KR100893396B1 - Partial discharge detector of gas insulated apparatus having sensor - Google Patents

Abstract

A partial discharge detector apparatus which detects the partial discharge generated during the operation of the gas insulation device by utilizing the sensor is provided to detect the partial discharge generated with all kinds of the deformities within the metal case. A high voltage conductor(19) is supported by an insulating support(18) inside a metal vessel(17) in which the insulation gas is sealed up. A flange(20) is installed in order to seal the hand hole installed at one side of body of the metal case. It is installed at THE flange so that the antenna reception part of the cupola-shape consisting of 2 conductive components be symmetrical. The signal wire and conductor are combined with connector in flange.

Description

PARTIAL DISCHARGE DETECTOR OF GAS INSULATED APPARATUS HAVING SENSOR}

The present invention relates to a partial discharge detection device for a gas insulated device, and more particularly, to a partial discharge detection device for a gas insulated device provided with a built-in sensor capable of detecting a partial discharge generated over voltage during operation of the gas insulated device. .

Power equipment used in substations, such as gas insulated switchgear, gas insulated busbar, and gas insulated transformer, is a gas insulator made by insulating and supporting high voltage conductors in a sealed metal container filled with insulated gas. In this case, a partial discharge occurs due to a high electric field locally.

If the partial discharge is left as it is, it may lead to insulation breakdown and lead to a major accident. Therefore, it is necessary to find a partial discharge occurring inside the metal container early and take countermeasures.

By detecting such partial discharge in the form of a signal, it is possible to foresee breakdown in advance and it is important as a preventive maintenance method of a gas insulator.

However, the partial discharge in the insulating gas is a high voltage phenomenon in which a sudden pulse current is generated. The electromagnetic waves generated by the partial discharge radiate into the space at the moment, propagate in the metal container, and the electromagnetic wave is almost discharged from the closed metal container to the outside. It is not radiated.

From this, a partial discharge detection device of a gas insulator is proposed which detects a signal generated inside the metal container, which is a sealed container, by an external measuring device using an airtight terminal.

For example, Patent Application No. 1999-7010683 (Invention Name: Partial Discharge Detection Device of Gas Insulation Device) provides a wideband and high sensitivity for electromagnetic waves due to partial discharge occurring at the time of an internal abnormality of the gas insulation device. Use an antenna to detect with an external measuring device.

FIG. 1 is a longitudinal cross-sectional view showing a partial discharge detection apparatus of a conventional gas insulator, and FIG. 2 is a longitudinal cross-sectional view showing an example in which the partial discharge detection apparatus of FIG. 1 is applied to the potential measurement of gas insulation.

As shown in Figs. 1 and 2, the partial discharge detection apparatus of the conventional gas insulator has a very weak partial discharge signal and is affected by external noise. Therefore, the detection sensitivity and precision of the partial discharge signal must be satisfied. Although not possible, the antenna receiver 11 supported by the antenna support 12 is configured by combining two semicircle plates on a plane in the metal container 17 to detect electromagnetic waves of partial discharge with wideband and high sensitivity.

In this case, since the area of the antenna receiver 11 is increased, the capacitance C1 of the high voltage conductor 19 and the antenna receiver 11 and the capacitance C2 of the flange 20 and the antenna receiver 11 are increased. Increasing the value of the electrode enables high sensitivity potential measurement in the gas insulator.

In addition, since the dipole antenna having a high directivity is used in the antenna receiver 11, it is possible to detect in a wideband by one antenna which part of the partial discharge detection device installed in the gas insulator. It is economical because there is no need to install the antenna.

The signal detected by the antenna receiver 11 is transmitted to the coaxial structure of the sealing terminal 13, the coaxial sealing terminal 14, and the coaxial cable 15, so that the high voltage conductor 19 is provided by the insulating support 18. ) Can be transmitted to the measuring device 16 without attenuating a signal of 100 MHz or more received by the partial discharge in the metal container 17 supported by, and can measure up to a high frequency band of several GHz.

In addition, since the antenna receiver 11 is grounded and used, the antenna itself can be used as the ground potential without using the float electrode, so that the occurrence of a failure can be reduced even when placed inside the gas insulator.

In addition, the technique applied to the detection device is a structure that detects electromagnetic waves generated during partial discharge using a dipole antenna without a balance, the characteristics of the antenna may be changed by external factors due to the current flowing through the coaxial cable 15. .

In addition, the size of the flange 20 of the detection device is large and heavy, which also causes inconvenience when carrying.

Accordingly, an object of the present invention is to provide a partial discharge detection device for a gas insulated device equipped with a built-in sensor for mounting a built-in sensor to a gas insulated device and detecting the abnormality caused by partial discharge occurring during operation of the gas insulated device. will be.

In addition, another object of the present invention is to improve the sensitivity of the sensor while minimizing the number of sensors to enable the detection and cause of the partial discharge.

According to a feature of the present invention for achieving the above object, a pair of antenna receiver having a hemispherical shape that receives the signal of the partial discharge generated in the metal container and are located symmetrically with each other; A built-in sensor comprising a signal line and a ground line connected to each conductive electrode of the antenna receiver; a coaxial cable for drawing a signal transmitted through the signal line to the outside of the metal container; and a measuring device connected to the coaxial cable. It is configured by.

The antenna receiver is preferably installed to be perpendicular to each other with the high voltage conductor installed in the metal container.

The antenna receiver provides a frequency characteristic of -10 dB or less in a frequency band of 1 to 1.5 kHz in the frequency band.

A matching element having an impedance equal to that of the coaxial cable connected to the signal line is connected to the ground line. In this case, the impedance of the coaxial cable generally has an impedance of 50 Ω, so that a matching element having a 50 Ω impedance is also connected to the ground line.

According to the partial discharge detection device of the gas insulated device with the built-in sensor of the present invention having such a configuration has the following effects.

That is, a hemispherical antenna is installed in the metal container, and since the characteristics of the antenna have a frequency characteristic of -10 dB or less in the 0.5 to 1.5 GHz band, which is a partial discharge generation frequency band, particularly in the 1 to 1.5 GHz high frequency band, the conventional partial discharge detection is performed. Compared to the antenna receiver used in the device, the sensor sensitivity is improved, so that partial discharge caused by various defects in the metal container can be detected.

Hereinafter, a partial discharge detection device of a gas insulator equipped with a built-in sensor according to the present invention will be described in detail with reference to the preferred embodiment shown in the accompanying drawings.

In describing an embodiment of the present invention, the overall configuration is similar to the partial discharge detection device of the gas insulator of the prior art, except that the built-in sensor of the present invention is configured in a flange sealing a hand hole installed at one side of the body of the metal container. Since there is a difference, the following description will focus on these differences. Therefore, the same components will be described with the same reference numerals, and the other components will be described with the new reference numerals.

3 is a longitudinal cross-sectional view of a partial discharge detection device of a gas insulator equipped with a built-in sensor in a preferred embodiment of the present invention, Figure 4 is a cross-sectional view taken along the line A-A of FIG.

3 and 4 illustrate a case where a partial discharge detection device of a gas insulator according to an embodiment of the present invention is applied to a part of a gas insulated bus bar, which is known as a gas insulator.

In general, the gas-insulated bus is isolated by the support (18) in a metal container 17 which is formed in a tubular shape and the insulation sealing the insulating gas such as SF ₆ gas is superior not a high-voltage conductor (19).

And the flange 20 is installed to seal the hand hole installed on one side of the body of the metal container (17).

The flange 20 is provided with a built-in sensor. In the present embodiment, the built-in sensor is a dipole sensor having a hemispherical shape (eg, 'Ball' type). That is, a pair of hemispherical shapes that accurately divide 'Ball', which is a hemispherical antenna receiver 100a (100b) consisting of two conductive elements are installed on the flange 20 to be symmetrical to each other. The two terminals of the signal line 102 and the ground line 104 for supporting the 100b are connected to the lower ends of the antenna receivers 100a and 100b, and the signal line 102 and the ground line 104 are flanges 20. on Join with the connector. Although the antenna receivers 100a and 100b are supported by the signal line 102 and the ground line 104, the antenna receivers 100a and 100b may be supported by a separate antenna support (not shown).

In addition, the antenna receivers 100a and 100b including the signal line 102 and the ground line 104 may be disposed perpendicular to the high voltage conductor 19 when installed in the metal container 17. This is to increase the sensor sensitivity of the built-in sensor. That is, the antenna receiver 100a (a vertical line connecting the signal line 102 and the ground line 104, which are two terminals of the high voltage conductor 19 and the antenna receivers 100a and 100b, which are semi-spherical conductive elements, is perpendicular to each other). 100b).

On the other hand, the signal line 102 is connected to the measuring device 16 by a coaxial cable 15 having a small change in impedance through a connector 14 coupled to the flange 20.

In addition, a matching element 106 having the same impedance (50Ω) as the impedance (50Ω) of the coaxial cable 15 connected to the signal line 102 is connected to the ground line 104 so as to be exposed to the metal container 17 as a connector. Attached.

The reason why the built-in sensor has such a structure is that a sensor function capable of detecting partial discharge in a general gas insulator can be most optimally provided. However, when the size of the gas insulated device, the function as the partial discharge detection device, and the like are combined, it is natural that the size and position of each component of the built-in sensor may be changed.

Thus, the partial discharge detection method using the partial discharge detection device of the gas insulated device provided with a built-in sensor will be described.

First, the 50Ω matching element 106 is connected to the ground wire 104 of the built-in sensor, thereby providing stable sensor sensitivity.

In this state, the partial discharge detection device detects a partial discharge occurring in the metal container 17.

Specifically, partial discharge occurs when the insulation abnormality occurs in the metal container 17 as described above. The causes of the insulation abnormality include various causes such as mixing of foreign metals, defects in insulation such as voids in the metal vessel 17 or cracks occurring in the metal vessel 17, poor contact of a conductive member such as a shield member, and the like. This causes partial discharge.

When a partial discharge occurs, a current pulse including a high frequency of several kHz is generated, and electromagnetic waves generated therefrom propagate in the metal container 17, which is the antenna receiver 100a (100b) of the built-in sensor. Is received by. Then, the voltage is induced in the antenna receivers 100a and 100b and is drawn to the outside of the metal container 17 through the signal line 102 and transmitted to the measuring device 16 via the coaxial cable 15.

At this time, the built-in sensor has a frequency characteristic of less than -10dB in the 1 ~ 1.5 kHz high frequency band of the 0.5 ~ 1.5 kHz band of the partial discharge generation frequency band, it can detect the partial discharge better than the function of the conventional antenna receiver Can be.

On the other hand, the measuring device 16 prepares data in a state where the partial discharge signal does not occur in advance, and generates partial discharge in comparison with the data applied to the measuring device 16 while continuously monitoring the inside of the metal container 17. Is detected.

Although described with reference to the illustrated embodiment of the present invention as described above, this is merely exemplary, those skilled in the art to which the present invention pertains various modifications without departing from the spirit and scope of the present invention. It will be apparent that other embodiments may be modified and equivalent. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a longitudinal sectional view showing a partial discharge detection apparatus of a conventional gas insulator.

FIG. 2 is a longitudinal sectional view showing an example where the partial discharge detection device of FIG. 1 is applied to the potential measurement of gas insulation. FIG.

Figure 3 is a longitudinal sectional view showing a partial discharge detection device of a gas insulator equipped with a built-in sensor in accordance with a preferred embodiment of the present invention.

4 is a cross-sectional view taken along the line A-A of FIG.

* Description of the symbols for the main parts of the drawings *

100a, 100b: antenna receiver 102: signal line

104: ground wire 106: matching element

Claims (4)

A built-in sensor consisting of a pair of antenna receivers having a hemispherical shape receiving a partial discharge signal generated in a metal container and symmetrically positioned with each other, and a signal line and a ground line connected to each conductive electrode of the antenna receiver; A coaxial cable for drawing the signal transmitted to the signal line to the outside of the metal container; And, Partial discharge detection device of a gas insulated device with a built-in sensor, characterized in that it comprises a measuring device connected to the coaxial cable. The method of claim 1, The antenna receiver, Partial discharge detection device of a gas insulated device with a built-in sensor, characterized in that installed in the metal container perpendicular to each other high voltage conductors. The method of claim 2, The built-in sensor is a partial discharge detection device of a gas insulated device with a built-in sensor, characterized in that to provide a frequency characteristic of less than -10dB in the high frequency band of 1 ~ 1.5kHz of the frequency band. The method of claim 1, And a matching element having an impedance equal to that of a coaxial cable connected to the signal line, connected to the ground line.

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