KR20150078415A - Partial discharge detecting device in gas insulated switchgear - Google Patents

Abstract

The present invention is to provide a partial discharge detecting device of a gas insulated switchgear capable of effectively sensing a partial discharge of a small volume. The partial discharge detecting device of the gas insulated switchgear of the present invention comprises: an antenna semicircle plate; an antenna upper end panel including an antenna expansion unit which is expanded to the opposite side of the antenna semicircle plate from a circular arc center point of the antenna semicircle plate as a rectangular shape; a ground semicircle plate; an antenna lower end panel including a ground expansion unit which is expanded to the opposite side of the ground semicircle plate from the circular arc center point of the ground semicircle plate as a rectangular shape; and a base to horizontally maintain the antenna upper end panel and the antenna lower end panel and to vertically attach an antenna connector capable of electrically connecting the antenna upper end panel and the antenna lower end panel to the outside. In this regard, the antenna upper end panel includes a bending unit which is curved towards the base in a vertical direction of the antenna expansion unit by being bent at a long side of the antenna expansion unit.

Description

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

The present invention relates to an apparatus for diagnosing a partial discharge of a gas insulated switchgear, and more particularly to an apparatus for diagnosing a partial discharge of a gas insulated switchgear, which is applied to an antenna of a partial discharge detection sensor for detecting an electromagnetic wave partial discharge signal generated in an internal defect of a gas insulated switchgear And more particularly, to a partial discharge detecting apparatus of a gas insulated switchgear.

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.

Therefore, a gas insulated switchgear (GIS) using a high-pressure gas (SF6) as an insulated medium is used to measure and diagnose the deterioration state of insulation in the electric power facility in real time. GIS is widely used in power plants and substations due to its advantages of high insulation strength and compactness due to enclosure, high reliability and easy maintenance.

However, in the process of installing the gas insulated switchgear, protrusions of the conductor, cracks of the spacer, and conductive metal impurities may occur. 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 discharge is a generic term that occurs due to internal defect in GIS and does not occur between electrode and electrode. It is a collective term such as corona discharge, void discharge, surface discharge and so on. A signal is detected in a frequency band in which a defect is detected, and it is applied as a factor that can easily grasp the cause of the defect or the location of the defect.

Therefore, a partial discharge detecting device of a partial gas insulated switchgear for detecting a partial discharge signal and judging an abnormal symptom from the partial discharge signal is applied in order to prevent an accident caused by breakage of a power facility.

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 a shielding band surrounding the outer peripheral surface of the spacer.

The external partial discharge detection device can detect the partial discharge phenomenon inside the gas insulated switch by measuring the electromagnetic wave from the outside when the partial discharge to the outside occurs through the spacer. The built-in partial discharge detection device can detect a partial discharge phenomenon caused by insulation deterioration or electric field concentration inside the bus bar by being installed inside the bus bar of the gas insulated switchgear.

As described above, techniques for detecting the partial discharge of the gas insulated switchgear have been developed, but it is not easy to have a structure for detecting the partial discharge inside the insulated GIS and delivering it to the outside, and it is difficult to install it in a relatively narrow interior . In addition, it is necessary to secure the insulation property in the structure for transmitting the detection signal to the outside, and to suppress the influence of noise or the like.

Korea Patent Publication No. 2011-0046226

An object of the present invention is to provide a partial discharge detection device of a gas insulated switchgear capable of efficiently detecting a partial discharge with a relatively small volume.

Another object of the present invention is to provide a partial discharge detecting device for a gas insulated switchgear which can ensure insulation in a structure for transmitting a detection signal to the outside and suppress the influence of noise or the like.

An apparatus for detecting partial discharge of a gas insulated switchgear according to an aspect of the present invention includes an antenna half plate and an antenna upper panel having an antenna extension extending in a rectangular shape opposite to the antenna half plate at a circular center point of the antenna half plate, ; An antenna bottom panel having a grounding semi-circular plate and a ground extending portion extending in a rectangular shape opposite to the grounding semi-circular plate at a circle center point of the grounding semi-circular plate; And a base to which the antenna upper panel and the antenna lower panel are horizontally held to each other and to which an antenna connector for electrically connecting the antenna upper and lower antenna panels is vertically attached.

The antenna top panel may further include a bent portion bent at a long side of the antenna extension portion and bent toward the base in a direction perpendicular to the antenna extension portion.

The antenna upper panel may further include an antenna connecting hole formed at a central portion of the antenna extension, and the antenna lower panel may further include a ground plate connecting hole formed at a center of the ground extending portion.

The antenna may further include a sorting pin for providing an electrical impedance between the antenna upper panel and the antenna lower panel.

The antenna panel may further include an antenna panel insulation block for maintaining an insulation state between the antenna upper panel and the antenna lower panel.

The antenna panel insulating block may further include an embossing portion positioned on one or both sides of the antenna panel insulating block and contacting the antenna upper panel or the antenna lower panel so that the antenna panel insulating block and the antenna upper panel or the antenna lower panel are spaced apart from each other .

The antenna may further include a base insulating block for maintaining an insulated state between the antenna bottom panel and the base.

The base insulating block may include an embossing portion that is in contact with the antenna bottom panel such that the antenna bottom panel and the base insulating block are spaced apart from each other.

The cover may further include an embossed portion for protecting the antenna upper panel or the antenna lower panel and having an embossed portion contacting the antenna upper panel so as to be spaced apart from the antenna upper panel.

The apparatus may further include a phase detection probe positioned on the base in the vicinity of the antenna extension and the antenna backing plate.

Here, the phase sensing probe and the antenna connector may include: a first conductive line located at a center of the cylinder; An insulating cylinder surrounding the first conductive line; And a second conductive line formed in a cylindrical shape surrounding the insulating tube.

A discharge detection module of a gas insulated switch according to an aspect of the present invention includes: a fixing part coupled to a power equipment to be measured; An inner housing extending from the fixing portion to the inside of the electric power facility; And an outer housing extending from the fixing portion to the outside of the electric power facility, wherein a discharge detection antenna is disposed inside the inner housing, and a noise detection antenna is installed in the outer housing or in the outer housing Can be located.

Here, the phase detection probe may further include a phase detection probe located in the inner housing.

The external housing may further include a signal processing unit for processing detection signals of the discharge detection antenna and the noise detection antenna.

The connection terminal may further include a connection terminal connected to the discharge detection antenna and the noise detection antenna in the outer housing and for transmitting the detected signal to the outside.

Here, the discharge detection antenna may include an antenna upper panel having an antenna half plate and an antenna extension extending in a rectangular shape opposite to the antenna half plate at a circle center point of the antenna half plate; And

And an antenna bottom panel having a ground extending portion extending in a rectangular shape opposite to the grounding half disc at a circular center point of the grounding half disc.

The partial discharge detecting apparatus of the gas insulated switch of the present invention according to the above-described configuration has an advantage that partial discharge can be efficiently detected with a relatively small volume.

Alternatively, the present invention has an advantage that insulation can be ensured in a structure for transmitting a detection signal to the outside, and influence of noise or the like can be suppressed.

1 is a front view, a side view, and a plan view showing a partial discharge detecting device of a gas insulated switch according to an embodiment of the present invention;
FIG. 2 is a perspective view showing in more detail one embodiment of the antenna top panel and the antenna bottom panel of FIG. 1; FIG.
Figure 3 is a perspective view showing in more detail one embodiment of the base of Figure 1;
4 is a perspective view showing the entire assembled structure of the partial discharge detecting device of the gas insulated switch according to the embodiment of the present invention.
Figure 5 is a perspective view showing in greater detail one embodiment of the cover of Figure 4;
FIG. 6 is a perspective view showing in more detail an embodiment of the antenna isolation block of FIG. 5; FIG.
FIG. 7 is a front view, a side view, and a plan view showing a partial discharge detection module according to an embodiment of the present invention, including partial discharge detection structure of FIG. 1;

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a partial discharge detection apparatus of a gas insulated switch according to an embodiment of the present invention.

The partial discharge detecting device of the illustrated gas insulated switch includes an antenna upper panel 100, an antenna lower panel 200 installed horizontally with the antenna upper panel 100, a gap between the antenna upper panel 100 and the antenna lower panel 100 And a base 400 to which the antenna connector 420 for vertically attaching the antenna connector 420 is electrically connected to the outside.

The partial discharge detecting device of the illustrated gas insulated switch further includes a phase sensing probe 440 located in an empty space on the base near the antenna top panel 100 and the antenna bottom panel 200.

The phase sensing probe 440 is located in a vacant space of the fan-shaped antenna upper panel 100 and the antenna lower panel 200 having a handle, thereby saving the installation position of the sensor, There is an advantage of not having to add the device to the GIS. The phase of the voltage applied to the gas insulated switch can be accurately detected using the phase sensing probe 440, and the diagnosis is performed with the detected voltage phase.

The gap between the antenna upper panel 100 and the antenna lower panel 200 is maintained by the shorting pin and the antenna connector 420. The gap between the antenna lower panel 200 and the base 400 is maintained by the antenna supporting bar (482, 484) and the antenna connector (420).

The antenna top panel 100 is electrically connected to the end of the antenna connector 420 and the antenna bottom panel 200 is electrically connected to a portion of the antenna connector 420 that is spaced apart from the end of the antenna connector 420. The connection portion of the antenna connector 420 with the antenna top panel 100 and the connection portion with the antenna bottom panel 200 may be insulated from each other.

In addition to the structures of the antenna top panel 100, the antenna bottom panel 200, and the base 400 shown in the figure, the partial discharge detecting device of the gas insulated switch includes a cover for protecting the structure, And an insulating layer for increasing the insulation between the base 440 and the antenna lower panel 200. The insulating layer may be formed of a material having a high thermal conductivity.

FIG. 2 illustrates one embodiment of the antenna top panel 100 and the antenna bottom panel 200 of FIG. 1 in greater detail. The illustrated antenna top panel 100 and antenna bottom panel 200 may be formed of a conductive flat plate material.

2, the antenna top panel 100 includes a semicylindrical antenna half plate 122 and a rectangular shape (not shown) on the opposite side of the antenna half plate 122 from the circular center point of the antenna half plate 122 And an antenna extension 124 extending from the antenna extension part 124 to the antenna extension part 124.

The illustrated antenna lower panel 200 includes a grounding semi-circular plate 222 and a ground extending portion 224 extending in a rectangular shape from the circular center point of the grounding semi-circular plate 222 to the opposite side of the grounding circular plate 222, Like shape with a handle.

The antenna upper panel 100 includes a pair of bent portions 126 bent at a long side of the antenna extension portion 124 and bent toward the base 400 in a direction perpendicular to the antenna extension portion 124 , 127). The width of the antenna lower panel extension 224 may be smaller than the width of the antenna extension 124 so that the bent portions 126 and 127 are insulated from the antenna lower panel 200.

The antenna top panel 100 and the antenna bottom panel 200 having the structure shown in the figure are designed to increase the receiving sensitivity of signals in the UHF band in a semicircular shape while providing a separate antenna There is an advantage that the expansion / contraction portion 124 is provided to enhance the convenience of manufacture / assembly. Also, since the bent portions 126 and 127 are provided, there is an advantage that the reception sensitivity and the sensitivity to signals in various directions can be increased without increasing the installation space.

The bent portions 126 and 127 are formed with one circular plate together with the antenna half plate 122 and the antenna extension portion 124 before being bent and bent and cut in the illustrated structure, It is advantageous in terms of a production cost to be manufactured integrally with the antenna extension portion 124 and the antenna extension portion 122.

An antenna connecting hole 132 for fixing the antenna connector 420 of FIG. 1 is formed at the central point of the antenna extension 124 of the antenna top panel 100 and the antenna bottom plate 122 is connected to the antenna bottom panel A shorting pin fixing hole 134 for fixing the shorting pin 234 of the light emitting device 200 may be formed.

A grounding plate connecting hole 232 for fixing the antenna connector 420 of FIG. 1 is formed at a central point of the ground extending portion 224 of the antenna lower panel 200, Shorting pin fixing holes 282 and 284 for fixing the shorting pin 234 of the panel 200 and the antenna supporting bars 482 and 484 of FIG. 1 may be formed.

An antenna panel insulation block 540 for maintaining an insulation state between the antenna upper panel 100 and the antenna lower panel 200 is provided between the antenna upper panel 100 and the antenna lower panel 200 of the illustrated structure Can be located. The antenna panel isolation block 540 may further include an embossed portion 545 disposed on one or both surfaces of the antenna panel insulation block 540 and contacting the antenna upper panel 100 or the antenna lower panel 200, The block 540 and the antenna top panel 100 or the antenna bottom panel 200 may be spaced apart from each other.

The partial discharge detection antenna structure including the antenna upper panel 100 and the antenna lower panel 200 shown in FIG. 2 can increase detection efficiency of the partial discharge signal of the wide-band electromagnetic wave type, There is an advantage to be able to.

Specifically, the central portion of the antenna top panel 100 is cut and bent so that the inductance component (inductance component) of the bent portions 126 and 127, which is a patch And the capacitance component depending on the separation distance between the antenna connector 420 and the bent portions 126 and 127, the antenna can be conveniently designed in a wide band.

The shorting pin 234 may contribute to miniaturization of the overall antenna structure and adjust the coupling capacitance and / or adjust the coupling capacitance between the antenna top panel 100 and the antenna bottom panel 200 of the shorting pin 234, Or by adjusting the impedance of the shorting pin 234, the desired wide band characteristic can be designed.

The partial discharge detection antenna structure of FIG. 2 has an advantage that the radiation pattern and the gain are evenly distributed over the three-dimensional space, compared with the partial discharge detection structure according to the related art, There is an advantage of having characteristics.

FIG. 3 illustrates one embodiment of the base 400 of FIG. 1 in more detail. The illustrated base 400 may be formed of an insulating material.

In the illustrated base 400, a cylindrical rod-shaped antenna connector 420, which holds the antenna top panel 100 and the antenna bottom panel 200 in a horizontal direction and electrically connects the antenna top panel 100 and the antenna bottom panel 200, have.

An antenna support bar 482 or 484 may be attached to the base 400 to maintain a gap between the antenna lower panel 200 and the base 400.

In addition, a cover attaching hole for attaching the cover of the partial discharge detecting device of the gas insulated switchgear and a flange attaching hole for attaching to the flange of the gas insulated switchgear may be formed in the base 400.

The illustrated phase sensing probe 440 and the antenna connector 420 include a first conductive line located at the center of the cylinder; Insulating tubes (422, 442) surrounding the first conductive lines; And a second conductive line formed in a cylindrical shape surrounding the insulating tube.

FIG. 4 shows an overall assembled structure of a partial discharge detection device of a gas insulated switch according to an embodiment of the present invention. FIG. 5 illustrates one embodiment of the cover of FIG. 4 in greater detail, and FIG. 6 illustrates one embodiment of the antenna isolation block of FIG. 4 in greater detail.

 The partial discharge detecting device of the illustrated gas insulated switch includes a protective cover 520, an antenna top panel 100, an antenna bottom panel 200, a base 400, the antenna top panel 100 and the antenna bottom panel 200 And an antenna isolation block 560 for increasing the insulation between the base 440 and the antenna lower panel 200. The antenna isolation block 560 may be formed of an insulating material,

The protective cover 520, the panel insulating block 540 and the antenna insulating block 560 may be formed of an insulating material such as Teflon. The antenna top panel 100 and the antenna bottom panel 200 may have the structure of FIG. 2, and the base 400 may have the structure of FIG.

The panel insulating block 540 and the antenna insulating block 560 are connected to the antenna upper panel bend 126, the shorting pin 234, the antenna connector 420 and the phase sensing probe 440 of FIG. Holes or slots for passing through the antenna support rods 482 and 484 may be formed. The panel insulating block 540 and the antenna insulating block 560 may be formed with holes through which the base 400 and the protective cover 520 are fixed.

At least one of the inner surface of the protective cover 520, the upper surface of the antenna insulating block 560, the lower surface of the antenna insulating block 560, and the upper surface of the antenna panel insulating block 540, Embossing portions 525, 545, and 565 may be provided.

For example, in order to protect the antenna internal structure and minimize the loss of the antenna due to the molding case forming the protective cover 520, the embossed portions 525 (or 525) are formed on the contact surfaces of the antenna top panel 100 and / ) Can be applied.

In this case, when the entire surface of the molding case and the antenna upper panel are in contact with each other, the antenna resonance frequency and the antenna gain characteristic may be degraded due to impedance mismatching. However, It is possible to minimize the contact area between the antenna top panel and the molding case.

7 illustrates an electrical discharge detection module according to an embodiment of the present invention.

The illustrated discharge detection module comprises: a fixing part (40) coupled to a power equipment to be measured; An inner housing (10) extending from the fixing portion (40) to the inside of the electric power facility; And an outer housing 50 extending from the fixing portion 40 to the outside of the electric power facility.

The noise detection antenna 60 is attached to the antenna attachment portion 56 on the side surface of the outer housing 50. The noise detection antenna 60 is attached to the inner housing 10, Located. In other implementations, the noise sensing antenna 60 may be mounted within the outer housing 50.

The inner housing 10 may include a partial discharge detection device as shown in Fig. 1, the discharge detection antenna includes an antenna upper panel 100, an antenna lower panel 200 installed horizontally with the antenna upper panel 100, an antenna upper panel 100, And an antenna connector 420 that maintains the interval of the panel and electrically connects to the outside. The phase sensing probe may be a phase sensing probe 440 of FIG.

The outer surface of the inner housing 10 may have a shape in which the cover 520 of FIG. 5 and the base 400 are coupled.

The fixing portion 40 may be part or all of the base 400 of FIG. For example, by using eight coupling holes provided on the outer periphery of the base 400, it can be fixed to a power facility, which is a discharge detection target, such as a gas insulated switchgear.

Depending on the implementation, the outer housing 50 may be implemented such that a portion of the case connected by a hinge or the like is opened to inspect the internal components.

According to the embodiment, the outer housing 50 may include a display device, such as a front panel, for displaying the detection value or the operation state so that the operation of each antenna can be recognized by a user outside the power facility.

The illustrated discharge detection module not only can effectively detect the partial discharge signal but also has an advantage that it is possible to directly detect the phase signal of the GIS applied voltage in the vicinity of the position where the partial discharge signal is detected, There is an advantage that the external noise signal for measuring the noise can be measured together from the integrated noise detecting antenna 60 in the module.

It should be noted that the above-described embodiments are intended to be illustrative, not limiting. In addition, it will be understood by those of ordinary skill in the art that various embodiments are possible within the scope of the technical idea of the present invention.

10: Inner housing
40:
50: outer housing
60: Noise detection antenna
100: Antenna top panel
200: Antenna bottom panel
400: Base
420: Antenna connector
440: phase detection probe

Claims (16)

An antenna half plate,
An antenna upper panel having an antenna extension extending in a rectangular shape opposite to the antenna half plate at a circle center point of the antenna half plate;
A grounding half disc,
An antenna bottom panel having a ground extending portion extending in a rectangular shape opposite to the grounding half disc at a circular center point of the grounding half disc; And
The antenna upper panel and the antenna lower panel are held horizontally relative to each other, and an antenna connector, which is electrically connected to the outside,
Wherein the partial discharge detection device comprises:
The method according to claim 1,
The antenna top panel includes:
Further comprising a bent portion bent at a long side of the antenna extension portion and bent toward the base in a direction perpendicular to the antenna extension portion.
The method according to claim 1,
The antenna top panel further includes an antenna connecting hole formed at a central portion of the antenna extension portion,
Wherein the antenna lower panel further comprises a ground plate connecting hole formed at a center portion of the ground extending portion.
The method according to claim 1,
Further comprising: a sorting pin for providing an electrical impedance between the antenna upper panel and the antenna lower panel.
The method according to claim 1,
Further comprising an antenna panel insulation block for maintaining an insulation state between the antenna top panel and the antenna bottom panel.
The method of claim 5, wherein
The antenna panel isolation block and the antenna top panel or the antenna bottom panel are spaced apart from each other.
Further comprising: an embossed portion located on one or both surfaces of the antenna panel insulating block and contacting the antenna upper panel or the antenna lower panel.
The method according to claim 1,
Further comprising a base insulating block for maintaining an insulating state between the antenna lower panel and the base.
8. The method of claim 7,
Wherein the base insulating block includes an embossed portion that is in contact with the antenna bottom panel so that the antenna bottom panel and the base insulating block are spaced apart from each other.
The method according to claim 1,
And an embossing portion for protecting the antenna upper panel or the antenna lower panel and contacting an inner surface of the antenna upper panel so as to be spaced apart from the antenna upper panel,
The partial discharge detection device further comprising:
The method according to claim 1,
Further comprising a phase sensing probe positioned on the base in the vicinity of the antenna extension and the antenna backplane.
11. The method of claim 10,
The phase-sensing probe and the antenna connector may include:
A first conductive line located in the center of the cylinder;
An insulating cylinder surrounding the first conductive line; And
A second conductive line formed in a cylindrical shape surrounding the insulating cylinder,
The partial discharge detecting device comprising:
A fixture coupled to the electrical equipment to be measured;
An inner housing extending from the fixing portion to the inside of the electric power facility; And
And an outer housing extending from the stationary portion to the outside of the power plant,
A discharge detection antenna is disposed inside the inner housing,
Wherein the noise detection antenna is located inside the outer housing or attached to the outer housing.
13. The method of claim 12,
A phase sensing probe located in said inner housing;
Further comprising a discharge detection module.
13. The method of claim 12,
A signal processing section for processing detection signals of the discharge detection antenna and the noise detection antenna in the outer housing,
Further comprising a discharge detection module.
13. The method of claim 12,
A discharge detection antenna connected to the noise detection antenna and the noise detection antenna inside the outer housing,
And a connection terminal for transferring the detected signal to the outside.
13. The method of claim 12,
The discharge detection antenna
An antenna half plate,
An antenna upper panel having an antenna extension extending in a rectangular shape opposite to the antenna half plate at a circle center point of the antenna half plate; And
A grounding half disc,
An antenna bottom panel having a ground extending portion extending in a rectangular shape opposite to the grounding half disc at a circular center point of the grounding half disc,
And a discharge detection module.

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