KR101496588B1 - Partial discharge detecting device for gas insulated switchgear - Google Patents

Abstract

The present invention relates to a partial discharge detecting device for a gas insulated switchgear. The partial discharge detecting device including an antenna which detects a partial discharge signal generated in a gas insulated switchgear comprises: a cover which is coupled to one side of an outer enclosure of the gas insulated switchgear; a case which is disposed between the outer enclosure and the cover to accommodate the antenna therein; a connector which is coupled to an inner surface of the cover and electrically connected to the antenna in the case; a first sealing member which is disposed between the cover and the connector; a probe which is coupled to the inner surface of the cover and inserted into the case to detect a phase signal within the outer enclosure; a second sealing member which is disposed between the cover and the probe; and a third sealing member which is disposed outside the case above the cover to shield internal and external electromagnetic waves of the gas insulated switchgear. The first to third sealing members can prevent an insulation gas or electromagnetic waves from leaking from the inside to the outside of the gas insulated switchgear.

Description

TECHNICAL FIELD [0001] The present invention relates to a partial discharge detection device for a gas insulated switchgear,

The present invention relates to a partial discharge detecting apparatus for a gas insulated switchgear, and more particularly, to a gas discharge apparatus for a gas insulated switchgear, in which a high voltage gas is used as an insulated medium in a power plant or a substation, The present invention relates to a partial discharge detecting device for a gas insulated switchgear capable of detecting an internal deterioration or a partial discharge due to electric field concentration and preventing leakage of an insulating gas and an electromagnetic wave to the outside.

Generally, in a power system, insulation deterioration occurs due to mechanical stress, temperature, and the like, and a partial discharge is generated in the internal insulation portion. Such partial discharges can cause the power plant to fail if it occurs for a sustained period of time, even if there is no problem with the performance and operation of the system initially, and in the extreme case, it may lead to an explosion.

Accordingly, a gas insulated switchgear (GIS) in which a bus bar, a breaker, a disconnector, and the like are disposed in a steel container and a high-pressure gas (SF6) serving as an insulating medium is filled and sealed is used. The gas insulated switchgear is widely used in power plants and substations because it has the advantages of high insulation strength and compactness due to enclosure, high reliability and simplification of maintenance.

However, protrusions, spacer cracks, and conductive metal foreign substances may occur during the operation or operation of the gas insulated switchgear. Such defects cause the electric field concentration phenomenon in the gas insulated switchgear, and there is a possibility that the partial discharge occurs at the electric field concentrated region to reach the insulation breakdown.

Partial discharges are caused by internal defects in the gas insulated switchgear, and are not caused between the electrodes and the electrodes, and discharge occurs in any one of them, collectively referred to as corona discharge, void discharge and surface discharge. In addition, the partial discharge is applied as a factor that can identify the cause of the defect or the position of the defect.

Accordingly, in order to prevent an accident caused by breakage of the power equipment, a partial discharge detection device for detecting a partial discharge signal and determining an abnormal symptom from the partial discharge signal is applied. Such a partial discharge detecting apparatus is classified into an external type or an internal type.

Here, the gas insulated switchgear is composed of a plurality of metal circular waveguides and a plurality of spacers for connecting the circular waveguides to divide the insulating gas compartment or for easy maintenance work. The external partial discharge detecting device is generally provided on the outer peripheral surface of the spacer. The external partial discharge detection device can measure the partial discharge phenomenon inside the gas insulated switch by measuring the electromagnetic wave internally when the partial discharge is generated to the outside through the spacer.

The built-in partial discharge detection device can detect a partial discharge phenomenon caused by insulation deterioration or electric field concentration in the inside of the enclosure by being installed inside the enclosure of the gas insulated switchgear. An example of such a built-in partial discharge detecting device is disclosed in Korean Patent Registration No. 10-0864066.

When the insulated gas SF6 of the gas insulated switchgear is leaked, there is a possibility that the dielectric strength (insulation performance) inside the gas insulated switchgear may be lowered. Insulation gas (SF6), which is filled in the interior of a gas insulated switchgear, is a typical greenhouse gas. The global warming index of insulated gas (SF6) (when the degree of contribution of carbon dioxide to global warming is 1, the same amount of greenhouse gas Contributing to global warming) is an average of 22,000 times higher than carbon dioxide. Therefore, the partial discharge detection device of the gas insulated switchgear must ensure the airtightness performance so that the insulating gas (SF6) is not leaked inside the gas insulated switchgear.

Further, the partial discharge detecting device of the gas insulated switchgear can malfunction when the interception of electromagnetic waves inside and outside is unstable. That is, the partial discharge detecting device may malfunction when the electromagnetic wave generated in the gas-insulated switchgear flows out to the outside or when the electromagnetic wave flows into the inside from the outside of the gas-insulated switchgear. Therefore, the partial discharge detecting device may fail to detect the partial discharge inside the gas insulated switchgear.

Korean Patent No. 10-0864066 (Jul. 21, 2008).

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a partial discharge detecting apparatus for a gas insulated switchgear capable of preventing an insulating gas filled in a gas insulated switchgear from leaking through a partial discharge detecting apparatus .

The present invention also relates to a partial discharge detection device of a gas insulated switchgear capable of preventing an insulated gas filled in a gas insulated switchgear from flowing out to the outside or flowing outside air into a gas insulated switchgear through a partial discharge detection device, The purpose of this paper is to provide

According to an aspect of the present invention, there is provided a partial discharge detection apparatus including an antenna for sensing a partial discharge signal generated in a gas insulation switch, the cover comprising: a cover coupled to one side of an enclosure of the gas insulation switch; A case interposed between the enclosure and the cover and housing the antenna therein; a connector coupled to an inner surface of the cover and electrically connected to the antenna inside the case; A first sealing member, a probe coupled to an inner surface of the cover and inserted into the case to sense a phase signal in the enclosure, a second sealing member interposed between the cover and the probe, And is disposed outside the case portion to shield the electromagnetic waves inside and outside the gas insulated switchgear 3 comprises a sealing member.

The case includes a ground panel fixing block coupled to the inside of the cover, a ground panel sequentially coupled to the ground panel fixing block, an antenna fixing block, and the antenna and the ground panel fixing block, the ground panel, A fixed block, and an outer case coupled to the inside of the cover to surround the antenna.

In addition, the cover preferably includes a ground panel fixing member penetrating the ground panel fixing block and electrically connected to the ground panel.

Preferably, the connector further includes a fourth sealing member having a connecting portion formed to penetrate the ground panel fixing block, and a fourth sealing member coupled to an outer circumferential surface of the connecting portion to closely contact the inside of the ground panel fixing block.

Preferably, the fourth sealing member is at least two O-rings separated from each other.

The probe may further include a fifth sealing member formed to extend through the ground panel fixing block and coupled to an outer circumferential surface of the extension to closely contact the inside of the ground panel fixing block.

In addition, it is preferable that at least two O-rings are coupled to the fifth sealing member so as to be spaced apart from each other.

According to the present invention, since the sealing member is provided inside the partial discharge detecting device, it is possible to prevent the insulating gas filled in the gas insulating breaker from leaking through the partial discharge detecting device.

According to the present invention, since the EMI gasket is provided on the outside of the partial discharge detecting device, electromagnetic waves inside and outside of the gas insulated switchgear are intercepted and the electromagnetic wave is leaked to the outside of the gas insulated switchgear through the partial discharge detecting device, It is possible to prevent the insulating gas filled in the inside of the gas insulated switchgear from flowing to the outside or the outside air from flowing into the inside of the gas insulated switchgear.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view for explaining a partial discharge detecting apparatus of a gas insulated switch according to an embodiment of the present invention; FIG.
2 is a cross-sectional view illustrating the sealing structure of the connector of Fig. 1;
3 is a sectional view B illustrating the sealing structure of the probe of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a front view explaining a partial discharge detecting device of a gas insulated switchgear according to an embodiment of the present invention, Fig. 2 is a cross-sectional view illustrating a sealing structure of the connector of Fig. 1, Fig. 3 is a cross- Sectional view illustrating the sealing structure.

1 to 3, a partial discharge detecting apparatus 100 of a gas insulated switchgear according to an embodiment of the present invention includes a cover 110, a case 120, a connector 130, a first sealing member 140, a probe 150, a second sealing member 160, and a third sealing member 170.

The partial discharge detecting device 100 of the gas insulated switch connects to a flange protruding from one side of the enclosure of the gas insulated switchgear. The flange may be formed at a position where it senses a partial discharge in the enclosure. The partial discharge detecting apparatus 100 of the gas insulated switchgear can sense a partial discharge phenomenon caused by insulation deterioration or electric field concentration inside the enclosure.

The cover 110 is coupled to one side of the enclosure of the gas insulated switchgear. That is, the cover 110 is coupled to the flange protruding from the enclosure. The cover 110 includes a ground panel fixing member formed on an inner side of the housing and extended to the housing side, and the connector 130 and the probe 150 are coupled.

The ground panel fixing member passes through the ground panel fixing block 121 and is electrically connected to the ground panel 122 described later. That is, the ground panel fixing member extends from the cover 110 and contacts the ground panel 122. Accordingly, the ground panel fixing member grounds the ground panel 122 to the cover 110. [

The case 120 is interposed between the enclosure and the cover 110, and houses the antenna 124 therein. That is, the case 120 includes a ground panel fixing block 121 coupled to the inside of the cover 110, a ground panel 122 sequentially coupled to the top of the ground panel fixing block 121, an antenna fixing block 123 And an antenna 124 and an outer case 125 which is coupled inside the cover 110 to surround the ground panel fixing block 121, the ground panel 122, the antenna fixing block 123 and the antenna 124 .

The lower surface of the ground panel fixing block 121 is coupled to the cover 110, and the ground panel 122 is coupled to the upper surface. The ground panel fixing block 121 is formed with a plurality of through holes. One of the plurality of through holes is inserted into the connector 130, and the other through hole is inserted into the probe 150. Further, the other through hole is inserted with the ground panel fixing member.

The ground panel 122 is coupled to the upper side of the ground panel fixing block 121. That is, the ground panel 122 is interposed between the ground panel fixing block 121 and the antenna fixing block 123. The ground panel 122 is electrically connected to the cover 110 by a ground panel fixing member inserted through the ground panel fixing block 121 to be grounded.

The antenna fixing block 123 is positioned on the ground panel 122 and coupled to the ground panel fixing block 121 on the upper side. The antenna fixing block 123 is coupled to the antenna 124 on the upper side.

The antenna 124 is coupled to the upper side of the antenna fixing block 123. The antenna 124 is in contact with the end of the connector 130. The antenna 124 detects electromagnetic waves generated in the gas insulated switchgear 1 and transmits the electromagnetic waves to the connector 130.

The outer case 125 is coupled to the upper side of the cover 110 and accommodates therein the ground panel fixing block 121, the ground panel 122, the antenna fixing block 123 and the antenna 124.

The connector 130 is coupled to the inner surface of the cover 110 and is electrically connected to the antenna 124 inside the case 120. The connector 130 includes a connecting portion 131 formed to penetrate the ground panel fixing block 121 and a fourth sealing member 132 (not shown) which is coupled to the outer circumferential surface of the connecting portion 131 and closely contacts the inside of the ground panel fixing block 121. ). At least two O-rings are vertically coupled to the fourth sealing member 132 so as to be spaced apart from each other.

The connector 130 includes a terminal portion 134 protruding outside the cover 110 and a connecting portion 131 contacting the position fixing portion 133 and the antenna 124 for fixing the position of the cover 110 . The connector 130 transmits the electromagnetic wave information detected by the antenna 124 to the outside through the terminal unit 134. That is, the connector 130 is configured such that the connecting portion 131 is inserted through the ground panel fixing block 121, the ground panel 122 and the antenna fixing block 123 and the end of the connecting portion 131 is connected to the antenna 124 And are electrically connected to each other.

The connector 130 is fixed to the position fixing portion 133 by inserting the position fixing portion 133 into the cover 110 and the first sealing member 140 is interposed between the position fixing portion 133 and the cover 110. [ Here, the first sealing member 140 is interposed between the cover 110 and the connector 130.

The first sealing member 140 is formed in an O-ring shape so as to be fitted to the outer peripheral surface of the terminal portion 134 of the connector 130. The first sealing member 140 is interposed between the position fixing portion 133 of the connector 130 and the cover 110 to prevent leakage of the insulating gas from the inside of the gas insulated switch through the cover 110 to the outside. Further, the first sealing member 140 may be formed of silicon.

The fourth sealing member 132 is coupled to the outer circumferential surface of the connecting portion 131 of the connector 130. The fourth sealing member 132 is in close contact with the inner circumferential surface of the through hole in a state where the connecting portion 131 is inserted into the through hole of the ground panel fixing block 121. Therefore, the fourth sealing member 132 is formed of a silicone material to prevent the insulating gas from flowing toward the cover 110 side through the through-hole.

The probe 150 is coupled to the inner surface of the cover 110 and inserted into the case 120 to sense a phase signal inside the enclosure. The probe 150 includes an extension 151 formed to penetrate the ground panel fixing block 121 and a fifth sealing member 152 152 fitted to the outer circumferential surface of the extension 151 and closely inboard of the ground panel fixing block 121 ). The fifth sealing member 152 is coupled with at least two O-rings spaced apart from each other.

The probe 150 penetrates through the terminal portion 154 protruding outside the cover 110 and the position fixing portion 153 and the ground panel fixing block 121 for fixing the position of the cover 110 to the antenna 124 And an extension portion 151 that is spaced apart. The probe 150 senses the phase signal of the electromagnetic wave generated in the gas insulated switchgear.

The position of the probe 150 is fixed by inserting the position fixing portion 153 into the cover 110 and the second sealing member 160 is interposed between the position fixing portion 153 and the cover 110. Here, the second sealing member 160 is interposed between the cover 110 and the probe 150.

The second sealing member 160 is formed in an O-ring shape so as to be fitted to the outer peripheral surface of the terminal portion 154 of the probe 150. The second sealing member 160 is interposed between the position fixing portion 153 of the probe 150 and the cover 110 to prevent leakage of the insulating gas from the inside of the gas insulated switch through the cover 110 to the outside. The second sealing member 160 may be formed of silicon.

The fifth sealing member 152 is coupled to the outer peripheral surface of the extension portion 151 of the probe 150. The fifth sealing member 152 is in close contact with the inner circumferential surface of the through-hole in a state where the extension portion 151 is inserted into the through-hole of the ground panel fixing block 121. Therefore, the fifth sealing member 152 is made of a silicon material and prevents the insulating gas from flowing to the cover 110 side through the through hole.

The third sealing member 170 is disposed outside the case 120 at the top of the cover 110 to shield the internal and external electromagnetic waves of the gas insulated switchgear. The third sealing member 170 protrudes from the top of the cover 110 and is interposed between the cover 110 and the gas insulated switch when the cover 110 is coupled to the gas insulated switch. That is, when the cover 110 is engaged with the flange, the third sealing member 170 is interposed between the cover 110 and the flange to maintain airtightness between the cover 110 and the flange.

The third sealing member 170 may be formed of an EMI (Electro Magnetic Interference) gasket to prevent the electromagnetic wave from being leaked to the outside or the electromagnetic wave from flowing into the inside. That is, the third sealing member 170 is interposed between the cover 110 and the flange of the gas insulated switchgear to prevent the electromagnetic wave from flowing out from the inside of the gas insulated switchgear. Further, the third sealing member 170 can prevent electromagnetic waves from flowing from the outside to the inside of the gas insulated switchgear.

The operation of the partial discharge detecting apparatus 100 of the gas insulated switchgear according to the embodiment of the present invention having the above-described structure will be briefly described.

The partial discharge detecting device 100 of the gas insulated switch detects the partial discharge phenomenon occurring inside the gas insulated switchgear inside the casing of the gas insulated switchgear. The partial discharge phenomenon can be detected through detection of ultra high frequency (UHF) caused by insulation deterioration or electric field concentration.

The partial discharge detecting device 100 of the gas insulated switch includes an antenna 124 for detecting electromagnetic waves of a very high frequency, a connector 130 for transmitting electromagnetic wave information detected by the antenna 124 to the outside, And a probe 150. The antenna 124, the connector 130 and the probe 150 are accommodated inside the cover 110 and the outer case 125, and the cover 110 is accommodated inside the gas insulated switch by being coupled to the enclosure.

Here, the connector 130 prevents the insulating gas from flowing along the connecting portion 131 by the fourth sealing member 132 coupled to the connecting portion 131 being in close contact with the through hole. The connector 130 is configured such that the first sealing member 140 is interposed between the position fixing portion 133 and the cover 110 so that the insulating gas leaks to the outside through the connector 130 at the cover 110. [ And blocks the electromagnetic waves.

The probe 150 also prevents the insulating gas from flowing along the extended portion 151 by the fifth sealing member 152 coupled to the extended portion 151 being in close contact with the through hole. The probe 150 may be configured such that the insulating gas leaks to the outside through the position where the probe 150 is engaged at the cover 110 by interposing the second sealing member 160 between the position fixing portion 153 and the cover 110. [ And blocks the electromagnetic waves.

Therefore, the partial discharge detecting device 100 of the gas insulated switchgear can prevent the insulated gas SF6 filled in the gas insulated switchgear from flowing out to the outside, thereby preventing the insulation performance of the inner periphery of the gas insulated switchgear from deteriorating . In addition, the partial discharge detecting device 100 of the gas insulated switchgear can prevent environmental destruction of global warming.

In addition, the partial discharge detecting device 100 of the gas insulated switchgear can improve the partial discharge detection accuracy by preventing malfunction or reducing the error. In addition, the partial discharge detecting device 100 of the gas insulated switchgear can improve the precision of detecting abnormality indications of the gas insulated switchgear, and can prevent the breakage of the power equipment

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is understandable. Accordingly, the true scope of the present invention should be determined by the following claims.

100: Partial discharge detection device of gas insulated switchgear
110: cover 120: case part
121: ground panel fixing block 122: ground panel
123: antenna fixing block 124: antenna
125: outer case 130: connector
131: connecting part 132: fourth sealing member
140: first sealing member 150: probe
151: extension part 152: fifth sealing member
160: second sealing member 170: third sealing member

Claims (7)

A partial discharge detection device comprising an antenna for sensing a partial discharge signal generated inside a gas insulated switch,
A cover coupled to one side of the enclosure of the gas insulated switchgear;
A case part interposed between the enclosure and the cover, the case part accommodating the antenna therein;
A connector coupled to the inner surface of the cover and electrically connected to the antenna within the casing;
A first sealing member interposed between the cover and the connector;
A probe coupled to an inner surface of the cover and inserted into the case to sense a phase signal inside the enclosure;
A second sealing member interposed between the cover and the probe; And
A third sealing member disposed on the outer side of the case portion at the upper portion of the cover to shield internal and external electromagnetic waves of the gas insulated switchgear;
Wherein the partial discharge detection device comprises: The method according to claim 1,
The case
A ground panel fixing block coupled to the inside of the cover,
A ground panel fixed to the ground panel, a ground panel fixed to the ground panel,
And an outer case coupled to the inside of the cover to surround the ground panel fixing block, the ground panel, the antenna fixing block, and the antenna. 3. The method of claim 2,
The cover
And a ground panel fixing member penetrating through the ground panel fixing block and electrically connected to the ground panel inside the ground panel fixing block. 3. The method of claim 2,
The connector
And a fourth sealing member having a connecting portion formed to penetrate through the ground panel fixing block, and a fourth sealing member coupled to an outer circumferential surface of the connecting portion and closely in contact with the inside of the ground panel fixing block. 5. The method of claim 4,
The fourth sealing member
And at least two O-rings are coupled to each other so as to be spaced apart from each other. 3. The method of claim 2,
The probe
And a fifth sealing member having an extension formed to penetrate the ground panel fixing block, and a fifth sealing member coupled to an outer circumferential surface of the extension to closely contact the inside of the ground panel fixing block. The method according to claim 6,
The fifth sealing member
And at least two O-rings are coupled to each other so as to be spaced apart from each other.

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