KR100999575B1 - System and method for measuaring partial discharge for power cable - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system and method for measuring partial discharge of a power cable capable of accurately grasping the position of occurrence of partial discharge in a power cable embedded in a wide range and enabling quick maintenance work or maintenance work. According to the present invention, there is provided a system for identifying the occurrence position of partial discharge in a power cable, and is mounted across one or more connection points included in the power cable to detect a signal (partial discharge signal) due to the occurrence of the partial discharge. A sensor unit configured to receive a signal sensed by the sensor unit, and analyze the detected signal to determine one or more on-site diagnosis units for determining a location of a partial discharge and a direction in which the partial discharge signal proceeds, and determining the one or more on-site diagnosis units. A system is provided that includes a central server that finally expresses the location of occurrence of a partial discharge and displays it together with the progress direction of the partial discharge signal.

Power cable, partial discharge, partial discharge signal, strength, phase, attenuation

Description

SYSTEM AND METHOD FOR MEASURED PARTIAL DISCHARGE IN A POWER CABLE {SYSTEM AND METHOD FOR MEASUARING PARTIAL DISCHARGE FOR POWER CABLE}

The present invention relates to a system and method for measuring a partial discharge of a power cable, and more particularly, it is possible to accurately grasp the location of the occurrence of partial discharge in a power cable that is embedded over a wide range, and to perform a quick maintenance work or maintenance work. A partial discharge measurement system and method for power cables.

Partial discharge is a local electrical discharge phenomenon in an insulation system, and is called partial discharge because it occurs in a part of an insulator and does not cause complete insulation breakdown between electrodes.

Such partial discharges may be generated in a gas in the presence of voids or voids in solid or liquid dielectrics, surface discharges at the interface of different insulating materials, or when a strong uneven field is applied. This concept includes all discharge phenomena such as corona discharge and electric tree discharge caused by the continuous effects of discharge in solid dielectric.

Partial discharges can be caused by loss of dielectric strength due to manufacturing and construction defects, maintenance defects, operational stress, natural deterioration, etc. Typically, the detection of such partial discharges is the conversion of energy generated during partial discharges. By sensing the

Meanwhile, in recent years, high voltage or ultra high voltage underground power cables have been widely used for the transmission of high voltage power. High-voltage or ultra-high voltage underground power cable is a concept that includes a power cable embedded in underground lines by means of hollow holes, power pipes, tunnels, ducts, direct sales, etc. for the transmission of high voltage power of 22.9 kV or more and its accessories.

Types of ultra high voltage underground power cables include cross linked polyethylene (XLPE) and oil filled (OF). For example, the cause of partial discharge of the ultra high voltage underground power cable will be briefly described.

Operational conditions due to component defects, assembly defects, conductive / insulating foreign objects, external shocks, abrasion, surge, heat, salt, moisture, dust, external shocks, etc. that may occur during the manufacture, construction, and maintenance of ultra high voltage underground power cables When stress, naturally occurring aging, etc. are applied over a long time, the insulation strength of the cable is gradually lowered to reach an insulation breakdown, which is accompanied by a partial discharge along with the insulation breakdown.

The DC voltage test, the AC voltage no-load test, and the partial discharge test have been conducted simultaneously since the 1960s as a method of detecting partial discharge in the insulated ultra high voltage underground power cable. It is not established, and the development of the partial discharge detection technology by the high frequency partial discharge measurement method is in progress.

Briefly, the high frequency partial discharge measurement method, when partial discharge occurs in the insulator of the power cable, the discharge current proceeds along the cable in the form of traveling wave and has a frequency of several hundred MHz. If a partial discharge occurs in the power cable, the frequency of the traveling wave is attenuated to have a frequency of about 1 to 50 MHz. The partial discharge is measured by detecting a signal having the band thus attenuated by various sensors.

On the other hand, the technique of identifying the location of the partial discharge of the ultra-high voltage underground power cable is an important technology that enables rapid cause analysis, life prediction, prevention or recovery in the event of an accident during line operation of the power system. The method of expressing the partial discharge position of the power cable includes a method of using the pulse arrival time difference between the direct wave and the reflected wave of the partial discharge generation signal, and a method of using the phase of the signal with respect to the connecting member off-line.

1 shows the overall configuration of a conventional system that detects partial discharge of an ultra-high voltage underground power cable and expresses its position.

As shown in FIG. 1, the power cable includes three transmission lines of A phase, B phase, and C phase, and a conventional system for measuring partial discharge thereof includes an RF sensor unit for detecting a high frequency partial discharge signal. 110, an A / D converter 130 for converting an analog signal detected by the RF sensor 110 into a digital signal, and a partial discharge measuring instrument 150 for periodic inspection.

The RF sensor unit 110 detects the arrival of the direct wave and the reflection wave of the signal generated at the partial discharge point. By using the difference in arrival time between the direct wave and the reflected wave, the position of the partial discharge can be expressed. The A / D converter 130 converts a signal from the RF sensor unit 110 into a digital signal and then transmits the signal to a controller (not shown) that performs signal processing through an optical network.

Such a system is capable of real-time detection of partial discharge and expression of its position, but is essential for visual synchronization of the entire system, that is, the entire system including a plurality of RF sensor units 110 and A / D converters 130. There is a problem of having to configure an expensive optical network.

In addition, since the entire system is connected in series, there is a disadvantage in that a failure of one equipment causes problems in the entire system.

The power cable includes an insulation joint (IJ) 101 and a normal joint (NJ) 103. Since the RF sensor unit 110 is provided only at the insulation joint 101, the RF sensor unit For partial discharges generated at a long distance from 110, there may be a problem that the measurement is inaccurate due to the attenuation of the signal generated by the partial discharges. There may be a problem that the detection and the expression of the position are inaccurate.

In addition, the site where the power cable is located does not go through the data processing, only A / D conversion is performed, there is a fear of the data bottleneck of the server due to the large data generation.

On the other hand, the periodic inspection using the partial discharge measuring instrument 150 may be checked off-line regularly, but the measurement range of the partial discharge is limited to the surroundings of the connecting member installed with the measuring instrument 150, and real-time diagnosis is impossible, so when an accident occurs Not only are they unable to cope quickly or monitor, but there are also problems that preventive diagnosis is impossible.

Therefore, there is an urgent need to develop technologies for real-time measurement and online measurement, preventive diagnosis of facilities, accurate positional expression of partial discharges, rapid recovery in the event of a failure, detection of partial discharge occurrences that enable the system to be implemented at low cost, and their positional expressions. .

The present invention is to solve the above-mentioned problems of the prior art, and by using the attenuation of the signal due to the partial discharge of the power cable and the phase change thereof, the accurate position determination of the partial discharge and the direction determination of the partial discharge signal is determined. Its purpose is to make it possible.

In addition, another object of the present invention is to compare the signals detected in the plurality of connecting members formed on the power cable with each other, so that it is possible to accurately measure the partial discharge generated not only around the connecting member but also at a point relatively relatively far from the connecting member. will be.

Further, another object of the present invention is to enable quick maintenance work in addition to the measurement of partial discharge.

According to one embodiment of the present invention for achieving the above object, a system for identifying the occurrence position of the partial discharge in the power cable, which is mounted at both ends of one or more connection points included in the power cable, Sensor unit for detecting a signal (partial discharge signal) due to the occurrence, One or more field diagnosis unit for determining the occurrence position of the partial discharge and the direction of the partial discharge signal by receiving the signal sensed by the sensor unit and analyzing it And a central server for finally expressing a location of occurrence of partial discharge on the basis of the determination of the one or more on-site diagnosis units and displaying it together with the direction of travel of the partial discharge signal.

The on-site diagnosis unit may include a position determination unit determining a generation position of the partial discharge based on the signal sensed by the sensor unit, and a direction determination unit determining the moving direction of the partial discharge signal.

The position determining unit determines the position of the partial discharge by using the attenuation amount of the partial discharge signal, the attenuation amount of the partial discharge signal, the loss (conductor loss) by the conductor included in the power cable and the power cable It can be expressed as the sum of the losses (dielectric losses) due to the dielectric contained in the.

The conductor loss,

(dB/m) 와 상기 센서부로부터 부분방전 발생 지점까지의 거리의 곱으로 표현되고,

expressed as the product of (dB / m) and the distance from the sensor portion to the partial discharge occurrence point,

The dielectric loss is,

(dB/m) 와 상기 센서부로부터 부분방전 발생 지점까지의 거리의 곱으로 표현되며,

expressed as the product of (dB / m) and the distance from the sensor unit to the partial discharge occurrence point,

는 상기 전력 케이블의 도체 손실률,

은 상기 전력 케이블에 포함되는 도체의 단위 길이당 저항,

는 상기 도체의 특성 임피던스,

는 상기 도체의 도전율,

는 상기 도체의 등가 표피 두께, a는 상기 도체의 내부 도체 외경, b는 상기 도체의 외부 도체 내경,

는 상기 전력 케이블의 유전 손실률,

로서,

는 상기 부분방전 신호의 공기 중 파장, 및

은 상기 전력 케이블에 포함되는 유전체의 비유전율이다. here,

Is the conductor loss rate of the power cable,

Is a resistance per unit length of the conductor included in the power cable,

Is the characteristic impedance of the conductor,

Is the conductivity of the conductor,

Is the equivalent skin thickness of the conductor, a is the outer conductor outer diameter of the conductor, b is the outer conductor inner diameter of the conductor,

Is the dielectric loss rate of the power cable,

as,

Is the wavelength in air of the partial discharge signal, and

Is the relative dielectric constant of the dielectric included in the power cable.

When the partial discharge signal is advanced from the input side (primary side) of the sensor unit to the output side (secondary side), the direction determination unit does not change a phase before and after the input to the sensor unit, but on the input side from the output side (secondary side) direction of the sensor unit. When proceeding in the (primary side) direction, the direction in which the partial discharge signal travels may be determined using a characteristic in which the phase is changed 180 degrees before and after input to the sensor unit.

The central server compares the attenuation amounts of the partial discharge signals analyzed by the one or more on-site diagnostics to finally determine the location of the partial discharge, and then the position expression unit expressing the partial discharge, and the finally determined partial discharge. It may include an importance determination unit for weighting the occurrence position.

The sensor unit may be an RF sensor.

The system may further include a data transmission unit for transmitting the determination result from the field diagnosis unit to the central server.

The data transmission unit may be an optical transceiver unit (OTU).

According to another embodiment of the present invention for achieving the above object, as a method for identifying the occurrence position of the partial discharge in the power cable, using a sensor mounted across one or more connection points included in the power cable Detecting a signal (partial discharge signal) due to the occurrence of the partial discharge; analyzing the detected signals to determine the location of the partial discharge and the direction in which the partial discharge signal proceeds; and based on the determinations A method is provided that includes finally expressing a location of occurrence of a discharge and displaying the discharge along with a direction of travel of the partial discharge signal.

In the determining of the occurrence position of the partial discharge, the occurrence position of the partial discharge is determined by using the attenuation amount of the partial discharge signal, and the attenuation amount of the partial discharge signal is a loss due to a conductor included in the power cable (conductor Loss) and a loss (dielectric loss) caused by a dielectric included in the power cable.

The conductor loss,

(dB/m) 와 상기 센서부로부터 부분방전 발생 지점까지의 거리의 곱으로 표현되고,

expressed as the product of (dB / m) and the distance from the sensor portion to the partial discharge occurrence point,

The dielectric loss is,

(dB/m) 와 상기 센서부로부터 부분방전 발생 지점까지의 거리의 곱으로 표현되며,

expressed as the product of (dB / m) and the distance from the sensor unit to the partial discharge occurrence point,

는 상기 전력 케이블의 도체 손실률,

은 상기 전력 케이블에 포함되는 도체의 단위 길이당 저항,

는 상기 도체의 특성 임피던스,

는 상기 도체의 도전율,

는 상기 도체의 등가 표피 두께, a는 상기 도체의 내부 도체 외경, b는 상기 도체의 외부 도체 내경,

는 상기 전력 케이블의 유전 손실률,

로서,

는 상기 부분방전 신호의 공기 중 파장, 및

은 상기 전력 케이블에 포함되는 유전체의 비유전율이다. here,

Is the conductor loss rate of the power cable,

Is a resistance per unit length of the conductor included in the power cable,

Is the characteristic impedance of the conductor,

Is the conductivity of the conductor,

Is the equivalent skin thickness of the conductor, a is the outer conductor outer diameter of the conductor, b is the outer conductor inner diameter of the conductor,

Is the dielectric loss rate of the power cable,

as,

Is the wavelength in air of the partial discharge signal, and

Is the relative dielectric constant of the dielectric included in the power cable.

The determining of the traveling direction of the partial discharge signal may include: when the partial discharge signal travels from the input side (primary side) to the output side (secondary side) of the sensor, the phase does not change before and after the input to the sensor. When traveling from the output side (secondary side) direction to the input side (primary side) direction, the direction in which the partial discharge signal travels may be determined by using a characteristic in which the phase changes 180 degrees before and after input to the sensor.

The final expression of the location of the partial discharge may include: comparing the attenuation amounts of the partial discharge signals analyzed in the determining of the location of the partial discharge, determining the location of the partial discharge, and finally expressing the location of the partial discharge. And weighting the finally determined location of the partial discharge.

According to the present invention, by using the attenuation of the signal due to the partial discharge of the power cable and the phase change thereof, it is possible to accurately determine the position of occurrence of the partial discharge and to determine the direction of the partial discharge signal.

Further, according to the present invention, by comparing the signals detected in the plurality of connecting members formed on the power cable with each other, it is possible to accurately measure the partial discharge generated not only around the connecting member but also at a point relatively far from the connecting member.

In addition, according to the present invention, by assigning weights to the points where the partial discharge has occurred, maintenance work from a high risk point is possible.

DETAILED DESCRIPTION The following detailed description of the invention refers to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is defined only by the appended claims, along with the full range of equivalents to which such claims are entitled. Like reference numerals in the drawings refer to the same or similar functions throughout the several aspects.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

Configuration of the entire system

FIG. 2 is a diagram schematically showing the configuration of an entire system for detecting a partial discharge of a power cable and facializing its position according to an embodiment of the present invention. Here, the expression means to indicate the position where the partial discharge occurred in the power cable.

As shown in FIG. 2, the power cable 200 may include a body of the power cable 200 and a connection point 205. The connection point 205 serves as a connection point between the power cable 200 or a connection point between the power cable 200 and other equipment and at the same time maintains electrical performance at that point.

On the other hand, the entire system of the present invention for detecting the partial discharge occurring in the power cable 200 and the expression of the position, the sensor unit 210, the field diagnosis unit 230, the data transmission unit 250, and It may be configured to include a central server (270).

The sensor unit 210 may be configured as an RF sensor, and may be installed at the body of the power cable 200, specifically, at both ends of the connection point 205 or at ground. The sensor unit 210 detects the high frequency partial discharge signal of the power cable 200. That is, when a partial discharge occurs at any point of the power cable 200, a signal according to this progresses along the power cable 200, the sensor unit 210 detects such a signal, a plurality of sensors By using the correlation between the signals detected by the unit 210, it is possible to determine the occurrence and location of the partial discharge.

Meanwhile, the power cable 200 generally includes three transmission lines having different phases with the same phase difference, and the sensor unit 210 is mounted at both ends of the connection point 205 formed at each transmission line. do. Accordingly, six sensor units 210 formed at both ends of the connection point 205 of the power cable 200 including three transmission lines form a group.

The field diagnosis unit 230 may be referred to as a local unit (LU), and receives a partial discharge signal received from the sensor unit 210. The on-site diagnosis unit 230 is composed of all six channels may receive a partial discharge signal transmitted from the six sensor unit 210. After receiving the six signals, the strength or phase of each signal is identified and the correlation between the six signals is analyzed. Analysis of these correlations can identify the point of occurrence of the partial discharge, and may determine whether the partial discharge occurred in the body of the power cable 200 or the connection point 205, and which of the three transmission lines It is also possible to determine whether a failure has occurred in the transmission line. The processing of the results of the correlation analysis of each of the partial discharge signals will be described later in detail.

Meanwhile, the data transmitter 250 may be implemented as an optical transceiver unit (OTU) or the like, and transmits data processed by the field diagnosis unit 230 to the central server 270.

The central server 270 receiving the data expresses the location of the partial discharge using a predetermined algorithm. First, the point of occurrence of the partial discharge or the direction of the partial discharge, etc., which are inaccurately identified by the on-site diagnosis unit 230 are more accurately determined, and finally, the position of the partial discharge is expressed by using the result. As will be described later, the field diagnosis unit 230 can accurately detect the occurrence of the partial discharge near the connection point 205 of the power cable 200, but the distance from the connection point 205 to the partial discharge occurrence point will be farther away. The more difficult it is to grasp. The measurement of the location of the partial discharge occurrence in the central server 270 is to compensate for this, and this method will be described in detail later.

Hereinafter, with the detailed configuration of the on-site diagnosis unit 230, the on-site diagnosis unit 230 receives a partial discharge signal received from the sensor unit 210, for the process of detecting the position where the partial discharge occurred Let's explain.

Generation position detection method of partial discharge

3 is a view showing a detailed configuration of the on-site diagnosis unit 230 in the system according to an embodiment of the present invention. As shown in FIG. 3, the spot diagnosis unit 230 may include a position determiner 231 and a direction determiner 233.

The position determining unit 231 analyzes the partial discharge signal sensed by the sensor unit 210 to determine the occurrence position of the partial discharge.

As described above, when a partial discharge occurs at any point of the power cable 200, a high frequency signal is generated accordingly. The high frequency signal proceeds along the power cable 200, and attenuation may occur according to the characteristics of the power cable 200 during the process.

The power cable 200 may include a dielectric, which is generally a central conductor and an insulator surrounding it. Therefore, a high frequency signal traveling along the power cable 200 also receives a loss due to a conductor (hereinafter referred to as 'conductor loss') and a loss caused by a dielectric (hereinafter referred to as 'dielectric loss'), which is generally 20 MHz. A signal with a frequency of 0.5 dB / 100m has a loss rate.

The partial discharge signal or a signal attenuated according to the progress thereof is detected by the sensor unit 210 installed in the body or the connection point 205 of the power cable 200. Since the attenuation amount of the partial discharge signal increases as the distance from the partial discharge occurs, it is possible to determine the point where the partial discharge occurred by grasping the strength of the signal detected by the sensor unit 210.

The attenuation amount per unit length of the high frequency signal due to the conductor loss in the power cable 200 is represented by the equation (1).

(dB/m)

(dB / m)

는 전력 케이블(200)의 도체 손실률,

은 전력 케이블(200)의 구성 중 도체로 이루어지는 중심 동축에서의 단위 길이당 저항,

는 상기 중심 동축의 특성 임피던스,

는 중심 동축의 도전율,

는 중심 동축의 등가 표피 두께, a는 중심 동축의 내부 도체 외경, b는 중심 동축의 외부 도체 내경을 나타낸다. here,

Is the conductor loss rate of the power cable 200,

Is a resistance per unit length in the center coaxial made of a conductor of the power cable 200,

Is the characteristic impedance of the central coaxial,

Is the central coaxial conductivity,

Is the equivalent skin thickness of the central coaxial, a is the inner conductor outer diameter of the central coaxial, and b is the outer conductor inner diameter of the central coaxial.

Meanwhile, the attenuation amount per unit length of the high frequency signal due to the dielectric loss in the power cable 200 is represented by Equation 2.

(dB/m)

(dB / m)

는 전력 케이블(200)의 유전 손실률을 나타내며,

은 전력 케이블(200)의 유전체 내에서의 고주파 신호 파장을 나타낸다.

와 같이 표현되며, 여기서,

는 신호의 공기 중 파장, 및

은 전력 케이블(200)를 구성하는 유전체의 비유전율이다.here,

Represents the dielectric loss rate of the power cable 200,

Denotes the high frequency signal wavelength in the dielectric of the power cable 200.

Is expressed as

Is the wavelength in air of the signal, and

Is the dielectric constant of the dielectric constituting the power cable 200.

Therefore, when the distance from the point where the partial discharge occurs to the specific sensor unit 210 is L, the signal detected by the sensor unit 210, The partial discharge signal attenuated by.

Using this principle, the on-site diagnosis unit 230 receives signals detected from the sensor units 210 through six channels, and the position determination unit 231 of the on-site diagnosis unit 230 correlates them. By analyzing, we can find out the location of partial discharge.

이고, 제 2 센서부(210)로부터 감지된 신호의 세기가

일 때,For example, the intensity of the signal detected from the first sensor unit 210

, The intensity of the signal detected from the second sensor unit 210

when,

(L₁은 부분방전 지점으로부터 제 1 센서부(210)까지의 거리, A₀는 부분방전 신호의 무감쇄 세기), 및

(L ₁ is the distance from the partial discharge point to the first sensor unit 210, A ₀ is the attenuation intensity of the partial discharge signal), and

(L₂는 부분방전 지점으로부터 제 2 센서부(210)까지의 거리)로 표현될 수 있다.

L ₂ may be expressed as a distance from the partial discharge point to the second sensor unit 210.

라는 수학식이 얻어지고, 제 1 센서부(210)와 제 2 센서부(210) 사이의 거리 파악을 통해 L₁ 과 L₂ 사이의 관계식을 얻어낼 수 있으므로, 상기 식으로부터 L₁ 또는 L₂ 를 구해낼 수 있게 된다.Using this, from the above two equations,

Is obtained, and the relationship between L ₁ and L ₂ can be obtained by grasping the distance between the first sensor unit 210 and the second sensor unit 210, and thus L ₁ from the above equation. or L ₂ can be obtained.

Through this process, the position determination unit 231 can determine the position of the point where the partial discharge occurred.

On the other hand, the direction determination unit 233 of the field diagnosis unit 230 is the position of the partial discharge through the phase of the signals detected by the two sensor unit 210 formed on both ends of the connection point 205 of one transmission line and It is also possible to grasp the direction of the signal generated by the partial discharge and the like.

4A to 4C show the partial discharge signal phases at each point when partial discharge occurs at each point of the transmission line.

The sensor unit 210, which is composed of an RF sensor or the like, is generally composed of coils having N number of turns. Each of the sensor units 210 has an input side (primary side) and an output side (secondary side), and the Enfer law There is a direction to follow. That is, the phase does not change when the signal having a predetermined phase is input to the input side and output to the output side, but the phase does not change, but when the signal is input to the output side and proceeds to the input direction, the phase is changed 180 degrees.

Each of the sensor units 210 illustrated in FIGS. 4A to 4C are RF sensors having an input side on the left side and an output side on the right side.

First, FIG. 4A shows a partial discharge signal pulse at each point when partial discharge occurs at A point.

As shown in FIG. 4A, when a partial discharge occurs at point A, a pulse signal due to the partial discharge proceeds to both sides based on the point A. Looking at the progress direction, the sensor unit 211 and the sensor Since the input is input from the input side on the left side of the unit 213 and output to the output side on the right side, the phase of the pulse signal becomes the same before and after passing through the sensor units 211 and 213.

On the other hand, as shown in Figure 4b, when the partial discharge occurs at the point B, at this time also the pulse signal due to the partial discharge proceeds to the left and right around the point B. In this case, since the pulse signal is input from the right side (output side) to the left side (input side) on the basis of the sensor unit 211, the phase of the pulse signal is changed by 180 degrees. On the other hand, in the reference of the sensor unit 213, since the pulse signal is input from the left side (input side) and output to the right side (output side), the phase before and after the input of the pulse signal does not change. Therefore, the generation direction can be determined due to the generation of the 180 degree phase difference between the A point and the C point.

In addition, referring to 4c showing the case where the partial discharge occurs at the point C, the pulse signal resulting from the partial discharge is input from the right side (output side) of the sensor portion 211 and the sensor portion 213 to the left side (input side). Since it is outputted as, the phase of both before and after the input of the pulse signal is changed on the basis of the sensor unit 211 and the sensor unit 213.

By using this principle, the direction determination unit 233 of the on-site diagnosis unit 230 can know the traveling direction of the pulse signal due to the partial discharge, as shown in Figures 4a to 4c, the partial discharge connection point It can be determined whether it occurs at 205 (occurring at point B in FIGS. 4A to 4C) or at the body of the power cable 200 (occurring at point A or C in FIGS. 4A to 4C). .

In addition, since two sensor units 210 are provided at each of the connection points of the three transmission lines included in the power cable 200, the six sensor units 210 may be part of any one of the three transmission lines. It is also possible to know whether a discharge has occurred.

Hereinafter, the detailed configuration of the central server 270 and how the central server 270 processes the result based on the measurement result of each field diagnosis unit 230 will be described in detail. Do it.

Data processing by the central server

5 is a diagram illustrating a detailed configuration of the central server 270 in the system according to an embodiment of the present invention.

As shown in FIG. 5, the central server 270 finally determines the occurrence position of the partial discharge based on the determination result of the field diagnosis unit 230 and finally determines the position expression unit 271 and the facial expression. It may be configured to include a importance determination unit 273 to determine the importance by giving a weight to the location of the partial discharge.

As described above, the field diagnosis unit 230 includes two sensor units 210 mounted at both ends of the connection point 205 of the three transmission lines, that is, all six sensor units 210 formed at the local point. Use this to identify the point or direction of partial discharge.

However, if the partial discharge does not occur near the connection point 205 but at a point far from the connection point 205, the distance between the sensor portions 210 mounted at both ends of the connection point 205 becomes negligible, There is a problem that can not pinpoint the point of occurrence.

로 표현되는데, 여기서, L1과 L2의 값이 매우 커지게 되면

이 되어, 부분 방전의 발생 지점을 정확히 알아낼 수가 없게 된다.That is, as described above, the intensity of the signal sensed by the two sensor units 210 mounted at both ends of the connection point 205 is A ₁ and A ₂ , respectively, and the occurrence point of the partial discharge and each sensor unit 210. When the distances to) are L ₁ and L ₂ , the relation is

Where L1 and L2 become very large

This makes it impossible to pinpoint the point of occurrence of partial discharge.

Therefore, since only the diagnosis by the on-site diagnosis unit 230 is impossible to detect or measure the accurate partial discharge, the position and the direction of the partial discharge are finally measured based on the measurement result by the at least one on-site diagnosis unit 230. The process is necessary, and the position expression unit 271 of the central server 270 is in charge.

The central server 270 receives data processed by the field diagnosis unit 230 in parallel through the data transmitter 250.

Thereafter, the position expression unit 271 of the central server 270 displays the importance in the order of the on-site diagnosis unit 230 determined that the greatest partial discharge has occurred among the partial discharge measurement results by the entire on-site diagnosis unit 230. . That is, the on-site diagnosis unit 230 where the signal caused by the partial discharge is most detected is prioritized.

Next, the partial discharge signal detected by the highest priority field diagnosis unit 230 and the surrounding field diagnosis unit 230 is compared and contrasted.

By using the above-described equation for conductor loss and dielectric loss, the magnitude of the partial discharge signal measured at each field diagnosis unit 230, and the distance between the points where the field diagnosis unit 230 is installed, The point of occurrence of discharge can be identified, and the direction of progress of the partial discharge signal can also be identified.

On the other hand, by comparing the magnitude of the partial discharge signal detected by each field diagnosis unit 230, it is possible to determine whether the problem is a particular field diagnosis unit 230, the adjacent field diagnosis unit 230 is also a problem. For example, assuming that the first on-site diagnosis unit 230, the second on-site diagnosis unit 230, and the third on-site diagnosis unit 240 are sequentially mounted on the power cable 200, the first site The partial discharge signal detected by the diagnosis unit 230 and the partial discharge signal detected by the third field diagnosis unit 230 are similar values, and the intensity of the signal detected by the second field diagnosis unit 230 may be smaller than the value. At this point, it is unlikely that a partial discharge would occur at one point. In this case, the occurrence points of the partial discharges can be identified by comparing the characteristics of the signals detected by more adjacent field diagnosis units 230.

In addition, the central server 270 may determine the traveling direction of the partial discharge signal by analyzing the phase based on the signal detection result of each field diagnosis unit 230. Principle of determining the direction of the signal based on the phase of the partial discharge signal is the above-described method, that is, the method of determining the direction of the partial discharge signal through the phase analysis of the signal detected by the sensor unit 210 and Since it is the same, the description thereof will be omitted here.

If the point of occurrence of the partial discharge and the traveling direction of the partial discharge signal matched in this manner coincide, the estimation is correct, and thus the identified point of occurrence of the partial discharge is stored.

On the other hand, if there are a plurality of on-site diagnosis unit 230 that detects the partial discharge signal having a different size, it is necessary to first repair the power cable 200 at the point where the largest partial discharge signal is detected, If it is determined that the partial discharge signal having the same or similar size is detected in the multiple on-site diagnosis unit 230, the order of maintenance work should be determined by setting the priority.

To this end, the importance determination unit 273 of the central server 270 may give a weight to the occurrence position of the partial discharge finally determined by each field diagnosis unit 230 or the position expression unit 271, the The weight may be determined in relation to the accident history, the temperature of the power cable 200, the waveform of the partial discharge signal, and the like.

In this case, the importance determination unit 273 may refer to the partial discharge database 275 in which information on an accident history at each point of the power cable is stored. Information stored in the partial discharge database 275 may be updated at any time. In FIG. 5, the partial discharge database 275 is illustrated as one component of the central server 270, but is not limited thereto. Of course it can be composed of components or media.

Accordingly, even if there are several on-site diagnosis units 230 that detect the partial discharge signal of the same size, the specific on-site diagnosis unit 230, that is, the accident history is high, or the temperature of the power cable 200 is high The weight of the on-site diagnosis unit 230 having the characteristics such as this becomes high, thereby giving priority to maintenance and repair work.

By doing so, the central server 270 may find the point of the power cable 200 that has the highest risk and has to be performed urgently.

Meanwhile, the central server 270 finally expresses the identified point of occurrence of the partial discharge, and displays it on a human machine interface (HMI). In the display, the risk or importance reflected with the weight may be displayed together with the occurrence point of the partial discharge.

Although the present invention has been described by specific embodiments such as specific components and limited embodiments and drawings, it is provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments, Those skilled in the art to which the present invention pertains can make various modifications and variations from this description.

Therefore, the spirit of the present invention should not be construed as being limited to the above-described embodiments, and all of the equivalents or equivalents of the claims, as well as the following claims, I will say.

1 shows the overall configuration of a conventional system that detects partial discharge of an ultra-high voltage underground power cable and expresses its position.

2 shows the overall configuration of an entire system for measuring partial discharge of a power cable according to an embodiment of the invention.

3 is a view showing the internal configuration of the on-site diagnosis according to an embodiment of the present invention.

4A to 4C show the partial discharge signal phases at each point when partial discharge occurs at each point of the transmission line.

5 is a diagram illustrating an internal configuration of a central server according to an embodiment of the present invention.

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

200: power cable 205: connection point

210: sensor unit 230: field diagnostic unit

250: data transmission unit 270: central server

231: position determination unit 233: direction determination unit

271: position expression unit 273: importance determination unit

275: partial discharge database

Claims (14)

A system for identifying the occurrence position of partial discharge in a power cable, A sensor unit mounted at both ends of one or more connection points included in the power cable to detect a signal (partial discharge signal) resulting from partial discharge, At least one on-site diagnosis unit for receiving a signal sensed by the sensor unit and analyzing the detected signal to determine a generation position of the partial discharge and a moving direction of the partial discharge signal, and Based on the determination of the one or more on-site diagnosis unit includes a central server for finally expressing the location of the occurrence of partial discharge and displaying it along with the direction of the partial discharge signal, The on-site diagnosis unit, The occurrence position of the partial discharge is determined by using the attenuation amount of the partial discharge signal expressed as the sum of the loss caused by the conductor included in the power cable (conductor loss) and the loss caused by the dielectric included in the power cable (dielectric loss). Position determination unit, and When the partial discharge signal travels from the input side (primary side) of the sensor unit to the output side (secondary side), the phase does not change before and after the input to the sensor unit, but from the output side (secondary side) direction of the sensor unit to the input side (primary side) direction. And a direction determining unit which determines a moving direction of the partial discharge signal by using a characteristic of changing a phase 180 degrees before and after input to the sensor unit. delete delete The method of claim 1, The conductor loss,

expressed as the product of (dB / m) and the distance from the sensor portion to the partial discharge occurrence point, The dielectric loss is,

expressed as the product of (dB / m) and the distance from the sensor unit to the partial discharge occurrence point, here,

Is the conductor loss rate of the power cable,

Is a resistance per unit length of the conductor included in the power cable,

Is the characteristic impedance of the conductor,

Is the conductivity of the conductor,

Is the equivalent skin thickness of the conductor, a is the outer conductor outer diameter of the conductor, b is the outer conductor inner diameter of the conductor,

Is the dielectric loss rate of the power cable,

as,

Is the wavelength in air of the partial discharge signal, and

Is a relative dielectric constant of a dielectric included in the power cable. delete The method of claim 1, The central server, A position expression unit for comparing the attenuation amounts of the partial discharge signals analyzed by the one or more on-site diagnosis units to finally determine a location of the partial discharge, and then expressing the partial discharge signal; And a importance determination unit for assigning a weight to the finally determined position of the partial discharge. The method of claim 1, The sensor unit is characterized in that the RF sensor. The method of claim 1, And a data transmitter for transmitting the determination result from the field diagnosis unit to the central server. The method of claim 8, The data transmission unit is characterized in that the optical transmission unit (OTU; Optical Transceiver Unit). As a method for identifying the occurrence position of partial discharge in a power cable, Detecting a signal (partial discharge signal) resulting from partial discharge by using a sensor unit including a sensor mounted at both ends of at least one connection point included in the power cable; The occurrence position of the partial discharge is determined by using the attenuation amount of the partial discharge signal expressed as the sum of the loss caused by the conductor included in the power cable (conductor loss) and the loss caused by the dielectric included in the power cable (dielectric loss). When the partial discharge signal proceeds from the input side (primary side) of the sensor to the output side (secondary side), the phase does not change before and after the input to the sensor, and the input side (primary side) in the output side (secondary side) direction of the sensor. Determining a traveling direction of the partial discharge signal by using a characteristic of changing a phase 180 before and after input to the sensor when proceeding in the) direction, and Finally expressing a position of occurrence of the partial discharge based on the judgments and displaying the final position of the partial discharge together with the direction of travel of the partial discharge signal. delete The method of claim 10, The conductor loss,

expressed as the product of (dB / m) and the distance from the sensor portion to the partial discharge occurrence point, The dielectric loss is,

expressed as the product of (dB / m) and the distance from the sensor unit to the partial discharge occurrence point, here,

Is the conductor loss rate of the power cable,

Is a resistance per unit length of the conductor included in the power cable,

Is the characteristic impedance of the conductor,

Is the conductivity of the conductor,

Is the equivalent skin thickness of the conductor, a is the outer conductor outer diameter of the conductor, b is the outer conductor inner diameter of the conductor,

Is the dielectric loss rate of the power cable,

as,

Is the wavelength in air of the partial discharge signal, and

Is a relative dielectric constant of a dielectric included in the power cable. delete The method of claim 10, The step of finally expressing the location of the partial discharge, Comparing the attenuation amounts of the partial discharge signals analyzed in the step of determining the location of the partial discharge, finally determining the location of the partial discharge, and expressing the result; And assigning a weight to the position of occurrence of the finally determined partial discharge.

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