KR101938189B1 - Leakage sensing system for gas-insulated switchgear of substation - Google Patents

Abstract

The present invention relates to a leakage sensing system for sensing insulation gas from a gas-insulated switchgear installed in a substation. The leakage sensing system includes: a sealing housing formed therein with a receiving space to accommodate a gas-insulated switchgear in the receiving space while sealing the gas-insulated switchgear from the outside, in which the receiving space is filled with gas different from insulation gas; a first sensor installed inside the gas-insulated switchgear to provide a sensing signal while sensing an internal pressure of the gas-insulated switchgear; a second sensor installed in the receiving space of the sealing housing to provide a sensing signal while sensing an internal pressure of the sealed housing; and a diagnosis unit for diagnosing whether there is leakage in the gas-insulated switchgear or the sealing housing and whether the first sensor or the second sensor is faulty based on the sensing signals of the first sensor and the second sensor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a leakage monitoring system for a gas insulated switchgear in a substation,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a leakage monitoring system, and more particularly, to a leakage monitoring system for a gas insulated switchgear in a substation that monitors leakage of insulated gas filled in a gas insulated switchgear installed in a substation.

Generally, a gas-insulated switchgear is installed in a substation or a power plant as one of devices for protecting electric power facilities.

The gas insulated switchgear is a device that protects the electric power facilities by opening and closing the current normally and by rapidly breaking the excessive current in the event of a fault.

More specifically, a gas insulated switchgear is provided with electric power facilities such as a circuit breaker, a disconnector, and a switch for opening and closing an electric circuit, and is filled with an insulated gas to ensure insulation between conductors.

As the insulating gas filled in the gas insulated switchgear, sulfur hexafluoride (SF ⁶ ) gas having excellent dielectric strength is used and filled with a predetermined pressure (3 to 7 bar) and sealed.

Sulfur hexafluoride gas is a harmful gas and is about 6 times heavier than air and has colorless and odorless characteristics. Therefore, when it leaks, it sinks on the floor of the indoor substation, There is a serious problem that the insulation of the opening and closing device is destroyed, causing a facility accident.

Therefore, the substation operates a surveillance system to check whether the insulation gas filled in the gas insulated switchgear leaks.

The existing leak monitoring system has a pressure sensor for detecting the internal pressure of the gas insulated switchgear and uses a method of outputting an alarm when it is determined that the gas is leaked when the sensed pressure deviates from the error range.

However, in the conventional leak monitoring system as described above, when the leak is detected by the pressure sensor, since the gas has already leaked to the outside, there is a problem that contamination inside the indoor substation due to the gas can not be prevented.

In addition, the existing leak monitoring system can detect only the leak of the gas, and can not detect the failure of the pressure sensor.

Therefore, a technique for solving the above-described problems is required.

On the other hand, the background art described above is technical information acquired by the inventor for the derivation of the present invention or obtained in the derivation process of the present invention, and can not necessarily be a known technology disclosed to the general public before the application of the present invention .

Embodiments disclosed herein are capable of detecting leakage of insulated gas from a gas insulated switchgear and preventing leakage of leaked insulated gas to the outside, thereby preventing a safety accident. Leakage monitoring for a gas insulated switchgear in a substation The purpose is to present the system.

In particular, it is an object of the present invention to provide a leakage monitoring system for a gas insulated switchgear in a substation that can diagnose whether or not an insulation gas is leaked together with a failure of the detection sensor.

In addition, the embodiments disclosed herein provide a leakage monitoring system for a gas insulated switchgear in a substation that can prevent a safety accident caused by trapped gas by collecting leaked insulated gas in a separate trapping space when leakage of an insulated gas There is a purpose.

According to an aspect of the present invention, there is provided a system for monitoring leakage of insulated gas in a gas insulated switchgear installed in a substation, the system comprising: A sealing housing for sealing the outside of the gas insulated switchgear while receiving the gas insulated switchgear in the accommodating space, the accommodating space being filled with a gas different from the insulated gas; A first sensor installed inside the gas insulated switch to provide a sensing signal while sensing an internal pressure of the gas insulated switch; A second sensor installed in a receiving space of the closed housing to provide a sensing signal while sensing an internal pressure of the sealed housing; And a diagnosis unit for diagnosing at least one of the leakage of the gas insulated switchgear or the closed housing and the failure of the first sensor or the second sensor based on the sensing signals of the first sensor and the second sensor .

For example, when the sensed pressure by the first sensor is equal to or lower than a predetermined value and the sensed pressure by the second sensor is equal to or higher than a set value, the diagnosis unit diagnoses the leakage of the gas insulated switch, Is normal and the sensed pressure by the second sensor is less than the set value, the leakage of the sealed housing can be diagnosed.

The diagnosis unit may diagnose the leakage of the gas insulated switchgear and the failure of the second sensor when the sensing pressure by the first sensor is less than the set value and the sensing pressure by the second sensor is normal.

The diagnosis unit may diagnose the leakage of the gas insulated switch and the failure of the first sensor when the sensed pressure by the first sensor is normal and the sensed pressure by the second sensor is equal to or higher than a set value.

The closed housing may further include an insulating gas collecting member for collecting and collecting the insulating gas leaking from the gas insulated switchgear by forcibly discharging the insulated gas.

According to any one of the above-mentioned means for solving the problems, it is possible to diagnose leakage of insulation gas through a plurality of detection sensors for sensing the pressure of insulation gas. Especially, when the outside of the gas insulation breaker is sealed by the closed housing, It is possible to propose a leakage monitoring system for a gas insulated switchgear in a substation that can prevent a safety accident by preventing the insulation gas from being diffused to the outside.

According to any one of the above-mentioned means for solving the above-mentioned problems, the diagnosis part can diagnose based on the detection signals of the first sensor and the second sensor based on the detection signals of the first sensor and the second sensor, A leakage monitoring system for a gas insulated switchgear may be proposed.

Further, according to any one of the above-mentioned means for solving the problems, since the gas inside the closed housing is forcibly discharged and collected by the insulating gas collecting member when the gas insulating breaker leaks, a gas in the substation A leakage monitoring system for an insulating switch may be proposed.

The effects obtained in the disclosed embodiments are not limited to the effects mentioned above, and other effects not mentioned are obvious to those skilled in the art to which the embodiments disclosed from the following description belong It can be understood.

1 is a configuration diagram showing a leakage monitoring system for a gas insulated switch according to an embodiment.
FIG. 2 is a table showing a form of diagnostic diagnosis of the leak monitoring system for a gas insulated switch according to an embodiment. FIG.
3 is a block diagram showing another embodiment of a leakage monitoring system for a gas insulated switchgear.

Various embodiments are described in detail below with reference to the accompanying drawings. The embodiments described below may be modified and implemented in various different forms. In order to more clearly describe the features of the embodiments, detailed descriptions of known matters to those skilled in the art are omitted. In the drawings, parts not relating to the description of the embodiments are omitted, and like parts are denoted by similar reference numerals throughout the specification.

Throughout the specification, when a configuration is referred to as being "connected" to another configuration, it includes not only a case of being directly connected, but also a case of being connected with another configuration in between. In addition, when a configuration is referred to as "including ", it means that other configurations may be included, as well as other configurations, as long as there is no specially contradicted description.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram showing a leakage monitoring system for a gas insulated switch according to an embodiment.

Referring to FIG. 1, a leakage monitoring system for a gas insulated switchgear according to an embodiment of the present invention is for monitoring leakage of insulated gas charged in a gas insulated switchgear 10 installed in a substation, and includes a closed housing 100, A sensor 200, a second sensor 300, and a diagnosis unit 400. [

Here, the gas insulated switchgear 10 is installed in a substation or a power plant to protect the electric power facility while opening and closing a current, and all the commonly used constructions can be applied.

For example, the gas insulated switchgear 10 includes power equipment 12 such as a disconnector, a ground switch, a circuit breaker, and the like installed inside a switch housing 11 formed in the form of a tank. Inside the switch housing 11, Can be charged.

Here, the insulating gas filled in the gas insulated switchgear 10 can be SF6 gas, and can be sealed after being filled in the switch housing 11 at a predetermined pressure (3 to 7 bar).

The closed housing 100 is a component for sealing the outside of the gas insulated switchgear 10 and ultimately has a structure for preventing the leakage gas from diffusing into the inside of the substation when the gas insulated switchgear 10 is leaked Element.

Specifically, the closed housing 100 is formed in the form of a tank having a receiving space therein to seal the outside of the gas insulated switchgear 10 by accommodating the gas insulated switchgear 10 in the accommodating space, It can be charged with pressure.

Here, the closed housing 100 may be filled with a harmless gas different from the insulating gas of the gas insulated switchgear 10, and may be charged at a pressure lower than the filling pressure of the gas insulated switchgear 10. This is to prevent the filling body of the closed housing 100 from flowing back to the gas insulated switchgear 10 when leakage of the gas insulated switchgear 10 occurs.

The first sensor 200 is a component for detecting the leakage of the gas insulated switch 10 by sensing the internal pressure of the gas insulated switchgear 10.

The first sensor 200 may be configured to detect pressure, and may be installed in the gas insulated switchgear 10 to sense the internal pressure of the gas insulated switchgear 10, And provides it to the diagnosis unit 400.

The second sensor 300 is a component for detecting leakage of the gas insulated switchgear 10 and the closed housing 100 by detecting the internal pressure of the closed housing 100 described above.

The second sensor 300 satisfies any configuration as long as it can sense the pressure. The second sensor 300 is installed inside the closed housing 100 to sense the internal pressure of the closed housing 100, (400).

The diagnosis unit 400 determines whether leakage of the gas insulated switchgear 10 and the closed housing 100 is detected based on the detection signals of the first sensor 200 and the second sensor 300, And diagnoses whether the second sensor 300 is malfunctioning or not.

Here, the diagnosis unit 400 may mean a hardware component such as software or a field programmable gate array (FPGA) or an ASIC, and is not limited to software or hardware.

For example, the diagnosis unit 400 may be configured to be in an addressable storage medium and configured to play back one or more processors. Thus, by way of example, the diagnostics 400 may include components such as software components, object-oriented software components, class components and task components, and processes, functions, Routines, subroutines, segments of program patent code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables.

Further, the functions provided in the diagnosis unit 400 may be combined with a smaller number of components or separated from additional components.

FIG. 2 is a table showing a form of diagnostic diagnosis of the leak monitoring system for a gas insulated switch according to an embodiment. FIG.

2, the diagnosis unit 400 determines whether or not the gas insulated switchgear 10 and the closed housing 100 are leaked based on the detection signals applied from the first sensor 200 and the second sensor 300 The diagnosis is made as to whether the first sensor 200 or the second sensor 300 has failed.

More specifically, the diagnosis unit 400 determines whether the sensing pressure of the gas insulated switchgear 10 applied by the first sensor 200 is equal to or lower than the set value, and the sensing pressure of the sealed housing 100 applied by the second sensor 300 It is possible to diagnose that the insulating gas of the gas insulated switchgear 10 has leaked.

If the sensing pressure of the gas insulated switchgear 10 applied by the first sensor 200 is in the normal range and the sensed pressure of the closed housing 100 applied by the second sensor 300 is set to a predetermined value, It is possible to diagnose that the filling gas of the closed housing 100 is leaked.

Here, the diagnosis unit 400 may include an alarm unit (not shown) to transmit the diagnosis result to a management server or a portable terminal of an administrator.

If the sensed pressure of the gas insulated switchgear 10 applied by the first sensor 200 is lower than the set value and the sensed pressure of the enclosed housing 100 applied by the second sensor 300 It is possible to diagnose that the insulation gas of the gas insulated switchgear 10 has leaked and that the failure of the second sensor 300 has occurred.

If the sensing pressure of the gas insulated switchgear 10 applied by the first sensor 200 is in the normal range and the sensed pressure of the closed housing 100 applied by the second sensor 300 is set to a predetermined value, It is possible to diagnose that the insulation gas of the gas insulated switchgear 10 has leaked and diagnose that the failure of the first sensor 200 has occurred.

3 is a configuration diagram showing another embodiment of a leakage monitoring system for a gas insulated switchgear.

3, an insulating gas collecting member 500 for collecting and collecting the insulating gas leaked from the gas insulated switchgear 10 by forcibly discharging the insulating gas to the outside of the closed housing 100 may be provided in the enclosed housing 100 have.

For example, the collecting member 500 may be configured to include a collecting tank 510, a collecting valve 520, and a forced exhaust fan 530.

The collecting tank 510 is installed adjacent to the closed housing 100 and is connected to the closed housing 100 through a collecting valve 520 to be described later and is leaked from the gas insulated switchgear 10 to the closed housing 100, It is possible to provide a space in which the insulating gas leaking into the space is forcibly collected.

The collecting valve 520 is a component for opening and closing the connecting passage while connecting the collecting tank 510 and the closed housing 100.

The collecting valve 520 can operate according to the diagnosis result of the diagnosis unit 400 described above. That is, the collecting valve 520 is normally kept closed, and when the diagnostic result by the diagnosis unit 400 is diagnosed as leakage of the gas insulated switchgear 10, it is opened to the closed housing 100 and the collecting tank 510).

The collecting valve 520 may be configured to operate remotely by the diagnosis unit 400 and may be configured to be manually opened and closed in an emergency situation.

The forced exhaust fan 530 is installed in the connection path between the collecting tank 510 and the closed housing 100 and connected to the collecting valve 520 according to the diagnosis result of the diagnosis unit 400, Can be forcibly evacuated to the collection tank (510).

Here, the diagnosis unit 400 operates the collecting valve 520 and the forced exhaust fan 530 at the time of diagnosing leakage of the gas insulated switchgear 10, and additionally, at the time of diagnosing leakage of the closed housing 100, And the forced exhaust fan 530 can be operated.

The operation and operation of the leakage monitoring system for a gas insulated switchgear in a substation including the above-described components will be described.

The diagnosis unit 400 receives the internal pressure sensing signal of the gas insulated switchgear 10 and the internal pressure sensing signal of the sealed housing 100 while communicating with the first sensor 200 and the second sensor 300.

When the sensing pressure applied from the first sensor 200 is equal to or lower than the set value and the sensing pressure applied from the second sensor 300 is equal to or higher than the set value, the diagnosis unit 400 determines that the insulating gas of the gas insulated switch 10 leaks When the sensed pressure applied from the first sensor 200 is in the normal range and the sensed pressure applied from the second sensor 300 is less than the set value, it is determined that the filled gas in the sealed housing 100 is leaked. do.

At this time, when the alarm unit is provided, the diagnosis unit 400 can transmit the diagnosed leakage information to the management server or the terminal of the manager.

In the case where the scavenging gas collecting member 500 is provided, the diagnosis unit 400 may open the collecting valve 520 and then operate the forced exhaust fan 530 so that the gas inside the enclosed housing is returned to the collecting tank 510 It can be exhausted.

When the sensing pressure applied from the first sensor 200 is less than the set value and the sensing pressure applied from the second sensor 300 is in the normal range, the diagnosis unit 400 determines that the insulated gas of the gas insulated switchgear 10 It is diagnosed that a failure of the second sensor 300 occurs.

When the sensing pressure applied from the first sensor 200 is in the normal range and the sensed pressure applied from the second sensor 300 is equal to or higher than the set value, the diagnosis unit 400 determines that the insulated gas of the gas insulated switchgear 10 It is diagnosed that a leak has occurred and that a failure of the first sensor 200 has occurred.

At this time, the diagnosis unit 400 also transmits the diagnosis result through the alarm unit and can exhaust the gas inside the closed housing to the collecting tank 510 through the collecting valve 520 and the forced exhaust fan 530.

As described above, according to the leakage monitoring system for a gas insulated switchgear in a substation according to an embodiment, it is possible to accurately diagnose leakage of insulation gas through the first sensor 200 and the second sensor 300, In particular, as the outside of the gas insulated switchgear 10 is sealed by the closed housing 100, the leaked insulated gas is prevented from diffusing to the outside, thereby preventing a safety accident.

It will be apparent to those skilled in the art that the above-described embodiments are for illustrative purposes only and that those skilled in the art will readily understand that various changes and modifications can be made without departing from the spirit or scope of the present invention. You will understand. It is therefore to be understood that the above-described embodiments are to be considered in all respects only as illustrative and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

It is to be understood that the scope of the present invention is defined by the appended claims rather than the foregoing description and should be construed as including all changes and modifications that come within the meaning and range of equivalency of the claims, .

10: gas insulated switchgear
11: Actuator housing
12: Electric power equipment
100: Sealed housing
200: first sensor
300: second sensor
400:
500: insulated gas collecting member
510: collection tank
520: collection valve
530: Forced exhaust fan

Claims (4)

A system for monitoring insulation gas leakage in a gas insulated switchgear installed in a substation,
Wherein the gas insulated switchgear is accommodated in the accommodating space to seal the outside of the gas insulated switchgear and a gas other than the insulating gas is supplied to the accommodating space at a pressure lower than the filling pressure of the gas insulated switchgear A sealed housing to be charged;
A first sensor installed inside the gas insulated switch to provide a sensing signal while sensing an internal pressure of the gas insulated switch;
A second sensor installed in a receiving space of the closed housing to provide a sensing signal while sensing an internal pressure of the sealed housing;
A diagnosis unit for diagnosing at least one of a leakage of the gas insulated switchgear or the closed housing and a failure of the first sensor or the second sensor based on a sensing signal of the first sensor and the second sensor;
A collecting tank connected to the closed housing to provide a space for collecting the insulating gas leaked from the gas insulated switch to the closed housing;
A collecting valve that connects the collecting tank and the closed housing and opens and closes the connection passage between the collecting tank and the closed housing according to a diagnosis result of the diagnosis unit; And
And a forced exhaust fan installed in a connection path between the collection tank and the closed housing for forcibly discharging the internal gas of the closed housing to the collection tank in cooperation with the collection valve according to a diagnosis result of the diagnosis unit,
Wherein the diagnosis unit comprises:
A leakage monitoring system for a gas insulated switchgear in a substation for diagnosing leakage of the gas insulated switchgear and failure of the second sensor when the sensed pressure by the first sensor is less than a set value and the sensed pressure by the second sensor is normal, .
The method according to claim 1,
Wherein the diagnosis unit comprises:
Wherein when the sensed pressure by the first sensor is equal to or lower than a predetermined value and the sensed pressure by the second sensor is equal to or greater than a set value, the sensed pressure by the first sensor is normal, A leakage monitoring system for a gas insulated switchgear in a substation diagnosed by leakage of the enclosed housing when the sensing pressure by the sensor is less than a set value.
delete The method according to claim 1,
Wherein the diagnosis unit comprises:
A leakage monitoring system for a gas insulated switchgear in a substation for diagnosing a leakage of the gas insulated switchgear and a failure of the first sensor when the sensed pressure by the first sensor is normal and the sensed pressure by the second sensor is not less than a set value .

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