KR101608275B1 - Power equipment acoustic diagnostic system - Google Patents

Abstract

The present invention relates to an electric power equipment acoustical diagnosis system, in which acoustic signals of a power plant are amplified and acoustic signals of a filter bank passing acoustic signals of a specific frequency band are analyzed to diagnose electric power facilities in real time, And it is an object of the present invention to provide a power equipment acoustic diagnosis system which can save power energy by enabling the accident facility to be replaced at an appropriate time through diagnosis prevention in advance.
To achieve these objects and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, there is provided an audio system, comprising: a sound collector for amplifying sound generated from a power facility and converting an acoustic signal in a specific frequency band of the amplified sound signal into a digital signal; And a digital filter for dividing a digital signal received from the sound collector into a plurality of signals by a bit unit and a signal passing through a filter bank unit of the sound collector, A diagnostic device; .

Description

Technical Field [0001] The present invention relates to a power equipment acoustic diagnostic system,

More particularly, the present invention relates to a power equipment acoustic diagnostic system, and more particularly, to a system for amplifying sound generated from a power facility, converting an acoustic signal into a digital signal, transmitting the signal to a diagnostic device, storing the received digital signal, The present invention relates to an energy-saving power equipment acoustic diagnostic system technology capable of preventing power plant problems and reducing power loss.

The causes of failure in domestic electrical equipment are natural deterioration, poor repair and poor manufacturing, accounting for 58.2%, which causes problems in reliability of power supply.

Currently, it detects the partial discharge generated when there is an abnormality in a power equipment such as a transformer and a gas insulated switch-gear (GIS) by using an electromagnetic wave, an acoustic sensor and a current to diagnose a defect, , And risk assessment.

In recent years, research and development have been conducted in connection with the present invention, and a large number of registered and disclosed in addition to Korean Patent No. 10-0784302 (hereinafter referred to as 'prior art document') have been disclosed.

The above prior art document includes a current detector for dividing the current signal into a plurality of channels according to the magnitude of the current signal inputted from the power device and the current signal divided into the plurality of channels, And a signal processing unit.

In this prior art document, a method of checking whether a power device is faulty by using a current signal inputted from a power device is used, but a current signal may be distorted by an abnormal current flowing from the outside, There was a limit that I could not confirm.

Korean Patent No. 10-0784302.

SUMMARY OF THE INVENTION The present invention has been conceived in view of the above problems, and it is an object of the present invention to provide a method and apparatus for analyzing an acoustic signal of a filter bank that amplifies sound generated in a power facility and passes an acoustic signal of a specific frequency band, It is an object of the present invention to provide a power equipment acoustic diagnosis system which can confirm whether or not a facility is faulty and can replace the accident facility at an appropriate time through diagnosis prevention in advance so as to save power energy.

According to an aspect of the present invention, there is provided a power equipment acoustic diagnostic system including: a sound collector for amplifying sound generated from a power facility and converting an acoustic signal of a specific frequency band of the amplified sound signal into a digital signal; And a digital filter for dividing a digital signal received from the sound collector into a plurality of signals by a bit unit and a signal passing through a filter bank unit of the sound collector, A diagnostic device; .

The sound collector may further include: an sound collecting sensor unit for picking up sound; An amplification unit amplifying the sound collected through the sound collection sensor unit; A filter bank unit for passing an acoustic signal of a specific frequency band among the acoustic signals amplified through the plurality of band pass filters; And an ADC unit for converting the analog sound signal having passed through the filter bank unit into a digital signal; And a control unit.

The diagnostic apparatus may further include: an interface unit for receiving a digital signal from the sound collector; An audio processing unit for converting the digital signal received through the interface unit into digital data and analog sound signals; The digital data and the analog sound signal converted by the audio processing unit are classified according to power facilities and the digital data is subdivided into a plurality of subdivided data by a bit unit and a signal bank that passes through the filter bank unit of the sound collector, A diagnostic unit for diagnosing abnormality data through time series and frequency series analysis of digital data and outputting real time diagnosis results; A database unit for storing a diagnosis result through the diagnosis unit; An alarm unit for generating an alarm sound when abnormality data is generated and transmitting the location and fault detail information of the electric power facility to the manager terminal; And a display unit for displaying a diagnosis result through the diagnosis unit in a waveform and a spectrogram of an acoustic signal; And a control unit.

The diagnosis unit may further include: a classification module for classifying the digital data and the analog sound signal converted by the audio processing unit by power equipment; A subdivision module for subdividing the converted digital data into bits and subdividing the subdivided digital data into a plurality of subdivisions so as to have a reference range for each signal passing through the filter bank section of the sound collector to monitor data values, ; And a diagnostic module for determining the location and fault information of the electric power facility when an abnormality occurs, when the abnormality occurs, ; And a control unit.

The diagnosis module outputs the diagnosis results to each electric power facility by time, month, and day, and provides the result.

According to the present invention, by analyzing the acoustic signal of the filter bank which amplifies the sound generated from the power equipment and passes the acoustic signal of the specific frequency band, the power equipment can be diagnosed in real time, , It is possible to improve the performance of electric power facilities, restoration of reliability, improvement of economical efficiency of maintenance, and replacement of accident facilities at an appropriate time.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a general configuration diagram conceptually showing a power equipment acoustic diagnostic system according to the present invention; FIG.
2 is a detailed configuration diagram of a diagnosis unit according to the present invention;
FIG. 3 is a diagram illustrating an example in which digital data according to the present invention is segmented into channels according to the number of signals that have passed through a filter bank unit. FIG.
FIG. 4 is a diagram illustrating an example of monitoring data by dividing digital data according to the present invention into channels according to the number of signals passed through the filter bank unit.
FIG. 5 is an exemplary diagram showing abnormal data through the magnitude and spectrogram of a signal according to the present invention; FIG.
6 illustrates an example of abnormal data generated in an actual power facility according to the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

The power equipment acoustic diagnostic system according to the present invention will now be described with reference to FIGS. 1 to 6. FIG.

FIG. 1 is an overall configuration diagram conceptually showing a power equipment acoustic diagnosis system S according to the present invention, and includes an audio sound collector 100 and a diagnostic apparatus 200 as shown in FIG.

The sound collector 100 amplifies the sound generated from the power equipment and converts the amplified sound into a digital signal. As shown in FIG. 1, the sound collector 100 includes an integration sensor 110, an amplification unit 120, a filter bank unit 130 and an ADC unit 140.

Specifically, the sound collection sensor unit 110 is a microphone sensor that picks up sound generated from a power facility such as a gas insulated switch-gear (GIS) and a main transformer (MTR).

At this time, the sound collection sensor unit 110 may include an ANN (Amine Noise Rejection) for removing noise of the sound collected.

The amplifying unit 120 amplifies the sound collected through the sound collecting sensor unit 110.

The filter bank unit 130 passes an acoustic signal of a specific frequency band among the acoustic signals amplified through the plurality of band pass filters. That is, the filter bank unit 130 can remove the noise by passing only the signal of the specific frequency band through the collected sound signal.

The ADC unit 140 converts an analog sound signal having passed through the filter bank unit 130 into a digital signal.

The diagnostic apparatus 200 monitors the data values by subdividing the digital signals received from the sound collector 100 into a plurality of bits each having a reference range for each bit passing through the filter bank section of the sound collector 100, 1, an audio processing unit 220, a diagnosis unit 230, a database unit 240, an alarm unit 250, and an alarm unit 250. The interface unit 210, the audio processing unit 220, And a display unit 260.

Specifically, the interface unit 210 receives a digital signal from the sound collector 100. At this time, the interface unit 210 can interface with the sound collector 100 wirelessly, and can be interfaced using a USB port as a wired line.

The audio processing unit 220 converts the digital signal received through the interface unit 210 into digital data and analog sound signals.

The diagnostic unit 230 classifies the converted digital data and the analog sound signal by the power processing unit 220 and converts the digital data into a bit range and a reference range for each signal that has passed through the filter bank unit of the sound collector 100 And performs a function of monitoring data values and diagnosing abnormality data through time series and frequency series analysis on digital data and outputting real-time diagnosis results. As shown in FIG. 2, 231, a segmentation module 232, and a diagnostic module 233.

Specifically, the classification module 231 classifies and stores the converted digital data and the analog sound signal by the power equipment through the audio processor 220.

As shown in FIGS. 3 and 4, the subdivision module 232 subdivides the converted digital data into 10 bits (preferably, 1024 bits) in units of bits, and further subdivides the digital data into a filter bank portion of the sound collector 100 (From -80 (dB) to 120 (dB) by dividing the data value into five levels so as to have a reference range in each signal (per channel) that has passed through the frequency band 130.

Here, the data value is based on the data obtained by averaging the signal values monitored for 10 seconds in a normal state where there is no problem in the electric power facility.

The diagnostic module 233 sets a reference value range having the minimum and maximum values for the subdivided digital data. If the range is out of the set reference value range, the diagnostic module 233 determines that the abnormal data is abnormal. . At this time, the diagnosis module 233 can output the diagnosis results to each electric power facility by time, month, and day.

Meanwhile, the diagnostic module 233 can measure signals in the time domain and the frequency domain as described above, and real-time data transmission is possible through the embedded software and the network can be expanded.

The database unit 240 stores diagnosis results through the diagnosis unit 230 so as to facilitate subsequent analysis.

The alarm unit 250 generates an alarm sound when abnormality data is generated as a result of the diagnosis through the diagnosis unit 230, and transmits the location and the failure history information of the electric power facility to the administrator terminal 10. At this time, the administrator terminal 10 can also generate an alarm according to the generation of abnormal data.

The display unit 260 displays the diagnostic result through the diagnosis unit 230 as a waveform and a spectrogram of the acoustic signal.

Accordingly, when abnormal data is generated as shown in FIG. 5, it can be confirmed that the signal size and spectrogram change in the time domain and the frequency domain.

In particular, when a switch is switched in the gas insulated switchgear (GIS), or when a problem actually occurs, it is possible to confirm that a problem has occurred in the power equipment as shown in Fig. 6, It notifies that there is a problem by transmitting the location and the fault detail information of the electric power facility.

As described above, the power equipment acoustic diagnostic system according to the present invention amplifies sound generated in a power facility including a gas insulated switchgear (GIS), a main transformer (MTR), and the like, By analyzing the acoustic signal of the filter bank passing through it, it can diagnose the power facilities in real time, so that it has a characteristic advantage that it can cope quickly in the case of failure of power facilities, prevent diagnosis and save energy.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

100: sound collector
200: Diagnostic device
110:
120:
130: Filter bank section
140: ADC section
210:
220:
230:
240:
250:
260:
231: Classification module
232: Segmentation module
233: Diagnostic module
10:

Claims (5)

A sound collector for amplifying sound generated from a power facility and converting an acoustic signal of a specific frequency band of the amplified sound signal into a digital signal; And
A plurality of the digital signals are subdivided using a subdivision module so that the digital signal received from the sound collector is divided into a bit unit and a signal passing through the filter bank unit of the sound collector, A diagnostic device for diagnosing data through frequency sequence analysis; Lt; / RTI >
The filter bank unit includes:
Allocating the digital signal according to the signal or channel according to the frequency band,
The channel may comprise:
And outputs a maximum value or a minimum value of the digital signal and compares the digital signal with a predetermined reference value to pass the digital signal to a plurality of band pass filters provided for each frequency band to output a difference value.
The method according to claim 1,
The sound collector,
A collecting sensor unit for collecting sound;
An amplification unit amplifying the sound collected through the sound collection sensor unit;
A filter bank unit for passing an acoustic signal of a specific frequency band among the acoustic signals amplified through the plurality of band pass filters; And
An ADC unit for converting an analog sound signal having passed through the filter bank unit to a digital signal; Wherein the power plant acoustic diagnostic system comprises:
The method according to claim 1,
The diagnostic apparatus may further comprise:
An interface for receiving a digital signal from the sound collector;
An audio processing unit for converting the digital signal received through the interface unit into digital data and analog sound signals;
The digital data and the analog sound signal converted by the audio processing unit are classified according to power facilities and the digital data is subdivided into a plurality of subdivided data by a bit unit and a signal bank that passes through the filter bank unit of the sound collector, A diagnostic unit for diagnosing abnormality data through time series and frequency series analysis of digital data and outputting real time diagnosis results;
A database unit for storing a diagnosis result through the diagnosis unit;
An alarm unit for generating an alarm sound when abnormality data is generated and transmitting the location and fault detail information of the electric power facility to the manager terminal; And
A display unit for displaying a diagnosis result through the diagnosis unit in waveform and spectrogram of an acoustic signal; Wherein the power plant acoustic diagnostic system comprises:
The method of claim 3,
Wherein the diagnosis unit comprises:
A classification module for classifying the digital data and the analog sound signal converted by the audio processing unit by power equipment;
A subdivision module for subdividing the converted digital data into bits and subdividing the subdivided digital data into a plurality of subdivisions so as to have a reference range for each signal passing through the filter bank section of the sound collector to monitor data values, ; And
A diagnostic module that sets a reference value range having minimum and maximum values for the subdivided digital data, determines the data as abnormal data if the range is out of the set reference value range, and confirms the location and failure detail information of the power equipment when the abnormality occurs; Wherein the power equipment acoustic diagnostic system comprises:
5. The method of claim 4,
The diagnostic module includes:
And outputting diagnosis results to each electric power facility by time, month, and day.

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