WO2017199346A1 - Distribution-line phase-management support method and distribution-line phase-management support system - Google Patents

Abstract

Provided are a distribution-line phase-management support method and distribution-line phase-management support system capable of detecting and managing the phases of various positions on a three-phase high-voltage distribution line at any time. A prescribed pulse current is applied to one phase of a three-phase distribution line 2, the currents of each line composing the three-phase distribution line 2 are monitored at a plurality of locations on the three-phase distribution line 2, and at each of the plurality of locations, the phase of the line, from among the lines, in which the pulse current has been detected is specified.

Description

Distribution line phase management support method and distribution line phase management support system

The present invention relates to a distribution line phase management support method and a distribution line phase management support system.

In the three-phase high-voltage distribution line, it is necessary to install transformers evenly for the three-phase distribution line from the viewpoint of ensuring power quality. In general, in the three-phase high-voltage distribution line route, unexpected twisting points occur in the three-phase distribution line at three-dimensional intersections with other distribution line routes, underground wiring based on the City Planning Act, or route bends, etc. . Conventionally, in the three-phase high-voltage distribution line, the phases of each part of the distribution line are managed as a ledger. However, it is difficult to accurately manage the phases in all sections of the three-phase high-voltage distribution line extending to tens of thousands of kilometers. is there. In addition, the ledger must be rebuilt at any time during the construction and design of the distribution lines, and it takes time to manage the phases of the three-phase high-voltage distribution lines.

In Patent Document 1, a signal generator that supplies different signals to each of a plurality of phases of a distribution line is installed, and a signal is detected by a signal discriminator provided in a smart meter installed downstream of a transformer. Thus, a technique for identifying a connection phase of a smart meter is disclosed.

JP 2010-156694 A

However, the above prior art is intended to detect the connected phase of the smart meter, and is not premised on phase management in the entire area of the three-phase high-voltage distribution line. That is, since it is not possible to obtain phase information of a smart meter that does not have a signal discriminator, phase management cannot be performed in the entire area of the three-phase high-voltage distribution line. Further, since a signal having a frequency that can pass through the transformer, that is, a signal having a low frequency component of about 1 Hz to 60 Hz is used, it is difficult to distinguish it from the frequency of the commercial power source. Moreover, since it is difficult to remove the detection signal from the commercial power, the power quality may be reduced.

The present invention has been made in view of the above, and provides a distribution line phase management support method and a distribution line phase management support system capable of detecting and managing phases at various points of a three-phase high-voltage distribution line at any time. .

In order to solve the above-described problems and achieve the object, the distribution line phase management support method of the present invention applies a predetermined pulse current to one phase of a three-phase distribution line, and the above-described method is performed at a plurality of locations of the three-phase distribution line. The current of each line constituting the three-phase distribution line is monitored, and the phase of the line in which the pulse current is detected among the lines is specified for each of the plurality of locations.

As a desirable aspect of the present invention, each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series, the phase of the line in which the pulse current is detected among the lines is specified.

As a desirable mode of the present invention, a first step of applying the pulse current to the first phase of the three-phase distribution line, and monitoring the current of each line constituting the three-phase distribution line at a plurality of locations of the three-phase distribution line And, for each of the plurality of locations, a second step of specifying the phase of the line in which the pulse current is detected among the lines as the first phase, and the pulse current to the second phase of the three-phase distribution line. The third step of applying power and the current of each line at a plurality of locations of the three-phase distribution line are monitored, and the phase of the line where the pulse current is detected among the lines is defined as the second phase for each of the plurality of locations. A fourth step of identifying, a fifth step of applying the pulse current to the third phase of the three-phase distribution line, and monitoring a current of each line at a plurality of positions of the three-phase distribution line, Each line The out phase of the line pulse current is detected; and a sixth step of specifying as the third phase.

As a desirable aspect of the present invention, the steps from the first step to the sixth step are repeated each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series.

As a desirable mode of the present invention, a first step of applying the pulse current to the first phase of the three-phase distribution line, and monitoring the current of each line constituting the three-phase distribution line at a plurality of locations of the three-phase distribution line And, for each of the plurality of locations, a second step of specifying the phase of the line in which the pulse current is detected among the lines as the first phase, and the pulse current to the second phase of the three-phase distribution line. The third step of applying power and the current of each line at a plurality of locations of the three-phase distribution line are monitored, and the phase of the line where the pulse current is detected among the lines is defined as the second phase for each of the plurality of locations. A fourth step of specifying, and a fifth step of specifying, as the third phase, the phase of the line that has not been specified as the first phase and the second phase among the lines for each of the plurality of locations.

As a desirable aspect of the present invention, the steps from the first step to the fifth step are repeatedly performed each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series.

In order to solve the above-described problems and achieve the object, a distribution line phase management support system of the present invention includes a pulse power application device that applies a predetermined pulse current to each phase of a three-phase distribution line, and the three-phase distribution line. And a plurality of pulse detectors for monitoring the current of each line constituting the three-phase distribution line and detecting the pulse current, and the pulse from the pulse applying unit to one phase of the three-phase distribution line. A control device that applies a current and identifies a phase of the line in which the pulse current is detected by the pulse detection device among the lines at each of the plurality of locations.

As a preferred aspect of the present invention, the control device causes the pulse detection device of the lines to apply the pulse each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series from the pulse power application device. Identify the phase of the wire where the current was detected.

As a desirable aspect of the present invention, the control device causes the pulse current to be applied to the first phase of the three-phase distribution line from the pulse power application device, and the pulse detection device among the lines at each of the plurality of locations. The phase of the line in which the pulse current is detected is identified as the first phase, the pulse current is applied from the pulse power application device to the second phase of the three-phase distribution line, and each line is provided for each of the plurality of locations. The phase of the line in which the pulse current is detected by the pulse detection device is identified as the second phase, and the pulse current is applied from the pulse power application device to the third phase of the three-phase distribution line, For each of a plurality of locations, the phase of the line in which the pulse current is detected by the pulse detection device among the lines is specified as the third phase.

As a desirable aspect of the present invention, the control device causes the pulse current to be applied to the first phase of the three-phase distribution line from the pulse power application device, and the pulse detection device among the lines at each of the plurality of locations. The phase of the line in which the pulse current is detected is identified as the first phase, the pulse current is applied from the pulse power application device to the second phase of the three-phase distribution line, and each line is provided for each of the plurality of locations. The phase of the line in which the pulse current is detected by the pulse detection device is identified as the second phase, and for each of the plurality of locations, the phase is not identified as the first phase and the second phase. The phase of the line is identified as the third phase.

As a desirable mode of the present invention, the pulse voltage applying device is provided at the input end of the first switch provided at the output end of the substation equipment.

As a desirable mode of the present invention, the pulse voltage applying device is provided in a substation building.

As a desirable mode of the present invention, the pulse voltage applying device is provided in a housing of the first switch.

As a desirable aspect of the present invention, the pulse detection device is provided in a housing of a second switch downstream of the first switch.

According to the present invention, it is possible to provide a distribution line phase management support method and a distribution line phase management support system capable of detecting and managing phases at various points of a three-phase high-voltage distribution line at any time.

FIG. 1 is a diagram illustrating an example of a distribution system to which the distribution line phase management support system according to the first embodiment is applied. FIG. 2 is a diagram illustrating a configuration example of a distribution line phase management support system according to the first embodiment. FIG. 3 is a diagram illustrating a configuration example different from FIG. 2 of the distribution line phase management support system according to the first embodiment. FIG. 4 is a diagram illustrating a hardware configuration of the distribution line phase management support apparatus according to the first embodiment. FIG. 5 is a diagram illustrating a waveform example of a pulse current applied by the pulse applying device to the three-phase high-voltage distribution line. FIG. 6 is a diagram illustrating a waveform example of a pulse current detected by the pulse detection device. FIG. 7 is a functional block diagram illustrating a functional configuration of the distribution line phase management support system according to the first embodiment. FIG. 8 is a diagram illustrating an example of distribution line phase management information stored in the database server. FIG. 9 is a diagram illustrating an example of a first distribution line phase management information display screen according to the first embodiment. FIG. 10 is a diagram illustrating an example of a second distribution line phase management information display screen according to the first embodiment. FIG. 11 is a flowchart illustrating an example of a distribution line phase management support processing flow in the distribution line phase management support method and the distribution line phase management support system according to the first embodiment. FIG. 12 is a flowchart illustrating an example different from FIG. 11 of the distribution line phase management support processing flow in the distribution line phase management support method and the distribution line phase management support system according to the first embodiment. FIG. 13 is a diagram illustrating an example of a first distribution line phase management information display screen according to the second embodiment. FIG. 14 is a flowchart illustrating an example of a distribution line phase management support processing flow in the distribution line phase management support method and the distribution line phase management support system according to the second embodiment. FIG. 15 is a flowchart illustrating an example different from FIG. 14 of the distribution line phase management support processing flow in the distribution line phase management support method and the distribution line phase management support system according to the second embodiment.

Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention is not limited by the following modes for carrying out the invention (hereinafter referred to as embodiments). In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those in a so-called equivalent range. Furthermore, the constituent elements disclosed in the following embodiments can be appropriately combined.

(Embodiment 1)
FIG. 1 is a diagram illustrating an example of a distribution system to which the distribution line phase management support system according to the first embodiment is applied. The power distribution system shown in FIG. 1 includes substations T1, T2,..., T7, switches S1 to S18, and distributed power supply facilities D1, D2,. In the example shown in FIG. 1, the three-phase high-voltage distribution line route is indicated by a solid line, and the wired or wireless communication route is indicated by a broken line.

Substations T1, T2,..., T7 supply power to the three-phase high-voltage distribution lines. Further, the three-phase high-voltage distribution line is provided with switches S1, S2,..., S18, and the three-phase high-voltage distribution lines are divided into a plurality of sections by these switches S1, S2,. It is divided. The distributed power supply facilities D1, D2,..., D7 are linked to a three-phase high-voltage distribution line in any of these sections. Note that the distribution line phase management support system according to the present embodiment can be applied to a distribution system in which the distributed power supply facilities D1, D2,..., D7 are not linked to the three-phase high-voltage distribution lines. However, as a distribution system to which the distribution line phase management support system according to the present embodiment is applied, a large-scale distributed power supply facility such as a large-scale solar power generation (mega solar) system or a large-scale wind power generation system is connected. A three-phase high-voltage distribution system is assumed.

In the configuration of the distribution system shown in FIG. 1, the distribution automation system 4 is installed in, for example, the operation control center 3. The switching state of each switch S <b> 1, S <b> 2,. Always monitor each facility related to the power distribution system. The distribution automation system 4 controls each switch S1, S2,..., S18 to automatically set a distribution path when an accident or the like occurs in the distribution system, for example. It has a function of outputting information including the open / closed states of S2,.

FIG. 2 is a diagram illustrating a configuration example of a distribution line phase management support system according to the first embodiment. In the example shown in FIG. 2, a three-phase high-voltage distribution line (three-phase distribution line) 2 includes a three-phase high voltage of r-phase, s-phase, and t-phase from the substation facility 11 provided in the substation building 10 in the substation 1 premises. Power is supplied. A switch (first switch) 20 including a switch device 21 is provided at the output end of the three-phase high-voltage power of the substation 1. The predetermined locations a, b,..., N,... Of the three-phase high-voltage distribution line 2 include switchgears 21-a, 21-b,. , 20-n,..., 20-a, 20-b,. The three-phase high-voltage distribution line 2 includes a plurality of switches (first switches) 20 and switches (second switches) 20-a, 20-b,..., 20-n,. It is divided into sections 30. In the present embodiment, it is assumed that the presence or absence of a twisted portion in each section 30 is unknown.

The distribution line phase management support system 100 according to the present embodiment includes a pulse power application device 40 provided in the substation building 10 in one substation, and switches (second switches) 20-a, 20-b, ..., 20-n, ... Pulse detection devices 50-a, 50-b, ..., 50-n, ... provided in the housing, and power distribution automation of the operation control center 3 Distribution line phase management support device (control device) that is incorporated as part of the system 4 and controls the pulse power application device 40 and the pulse detection devices 50-a, 50-b,..., 50-n,. And 5.

In the present embodiment, the pulse applying device 40 is provided in the substation building 10 in one substation, and the pulse detection devices 50-a, 50-b,..., 50-n,. 2 switches) 20-a, 20-b,..., 20-n,. Thereby, the distribution line phase management support system 100 excellent in weather resistance can be obtained.

FIG. 3 is a diagram illustrating a configuration example different from FIG. 2 of the distribution line phase management support system according to the first embodiment. In the example shown in FIG. 3, the pulse voltage applying device 40 is provided inside the housing of the switch (first switch) 20. Even in such a configuration, the distribution line phase management support system 100a having excellent weather resistance can be obtained, as in the configuration shown in FIG.

FIG. 4 is a diagram illustrating a hardware configuration of the distribution line phase management support apparatus according to the first embodiment. The distribution line phase management support device 5 is an information processing terminal such as a computer, for example, and includes a processing unit 51, a storage unit 52, a communication unit 53, an input unit 54, and a display unit 55. It is comprised so that transmission / reception is possible. The processing unit 51 is a component that performs data transfer between each unit via a predetermined memory and controls the distribution line phase management support device 5 as a whole, and a CPU (Central Processing Unit) is stored in the predetermined memory. This is realized by executing the programmed program. The storage unit 52 is a component that stores data from the processing unit 51 and reads out the stored data. For example, the storage unit 52 is realized by a nonvolatile storage device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive). Is done. The communication unit 53 is a component that communicates with the pulse applying device 40 and the pulse detection devices 50-a, 50-b,..., 50-n,..., For example, NIC (Network Interface Card). Etc. The input unit 54 is a component for an operator to input data and instructions, and is realized by, for example, a keyboard, a mouse, a touch panel, or the like. The display unit 55 is a component that displays data according to an instruction from the processing unit 51, and is realized by, for example, a liquid crystal display (LCD) or the like.

The pulse power application device 40 imposes a predetermined pulse current on any one phase (r phase, s phase, or t phase) of the three-phase high-voltage distribution line 2 based on the control command from the distribution line phase management support device 5. Electricity.

FIG. 5 is a diagram showing a waveform example of a pulse current applied to the three-phase high-voltage distribution line by the pulse power application device. The pulse current shown in FIG. 5 is a rectangular wave signal having a fundamental frequency f and a peak value I. Here, the basic frequency f of the pulse current is assumed to be in a frequency range from about 100 [Hz] to about several tens [kHz], for example. The basic frequency f of the pulse current can be easily separated from the commercial power source in the three-phase high-voltage distribution line 2 by pulse detectors 50-a, 50-b,..., 50-n,. Moreover, it is preferable that the harmonics have a frequency that is difficult to be emitted as radiation noise. The present invention is not limited by the fundamental frequency f of the pulse current.

The pulse detection devices 50-a, 50-b,..., 50-n,... Are based on the control commands from the distribution line phase management support device 5 and the currents of the lines constituting the three-phase high-voltage distribution line 2. And a pulse current superimposed on the three-phase high-voltage distribution line 2 is detected by the pulse voltage applying device 40. And the information of the line | wire which detected the pulse current is output to the distribution line phase management assistance apparatus 5 as pulse current detection information.

FIG. 6 is a diagram showing a waveform example of a pulse current detected by the pulse detection device. The pulse detectors 50-a, 50-b,..., 50-n,... Are preferably provided with a band-pass filter having the fundamental frequency f of the pulse current as a center frequency, for example. Thereby, the fundamental frequency component of the pulse current superimposed on the three-phase high-voltage distribution line 2 by the pulse applying device 40 can be extracted. In this case, as shown in FIG. 6, it is separated from the commercial power source by the band-pass filter and becomes a substantially sine waveform from which the harmonic component is removed. Note that the peak value i (<I) of the pulse current shown in FIG. 6 is preferably a value that can be detected by the pulse detection devices 50-a, 50-b,..., 50-n,. . That is, the peak value I of the pulse current applied to the three-phase high-voltage distribution line 2 by the pulse power application device 40 shown in FIG. 5 is determined by the pulse detection devices 50-a, 50-b,. .., 50-n,..., 50-n,..., Are set to sizes that can be detected by the pulse detectors 50-a, 50-b,. preferable. It should be noted that the pulse current peak I shown in FIG. 5 and the pulse detectors 50-a, 50-b,... The present invention is not limited by the peak value i (<I) of the pulse current shown in FIG.

The pulse detectors 50-a, 50-b,..., 50-n,... Detect the fundamental wave component of the pulse current superimposed on the three-phase high-voltage distribution line 2 by the pulse applying device 40. Thus, the phase of each line at the predetermined locations a, b,..., N,. Hereinafter, predetermined locations a, b,..., N,... On the three-phase high-voltage distribution line 2 where the pulse detection devices 50-a, 50-b,. Is also referred to as “phase detection points a, b,..., N,.

Further, the pulse detectors 50-a, 50-b,..., 50-n,... Are provided with a threshold value for the detected value, and when the detected value exceeds the threshold value, the detected value is Information on the line exceeding the threshold is transmitted to the distribution line phase management support device 5 as pulse current detection information. The threshold values provided in the pulse detection devices 50-a, 50-b,..., 50-n,... May be provided for the peak value of the pulse current waveform shown in FIG. The average value or effective value of the pulse current waveform shown in FIG. 6 may be provided. The present invention is not limited by the detection method of the pulse current detected by the pulse detection devices 50-a, 50-b,..., 50-n,.

In the present embodiment, the pulse voltage applying device 40 may be configured to apply a plurality of types of pulse currents having different fundamental frequencies f to the three-phase high-voltage distribution line 2. Further, the pulse detection devices 50-a, 50-b,..., 50-n,... Have a band pass filter corresponding to the fundamental frequency f of the pulse currents of a plurality of types of patterns. Also good. With such a configuration, by changing the basic frequency f of the pulse current and performing distribution line phase management support processing described later, for example, noise mixed in the three-phase high-voltage distribution line 2 from the load side, external noise, etc. Can be eliminated, and the phase detection accuracy at the phase detection points a, b,..., N,.

FIG. 7 is a functional block diagram illustrating a functional configuration of the distribution line phase management support system according to the first embodiment.

The distribution line phase management support device (control device) 5 receives information on the distribution system to which the distribution line phase management support system 100, 100a according to the present embodiment is applied from the distribution automation system 4 as distribution system information. The distribution system information includes, for example, distribution line route information, switch installation position information, and the like.

The database server 6 has the same hardware configuration as the distribution line phase management support apparatus 3 described above, and is installed in the operation control center 3 together with the distribution line phase management support apparatus 5, for example. The database server 6 includes pulse current detection information output from the pulse detection devices 50-a, 50-b,..., 50-n,... And distribution system information input from the distribution automation system 4. And are stored as distribution line phase management information. Here, the distribution line phase management information corresponds to a conventional phase management ledger, and is updated by distribution line phase management support processing described later.

FIG. 8 is a diagram showing an example of distribution line phase management information stored in the database server. As the distribution line phase management information, as shown in FIG. 8, for example, a switch provided with pulse detectors 50-a, 50-b,..., 50-n,. ) 20-a, 20-b,..., 20-n,..., That is, the phase detection points a, b,. .. includes phase information at n,. .., 50-n,..., That is, phase detection points a, b,..., N,.・ ・ It is memorized every time.

As described above, in this embodiment, since the presence or absence of the twisted portion in each section 30 is unknown, the switches (second switches) 20-a, 20-b,..., 20-n ..,...,... Are unknown as to which phase is connected among the three phases of r phase, s phase, and t phase. In this embodiment, as shown in FIG. 8, each line of the three-phase high-voltage distribution line 2 at the phase detection points a, b,..., N,. 2 ”and“ 3 ”, and“ 1 ”is applied to the first input / output terminals of the switches (second switches) 20-a, 20-b,..., 20-n,. It is assumed that a line is connected, a “2” line is connected to the second input / output terminal, and a “3” line is connected to the third input / output terminal. For example, in the example shown in FIG. 8A, the “1” line at the phase detection point a provided with the switch (second switch) 20-a is the r phase, the “2” line is the s phase, “3” The "" line indicates the t phase. In addition, at the phase detection point b where the switch (second switch) 20-b is provided, the “1” line indicates the s phase, the “2” line indicates the t phase, and the “3” line indicates the r phase. ing. In addition, at the phase detection point n where the switch (second switch) 20-n is provided, the “1” line indicates the r phase, the “2” line indicates the t phase, and the “3” line indicates the s phase. ing. Further, in the example shown in FIG. 8B, in the distribution line phase management support process described later, the detection result of each of the lines “1”, “2”, and “3” at the phase detection point b is “NG”. That is, it is indicated that the detection result in the pulse detection device 50-b includes an error due to the influence of noise mixed in the three-phase high-voltage distribution line 2 from the load side, external noise, or the like.

FIG. 9 is a diagram illustrating an example of a first distribution line phase management information display screen according to the first embodiment. FIG. 10 is a diagram illustrating an example of a second distribution line phase management information display screen according to the first embodiment.

As shown in FIG. 9, on the first distribution line phase management information display screen 71 according to the first embodiment, a distribution line system diagram 72 that is a target of distribution line phase management support processing to be described later, and a three-phase high-voltage distribution line A selection button (frequency selection button) 73 of the basic frequency f of the pulse current to be applied to 2 and a start button (processing start button) 74 of the distribution line phase management support processing are displayed. In the example shown in FIG. 9, a configuration is shown in which the fundamental frequency of the pulse current can be selected from three of f1, f2, and f3.

Also, as shown in FIG. 9, phase detection point buttons 75 corresponding to the phase detection points a, b,..., N,. The phase detection point button 75 has a function of displaying a second distribution line phase management information display screen for displaying a phase detection result by a distribution line phase management support process described later. In addition, the phase detection point button 75 is configured to be displayed in different colors depending on whether the phase is normally detected or not normally detected in the distribution line phase management support process described later. Also good.

When an administrator (operator) of the distribution line phase management support systems 100 and 100a operates the input unit 54 to select an arbitrary phase detection point button 75, a second distribution line phase management information display screen 76 shown in FIG. 10 is displayed. Is done. The second distribution line phase management information display screen 76 may be displayed so as to overlap the first distribution line phase management information display screen 71, or may be displayed side by side with the first distribution line phase management information display screen 71. Then, the first distribution line phase management information display screen 71 may be switched to the second distribution line phase management information display screen 76 and displayed. The present invention is not limited by the display modes of the first distribution line phase management information display screen 71 and the second distribution line phase management information display screen 76.

As shown in FIG. 10, on the second distribution line phase management information display screen 76, the phase detection displayed in the distribution line system diagram 72 on the first distribution line phase management information display screen 71 and selected by the operator. The phase detection result at the phase detection point corresponding to the point button 75 is displayed. In the example shown in FIG. 10A, at the phase detection point a, it is detected that the “1” line is the r phase, the “2” line is the s phase, and the “3” line is the t phase. Yes. In the example shown in FIG. 10 (b), the detection result is an error at the phase detection point b due to, for example, the influence of noise or external noise mixed in the three-phase high-voltage distribution line 2 from the load side. Show. In this case, as shown in FIG. 10B, “NG” is displayed as the detection result of each of the lines “1”, “2”, and “3”. In addition, each part display aspect on the 2nd distribution line phase management information display screen 76 is not restricted to this, For example, the detection result of each line of "1" line, "2" line, and "3" line becomes an error. In this case, the display mode may be a mode in which “x” is displayed or a mode in which “?” Is displayed.

FIG. 11 is a flowchart illustrating an example of a distribution line phase management support process in the distribution line phase management support method and the distribution line phase management support system according to the first embodiment. First, as a precondition of the distribution line phase management support processing flow shown in FIG. 11, distribution system information from the distribution automation system 4 is input to the distribution line phase management support apparatus 5 via the communication unit 53 to the processing unit 51 and stored. Assume that it is stored in the unit 52. In addition, the storage unit 52 of the distribution line phase management support device 5 stores basic frequencies f1, f2, and f3 of a plurality of types of pulse currents applied to the three-phase high-voltage distribution line 2 from the pulse applying device 40. It shall be.

The operator operates the frequency selection button 73 on the first distribution line phase management information display screen 71 shown in FIG. 9 via the input unit 54, that is, selects one of the frequencies “f1”, “f2”, and “f3”. When the button 73 is selected, the basic frequency f of the pulse current applied to the three-phase high-voltage distribution line 2 is determined, and the distribution line phase management support process start button (process start button) 74 is selected, the first embodiment is obtained. Distribution line phase management support processing in the distribution line phase management support method is started.

When instructing the start of the distribution line phase management support processing, the processing unit 51 of the distribution line phase management support device 5 performs the three-phase operation on the pulse power application device 40 based on the distribution system information stored in the storage unit 52. A control command (pulse current charging command) is output so as to apply a predetermined pulse current to any one phase (r-phase, s-phase, or t-phase) of the high-voltage distribution line 2, and a pulse detector 50-a , 50-b,..., 50-n,..., 50-b,..., 50-b,. A control command (pulse current monitoring command) is output so as to monitor the current of the line (step S101). At this time, if the phase information is stored in the storage unit 52, the phase information is reset (step S102).

When the pulse current application command is input, the pulse applying device 40 applies a predetermined pulse current to any one phase (r phase, s phase, or t phase) of the three-phase high-voltage distribution line 2. Here, the pulse applying device 40 first applies a pulse current of the fundamental frequency (any one of f1, f2, and f3) selected by the operator to the r phase of the three-phase high-voltage distribution line 2. .

When the pulse current monitoring command is input, the pulse detection devices 50-a, 50-b,..., 50-n,. ”Line,“ 2 ”line,“ 3 ”line) are monitored, and each line constituting the three-phase high-voltage distribution line 2 (here,“ 1 ”line,“ 2 ”line,“ 3 ”line) 3), the information of the line whose detected value exceeds the threshold is output to the distribution line phase management support device 5 as the pulse current detection information at the phase detection points a, b,..., N,. To do.

When the pulse current detection information for each phase detection point a, b,..., N,... Is input to the processing unit 51 of the distribution line phase management support device 5 (step S103), the phase information is stored in the storage unit. Phase detection points a, b,..., N,... That are not stored in 52, or phase detection points a, b,. , N,..., Pulse current detection information is determined for each of the pulse detection devices 50-a, 50-b,. The following processing from step S104 to step S108 is performed by pulse detection devices 50-a, 50-b,..., 50-n installed at phase detection points a, b,. ,... Are assumed to be performed for each output result.

First, the processing unit 51 determines whether or not pulse current detection information exists (step S104). When the pulse current detection information does not exist (step S104; No), the processing unit 51 indicates that the detection result in the pulse detection devices 50-a, 50-b,..., 50-n,. The phase information is stored in the storage unit 52 as an error due to the influence of noise mixed in the phase high-voltage distribution line 2 from the load side or external noise (step S108). For example, when the detection result at the phase detection point b, that is, the detection result at the pulse detection device 50-b includes an error, as shown in FIG. “NG” is stored.

When the pulse current detection information exists (step S104; Yes), the processing unit 51 determines whether or not a plurality of pulse current detection information exists (step S105). When there are a plurality of pieces of pulse current detection information (step S105; Yes), the processing unit 51 indicates that the detection result in the pulse detection devices 50-a, 50-b,..., 50-n,. The phase information is stored in the storage unit 52 as being included (step S108).

When a plurality of pulse current detection information does not exist (step S105; No), that is, when there is only one pulse current detection information, the processing unit 51 determines whether or not the pulse current detection information is a “1” line. (Step S106). When the pulse current detection information is the “1” line (step S106; Yes), the processing unit 51 corresponds to the pulse detection devices 50-a, 50-b,..., 50-n,. The phase information is stored in the storage unit 52 on the assumption that the “1” line at the phase detection points a, b,..., N,.

When the pulse current detection information is not the “1” line (step S106; No), the processing unit 51 determines whether the pulse current detection information is the “2” line (step S107). When the pulse current detection information is the “2” line (step S107; Yes), the processing unit 51 corresponds to the pulse detection devices 50-a, 50-b,..., 50-n,. The phase information is stored in the storage unit 52 on the assumption that the “2” line at the phase detection points a, b,..., N,.

When the pulse current detection information is not the “2” line (step S107; No), that is, when the pulse current detection information is neither the “1” line nor the “2” line, the processing unit 51 performs the pulse detection device 50. Assuming that the "3" line at the phase detection points a, b, ..., n, ... corresponding to -a, 50-b, ..., 50-n, ... is the r phase, The phase information is stored in the storage unit 52 (step S108).

When the processing from step S104 to step S108 described above is performed on the output results output from all the pulse detection devices 50-a, 50-b,..., 50-n,. The processing unit 51 of the distribution line phase management support apparatus 5 determines whether or not the pulse current has been applied to all of the r-phase, s-phase, and t-phase (step S109). When the application of the pulse current is not completed for all of the r-phase, s-phase, and t-phase (step S109; No), the processing unit 51 changes the application phase of the pulse current (step S109). (S110), the processing from step S103 to step S109 is repeated.

When the application of the pulse current has been completed for all of the r-phase, s-phase, and t-phase (step S109; Yes), the processing unit 51 displays the phase information stored in the storage unit 52 as a diagram. 8 is stored in the database server 6 as distribution line phase management information shown in FIG. 8 (step S111), and from the distribution line phase management information, the first distribution line phase management information display screen 71 shown in FIG. 9 and shown in FIG. The 2nd distribution line phase management information display screen 76 is produced | generated (step S112), it displays on the display part 55, and the distribution line phase management assistance processing flow which concerns on Embodiment 1 is complete | finished.

The operator refers to the first distribution line phase management information display screen 71 and the second distribution line phase management information display screen 76 displayed on the display unit 55. For example, as shown in FIG. Is “NG”, that is, for example, the phase detection point where the detection result is an error due to the influence of noise mixed in the three-phase high-voltage distribution line 2 from the load side or external noise (shown in FIG. 10B) In the example, when the phase detection point b) exists, the basic frequency f of the pulse current applied to the three-phase high-voltage distribution line 2 is changed, and the distribution line phase management support processing flow described above is executed again.

The distribution line phase management support processing flow according to the first embodiment described above can detect and manage the phases of the three-phase high-voltage distribution line 2 at any time. In addition, for example, phase detection points a, b,..., N,... In which the detection result is an error due to the influence of noise mixed in from the load side or external noise on the three-phase high-voltage distribution line 2. Even if there is an error, the distribution line phase management support processing flow according to the first embodiment described above is executed by changing the basic frequency f of the pulse current applied to the three-phase high-voltage distribution line 2 multiple times, and an error is generated. Can be eliminated. Further, the distribution line phase management support processing flow described above is executed at the time of construction and design of the distribution lines, or periodically, thereby facilitating the phase management of the three-phase high-voltage distribution lines and the maintenance of the power quality.

FIG. 12 is a flow chart showing an example different from FIG. 11 of the distribution line phase management support processing flow in the distribution line phase management support method and distribution line phase management support system according to the first embodiment. In the following description, detailed description of the same or equivalent description as in FIG. 11 is omitted.

In the example illustrated in FIG. 12, the processing unit 51 of the distribution line phase management support device 5 determines whether or not the application of the pulse current has been completed for two phases, for example, the r phase and the s phase (step S109a). ). When the application of the pulse current to the r-phase and the s-phase has not been completed (step S109a; No), the processing unit 51 changes the application phase of the pulse current (step S110), and the steps from step S103 to step S103 are performed. The processes up to S109a are repeated.

When the application of the pulse current to the r phase and the s phase has been completed (step S109a; Yes), the two-wire phases (here, the phase detection points a, b,..., n,...) , R phase, s phase) can be specified. If the two-wire phase can be identified, the remaining one-wire phase (here, the t-phase) can be identified naturally. Therefore, even when the distribution line phase management support processing flow shown in FIG. 12 is used, the phases of the three line segments at the phase detection points a, b,..., N,.

As described above, the distribution line phase management support method according to the first embodiment applies a predetermined pulse current to each phase of the three-phase high-voltage distribution line 2 and detects a plurality of phases of the three-phase high-voltage distribution line 2. At the points a, b,..., N,..., The current of each line constituting the three-phase high-voltage distribution line 2 is monitored, and a plurality of phase detection points a, b,. In addition, the phase of each line in which the pulse current is detected is specified.

More specifically, a predetermined pulse current is applied to the r phase of the three-phase high-voltage distribution line 2, and a plurality of phase detection points a, b, ..., n,. ··· The current of each line constituting the three-phase high-voltage distribution line 2 is monitored, and the pulse current of each line is detected at each of the plurality of phase detection points a, b, ..., n, ... Are identified as the r phase. Further, a pulse current is applied to the s phase of the three-phase high-voltage distribution line 2, and the current of each line at a plurality of phase detection points a, b,. , And for each of the plurality of phase detection points a, b,..., N,. Further, a pulse current is applied to the t-phase of the three-phase high-voltage distribution line 2, and the current of each line at a plurality of phase detection points a, b,. , And for each of the plurality of phase detection points a, b,..., N,.

Alternatively, a predetermined pulse current is applied to the r phase of the three-phase high- voltage distribution line 2, and 3 is detected at a plurality of phase detection points a, b,. The current of each line constituting the phase high-voltage distribution line 2 is monitored, and the phase of the line in which the pulse current is detected among each line is detected for each of the plurality of phase detection points a, b,. Identify as phase. Further, a pulse current is applied to the s phase of the three-phase high-voltage distribution line 2, and the current of each line at a plurality of phase detection points a, b,. , And for each of the plurality of phase detection points a, b,..., N,. Then, for each of the plurality of phase detection points a, b,..., N,.

In addition, the distribution line phase management support systems 100 and 100a according to the first embodiment include a pulse applying device 40 that applies a predetermined pulse current to the three-phase high-voltage distribution line 2, and a plurality of phases of the three-phase high-voltage distribution line 2. Pulse detection devices 50-a, 50-b, which are provided at detection points a, b,..., N,..., Monitor the current of each line constituting the three-phase high-voltage distribution line 2 and detect the pulse current. ,..., 50-n,..., A pulse current is applied to each phase of the three-phase high-voltage distribution line 2 from the pulse applying device 40, and a plurality of phase detection points a, b,. Distribution line phase management for identifying the phase of each line in which the pulse current is detected by the pulse detection devices 50-a, 50-b,..., 50-n,. A support device (control device) 5.

More specifically, the distribution line phase management support device (control device) 5 applies a pulse current to the r-phase of the three-phase high-voltage distribution line 2 from the pulse power application device 40, and a plurality of phase detection points a and b. ,..., N,..., The phase of the line in which the pulse current is detected by the pulse detectors 50-a, 50-b,. Identify as phase. Further, a pulse current is applied to the s phase of the three-phase high-voltage distribution line 2 from the pulse applying device 40, and a pulse of each line is detected at each of the plurality of phase detection points a, b,. The phase of the line in which the pulse current is detected by the detection devices 50-a, 50-b,..., 50-n,. Further, a pulse current is applied to the t phase of the three-phase high-voltage distribution line 2 from the pulse applying device 40, and a pulse of each line is detected at each of the plurality of phase detection points a, b,. The phase of the line in which the pulse current is detected by the detection devices 50-a, 50-b,..., 50-n,.

Alternatively, the distribution line phase management support device (control device) 5 applies a pulse current to the r phase of the three-phase high-voltage distribution line 2 from the pulse power application device 40, and a plurality of phase detection points a, b,. , N,..., The phase of the line in which the pulse current is detected by the pulse detectors 50-a, 50-b,..., 50-n,. . Further, a pulse current is applied to the s phase of the three-phase high-voltage distribution line 2 from the pulse applying device 40, and a pulse of each line is detected at each of the plurality of phase detection points a, b,. The phase of the line in which the pulse current is detected by the detection devices 50-a, 50-b,..., 50-n,. Then, for each of the plurality of phase detection points a, b,..., N,.

This makes it possible to detect and manage the phases of the three-phase high-voltage distribution line 2 at any time. In addition, for example, phase detection points a, b,..., N,... In which the detection result is an error due to the influence of noise mixed in from the load side or external noise on the three-phase high-voltage distribution line 2. The distribution line phase management support processing method according to the first embodiment and the distribution line phase management support processing flow in the distribution line phase management support systems 100 and 100a are applied to the three-phase high-voltage distribution line 2 even when The occurrence of an error can be suppressed by changing the basic frequency f of the pulse current to be executed and executing it a plurality of times. Further, the distribution line phase management support processing flow described above is executed at the time of construction and design of the distribution lines, or periodically, thereby facilitating the phase management of the three-phase high-voltage distribution lines and the maintenance of the power quality.

Furthermore, the distribution line phase management support system 100 according to the first embodiment is provided with the pulse voltage applying device 40 at the input end of the switch (first switch) 20 provided at the output end of the substation facility 11. This pulse voltage applying device 40 is provided in the substation building 10 in the substation 1 premises, and the pulse detection devices 50-a, 50-b,..., 50-n,. 20-a, 20-b,..., 20-n,... Can be obtained in the distribution line phase management support system 100 with excellent weather resistance.

In addition, the distribution line phase management support system 100a according to the first embodiment is configured such that the pulse voltage applying device 40 is provided inside the housing of the switch (first switch) 20, so that the pulse voltage applying device 40 is transformed. Similarly to the case where it is provided in the substation building 10 in one premises, the distribution line phase management support system 100a having excellent weather resistance can be obtained.

(Embodiment 2)
FIG. 13 is a diagram illustrating an example of a first distribution line phase management information display screen according to the second embodiment. FIG. 14 is a flowchart illustrating an example of a distribution line phase management support processing flow in the distribution line phase management support method and the distribution line phase management support system according to the second embodiment. In addition, the distribution system to which the distribution line phase management support system according to the second embodiment is applied, the configuration of the distribution line phase management support system, the hardware configuration of the distribution line phase management support apparatus, and the pulse power distribution device is a three-phase high-voltage distribution line 2, the waveform of the pulse current applied to the pulse 2, the waveform of the pulse current detected by the pulse detector, the functional block indicating the functional configuration of the distribution line phase management support system, the distribution line phase management information stored in the database server, and The second distribution line phase management information display screen is the same as that of the first embodiment described above, and therefore, a duplicate description is omitted here.

As shown in FIG. 13, on the first distribution line phase management information display screen 71 a according to the second embodiment, a distribution line system diagram 72 that is a target of distribution line phase management support processing to be described later, and distribution line phase management support A process start button (process start button) 74 is displayed.

In the present embodiment, in the distribution line phase management support process to be described later, the processing unit 51 of the distribution line phase management support apparatus 5 performs the basic frequency f of the pulse current applied from the pulse power application apparatus 40 to the three-phase high-voltage distribution line 2. The configuration is changed. For this reason, in this embodiment, the selection button (frequency selection button) 73 (see FIG. 9) of the basic frequency f of the pulse current does not necessarily have to be displayed.

Hereinafter, the distribution line phase management support processing flow according to the second embodiment will be described. In addition, about the process same as the distribution line phase management assistance process flow which concerns on Embodiment 1, it abbreviate | omits.

When the operator selects the distribution line phase management support processing start button (processing start button) 74 on the first distribution line phase management information display screen 71 shown in FIG. 9 via the input unit 54, the distribution lines according to the second embodiment. Distribution line phase management support processing in the phase management support method is started. Here, the pulse applying device 40 first applies a pulse current of the fundamental frequency f <b> 1 to the r phase of the three-phase high-voltage distribution line 2.

After the phase information is stored in the storage unit 52 in step S108, the processing unit 51 of the distribution line phase management support device 5 subsequently applies a pulse current to all the phases r, s, and t. Is determined (step S109), and when the application of the pulse current to all of the r-phase, s-phase, and t-phase is completed (step S109; Yes), the processing unit 51 Determines whether or not the flow of each of the fundamental frequencies f1, f2, and f3 of the plurality of types of pulse currents stored in the storage unit 52 has been completed (step S113).

When the flow by the fundamental frequencies f1, f2, and f3 of the plurality of types of pulse currents stored in the storage unit 52 is not completed (step S113; No), the processing unit 51 receives the three-phase high voltage from the pulse voltage applying device 40. The basic frequency f of the pulse current applied to the distribution line 2 is changed (for example, changed from the basic frequency f1 to the basic frequency f2 or the basic frequency f3) (step S114), and the processing from step S103 to step S113 is repeated. To do.

When the flow of each of the plurality of types of pulse currents stored in the storage unit 52 using the fundamental frequencies f1, f2, and f3 has ended (step S113; Yes), the processing unit 51 stores the phase information stored in the storage unit 52. Is stored in the database server 6 as distribution line phase management information shown in FIG. 8 (step S111), and from the distribution line phase management information, the first distribution line phase management information display screen 71a shown in FIG. 10 is generated (step S112), displayed on the display unit 55, and the distribution line phase management support processing flow according to the second embodiment is terminated.

By executing the distribution line phase management support processing flow according to the second embodiment described above, pulse currents of a plurality of types of patterns having different fundamental frequencies f (in the above-described example, the fundamental frequencies f1, f2, and the like) without using an operator. f3 pulse current) can be applied to the three-phase high-voltage distribution line 2. Thereby, the phase detection accuracy in phase detection point a, b, ..., n, ... can be improved rather than the distribution line phase management support processing flow which concerns on Embodiment 1. FIG.

FIG. 15 is a flowchart showing an example different from FIG. 14 of the distribution line phase management support processing flow in the distribution line phase management support method and distribution line phase management support system according to the second embodiment. In the following description, detailed description of the same or equivalent description as in FIG. 14 is omitted.

In the example shown in FIG. 15, the processing unit 51 of the distribution line phase management support device 5 determines whether or not the application of the pulse current has been completed for two phases, for example, the r phase and the s phase (step S109a). ). When the application of the pulse current to the r-phase and the s-phase has not been completed (step S109a; No), the processing unit 51 changes the application phase of the pulse current (step S110), and the steps from step S103 to step S103 are performed. The processes up to S109a are repeated.

When the application of the pulse current to the r phase and the s phase has been completed (step S109a; Yes), the two-wire phases (here, the phase detection points a, b,..., n,...) , R phase, s phase) can be specified. If the two-wire phase can be identified, the remaining one-wire phase (here, the t-phase) can be identified naturally. Therefore, even when the distribution line phase management support processing flow shown in FIG. 15 is used, the phases of the three line segments at the phase detection points a, b,..., N,.

As described above, by executing the distribution line phase management support method according to the second embodiment and the distribution line phase management support processing flow of the distribution line phase management support systems 100 and 100a, the basic frequency can be obtained without an operator. A plurality of patterns of pulse currents having different f can be applied to the three-phase high-voltage distribution line 2. Thereby, the phase detection accuracy in phase detection point a, b, ..., n, ... can be improved rather than the distribution line phase management support processing flow which concerns on Embodiment 1. FIG.

In the above-described embodiment, as a method for extracting the fundamental wave component of the pulse current, for example, the pulse detection devices 50-a, 50-b,..., 50-n,. , 50-n,..., 50-n,... use a band-pass filter to provide a fundamental frequency component of the pulse current. Although the detection method using the so-called physical method, which is configured to extract the signal, has been described, the method of extracting the fundamental wave component of the pulse current is not limited to this. For example, the pulse detection devices 50-a, 50-b,..., 50-n,... Have a CT (Current Transformer) sensor (instrument current transformer), and the pulse detection devices 50-a, 50 −b,..., 50-n,... Are obtained by performing software processing such as DFT (Discrete Fourier Transform) processing on each phase current measured by the CT sensor, A detection method using a so-called logical method configured to extract a fundamental wave component may be used. In this way, by using a logical method based on software processing to extract the fundamental component of the pulse current, the frequency of the pulse current applied to the three-phase high-voltage distribution line 2 can be changed, or multiple types It is easy to change the specification when the pulse current of the pattern is configured to be able to apply power.

1 Substation 2 3-phase high-voltage distribution line (3-phase distribution line)
3 Operation Control Center 4 Distribution Automation System 5 Distribution Line Phase Management Support Device (Control Device)
6 Database server 10 Substation building 11 Substation equipment 20 Switch (first switch)
20-a, 21-b, ..., 21-n, ... Switch (second switch)
21, 21-a, 20-b,..., 20-n,... Switchgear 30 section 40 pulse power application devices 50-a, 50-b,. Detection device 51 Processing unit 52 Storage unit 53 Communication unit 54 Input unit 55 Display unit 56 Bus 71, 71a First distribution line phase management information display screen 72 Distribution line system diagram 73 Selection button (frequency selection button)
74 Start button (Process start button)
75 Phase detection point button 76 Second distribution line phase management information display screen 100, 100a Distribution line phase management support system a, b, ..., n, ... Phase detection points T1, T2, T3, T4, T5 T6, T7 substations S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14, S15, S16, S17, S18 Switches D1, D2, D3, D4 D5, D6, D7 Distributed power supply equipment

Claims (14)

1. Apply a predetermined pulse current to one phase of the three-phase distribution line,
   Monitoring the current of each line constituting the three-phase distribution line at a plurality of locations of the three-phase distribution line, and identifying the phase of the line in which the pulse current is detected among the lines for each of the plurality of locations;
   Distribution phase management support method.
2. Each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series, the phase of the line where the pulse current is detected among the lines is specified.
   The distribution line phase management support method according to claim 1.
3. A first step of applying the pulse current to a first phase of the three-phase distribution line;
   The current of each line constituting the three-phase distribution line is monitored at a plurality of locations of the three-phase distribution line, and the phase of the line in which the pulse current is detected among the lines is specified as the first phase for each of the plurality of locations. The second step;
   A third step of applying the pulse current to the second phase of the three-phase distribution line;
   A fourth step of monitoring the current of each line at a plurality of locations of the three-phase distribution line, and identifying, as the second phase, the phase of the line in which the pulse current is detected among the lines for each of the plurality of locations;
   A fifth step of applying the pulse current to a third phase of the three-phase distribution line;
   A sixth step of monitoring the current of each line at a plurality of locations of the three-phase distribution line, and identifying, as the third phase, the phase of the line in which the pulse current is detected among the lines for each of the plurality of locations;
   Having
   The distribution line phase management support method according to claim 1.
4. Each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series, the steps from the first step to the sixth step are repeatedly performed.
   The distribution line phase management support method according to claim 3.
5. A first step of applying the pulse current to a first phase of the three-phase distribution line;
   The current of each line constituting the three-phase distribution line is monitored at a plurality of locations of the three-phase distribution line, and the phase of the line in which the pulse current is detected among the lines is specified as the first phase for each of the plurality of locations. The second step;
   A third step of applying the pulse current to the second phase of the three-phase distribution line;
   A fourth step of monitoring the current of each line at a plurality of locations of the three-phase distribution line, and identifying, as the second phase, the phase of the line in which the pulse current is detected among the lines for each of the plurality of locations;
   For each of the plurality of locations, a fifth step of identifying a phase of a line that has not been identified as the first phase and the second phase among the lines as a third phase;
   Having
   The distribution line phase management support method according to claim 1.
6. Each time the plurality of types of pulse currents having different fundamental frequencies are applied in time series, the steps from the first step to the fifth step are repeatedly performed.
   The distribution line phase management support method according to claim 5.
7. A pulse applying device for applying a predetermined pulse current to each phase of the three-phase distribution line;
   A plurality of pulse detection devices that are provided at a plurality of locations of the three-phase distribution line, monitor the current of each line constituting the three-phase distribution line, and detect the pulse current;
   The pulse current is applied to one phase of the three-phase distribution line from the pulse power application device, and the phase of the line where the pulse current is detected by the pulse detection device among the lines is specified for each of the plurality of locations. A control device;
   Comprising
   Distribution line phase management support system.
8. The control device includes:
   Each time a plurality of types of pulse currents having different fundamental frequencies are applied in time series from the pulse power application device, the phase of the line in which the pulse current is detected by the pulse detection device among the lines is specified.
   The distribution line phase management support system according to claim 7.
9. The control device includes:
   The pulse current is applied to the first phase of the three-phase distribution line from the pulse power application device, and the phase of the line in which the pulse current is detected by the pulse detection device among the lines is determined for each of the plurality of locations. Identified as Phase 1,
   The pulse current is applied to the second phase of the three-phase distribution line from the pulse applying device, and the phase of the line in which the pulse current is detected by the pulse detecting device among the lines is determined for each of the plurality of locations. Identified as Phase 2,
   The pulse current is applied to the third phase of the three-phase distribution line from the pulse power application device, and the phase of the line in which the pulse current is detected by the pulse detection device among the lines is determined for each of the plurality of locations. Identified as the third phase,
   The distribution line phase management support system according to claim 7 or 8.
10. The control device includes:
    The pulse current is applied to the first phase of the three-phase distribution line from the pulse power application device, and the phase of the line in which the pulse current is detected by the pulse detection device among the lines is determined for each of the plurality of locations. Identified as Phase 1,
    The pulse current is applied to the second phase of the three-phase distribution line from the pulse applying device, and the phase of the line in which the pulse current is detected by the pulse detecting device among the lines is determined for each of the plurality of locations. Identified as Phase 2,
    For each of the plurality of locations, a phase of a line that is not specified as the first phase and the second phase among the lines is specified as a third phase.
    The distribution line phase management support system according to claim 7 or 8.
11. The pulse voltage applying device is provided at an input end of a first switch provided at an output end of a substation facility,
    The distribution line phase management support system according to claim 7.
12. The pulse power application device is provided in a substation building,
    The distribution line phase management support system according to claim 7.
13. The pulse voltage applying device is provided in a casing of the first switch.
    The distribution line phase management support system according to claim 7.
14. The pulse detection device is provided in a housing of a second switch downstream of the first switch.
    The distribution line phase management support system according to any one of claims 11 to 13.

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