KR101308812B1 - Apparatus and method for noise elimination of partial discharge - Google Patents

Abstract

The present invention relates to an apparatus and method for removing partial discharge noise, comprising a partial discharge sensor for detecting an electromagnetic wave signal generated during partial discharge in a power device, a splitter for distributing an electromagnetic wave signal into two identical signals, and a high speed log amplifier. It includes a high speed circuit unit for performing high speed signal processing on any one of two signals using a high speed log amplifier, and a low speed log amplifier, and processing a low speed signal for the other one of the two signals using a low speed log amplifier. The signal strengths of the low speed circuit section and the first signal output from the high speed circuit section and the second signal output from the low speed circuit section are respectively measured, and from the difference between the signal intensity peak value of the first signal and the signal intensity peak value of the second signal, respectively. It includes a signal processing unit for removing the noise signal contained in the electromagnetic wave signal.

Description

Apparatus and method for noise elimination of partial discharge

The present invention relates to an apparatus and method for removing partial discharge noise, and more particularly, to a partial discharge defect type determination device for removing noise of a partial discharge signal by using a characteristic of the partial discharge signal and a response speed difference of a wireless power detector. And to a method thereof.

In general, as a method for removing noise of a partial discharge signal, a separate noise sensor and a separate noise sensor are installed, and the peaks of the partial discharge sensor signals located at the same time interval as the peak intervals detected by the noise sensors are located. There are a noise gating method for removing noise by removing and an offset processing method for adjusting base noise level by adjusting amplification degree.

In the noise gating method, the noise sensor and the partial discharge sensor must be in the same condition, but the peak value is removed because conditions such as phase difference, sensor sensitivity, distance from the noise occurrence point, sensor directivity, and attenuation ratio of the coaxial line are different. As a result, the practical noise removal efficiency is low.

On the other hand, in the offset processing method, since a plurality of filtering circuits are superposed on the front end of the RF processing analog circuit to suppress noise, a partial discharge signal may not be detected.

An object of the present invention is to distribute the signal detected by the partial discharge sensor equally through the divider, and then to obtain the difference of the result value by applying electronic circuits having different operating speed characteristics for each of the partial discharge signal and the noise signal. The present invention provides a partial discharge noise removing device and a method for removing noise of a partial discharge signal without a separate noise filter by removing the noise using the acquired value.

Partial discharge noise removing device according to the present invention for achieving the above object, a partial discharge sensor for detecting an electromagnetic wave signal generated during partial discharge in a power device, a splitter for distributing the electromagnetic wave signal into the same two signals, high-speed log And a high speed circuit unit configured to perform high speed signal processing on any one of the two signals using the high speed log amplifier, and a low speed log amplifier, and the other of the two signals using the low speed log amplifier. The signal strength of the low speed circuit portion for processing a low speed signal with respect to one signal, and the first signal output from the high speed circuit portion and the second signal output from the low speed circuit portion, are respectively measured, and the signal intensity peak value of the first signal is measured. Noise included in the electromagnetic signal from the difference in the signal intensity peak value of the second signal And a signal processor for removing the signal.

The high speed circuit unit is characterized in that for detecting the electromagnetic wave signal having a high speed and a low operating speed.

The high speed circuit unit measures a signal strength of the detected electromagnetic wave signal and outputs a voltage signal proportional to the measured signal strength.

The low speed circuit unit is characterized in that it detects an electromagnetic wave signal having a low operating speed.

The low speed circuit unit measures a signal strength of the detected electromagnetic wave signal and outputs a voltage signal proportional to the measured signal strength.

The fast log amplifier may process an input signal at a response speed set within a range of 6 ns to 60 ns.

The low speed log amplifier may process an input signal at a response speed set within a range of 60 ns to 1000 ns.

The high speed log amplifier and the low speed log amplifier have different reaction rates, and the high speed log amplifier has a faster response speed than the low speed log amplifier.

The signal processor may remove the noise signal included in the electromagnetic wave signal by subtracting the signal intensity peak value of the output signal of the low speed log amplifier from the signal intensity peak value of the output signal of the high speed log amplifier. .

On the other hand, the partial discharge noise removing method according to the present invention for achieving the above object, detecting an electromagnetic wave signal generated during the partial discharge in the power device, the step of distributing the electromagnetic wave signal in the splitter to the same two signals, Signal processing at any one of the two signals distributed in the distributing step using a high speed log amplifier at high speed, and processing the other one of the two signals at a low speed using a low speed log amplifier Measuring signal strengths of the output signal of the high speed log amplifier and the output signal of the low speed log amplifier; and measuring signal intensity peak values of the output signals of the high speed log amplifier and output signals of the low speed log amplifier. The noise signal included in the electromagnetic wave signal is removed from the difference of the signal intensity peak value. Is characterized in that it comprises a step.

The signal processing may include detecting an electromagnetic wave signal having a high speed and a low operating speed among the signals input by the high speed log amplifier, and outputting a voltage signal proportional to the detected signal strength. .

Before the step of measuring the signal strength, it is characterized in that for converting the voltage signal output from the high speed log amplifier into a proportional electromagnetic wave signal.

The signal processing may include detecting an electromagnetic wave signal having a low operating speed among the signals input by the low speed log amplifier, and outputting a voltage signal proportional to the detected signal strength.

Before the step of measuring the signal strength, characterized in that for converting the voltage signal output from the low-speed log amplifier to a proportional electromagnetic wave signal.

The removing of the noise signal may be performed by subtracting a signal intensity peak value of the output signal of the low speed log amplifier from a signal intensity peak value of the output signal of the high speed log amplifier.

According to the present invention, the signal detected by the partial discharge sensor is equally distributed through the divider, and the difference in the result value is obtained by applying an electronic circuit having different operating speed characteristics for each of the partial discharge signal and the noise signal, By removing the noise using the acquired value, there is an advantage that a partial discharge signal can be obtained without a separate noise filter.

In addition, the present invention has the advantage that the efficiency of the partial discharge signal can be removed without the partial discharge dead frequency band is increased.

1 is a block diagram referred to to explain the configuration of a partial discharge noise removing device according to the present invention.
2 is a structural diagram referred to for explaining the operation of the partial discharge noise removing device according to the present invention.
3 is an exemplary view showing a partial discharge signal detected by the partial discharge noise removing device according to the present invention.
4 is an exemplary view showing measurement data of a high speed circuit unit and a low speed circuit unit applied to the partial discharge noise removing device according to the present invention.
5 is an exemplary view showing a signal output from the high speed circuit portion and the low speed circuit portion of the partial discharge noise removing device according to the present invention.
6 is an exemplary view illustrating a partial discharge signal from which noise is removed in the partial discharge noise removing device according to the present invention.
7 is a flowchart illustrating an operation flow of the method for controlling the partial discharge noise according to the present invention.

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

Unlike other signals, the partial discharge signal has a very rapid rise and fall time of several ns and a very short duration. The present invention is to provide an apparatus and method for removing partial discharge noise using a speed difference by utilizing such characteristics of the partial discharge signal.

1 is a block diagram referred to to explain the configuration of a partial discharge noise removing device according to the present invention.

As shown in FIG. 1, the apparatus for removing partial discharge noise according to the present invention includes a partial discharge sensor 10, a divider 20, a high speed circuit unit 30, a low speed circuit unit 40, and a signal processing unit 50. do.

The partial discharge sensor 10 measures electromagnetic waves, ultrasonic waves, etc. generated by the partial discharge in real time. An embodiment of the present invention will be described as an example of a sensor for measuring electromagnetic waves, but is not limited thereto. It is also possible to apply other types of sensors such as an impedance sensor and an ultrasonic sensor.

The distributor 20 distributes the electromagnetic wave signals input in real time through the partial discharge sensor 10 in two paths, and outputs the divided signals to the high speed circuit unit 30 and the low speed circuit unit 40, respectively. At this time, the signals output to the high speed circuit unit 30 and the low speed circuit unit 40 are signals of the same time and the same condition.

In the exemplary embodiment of the present invention, an example in which the splitter 20 divides the input partial discharge signal into two paths will be described. In this case, more precise signal analysis can be achieved by applying different speeds.

Meanwhile, in the embodiment of the present invention, it is assumed that the same signal is input to the high speed circuit unit 30 and the low speed circuit unit 40 at the same time and under the same conditions. If the input signals to the 30 and the low speed circuit unit 40 are not the same, zero adjustment means (not shown) for the input signals may be separately provided.

Here, the zero point adjusting means may generate an electromagnetic wave signal from the outside for calibration purposes and be input to the partial discharge sensor, or adjust the zero point by inputting an electrical high frequency signal from the outside by putting a test input point in front of the distributor. have.

In addition, in order to prevent a characteristic change between the high speed circuit unit 30 and the low speed circuit unit 40 from occurring, a correction means (not shown) for correcting the deviation between the high speed circuit unit 30 and the low speed circuit unit 40 is separately provided. It may be provided.

Here, the correction means may correct the characteristic value of the internal circuit or correct the result value in software in order to correct the signal characteristics of the high speed circuit section 30 and the low speed circuit section 40.

The high speed circuit unit 30 measures the signal strength of the signals distributed from the divider 20. At this time, the high speed circuit unit 30 has a response speed of 6ns to 60ns band. Therefore, the high speed circuit unit 30 measures the signal strength with respect to a signal having a response speed of 6 ns to 60 ns of the input signals.

In addition, the high speed circuit unit 30 outputs a voltage signal proportional to the measured signal strength dBm. Here, the voltage signal output by the high speed circuit unit 30 is referred to as a first voltage signal for convenience.

The low speed circuit 40 measures the signal strength of the signals distributed from the divider 20. In this case, the low speed circuit unit 40 has a response speed of 60 ns to 1000 ns, or more. Therefore, the low speed circuit unit 40 measures signal strength with respect to a signal having a response speed of 60 ns to 1000 ns or more of the input signals.

In addition, the low speed circuit unit 40 outputs a voltage signal proportional to the measured signal strength dBm. Here, the voltage signal output by the low speed circuit unit 40 is referred to as a second voltage signal for convenience.

In the case of the low speed circuit unit 40, it is possible to vary the reaction speed by external logic. In this case, the number of measurement pulses and the repetition rate of the partial discharge pulses can be obtained by minimizing the measurement time period and making a compact diagnosis. Accurate signal analysis can be performed by finding the number of occurrences and repetition rate of partial discharge pulses.

When the first voltage signal and the second voltage signal are input, the signal processor 50 measures the voltage strength of the first voltage signal and outputs a first electromagnetic wave signal dBm proportional to the voltage strength of the first voltage signal. In addition, the signal processor 50 measures the voltage intensity of the second voltage signal and outputs a second electromagnetic wave signal dBm proportional to the voltage intensity of the second voltage signal.

At this time, the signal processing unit 50 compares the peak values of the first electromagnetic wave signal and the second electromagnetic wave signal, and subtracts the peak value of the second electromagnetic wave signal from the peak value of the first electromagnetic wave signal to thereby input the signal through the partial discharge sensor 10. Eliminate noise for.

When the partial discharge noise removing device according to the present invention is used, real-time difference value data for each speed may be converted into a DAC, supplied to the outside, and analyzed by an oscilloscope, or may be supplied to an input of a conventional PRPD or PRPS system.

In addition, the digital data may be sent to a graphic processing device such as a PC to output a waveform related to the speed to enable the operator to perform visual analysis.

2 is a structural diagram referred to for explaining the operation of the partial discharge noise removing device according to the present invention.

As shown in FIG. 2, the signal sensed by the partial discharge sensor 10 is divided through a low noise amplifier (LNA) 13 and a variable gain amplifier (VGA) 16. 20).

The divider 20 divides the input signal into two paths so that the same signal is input to the high speed log amplifier of the high speed circuit unit 30 and the low speed log amplifier of the low speed circuit unit 40, respectively.

Since the high speed log amplifier has a high response speed, the high speed log amplifier detects signals having high and low operating speeds, and outputs a first voltage signal proportional to the signal strength to the analog-to-digital converter (ADC) 35. do. At this time, the ADC 35 converts the first voltage signal in the analog form into a digital signal and outputs the digital signal to the signal processor (DSP) 50.

Since the low speed log amplifier has a low response speed, a signal having a high operating speed is not detected, and only a signal having a low operating speed is detected. The low speed log amplifier outputs a second voltage signal proportional to the detected signal strength to an analog-to-digital converter (ADC) 45. At this time, the ADC 45 converts the second voltage signal of the analog form into a digital signal and outputs it to the signal processor (DSP) 50.

Here, the high speed log amplifier and the low speed log amplifier simultaneously process input signals and operate at the same reference voltage and sampling frequency. In addition, the low-speed log amplifier is a variable speed, it is possible to control the speed by the control logic of the signal processor 50. The signal processor 50 also controls the signal gain of the variable gain amplifier (VGA) 16.

3 is an exemplary view showing a partial discharge signal detected by the partial discharge noise removing device according to the present invention.

In Figure 3, (a) is a pure partial discharge signal, (b) is a noise signal, (c) shows a signal detected through the partial discharge sensor (10).

In other words, when the partial discharge occurs in the power device, the partial discharge signal as shown in FIG. 3 (a) is generated, but at the same time, a noise signal as shown in (b), for example, a cellular phone base station signal may occur. .

In this case, the partial discharge sensor 10 detects the partial discharge signal of (a) and the noise signal of (b) together as shown in (c) of FIG. 3. Therefore, in the present invention, the pure partial discharge signal as shown in FIG. 3 (a) is obtained only by removing the noise signal from the signal detected by the partial discharge sensor 10.

To this end, in the present invention, in order to remove noise by using the difference in operating speeds of FIGS. 3A and 3B, the signal of FIG. 3C is respectively transmitted by the high speed circuit unit 30 and the low speed circuit unit 40. Do it.

4 is an exemplary view showing measurement data of the high speed circuit unit 30 and the low speed circuit unit 40 applied to the partial discharge noise removing device according to the present invention.

In FIG. 4, area A shows signal measurement data of the high speed circuit section 30. In the embodiment of FIG. 4, the high speed circuit section 30 has a response speed of 24 ns. On the other hand, area B shows measurement data of the low speed circuit section 40, and the reaction rate was set to 1000 ns.

Here, the partial discharge signal as shown in FIG. 3A has a high operation speed, whereas the cellular phone base station signal as shown in (B) has a low operation speed.

Therefore, as shown in Fig. 4, in the region A, it is possible to confirm the state of detecting the high speed partial discharge signal and the low speed mobile phone base station signal together. On the other hand, in the region B, it is possible to confirm that the high speed partial discharge signal is not detected and only the low speed mobile phone base station signal is detected.

As described above, since the low speed circuit unit 40 does not detect the high speed partial discharge signal because the reaction speed is slow, the signal detected by the low speed circuit unit 40 is regarded as a noise signal for the partial discharge.

5 is an exemplary view showing signals output from the high speed circuit unit 30 and the low speed circuit unit 40 of the partial discharge noise removing device according to the present invention.

5A illustrates an output signal of the high speed circuit unit 30. That is, the high speed circuit unit 30 detects both the partial discharge signal and the cellular phone base station signal. At this time, the high speed circuit unit 30 outputs a first voltage signal proportional to the signal strength of the detected electromagnetic wave signal, and thus outputs a signal having a waveform as shown in FIG.

5B illustrates an output signal of the low speed circuit unit 40. That is, the low speed circuit unit 40 does not detect both the partial discharge signal and the cellular phone base station signal, but detects only the cellular phone base station signal. At this time, the low-speed circuit unit 40 outputs a second voltage signal proportional to the signal strength of the detected electromagnetic wave signal, thereby outputting a signal having a waveform as shown in FIG.

The first voltage signal and the second voltage signal as shown in FIGS. 5A and 5B are converted into digital signals by the AD converters 35 and 45, respectively, to the signal processor 50. It is input.

6 is an exemplary view illustrating a partial discharge signal from which noise is removed in the partial discharge noise removing device according to the present invention.

When the first voltage signal and the second voltage signal are input, the signal processor 50 outputs a first electromagnetic wave signal dBm proportional to the voltage intensity of the first voltage signal. In addition, the signal processor 50 outputs a second electromagnetic wave signal dBm proportional to the voltage intensity of the second voltage signal.

At this time, the signal processing unit 50 compares the peak values of the first electromagnetic wave signal and the second electromagnetic wave signal, and subtracts the peak value of the second electromagnetic wave signal from the peak value of the first electromagnetic wave signal. The result of subtracting the peak value of the second electromagnetic wave signal from the peak value of the first electromagnetic wave signal is shown in FIG. 6.

In conclusion, comparing FIG. 6 and FIG. 3A, it can be seen that the result of subtracting the peak value of the second electromagnetic wave signal from the peak value of the first electromagnetic wave signal has a form close to the pure partial discharge signal.

Therefore, by using the partial discharge noise removing device according to the present invention, it is possible to detect the partial discharge signal with high reliability.

The operation of the partial discharge noise control apparatus according to the present invention configured as described above is as follows.

7 is a flowchart illustrating an operation flow of the method for controlling the partial discharge noise according to the present invention.

As shown in FIG. 7, the partial discharge noise removing apparatus according to the present invention detects the partial discharge sensor 10 when the partial discharge occurs in the power device (S100).

In this case, in order to remove noise of the signal detected by the partial discharge sensor 10, the partial discharge noise removing device distributes the signal detected in the process 'S100' into two identical signals through the distributor 20 (S110). , And outputs the signals distributed in the 'S110' process to the high speed log amplifier 31 and the low speed log amplifier 41.

The high speed log amplifier 31 and the low speed log amplifier 41 perform high speed and low speed signal processing on the input signal (S120). That is, the high speed log amplifier 31 performs high speed signal processing on one of the two divided signals, and the low speed log amplifier 41 processes the low speed signal on the other of the two divided signals.

Thereafter, the partial discharge noise removing device detects and compares the peak value of the output signal of the high speed log amplifier 31 and the peak value of the output signal of the low speed log amplifier 41 (S130), and the low speed at the peak value of the output signal of the high speed log amplifier 31. By subtracting the peak value of the log amplifier 41 output signal, the noise of the partial discharge sensor 10 detection signal is removed (S140).

Thus, the partial discharge noise removing device obtains the partial discharge signal from which the noise is removed (S150).

As described above, the apparatus for removing the partial discharge noise and the method thereof according to the present invention have been described with reference to the illustrated drawings. However, the present invention is not limited by the embodiments and drawings disclosed herein, and the technical idea is within the scope of protection. Can be applied.

10: Partial discharge sensor 13: low noise amplifier (LNA)
16: Variable Gain Amplifier (VGA) 20: Splitter
30: high speed circuit section 31: high speed log amplifier
35: analog-to-digital converter (ADC) 40: low-speed circuit portion
41: low speed log amplifier 45: analog-to-digital converter (ADC)
50: signal processing unit

Claims (15)

A partial discharge sensor detecting an electromagnetic wave signal generated during partial discharge in a power device;
A divider for distributing the electromagnetic wave signal into two identical signals;
A high speed circuit unit including a high speed log amplifier, and performing high speed signal processing on any one of the same two signals using the high speed log amplifier;
A low speed circuit unit including a low speed log amplifier and performing low speed signal processing on the other of the same two signals using the low speed log amplifier; And
The signal strengths of the first signal output from the high speed circuit unit and the second signal output from the low speed circuit unit are respectively measured, and the signal intensity peak value of the second signal is subtracted from the signal intensity peak value of the first signal. Partial discharge noise removing device comprising a; signal processing unit for removing the noise signal contained in the electromagnetic wave signal. The method according to claim 1,
The high speed circuit unit,
Partial discharge noise elimination device, characterized in that for detecting an electromagnetic wave signal having a high speed and a low operating speed. The method according to claim 2,
The high speed circuit unit,
And measuring the signal strength of the detected electromagnetic wave signal and outputting a voltage signal proportional to the measured signal strength. The method according to claim 1,
The low speed circuit portion,
Partial discharge noise elimination device characterized by detecting an electromagnetic wave signal having a low operating speed. The method of claim 4,
The low speed circuit portion,
And measuring the signal strength of the detected electromagnetic wave signal and outputting a voltage signal proportional to the measured signal strength. The method according to claim 1,
The high speed log amplifier,
Partial discharge noise canceller, characterized in that for processing the input signal at a set reaction rate within the range of 6ns to 60ns. The method according to claim 1,
The low speed log amplifier,
Partial discharge noise canceller, characterized in that for processing the input signal at a set reaction rate within the range of 60ns to 1000ns. The method according to claim 1,
The high speed log amplifier and the low speed log amplifier have different reaction rates,
And the high speed log amplifier has a faster response speed than the low speed log amplifier. The method according to claim 1,
The signal processing unit,
Partial discharge noise removing device characterized in that to remove the noise signal contained in the electromagnetic wave signal by subtracting the signal strength peak value for the output signal of the low speed log amplifier from the signal strength peak value for the output signal of the high speed log amplifier . Detecting an electromagnetic wave signal generated during partial discharge in a power device;
Splitting the electromagnetic wave signal into two identical signals at a splitter;
Signal processing of any one of the same two signals distributed in the distributing step at high speed using a high speed log amplifier, and a signal of the other of the same two signals at a low speed using a low speed log amplifier Processing;
Measuring signal strengths of the output signal of the high speed log amplifier and the output signal of the low speed log amplifier; And
And subtracting the signal strength peak value of the output signal of the low speed log amplifier from the signal strength peak value of the output signal of the fast log amplifier to remove the noise signal included in the electromagnetic wave signal. Partial discharge noise removal method. The method of claim 10,
The signal processing step,
And detecting an electromagnetic wave signal having a high speed and a low operating speed among the signals inputted by the high speed log amplifier, and outputting a voltage signal proportional to the detected signal strength. The method of claim 11,
Before measuring the signal strength,
Partial discharge noise removing method, characterized in that for converting the voltage signal output from the high-speed log amplifier to a proportional electromagnetic wave signal. The method of claim 10,
The signal processing step,
And detecting an electromagnetic wave signal having a low operating speed among the signals inputted by the low speed log amplifier, and outputting a voltage signal proportional to the detected signal strength. The method according to claim 13,
Before measuring the signal strength,
Partial discharge noise removing method, characterized in that for converting the voltage signal output from the low-speed log amplifier to a proportional electromagnetic wave signal. The method of claim 10,
Removing the noise signal,
And subtracting the signal intensity peak value of the output signal of the low speed log amplifier from the signal intensity peak value of the output signal of the high speed log amplifier.

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