KR100518370B1 - Discharge diagnostic system of Gas Insulation Switchgea - Google Patents

Abstract

 The present invention relates to a discharge diagnosis system employing an electromagnetic wave sensor, and in particular, a gas insulated switchgear to prevent a malfunction of a GIS diagnosis system generated by an external noise electromagnetic wave through mutual comparison between an external noise electromagnetic wave and an internal partial discharge signal. A discharge diagnosis system.

Conventionally, externally generated noise electromagnetic waves are affected, and thus, in the diagnostic system, external noise electromagnetic waves received by the UHF may be mistaken as GIS internal discharges even though there is no discharge generated inside the GIS.

In the present invention, in configuring a sensor for sensing electromagnetic waves in a GIS spacer, by configuring a sensor on each of the inner and outer portions of the spacer, by comparing the signals detected therefrom, the generated electromagnetic waves are noise electromagnetic waves introduced from the outside It is possible to accurately detect the electromagnetic wave generated due to the recognition, partial discharge generated inside, it is possible to prevent the malfunction of the system due to external noise.

Description

Discharge diagnostic system of gas insulated switchgear

The present invention relates to a discharge diagnosis system using an electromagnetic wave sensor for diagnosing a partial discharge of a GIS, and in particular, to prevent malfunction of the GIS diagnosis system generated by an external noise electromagnetic wave through mutual comparison between an external noise electromagnetic wave and an internal partial discharge signal. The present invention relates to a discharge diagnosis system for a gas insulated switchgear using a dual type electromagnetic wave sensor.

GIS (Gas Insulation Switchgear) is for substations in jade, internal and external substations, and it is a device that protects the system appropriately by safely opening and closing lines in abnormal conditions such as accidents and short circuits under normal operating conditions. , Switchgear with built-in switchgear and busbar such as disconnector (DS), ground switch (ES), breaker (CB) in a metal enclosure filled with SF ₆ gas.

In such a GIS there is an insulating spacer made of epoxy which supports the conductors in the metal enclosure and sets the compartment of the insulating gas SF ₆ .

Such spacers must be resistant to high electric fields, have low electrical and mechanical properties change for insulation gas decomposition products, and must be made of materials that are resistant to mechanical stress.

Types of such insulators include an insulation spacer for 170 ㎸ GIS, an insulation spacer for 362 ㎸ GIS, other 170 ㎸ insulation support, and many other insulation parts.

Radiation electromagnetic waves are generated when partial discharge occurs due to bolt loosening, poor contact, inflow of metallic foreign matter, void inside the spacer, etc.

The electromagnetic waves generated as described above move along the metal conductor, and the electromagnetic waves moving along the metal conductor are radiated to the outside through the spacers.

At this time, UHF or ultrasonic sensor is configured on the spacer to measure the electromagnetic wave radiated to the outside to diagnose whether there is partial discharge inside the GIS. Make a diagnosis.

A method of detecting electromagnetic waves generated due to partial discharge adopted in the conventional GIS system will be described with reference to FIG. 1.

In the GIS system, a spacer 12 connecting a cylindrical metal enclosure at an appropriate interval is made of an insulating material such as epoxy, and when a partial discharge occurs in the GIS, radiated electromagnetic waves leak to the outside through the spacer 12. Attach the electromagnetic wave sensor to the spacer 12 and detect the electromagnetic wave generated inside the GIS, and then remove the noise included in the detected signal to diagnose the abnormality such as corona generation or deterioration degree in the GIS. And estimate the time for repair or replacement.

However, in the conventional method, malfunction may occur when there is a strong electromagnetic wave generation source near the GIS.

In particular, since the GIS system is applied to a high-voltage power equipment, malfunctions may be caused by equipment or devices that generate strong electromagnetic waves, such as high voltage transformers, insulators, switchgear, and transmission lines in the vicinity.

The detection sensor is affected by the noise electromagnetic waves generated as described above, and thus, in the diagnostic system, the external noise electromagnetic wave received by the UHF is mistaken as the GIS internal discharge even though there is no discharge in the GIS, causing a malfunction.

Accordingly, in the present invention, in configuring a sensor for sensing electromagnetic waves in a GIS spacer, a sensor is configured in each of the inner and outer parts of the spacer, and the signals detected therefrom are compared to generate noise generated from the outside. The present invention relates to a discharge diagnosis system of a gas insulated switchgear, which can prevent malfunction of a system due to external noise by accurately detecting electromagnetic waves or electromagnetic waves generated by partial discharges generated therein.

In the discharge diagnosis system of the gas insulated switchgear for diagnosing the internal abnormality by determining the presence of internal partial discharge by configuring the electromagnetic wave detection means for detecting the electromagnetic wave emitted through the spacer,

The electromagnetic wave sensing means includes an internal electromagnetic wave sensing means configured to be close to the inner side of the spacer, and an external electromagnetic wave sensing means for receiving an external noise signal at a predetermined distance from the internal electromagnetic wave sensing means toward the outer side of the spacer.

Diagnosing whether the electromagnetic wave signal sensed from the electromagnetic wave sensing means is a noise signal introduced from the outside or an electromagnetic wave signal generated by internal partial discharge by comparing each sensing signal detected by the internal and external electromagnetic wave sensing means with each other It characterized in that it comprises a means.

The discharge diagnosis system of the gas insulated switchgear according to the present invention having such a feature will be described in detail with reference to the embodiment shown in the accompanying drawings.

2 is a view showing the configuration of the electromagnetic wave sensor configured in the spacer in the discharge diagnosis system of the present invention, Figure 3 is a block diagram showing the configuration of the discharge diagnosis system of the present invention.

An electromagnetic wave sensing sensor including an internal electromagnetic wave receiving antenna 1A configured at a position close to the inner side of the spacer, and an external electromagnetic wave receiving antenna 1B configured at a predetermined distance from the internal electromagnetic wave receiving antenna 1A in the direction of the outer portion of the spacer. (1),

The differential calculation unit 2A differentially calculates the detection signal received from the internal electromagnetic wave reception antenna 1A of the electromagnetic wave sensor unit 1 and the detection signal received from the external electromagnetic wave reception antenna 1B, and the differential calculation unit 2A. Diagnosis control including a control unit 2B for determining whether the electromagnetic wave generated according to the calculation result is electromagnetic waves emitted from the inner side of the spacer to the outside or a noise signal flowing into the spacer from the outside of the spacer to perform alarm generation control. It consists of the system (2).

Such a discharge diagnosis system of the present invention,

The internal electromagnetic signal reception antenna 1A is configured at a position close to the inside of the spacer, and the external electromagnetic signal reception antenna 1B is configured at a predetermined distance therefrom.

This is in consideration of the characteristic that the intensity of the electromagnetic signal is attenuated inversely with the square of the distance transmitted, when the electromagnetic signal is emitted to the outside through the spacer or when a noise signal is introduced into the spacer from the outside, The purpose of the present invention is to determine the emission direction of electromagnetic waves by varying the intensity of electromagnetic waves transmitted according to the positions of the two receiving antennas on the path.

When the electromagnetic signal generated internally is emitted to the outside through the spacer, it is transmitted to the external electromagnetic signal receiving antenna 1B via the internal electromagnetic signal receiving antenna 1A, and thus the intensity of the electromagnetic signal transmitted is transmitted to the external electromagnetic signal receiving antenna ( The intensity of the electromagnetic signal transmitted to the internal electromagnetic signal reception antenna 1A is greater than that of the electromagnetic signal transmitted to 1B).

Therefore, in the diagnostic control system 2, the generation position of the generated electromagnetic waves is discriminated by differentially calculating the signals detected from these external electromagnetic wave signal reception antennas 1B and the internal electromagnetic wave signal reception antenna 1A.

The electromagnetic wave sensor unit 1 sets an electromagnetic wave inflow / emission path so that an electromagnetic wave flowing in or out through a spacer can be accurately received through an external electromagnetic wave signal receiving antenna 1B and an internal electromagnetic wave signal receiving antenna 1A. The side is shielded by an aluminum case 3 having an inner face sufficient to cover the entire face of the spacer.

This is to prevent the external noise electromagnetic wave from flowing indiscriminately, and also to prevent the external electromagnetic wave from flowing into the spacer without passing through the external electromagnetic wave reception receiving antenna 1B even when the external noise electromagnetic wave flows indiscriminately.

The electromagnetic wave sensor unit 1 is configured as an ultra high frequency (UHF) sensor.

In the discharge diagnosis system of the present invention as described above, an operation process for diagnosing an internal abnormality is as follows.

When electromagnetic waves are generated due to the internal partial discharge of the spacer, the electromagnetic waves move through the metal conductor and are emitted through the spacer.

In addition, when external electromagnetic noise is generated, electromagnetic waves are introduced through the spacer.

In this way, the electromagnetic wave emitted or introduced through the spacer passes through the internal electromagnetic signal reception antenna 1A and the external electromagnetic signal reception antenna 1B, and the internal electromagnetic signal reception antenna 1A and the external electromagnetic signal reception antenna 1B The emitted electromagnetic wave signal is detected and transmitted to the diagnostic control system 2.

The differential calculation unit 2A of the diagnostic control system 2 differentially calculates the detection signals input from the internal electromagnetic wave receiving antenna 1A and the external electromagnetic wave receiving antenna 1B to obtain the result.

In the case of the electromagnetic wave signal flowing from the outside, the external electromagnetic wave receiving antenna 1B is transmitted to the internal electromagnetic wave receiving antenna 1A, so the value of the external electromagnetic wave receiving antenna 1B appears large, and the internal electromagnetic wave is emitted from the inside to the inside. Since the electromagnetic wave reception antenna 1A is transmitted to the external electromagnetic wave signal reception antenna 1B, the value of the internal electromagnetic wave reception antenna 1A is large.

For example, when the internal electromagnetic reception antenna 1A is used as a reference, a positive value is displayed in the case of electromagnetic waves emitted from the inside to the outside, and a negative value is shown in the case of electromagnetic waves emitted from the outside. .

Therefore, the control unit 2B determines these values to determine whether the electromagnetic waves are generated internally and emitted to the outside, or whether the electromagnetic waves are noise flowing from the outside to control the alarm occurrence.

4 is a flowchart showing an internal discharge diagnosis process performed in the diagnostic control system 2.

In this embodiment of the present invention, when the generated electromagnetic wave has a high frequency, a difference value is generated through signal attenuation generated at a distance between the internal electromagnetic wave sensing means 1A and the external electromagnetic wave sensing means 1B, but the low frequency electromagnetic wave is generated. In the case of, the distance between the internal electromagnetic wave sensing means 1A and the external electromagnetic wave sensing means 1B is not sufficient to compare the signals and obtain the signal attenuation difference.

In another embodiment of the present invention, there is provided an electromagnetic wave sensor 1 having a structure in which an electromagnetic shield is shielded between the internal electromagnetic wave detecting means 1A and the external electromagnetic wave detecting means 1B.

5 is a view showing the configuration of the electromagnetic wave sensing means provided in another embodiment of the present invention.

The electromagnetic wave sensor unit 1 includes an internal electromagnetic wave reception antenna 1A for sensing electromagnetic waves transmitted from the inside of the spacer, and an external electromagnetic wave reception antenna 1B for sensing electromagnetic waves transmitted from the outside of the spacer. 4) has a shielded configuration.

The electromagnetic wave sensing means 1 configured as described above has a structure that electromagnetically shields the internal electromagnetic wave reception antenna 1A and the external electromagnetic wave reception antenna 1B, and the electromagnetic waves generated therein are internal electromagnetic wave reception antennas 1A. Detecting through, the externally generated electromagnetic waves to be detected through the external electromagnetic receiving antenna (1B).

When the electromagnetic wave sensor 1 having such a configuration is provided in the spacer, it is not necessary to shield the peripheral spacers.

For example, if electromagnetic waves are generated internally, there will be an output only through the internal electromagnetic reception antenna 1A.

If electromagnetic waves are generated from the outside, electromagnetic waves are detected through the external electromagnetic wave reception antenna 1B, and if the surrounding spacers are not shielded, the generated electromagnetic waves flow through the peripheral spacers and move along the inner conductor, thereby Since it is sensed by the electromagnetic wave receiving antenna 1A, both the internal and external electromagnetic wave receiving antennas 1A and 1B have an output.

However, since the signal is attenuated according to the distance traveled along the inner conductor and transmitted to the internal electromagnetic wave reception antenna 1A, the electromagnetic wave strength delivered to the internal electromagnetic wave reception antenna 1A is higher than the electromagnetic wave strength transmitted to the external electromagnetic wave reception antenna 1B. Appears small.

Therefore, the diagnosis control system 2 determines the position where the electromagnetic wave is generated by comparing the outputs of the internal and external electromagnetic wave reception antennas 1A and 1B as described in the above embodiment.

As described above, the present invention configures a sensor for detecting electromagnetic waves generated by internal partial discharge through a spacer, and configures a dual type sensor to compare the transmitted electromagnetic waves, and according to the strength of the compared electromagnetic waves. By determining the inflow or emission of electromagnetic waves, it is possible to accurately diagnose the abnormality in the gas switchgear.

1 is a schematic diagram of a general GIS system.

Figure 2 is a view showing the configuration of the electromagnetic wave detection means of the discharge diagnosis system of the gas insulated switchgear of the present invention.

Figure 3 is a block diagram showing the configuration of the discharge diagnosis system of the gas insulated switchgear of the present invention.

4 is a flowchart showing an internal discharge diagnosis process performed in the diagnostic control system according to the present invention.

5 is a view showing another embodiment of the electromagnetic wave detection means of the discharge diagnosis system of the gas insulated switchgear of the present invention.

Claims (5)

In the discharge diagnosis system of the gas insulated switchgear for diagnosing the internal abnormality by determining the presence of internal partial discharge by configuring the electromagnetic wave detection means for detecting the electromagnetic wave emitted through the spacer, The electromagnetic wave detection means is composed of an internal electromagnetic wave detection means configured in a position close to the inner portion of the spacer, the external electromagnetic wave signal detection means configured in a predetermined spaced position with the internal electromagnetic wave detection means in the direction of the outer portion of the spacer, Compares the respective detection signals detected from the internal electromagnetic wave detection means and the external electromagnetic wave detection means of the electromagnetic wave detection means, and whether the electromagnetic wave signal detected through the electromagnetic wave detection means is a noise signal introduced from the outside or is generated due to internal partial discharge. Discharge diagnosis system of a gas insulated switchgear characterized in that it comprises a diagnostic control means for determining whether the signal. In the discharge diagnosis system of the gas insulated switchgear for diagnosing the internal abnormality by determining the presence of internal partial discharge by configuring the electromagnetic wave detection means for detecting the electromagnetic wave emitted through the spacer, The electromagnetic wave sensing means includes an internal electromagnetic wave sensing means for sensing electromagnetic waves transmitted from the inside of the spacer, and an external electromagnetic wave sensing means for sensing electromagnetic waves transmitted from the outside of the spacer, and the internal electromagnetic wave sensing means and the external electromagnetic wave sensing means It is shielded by electromagnetic shielding material, Compares the respective detection signals detected from the internal electromagnetic wave detection means and the external electromagnetic wave detection means of the electromagnetic wave detection means, and whether the electromagnetic wave signal detected through the electromagnetic wave detection means is a noise signal introduced from the outside or is generated due to internal partial discharge. Discharge diagnosis system of a gas insulated switchgear characterized in that it comprises a diagnostic control means for determining whether the signal. The method according to claim 1 or 2, wherein the diagnostic control means comprises: a differential calculation unit for differentially calculating the detection signal of the internal electromagnetic wave detection means of the electromagnetic wave detection means and the detection signal detected from the external electromagnetic wave detection means, and according to the calculation result of the differential calculation unit. And a control unit configured to determine whether the generated electromagnetic waves are electromagnetic waves generated inside the spacer or electromagnetic waves generated outside the spacer to perform alarm generation control. 3. The discharge diagnosis system of the gas insulated switchgear according to claim 1 or 2, wherein the electromagnetic wave detection means shields the side surface with a metallic shield having an inner circumferential surface sufficient to surround the entire surface of the spacer. 3. The discharge diagnosis system of the gas insulated switchgear according to claim 1 or 2, wherein the electromagnetic wave detecting means comprises an ultra high frequency (UHF) sensor.