KR20120015806A - Gas valve for circuit breaker - Google Patents

Abstract

PURPOSE: A gas valve for a breaker installed at an gas insulation switch for opening and closing a high-voltage electric power is provided to perform a contact point test by suing simple rotating operation of a coupling. CONSTITUTION: A gas valve for a breaker comprises a first main body, a secondary body(20), a stem(30), a coupling(40), a third body(50), and a pressure gauge. The first main body comprises the first flow path communicated with a tanker and is fixed and coupled in the tanker in which the gas is saved. The secondary body comprises a second fluid path(21) communicated with the first flow path and is combined in the first main body. The second fluid path is opened and closed by sliding a stem in the secondary body. The coupling is screwed up in the secondary body. The third body is combined in the coupling by pushing or releasing the stem according to the rotation of the coupling. The pressure gauge is communicated with the third flow path and measures the pressure of the inserted gas.

Description

GAS VALVE FOR CIRCUIT BREAKER}

The present invention relates to a gas valve, and more particularly, to a gas valve for a circuit breaker provided in a gas insulated circuit breaker for opening and closing a high-voltage power, such as a power plant, substation.

In general, breakers are installed for the purpose of blocking or connecting the transformed power in a power plant, substation, or the like as necessary. Since the breaker is a device that opens and closes the high voltage power, sulfur hexafluoride (SF6) gas is injected into the device to minimize the spark generated when the high voltage power is opened and closed to protect the breaking current.

In other words, the pressure of the SF6 gas must be maintained above a predetermined pressure inside the gas insulation breaker to prevent damage to the device due to spark generation.

To this end, the administrator must periodically check for the presence of the specified pressure in the device, and as a safety device, contact test work to verify that the set pressure of the contact gauge is appropriate and that the contact gauge is functioning properly at the set pressure. Do this. In this case, the contact gauge is a pressure gauge with a built-in contact capable of setting a pressure by attaching a contact and generating a warning signal when the pressure drops below the set pressure.

In other words, the proper gas pressure inside the breaker has a great influence on the insulation, so it is necessary to continuously monitor whether the pressure inside the tanker is appropriate. In addition, the gauge contact test is performed from time to time to prevent the gauge from detecting pressure changes.

1 illustrates a conventional gas valve connection structure.

As shown in FIG. 1, in the related art, the tanker 140 and the pressure gauge 110 are connected by a pipe, and a first valve 130 is installed on the pipe to open and close the flow of gas in the pipe. In addition, another pipe is branched between the first valve 130 and the pressure gauge 110, and a second valve 120 is installed on the branched pipe. In this case, the first valve 130 is locked and the second valve 120 is gradually opened while checking whether a normal signal is transmitted when the pressure of the pressure gauge 110 drops.

However, the conventional gas valve connecting structure requires two valves, thus requiring at least two pipes for connecting the valves and at least one block for covering the pipes. Accordingly, the conventional gas valve connection structure has a problem of having a complicated structure.

In addition, there was a possibility of gas leakage at the brazing welding area where the pipe and the valve are connected.

In addition, since the installation position of the pressure gauge with respect to the tanker is fixed, it is difficult to meet the user's eye level with respect to the pressure gauge according to the position of the tanker, and to meet the user's eye level, various types of pipes and blocks are required. There was a downside.

In order to solve such a conventional problem, it is an object of the present invention to provide a gas valve for a circuit breaker that can be implemented a single integral gas valve structure and the pressure gauge can be variously adjusted.

The gas valve for a circuit breaker according to the present invention has a first body coupled to a tanker containing gas and having a first flow passage communicating with the tanker therein, and a second flow passage coupled to the first body and communicating with the first flow passage therein. The formed second body, a stem slidably disposed in the second body to open and close the second flow path, a coupling screwed to the second body, a coupling coupled to the coupling, and the stem being rotated by the coupling. And a third body having a third flow passage communicating with or disengaging from the second flow passage by pressurizing or depressurizing the pressure, and a pressure gauge measuring the pressure of the gas being communicated with the third flow passage.

In addition, the third body has a press portion in contact with or released from the stem in the third flow path, where the press portion presses the stem when the coupling is tightened to the second body, and the press portion presses the stem when the coupling is released from the second body. It is characterized by releasing the pressure.

In addition, the first hole for the gas vent is formed in the coupling, and the second body is formed in the second body in communication with or released from the first hole by the rotation of the coupling.

In addition, a plurality of fastening holes are formed radially in the first body, and the pressure gauge is arranged to be angle-adjustable in the front-rear direction with respect to the tanker.

In addition, the second body is rotatably fastened in a vertical direction with respect to the first body, the pressure gauge is characterized in that the angle adjustable in the left and right directions with respect to the tanker.

The gas valve for the circuit breaker according to the present invention is a very useful invention that enables the contact test through a simple rotational operation of the coupling, as well as having a simple structure, there is no fear of gas leakage.

In addition, the gas valve for the circuit breaker according to the present invention can be freely selected in the front, rear, left, right direction with respect to the tanker, it does not require a variety of valves and blocks to reduce the cost and convenience of installation This is improved.

1 shows a conventional gas valve connection structure,
Figure 2 shows a gas valve for a circuit breaker according to an embodiment of the present invention,
Figure 3 shows a cross-sectional view of a gas valve for a circuit breaker according to an embodiment of the present invention,
4 and 5 illustrate an operation example of a gas valve for a circuit breaker according to an embodiment of the present invention,
6A, 6B, and 6C illustrate fastening holes of a gas valve for a breaker according to various embodiments of the present disclosure.
Figure 7 shows a gas valve for a circuit breaker according to another embodiment of the present invention.

Hereinafter, a technical configuration of a gas valve for a circuit breaker according to the accompanying drawings will be described in detail.

Figure 2 shows a gas valve for a circuit breaker according to an embodiment of the present invention, Figure 3 shows a cross-sectional view of the gas valve for a circuit breaker according to an embodiment of the present invention.

4 and 5 illustrate an operation example of a gas valve for a circuit breaker according to an exemplary embodiment of the present invention.

As shown in FIGS. 2 to 5, the gas valve for the circuit breaker includes a first body 10, a second body 20, a stem 30, a coupling 40, and a third body 50. ), And a pressure gauge 60.

The first body 10 is fastened to one side of the tanker 11 in which the gas is accommodated. A first flow path (not shown) is formed inside the first body 10. The first flow passage communicates with the tanker 11. Sulfur hexafluoride (SF6) gas having a high insulating property is contained in the tanker 11 at a predetermined pressure, and the first channel functions as a passage through which the gas flows.

Although not shown, opening and closing means for opening and closing the flow of gas may be further provided at the inlet side of the first body (10). The opening and closing means blocks the first flow path of the first body 10 at a predetermined pressure or less, and opens the first flow path at a predetermined pressure or more to allow gas in the tanker 11 to flow into the first flow path. Such opening and closing action may be implemented by installing a separate elastic means in the first passage.

The second body 20 is coupled to the first body 10. The second body 20 may be screwed to the first body 10, it may be formed integrally. A second flow passage 21 is formed in the second body 20. The second flow passage 21 communicates with the first flow passage formed in the first body 10. In the first passage, the second passage 21, or a connection portion between the first passage and the second passage 21, a pressurization device such as a bellows and the like for sealing the gas may be further included.

The stem 30 is slidably arranged inside the second body 20 to open and close the second flow passage 21. That is, the stem 30 is installed on the passage through which the gas flows, and functions to block the flow of the gas. In this case, the stem 30 is pressurized in the direction of closing the second flow passage 21 by the pressure of the gas, and the second passage 21 is stepped inward to contact the stem 30.

In addition, the second passage 21 may further include rubber or silicone made of an elastic material that presses the stem 30 in the direction in which the stem 30 closes the second passage 21.

The coupling 40 is screwed to the second body 20.

The third body 50 is coupled to the coupling 40 and has a third flow path 51. The third flow path 51 is formed inside the third body 50 and communicates or releases communication with the second flow path 21 by pressing or releasing the stem 30 by the rotation of the coupling 40. It is characterized by.

The pressure gauge 60 communicates with the third flow path 51 and measures the pressure of the injected gas.

In addition, the third body 50 has a pressing portion 52 in contact with or released from the stem 30 in the third flow path 51. As a result, when the coupling 40 is tightened to the second body 20, the pressing unit 52 presses the stem 30, and when the coupling 40 is loosened from the second body 20, the pressing unit ( 52 depressurizes the stem 30.

Therefore, when the coupling 40 is completely tightened to the second body 20, the third passage 51 communicates with the second passage 21 so that the gas reaches the pressure gauge 60 side. In addition, when the coupling 40 is loosened from the second body 20, the third passage 51 is closed with the second passage 21 so that the gas does not reach the pressure gauge 60.

In addition, a first vent 41 for gas venting is formed in the coupling 40. In addition, the second body 20 is formed with a second hole 22 in communication with or released from the first hole 41 by the rotation of the coupling 40.

That is, when the coupling 40 is completely tightened to the second body 20 or loosened within a predetermined range, the first hole 41 is not in communication with the second hole 22, and thus, the first passage 51 does not communicate with the second body 20. The gas is not released to the outside. However, when the coupling 40 is released beyond the predetermined range in the second body 20, the first hole 41 communicates with the second hole 22 so that the gas in the third flow path 51 is discharged to the outside. Will be.

Therefore, when the coupling 40 is unwound from the second body 20 by more than a predetermined range, the stem 30 closes the second passage 21 so that the second passage 21 and the third passage 51 are closed. They are blocked from each other, and the gas in the second flow passage 21 is disconnected from the third flow passage 51 side. In this case, the gas in the third passage 51 is vented to the outside through the first hole 41 and the second hole 22, so that the contact test of the pressure gauge 60 can be performed.

As such, the gas valve for the circuit breaker according to the present invention is implemented in a monolithic valve structure, and there is no fear of gas leakage, the structure has a simple advantage, and the contact test is easily performed through a simple rotation operation of the coupling 40. It has a big advantage in that it is possible.

6A, 6B, and 6C illustrate fastening holes of a gas valve for a circuit breaker according to various embodiments of the present disclosure.

As shown in FIGS. 6A to 6C, a plurality of fastening holes 13 are radially formed in the first body 10, such that the pressure gauge 60 can be angled in the front-rear direction with respect to the tanker 11. It is preferable to arrange.

In addition, the second body 20 is rotatably fastened in a vertical direction with respect to the first body 10, so that the pressure gauge 60 is arranged to be angle-adjustable in the left-right direction with respect to the tanker 11.

Therefore, the pressure gauge 60 may be installed to enable free positioning in the front, rear, left, and right directions with respect to the tanker 11. As a result, since it is possible to install a gas valve to observe the pressure gauge from various angles through securing a small number of parts, it has a great advantage in terms of cost and convenience of use.

In addition, Figure 7 shows a gas valve for a circuit breaker according to another embodiment of the present invention.

As illustrated in FIG. 7, the first body 10 of the gas valve for the circuit breaker may have a rectangular shape. In addition, the flange portion of the first body 10 may be circular as in the above-described embodiment, it may be manufactured in other shapes.

In summary, the gas valve for the circuit breaker according to the present invention is not composed of a combination of a conventional ball valve or a bellows seal valve, but is composed of a combination of a non-return valve as described above and thus a contact of a gas gauge. Test functions and gas injection and discharge functions will be provided.

The gas valve for the circuit breaker according to the present invention has been described with reference to the embodiments shown in the drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope should be defined by the technical spirit of the appended claims.

10: first body 11: tanker
20: second body 21: second euro
30 stem 40 coupling
50: third body 51: third euro
60: pressure gauge

Claims (5)

A first body 10 fastened to a tanker 11 in which gas is accommodated and having a first flow path communicating with the tanker 11 therein;
A second body 20 coupled to the first body 10 and having a second passage 21 formed therein in communication with the first passage;
A stem 30 disposed slidably inside the second body 20 to open and close the second flow passage 21;
A coupling 40 screwed to the second body 20;
A third flow passage 51 coupled to the coupling 40 and communicating or releasing communication with the second flow passage 21 by pressing or releasing the stem 30 by the rotation of the coupling 40. Is formed third body 50; And
A gas valve for a circuit breaker, which is in communication with the third passage 51, and includes a pressure gauge 60 for measuring the pressure of the injected gas. The method according to claim 1,
The third body 50 has a pressing portion 52 in contact with or released from the stem 30 in the third flow path 51, so that the coupling 40 has the second body 20. The pressing portion 52 pressurizes the stem 30 and the pressing portion 52 pressurizes the stem 30 when the coupling 40 is loosened from the second body 20. Gas valve for a circuit breaker, characterized in that. The method according to claim 1,
The coupling 40 is formed with a gas vent first hole 41,
The second body (20) gas valve for a circuit breaker, characterized in that the second hole (22) which is in communication with or released from the first hole (41) by the rotation of the coupling (40) is formed. The method according to claim 1,
A plurality of fastening holes 13 are radially formed in the first body 10, and the pressure gauge 60 is disposed to be angle-adjustable in the front-rear direction with respect to the tanker 11. Gas valve. The method according to claim 1,
The second body 20 is rotatably fastened in a vertical direction with respect to the first body 10, the pressure gauge 60 is arranged to be adjustable in the left and right directions with respect to the tanker (11). A gas valve for a breaker, characterized in that.

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