JP2008032595A - Partial discharge part locating method of three-phase batch gas insulation equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a partial discharge part locating method for surely locating a partial discharge part from specification of a partial discharge position of a gas section by three-phase batch gas insulation equipment. <P>SOLUTION: The partial discharge part locating method includes: arranging each three-phase conductor 2 in a metal vessel 1; detecting partial discharge signals by each detection sensor 5 provided in different gas sections 4 of the metal vessel 1 because of locating of the partial discharge part with the three-phase batch gas insulation equipment sealing an insulating gas in a plurality of the gas sections 4 divided airtightly by insulators 3 by supporting each conductor 2 by the insulators 3; and specifying the gas section 4 of a part discharged partly from the partial discharge signals of at least the two detection sensors 5. Next, the method includes: measuring detection intensity of each discharge signal detected with the detection sensor and an acoustic sensor 6 in the specified gas section 4; and locating a defect part based on the detection intensity of the discharge signal and the detection phase waveform of a three-phase voltage detected by the detection sensor 5 and the acoustic sensor 6. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a method for locating a partial discharge part of a three-phase collective gas insulation device, and in particular, a partial discharge of a three-phase collective gas insulation device that is effective for locating a defect position and identifying the cause of a defect in a three-phase collective gas insulation device part. It relates to a site location method.

Normally, gas insulation equipment such as gas circuit breakers, gas insulated switchgears, and gas insulated busbars installed in substations will cause partial discharge at the location of insulation failure inside the equipment, and eventually dielectric breakdown An accident may occur. Partial discharge of gas-insulated equipment is caused by metallic foreign matter mixed in a cylindrical metal container enclosing an insulating gas such as SF ₆ gas, internal defects in insulators such as spacers supporting conductors, and conductive materials such as conductors and shields. It is known to be caused by poor contact of parts. For this reason, conventional gas-insulated equipment detects partial discharge, which can be said to be a precursor of dielectric breakdown accidents, by various means, identifies the location of occurrence, identifies the type of foreign object defect, etc., and is based on highly accurate partial discharge. Insulation abnormality diagnosis is performed with good accuracy.

  For example, as a partial discharge detection device in a gas insulation device in which a conductor is contained in a metal container and filled with an insulating gas, vibration detectors that receive mechanical vibration signals based on the partial discharge are provided at different positions of the metal container, The time difference at the detection time of each mechanical vibration signal received by each of these vibration detectors is obtained by a time difference calculator, and whether or not the occurrence position of partial discharge is moved by the judgment unit depending on whether each time difference is different or the same. Has been proposed (see Patent Document 1).

  Further, when a partial discharge signal is detected by a partial discharge signal detector provided in the gas insulation apparatus, and the cause of the occurrence is diagnosed and displayed by using the partial discharge signal detector, a diagnostic unit that branches in multiple stages is used. It is proposed to perform a more accurate diagnosis by branching a condition from a plurality of second diagnosis means to one diagnosis means according to the diagnosis result of this, thereby obtaining a diagnosis result of the second diagnosis means ( Patent Document 2).

  A plurality of detectors provided with a plurality of detectors at a distance, a plurality of measuring devices capable of measuring by frequency tuning, and a trigger signal generator necessary for synchronous measurement, in a metal container of a gas insulating device The signal obtained from the above is synchronized with the measuring instrument, and the signal from the detector is positioned with high accuracy from both the time and the size using the adder and delay circuit, and the inside of the metal container It has also been proposed to detect a partial discharge electromagnetic wave generated from the inside of a gas-insulated device enclosed in a gas and perform highly accurate positioning of the partial discharge generation source (see Patent Document 3).

  Further, when analyzing a detection signal for detecting a partial discharge inside the gas insulation device, a frequency (f) -phase (φ) -signal strength (q) characteristic is obtained from the detection signal, and the frequency, phase and signal of these characteristics are obtained. It has also been proposed to improve the accuracy of device diagnosis by obtaining a feature pattern by arranging each value of intensity in a predetermined manner and detecting an abnormality from the feature pattern (see Patent Document 4).

  Separately, the voltage of the conductor stored in the container together with the insulating medium is detected, and the waveform of the operating voltage applied to the conductor is converted by the signal conversion circuit, and the converted operating voltage is displayed on the input information screen. The time axis that is input to the measuring instrument displayed above, detects the phase difference between the driving power supply voltage of the measuring instrument and the operating voltage based on the input operating voltage, and is displayed on the measuring instrument screen according to the phase difference. It is also proposed to detect the partial discharge pattern synchronized with the operating voltage by inputting the detected voltage as it is into the corrected measuring instrument, and to determine the type of defect based on this pattern. (See Patent Document 5).

  Still further, partial discharge signals generated by foreign substances in the gas insulation equipment are detected by a plurality of detectors, and the partial discharge signals detected by each detector are subjected to frequency analysis, and the analysis waveform or application of the gas insulation equipment is performed. Estimate the defect type of a foreign substance from the voltage phase of the partial discharge synchronized with the frequency, and estimate the defect position and signal intensity considering the signal attenuation (gradient) of multiple partial discharge signals. The defect size is estimated using the signal intensity and the electric field distribution at the defect position. When the foreign object is a protrusion on the conductor, the electric field strength and electric field inequality of the protrusion showing the electric field distribution are used, and when the foreign object adheres to the spacer surface, the electric field strength in the spacer surface direction is used. It has also been proposed to perform a risk evaluation for evaluating the risk of dielectric breakdown from the seeds and diagnose the risk of insulation abnormality of gas-insulated equipment from the generated partial discharge (see Patent Document 6).

JP 2000-187055 A JP 2000-224723 A JP 2001-16722 A JP 2001-133506 A Japanese Patent Laid-Open No. 2005-233837 JP 2006-170815 A

  With the above-described known partial discharge detection methods for gas insulation equipment, it is possible to judge the movement of the partial discharge occurrence position, to diagnose the partial discharge with high accuracy, and to identify the type of defect causing the partial discharge. , It can improve the accuracy of diagnosis by detecting abnormalities from the characteristic pattern of partial discharge, can identify the location of partial discharge and the type of defect, etc., can perform insulation abnormality diagnosis based on partial discharge with high accuracy, There is an advantage of diagnosing the risk for insulation anomalies. However, although any technique is effective when applied to a single-phase gas insulation apparatus, there is a problem that the effect cannot be sufficiently exhibited when applied to a three-phase collective gas insulation apparatus.

  In particular, the location of the partial discharge occurrence and the location of the partial discharge in the three-phase gas-insulated equipment should be monitored for subsequent maintenance, for example, whether it is necessary to immediately dismantle the relevant part of the gas-insulated equipment. This is important in determining whether to continue or respond to the next maintenance inspection. For this reason, even if it is a three-phase collective gas insulation apparatus, it is desired to ensure the location of the partial discharge and the location of the part.

  An object of the present invention is to provide a partial discharge site locating method for a three-phase collective gas insulated device that can reliably identify a partial discharge site from specifying a partial discharge position in the three-phase collective gas insulated device.

  Three-phase collective gas insulation equipment that arranges three-phase conductors in a metal container, supports each conductor with an insulator, and encloses an insulating gas in a plurality of gas compartments that are hermetically divided with the insulator. A partial discharge signal is detected by each detection sensor in the gas section of the metal container, and the partial discharge signals detected by at least two detection sensors The gas compartment which is discharging is specified, the detection intensity of each discharge signal detected by the detection sensor and the acoustic sensor in the specified gas section is measured, and each discharge signal detected by the detection sensor and the acoustic sensor is detected. A defect site is specified based on the intensity and the phase waveform of the three-phase voltage.

  The detection sensor for detecting a partial discharge signal measures the detection intensity of the signal using a detection sensor provided in advance in a metal container. Further, the detection sensor for measuring the detection intensity of the signal is newly arranged after the gas section is specified, and measures the detection intensity of the signal.

  According to the present invention, by detecting the partial discharge signal in the three-phase collective gas insulation apparatus, the partial discharge position partitioned by the gas is determined, and then the partial discharge signal and the acoustic signal are used to reliably determine the partial discharge site. Can be done. Therefore, the maintenance and inspection work of the three-phase collective gas insulation apparatus becomes easy and can be performed economically.

  Three-phase collective gas insulation equipment that arranges three-phase conductors in a metal container, supports each conductor with an insulator, and encloses an insulating gas in a plurality of gas compartments that are hermetically divided with the insulator. Thus, the partial discharge signal is detected by the detection sensors provided in the metal containers of the different gas compartments, and the partial gas discharge is identified from the partial discharge signals of the two detection sensors. Thereafter, the detection intensity of each discharge signal detected by the detection sensor and the acoustic sensor in the specified gas compartment is measured, and the detection intensity of the discharge signal detected by the detection sensor and the acoustic sensor and the detection voltage of the three-phase conductor are detected. A defective part is specified based on the phase waveform.

  Hereinafter, the partial discharge region locating method for a three-phase collective gas insulation device of the present invention will be described with reference to FIGS. 1 to 4 which are examples in which the method is applied to a three-phase collective gas bus of a gas insulated switchgear. In the three-phase collective gas bus, the conductors 2 for the three phases of the U phase, the V phase, and the W phase are arranged in a cylindrical metal container 1, but in FIG. It is shown in a state where conductors for one phase are arranged.

  Each conductor 2 of the three-phase collective gas bus is supported by an insulator 3 such as an insulating spacer or an insulating post, and the metal container 1 is hermetically divided by the insulator 3 to form a plurality of gas compartments 4. The metal container 1 is mechanically firmly connected, and an insulating gas serving as an insulating medium is sealed inside each gas compartment 4.

  The metal container 1 has each gas compartment 4 sealed, or the gas compartment 4 having a predetermined interval as shown in FIG. 1 (a), at either a selected position on the inner surface or the outer surface of the metal container 1. Detection sensors 5a and 5b for detecting a partial discharge signal are provided, and an ultra high frequency method (UHF: Ultra High Frequency, hereinafter abbreviated as “UHF method”) or an acoustic method (AE: Acoustic Emission, hereinafter referred to as “AE method”). The partial discharge is detected by using the abbreviation.

  Generally, as shown in FIG. 2, the three-phase collective gas bus, which is a gas insulation device, has adhered foreign matter a attached to the surface of an insulator 3 such as an insulating spacer, attached foreign matter b attached to the conductor 2 of each phase, metal container 1 It is sufficient if the internal floating foreign matter c and further each defect in the conductor float state d such as the contact portion can be determined. By determining the defective part of the three-phase collective gas bus, determine the action at the time of partial discharge detection, that is, continue the dismantling inspection or monitoring of the partial discharge state, or make appropriate judgments such as responding to the next inspection. be able to.

  In the present invention, in order to determine the partial discharge position of the gas insulating device, first, as shown in FIG. 1A, each of the UHF detection sensors 5a and 5b provided in different gas sections 4 is connected to the partial discharge position determination device 6. The signal processing unit 6A including a signal amplifier or the like is connected to the position determination unit 6B. A plurality of detection signals detected by the respective detection sensors 5a and 5b are used, and a gas section having a portion (x point) in which partial discharge is performed in the position determination unit 6B of the partial discharge position locating device 6 by the method described below. 4 is standardized.

  In locating the gas section 4, a partial discharge signal is detected using at least two detection sensors 5a and 5b. Then, the signal detection amounts Ya and Yb in the detection sensors 5a and 5b shown in FIG. 1B, the distance (Xa + Xb) between the detection sensors 5a and 5b, and the number of insulators 4 existing between the gas sections 4 to be detected. Considering the attenuation amount α through which the partial discharge signal propagates in the metal container 1 and the attenuation amount β due to the insulator 3, the point where the attenuation gradient intersects and the electromagnetic wave intensity Y0 at this point can be obtained. By using the partial discharge position locating apparatus 6 incorporating this detection means, the location of the gas compartment 4 having the part (x point) in which partial discharge is performed in the three-phase collective gas bus is determined.

  As shown in FIG. 1A, the detection sensor for UHF method used for specifying the gas compartment 4 that generates the partial discharge is a detection sensor that is opposed to each other with the portion (x point) that is partially discharged interposed therebetween. The gas compartment 4 in which partial discharge is caused can be identified by using a plurality of detection sensors that are located in the same direction and have different detection values of the partial discharge signal.

  Subsequently, as shown in FIG. 1 (c), in order to locate the defective part of the specified gas compartment 4, a detection sensor 5x for the UHF method and an acoustic sensor 7 for the AE method are provided on the metal container 1 part. The detection sensor 5x and the acoustic sensor 7 for the AE method are connected to the site determination unit 8B via the signal processing unit 8A of the defect site location device 8, and the location of the defect site is implemented. Thus, instead of newly arranging the detection sensor 5x for the UHF method, for example, the detection sensor 5a that already exists near the metal container 1 in the specified gas compartment 4 can be used.

  In the gas section 4 specified by the partial discharge orientation, the partial discharge signal is detected by the detection sensor 5x and the acoustic sensor 7 and the detected intensity is measured for the location of the defective part. A threshold value is set for the detected intensity of the signal to facilitate identification of partial discharge or external noise. Then, the degree of the detected intensity of the partial discharge signal is classified, for example, the intensity of the signal is classified into large, medium, and small, and the phase waveform of each voltage in the three-phase conductor in which the detected partial discharge signal shown in FIG. .

  Each defect portion shown in FIG. 2 has a magnitude of the intensity of the partial discharge signal detected by the UHF method, the magnitude of the intensity of the partial discharge signal detected by the AE method, and the time when the partial discharge of FIG. 4 is generated. There is a correlation shown in FIG. 3 between the phase of the voltage and classification is possible. Accordingly, the site determination unit 8B of the defect site location device 8 taking these relationships into account determines the location of the defect in the gas compartment 4 in the three-phase collective gas insulated bus generating the partial discharge indicated by the x mark.

  The phase of each phase voltage is examined at the time when the partial discharge shown in FIG. 4 (d) occurs, in the vicinity of the peak of the voltage phase (vertical) in one of the three phases shown in FIG. 4 (a). Whether a partial discharge signal is detected in (line addition display) or at a point in time on the way from 0 to-side in the voltage phase in the other phase as shown in FIG. Furthermore, any defect can be inferred depending on whether it is detected at a point in the middle of the voltage phase in another phase as shown in FIG. For this reason, by using the intensity of the partial discharge signal detected by each of the sensors 5x and 7 and the phase of the voltage at the time when the partial discharge is generated, it is possible to reliably locate the defective part.

  In the gas-insulated equipment, the insulator-attached foreign matter a and the conductor-attached foreign matter b at the defect site have a high risk evaluation, so the size of the defective portion can be estimated by the amount of discharge charge, and the floating foreign matter c inside the metal container 1 Since the size of the foreign matter can be estimated by the size of the sound, and the conductor float state d can be determined for each of the above-mentioned appropriate measures by performing a risk evaluation by the discharge charge amount. Inspection work can be performed easily and economically.

It is explanatory drawing which shows the procedure of the partial discharge site | part localization method of the three-phase collective gas insulation apparatus in this invention. It is a schematic diagram which shows the state of the foreign material adhesion which causes the partial discharge of a three-phase collective gas insulation apparatus. It is explanatory drawing used for the partial discharge site | part localization method of the three-phase collective gas insulation apparatus of this invention. It is explanatory drawing of the relationship between the phase waveform of a three-phase voltage, and a partial discharge detection signal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Metal container, 2 ... Conductor, 3 ... Insulator, 4 ... Gas compartment, 5 ... Detection sensor, 6 ... Partial discharge position locating device, 7 ... Acoustic sensor, 8 ... Defect site | part locating device.

Claims (3)

  Three-phase collective gas insulation equipment that arranges three-phase conductors in a metal container, supports each conductor with an insulator, and encloses an insulating gas in a plurality of gas compartments that are hermetically divided with the insulator. A partial discharge signal is detected by each detection sensor in the gas section of the metal container, and the partial discharge signals detected by at least two detection sensors The gas compartment which is discharging is specified, the detection intensity of each discharge signal detected by the detection sensor and the acoustic sensor in the specified gas section is measured, and each discharge signal detected by the detection sensor and the acoustic sensor is detected. A partial discharge site locating method for a three-phase collective gas insulation apparatus, wherein a defect site is specified based on intensity and a phase waveform of a three-phase voltage.   2. The partial discharge site determination of a three-phase collective gas insulation apparatus according to claim 1, wherein the detection sensor for detecting a partial discharge signal measures the detection intensity of the signal using a detection sensor provided in advance in a metal container. Method.   2. The partial discharge of the three-phase collective gas insulation apparatus according to claim 1, wherein the detection sensor for measuring the signal detection intensity is newly arranged after the gas section is specified and the signal detection intensity is measured. Site location method.

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