KR102530465B1 - Apparatus for sensing partial discharge of power cable and method for diagnosing partial discharge of power cable unsing the same - Google Patents

Abstract

The present invention relates to a device for detecting partial discharge of a power cable and a method for diagnosing partial discharge of a cable connection part using the same. Partial discharge diagnosis is easy and diagnosis is possible at a close position, including a sensing unit installed to measure electromagnetic signals and detecting partial discharge signals, and a close-fitting part formed to cover the cable connection part and one side fixed to the sensing unit.

Description

Partial discharge detection device of power cable and method for diagnosing partial discharge of cable connection part using same

The present invention relates to an apparatus for detecting partial discharge of a power cable and a method for diagnosing partial discharge of a cable connection part using the same. It relates to a method for diagnosing partial discharge.

In general, partial discharge refers to any of power equipment systems such as power receiving facilities, high voltage switchboards, high voltage cables, transformers, GIS (Gas Insulated Switchgear, gas insulated switchgear), switchgear, and power receiving facilities installed in various industries and power system substations. As a generic term for discharges occurring in one part, corona discharges occurring near the tips of electrodes, creeping discharges occurring along the surface of an insulator, and void discharges occurring in voids in an insulator may be mentioned.

In addition, it is very important to detect abnormalities in power devices, monitor the degree of deterioration of insulators, and predict repair times, and such prediction and management are possible by measuring and monitoring partial discharges.

For this purpose, partial discharge in various power facilities such as high voltage cables, transformers, GIS (Gas Insulated Switchgear), switches, power receiving facilities, high voltage panels, low voltage panels, motor control panels, power distribution panels, etc. Measuring devices are being used.

Demand for electricity is continuously increasing due to the advancement of industry, and accidents due to high voltage cables, transformers, GIS, power receiving facilities, and power facilities within the power equipment system occur frequently. These accidents can cause technical as well as economic loss.

In particular, as a result of the 3-year failure analysis, more than half of the occurrences occur near cable connections installed in manholes. Aging deterioration of trees, electric trees, etc. causes failure.

However, there is a problem in that a clear diagnosis is difficult because the PD diagnosis periodic inspection of the internal cable connection box is performed once a year and PD diagnosis is forced for a short time due to poor environmental conditions.

In addition, the sensor device that performs PD diagnosis by contacting the existing cable is inconvenient and takes a long time to work because the operator must maintain the sensor device in contact with the cable during inspection, and the sensor device is separated from the cable. However, it is difficult to obtain an accurate diagnosis result and the reliability of the diagnosis result is low.

The present invention has been devised from the foregoing background, and by providing a connection unit for more stably contacting and maintaining contact with a power cable or cable connection, work becomes easier and work time can be shortened, and accurate diagnosis results can be obtained. It is an object of the present invention to provide a partial discharge detection device for a power cable, which can be obtained to improve the reliability of diagnostic results, and a method for diagnosing partial discharge in a cable connection using the same.

In addition, the purpose is to provide a partial discharge detection device for a power cable, which has a wide range of application and improves convenience in diagnosis as it can be installed on power cables or cable connections of various diameters, and a method for diagnosing partial discharge on cable connections using the same. .

In addition, even if noise is input due to peripheral power devices and the output value of the sensor module contains noise, accurate partial discharge diagnosis is possible and reliability of the diagnosis result is improved, and the part of the cable connection part using the same Its purpose is to provide a discharge diagnosis method.

The object of the present invention is not limited thereto, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

According to the present invention, a rod-shaped support, provided at an end of the support and installed to come into contact with one side of the outer circumferential surface of the cable connector, detects a partial discharge signal by measuring an electromagnetic wave signal, and one side is fixed to the detector and wraps around the cable connector. An apparatus for detecting partial discharge of a power cable including a contact portion formed to be formed may be provided.

The contact portion may be formed of a conductor to assist the detection unit in detecting a partial discharge signal.

In addition, the apparatus for detecting partial discharge of a power cable may further include a connection block having an insertion hole into which the detection unit is inserted and fixed, and one side of the contact portion may be fixed to the connection block.

The connection block may be fixed to the sensing unit by press-fitting the sensing unit into the insertion hole.

In addition, the connection block may be provided with a coupling groove in which one side of the contact portion is inserted and fixed by being recessed on one side.

The apparatus for detecting partial discharge of the power cable may further include a support member that is positioned to surround the other end of the connection block and the close contact portion and applies elastic force so that the other end of the close contact portion is in close contact with the side surface of the connection block.

In this case, the connection block may be formed of a conductor and may have a cover made of an insulating material surrounding the outside.

In addition, the support may be provided with a length adjustment unit to be able to adjust the length.

In addition, according to the present invention, after installing a sensing device including an electromagnetic wave sensor at three or more diagnosis points among cable connection parts, acquiring a magnitude value of an output electromagnetic wave output from the sensing device at the diagnosis point, Partial discharge of the cable connection, including calculating an average value for magnitude values, calculating an error rate between the magnitude values and the average value of a plurality of output electromagnetic waves, and diagnosing whether a partial discharge has occurred by comparing the error rate with a preset tolerance rate. A diagnostic method may be provided.

In the step of acquiring the magnitude value of the output electromagnetic wave of the sensing device, the three or more diagnosis points may include a central point of the cable connection part and a plurality of symmetrical points on both sides of the cable connection part based on the center point of the cable connection part.

Also, in the step of acquiring the magnitude value of the output electromagnetic wave of the sensing device, the sensing device may sequentially measure the magnitude value of the output electromagnetic wave at three or more diagnosis points from one side to the other.

In addition, in the step of diagnosing whether partial discharge has occurred, if the error rate of any one diagnosis point among the error rates of a plurality of diagnosis points is equal to or greater than a preset allowable error rate, it is diagnosed that partial discharge has occurred, and the error rates of the plurality of diagnosis points If the error rate is smaller than the preset tolerance rate, it can be diagnosed that no partial discharge has occurred.

And, in the step of diagnosing whether partial discharge has occurred, if it is diagnosed that partial discharge has occurred in the cable connection part, the point where the partial discharge occurred is estimated as the diagnosis point where the magnitude value of the largest output electromagnetic wave from the sensing device among the cable connection parts was acquired. can do.

According to the present invention, the flexible contact portion is provided to more stably contact the power cable or cable connection portion, and the connection unit for maintaining the contact is provided, thereby facilitating work and reducing work time, signal acquisition Efficiency is increased, accurate diagnosis results can be obtained, and reliability of diagnosis results is improved.

In addition, as it can be installed in power cables or cable connectors of various diameters, the application range is wide and convenience is improved during diagnosis.

In addition, even if noise is input due to peripheral power devices and the output value of the sensor module contains noise, accurate partial discharge diagnosis is possible, thereby improving the reliability of the diagnosis result.

1 is an exploded perspective view of an apparatus for detecting partial discharge of a power cable according to an embodiment of the present invention.
2 is a perspective view of an apparatus for detecting partial discharge of a power cable according to an embodiment of the present invention.
3 is a perspective view of a connection unit of an apparatus for detecting partial discharge of a power cable according to an embodiment of the present invention.
4 is a perspective view of a sensor rod of a device for detecting partial discharge of a power cable according to an embodiment of the present invention.
5 and 6 are photographs of a partial discharge detection device of a power cable according to an embodiment of the present invention installed in a cable connection part and an elbow connection member, respectively.
7 is a photograph illustratively showing a diagnosis point at which a magnitude value of an output electromagnetic wave is obtained in a method for diagnosing partial discharge of a cable connection part according to an embodiment of the present invention.
8 is a signal waveform obtained from a device for detecting partial discharge of a power cable according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

1 is an exploded perspective view of a device for detecting partial discharge of a power cable according to an embodiment of the present invention, FIG. 2 is a perspective view of a device for detecting partial discharge of a power cable according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention. A perspective view of a connection unit of a partial discharge detection device for a power cable according to an example, FIG. 4 is a perspective view of a sensor rod of a partial discharge detection device for a power cable according to an embodiment of the present invention, and FIGS. 7 is a photograph of a partial discharge detection device of a power cable installed in a cable connection part and an elbow connection member according to an example, and FIG. Illustratively, FIG. 8 is a signal waveform obtained from a device for detecting partial discharge of a power cable according to an embodiment of the present invention.

As shown in these drawings, the device for detecting partial discharge of a power cable according to an embodiment of the present invention is provided at the end of the rod-shaped support 110 and the support 110, and the power cable 10 or the cable connector 20 A sensing unit 120 installed to be in contact with one side of the outer circumferential surface of the sensor 120 for detecting a partial discharge signal by measuring an electromagnetic wave signal, one side of which is fixed to the sensing unit 120 and formed to surround the power cable 10 or the cable connector 20 It includes the contact part 220.

The partial discharge detection device of the power cable 10 of the present invention is a part generated in any one of the power saving facilities of the high voltage cable 10, transformer, GIS (Gas Insulated Switchgear, gas insulated switchgear), switchgear, power receiving facility, and switchboard. Used to monitor discharge.

In particular, the sensing device of the present invention is composed of the sensor rod 100 and the contact part 220 so as to be easily installed in the power cable 10 and the cable connection part 20 of various standards.

The sensor rod 100 is composed of a rod-shaped support 110 and a block-shaped sensing unit 120.

The support 110 is provided in the shape of a long bar in the longitudinal direction, and can be easily gripped by the operator, and is provided with a length adjustment unit 111 so that the length can be adjusted.

The length adjustment unit 111 is provided in the shape of a hollow rod, into which the support 110 is inserted, and overlapped with the support 110 to adjust the length of the support 110 by adjusting the overlapping length. can

In addition, a plurality of length adjustment units 111 may be installed on the support 110 and may be provided to maintain the state after being inserted into each other to adjust the length.

As the length adjustment unit 111 is provided on the support 110, the partial discharge signal is easily detected even when the power cable 10 is located in a manhole or when a worker cannot easily reach the power cable 10 from a long distance. and improve accessibility.

The sensing unit 120 is provided in a block shape and provided at an end of the support 110, and is installed to contact one side of the outer circumferential surface of the power cable 10 including a sensor module to measure an electromagnetic wave signal and detect a partial discharge signal.

In addition, the sensing unit 120 has a contact portion 121 formed in a concave round surface in contact with the outer circumferential surface of the power cable 10, and is stably positioned and seated on the outer circumferential surface of the power cable 10.

However, the contact portion 121 may be formed with a radius of curvature greater than that of the power cables 10 of various diameters and the cable connectors 20 of various diameters and seated on the power cable 10 or the cable connector 20. It is preferable to be formed so that

The sensor module is a HFCT (High Frequency Current Transducer) sensor that measures the partial discharge generated from the cable 10 and the terminal of the cable 10 inside the switchboard, and a UHF (Ultra High Frequency) electromagnetic wave sensor, TEV (Transient Earth Voltage) sensor that detects discharge inside the switchboard, ultrasonic corona sensor that tracks the position of partial discharge generated from power devices inside the switchboard, etc., but is not limited thereto.

In addition, the detection unit 120 is provided to enable wireless communication, diagnoses partial discharge of the power cable 10 or cable connector 20, and can transmit and receive electromagnetic signals or partial discharge signals to and from an inspector's portable terminal or portable inspection device. It is desirable to be prepared to do so.

Alternatively, the detector 120 may be connected to an inspector's portable terminal or a portable inspection device through wires to transmit and receive information such as an electromagnetic wave signal or a partial discharge signal.

In addition, the detection unit 120 can detect the partial discharge signal by directly measuring the electromagnetic wave signal through contact with the power cable 10 or the cable connection unit 20, and indirectly through the connection unit 200 to be described later. The partial discharge signal may be detected by measuring the electromagnetic wave signal.

One side of the close contact part 220 is fixed to the sensing part 120 and is formed to surround the power cable 10 .

The contact portion 220 may be formed to be flexible by using a flexible material as a main body so as to easily wrap the power cable 10, and after wrapping the power cable 10 or the cable connection portion 20, the other side is a sensor It is supported on the rod 100 side.

Alternatively, the contact portion 220 may be provided in the form of a curved plate having elasticity and may be easily installed while wrapping the power cable 10 and the cable connection portion 20 having various diameters.

In addition, the adhesion part 220 may be formed of a conductor having conductivity to assist the sensing part 120 in measuring the electromagnetic wave signal and detecting the partial discharge signal. For example, it may be a thin plate-shaped copper, but is not limited thereto. no.

After one side of this close contact 220 is fixed to the sensing unit 120 and then wraps around the power cable 10 or cable connection 20, the other side is supported on the side of the sensing unit 120, and power cables of various diameters ( 10) or provided in a flexible plate shape having a sufficient length to surround the cable connection part 20.

In addition, the other side of the close contact part 220 is supported on the side of the sensing part 120 after wrapping the power cable 10 or the cable connection part 20 in close contact.

The connection unit 200 is composed of the contact part 220 and the connection block 210 for fixing the contact part 220 to the sensor rod 100.

The connection block 210 is provided in a block shape, and the detection unit 120 is inserted and fixed, and the insertion hole 211 formed in a shape corresponding to the shape of the detection unit 120 and one end of the contact unit 220 Is provided with a coupling groove 212 is inserted and fixed.

The sensing unit 120 is press-fitted and inserted into the insertion hole 211 and fixed to the connection block 210, and is formed to be tapered to facilitate coupling, and the insertion hole 211 may also be formed to correspond thereto.

The coupling groove 212 is formed by being recessed on one side of the connection block 210, and one end of the close contact portion 220 is inserted and fixed through the fastening member 201.

For example, the coupling groove 212 is formed by being recessed on the front surface facing the power cable 10, one end of the contact portion 220 is inserted, and a fastening member 201 such as a bolt or screw is connected to a block ( As the connection block 210 passes through the side surface adjacent to the coupling groove 212 of 210 and one end of the contact portion 220, the contact portion 220 may be fixed to the coupling groove 212.

In addition, the connection block 210 is provided as a conductor having conductivity and assists the detector 120 in measuring the electromagnetic wave signal and detecting the partial discharge signal.

That is, since the power cable 10 or the cable connection part 20, the contact part 220, the connection block 210, and the sensing part 120 are electrically connected to each other, the sensing part 120 is the power cable 10 or It is indirectly in contact with the cable connection part 20 to measure the electromagnetic wave signal.

As a result, the sensing unit 120 can measure the electromagnetic wave signal by contacting the contact unit 121 with the power cable 10 or the cable connector 20, and at the same time, the power cable 10 or the cable connector 20. An electromagnetic wave signal is measured through the wrapping portion 220 and the connection block 210 fixed in surface contact with the contact portion 220 and fixed in surface contact with the outer circumferential surface of the sensing unit 120.

As such, the connection unit 200 provides an antenna function between the power cable 10 or the cable connector 20 and the sensor rod 100 so that the sensor 120 can accurately measure the electromagnetic wave signal.

In addition, as the contact state between the power cable 10 or the cable connection part 20 and the sensor rod 100 is fixed, the contact state of the sensor rod 100 with the power cable 10 or the cable connection part 20 is maintained. This makes the work easier and provides more accurate magnitude values and signal waveforms of the output electromagnetic waves.

And, for safety, the connection block 210 is provided with an insulating cover 213 surrounding the outside.

The cover 213 may be formed of, for example, a plastic material, and protects the connection block 210 from the outside and insulates the connection block 210.

In addition, the connection unit 200 is positioned to surround the other end of the connection block 210 and the close contact portion 220, so that the other end of the close contact 220 is in close contact with the side surface of the connection block 210. A support member 230 is further included.

The support member 230 may be provided as an example of a rubber ring, and is positioned to surround the connection block 210 and the contact portion 220 together in a tensioned state so that there is a gap between the contact portion 220 and the connection block 210. It provides an elastic restoring force that makes it adhere closely.

In particular, the support member 230 provides an elastic restoring force to keep the connection unit 200 to which the sensor rod 100 is fixed in contact with the power cable 10 or the cable connector 20 .

This support member 230 is an exemplary means for supporting the other side of the close contact 220 on the side of the connection block 210, for supporting the other side of the close contact 220 on the side of the connection block 210. If it is, it may be prepared in a different form.

As shown in FIGS. 5 and 6 , the device for detecting partial discharge of the power cable 10 is a support member 230 in a state where the contact portion 220 surrounds the cable connection portion 20 or an elbow connection member such as a ground switch. ) is supported by the elastic restoring force, so that the contact portion 121 of the sensor rod 100 is kept in contact with the cable connection portion 20 or the elbow connection member.

Referring to the process of installing such a detection device to the cable connection part 20 or the elbow connection member, first, the detection part 120 is press-fitted into the insertion hole 211 of the connection block 210 so that the connection unit 200 is fixed. Prepare the sensor rod 100.

Then, the contact part 121 of the sensor rod 100 exposed through the insertion hole 211 is brought into contact with the cable connection part 20 or the point where partial discharge of the elbow connection material is to be diagnosed.

Then, while the contact part 121 of the sensor rod 100 is in contact with the cable connection part 20 or the elbow connection material, hold the other side of the close contact part 220 and then surround the outside of the cable connection part 20 or the elbow connection material. wind up

Then, the support member 230 is elastically deformed while the other side of the close contact 220 is supported on the side of the connection block 210, and the support member 230 wraps around the connection block 210 and the close contact 220. place the

In addition, by pulling the other side of the close contact part 220, the cable connection part 20 or the elbow connection member and the contact part 121, the cable connection part 20 or the elbow connection member and the contact part 220 can be brought into close contact.

In addition, the partial discharge diagnosis method of the cable connection part 20 according to an embodiment of the present invention installs a detection device including an electromagnetic wave sensor at three or more diagnosis points among the cable connection parts 20, and then detects the device at the diagnosis point. Acquiring the magnitude value of the output electromagnetic waves, calculating an average value of the magnitude values of the plurality of output electromagnetic waves, and calculating an error rate between the magnitude values and the average value of the plurality of output electromagnetic waves, comparing the error rate with a preset tolerance rate. and diagnosing whether partial discharge has occurred.

In the method for diagnosing partial discharge of the cable connection part 20 of the present invention, no noise or a lot of noise occurs due to the influence of nearby transmission towers or power devices, and as a result, partial discharge occurs even when the output value of the sensor module of the sensing device fluctuates. Provided is a partial discharge diagnosis method capable of accurately diagnosing whether

That is, in the partial discharge diagnosis method of the cable connection part 20 of the present invention, since the output value of the detection device may vary due to the surrounding environment, after diagnosing several parts of the cable connection part 20 to be inspected, the output value is compared to determine the partial discharge. Diagnose whether or not

When diagnosing several places of the cable connection part 20, if there is little change in the magnitude value of the plurality of output electromagnetic waves, it is diagnosed as a normal state in which partial discharge does not occur, and the fluctuation in the magnitude value of the plurality of output electromagnetic waves is severe and the plurality of output electromagnetic waves If the maximum or minimum value of the magnitude of the electromagnetic wave is significantly different from the average value, it is diagnosed as a failure state in which a partial discharge has occurred.

More specifically, first, a detection device including an electromagnetic wave sensor is installed at three or more diagnosis points among the cable connection parts 20, and then a step of obtaining a magnitude value of an output electromagnetic wave output from the detection device at the diagnosis point is performed. do.

Since noise is reflected in the magnitude value of the output electromagnetic wave according to the environment in which the cable connector 20 is installed, when measuring the magnitude value of the output electromagnetic wave for comparison after obtaining the magnitude value of a plurality of output electromagnetic waves, the size of the cable connector 20 Acquired at multiple diagnostic points.

In particular, the magnitude value of the output electromagnetic wave is more accurate when the magnitude value of the output electromagnetic wave is acquired at three or more diagnosis points, and the three or more diagnosis points are the center point of the cable connection part 20 and the center point of the cable connection part It includes a plurality of symmetrical points on both sides as a reference.

If the diagnosis points are concentrated on one side with respect to the center point of the cable connection part 20, the magnitude value of the output electromagnetic wave cannot be obtained evenly. It is preferable to be symmetrical based on .

For example, when acquiring the magnitude value of the output electromagnetic wave at three diagnosis points, the diagnosis point includes a center point of the cable connector 20 and points on both sides of the center point of the cable connector 20 .

In addition, as shown in FIG. 7, when acquiring the magnitude value of the output electromagnetic wave at five diagnosis points, four points spaced apart by a certain distance from the center point of the cable connection part 20 and the center point of the cable connection part 20 to both sides are selected. include

More specifically, the center point of the cable connection portion 20, the two points between the center point of the cable connection portion 20 and the portion where the ground line 30 of the cable connection portion 20 is connected, and the cable connection portion 20 are connected. It includes two points adjacent to the ends of the two cables 10.

At this time, it is preferable that the sensing device acquires the magnitude value of the output electromagnetic wave by sequentially measuring the magnitude value of the output electromagnetic wave at three or more diagnosis points in a direction from one side to the other.

That is, as shown in the drawing, the sensing device sequentially acquires the magnitude value of the output electromagnetic wave while moving from one point to a fifth point of the cable connector 20.

Then, an average value of the magnitude values of the plurality of output electromagnetic waves is calculated, and an error rate between the magnitude values and the average value of the plurality of output electromagnetic waves is calculated.

Since noise is reflected in the magnitude values of the plurality of output electromagnetic waves due to the surrounding environment, an average is calculated to determine an error rate.

First, the average value is obtained by dividing the sum of the magnitude values of the plurality of output electromagnetic waves by the number of diagnosis points.

The error rate is obtained by dividing the difference value by the average value after calculating the difference value between the magnitude value and the average value of each of the plurality of output electromagnetic waves.

The plurality of error rates thus calculated are compared with preset allowable error rates in the next step.

Next, a step of diagnosing whether a partial discharge has occurred by comparing the error rate with a preset allowable error rate is performed.

The method for diagnosing partial discharge of the cable connector 20 according to the present invention checks the distribution of magnitude values of output electromagnetic waves obtained from a plurality of diagnosis points and diagnoses whether or not partial discharge has occurred according to variations in magnitude values of output electromagnetic waves. setting is required.

The allowable error rate is set to a preset value by repeating diagnosis and checking the state of the cable connector 20, and may be set to, for example, 20%, but is not limited thereto.

If the error rate of any one diagnosis point among the error rates of a plurality of diagnosis points is equal to or greater than the preset allowable error rate, it is diagnosed that partial discharge has occurred, and if the error rate of the plurality of diagnosis points is smaller than the preset allowable error rate, partial discharge occurs. diagnosed as not occurring.

That is, if any one of the error rates of the plurality of diagnosis points is equal to or greater than 20%, it is diagnosed that partial discharge has occurred in the cable connection part 20, and if the error rates of the plurality of diagnosis points are all smaller than 20%, the cable connection part In (20), it is diagnosed as a normal state with no partial discharge.

Here, the point where the partial discharge occurred in the cable connection part 20 can be estimated, and since the defect is highly likely to occur in the part where the magnitude value of the output electromagnetic wave is the largest, the diagnosis point at which the magnitude value of the output electromagnetic wave is the largest. is assumed to be the point where the partial discharge occurred.

This is because when a defect occurs, the magnitude of the output electromagnetic wave is measured to be large, and signal attenuation occurs as the distance from the defect location increases.

In other words, when it is diagnosed that partial discharge has occurred in the cable connector 20, the point where the partial discharge has occurred is estimated as the diagnosis point where the magnitude value of the largest output electromagnetic wave from the sensing device is acquired among the cable connectors 20.

8 shows a signal waveform acquired by the sensing device.

8(a) is a signal waveform including noise, which is obtained when the cable connector 20 is in a normal state where partial discharge does not occur, and it can be seen that the signal waveform is a low-frequency signal waveform with a wide phase angle. there is.

8(b) is a partial discharge signal waveform obtained when a partial discharge occurs in the cable connector 20 in a fault state, and it can be seen that it is a high-frequency signal waveform having a precise phase angle.

In this way, it is possible to estimate whether or not partial discharge has occurred in the cable connector 20 from the shape of the signal waveform acquired by the sensing device.

According to the embodiments of the present invention having such a shape and structure, a flexible contact portion is provided to more stably contact the power cable or cable connection, and a connection unit for maintaining contact is provided, thereby facilitating work and reducing work time. It can be shortened, signal acquisition efficiency is increased, and accurate diagnosis results can be obtained, thereby improving the reliability of diagnosis results.

In addition, as it can be installed in power cables or cable connectors of various diameters, the application range is wide and convenience is improved during diagnosis.

In addition, even if noise is input due to peripheral power devices and the output value of the sensor module contains noise, accurate partial discharge diagnosis is possible, thereby improving the reliability of the diagnosis result.

In the above, even though all the components constituting the embodiment of the present invention have been described as being combined or operated as one, the present invention is not necessarily limited to these embodiments. That is, within the scope of the object of the present invention, all of the components may be selectively combined with one or more to operate.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: cable 20: cable connection
100: sensor rod 110: support
111: length adjusting unit 120: sensing unit
121: contact part 200: connection unit
210: connection block 211: insertion hole
212: coupling groove 213: cover
220: close contact 230: support member

Claims (13)

rod-shaped support;
a detector provided at an end of the support and installed to contact one side of the outer circumferential surface of the power cable to measure an electromagnetic wave signal and detect a partial discharge signal;
a connecting block formed of a conductor and having an insertion hole to which the sensing unit is fixed; and
a contact portion formed of a conductor, one end fixed to the connection block and formed to surround the power cable;
including,
The contact portion is formed to be flexible with a flexible material as the main body,
The sensing unit is formed in a block shape inserted into and fixed to the insertion hole and comes into surface contact with the connection block,
The sensing unit is electrically connected to the power cable, the contact portion, and the connection block, and directly measures the electromagnetic wave signal of the power cable, and indirectly measures the electromagnetic wave signal of the power cable through the connection block and the adhesion portion. Partial discharge detection device of power cable to be.
According to claim 1,
The partial discharge detection device of the power cable, characterized in that the sensing part is formed in a concave round surface in contact with the outer circumferential surface of the power cable.
delete According to claim 1,
The connection block is a partial discharge detection device of a power cable, characterized in that the detection unit is press-fitted into the insertion hole and fixed to the detection unit.
According to claim 1,
The device for detecting partial discharge of a power cable, characterized in that the connecting block has a coupling groove in which one side of the connection block is recessed and into which one side of the close contact portion is inserted and fixed.
According to claim 1,
a support member positioned so as to surround the connection block and the other end of the close contact portion and applying elastic force so that the other end of the close contact portion is in close contact with the side surface of the connection block;
Partial discharge detection device of a power cable, characterized in that it further comprises.
According to claim 1,
The partial discharge detection device of the power cable, characterized in that the connection block is formed of a conductor and has an insulating cover covering an outer side.
According to claim 1,
The partial discharge detection device of the power cable, characterized in that the support is provided with a length adjusting portion so that the length can be adjusted.
A diagnosis method for diagnosing partial discharge of a cable connection part through the partial discharge detection device of claim 1,
acquiring a magnitude value of an output electromagnetic wave output from the detection device at the diagnosis point after sequentially installing a sensing device including an electromagnetic wave sensor at three or more diagnosis points among cable connections in a direction from one side to the other side of the cable;
calculating an average value of the magnitude values of the plurality of output electromagnetic waves, and calculating an error rate between the magnitude values of the plurality of output electromagnetic waves and the average value; and
diagnosing whether a partial discharge has occurred by comparing the error rate with a preset allowable error rate;
Method for diagnosing partial discharge of a cable connection comprising a.
According to claim 9,
In the step of acquiring the magnitude value of the output electromagnetic wave of the sensing device,
The method of diagnosing partial discharge of a cable connection part, characterized in that the three or more diagnosis points include a center point of the cable connection part and a plurality of symmetrical points on both sides of the center point of the cable connection part.
According to claim 10,
In the step of acquiring the magnitude value of the output electromagnetic wave of the sensing device,
The partial discharge diagnosis method of the cable connection part, characterized in that the sensing device sequentially measures the magnitude value of the output electromagnetic wave at the three or more diagnosis points from one side to the other side.
According to claim 9,
In the step of diagnosing whether the partial discharge has occurred,
Diagnosing that partial discharge has occurred when the error rate of any one diagnosis point among the error rates of the plurality of diagnosis points is equal to or greater than the preset allowable error rate;
The method of diagnosing partial discharge of a cable connection part, characterized in that it diagnoses that partial discharge has not occurred when the error rate of the plurality of diagnosis points is smaller than the preset allowable error rate.
According to claim 12,
In the step of diagnosing whether the partial discharge has occurred,
When it is diagnosed that partial discharge has occurred in the cable connection part, the point where the partial discharge has occurred is estimated as a diagnosis point where the magnitude value of the largest output electromagnetic wave from the detection device is obtained among the cable connection parts. Discharge diagnosis method.

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