KR102089180B1 - Apparatus for diagnosing partial discharge of gas insulated switchgear - Google Patents

Abstract

The present invention relates to a partial discharge diagnosis device for a gas insulation switchgear, which comprises a dummy plug (100) installed in a power outlet (3) of a gas insulation switchgear (1) to maintain insulation from the outside and a partial discharge diagnosis sensor (200) installed in the dummy plug (100) and detecting an electromagnetic signal generated when an internal defect occurs in the gas insulation switchgear (1). In the present invention, limitations of the performance of a built-in UHF sensor of the gas insulation switchgear currently in operation are complemented, and a gas insulation switchgear having a structure in which an internal signal cannot be emitted to the outside due to no epoxy-exposed insulating material enables the determination of a place of partial discharge generation.

Description

Partial discharge diagnosis device for gas insulated switchgear {APPARATUS FOR DIAGNOSING PARTIAL DISCHARGE OF GAS INSULATED SWITCHGEAR}

The present invention relates to a partial discharge diagnostic device for a gas insulated switchgear, and more particularly, to a partial discharge diagnostic device for a gas insulated switchgear for detecting an electromagnetic signal that appears when an abnormal symptom occurs due to an internal defect of the gas insulated switchgear.

Power devices such as gas insulated switchgear (GIS) generate partial discharge when an insulation problem occurs in the device. Due to partial discharge, various phenomena such as electromagnetic waves, high-frequency current, sound, and vibration occur, which can be measured to diagnose the insulation state of the device.

For example, the electromagnetic waves that appear when an internal defect in the gas insulated switchgear occurs are not emitted to the outside due to the metal shell of the gas insulated switchgear, and internal reflections and refractions proceed. Built-in UHF partial discharge detection sensor (hereinafter referred to as "UHF sensor") or epoxy insulation Emitted to the material part, it is possible to detect the partial discharge signal through an external UHF sensor.

1 shows a position where a UHF sensor is installed in a 170 kV gas insulated switchgear.

However, since the UHF sensor shown in FIG. 1 is a built-in sensor installed inside a 170 kV gas insulated switchgear, due to the limitations of the built-in sensor performance, the partial discharge signal generated at a long distance gradually attenuates the signal size during propagation, and thereby the built-in type There is a problem that the sensor cannot be reached.

In addition, the 25.8kV gas insulated switchgear has a great problem in terms of stable equipment maintenance because it is impossible to externally discharge the internal defect signal due to the inherent design characteristics of the equipment without externally exposed epoxy insulation.

In addition, when the gas insulated switchgear is installed for the first time, the commercial frequency withstand voltage, which is a test procedure for integrity, and a dummy plug made of a metal cover is pressed at the end in the no-load pressurization test, so the partial discharge signal due to internal defects is blocked at the source. There is a problem in that it is difficult to find the initial defects in power facilities.

If an abnormality occurs in the gas insulated switchgear, it can seriously damage the entire power system, so it is necessary to improve the reliability of partial discharge detection.

Patent Document 1: Registered Patent Publication No. 0757075 (Registered on Sep. 2007)

The object of the present invention is to compensate for the limitations of the performance of the gas insulated switchgear built-in sensor currently in operation, and to solve the structural problem that the internal signal cannot be released to the outside because there is no epoxy exposed insulating material. Is to provide

According to a feature of the present invention for achieving the above object, the present invention is installed on the power outlet of the gas insulated switchgear and is installed on the dummy plug and the dummy plug to maintain insulation from the outside, and when an internal defect occurs in the gas insulated switchgear And a partial discharge diagnostic sensor that detects the electromagnetic signal.

The dummy plug is inserted into the power outlet of the gas insulated switchgear, is connected to the insulated body disposed in the gas insulated switchgear and connected to the insulated body, is provided with a cable connection, and is disposed outside the gas insulated switchgear to provide the gas insulated switchgear. And an insulating cover fixed with a fixing bolt.

The partial discharge diagnosis sensor is disposed in the insulating body and receives a UHF antenna for receiving a partial discharge signal in the UHF band caused by an internal defect of the gas insulated switchgear, a connector connector connected to the cable connection part, and a UHF antenna received by the UHF antenna. And a coaxial cable for transmitting a partial discharge signal to a diagnostic device and a signal transmission connection portion for transmitting a partial discharge signal to the connector, and for transmitting the partial discharge signal to a diagnostic device.

The UHF antenna includes a signal receiver and a plurality of signal receivers radially disposed on the signal receiver, and a signal extractor connected to the signal transmission connector and the signals coming into the signal receiver.

The connector portion is an N-type connector, and the cable connection portion is an N-type connector connection portion corresponding to the N-type connector.

The N-type connector is a conductor of the connector body and the coaxial cable that are fixed with connector fastening bolts at the edges of the N-type connector connection part, is connected to the core conductor and the core conductor inserted into the connector body, and protrudes from the connector body. And a connector pin inserted into the cable connection portion and connected to the signal transmission connection portion.

It is formed to connect the signal output portion and the cable connection portion, and includes a signal transmission portion protection tube to protect the connector pin connected to the signal transmission connection portion and the signal transmission connection portion.

The coaxial cable and the N-type connector are connected by an antenna adapter.

A surge arrester is connected to the antenna adapter.

The surge arrester is connected to a ground wire.

When the connector fastening bolt is loosened, the connector pin is separated from the signal transmission connection part.

When testing the integrity of the gas insulated switchgear, connect the connector to the cable connection section to check the electromagnetic signal that appears when an internal defect occurs in the gas insulated switchgear.

It further includes a built-in UHF sensor installed inside the gas insulated switchgear.

The present invention is to install a partial discharge diagnostic sensor for detecting an electromagnetic signal that appears when an internal defect occurs in a gas insulated switchgear in a dummy plug installed at the power outlet of the gas insulated switchgear, so that the electromagnetic signal in the partial discharge can be transmitted to external diagnostic equipment. .

Therefore, the present invention is capable of determining the location of the partial discharge occurrence of the 25.8 kV gas insulated switchgear having no externally exposed insulating material, and enables more accurate determination of the source when tracking the location of the partial discharge.

In addition, the present invention is capable of detecting a long-distance partial discharge signal exceeding the reception range of a 170kV gas insulated switchgear built-in UHF sensor, and can increase the diagnostic effect of partial discharge and maximize the diagnostic reliability through overlapping diagnosis with the built-in UHF sensor. It works.

Therefore, the present invention complements the limitations of the performance of the built-in UHF sensor of the gas insulated switchgear currently in operation, and it is possible to determine the location of the partial discharge occurrence of the gas insulated switchgear in which the internal signal cannot be emitted to the outside because there is no epoxy exposed insulating material. It works.

1 is a view showing a position where a built-in UHF sensor is installed in a 170kV gas insulated switchgear.
2 is a view showing a state in which a partial discharge diagnostic device for a gas insulated switchgear according to the present invention is installed in a 170kV gas insulated switchgear.
Figure 3 is a cross-sectional view showing a partial discharge diagnostic device for a gas insulated switchgear according to the present invention.
Figure 4 is a bottom view showing the cable connection provided in the insulating cover according to the present invention.
Figure 5 is a cross-sectional view showing a partial discharge diagnostic sensor according to the present invention.
6 is a plan view showing a UHF antenna according to the present invention
7 is a cross-sectional view showing a state in which the connector connection portion is separated from the cable connection portion in the gas insulated switchgear partial discharge diagnosis apparatus according to the present invention.
8 is a view showing a state in which a partial discharge diagnostic device for a gas insulated switchgear according to the present invention is installed in a 25.8kV gas insulated switchgear.

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

The partial discharge diagnosis device for the gas insulated switchgear of the present invention is installed in the dummy plug 100 installed in the power outlet 3 of the gas insulated switchgear 1.

The dummy plug 100 is installed at the power outlet 3 of the gas insulated switch 1 to maintain insulation from the outside. In detail, the dummy plug 100 prevents the power outlet 3 from being pressurized when the gas insulation switch 1 is tested for integrity.

The gas insulation switch 1 performs a soundness test accompanied by an electrical insulation test at the time of factory shipment and after installation on site. During the soundness test, a charging voltage is applied to the gas insulated switchgear 1. At this time, a dummy plug 100 is installed at the power outlet 3 to prevent a person and a facility accident due to a ground fault.

The power outlet 3 is a power cable connection portion to which the power cable is connected, and after the integrity test, the dummy plug 100 blocking the power outlet 3 is removed and a power cable (not shown) is connected to the power outlet 3. .

The dummy plug 100 is provided with a partial discharge diagnosis sensor 200 capable of detecting an electromagnetic signal that appears when an internal defect occurs in the gas insulated switchgear 1.

During the integrity test of the gas insulated switchgear, the partial discharge diagnosis sensor 200 installed in the dummy plug 100 detects an electromagnetic wave signal that appears when an internal defect occurs in the gas insulated switchgear 1. The electromagnetic signal detected by the partial discharge diagnostic sensor 200 is transmitted to the diagnostic equipment 300. The diagnostic equipment 300 may analyze the electromagnetic wave signal to perform the insulation state diagnosis of the defect and risk of the gas insulated switchgear.

To this end, as shown in FIG. 3, the dummy plug 100 includes an insulating body 110 and an insulating cover 120. The insulating body 110 is inserted into the power outlet 3 of the gas insulated switchgear 1 and is disposed inside the gas insulated switchgear 1. The insulating body 110 may be formed in a cylindrical shape.

The insulating cover 120 is connected to the insulating body 110 and is disposed outside the gas insulating switch 1 and is fixed by the gas insulating switch 1 and the fixing bolt 130. In the embodiment, the dummy plug 100 is fixed to the gas insulation switch 1 with three fixing bolts 130. The fixing bolt 130 is inserted into the insulating outlet 110 of the dummy plug 100 in the electric power outlet 3 of the gas insulating switch 1, and then is inserted into the gas insulating switch 1 so that the insulating body 110 does not deviate. Fix firmly. The fixing bolt 130 may be of a screw bolt type.

The insulating body 110 and the insulating cover 120 serve to maintain an insulating state so that high voltage generated when charging the internal conductor of the gas insulating switch 1 is not induced in the enclosure of the gas insulating switch 1.

As shown in Figure 4, the cable cover 121 is provided on the insulating cover 120. The cable connector 121 is detachably connected to a connector 240 for drawing out an electromagnetic signal when an internal defect occurs in the gas insulator 1.

As shown in FIG. 5, the partial discharge diagnosis sensor 200 includes a UHF antenna 210, a signal transmission connection unit 220, a signal transmission protection tube 230, a connection connector 240, and a coaxial cable 250 do.

The UHF antenna 210 is disposed within the insulating body 110. The UHF antenna 210 detects a partial discharge signal in the UHF frequency band caused by an internal defect in the gas insulated switchgear 1.

When the partial discharge occurs, the UHF frequency band (300MHz ~ 3GHz) has a relatively low noise effect compared to the VHF band (30Mhz ~ 300Mhz), so it is highly reliable for diagnosing insulation problems when detecting.

The UHF antenna 210 includes a signal receiving plate 211, a signal receiving unit 212, and a signal extraction unit 214. The signal receiving plate 211 is formed in a disc shape.

As shown in FIG. 6, the signal receiving unit 212 includes a plurality of radially arranged signal receiving plates 211. The signal extraction unit 214 is a signal input to the signal receiving unit 212 is aggregated and is connected to the signal transmission unit protection tube 230. The signal extraction unit 214 is formed at the center of the signal receiving plate 211.

The signal receivers 212 are made of a conductor, and the conductors are connected to each other through a conductor 213 and also to a signal extractor 214 through a conductor 213. The signal receiving plate 211 is a dielectric substrate, the signal receiving unit 212 is a conductor printed on the dielectric substrate, and the conductor can be electrically connected through a conductor 213 printed on the dielectric substrate.

When the signal receivers 212 disposed on the signal receiving plate 211 receive a partial discharge signal in the UHF frequency band, which is a characteristic high frequency when partial discharge occurs, the partial discharge signal received by the signal receiver 212 is connected to the conductor 213. Through this, it can be integrated into the signal extraction unit 214.

As shown in FIG. 5, the signal extraction unit 214 is connected to the signal transmission connection unit 220. The signal transmission connection unit 220 transmits the partial discharge signal received by the UHF antenna 210 to the connection unit connector 240. The signal transmission connection unit 220 has a structure in which a connector pin of an N-type connector is inserted into and connected to a terminal of the signal extraction unit (signal transmission conductor) 214 of the UHF antenna 210.

The signal transmission unit protection pipe 230 is formed to connect the signal extraction unit 214 and the cable connection unit 121. The signal transmission part protection pipe 230 protects the signal transmission connection part 220 and the connector pin 243 connected to the signal transmission connection part 220. The signal transmission connection unit 220 and the connector pin 243 are conductors that transmit electromagnetic signals received by the UHF antenna 210 to the connection unit connector 240, and the signal transmission protection tube to prevent external contact and damage of the conductor 230 is provided. The signal transmission part protection pipe 230 may be made of an insulating material.

The connector 240 is connected to the cable connector 121. The UHF antenna 210, the signal transmission connection part 220 and the cable connection part 121 are built in the dummy plug 100, and the connection part connector 240 is connected to the cable connection part 121 of the dummy plug 100 if necessary. The UHF antenna 210 may transmit the electromagnetic signal of the partial discharge received to the outside.

The connector 240 is an N-type connector, and the cable connection 121 is formed of an N-type connector connection corresponding to the N-type connector 240. The connector 240 employs an N-type connector to minimize loss of the frequency signal received from the UHF antenna 210 and securely fix it with external connection accessories.

The cable connection part 121 is formed in a shape in which the connector pin 243 of the N-type connector 240 can be inserted. A hole 123 through which a connector fastening bolt 245 for firmly fixing the N-type connector 240 to the dummy plug 100 is formed is formed at an edge of the cable connection part 121.

The N-type connector 240 has a structure including a connector body 241, a core conductor 242, and a connector pin 243.

The connector body 241 is fixed to the edge of the N-type connector connection portion 121 with a connector fastening bolt 245. The core conductor 242 is a core conductor of the coaxial cable 250 and is fixed by being inserted into the connector body 241. The connector pin 243 is connected to the core conductor 242 by soldering or the like and protrudes from the connector body 241. The connector pin 243 is inserted into the cable connection portion 121 and is electrically connected to the signal transmission connection portion 220.

The connector pin 243 and the core conductor 242 are for transmitting the signal received by the UHF antenna 210 to the external diagnostic equipment 300.

The coaxial cable 250 is connected to the connector 240, that is, the N-type connector, and transmits a partial discharge signal to the diagnostic device 300. Since the partial discharge signal received from the UHF antenna 210 is a high frequency band, a coaxial cable 250 with low signal loss is used.

The coaxial cable 250 and the N-type connector 240 are connected to the antenna adapter 260. The antenna adapter 260 is for connecting the N-type connector 240, the coaxial cable 250, and the surge arrester 270. The antenna adapter 260 is made of a sturdy stainless material whose outer shell is not damaged by external impact.

One end of the antenna adapter 260 is connected to the N-type connector 240 through the adapter connector 261, and the other end of the antenna adapter 260 is connected to the coaxial cable 250 through the coaxial cable connector 262. The adapter connection portion 261 securely fixes the N-type connector 240 and the antenna adapter 260, and the N-type connector 240 and the antenna adapter 260 in order to prevent conductor damage of the N-type connector 240. It plays a role in keeping the fixed state firmly. The coaxial cable connector 262 is for firmly connecting the coaxial cable 250 to the antenna adapter 260.

A surge arrester (Surge-arrester) 270 is connected to the antenna adapter 260. The surge arrester 270 serves to emit high voltage when it is introduced to prevent damage to humans and diagnostic equipment due to accidental high voltage in addition to electromagnetic signals received through the UHF antenna 210.

The surge arrester 270 is connected to the ground wire 271. The grounding conductor 271 is a wire that discharges high voltage flowing into the surge arrester 270 and induced voltage flowing from the outside of the antenna adapter 260 to the ground.

The connector 240, the antenna adapter 260, the coaxial cable 250, and the surge arrester 270 are formed as one body and are detachable from the dummy plug 100 equipped with the UHF antenna.

As shown in FIG. 7, when the connector fastening bolt 245 of the connector 240 is loosened, the connector pin 243 is drawn out from the cable connection part 121 of the dummy plug 100 and is electrically connected to the signal transmission connection part 220. Is separated. Therefore, if necessary, the connector 240 can be separated from the cable connector 121.

On the other hand, the partial discharge diagnostic device for the gas insulated switchgear may further include a built-in UHF sensor (reference numeral 5 in FIG. 2) installed inside the gas insulated switchgear.

The gas insulating switch shown in FIG. 2 is a 170 kV gas insulating switch. The 170kV gas insulation switch is equipped with a built-in UHF sensor (5). In this case, the partial discharge diagnosis sensor 200 installed in the dummy plug 100 installed in the power outlet 3 detects the remote partial discharge signal exceeding the reception range of the built-in UHF sensor 5, and the built-in UHF sensor The diagnosis effect and reliability can be maximized through (5) and overlapping diagnosis.

The gas insulating switch shown in FIG. 8 is a 25.8 kV gas insulating switch. The 25.8kV gas insulated switchgear 1 'does not have a built-in UHF sensor and has no externally exposed insulation. In this case, the dummy plug 100 installed at the power outlet 3 ′ serves as an externally exposed insulation, and the partial discharge diagnosis sensor 200 installed on the dummy plug 100 detects a partial discharge signal and generates partial discharge. Make it possible to judge the location. Therefore, it is possible to more accurately determine the source of occurrence when tracking the partial discharge position.

Hereinafter, the operation of the present invention will be described.

2 and 3, the present invention is installed at the power outlet 3 of the gas insulated switchgear 1 and connected to the cable connection portion 121 of the dummy plug 100 incorporating the UHF antenna 210. By connecting the connector 240, it is possible to detect an electromagnetic wave signal that appears when an internal defect occurs in the gas insulator 1.

The UHF antenna 210 embedded in the dummy plug 100 receives an electromagnetic wave signal in an ultra-high frequency (UHF) frequency band that appears when an abnormal symptom occurs due to an internal defect of the gas insulated switchgear. In the UHF antenna 210, the signal receiving unit 212 made of sensors is radially arranged on the original plate to facilitate reception of the electromagnetic wave signal.

In addition, the signal receiving units 212 are connected to each other by a conducting wire, and received electromagnetic signals may be aggregated into the signal extraction unit 214.

The electromagnetic wave signal collected by the signal extraction unit 214 is a core wire of the N-type connector 240 through a connector pin 243 connected to the signal transmission connection unit 220 which is an end of the signal extraction unit (signal transmission conducting wire) 214. It is sent to the diagnostic equipment 300 through the conductor 242 and the coaxial cable 250 connected thereto.

During this process, surge arresters and ground wires discharge UHF antennas or high voltage from outside to prevent damage to people or diagnostic equipment.

On the other hand, in the partial discharge diagnosis sensor 200, when the connector fastening bolt 245 is loosened, the connector pin 243 is separated from the signal transmission connection part 220, so that it is possible to attach and detach as necessary.

For example, when the power outlet 3 is three-phase, the dummy plug 100 equipped with the UHF antenna is installed for each phase, and the connector pin 243 of the N-type connector 240 is installed in the signal transmission connection part 220 for each phase. It is possible to test by phase and measure abnormality by connecting.

In this way, in the integrity test of the gas insulated switchgear 1, the connector pin 243 of the N-type connector 240 is connected to the signal transmission connection part 220 of the dummy plug 100 installed for each phase to perform the integrity test. can do.

The above-described present invention can overcome the limitations of the performance of the built-in UHF sensor of the gas insulated switchgear currently in operation, and solve the problem in the case of a structure in which an internal signal cannot be emitted to the outside because there is no epoxy exposed insulating material.

In addition, the present invention can detect the partial discharge signal generated by internal defects during the commercial frequency withstand voltage and no-load pressurization test when the gas insulator is installed for the first time, thereby contributing to maintenance and failure prevention before or after commercial or use of the facility.

In addition, the present invention can determine the location of the partial discharge occurrence of the 25.8kV gas insulated switchgear having no externally exposed insulating material, and enables more accurate determination of the source when tracking the location of the partial discharge.

In addition, the present invention can detect a long-distance partial discharge signal exceeding the reception range of the 170kV gas insulated switchgear built-in UHF sensor, and can increase the diagnostic effect and maximize the diagnostic reliability through overlapping diagnosis with the built-in UHF sensor.

The present invention has been described with the best embodiments in the drawings and specifications. Here, although specific terms are used, they are used for the purpose of describing the present invention only, and are not used to limit the scope of the present invention described in the meaning limitation or the claims. Therefore, the present invention will be understood by those of ordinary skill in the art that various modifications and other equivalent embodiments are possible. Therefore, the true technical scope of the present invention should be defined by the technical spirit of the appended claims.

1: Gas insulation switch 3: Power outlet
5: UHF sensor 10: Partial discharge diagnosis device
100: dummy plug 110: insulated body
120: insulation cover 121: cable connection (N-type connector connection)
130: fixing bolt 200: partial discharge diagnostic sensor
210: UHF antenna 211: signal receiving plate
212: signal receiver 213: conductor
214: signal extraction unit 220: signal transmission connection unit
230: signal transmission section protection tube 240: connector (N-type connector)
241: connector body 242: core conductor
243: connector pin 245: connector fastening bolt
250: Coaxial cable 260: Antenna adapter
261: adapter connection 262: coaxial cable connector
270: surge arrester 271: ground wire
300: diagnostic equipment

Claims (13)

A dummy plug installed at the power outlet of the gas insulated switch to maintain insulation from the outside;
A partial discharge diagnosis sensor installed on the dummy plug and detecting an electromagnetic signal that appears when an internal defect occurs in the gas insulated switchgear;
Including,
The dummy plug
An insulating body inserted into the power outlet of the gas insulated switchgear and disposed inside the gas insulated switchgear; And
An insulating cover which is connected to the insulating body, is provided with a cable connection part, and is disposed outside the gas insulating switch and fixed with the gas insulating switch and a fixing bolt;
It includes,
The partial discharge diagnostic sensor
A UHF antenna disposed in the insulating body and receiving a partial discharge signal in the UHF band caused by an internal defect of the gas insulated switchgear;
A connector connector connected to the cable connector;
A signal transmission connection unit for transmitting the partial discharge signal received by the UHF antenna to the connection unit connector; And
A coaxial cable connected to the connector to transmit the partial discharge signal to diagnostic equipment;
Including,
The connector connector is an N-type connector,
The cable connection portion is an N-type connector connection portion corresponding to the N-type connector,
The N-type connector
A connector body fixed with a connector fastening bolt to an edge of the N-type connector connection portion;
A core wire conductor which is a conductor of the coaxial cable and is inserted into the connector body; And
A connector pin connected to the core conductor and protruding from the connector body and inserted into the cable connection portion to be connected to the signal transmission connection portion;
It includes,
The coaxial cable and the N-type connector are connected by an antenna adapter,
A surge arrester is connected to the antenna adapter,
The surge arrester is a partial discharge diagnostic device for a gas insulated switchgear, characterized in that the ground wire is connected. delete delete The method according to claim 1,
The UHF antenna
Signal receiving plate;
A plurality of signal receivers radially disposed on the signal receiver plate; And
A signal extracting unit in which a signal coming into the signal receiving unit is collected and connected to the signal transmitting connecting unit;
Partial discharge diagnostic device for a gas insulated switchgear comprising a. delete delete The method according to claim 1,
It is formed to connect the signal outlet and the cable connection,
And a signal transmission part protection pipe protecting a connector pin connected to the signal transmission connection part and the signal transmission connection part. delete delete delete The method according to claim 1
Partial discharge diagnosis device for a gas insulated switchgear, characterized in that when the connector fastening bolt is loosened, the connector pin is separated from the signal transmission connection part. The method according to claim 1
A partial discharge diagnostic device for a gas insulated switchgear, characterized in that, during the soundness test of the gas insulated switchgear, the connection part connector is connected to the cable connection part to check the electromagnetic signal generated when an internal defect occurs in the gas insulated switchgear. The method according to claim 1
A partial discharge diagnostic device for a gas insulated switchgear, further comprising a built-in UHF sensor installed inside the gas insulated switchgear.

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