KR101417191B1 - System and Method for Analyzing Partial Discharge Risk of Power Equipment - Google Patents

Abstract

The present invention can detect and analyze electromagnetic waves generated due to partial discharge (PD) in a power device and determine a risk thereof. Particularly, the magnitude of the pulse signal generated due to the partial discharge (q parameter) is compensated to have a constant value irrespective of the frequency characteristics of the sensor or the related circuit, and then the magnitude of the compensated pulse signal is used to determine the risk. Since the size of the electromagnetic wave generated by the partial discharge is normalized so as not to depend on the frequency characteristic of the system, even if the frequency characteristic of the system for determining the risk varies, the risk of the power equipment can be accurately .

Description

TECHNICAL FIELD [0001] The present invention relates to a system and a method for analyzing a power device,

The present invention relates to a system and method for analyzing a risk of an electric power apparatus, and more particularly, to a system and method for detecting and analyzing electromagnetic waves generated by a partial discharge (PD) in an electric power apparatus.

As the electric power equipment becomes larger and larger, the possibility of various types of accidents is increasing, and the scale of damage caused by accidents is also increasing. Accordingly, various diagnostic techniques and advanced equipments for detecting an abnormal signal in a power device are being developed before an accident occurs.

UHF PD measurement technique is widely used as a method for diagnosis of power equipment. This technique detects an electromagnetic wave generated by a physical phenomenon called a partial discharge when there is a defect inside the power device, and discriminates an abnormality.

Partial discharge (PD) is not a phenomenon occurring between an electrode and an electrode but refers to a discharge phenomenon occurring in any part of an insulator or a cable.

For example, a corona discharge in the vicinity of the tip of a sharp electrode in the gas, a creeping discharge along the surface of the solid insulator, and a void discharge in the pores in the solid insulator.

In the partial discharge measurement technique, the phase (φ), the magnitude (q), and the frequency (n) of the partial discharge signal are used to determine whether or not the power device is abnormal, as shown in FIG.

That is, it is possible to determine the phase of the partial discharge pulse and how many of the partial discharge pulses are generated in any phase to determine whether or not the power device is abnormal.

FIG. 1A shows a three-dimensional φ-q-n graph, and FIG. 1B is a graph showing the results of analysis of φ-q, φ-n, and q-n in two dimensions, respectively.

Such a pattern differs depending on free conductive particle defects, floating electrode defects, insulator defects, noise, etc., which cause anomalies. Therefore, the cause of a defect in the power device can be determined by analyzing the pattern.

Here, the phase (?) Data is a main parameter for estimating the kind of defect causing partial discharge, and the size (q) data is a main parameter for estimating the risk and state.

FIG. 2 shows an example of a PPS (Pulse Per Second) analysis technique for a partial discharge signal. The number of times a partial discharge pulse of a predetermined magnitude or more is detected for one second is measured to manage a trend.

For example, assuming that the precautionary reference value is set to 2000 and the risk reference value is set to 4000, if the partial discharge pulses are introduced in a quantity of 2,000 or more per second, a critical state is indicated. If the partial discharge pulses exceed 4000 per second, State.

3, a partial discharge pulse is generated in the middle of the operation voltage of the power device when an insulation fault exists in the power device under operation due to the application of the grid voltage. The cause of the defect can be estimated by analyzing the generation phase (φ), the size (q), and the frequency (n) of the partial discharge pulse.

4A is an example of a partial discharge pattern that appears at the protruding portion of the conductor portion, FIG. 4B is an example of a partial discharge pattern of the void portion, FIG. 4C is an example of a partial discharge pattern that appears when a free conductive particle defect occurs. FIG.

On the other hand, the q parameter indicating the magnitude of the partial discharge pulse is a main parameter for determining the state and the degree of danger of the electric power equipment, and is largely dependent on the frequency characteristic of the sensor or the related circuit that senses the electromagnetic wave generated by the partial discharge.

That is, the risk assessment criteria related to the q parameter are dependent on the frequency characteristics. Therefore, if the frequency characteristics of the sensor for detecting the electromagnetic wave generated by the partial discharge or the circuit for receiving and processing the received signal are changed, the q parameter also fluctuates and the accuracy of the risk determination must be deteriorated.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a pulse width modulation (PWM) The present invention also provides a system and method for analyzing a risk of an electric power equipment, which can accurately determine a risk associated with a q parameter regardless of a frequency characteristic.

According to an aspect of the present invention, there is provided a risk analysis system for a power device, comprising: a PD sensor for sensing an electromagnetic wave generated due to a partial discharge (PD) in a power device; A PD detector for receiving the electromagnetic wave signal sensed by the PD sensor and detecting a pulse signal of a predetermined frequency band; In order to compensate for the degree of distortion due to the combined frequency characteristics of the frequency characteristics of the PD sensor and the PD detection unit, the magnitude of the pulse signal detected by the PD detection unit is converted into a characteristic curve that is inverse to the curve of the sum frequency characteristic A compensating unit for compensating using the set compensation information; And a risk judging unit for judging a risk of the power equipment on the basis of the number and size of pulse signals generated for a predetermined time.

As the PD sensor, a sensor for detecting an electromagnetic wave in a UHF (Ultra-High Frequency) band may be used.

The compensation information may be set such that the magnitude of the pulse signal detected by the PD detector is not dependent on the frequency characteristics of the PD sensor and the PD detector.

The compensation information may be set in the form of a compensation equation or a compensation table.

The risk judging unit maps the number and size of pulse signals generated for a predetermined time to a QN (Quantity / Number) matrix, compares the position mapped to the QN matrix with a preset risk judgment criterion, .

A risk analysis method for a power device according to the present invention is a risk analysis method for a power device that detects an electromagnetic wave generated by a partial PD in a power device to determine a risk of the power device, Sensing an electromagnetic wave generated due to a partial discharge in the power device; The PD detection unit detects a pulse signal from electromagnetic waves sensed through the PD sensor and the magnitude of the detected pulse signal is adjusted to compensate for the degree of distortion due to the sum frequency characteristics of the frequency characteristics of the PD sensor and the PD detection unit, Compensating using compensation information preset in the form of a characteristic curve which is inverse to the curve of the sum frequency characteristic; And determining the risk of the power device based on the number and size of the pulse signals generated during a predetermined time.

The compensation information may be set such that the magnitude of the pulse signal has a constant value without being dependent on the frequency of the electromagnetic wave.

Wherein the step of determining the risk of the power device comprises the steps of mapping the number and size of pulse signals generated for a predetermined time to a QN (Quantity / Number) matrix, and comparing a position mapped to the QN matrix with a predetermined risk- And to determine the risk of the power device.

According to the present invention, the magnitude (q parameter) of the electromagnetic wave generated due to the partial discharge is compensated so as not to depend on the frequency characteristics of the sensor or the related circuit, and is used for risk assessment of the power device after normalization.

That is, even if the magnitude of the pulse signal generated due to the partial discharge is detected to be larger or smaller than the original size according to the frequency characteristic of the sensor or the related circuit, compensation is performed to the original size and then processed.

Therefore, even if the frequency characteristics of the sensor for detecting the electromagnetic wave generated by the partial discharge and the circuit for receiving and processing the signal sensed by the sensor are changed, the risk of the power device can be accurately determined using the same risk criteria .

1 is an example of a risk analysis graph using? -Qn,
2 illustrates an example for explaining the PPS technique,
3 is an example showing a state in which a partial discharge pulse appears,
FIG. 4 shows an example of an abnormal pattern that appears according to a defect of the power device,
5 is a diagram illustrating an embodiment of a risk analysis system according to the present invention,
FIG. 6 is a schematic diagram illustrating a process of compensating for the magnitude of a pulse signal,
Figure 7 is an example of a QN matrix used for risk determination,
FIG. 8 is an embodiment of a risk analysis method according to the present invention.

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

5, the risk analysis system 50 of the power equipment according to the present invention includes a PD sensor 51, a PD detection unit 52, a compensation unit 53, and a risk judgment unit 54. [ The PD detection unit 52, the compensation unit 53 and the risk degree determination unit 54 of the risk analysis system 50 are constituted by a device separate from the PD sensor 51 and are generated from the PD sensor 51 An electromagnetic wave signal can be received.

The PD sensor 51 senses an electromagnetic wave generated due to a partial discharge (PD) in the power device 11.

The partial discharge may be caused by various causes such as cracks in the power device 11 such as an electric distribution board, a load break switch, and a mold transformer, a conductor protrusion, a floating body, and the like.

The PD sensor 51 can sense an electromagnetic wave in a UHF (Ultra-High Frequency) band caused by a partial discharge.

The PD detection unit 52 receives the electromagnetic wave signal detected by the PD sensor 51 from the PD sensor 51 and detects a pulse signal of a predetermined frequency band. At this time, the PD detection unit 52 can wirelessly receive the electromagnetic wave signal sensed by the PD sensor 51.

Although one PD sensor is shown in FIG. 5, a plurality of PD sensors may be provided. In this case, unique identification information is assigned to each PD sensor so that the PD detecting unit 52 can recognize which electromagnetic wave signal is detected by which PD sensor.

The compensation unit 53 compensates the magnitude of the pulse signal detected by the PD detection unit 52 by using the compensation information.

The compensation information refers to information for compensating the magnitude of the pulse signal detected due to the partial discharge so as to have a normalized value without depending on the frequency characteristics of the PD sensor 51 and the PD detector 52. [

Referring to FIG. 6, the magnitude of the electromagnetic wave signal sensed through the PD sensor 51 has a characteristic that varies depending on the frequency as shown in FIG. 6A.

When the PD sensor 51 transmits the detected electromagnetic wave signal to the PD detector 52 in a wireless manner, the PD detector 52 detects the RF (Radio Frequency) signal for receiving the RF Circuit.

In this case, the magnitude of the electromagnetic wave signal received by the PD detector 52 also varies depending on the frequency as shown in FIG. 6B.

As a result, the electromagnetic wave signal generated due to the partial discharge has the frequency characteristic of the risk analysis system in which the frequency characteristics of the PD sensor 51 and the PD detector 52 are both combined as shown in FIG. 6C.

Therefore, in order to standardize the pulse signal of the electromagnetic wave generated due to the partial discharge to have a constant value without depending on the frequency characteristics of the PD sensor 51 and the PD detector 52, the frequency characteristic curve of FIG. The compensation curve should be used.

That is, the magnitude of the original pulse signal generated due to the partial discharge compensates for the degree of distortion due to the frequency characteristics of the PD sensor 51 and the PD detector 52.

In this case, if the frequency characteristic curve of FIG. 6C can be expressed by a statistical technique such as a periodic analysis, the equation (y = F [x]) can be expressed. In this case, [x]).

The original electromagnetic wave signal (FIG. 6F) generated due to the partial discharge in the absence of compensation will be detected in a distorted size according to the frequency characteristic curve shown in FIG. 6C. However, the frequency characteristic of the risk analysis system, The distortion of the magnitude can be compensated to detect the magnitude of the original electromagnetic wave signal generated due to the partial discharge (FIG. 6G).

As a specific example, if the frequency of the electromagnetic wave signal is 0.7 GHz and the magnitude at the level of dB (dB) is 33.6 dB in FIG. 6C, this size should be reduced by 1.5 dB.

The compensation information is used to empirically examine and set the frequency characteristics of the PD sensor 51 and the PD detector 52 in advance. The compensation information may be set in a form of a compensation equation, Table).

The risk judgment unit 54 judges the risk of the power equipment 11 based on the number and size of the compensated pulse signals through the compensation unit 53. [

The method for determining the risk by using the number and size of the pulse signals generated due to the partial discharge may be variously configured.

One example is to map the number and magnitude of pulse signals generated due to partial discharges for a certain period of time (e.g., 1 second) to a QN (Quantity / Number) matrix and compare the position mapped to the QN matrix with a predetermined risk criterion To determine the risk level of the power device 11.

At this time, as the magnitude of the pulse signal due to the partial discharge, the average magnitude of the pulse signals generated during the corresponding time can be used.

To this end, the risk judgment unit 54 stores and maintains QN matrix information on the number and size of the pulse signals in a memory, and a range of risk (safety, attention, risk, etc.) have.

FIG. 7 shows an example of a QN matrix. The x-axis is divided according to the number of pulse signals detected for a predetermined time, and the y-axis is divided according to the average size of pulse signals detected for a predetermined time.

The risk level determining unit 54 maps the number and the size of the pulse signals detected for a predetermined time to the QN matrix, and determines the risk level based on the mapped position, safety, attention, and the like.

As described above, since the pulse signal detected by the PD detecting section 52 is normalized so as not to be influenced by the frequency characteristics, the risk determination criterion such as the example shown in FIG. 7 can be used as appropriate reference information in any system.

Referring to FIG. 8, an embodiment of a risk analysis method of an electric power apparatus according to the present invention will be described.

First, a PD sensor is used to detect an electromagnetic wave generated due to a partial discharge in the power device (S81).

Particularly, in step S81, the PD sensor that senses the electromagnetic wave generated due to the partial discharge can detect electromagnetic waves in the UHF (Ultra-High Frequency) band.

When an electromagnetic wave signal is detected through the PD sensor, a pulse signal is detected from the sensed electromagnetic wave (S82), and the magnitude of the detected pulse signal is compensated using the compensation information 53-1 (S83).

At this time, the compensation information is set so that the magnitude of the original pulse signal generated due to the partial discharge is not dependent on the frequency characteristics of the PD sensor, the RF circuit for receiving the RF (Radio Frequency) signal transmitted by the PD sensor, and the like.

The compensation information may be set in a form of a compensation equation, or may be set in the form of a compensation table.

Then, the risk of the power equipment is determined based on the number and size of pulse signals generated for a predetermined time (e.g., 1 second) (S84).

In the risk determination in step S84, the number and size of pulse signals generated due to the partial discharge for a predetermined time are mapped to a QN (Quantity / Number) matrix, and a position mapped to the QN matrix is compared with a predetermined risk judgment reference And a method for determining the risk level of the electric power equipment.

At this time, as the magnitude of the pulse signal due to the partial discharge, the average magnitude of the pulse signals generated during the corresponding time can be used.

As described with reference to FIG. 7, the risk (safety, attention, risk, and the like) for each position of the QN matrix is predetermined, and the more the risk is classified according to the matrix position, the greater the accuracy.

That is, in step S84, the number and the size of the pulse signals detected for a predetermined time are mapped to the QN matrix, and the risk is determined based on the mapped position, safety, attention, and the like.

If the risk determined in step S84 is a critical level or a critical level, a message informing the administrator of the risk can be transmitted to other devices using various types of wire / wireless communication methods.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various changes and modifications may be made by those skilled in the art without departing from the technical spirit of the present invention. to be.

11: Power equipment 50: Power equipment risk analysis system
51: PD sensor 52: PD detector
53: compensation section 54: risk judgment section

Claims (8)

A PD sensor for detecting an electromagnetic wave generated due to a partial discharge (PD) in a power device;
A PD detector for receiving the electromagnetic wave signal sensed by the PD sensor and detecting a pulse signal of a predetermined frequency band;
In order to compensate for the degree of distortion due to the combined frequency characteristics of the frequency characteristics of the PD sensor and the PD detection unit, the magnitude of the pulse signal detected by the PD detection unit is converted into a characteristic curve that is inverse to the curve of the sum frequency characteristic A compensating unit for compensating using the set compensation information; And
And a risk judging unit for judging a risk of the power equipment on the basis of the number and size of pulse signals generated for a predetermined time. The method according to claim 1,
Wherein the PD sensor senses an electromagnetic wave in a UHF (Ultra-High Frequency) band. The method according to claim 1,
Wherein the compensation information is set such that the magnitude of the pulse signal detected by the PD detection unit is not dependent on the frequency characteristics of the PD sensor and the PD detection unit. The method of claim 3,
Wherein the compensation information is set in a form of a compensation equation or a compensation table. The method according to claim 1,
The risk judging unit maps the number and size of pulse signals generated for a predetermined time to a QN (Quantity / Number) matrix, compares the position mapped to the QN matrix with a preset risk judgment criterion, Wherein said power analyzer comprises: A method for analyzing a risk of an electric power equipment for detecting an electromagnetic wave generated by a partial discharge (PD) in the power equipment to determine a risk of the power equipment,
Sensing an electromagnetic wave generated by a partial discharge in the power device using a PD sensor;
The PD detection unit detects a pulse signal from electromagnetic waves sensed through the PD sensor and the magnitude of the detected pulse signal is adjusted to compensate for the degree of distortion due to the sum frequency characteristics of the frequency characteristics of the PD sensor and the PD detection unit, Compensating using compensation information preset in the form of a characteristic curve which is inverse to the curve of the sum frequency characteristic; And
And determining a risk of the power device based on the number and size of the pulse signals generated for a predetermined period of time. The method according to claim 6,
Wherein the compensation information is set such that the magnitude of the pulse signal has a constant value without being dependent on the frequency of the electromagnetic wave. The method according to claim 6,
Wherein the risk determination is performed by mapping the number and size of the pulse signals to a QN (Quantity / Number) matrix and comparing a position mapped to the QN matrix with a predetermined risk criterion.

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