KR102436136B1 - IoT sensor module for sensing electric arc of power line - Google Patents

Abstract

The present invention relates to an Internet of Things (IoT) sensor module for detecting arc discharge in transmission and distribution lines. More specifically, the present invention relates to an IoT sensor module which is installed at a point where the arc discharge is likely to occur in order to prevent a large-scale fire such as a forest fire caused by the arc discharge occurring in the transmission and distribution lines and which can transmit a danger signal through an IoT communications network by detecting the arc discharge when the arc discharge occurs in the transmission and distribution lines. The IoT sensor module according to the present invention is installed to monitor a point where pole-mounted electric power equipment such as a switchgear, a transformer and a cable head is connected to a drop wire, when a series arc occurs due to a loose contact or a disconnection at a connection point with the electric power equipment, the loose contact or the disconnection can be automatically detected and the danger signal can be transmitted through the IoT communications network. Accordingly, a manager of the corresponding transmission and distribution lines can quickly find and inspect an area where the danger signal is generated, and prevent the arc discharge from expanding into a larger arc discharge accident or developing into the large-scale fire such as the forest fire.

Description

IoT sensor module for sensing electric arc of power line

The present invention relates to an IoT sensor module for detecting arc discharge in a transmission/distribution line. More specifically, in order to prevent large fires such as forest fires due to arc discharge occurring on transmission lines or distribution lines, it is mounted at a point where arc discharge is likely to occur and detects arc discharge on transmission and distribution lines. Thus, it relates to an IoT sensor module that can transmit a dangerous signal through the Internet of Things (IoT) communication network. The IoT sensor module according to the present invention is mounted so as to monitor the point where the electric power cut-down wire is connected to a pole power device such as a switchgear, a transformer, or a cable head, and the reason for poor contact or disconnection at the connection point with the power device, etc. When a serial arc discharge occurs, it can automatically detect it and transmit a dangerous signal through the IoT communication network. Therefore, the manager of the transmission/distribution line can quickly find and inspect the area where the dangerous signal is generated, and it is possible to prevent it from escalating into a larger arc discharge accident or developing into a large fire such as a forest fire.

Transmission and distribution lines often pass through mountainous areas where trees are dense. When a ground fault or short circuit accident occurs in a transmission line or distribution line crossing a mountainous region, overheating or arc discharge may occur due to the overcurrent generated at the accident point, which may lead to a wildfire. However, in the case of parallel arc discharge, which is an arc discharge caused by a ground fault or short circuit accident between wires, which occurs due to disconnection of the wire itself, etc., a highly reliable traditional protection system such as a ground fault relay or an overload relay operates. Because it is possible to quickly cut off the related lines, there are not many cases that lead to actual fire or casualties.

However, at the point where it is connected to a power device installed on a pylon or column, due to a series arc discharge that occurs due to a disconnection due to poor contact at the connection point or the accumulation of fatigue in the connection line, it may lead to a large forest fire in dry seasons such as spring. There is a need for measures to address this. In the case of the forest fire that occurred in Toseong-myeon, Goseong-gun, Gangwon-do in 2019, it was ignited by a series arc discharge that occurred at the connection point between the column switch of the 22.9kv special high-voltage distribution line and the in-ha electric wire, which developed into a very large forest fire that damaged a whopping 1,757ha of forest. is the case Therefore, there is a high need to detect a series arc discharge accident occurring on a power transmission line or a distribution line at an early stage and prevent the spread of a forest fire, personal injury, or property damage.

Arc discharge refers to a discharge phenomenon in which electricity flows while breaking an insulating layer such as air, continuously generating sparks, and generating heat and flame. Arc discharge can be divided into parallel arc discharge and series arc discharge according to the mechanism of its occurrence. As shown in Fig. 1(a), when the wires of each phase are close to each other, such as between phase A and phase B, the parallel arc discharge occurs as the insulation between phases is broken, or when the wire of each phase comes into contact with or close to the ground wire or the ground. This is what happens when the insulation is broken. In other words, parallel arc discharge is a discharge that occurs between wires having a high potential difference, coming into contact with each other in the absence or damaged state, or in the gap between two wires while approaching them too closely. In parallel arc discharge, since the phase-to-phase voltage is directly applied to the arc discharge area, an excessive current flows in the area where the arc discharge occurs. However, in the case of parallel arc discharge, a very large overcurrent is generated in an instant, so it can be detected quickly in a substation or various line protection facilities. damage can be prevented from spreading.

On the other hand, series arc discharge occurs at an incomplete connection part of a single conductor, such as a faulty connection of a power device or damage to an internal line. That is, as shown in Fig. 1(b), the series arc discharge is an arc discharge generated in a gap formed due to a contact failure or disconnection in one of the wires of each phase. Therefore, the spark or flame generated by the series arc discharge depends on the magnitude of the load current, and is not generated by the potential difference between phases, so it is generated in a smaller size than in the parallel arc discharge. And since it is connected in series with the load, the arc current increases in proportion to the load current, so it is difficult to determine whether an arc discharge has occurred only by the increase in the current. However, since series arc discharge also causes sparks and flames like parallel arc discharge, there is a possibility that not only power equipment is damaged, but the flame or flame is transferred to surrounding trees or buildings, and it is likely to spread to general fires or wildfires. Nevertheless, there is a problem in that it is difficult to quickly determine whether a series arc discharge occurs because it is rarely accompanied by an overcurrent enough to be detected in the power supply stage, such as in a substation, at the initial stage of the series arc discharge.

As such, arc discharge causes fire hazard as well as casualties, so detection of arc discharge is very important for accident prevention. As a conventional method for detecting arc discharge, it is possible to detect the occurrence of a spark by using a light receiving element near a region where arc discharge is likely to occur, or to detect the occurrence of arc discharge by detecting the ripple voltage or the frequency of the arc waveform. There is a method, and there is also a method of detecting and measuring electromagnetic waves emitted during the arc discharge generation process. However, the method of using a light receiving element is appropriate in a dark indoor such as a substation or a switchboard, but there is a problem in that it is difficult to use it in a transmission and distribution line because it is difficult to detect the occurrence of a spark outdoors in the presence of sunlight. In addition, the method of detecting arc discharge by analyzing the frequency of the ripple voltage or arc waveform is installed in each supply area or branch circuit to operate a circuit breaker when arc discharge is detected. When an arc discharge is detected, it is possible to prevent an arc discharge accident from expanding by blocking the branch line itself, but it becomes impossible to detect the point where the arc discharge occurs among long-distance lines such as transmission and distribution lines. That is, the method of detecting and analyzing the frequency of the arc waveform can detect that the arc discharge has occurred at any point in any one line, but it is difficult to detect exactly at which point it occurred, and the There is also the problem that expensive parts are required because analysis and judgment are required.

And the detection method using radiated electromagnetic waves is not only short of reach, but also in places where electromagnetic radiation due to other reasons, such as corona discharge, is generated due to the noise. It is useful in a closed space, but it is difficult to apply in the case of transmission and distribution lines that are installed outdoors and formed over long distances, as well as corona discharges, temporary flashovers caused by brains, reverse flashovers, etc., on the surface of electric wires. there has been

On the other hand, when an arc discharge occurs, harmonics are generated on the wire path. Harmonics generated by arc discharge sometimes flow to the wire of the phase where the arc discharge occurred, but harmonics generated in each phase flow into the neutral wire to form zero harmonic current. Therefore, it is possible to determine whether an arc discharge has occurred by measuring the third harmonic, which is the zero harmonic current flowing through the neutral line, but since the harmonics generated in the transmission and distribution lines are caused by various causes, the occurrence of harmonics is caused by arc discharge. There is a problem that it cannot be determined that it is. Therefore, it was difficult to apply the arc discharge detection method through the detection of harmonics.

The IoT sensor module for detecting arc discharge in a transmission and distribution line according to the present invention, which was created to solve the above-mentioned problems, is an IoT sensor module that can quickly detect and transmit a danger signal when a serial arc discharge occurs on a transmission and distribution line. intended to provide

Another object of the present invention is to provide an IoT sensor module for detecting arc discharge in transmission and distribution lines, which can prevent a wildfire from occurring or spreading to a large forest fire by quickly identifying it in the management body when a series arc discharge occurs on the transmission and distribution line. will provide

Another object of the present invention is to transmit a dangerous signal along with its identification information when a series arc discharge occurs on a transmission/distribution line, so that the monitoring server that receives the danger signal can quickly identify the exact location of the arc discharge. , to provide an IoT sensor module for detecting arc discharge in transmission and distribution lines.

Another object of the present invention is to prevent erroneous detection by filtering when a signal similar to arc discharge is received even though arc discharge has not occurred, and through this, IoT sensor for detecting arc discharge in transmission and distribution lines, which can increase the reliability of detection of series arc discharge to provide a module.

Another object of the present invention is to provide an IoT sensor module for detecting arc discharge in a transmission/distribution line, which has high durability and low maintenance cost, so that power to operate the IoT sensor module is supplied semi-permanently, which is economical.

Another object of the present invention is to provide an IoT sensor module for detecting arc discharge in a transmission/distribution line that can perform highly reliable serial arc discharge detection without using expensive components for analyzing arc discharge waveforms.

Another object of the present invention is to detect when the secondary side of the current transformer is opened so that high voltage is generated from the secondary side of the current transformer in the IoT sensor module so that the IoT sensor module is not destroyed or a fire is caused by this. It is to provide an IoT sensor module for detecting arc discharge in a transmission/distribution line having a safety means that can be short-circuited.

Another object of the present invention is to provide an IoT sensor module for detecting an arc discharge in a transmission/distribution line, which can quickly and easily detect the failure of the IoT sensor module in a monitoring server.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

In order to achieve the above object, the present invention provides an IoT sensor module for detecting an arc discharge occurring on a power transmission line or a distribution line, comprising: harmonic measuring means for measuring harmonics flowing in the electric line; Electromagnetic wave measuring means for measuring the radiated electromagnetic wave generated due to arc discharge; Communication means for transmitting and receiving data by connecting to the Internet of Things (IoT) communication network; storage means; and a control means; wherein, in the storage means, an identification code for identifying each of the IoT sensor modules is stored, and the control means, - the harmonic measurement value measured by the harmonic measurement means at a predetermined interval while monitoring the measured value of the electromagnetic wave measured by the electromagnetic wave measuring means while storing it in the storage means, - while the measured value of the radiated electromagnetic wave is measured higher than the reference value, the current measured value of harmonics among the measured harmonics is the storage means If it exceeds a certain range than the previous harmonic measurement value stored in the , it is judged as an arc discharge, - In the case of determining the arc discharge, a danger signal including the identification code is generated and transmitted through the communication means It is preferable to use an IoT sensor module for detecting arc discharge in a transmission/distribution line, which is characterized.

The present invention also provides, in addition to the above-mentioned features, the IoT sensor module is installed on one electric wire of the electric wire, and the harmonic measuring means measures the current value of the third harmonic flowing in the one electric wire. , an IoT sensor module for detecting arc discharge in transmission and distribution lines, or in addition to this, the harmonic measuring means is a current measuring device that measures a current transformer, a band filter connected to both ends of the secondary terminal of the current transformer, and the third harmonic current passing through the band filter It is also preferable to be an IoT sensor module for detecting arc discharge in a transmission/distribution line, characterized in that it comprises a.

The present invention also provides an IoT sensor module for detecting arc discharge in a transmission/distribution line, characterized in that in addition to the above features, the one wire is an overhead neutral wire, and the current transformer can be fixed while surrounding the overhead neutral wire In addition, a negative temperature coefficient (NTC) thermistor is connected to both ends of the secondary side of the current transformer in parallel with the band filter, and the NTC thermistor is attached to the iron core of the current transformer to operate according to the iron core temperature of the current transformer. When the temperature of the current transformer rises, both ends of the secondary side of the current transformer are short-circuited, and when the NTC thermistor shorts both ends of the secondary side of the current transformer, the communication unit generates a fault signal including the identification code and then the communication unit It is also preferable to use an IoT sensor module for detecting arc discharge in a transmission/distribution line, characterized in that it is transmitted through the .

As described above, since the IoT sensor module for detecting arc discharge in a transmission/distribution line according to the present invention detects an arc discharge using electromagnetic waves and harmonics at the same time, 'series arc discharge', which is difficult to detect at the beginning of occurrence, occurs on the transmission/distribution line. However, it has the effect of detecting it quickly and accurately.

The present invention also, when an arc discharge occurs on the transmission/distribution line, it detects it quickly and transmits a danger signal including its own identification code, so that the device (monitoring server, etc.) Since the exact location can be quickly identified and informed to the manager, etc., even if a series arc discharge occurs on the transmission/distribution line, it is effective to prevent the occurrence of a forest fire or the spread of a large forest fire.

In addition, the occurrence of arc discharge is detected by measuring the radiated electromagnetic wave generated due to arc discharge, but since it is judged in consideration of the change in harmonics flowing through the electric wire, it is possible to filter electromagnetic noise caused by corona discharge, etc. occurring on the transmission and distribution lines. Therefore, there is an effect of increasing the reliability of the arc discharge detection.

In addition, since it has a current transformer for measuring harmonic current inside and includes a power supply means constituting a charging circuit with the power supplied through the current transformer, operating power can be supplied semi-permanently, and thus durability is high and maintenance cost is high This has the effect of providing an IoT sensor module that costs less and is highly economical.

In addition, as a means for measuring the intensity of electromagnetic waves and a means for measuring the intensity of harmonics can be made relatively simply, economically and reliably to detect the occurrence of arc discharge, the arc discharge waveform can be analyzed There is an effect that it is possible to provide an IoT sensor module that can detect arc discharge with high reliability even if expensive parts are not used.

In addition, at both ends of the secondary side of the current transformer in the IoT sensor module, an NTC thermistor is connected in parallel with the band filter to operate according to the iron core temperature of the current transformer. Therefore, even if the secondary side of the current transformer is opened due to a breakdown of the band filter, etc., high voltage is generated and the IoT sensor module is not destroyed or fire does not occur. Therefore, it is possible to provide an IoT sensor module with enhanced safety even though it is an IoT sensor that is installed at a very high voltage above a special high voltage.

In addition, when the NTC thermistor short-circuits both ends of the secondary side of the current transformer, it includes a configuration that generates and transmits a fault signal including an identification code. there is an effect In addition, if the IoT sensor module transmits an operation signal including the identification code and the third harmonic value at regular time intervals, daily inspection of the IoT sensor module can be automatically performed, and the zero-phase current flowing through the transmission and distribution line is constantly monitored Since it can be monitored, it is possible to achieve the effect of blocking in advance the occurrence of various problems such as overheating of the neutral line and malfunction of the relay due to the zero current flowing in the neutral line of the transmission and distribution line.

1 shows a conceptual diagram of generation of a parallel arc discharge (a) and a series arc discharge (b).
2 is a diagram illustrating a state in which the IoT sensor module for detecting arc discharge in a transmission/distribution line according to the present invention is mounted on the electric line.
3 is an enlarged view of the IoT sensor module according to the present invention mounted on a wire path.
4 is an internal configuration diagram of an IoT sensor module according to the present invention.
5 is a block diagram of a monitoring system using an IoT sensor module according to the present invention.
6 is a configuration diagram of a harmonic measuring means among IoT sensor modules according to the present invention.
7 illustrates a current transformer included in the IoT sensor module according to the present invention.
8 is a block diagram of a case in which an NTC thermistor is included in the harmonic measuring means in the present invention.

Hereinafter, the present invention will be described in detail so that the above-described objects and features become clear, and accordingly, those skilled in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In addition, in the description of the present invention, if it is determined that the detailed description of the known technology may unnecessarily obscure the gist of the present invention as it is already well known in the technical field among the known technologies related to the present invention, the detailed description thereof is omitted. to be omitted.

In addition, the terms used in the present invention have been selected as widely used general terms as possible, but in certain cases, there are also terms arbitrarily selected by the applicant. It is intended to clarify that the present invention should be understood as the meaning of the term, not the name. Terms used in the description of the embodiments are only used to describe specific embodiments, and are not intended to limit the embodiments. The singular expression includes the plural expression unless the context clearly dictates otherwise.

Embodiments may be modified in various forms and may have various additional embodiments, in which specific embodiments are shown in the drawings and related detailed descriptions are given. However, this is not intended to limit the embodiments to specific forms, and it should be understood to include all changes or equivalents or substitutes included in the spirit and scope of the embodiments.

In the description of various embodiments, expressions such as “first”, “second”, “first”, or “second” may modify various components of the embodiments, but do not limit the corresponding components. For example, the above expressions do not limit the order and/or importance of corresponding components. The above expressions may be used to distinguish one component from another.

Hereinafter, the present invention will be described with reference to the accompanying drawings. 1 shows a conceptual diagram for a situation in which parallel arc discharge (a) and series arc discharge (b) occur. As described above, in the parallel arc discharge as shown in FIG. 1(a), due to a short circuit or a ground fault between phases, an overcurrent rapidly flows while a high voltage is applied to a short circuit or a ground fault, so that an arc discharge of a considerable size occurs. However, due to such overcurrent, parallel arc discharge is not only quickly detected by various protection systems such as overcurrent protection facilities or ground fault protection facilities, but also the technology that can detect even the location of ground faults or short circuits in these protection facilities or systems. Since it has been developed and applied, in the case of parallel arc discharge, it can be taken rather quickly compared to its size or risk.

However, since the series arc discharge as shown in Fig. 1 (b) is a state connected in series to the load, the voltage applied to the gaps at both ends of the discharged wire is small, so that the current value that increases due to the arc is not large, but also proceeds slowly or normally Since the state and the arc discharge state may occur alternately, there has been a problem in that it is difficult to detect this in the protective equipment installed on the power supply side such as a substation. Even if an arc waveform analysis or ripple voltage analysis device is installed in a substation, etc.

The present invention is to solve this problem, and when a series arc discharge occurs in a power transmission line or a distribution line, it is to provide an IoT sensor module that can quickly determine whether an arc discharge has occurred and the point of occurrence. 2 shows a state in which the 'IoT sensor module 100 for detecting arc discharge in a transmission/distribution line' according to the present invention is mounted on the electric wire 220. As shown in FIG. As shown in FIG. 2 , the IoT sensor module 100 for detecting arc discharge in a transmission/distribution line according to the present invention is preferably installed in a location where a pole power device 230 is installed, where a series arc discharge is highly likely to occur in a transmission/distribution line. . That is, as shown in FIG. 2 , it is preferable to install it near the place where the pole transformer 230 is installed, or a pylon or electric pole 210 in which a pole switch or cable head is installed. As a specific mounting position, as shown in FIG. 2 , it is preferable to be mounted on the overhead wire 220 wired to a pylon or electric pole 210 , and among them, it is most preferable to be mounted on the overhead neutral wire 221 .

As shown in FIG. 2, in a place where a pole power device 230, such as a pole transformer, is installed, a cut-down wire 250 branching down from the electric wire 220 and a COS (Cut Out Switch, 240) or COS (Cut Out Switch, 240) connected thereto ( 240) and the pole power device 230 are connected with a down wire 250, and since these down wires 250 are easily shaken by wind or vibration, the There is a possibility that poor contact may occur, and if it is shaken by wind or vibration, there is a high possibility that some of the multiple strands constituting the down-duty wire 250 may be disconnected due to fatigue applied to the down-duty wire 250 . . When a part of the stranded wire constituting the cut-down electric wire 250 is disconnected, heat is generated, and damage or fatigue caused by the heat is aggravated, so that the entire electric wire is temporarily disconnected. In this way, there is a possibility that a gap may be generated due to poor contact or disconnection in the portion where the electric wire 250 for cut-down and the power device are connected.

This possibility is the same even in places where switchgear, automatic reclosing device, lightning arrester, power fuse, cable head, circuit breaker or branch line are installed. In the place where such a pole power device 230 is installed, the point where the down-duty wire 250 is connected to the wire line 220, the power device 230 such as a power fuse or COS 240 connection, hot clamp, transformer bushing, etc. This is because, when the screw fastened to the connection part is shaken by wind or vibration, it may become loose, and there is a high possibility of contact failure due to corrosion caused by wind and rain. Therefore, in the pylon or electric pole 210 in which the pole power device 230 is installed, the possibility of series arc discharge increases, and when such a pylon or electric pole 210 is installed in a mountainous area, the series arc discharge causes a forest fire accident. chances will increase

The IoT sensor module 100 for detecting arc discharge in the transmission and distribution line according to the present invention is mounted on the overhead wire 220 on the pylon or electric pole 210 in which the pole power device 230 is installed, and preferably, the overhead neutral wire ( 221), it is a sensor that detects a series arc discharge occurring in a portion where the pole power device 230 and the electric wire 250 for cut-down are connected. 3 is an enlarged view of the IoT sensor module 100 for detecting arc discharge in a transmission/distribution line according to the present invention mounted on an electric line. As will be described later, since the IoT sensor module 100 according to the present invention has to measure the harmonic components flowing in the electric wire, a current measuring means and a current transformer (CT) for it to measure the current flowing in the electric wire 220 and 221 are provided. should be provided However, in the case of the current transformer (CT), it is preferable to be mounted while wrapping the electric wire, so as shown in FIG. 3 , the main body 101 of the IoT sensor module 100 is a conductor of the overhead wire 220, more preferably the overhead neutral wire ( It is preferable to include a clamp 102 that can wrap and fix the conductor of 221). And it is preferable that the clamp 102 be firmly fastened to the processed neutral wire 221 by the fastening means 103 .

4 is an internal configuration diagram of the IoT sensor module 100 for detecting arc discharge in a transmission/distribution line according to the present invention. As described above, the present invention is an IoT sensor module 100 for detecting a series arc discharge occurring on a power transmission line or a distribution line 200, and as shown in FIG. 4, a harmonic measuring means ( 110), electromagnetic wave measuring means 120 for measuring radiated electromagnetic waves generated due to arc discharge, communication means 130 for transmitting and receiving data by connecting to the Internet of Things (IoT) communication network, and the harmonic measuring means 110 To include a storage means 140 that can store the measured values or the identification code of the IoT sensor module 100 and other necessary data, and further include a control means 190 that can control these components It is preferable to do In addition, the electromagnetic wave measuring means 120 includes an electromagnetic wave receiving antenna 121 for receiving electromagnetic waves radiated due to serial arc discharge, and the communication means 130 includes Internet of Things (IoT) communication data for transmitting and receiving data. It is preferable to include the IoT antenna 131 . In the case of the electromagnetic wave receiving antenna 121, a directional antenna capable of receiving electromagnetic waves from the downward inclined side toward the pole power device 230 and the down-grade wire 250 installed in a pylon or electric pole 210, etc. more preferably.

When the series arc discharge phenomenon occurs, it is accompanied by high-frequency pulse current, vibration, light, gas, ultrasonic wave, and radiation electromagnetic wave. Therefore, it is possible to determine whether a series arc discharge has occurred by measuring one of the radiated electromagnetic waves. When a series arc discharge occurs, the radiation electromagnetic wave is measured in a very wide band of 30 Mhz to 500 Mhz, and shows a high electric field strength in a band of 100 Mhz to 160 Mhz. Therefore, in the present invention, the electromagnetic wave measuring means 120 is provided to measure the radiated electromagnetic wave, and when a radiated electromagnetic wave having a high electric field strength is emitted due to the occurrence of a series arc discharge, it is sensed to determine whether a series arc discharge has occurred. On the other hand, in the case of radiated electromagnetic waves due to series arc discharge, as described above, since the frequency band is very high (microwave and microwave), the straightness is high and there is no reflection in the ionosphere. And since the radiation output of the electromagnetic wave by the series arc discharge is not so high, the radiation electromagnetic wave caused by the series arc discharge cannot reach a very distant place. Therefore, measurement is possible only in the vicinity or the electromagnetic wave measuring means 120 located in the vicinity.

However, in transmission and distribution lines, radiated electromagnetic waves are not only generated in series arc discharge or parallel arc discharge, but also by other causes. For example, radiated electromagnetic waves are also generated by corona discharge generated when insulation of the air layer is destroyed by high voltage around the conductor. Therefore, when the electromagnetic wave measuring means 120 receives these radiation electromagnetic waves, there is a risk of erroneous determination as a series arc discharge. Therefore, if a series arc discharge is sensed only with radiated electromagnetic waves in an environment such as a transmission/distribution line, the probability of false detection is very high and effectiveness is reduced.

Therefore, the IoT sensor module 100 according to the present invention further includes the harmonic measurement means 110 in addition to the electromagnetic wave measurement means 120 . When a series arc discharge occurs, harmonics are generated, and in general, the content of the third harmonic component is the highest in addition to the fundamental wave. The third harmonic also flows through the overhead wire 220 of the phase in which the series arc discharge occurs, but all the third harmonics generated in each phase flow into the overhead neutral wire 221 to form a zero-phase current. Therefore, theoretically, if the third harmonic component is measured at the neutral wire, it will be possible to determine whether a series arc discharge has occurred. However, since harmonic components are generated by various causes in transmission and distribution lines, it is impossible to determine whether a series arc discharge has occurred only by measuring the harmonics. However, in the IoT sensor module 100 according to the present invention, the harmonic measurement result measured by the harmonic measurement means 110 is used together with the measurement result of the electromagnetic wave measured by the electromagnetic wave measuring means 120 to prevent the series arc discharge. It was possible to accurately determine the occurrence.

To this end, the control unit 190 stores the harmonic measurement value measured by the harmonic measurement unit 110 in the storage unit 140 at regular time intervals, and the electromagnetic wave measurement unit 120 measures the radiated electromagnetic wave. While monitoring the measured value, when the measured value of the radiated electromagnetic wave is measured higher than the reference value, the current measured value of harmonics among the measured values of harmonics exceeds a predetermined range of the measured values of the previous harmonics stored in the storage means 140 , it is preferable to judge this situation as a situation in which a series arc discharge has occurred. That is, if electromagnetic waves are measured in a place where there is a high probability of occurrence of a series arc discharge and harmonics increase at the same time, it is determined that a series arc discharge has occurred, so it is possible to accurately determine the occurrence of a series arc discharge.

Here, “storing the harmonic measurement value in the storage means 140 at the 'predetermined time interval'” means that the harmonic measurement means 110 continuously measures the harmonic measurement value, and measures the harmonics measured every moment. It refers to continuously storing a value in the storage means 140 at short time intervals, such as '1 second interval', '2 second interval' or '5 second interval', for example, There will be a limit to the storage capacity, and when judging the occurrence of a series arc discharge, only the most recent records are used, not all the records. It is preferable to do so.

In addition, the 'reference value' takes into account the measurement level of radiated electromagnetic waves that can be normally received and the radiated electromagnetic wave noise generated by corona discharge, etc., and the IoT sensor module 100 and the power device 230 or the In consideration of the distance to the electric wire 250, it is preferable to set the minimum value that can be measured when the series arc discharge actually occurs. In addition, it is also preferable to limit the measured value of the radiated electromagnetic wave measured by the electromagnetic wave measuring means 120 to a value measured in a specific frequency band. For example, if it is limited to a band of 100 Mhz to 160 Mhz that can represent a high electric field strength among the radiated electromagnetic waves of the series arc discharge, it will be a method to increase the precision of measurement and reduce the manufacturing cost.

And, “when the current harmonic measurement value exceeds a certain range than the previous harmonic measurement value stored in the storage means 140” means the harmonic measurement at the moment when the 'radiation electromagnetic wave measurement value is measured higher than the reference value' It refers to setting the value to a value higher within a certain range than the harmonic measurement value stored in the storage means 140 - for example, a value 10% or more higher than the previous value in the effective value of the third harmonic current. Here, the immediately preceding value may be the value stored immediately before, but it is more preferable to use the average value of the values stored immediately before. For example, the average value of the 10 measurement records measured and stored immediately before the measurement of the current harmonic measurement value.

On the other hand, the control means 190 is the measured value of the radiation electromagnetic wave of the electromagnetic wave measuring means 120, the harmonic measured value (current value) of the harmonic measuring means 110, and the harmonics stored in the storage means (140) When it is determined that a serial arc discharge has occurred as a result of determination based on the measured value (the previous value), etc., a danger signal including an identification code is generated and transmitted to the IoT communication network 700 through the communication means 130 it is preferable Here, the identification code is unique identification information uniquely assigned to each IoT sensor module 100 , and it is preferable to be stored in the storage means 140 , but the control means 190 or the communication means 140 . It is also possible to use the UID included in . The IoT communication network 700 preferably uses a conventional low power wide area (LPWA) communication network such as LoRa, but it is also possible to use a network such as LTE-M.

5 is a block diagram of a system using an IoT sensor module according to the present invention. It is preferable that the IoT sensor module 100 according to the present invention be mounted at each position where a series arc discharge is likely to occur among transmission lines or distribution lines. Therefore, as shown in FIG. 5 , a plurality of IoT sensor modules 100 are installed on a power transmission line or a distribution line 200 , and each overhead neutral wire 221 wired to a pylon or electric pole 210 in which the power device 230 is installed. installed at each location. And, as described above, when a serial arc discharge is detected among the plurality of IoT sensor modules 100, the control means 190 of the IoT sensor module 100 that has sensed the serial arc discharge includes its own identification code. After generating the danger signal, the danger signal is transmitted to the IoT communication network 700 through the communication means 130 . Therefore, it is preferable to include a monitoring server 500 that can receive this, identify the location where the serial arc discharge has occurred, and inform the administrator or the like.

The monitoring server 500 has an identification code for each of the plurality of IoT sensor modules 100 and a location table for each of the plurality of IoT sensor modules 100 mounting positions corresponding to each identification code. It is preferable to do And, when the monitoring server 500 receives the danger signal through the IoT communication network 700, it is preferable to use the location table to identify the location where the serial arc discharge occurs and inform the manager.

Meanwhile, FIG. 6 shows a configuration diagram of the harmonic measuring means 110 included in the IoT sensor module 100 according to the present invention. As described above, the harmonic measuring means 110 is a means for measuring a harmonic component flowing in the transmission line or the distribution line 200 . Therefore, it is preferable to measure the current flowing through the wires 220 and 221 to find the harmonic components contained therein and measure the effective value thereof. In the present invention, the current flowing through the overhead wire 220, preferably processing A current transformer 111 for measuring the current flowing through the neutral wire 221, a band filter 112 connected to both ends of the secondary terminal of the current transformer 111 in order to filter only harmonic components in the current, and the band filter 112. It is preferable to include a current meter 113 for measuring the passed harmonic current.

As shown in FIG. 7 , the current transformers 111 and CT are preferably formed of an annular iron core 111a surrounding the conductor 221 of the electric wire and a secondary winding 111b wound around the annular iron core 111a. In this way, the primary side of the current transformer 111 (CT) becomes the conductor 221 of the electric wire, and the secondary side becomes the secondary winding 111b wound around the annular iron core 111a, and the conductor 221 of the electric wire. The value of the current flowing through is lowered at a constant rate to flow through both ends of the secondary winding 111b. The annular iron core 111a constituting the current transformer 111 is connected to the main body 101 of the IoT sensor module 100 and positioned inside the clamp 102 surrounding the conductor 221, so that the clamp ( 102) is spread and wrapped around the conductor 221 of the electric wire, the annular iron core 111a surrounds the conductor 221, and is guided through the annular iron core 111a and the secondary winding 111b. Current flows to the band filter 112 and the current meter 113 . The annular iron core 111a is opened when the clamp 102 is opened, and when the clamp 102 is tightened, the annular shape can be completed, as shown in FIG. 7 , two halves It is also preferable to combine the annular iron cores to form one annular iron core 111a.

In addition, the band filter 112 is connected to both ends of the secondary winding 111b wound around the annular iron core 111a, which is the secondary side of the current transformer 111, and is a specific component of the current transformed through the current transformer 111. It is a configuration that filters out only the harmonic, preferably the third harmonic component. Therefore, the bandpass filter 112 is a bandpass filter that passes only the frequency band of 180hz so that all of the fundamental wave and other harmonic components among the currents transformed by the current transformer 111 can pass and only the third harmonic component can pass. It is preferable to do Since the band filter 112 passes only the third harmonic component, the value measured by the current measuring device 113 may be the effective value of the current of the third harmonic. It is more preferable to transmit the value measured by the current meter 113 to the control means 190 . As such, the present invention can implement the harmonic measuring means 110 for measuring only the third harmonic component with a simple configuration of the CT 111, the band filter 112, and the current measuring device 113, so the number of parts is small, so durability There is an effect that can provide this high and economical IoT sensor module (100).

A power supply unit 180 capable of supplying power required for operation of each component (communication unit, control unit, etc.) of the IoT sensor module 100 is connected between the current transformer 111 and the band filter 112 . more preferably. Preferably, the power supply means 180 includes a storage battery (not shown) that can be charged with the current supplied from the current transformer 111 and a charging circuit (not shown) for this. In this configuration, the power required for the operation of the IoT sensor module 100 can be used semi-permanently.

On the other hand, in the present invention, the configuration diagram of the embodiment including the NTC thermistor 114 in the harmonic measuring means 100 is shown in FIG. In the case of the current transformer 111 for measuring the current flowing in the conductor 221 of the electric wire, when the secondary side is opened, the magnetic flux of the iron core 111a constituting the current transformer 111 is rapidly increased, so that the current transformer 111 is A high voltage is applied to the secondary side of the Therefore, when the portion connected to the band filter 112 and the power supply unit 180 is disconnected and the secondary side of the current transformer 111 is in an open state, the IoT sensor module 100 is damaged and localized A fire may occur. Therefore, it is preferable that the IoT sensor module 100 according to the present invention further includes means for preventing this.

To this end, it is preferable to connect a negative temperature coefficient (NTC) thermistor 114 in parallel with the band filter 112 at both ends of the secondary side of the current transformer 111, and the NTC thermistor 140 increases in temperature. It is a device whose resistance value goes down. And the NTC thermistor 140 is attached to the annular iron core 111a of the current transformer 111 so as to operate according to the iron core temperature of the current transformer 111, and when the temperature of the current transformer 111 rises, the resistance value increases. It is preferable to go down to short-circuit both ends of the secondary side of the current transformer 111 .

And when the NTC thermistor 140 short-circuits both ends of the secondary side of the current transformer 111, the control means 190 generates a fault signal including the identification code and then through the communication means 130 It is preferable to transmit the data to the IoT communication network 700 . The control means 190 determines whether the current flowing through the current meter 113 becomes 0, measures the current value flowing through the NTC thermistor 114, or measures the voltage across the NTC thermistor 114 It is possible to know whether the NTC thermistor 140 has short-circuited both ends of the secondary side of the current transformer 111 by a method or the like. The monitoring server 500 that has received the failure signal through the IoT communication network 700 identifies the location where the IoT sensor module 100 that transmits the failure signal with the identification code included in the failure signal is mounted. and notify the manager, etc. of this so that they can take necessary action.

Meanwhile, the control means 140 generates an operation signal including its identification code and the harmonic measurement value at regular time intervals and transmits it to the IoT communication network 700 through the communication means 130 . it is preferable In this case, the monitoring server 500 can not only check whether the IoT sensor modules 100 are operating normally, but also constantly monitor the third harmonic value flowing through the transmission line or the distribution line 200. Therefore, it has a means to monitor the zero-phase current flowing in the neutral wire.

Although the present invention has been described with the various examples described above, the present invention is not necessarily limited to these examples, and various modifications may be made within the scope without departing from the technical spirit of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these examples. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100 IoT sensor module
101 Body 102 Clamp
103 Fastening means 110 Harmonic measuring means
111 current transformer 111a annular iron core
111b secondary winding 112 bandpass filter
113 Current Meter 114 NTC Thermistor
120 Electromagnetic wave measuring means 121 Electromagnetic wave receiving antenna
130 Communication means 131 IoT antenna
140 Storage means 180 Power supply means
190 Control means
200 transmission line or distribution line
210 pylon or pole 220 overhead wire (wire line)
221 overhead neutral wire 230 pole power equipment
240 COS 250 down-grade wire
500 monitoring server
700 Internet of Things Network

Claims (5)

As an IoT sensor module mounted on an overhead neutral wire wired to a pylon or electric pole in which a pole power device is installed in order to detect a series arc discharge occurring on a transmission line or a distribution line,
harmonic measuring means for measuring harmonics flowing in the electric wire;
Electromagnetic wave measuring means for measuring the radiated electromagnetic wave generated due to arc discharge;
Communication means for transmitting and receiving data by connecting to the Internet of Things (IoT) communication network;
storage means; and
control means; including,
An identification code for identifying each of the IoT sensor modules is stored in the storage means,
The control means,
- While the harmonic measurement value measured by the harmonic measurement means is stored in the storage means at regular time intervals, while monitoring the radiation electromagnetic wave measurement value measured by the electromagnetic wave measurement means,
- When the measured value of the radiation electromagnetic wave is measured higher than the reference value and at the same time, the current measured value of the harmonic among the measured values of the harmonic exceeds a certain range than the measured value of the previous harmonic stored in the storage means It is judged as an arc discharge, ,
- When it is determined as the arc discharge, a danger signal including the identification code is generated and transmitted to the monitoring server through the communication means,
- At regular time intervals, an operation signal including the identification code and the harmonic measurement value is generated and transmitted to the monitoring server through the communication means,
The immediately preceding harmonic measurement value is an average value of measurement records measured before the current harmonic measurement value measurement and stored in the storage means,
The harmonic measuring means includes a current transformer that can be fixed to surround the overhead neutral wire in order to measure the current value of the third harmonic flowing in the processed neutral wire, a band filter connected to both ends of the secondary terminal of the current transformer, and the band filter. Comprising a current meter for measuring the third harmonic current passed through,
Negative temperature coefficient (NTC) thermistors are connected to both ends of the secondary side of the current transformer in parallel with the band filter,
The NTC thermistor is attached to the iron core of the current transformer to operate according to the iron core temperature of the current transformer, and short-circuits both ends of the secondary side of the current transformer when the temperature of the current transformer rises;
When the NTC thermistor short-circuits both ends of the secondary side of the current transformer, the control means generates a fault signal including the identification code and transmits it to the monitoring server through the communication means,
The monitoring server may identify a mounting position of the IoT sensor module that has transmitted the danger signal, the failure signal, or the operation signal using the location table corresponding to the identification code, and receives the operation signal to receive the operation signal. IoT sensor module for detecting arc discharge in transmission and distribution lines, characterized in that it is possible to determine whether each module operates normally and monitor the zero-phase current on the transmission line or distribution line
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