KR20230069372A - Vacuum interrupter diagnostic device and method for rail vehicles - Google Patents

Abstract

A vacuum interrupter diagnostic device is provided adjacent to a vacuum interrupter of a vacuum interrupter for interrupting current, and an antenna for detecting in a non-contact state an electromagnetic wave signal of partial discharge generated inside the vacuum interrupter according to a change in the internal vacuum of the vacuum interrupter. A sensor and a diagnostic unit for diagnosing an abnormality of the vacuum interrupter by comparing the electromagnetic wave signal detected by the antenna sensor with preset abnormal patterns may be included.

Description

Vacuum interrupter diagnostic device and method for rail vehicles}

The present invention relates to a vacuum interrupter diagnosis apparatus and method, and more particularly, to a vacuum interrupter diagnosis apparatus and method for diagnosing an abnormality of a vacuum interrupter provided in a vacuum interrupter.

In general, when a charging part is short-circuited or grounded in a power system using electricity, a large fault current is generated. Therefore, in the power system, a circuit breaker is installed to block a fault current or a current flowing to a load.

Among the circuit breakers, a vacuum circuit breaker is a device that blocks current flowing in a vacuum by having a contact in a vacuum. Among the parts of the vacuum circuit breaker, a vacuum interrupter is a part that functions to cut off current.

The vacuum interrupter has a normal blocking force at a pressure having a degree of vacuum of 5x10 ^-4 Torr or less. As the vacuum interrupter is used for a long period of time, the vacuum pressure inside the vacuum interrupter increases due to internal and external factors such as gas emitted from the inside of the vacuum interrupter and leakage at the junction of each part, and accordingly, the insulation extinguishing ability of the vacuum interrupter increases. There is a problem that cannot be maintained. If the circuit breaker operates without detecting a state in which the insulation extinguishing ability is deteriorated due to the decrease in the degree of vacuum of the vacuum interrupter, a serious loss may occur in the power system. Therefore, monitoring the vacuum level of the vacuum interrupter is very important.

According to the prior art, a detection pin is provided inside a vacuum interrupter, and a change in state of the detection pin is detected, or a vacuum bellows communicating with the inside of the vacuum interrupter is provided, and a change in length of the bellows is detected to detect a change in the length of the vacuum interrupter. A configuration for constantly monitoring the degree of vacuum is disclosed. These technologies are disclosed in Patent Registration No. 10-1238643 (registered on Feb. 21, 2013) and Patent Registration No. 10-1264226 (registered on May 8, 2013).

However, since these technologies require modification of the vacuum interrupter, they are not applied to actual products. In addition, a technique for detecting a mechanical change according to a change in vacuum degree of the vacuum interrupter cannot accurately determine the change in vacuum degree of the vacuum interrupter.

The present invention provides a vacuum interrupter diagnosis apparatus and method for diagnosing an abnormality of a vacuum interrupter by detecting a partial discharge generated inside the vacuum interrupter according to a change in the degree of vacuum inside the vacuum interrupter.

A vacuum interrupter diagnosis apparatus according to the present invention is provided adjacent to a vacuum interrupter of a vacuum interrupter for cutting off current, and transmits an electromagnetic wave signal of partial discharge generated inside the vacuum interrupter according to a change in the internal vacuum level of the vacuum interrupter in a non-contact state. and an antenna sensor that detects the vacuum interrupter by comparing the electromagnetic wave signal detected by the antenna sensor with preset abnormal patterns to diagnose an abnormality of the vacuum interrupter.

According to one embodiment of the present invention, the vacuum interrupter includes a hollow tube, a movable electrode and a fixed electrode disposed to be in contact with each other inside the hollow tube, and a metal surrounding the movable electrode so that the movable electrode is movable. A bellows and an arc shield spaced apart from each other along an inner surface of the hollow tube may be included, and the antenna sensor may be adjacent to the movable electrode and the metal bellows where the partial discharge is relatively large in the vacuum interrupter.

According to one embodiment of the present invention, the diagnosis unit may include: a sampling unit configured to sample the electromagnetic wave signal and form sampling raw data represented by a voltage level of the electromagnetic wave in a time domain; and the sampling row In order to remove noise from the data, a processing unit that forms sampling data representing only voltage values greater than or equal to a predetermined reference value, and compares the sampling data with a predetermined first abnormal pattern to determine whether the vacuum interrupter is abnormal or normal 1 A diagnostic unit for diagnosing a vehicle may be included.

According to one embodiment of the present invention, the sampling unit may sample the electromagnetic wave signal in plurality in order to increase the accuracy of the sampling raw data.

According to one embodiment of the present invention, the diagnosis unit may further include a pattern setting unit configured to set a second abnormal pattern through machine learning using a diagnosis result of the first diagnosis unit, and the diagnosis unit may include the sampling data It is possible to secondarily diagnose whether the vacuum interrupter is abnormal or normal by comparing with the second abnormal pattern.

According to one embodiment of the present invention, the first abnormality pattern and the second abnormality pattern are each classified into several types according to the cause of the abnormality of the vacuum interrupter, and the diagnosis unit determines the first abnormality pattern and the second abnormality pattern. The cause of the abnormality of the vacuum interrupter can be further diagnosed using the type of pattern.

According to one embodiment of the present invention, the diagnosis unit may diagnose the vacuum interrupter as a final abnormality when both of the vacuum interrupter are diagnosed as abnormal in the first diagnosis and the second diagnosis.

According to one embodiment of the present invention, the diagnosis unit may further include a storage unit that stores information on the first abnormal pattern and the second abnormal pattern and diagnostic information of the diagnostic unit.

According to one embodiment of the present invention, the vacuum interrupter diagnosis device is provided inside the vacuum interrupter and further includes a temperature and humidity measurement unit for measuring the temperature and humidity of the vacuum interrupter, and the diagnosis unit, An abnormality of the vacuum interrupter may be diagnosed by comparing the temperature and humidity of the vacuum breaker with a preset reference temperature and humidity range.

According to one embodiment of the present invention, the vacuum interrupter diagnosis device further includes a current measuring unit for measuring a current of an operation unit for manipulating the vacuum interrupter, and the diagnosis unit includes a current of the operation unit and a preset reference current. It is possible to diagnose the abnormality of the vacuum interrupter by comparing.

According to one embodiment of the present invention, when there is an abnormality in any one of the electromagnetic wave signal of the partial discharge of the vacuum interrupter, the temperature and humidity of the vacuum breaker, and the current of the control unit, the diagnostic unit detects the vacuum interrupter as an abnormality. final diagnosis can be made.

A method for diagnosing a vacuum interrupter according to the present invention includes the steps of detecting, in a non-contact state, an electromagnetic wave signal of a partial discharge generated inside the vacuum interrupter according to a change in the internal vacuum level of the vacuum interrupter of a vacuum interrupter for cutting off current, and detecting the electromagnetic wave signal in a non-contact state. The method may include diagnosing an abnormality of the vacuum interrupter by comparing it with preset abnormal patterns.

According to one embodiment of the present invention, the vacuum interrupter includes a hollow tube, a movable electrode and a fixed electrode disposed to be in contact with each other inside the hollow tube, and a metal surrounding the movable electrode so that the movable electrode is movable. The electromagnetic wave signal may be sensed at a position adjacent to the movable electrode and the metal bellows where the electromagnetic wave is relatively generated.

According to one embodiment of the present invention, diagnosing the abnormality of the vacuum interrupter may include sampling the electromagnetic wave signal and forming sampling raw data represented by the voltage magnitude of the electromagnetic wave in the time domain. And, forming sampling data representing only voltage values greater than or equal to a reference value in order to remove noise from the sampling raw data, and comparing the sampling data with a preset first abnormal pattern to determine abnormality and normality of the vacuum interrupter. It may include a step of first diagnosing whether or not.

According to one embodiment of the present invention, in the step of forming the sampling raw data, the electromagnetic wave signal may be sampled in plurality in order to increase the accuracy of the sampling raw data.

According to one embodiment of the present invention, the step of diagnosing an abnormality of the vacuum interrupter may include setting a second abnormality pattern through machine learning using a diagnosis result of the first diagnosis unit and the sampling data and the first abnormality pattern. The method may further include secondarily diagnosing whether the vacuum interrupter is abnormal or normal by comparing two or more patterns.

According to one embodiment of the present invention, the first abnormal pattern and the second abnormal pattern are each classified into several types according to the cause of the abnormality of the vacuum interrupter, and in the step of diagnosing the vacuum interrupter as the final abnormality, the first abnormal pattern An abnormal cause of the vacuum interrupter may be additionally diagnosed using one or more patterns and the type of the second abnormal pattern.

According to one embodiment of the present invention, the step of diagnosing an abnormality of the vacuum interrupter may include diagnosing the vacuum interrupter as a final abnormality when the vacuum interrupter is diagnosed as abnormal in both the first diagnosis and the second diagnosis. Further steps may be included.

According to one embodiment of the present invention, the diagnosing the abnormality of the vacuum interrupter may further include storing information of the first abnormal pattern and the second abnormal pattern and diagnostic information of the vacuum interrupter. there is.

According to one embodiment of the present invention, the method for diagnosing the vacuum interrupter may include measuring the temperature and humidity of the vacuum interrupter and comparing the temperature and humidity of the vacuum interrupter with a preset reference temperature and humidity range to detect the vacuum interrupter. A step of diagnosing an abnormality of may be further included.

According to one embodiment of the present invention, the method for diagnosing the vacuum interrupter may include measuring a current of a control unit for manipulating the vacuum interrupter and diagnosing an abnormality of the vacuum interrupter by comparing the current of the control unit with a preset reference current. It may further include steps to do.

According to one embodiment of the present invention, the vacuum interrupter diagnosis method, as a result of diagnosing the abnormality of the vacuum interrupter, the electromagnetic wave signal of the partial discharge of the vacuum interrupter, the temperature and humidity of the vacuum breaker, and the current of the control unit. When there is an abnormality in any one, a step of finally diagnosing the vacuum interrupter as an abnormality may be further included.

In the vacuum interrupter diagnosis apparatus and method according to the present invention, since the antenna sensor is provided apart from the vacuum interrupter, the vacuum interrupter can be continuously diagnosed without interrupting the circuit of the vacuum interrupter. Therefore, it is possible to prevent an accident due to a failure of the vacuum interrupter by diagnosing an abnormality of the vacuum interrupter.

1 is a block diagram illustrating an apparatus for diagnosing a vacuum interrupter according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view for explaining a state in which the antenna sensor shown in FIG. 1 is disposed adjacent to the vacuum interrupter of the vacuum circuit breaker.
3 is a flowchart illustrating a method for diagnosing a vacuum interrupter according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating a method for diagnosing an abnormality of the vacuum interrupter shown in FIG. 3 .
5 is a flowchart illustrating a method for diagnosing a vacuum interrupter according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, it should be understood that this is not intended to limit the present invention to the specific disclosed form, and includes all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure. In the accompanying drawings, the dimensions of the structures are shown enlarged than actual for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 is a block diagram for explaining a vacuum interrupter diagnosis apparatus according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view for explaining a state in which the antenna sensor shown in FIG. 1 is disposed adjacent to a vacuum interrupter of a vacuum interrupter. am.

Referring to FIGS. 1 and 2 , the vacuum interrupter diagnosis apparatus 100 diagnoses an abnormality of the vacuum interrupter 10 provided in the vacuum circuit breaker 30 for cutting off current.

The vacuum interrupter 10 is composed of a housing 11 made of a ceramic or glass tube, and metallic flanges 12a and 12b bonded to upper and lower portions of the housing 11 to be sealed. Accordingly, the vacuum interrupter 10 may be formed in a cylinder shape capable of maintaining a vacuum.

A fixed electrode 13 is attached to one flange 12a of the flanges 12a and 12b, and a movable electrode 14 is attached to the opposite flange 12b. Contacts 15a and 15b are attached to the ends, respectively. Accordingly, when the two contact points 15a and 15b are attached by the movement of the movable electrode 14, current passes, and when the two contact points 15a and 15b are separated, the current is cut off.

On the inner surface of the opposite flange 12b through which the movable electrode 14 passes, there is a bellows 16 made of metal that allows movement of the movable electrode 14 and at the same time surrounds and seals the outer diameter of the movable electrode 14. Connected.

In addition, in order to prevent metal vapor generated from the contacts from being attached to the inner surface of the housing 11 when opening and closing the two contacts 15a and 15b, the metal vapor is separated by a predetermined distance along the inner surface of the housing 11. The arc shield 17 of is installed. A metallic plate-shaped O-ring 18 is attached to the arc shield 16 to fix the arc shield 16 to the housing 11 .

The vacuum interrupter 30 may further include a manipulation unit 20 for manipulating the vacuum interrupter 10 .

The vacuum interrupter diagnosis apparatus 100 may include an antenna sensor 110 and a diagnosis unit 120 .

The antenna sensor 110 is provided adjacent to the vacuum interrupter 10, and converts the electromagnetic wave signal of the partial discharge generated inside the vacuum interrupter 10 to a non-contact state according to the change in the degree of internal vacuum of the vacuum interrupter 10. detect

In the vacuum interrupter 10, since both the movable electrode 14 and the bellows 16 are made of metal, the partial discharge is relatively large at the location where the movable electrode 14 and the bellows 16 are located. do. Accordingly, the antenna sensor 110 may be disposed adjacent to the movable electrode 14 and the bellows 16 in order to detect a relatively large amount of the electromagnetic wave signal.

The diagnosis unit 120 compares the electromagnetic wave signal detected by the antenna sensor 110 with preset abnormal patterns to diagnose the abnormality of the vacuum interrupter 10 .

The abnormal patterns may be obtained for each vacuum degree at a vacuum degree exceeding 5x10 ^-4 Torr, at which partial discharge occurs in the vacuum interrupter 10 .

In addition, each of the abnormal patterns may be classified into several types according to the cause of the abnormality of the vacuum interrupter 10 . The type of the abnormal pattern may be confirmed by comparing the electromagnetic wave signal with the types of the abnormal patterns, and thus, the cause of the abnormality of the vacuum interrupter 10 may be additionally diagnosed.

Specifically, the diagnosis unit 120 may include a sampling unit 121 , a processing unit 122 and a diagnosis unit 123 .

The sampling unit 121 samples the electromagnetic wave signal sensed by the antenna sensor 110 to form sampling raw data. The sampling raw data may be displayed as a voltage of the electromagnetic wave signal in a time domain.

The sampling unit 121 may sample the electromagnetic wave signal in plurality in order to increase the accuracy of the sampling raw data. For example, the number of sampled electromagnetic wave signals may be 256 per cycle. However, the number of samplings is an example and may be adjusted according to the need.

Meanwhile, the sampling unit 121 may convert the electromagnetic wave signal from an analog signal to a digital signal. Accordingly, the sampling raw data may be displayed as the digital signal.

The processing unit 122 may form sampling data representing only voltage values greater than or equal to a preset reference value from the sampling raw data formed by the sampling unit 121 .

The reference value is set to remove meaningless voltage values generated by noise from the sampling raw data. The reference value may be set by a user or through machine learning. Accordingly, since a voltage value less than the reference value is deleted, noise may be removed from the sampling raw data and accuracy of the sampling data may be increased.

The diagnosis unit 123 receives the sampling data from the processing unit 122 and first diagnoses whether the vacuum interrupter 10 is abnormal or normal by comparing the sampling data with a preset first abnormal pattern.

The abnormal patterns may be obtained for each vacuum degree at a vacuum degree exceeding 5x10 ^-4 Torr, at which partial discharge occurs in the vacuum interrupter 10 .

Specifically, the first abnormal pattern is a pattern that appears when there is an abnormality in the vacuum interrupter 10, and may be variously set according to the degree of vacuum at which partial discharge occurs in the vacuum interrupter 10.

In addition, the first abnormal pattern may be divided into several types according to the cause of the abnormality of the vacuum interrupter 10 and set.

If the sampling data and the first abnormal pattern match, the diagnosis unit 123 diagnoses the vacuum interrupter 10 as abnormal.

In addition, when diagnosing the vacuum interrupter 10 as abnormal, the diagnosis unit 123 additionally diagnoses the cause of the abnormality of the vacuum interrupter 10 using the type of the first abnormal pattern that matches the sampling data. can do.

If the sampling data and the first abnormal pattern do not match, the diagnosis unit 123 diagnoses the vacuum interrupter 10 as normal.

The diagnosis unit 120 may further include a pattern setting unit 124 .

The pattern setting unit 124 sets a second abnormal pattern through machine learning using the primary diagnosis result of the diagnosis unit 123 .

The second abnormal pattern may be a pattern that appears when the diagnosis unit 123 diagnoses the vacuum interrupter 10 as abnormal, or may be a processed pattern obtained by processing the pattern through machine learning. The second abnormal pattern may be variously set for each vacuum degree at which partial discharge occurs in the vacuum interrupter 10 . In addition, the second abnormal pattern may be divided into several types according to the cause of the abnormality of the vacuum interrupter 10 and set.

Since the second abnormal pattern is set through machine learning, there may be a difference from the first abnormal pattern.

The diagnosis unit 123 secondarily diagnoses whether the vacuum interrupter 10 is abnormal or normal by comparing the sampling data with the second abnormal pattern.

If the sampling data and the second abnormal pattern match, the diagnosis unit 123 diagnoses the vacuum interrupter 10 as abnormal.

In addition, when diagnosing the vacuum interrupter 10 as abnormal, the diagnosis unit 123 additionally diagnoses the cause of the abnormality of the vacuum interrupter 10 using the type of the second abnormal pattern that matches the sampling data. can do.

If the sampling data and the second abnormal pattern do not match, the diagnosis unit 123 diagnoses the vacuum interrupter 10 as normal.

In addition, the diagnosis unit 123 finally diagnoses the vacuum interrupter 10 using the first diagnosis result and the second diagnosis result.

Specifically, when the vacuum interrupter 10 is diagnosed as abnormal in both the first diagnosis and the second diagnosis, the diagnosis unit 123 may diagnose the vacuum interrupter 10 as the final abnormality.

In contrast, when the vacuum interrupter 10 is diagnosed as normal in the first diagnosis and the second diagnosis, or if more than one of the vacuum interrupters is diagnosed, the diagnosis unit 123 finally determines the vacuum interrupter 10 to be normal. can be diagnosed

Since the diagnosis unit 123 uses both the first diagnosis result and the second diagnosis result, it is possible to accurately diagnose the vacuum degree abnormality of the vacuum interrupter 10 .

In addition, the diagnosis unit 123 can accurately determine the cause of the abnormality of the vacuum interrupter 10 by using the type of the first abnormal pattern and the type of the second abnormal pattern. If the cause of the vacuum interrupter 10 is confirmed, it is possible to prevent accidents caused by the vacuum interrupter 10 by removing the cause of the vacuum interrupter 10 through replacement of parts.

The diagnosis unit 120 may further include a storage unit 125 .

The storage unit 125 stores the first abnormal pattern and the second abnormal pattern set by the pattern setting unit 124 . The first abnormal pattern stored in the storage unit 125 may be used during the first diagnosis by the diagnosis unit 123 .

Also, the storage unit 125 stores diagnosis information of the diagnosis unit 123 .

Specifically, the storage unit 125 may store the first diagnosis information, the second diagnosis information, and the final diagnosis information of the diagnosis unit 123 .

The vacuum interrupter diagnosis apparatus 100 may further include a temperature and humidity measurement unit 130 and a current measurement unit 140 .

The temperature and humidity measurement unit 130 is provided inside the vacuum circuit breaker 30 and measures the temperature and humidity of the vacuum circuit breaker 30 .

The diagnosis unit 130 receives information on the temperature and humidity of the vacuum circuit breaker 30 from the temperature and humidity measurement unit 130, and converts the temperature and humidity of the vacuum circuit breaker 30 to a preset reference temperature. And compared with the humidity, the abnormality of the vacuum interrupter 10 is diagnosed.

When the temperature and humidity of the vacuum circuit breaker 30 are out of the range of the reference temperature and humidity, it is difficult for the vacuum interrupter 10 to operate normally. Therefore, the diagnosis unit 130 diagnoses the vacuum interrupter 10 as abnormal.

When the temperature and humidity of the vacuum circuit breaker 30 are within the range of the reference temperature and humidity, the diagnosis unit 130 diagnoses the vacuum interrupter 10 as normal.

The diagnosis unit 130 diagnoses the vacuum interrupter 10 based on the temperature and humidity information of the vacuum circuit breaker 30 and the temperature and humidity of the vacuum circuit breaker 30. The storage unit ( 125) can be stored.

The current measuring unit 140 measures the current of the manipulation unit 20 that manipulates the vacuum interrupter 10 .

The diagnosis unit 130 receives information on the current of the manipulation unit 20 from the current measuring unit 140 and compares the current of the manipulation unit 20 with a preset reference current to the vacuum interrupter 10 ) to diagnose abnormalities.

When the current of the manipulation unit 20 is out of the range of the reference current, it is difficult for the vacuum interrupter 10 to operate normally by the manipulation unit 20 . Therefore, the diagnosis unit 130 diagnoses the vacuum interrupter 10 as abnormal.

When the current of the manipulation unit 20 is within the range of the reference current, the diagnosis unit 130 diagnoses the vacuum interrupter 10 as normal.

Information on the current of the control unit 20 by the diagnosis unit 130 and diagnosis information obtained by diagnosing the vacuum interrupter 10 based on the current of the operation unit 20 may be stored in the storage unit 125. there is.

As described above, the diagnosis unit 123 determines the diagnosis result using the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the diagnosis result using the temperature and humidity of the vacuum interrupter 30, and the operation unit 20. The vacuum interrupter 10 may be finally diagnosed through a diagnosis result using current.

When there is an abnormality in any one of the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the temperature and humidity of the vacuum circuit breaker 30, and the current of the control unit 20, the diagnosis unit 123 The vacuum interrupter 10 is finally diagnosed as abnormal.

When the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the temperature and humidity of the vacuum interrupter 30, and the current of the control unit 20 are all normal, the diagnosis unit 123 determines the vacuum interrupter 10 ) is finally diagnosed as normal.

The diagnostic unit 123 diagnoses using the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the diagnostic result using the temperature and humidity of the vacuum circuit breaker 30, and the current of the control unit 20 Since all of the results are used, it is possible to diagnose the abnormality of the vacuum interrupter 10 accurately.

When the abnormality of the vacuum interrupter 10 is confirmed, the user checks it and takes action, so that accidents caused by the abnormality of the vacuum interrupter 10 can be prevented.

In the vacuum interrupter diagnosis device 100, the antenna sensor 110 is spaced apart from the vacuum interrupter 10 to detect the electromagnetic wave signal of the partial discharge, so that the circuit of the vacuum interrupter 10 is not blocked. The vacuum interrupter 10 can always be diagnosed. Therefore, it is possible to prevent an accident due to a failure of the vacuum interrupter 30 by diagnosing an abnormality of the vacuum interrupter 10 .

3 is a flow chart for explaining a vacuum interrupter diagnosis method according to an embodiment of the present invention, and FIG. 4 is a flow chart for explaining a vacuum interrupter diagnosis method shown in FIG. 3 .

3 and 4, first, the electromagnetic wave signal of the partial discharge generated inside the vacuum interrupter 10 according to the change in the internal vacuum level of the vacuum interrupter 10 of the vacuum circuit breaker 30 for cutting off the current is non-contact. detect the state (S110)

Detailed descriptions of the vacuum interrupter 10, the manipulation unit 20 for manipulating the vacuum interrupter 10, and the vacuum circuit breaker 30 are substantially the same as those with reference to FIGS. 1 and 2, and thus will be omitted.

In the vacuum interrupter 10, since both the movable electrode 14 and the bellows 16 are made of metal, the partial discharge is relatively large at the location where the movable electrode 14 and the bellows 16 are located. do. Accordingly, the electromagnetic wave signal may be sensed at a position adjacent to the movable electrode 14 and the bellows 16 in order to detect a relatively large amount of the electromagnetic wave signal.

Thereafter, the electromagnetic wave signal is compared with preset abnormal patterns to diagnose the abnormality of the vacuum interrupter 10 . (S120)

The abnormal patterns may be obtained for each vacuum degree at a vacuum degree exceeding 5x10 ^-4 Torr, at which partial discharge occurs in the vacuum interrupter 10 .

In addition, each of the abnormal patterns may be classified into several types according to the cause of the abnormality of the vacuum interrupter 10 . The type of the abnormal pattern may be confirmed by comparing the electromagnetic wave signal with the types of the abnormal patterns, and thus, the cause of the abnormality of the vacuum interrupter 10 may be additionally diagnosed.

The process of diagnosing the abnormality of the vacuum interrupter 10 (S120) will be described in detail.

First, sampling raw data is formed by sampling the detected electromagnetic wave signal. (S121)

The sampling raw data may be displayed as a voltage of the electromagnetic wave signal in a time domain.

In order to increase the accuracy of the sampling raw data, the electromagnetic wave signal may be sampled in plurality. For example, the number of sampled electromagnetic wave signals may be 256 per cycle. However, the number of samplings is an example and may be adjusted according to the need.

Meanwhile, in the sampling process, the electromagnetic wave signal may be converted from an analog signal to a digital signal. Accordingly, the sampling raw data may be displayed as the digital signal.

Next, sampling data representing only a voltage value equal to or greater than a predetermined reference value is formed in the sampling raw data. (S122)

The reference value is set to remove meaningless voltage values generated by noise from the sampling raw data. The reference value may be set by a user or through machine learning. Accordingly, since a voltage value less than the reference value is deleted, noise may be removed from the sampling raw data and accuracy of the sampling data may be increased.

Thereafter, by comparing the sampling data with a preset first abnormal pattern, it is first diagnosed whether the vacuum interrupter 10 is abnormal or normal. (S123)

The first abnormal patterns may be obtained for each vacuum degree at a vacuum degree exceeding 5x10 ^-4 Torr, at which partial discharge occurs in the vacuum interrupter 10 .

Specifically, the first abnormal pattern is a pattern that appears when there is an abnormality in the vacuum interrupter 10, and may be variously set according to the degree of vacuum at which partial discharge occurs in the vacuum interrupter 10.

In addition, the first abnormal pattern may be divided into several types according to the cause of the abnormality of the vacuum interrupter 10 and set.

If the sampling data and the first abnormal pattern match, the vacuum interrupter 10 is diagnosed as abnormal. In addition, when the vacuum interrupter 10 is diagnosed as abnormal, the cause of the vacuum interrupter 10 may be additionally diagnosed using the type of the first abnormal pattern that matches the sampling data.

If the sampling data and the first abnormal pattern do not match, the vacuum interrupter 10 is diagnosed as normal.

When the first diagnosis is completed, a second abnormality pattern is set through machine learning using the result of the first diagnosis. (S124)

The second abnormal pattern may be a pattern appearing in an electromagnetic wave signal detected by the vacuum interrupter 10 when the vacuum interrupter 10 is diagnosed as abnormal, or a pattern processed by machine learning. The second abnormal pattern may be variously set for each vacuum degree at which partial discharge occurs in the vacuum interrupter 10 . In addition, the second abnormal pattern may be divided into several types according to the cause of the abnormality of the vacuum interrupter 10 and set.

Since the second abnormal pattern is set through machine learning, there may be a difference from the first abnormal pattern.

When the second abnormal pattern is set, the sampling data and the second abnormal pattern are compared to secondarily diagnose whether the vacuum interrupter 10 is abnormal or normal. (S125)

If the sampling data and the second abnormal pattern match, the vacuum interrupter 10 is diagnosed as abnormal. In addition, when the vacuum interrupter 10 is diagnosed as abnormal, the cause of the vacuum interrupter 10 may be additionally diagnosed using the type of the second abnormal pattern that matches the sampling data.

If the sampling data and the second abnormal pattern do not match, the vacuum interrupter 10 is diagnosed as normal.

Thereafter, the vacuum interrupter 10 is finally diagnosed using the first diagnosis result and the second diagnosis result. (S126)

Specifically, when the vacuum interrupter 10 is diagnosed as abnormal in both the first diagnosis and the second diagnosis, the vacuum interrupter 10 may be diagnosed as the final abnormality.

In contrast, when the vacuum interrupter 10 is diagnosed as normal in the first diagnosis and the second diagnosis, or if more than one of the vacuum interrupters is diagnosed, the vacuum interrupter 10 may be finally diagnosed as normal.

Since the diagnosis is made using both the first diagnosis result and the second diagnosis result, it is possible to accurately diagnose the vacuum degree abnormality of the vacuum interrupter 10 .

In addition, it is possible to accurately determine the cause of the abnormality of the vacuum interrupter 10 using the type of the first abnormal pattern and the type of the second abnormal pattern. If the cause of the vacuum interrupter 10 is confirmed, it is possible to prevent accidents caused by the vacuum interrupter 10 by removing the cause of the vacuum interrupter 10 through replacement of parts.

Meanwhile, information on the first abnormal pattern and the second abnormal pattern and diagnostic information of the vacuum interrupter 10 are stored. (S127)

The first abnormal pattern may be stored in advance prior to the first diagnosis of the vacuum interrupter 10 and may be used during the first diagnosis of the vacuum interrupter 10 .

The diagnosis information of the vacuum interrupter 10 may include the first diagnosis information, the second diagnosis information, and the final diagnosis information.

Information of the second abnormal pattern and diagnostic information of the vacuum interrupter may be stored whenever they are generated.

5 is a flowchart illustrating a method for diagnosing a vacuum interrupter according to another embodiment of the present invention.

Referring to FIG. 5, first, the electromagnetic wave signal of the partial discharge generated inside the vacuum interrupter 10 is sensed in a non-contact state according to the change in the internal vacuum level of the vacuum interrupter 10 of the vacuum interrupter 30 for cutting off the current. do. (S210)

Thereafter, the electromagnetic wave signal is compared with preset abnormal patterns to diagnose the abnormality of the vacuum interrupter 10 . (S220)

A detailed description of the step of detecting the electromagnetic wave signal of the vacuum interrupter 10 (S210) and the step of diagnosing an abnormality of the vacuum interrupter 10 (S220) is the vacuum interrupter 10 shown in FIGS. 3 and 4. ) is substantially the same as the description of the step of detecting the electromagnetic wave signal (S110) and the step of diagnosing an abnormality of the vacuum interrupter 10 (S120).

In addition, the temperature and humidity of the vacuum circuit breaker 30 are measured. (S230)

Thereafter, the temperature and humidity of the vacuum interrupter 30 are compared with the preset reference temperature and humidity to diagnose the abnormality of the vacuum interrupter 10 . (S240)

When the temperature and humidity of the vacuum circuit breaker 30 are out of the range of the reference temperature and humidity, it is difficult for the vacuum interrupter 10 to operate normally. Accordingly, when the temperature and humidity of the vacuum circuit breaker 30 are out of the range of the reference temperature and humidity, the vacuum interrupter 10 is diagnosed as abnormal.

When the temperature and humidity of the vacuum circuit breaker 30 are within the range of the reference temperature and humidity, the vacuum interrupter 10 is diagnosed as normal.

Then, the current of the manipulation unit 20 that manipulates the vacuum interrupter 10 is measured. (S250)

Thereafter, the current of the control unit 20 is compared with a preset reference current to diagnose the abnormality of the vacuum interrupter 10 . (S260)

When the current of the control unit 20 is out of the range of the reference current, it is difficult for the vacuum interrupter 10 to operate normally by the control unit 20, so the vacuum interrupter 10 is diagnosed as abnormal.

When the current of the control unit 20 is within the range of the reference current, the vacuum interrupter 10 is diagnosed as normal.

Next, the diagnosis result using the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the diagnosis result using the temperature and humidity of the vacuum circuit breaker 30, and the diagnosis result using the current of the control unit 20 The vacuum interrupter 10 can be finally diagnosed. (S270)

When there is an abnormality in any one of the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the temperature and humidity of the vacuum circuit breaker 30, and the current of the control unit 20, the vacuum interrupter 10 is abnormally final diagnosis with

When the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the temperature and humidity of the vacuum circuit breaker 30, and the current of the control unit 20 are all normal, the vacuum interrupter 10 is finally diagnosed as normal. .

Since the diagnosis result using the partial discharge electromagnetic wave signal of the vacuum interrupter 10, the diagnosis result using the temperature and humidity of the vacuum interrupter 30, and the diagnosis result using the current of the control unit 20 are all used, An abnormality of the vacuum interrupter 10 can be accurately diagnosed.

When the abnormality of the vacuum interrupter 10 is confirmed, the user checks it and takes action, so that accidents caused by the abnormality of the vacuum interrupter 10 can be prevented.

Meanwhile, although not shown, diagnostic information of the vacuum interrupter 10 may be stored.

Specifically, information on the temperature and humidity of the vacuum circuit breaker 30 and diagnosis information obtained by diagnosing the vacuum interrupter 10 based on the temperature and humidity of the vacuum circuit breaker 30 may be stored.

In addition, information on current of the manipulation unit 20 and diagnosis information obtained by diagnosing the vacuum interrupter 10 based on the current of the manipulation unit 20 may be stored.

In addition, final diagnosis information on the vacuum interrupter 10 may also be stored.

Since the method of diagnosing the vacuum interrupter is separated from the vacuum interrupter 10 and detects the electromagnetic wave signal of the partial discharge, the vacuum interrupter 10 can always be diagnosed without blocking the circuit of the vacuum interrupter 10. there is. Therefore, it is possible to prevent an accident due to a failure of the vacuum interrupter 30 by diagnosing an abnormality of the vacuum interrupter 10 .

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

10: vacuum interrupter 20: control panel
30: vacuum breaker 100: vacuum interrupter diagnostic device
110: antenna sensor 120: diagnostic unit
121: sampling unit 122: processing unit
123: diagnosis unit 124: pattern setting unit
125: storage unit 130: temperature and humidity measuring unit
140: current measurement unit

Claims (22)

an antenna sensor provided adjacent to a vacuum interrupter of a vacuum interrupter for interrupting current and detecting, in a non-contact state, an electromagnetic wave signal of partial discharge generated inside the vacuum interrupter according to a change in the degree of internal vacuum of the vacuum interrupter; and
and a diagnosis unit for diagnosing an abnormality of the vacuum interrupter by comparing the electromagnetic wave signal detected by the antenna sensor with preset abnormal patterns. The method of claim 1, wherein the vacuum interrupter comprises a hollow tube, a movable electrode and a fixed electrode disposed to be in contact with each other inside the hollow tube, a metal bellows surrounding the movable electrode so that the movable electrode is movable, and the hollow tube. an arc shield spaced apart along the inner surface of the tube;
The antenna sensor is adjacent to the movable electrode and the metal bellows where the partial discharge is relatively large in the vacuum interrupter. The method of claim 1, wherein the diagnostic unit,
a sampling unit which samples the electromagnetic wave signal to form sampling raw data represented by a voltage level of the electromagnetic wave in a time domain;
a processor configured to form sampling data indicating only voltage values greater than or equal to a predetermined reference value in order to remove noise from the sampling raw data; and
and a diagnosis unit for firstly diagnosing whether the vacuum interrupter is abnormal or normal by comparing the sampling data with a preset first abnormal pattern. The vacuum interrupter diagnosis apparatus according to claim 3, wherein the sampling unit samples the electromagnetic wave signal in plurality in order to increase the accuracy of the sampling raw data. The method of claim 3, wherein the diagnosis unit further comprises a pattern setting unit configured to set a second abnormal pattern through machine learning using a diagnosis result of the first diagnosis unit,
The diagnosis unit compares the sampling data with the second abnormal pattern to secondarily diagnose whether the vacuum interrupter is abnormal or normal. The method of claim 5, wherein the first abnormal pattern and the second abnormal pattern are each classified into several types according to the cause of the abnormality of the vacuum interrupter,
The vacuum interrupter diagnosis apparatus according to claim 1 , wherein the diagnosis unit additionally diagnoses a cause of the abnormality of the vacuum interrupter using the types of the first abnormal pattern and the second abnormal pattern. The vacuum interrupter diagnosis apparatus according to claim 5, wherein the diagnosis unit diagnoses the vacuum interrupter as a final abnormality when both of the vacuum interrupters are diagnosed as abnormal in the first diagnosis and the second diagnosis. The method of claim 7, wherein the diagnostic unit,
The vacuum interrupter diagnosis apparatus further comprises a storage unit for storing information of the first abnormal pattern and the second abnormal pattern and diagnostic information of the diagnostic unit. The method of claim 3, further comprising a temperature and humidity measurement unit provided inside the vacuum circuit breaker and measuring the temperature and humidity of the vacuum circuit breaker,
The diagnosis unit compares the temperature and humidity of the vacuum interrupter with a preset reference temperature and humidity range to diagnose an abnormality of the vacuum interrupter. 10. The method of claim 9, further comprising a current measuring unit for measuring the current of the operating unit for manipulating the vacuum interrupter,
The vacuum interrupter diagnosis device, characterized in that the diagnostic unit diagnoses the abnormality of the vacuum interrupter by comparing the current of the manipulation unit with a preset reference current. 11. The method of claim 10, wherein the diagnostic unit finally diagnoses the vacuum interrupter as an abnormality when there is an abnormality in any one of the electromagnetic wave signal of the partial discharge of the vacuum interrupter, the temperature and humidity of the vacuum breaker, and the current of the control unit. Vacuum interrupter diagnostic device, characterized in that. sensing, in a non-contact state, an electromagnetic wave signal of partial discharge generated inside the vacuum interrupter according to a change in the degree of vacuum inside the vacuum interrupter of the vacuum interrupter for interrupting the current; and
and diagnosing an abnormality of the vacuum interrupter by comparing the electromagnetic wave signal with preset abnormal patterns. 13. The method of claim 12, wherein the vacuum interrupter comprises a hollow tube, a movable electrode and a fixed electrode disposed to be in contact with each other inside the hollow tube, a metal bellows surrounding the movable electrode so that the movable electrode is movable, and the hollow tube. an arc shield spaced apart along the inner surface of the tube;
The method of diagnosing a vacuum interrupter, characterized in that the electromagnetic wave signal is sensed at a position adjacent to the movable electrode and the metal bellows where the electromagnetic wave is relatively generated. The method of claim 12, wherein the step of diagnosing an abnormality of the vacuum interrupter,
sampling the electromagnetic wave signal to form sampling raw data represented by a voltage level of the electromagnetic wave in a time domain;
forming sampling data representing only voltage values greater than or equal to a reference value in order to remove noise from the sampling raw data; and
and firstly diagnosing whether the vacuum interrupter is abnormal or normal by comparing the sampling data with a preset first abnormal pattern. 15. The method of claim 14, wherein in the forming of the sampling raw data,
The method of diagnosing a vacuum interrupter, characterized in that for sampling the electromagnetic wave signal in plurality to increase the accuracy of the sampling raw data. 15. The method of claim 14, wherein the step of diagnosing an abnormality of the vacuum interrupter,
setting a second abnormality pattern through machine learning using a diagnosis result of the first diagnosis unit; and
The vacuum interrupter diagnosis method further comprising the step of secondarily diagnosing whether the vacuum interrupter is abnormal or normal by comparing the sampling data with the second abnormal pattern. The method of claim 16, wherein the first abnormal pattern and the second abnormal pattern are each classified into several types according to the cause of the abnormality of the vacuum interrupter,
In the step of diagnosing the vacuum interrupter as a final abnormality, a cause of the abnormality of the vacuum interrupter is further diagnosed using types of the first abnormality pattern and the second abnormality pattern. 17. The method of claim 16, wherein the step of diagnosing an abnormality of the vacuum interrupter,
and diagnosing the vacuum interrupter as a final abnormality when both of the vacuum interrupters are diagnosed as abnormal in the first diagnosis and the second diagnosis. The method of claim 18, wherein the step of diagnosing an abnormality of the vacuum interrupter,
The method of diagnosing a vacuum interrupter according to claim 1 , further comprising storing information of the first abnormal pattern and the second abnormal pattern and diagnostic information of the vacuum interrupter. The method of claim 12, further comprising: measuring temperature and humidity of the vacuum circuit breaker; and
The method of diagnosing the vacuum interrupter further comprising the step of diagnosing an abnormality of the vacuum interrupter by comparing the temperature and humidity of the vacuum interrupter with a preset reference temperature and humidity range. 21. The method of claim 20, further comprising: measuring a current of a manipulation unit for manipulating the vacuum interrupter; and
The method of diagnosing a vacuum interrupter, characterized in that it further comprises the step of diagnosing an abnormality of the vacuum interrupter by comparing the current of the control unit with a preset reference current. 22. The method of claim 21, wherein, as a result of diagnosing an abnormality of the vacuum interrupter, when an electromagnetic wave signal of a partial discharge of the vacuum interrupter, a temperature and humidity of the vacuum circuit breaker, and a current of the control unit are abnormal, the vacuum interrupter according to claim 21 is abnormal. A method for diagnosing a vacuum interrupter, further comprising the step of diagnosing the interrupter as abnormal.

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