KR100665879B1 - Apparatus for finding and processing partial discharge in power equipments - Google Patents

Abstract

The partial discharge detection and processing apparatus for a power device according to the present invention, which is installed inside the power device, detects partial discharges generated due to an internal abnormality during operation of the power device, and generates an electromagnetic signal represented by electromagnetic waves of the partial discharge. A composite sensor for detecting all the sound wave signals represented by the sound wave, and electrically connected to the composite sensor, a transient voltage protector for removing the transient voltage due to partial discharge flowing into the composite sensor, electrically connected to the composite sensor, Filters and amplifiers for filtering and amplifying the partial discharge electromagnetic and acoustic wave signals detected by the sensor, electrically connected to the filters and amplifiers, and converting the vibratory signals filtered and amplified by the filters and amplifiers into pulsed signals. To visually display the abnormal state of the signal shaper and the power equipment, Apparatus for detecting and discharging partial discharge of power equipment including displays and networks for transmission to where necessary:

A signal processor electrically connected to the signal shaper and receiving an output signal from the signal shaper to determine whether the signal is noise, and to perform a calculation algorithm for estimating the pattern and position of the partial discharge from the signal. It is characterized by the technical configuration.

According to the present invention, the partial discharge generated in the power equipment is detected by a composite sensor for detecting ultrasonic waves and electromagnetic waves, and the detection signal is linked to remove the noise, to track the location of the partial discharge, the type and the degree of risk Can be analyzed.

Description

Apparatus for finding and processing partial discharge in power equipments             

1 is a block diagram schematically showing the overall system configuration of a partial discharge detection and processing apparatus of a power device according to the present invention.

2 is a view showing a configuration example of a TTL method of a signal processor in the partial discharge detection and processing apparatus for a power device according to the present invention.

3 is a view showing a configuration example of a microprocessor method of a signal processor in the partial discharge detection and processing apparatus for a power device according to the present invention.

4 is a flowchart illustrating a signal processing procedure in the microprocessor-based signal processor of FIG. 3.

<Explanation of symbols for the main parts of the drawings>

110 ... Combination sensor 120 ... Overvoltage protector

130 ... Filters and Amplifiers 140 ... Signal Shaper

150 ... Signal Processor 160 ... Indicators and Networks

201,202 ... Comparators 203 ... Monostable vibrators

204 ... Schmitt Trigger 205 ... And Gate

301 ... A / D converter 302 ... Buffer memory

303 ... microprocessor 304 ... data memory

305 ... noise factor operation notification unit 306 ... zero generator

The present invention relates to a partial discharge detection and processing device of a power device, and particularly detects a partial discharge generated when an abnormality exists inside a power device such as a transformer in operation by using a complex sensor in which an ultrasonic sensor and an electromagnetic wave sensor are combined. The present invention relates to a partial discharge detection and processing apparatus for a power device that can remove noise, track the location of partial discharges by analyzing the detection signal, and analyze the type and risk of a defect.

In the operation of a power device such as a transformer, when a partial discharge occurs due to an abnormality in the power device during operation, the conventional partial discharge measurement method generally uses an electrical measurement method or a mechanical measurement method. Sometimes used. However, these measurement methods have the disadvantage of removing noise and estimating the location of the partial discharge which are very important in the measurement of the partial discharge. In case of partial discharge measurement, it is generally vulnerable to external noise and has low sensitivity by using a method of attaching a sensor to the outside of the device.It is reliable in the location information by installing electrical and mechanical sensors in different locations. This has the disadvantage of falling.

The present invention has been made in view of the above-mentioned matters, and the partial discharge generated when an abnormality exists in the operating power device is detected by a complex sensor in which an ultrasonic sensor and an electromagnetic wave sensor are combined, and the detection signal is interlinked. The purpose of the present invention is to provide a partial discharge detection and processing device for a power device that can remove noise, track the location of partial discharge, and analyze the type and risk of defects.

In order to achieve the above object, the partial discharge detection and processing apparatus of a power device according to the present invention,
A complex sensor installed inside the power device and detecting a partial discharge generated due to an internal abnormality during operation of the power device, and detecting both an electromagnetic signal represented by the electromagnetic wave of the partial discharge and a sound wave signal represented by the sound wave; A transient voltage protector that is electrically connected to the sensor and removes the transient voltage caused by the partial discharge flowing into the composite sensor, and is electrically connected to the composite sensor, and the electromagnetic signal and sound wave of the partial discharge detected by the composite sensor A filter and amplifier for filtering and amplifying a signal, a signal shaper electrically connected to the filter and amplifier, and converting a vibratory signal filtered and amplified by the filter and amplifier into a pulsed signal, and an internal abnormal state of a power device. Display device and network for displaying abnormal status information and transmitting abnormal status information to necessary place outside In the partial discharge detection and processing device of a power device comprising:

A signal processor electrically connected to the signal shaper and receiving an output signal from the signal shaper to determine whether the signal is noise, and to perform a calculation algorithm for estimating the pattern and position of the partial discharge from the signal. Its features are configured with.

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Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing the overall system configuration of a partial discharge detection and processing apparatus of a power device according to the present invention.

Referring to FIG. 1, the partial discharge detection and processing apparatus for a power device according to the present invention includes a composite sensor 110, a transient voltage protector 120, a filter and an amplifier 130, a signal shaper 140, and a signal processor 150. ), The display device, and the network 160.

The complex sensor 110 is installed inside the power device (eg, a transformer) 90, and detects partial discharge generated due to an abnormality during operation of the corresponding power device 90, but with an electromagnetic wave of the partial discharge. Detects both the appearing electromagnetic wave signal and the sound wave signal represented by the sound wave. The complex sensor 110 is composed of a coupler (110c) for detecting the electromagnetic wave of the partial discharge and the ultrasonic sensor (110s) for detecting the sound wave.

The transient voltage protector 120 is electrically connected to the composite sensor 110 and removes the transient voltage due to the partial discharge flowing into the composite sensor 110.

The filter and amplifier 130 are electrically connected to the composite sensor 110, and filter and amplify the electromagnetic wave signal and the acoustic wave signal of the partial discharge detected by the composite sensor 110.

The signal shaper 140 is electrically connected to the filter and the amplifier 130, and converts the vibratory signal filtered and amplified by the filter and the amplifier 130 into a pulsed signal.

The signal processor 150 is electrically connected to the signal shaper 140, and receives an output signal from the signal shaper 140 to determine whether the signal is noise or not, and from the signal, a pattern of partial discharge. Perform the algorithm to estimate the position and.

The display device and the network 160 are electrically connected to the signal processor 150, and visually display the result of the signal processor 150 and transmit it to a necessary place outside.

2 and 3 show an example of the configuration of the signal processor 150, FIG. 2 is a configuration example of a transistor transistor logic (TTL) method of the signal processor, and FIG. 3 is a microprocessor method of the signal processor. It is a figure which shows a structural example, respectively.

First, referring to FIG. 2, which shows a configuration of a TTL signal processor, a comparator circuit 201 which receives an electromagnetic wave signal and a sound wave signal of a partial discharge, compares it with a reference signal, and outputs a signal corresponding thereto. 202, a monostable vibrator circuit 203 for receiving an output from the electromagnetic wave signal comparator circuit 201 and adjusting a pulse width, and an output from the sound wave signal comparator circuit 202 Receiving a Schmidt trigger circuit 204 for shaping a signal (eg, shaping a square wave), and outputs of the monostable vibrator circuit 203 and the Schmitt trigger circuit 204 to perform an AND operation And gate circuit 205.

In the TTL signal processor, when an electrical signal is input to the electromagnetic signal comparator 201, the electromagnetic signal comparator 201 compares whether the input signal is higher than a preset reference level. In this comparison, if the input signal is higher than the reference level, the output of the electromagnetic signal comparator 201 is input to the monostable vibrator circuit 203, and the time width of the output pulse at this time is partially discharged farthest from the position of the sensor. Calculate the time the ultrasonic wave reaches the sensor when it occurs. In this case, if there is an ultrasonic signal within that time, the output is output from the And Gate circuit 205. Therefore, such a TTL method is a simple method in which the magnitude of the partial discharge is unknown but there is a partial discharge.

Referring to FIG. 3, which shows a configuration of a signal processor of a microprocessor type, an analog / digital converter (301) for converting an analog input signal into a digital signal, and an analog / digital converter (301). The buffer memory 302 for storing the output data from the memory, the microprocessor 303 for reading the data stored in the buffer memory 302 and processing it by a pre-written calculation processing program, and the microprocessor 303 for processing. A data memory 304 for storing the stored data, a noise factor operation notification unit 305 such as an external circuit breaker operation, and a zero point generation circuit 306 for generating a zero point of 60 Hz.

In the microprocessor-type signal processor as described above, the signal output from the signal shaper 140 is digitized by the analog / digital converter 301, and the signal is processed according to the flowchart of FIG. The magnitude, pattern and location of the discharge can be known. Here, such arithmetic processing programs are prepared in advance by the system designer and stored in a memory built in the microprocessor 303.

4 is a flowchart illustrating a signal processing procedure in a signal processor of a microprocessor method.

Referring to FIG. 4, first, the microprocessor determines whether the magnitude of the input electromagnetic wave or ultrasonic signal is larger than a preset reference value (step S401). In this determination, if the input signal is not larger than the reference value, the program is returned to the beginning, and if the input signal is larger than the reference value, it is determined whether the input signal is an electromagnetic wave or an ultrasonic wave (step S402). In this determination, if the input signal is an electromagnetic pie, it is determined whether or not the ultrasonic signal is present within a predetermined time delay from this signal, that is, within a time when the ultrasonic signal reaches the sensor when the partial discharge occurs from the furthest point from the sensor position. (Step S403). If there is an ultrasonic signal in this determination, it is regarded as a partial discharge pulse, the occurrence position of the partial discharge is estimated from the time difference with the electromagnetic wave, and the partial discharge amount is calculated by a pre-made calculation algorithm (step S404).

On the other hand, if the ultrasonic signal does not exist in the step S403, it is determined whether the ultrasonic signal also exists in other sensors (S405). If there is an ultrasonic signal in this determination, the occurrence position of the partial discharge is estimated from the time difference with the electromagnetic wave. At this time, if a signal is detected from two or more sensors, it will be possible to estimate the location of the partial discharge.

In the case of the ultrasonic signal in step S402, it is determined whether or not the electromagnetic wave signal exists before the predetermined time from this signal (step S406). In this determination, even if the electromagnetic wave signal is smaller than the reference level, it is recognized as a pulse of partial discharge, and the occurrence position of the partial discharge is estimated from the time difference with the ultrasonic wave, and the partial discharge amount is calculated by a pre-made algorithm. Step S404). If there is no electromagnetic signal in step S406, it is determined whether or not the electromagnetic signal also exists in other sensors (S407). If there is an electromagnetic wave signal in this determination, the occurrence position of the partial discharge is estimated from the time difference from the ultrasonic waves. At this time, if a signal is detected from two or more sensors, it will be possible to estimate the location of the partial discharge.

As described above, the partial discharge detection and processing apparatus for a power device according to the present invention is a sensor for detecting a partial discharge inside the power device, the power device in operation by installing a composite sensor in which an ultrasonic sensor and an electromagnetic wave sensor are combined In detecting partial discharge generated when there is an abnormality inside, it detects electromagnetic waves and sound waves and processes them together, so that the internal condition can be diagnosed without stopping the operation of the power device in operation, and noise, partial There is an advantage in that the type, location and risk of discharge generation can be diagnosed with high reliability.

Claims (4)

A complex sensor installed inside the power device and detecting a partial discharge generated due to an internal abnormality during operation of the power device, and detecting both an electromagnetic signal represented by the electromagnetic wave of the partial discharge and a sound wave signal represented by the sound wave; A transient voltage protector that is electrically connected to the sensor and removes the transient voltage caused by the partial discharge flowing into the composite sensor, and is electrically connected to the composite sensor, and the electromagnetic signal and sound wave of the partial discharge detected by the composite sensor A filter and amplifier for filtering and amplifying a signal, a signal shaper electrically connected to the filter and amplifier, and converting a vibratory signal filtered and amplified by the filter and amplifier into a pulsed signal, and an internal abnormal state of a power device. Display device and network for displaying abnormal status information and transmitting abnormal status information to necessary place outside In the partial discharge detection and processing device of a power device comprising: A signal processor electrically connected to the signal shaper and receiving an output signal from the signal shaper to determine whether the signal is noise, and to perform a calculation algorithm for estimating the pattern and position of the partial discharge from the signal. Partial discharge detection and processing apparatus for a power device comprising a. delete The method of claim 1, wherein the signal processor, A comparator circuit which receives the electromagnetic wave signal and the acoustic wave signal of the partial discharge, compares them with a reference signal, and outputs a signal corresponding thereto; A monostable vibrator circuit for receiving an output from the electromagnetic signal comparator circuit and adjusting a pulse width; A Schmitt trigger circuit for receiving an output from the sound wave signal comparator circuit and shaping the signal; And And an end gate circuit configured to perform an AND operation upon receiving the outputs of the monostable vibrator circuit and the Schmitt trigger circuit. The method of claim 1, wherein the signal processor, An analog / digital converter for converting an analog input signal into a digital signal; A buffer memory for once storing output data from the analog / digital converter; A microprocessor that reads data stored in the buffer memory and processes the data stored in the buffer memory by a previously prepared arithmetic program; A data memory for storing data processed by the microprocessor; Noise factor operation notification unit such as external breaker operation; And Partial discharge detection and processing device for a power device, characterized in that consisting of a zero point generation circuit for generating a zero point of 60 Hz.

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