized. The pump 200 is provided with a device capable of removing pulsation from the first pressure passage 210 or the pressure unit 100, Type pump may be used. Further, since the butterfly valve 10 may be used in an environment where pulsation occurs, a pump in which pulsation occurs may be used in the test.

In addition, a pressure sensor is provided in the pressing portion 100 to measure the pressure of the fluid filled in the pressure portion 100, and the operation of the direction switching valve and the opening and closing operation of the butterfly valve 10 are controlled in accordance with the pressure measured by the pressure sensor The impact pressure test can be performed. Also, a pressure sensor may be installed on the inspection unit 110, which is the other side of the butterfly valve 10, to monitor the pressure.

In the case of performing the impact pressure test while the test fluid accommodated in the main reservoir 400 is circulated, since the temperature of the fluid may pass through the pump 200, the temperature of the fluid may be measured using a temperature sensor, So that the reliability of the test can be improved by keeping the fluid at a constant temperature by cooling the fluid.

Also, it is possible to perform the butterfly valve impact pressure test by adjusting the degree of opening and closing of the butterfly valve 10 through the control unit.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: Butterfly Valve Impact Pressure Test System
10: Butterfly valve 11: Actuator
100:
110: Check section 111: Confirmation window
120: outlet 130: fixed bracket
200: pump
210: first pressurizing passage 220: suction passage
230: Directional switching valve
231: first valve 232: second valve
240: Replacement Euro
300: Pressure replenishment part (pressure replenishment tank)
310: second pressurizing flow passage 320: check valve
330: pilot check valve 340: drain portion
350: drain drain
400: main reservoir

Claims (8)

A pressurizing portion connected to one side of the butterfly valve and supplied with pressurized fluid;
A pump connected to the pressurizing portion to supply the pressurized fluid to the pressurizing portion; And
A pressure replenishing portion connected to the pressurizing portion and supplying the pressurized fluid to the pressurizing portion;
And,
The pressure-
A pressure replenishing tank which is provided above the pressurizing portion and supplies the fluid to the pressurizing portion by self weight of the fluid,
A supplementary flow passage is formed in the pump, one end of which is connected to a first pressure passage through which fluid is supplied to the pressure portion, and the other end of which is connected to the pressure supplement tank so as to supply the fluid to the pressure supplement tank,
Wherein a direction switching valve is provided in the first pressure passage and the supplementary flow passage so that the fluid can be selectively supplied to the pressure portion or the pressure supplement tank by the direction switching valve.
delete The method according to claim 1,
Characterized in that a check valve is provided in the second pressurizing passage to which the fluid is supplied from the pressure replenishing tank to the pressurizing portion so that the fluid can flow only from the pressure replenishing tank to the pressurizing portion by the check valve. Valve Impact Pressure Tester.
The method according to claim 1,
And a pilot check valve is installed in the second pressurizing passage through which the fluid is supplied from the pressure replenishing tank to the pressurizing portion.
delete delete The method according to claim 1,
Wherein the pressure replenishing tank is formed with a drain portion to maintain a constant level of the fluid to be filled in the pressure replenishing tank.
8. The method of claim 7,
Further comprising a main reservoir connected to the other side of the butterfly valve for discharging the fluid, a suction channel for sucking fluid through the pump, and an end of a drain channel connected to the drain, And a pressure sensor for detecting the impact pressure of the butterfly valve.

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