JP2018060764A - Electronic breaker and power distribution monitoring system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow the installed place and state of a breaker to be easily learned.SOLUTION: A power distribution monitoring system includes: an electronic breaker 100 including a current detection unit 130 for detecting conduction current, a cutoff unit 120 for cutting off conduction, a communication unit 102 for transmitting a detection result, and a control unit 101 for maintaining control so as to transmit a detection result if the detection result has changed; and a terminal device 200 including a communication unit 202 for receiving the detection result transmitted by the electronic breaker, a display unit 203 for displaying various types of information, and a control unit 201 for having the display unit 203 display the distance, direction and state of the electronic breaker 100 on the basis of the received detection result.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electronic breaker and a power distribution monitoring system, and more particularly to an electronic breaker capable of easily grasping a position and a state and a power distribution monitoring system using the electronic breaker.

  When the load exceeds a predetermined current capacity, the breaker cuts off the current for safety. In addition, it is necessary for a human being to visit the site to check the breaking status of the breaker. Moreover, such a breaker does not transmit any information. In addition, various proposals have been made in the following patent documents for similar technologies as power distribution monitoring systems.

JP-A-11-281702

  The overcurrent monitoring wireless notification system described in Patent Document 1 is configured to be able to identify an accident section in which an overcurrent has occurred by notifying wirelessly when an overcurrent is detected and receiving this notification. Yes. In the overcurrent monitoring wireless notification system described above, the presence / absence of overcurrent in the current transformer arranged on the distribution line is simply notified wirelessly using a mobile phone or the like. For this reason, it is necessary to know the overcurrent monitoring position (the location where the monitoring device is installed) in advance. Further, notification is made only after an overcurrent occurs, and the state is not always monitored. Furthermore, there are problems that are not suitable for applications where there are a large number of monitoring positions, such as breakers, or expansion.

  An object of this invention is to provide the electronic breaker which can grasp | ascertain an installation position and a state easily, and the power distribution monitoring system using this electronic breaker.

That is, the present invention for solving the above-described problems is as follows.
(1) An electronic breaker of the present invention includes a current detection unit that detects an energization current to a load, a blocking unit that interrupts energization to the load, a communication unit that transmits a detection result of the current detection unit, and the current A control unit that controls each unit according to the detection result of the detection unit, and the control unit controls the communication unit to transmit the detection result when a change occurs in the detection result of the current detection unit. It is characterized by.
Further, the power distribution monitoring system of the present invention includes a current detection unit that detects an energization current to a load, a blocking unit that interrupts energization to the load, a communication unit that transmits a detection result of the current detection unit, An electronic breaker including a control unit that controls the communication unit to transmit the detection result when a change occurs in the detection result, a communication unit that receives the detection result transmitted from the electronic breaker, and various information The terminal device includes: a display unit for displaying; and a control unit for displaying the distance, direction, and state of the electronic breaker on the display unit based on the received detection result.

  (2) In the electronic breaker and power distribution monitoring system according to (1) above, when the current detection unit detects that the energization current exceeds a set current value, the electronic breaker is loaded with the interrupting unit. The communication unit transmits an interruption of energization, and the terminal device displays the state of the electronic breaker on the display unit based on the content received from the electronic breaker. And

  (3) In the electronic breaker and power distribution monitoring system according to (1) and (2) above, the electronic breaker transmits an identification signal, and the terminal device transmits the electronic signal based on the identification signal. A breaker is identified, and the state of the electronic breaker is displayed on the display unit.

  (4) In the electronic breaker and power distribution monitoring system according to (1) to (3) above, the electronic breaker transmits at a predetermined communication frequency, and the terminal device receives the content received at the communication frequency. Based on the above, the state of the electronic breaker is displayed on the display unit.

  (5) In the electronic breaker and the power distribution monitoring system according to (1) to (4) above, the electronic breaker is used when the detection result of the current detection unit does not change even if a predetermined time or more elapses. The communication unit is controlled to transmit the detection result when the predetermined time has elapsed, and the terminal device displays the state of the electronic breaker on the display unit based on the received content.

  (6) In the electronic breaker and power distribution monitoring system according to (1) to (5) above, a plurality of electronic breakers each having a different identification signal are installed as the electronic breaker, and the terminal device is Each of the plurality of electronic breakers is identified based on the identification signal, and the state of each of the plurality of electronic breakers is displayed on the display unit.

  (7) In the electronic breaker and power distribution monitoring system according to (1) to (6) above, the terminal device transmits a cutoff control signal to the electronic breaker via the communication unit, and the electronic breaker Receives the cutoff control signal from the terminal device via the communication unit, and the cutoff unit cuts off the power supply to the load based on the cutoff control signal.

  (8) In the electronic breaker and the distribution monitoring system according to (1) to (7) above, the terminal device transmits a set current value, and the electronic breaker receives the set current value from the terminal device. It receives, updates the said setting current value, and controls interruption | blocking of the electricity supply to the load by the said interruption | blocking part based on the said setting current value updated.

  (9) In the electronic breaker and the power distribution monitoring system described in (1) to (8) above, it is possible to provide a vibration sensor and a smoke sensor in addition to the current detection unit.

According to the present invention, the following effects can be obtained.
(1) In the present invention, the electronic breaker includes a current detection unit that detects an energization current to the load, a blocking unit that interrupts energization of the load, a communication unit that transmits a detection result of the current detection unit, and a current detection unit. A control unit that controls each unit according to the detection result of the unit, and the control unit controls the communication unit to transmit the detection result when a change occurs in the detection result of the current detection unit. Further, the terminal device includes a communication unit that receives a detection result transmitted from the electronic breaker, a display unit that displays various information, and a control unit that displays the state of the electronic breaker on the display unit based on the received detection result. . Thereby, it becomes possible to grasp | ascertain easily the installation position and state of an electronic breaker by the terminal device side.

  According to the electronic breaker and the power distribution monitoring system of the present invention, it is effective for factories, apartment houses, commercial buildings, etc. having many breakers, and has excellent visual operability. And it becomes easy to quickly recover at the time of interruption, and to find out the cause of the interruption, and it is possible to minimize the economic loss of power outage due to breaker interruption.

  (2) In the power distribution monitoring system according to (1) above, when the current detection unit detects that the energization current has exceeded the set current value, the electronic breaker blocks the energization to the load. At the same time, the communication unit transmits an interruption of energization, and the terminal device displays the state of the electronic breaker on the display unit based on the content received from the electronic breaker. As a result, the load and wiring are protected from overcurrent, and the installation position and state of the electronic breaker where the overcurrent has occurred can be easily grasped on the terminal device side.

  (3) In the power distribution monitoring system according to (1) to (2) above, the electronic breaker transmits an identification signal, the terminal device identifies the electronic breaker based on the identification signal, and the electronic breaker's The status is displayed on the display unit. As a result, even when there are a plurality of electronic breakers, it is possible to easily and reliably grasp the installation position and state of the electronic breaker where the state change has occurred on the terminal device side.

  (4) In the power distribution monitoring system according to the above (1) to (3), the electronic breaker transmits at a predetermined communication frequency, and the terminal device determines the state of the electronic breaker based on the content received at the communication frequency. Display on the display. As a result, even when there are a plurality of electronic breakers, it is not affected by interference, and it is possible to reliably and easily grasp the installation position and state of the electronic breaker where the state change has occurred on the terminal device side. .

  (5) In the power distribution monitoring system according to (1) to (4) above, when the detection result of the current detection unit does not change even if the detection result of the current detection unit elapses over a predetermined time, the electronic breaker Control is performed so that the communication unit transmits the detection result, and the terminal device displays the state of the electronic breaker on the display unit based on the received content. Thereby, even in a situation where no state change occurs, the installation position and state of the electronic breaker can be reliably and easily grasped on the terminal device side, including survival confirmation and abnormal leaving.

  (6) In the power distribution monitoring system according to (1) to (5) above, a plurality of electronic breakers to which different identification signals are attached are installed as electronic breakers, and a plurality of terminal devices are provided based on the identification signals. Each electronic breaker is identified, and the state of each of the plurality of electronic breakers is displayed on the display unit. Thereby, even when there are a plurality of electronic breakers, it is possible to easily grasp the installation position and state of the electronic breaker (state change, overcurrent occurrence, survival confirmation, abnormal neglect, etc.).

  (7) In the power distribution monitoring system according to (1) to (6) above, the terminal device transmits a cutoff control signal to the electronic breaker via the communication unit, and the electronic breaker is shut off from the terminal device. The control signal is received via the communication unit, and the cutoff unit cuts off the power supply to the load based on the cutoff control signal. Thereby, after grasping the installation position and state of the electronic breaker on the terminal device side, it becomes possible to control the interruption of the electronic breaker from the terminal device.

  (8) In the power distribution monitoring system according to (1) to (7) above, the set current value is transmitted from the terminal device, and the electronic breaker receives the set current value from the terminal device and updates the set current value. And the interruption | blocking of the electricity supply to the load by the interruption | blocking part is controlled based on the said setting current value updated. This not only makes it possible to easily grasp the installation position and state of the electronic breaker, but also allows the set current value for interruption to be changed remotely, so that it is flexible and appropriate for the usage situation. Correspondence becomes possible.

  (9) In the electronic breaker and power distribution monitoring system described in (1) to (8) above, in addition to the current detection unit, other detection units such as a vibration sensor and a smoke sensor are provided, and the detection result of the detection unit is transmitted. This makes it possible to detect various states.

It is a block diagram which shows the structure of embodiment of this invention. It is a block diagram which shows the structure of embodiment of this invention. It is explanatory drawing which shows the operation state of embodiment of this invention. It is a flowchart which shows operation | movement of embodiment of this invention. It is explanatory drawing which shows the display screen of the terminal device of embodiment of this invention. It is explanatory drawing which shows the display screen of the terminal device of embodiment of this invention.

Hereinafter, a power distribution monitoring system 10 including an electronic breaker 100 and a terminal device 200 according to an embodiment of the present invention will be described in detail with reference to the drawings.
〔Constitution〕

  As shown in FIG. 1, the power distribution monitoring system 10 of the present embodiment includes an electronic breaker 100 and a terminal device 200. In FIG. 1, a three-wire wiring is shown as a specific example, but a two-wire wiring may be used. Further, the wiring 1a is defined as an upstream side close to the electric utility, and the wiring 1b is defined as a downstream side close to the load.

  Here, the electronic breaker 100 is disposed on the switchboard or distribution board, and cuts off the power supply to the load when it detects that the energization current exceeds the set current value. The electronic breaker 100 can be used as various breakers generally called a safety breaker, a current breaker, a leakage breaker, a circuit breaker, and the like.

  The electronic breaker 100 is controlled by electronic control as shown in FIG. 1, and includes a control unit 101, a communication unit 102, a storage unit 105, a power supply unit 110, a cutoff unit 120, and a current detection unit 130. It is prepared for.

  The control unit 101 includes a CPU and various processors, and controls each unit in the electronic breaker 100 as described below by processing of a control program.

  The communication unit 102 has a transmission function for transmitting the detection result of the energization current at least wirelessly. Note that the communication unit 102 preferably includes a reception function for receiving an instruction from the terminal device 200.

  The memory | storage part 105 memorize | stores the identification signal provided in order to identify each electronic breaker 100, a transmission frequency, or a transmission / reception frequency by a non-volatile memory element.

  The power supply unit 110 includes a power supply circuit 111 connected to the upstream wiring 1a that is not interrupted, and supplies power necessary for the operation of the electronic breaker 100 to each unit.

  The interruption unit 120 is normally connected (conducted) between the upstream side wiring 1a and the downstream (load) side wiring 1b (when the energizing current does not exceed the set current value), and the overcurrent (the energizing current is reduced). When the set current value is exceeded), the contacts 121, 122, and 123 that switch between connection and disconnection between the wires and the electromagnetic that drives the connection / disconnection state of the contacts 121 to 123 are disconnected. And a drive unit 124 composed of a solenoid or the like.

  The current detection unit 130 calculates a current value from the sensors 131, 132, 133 such as current transformers connected to the wiring 1a or the wiring 1b and the detection results of the sensors 131-133 in order to detect the energization current value. Current value calculation circuit 134.

  In addition, the electronic breaker 100 includes a manual pressing type reset switch (not shown) that restores the connection from the cut-off in the cut-off unit 120. In addition, when the electronic breaker 100 having the communication function of the present embodiment is disposed at an existing position such as a distribution board or a distribution board, it is desirable that the electronic breaker 100 has a size and shape equivalent to those of a conventional electronic breaker. That is, it can be said that the electronic breaker 100 of the present embodiment is a wireless built-in electronic breaker that is equivalent in appearance to a conventional breaker.

  The control unit 101 controls the communication unit 102 to transmit the detection result when a change occurs in the detection result of the current detection unit 130. Moreover, the control part 101 is controlled so that the interruption | blocking part 120 interrupts | blocks the electricity supply to a load, when the electric current detection part 130 detects that the energization current exceeded the setting electric current value. In addition, when the current detection unit 130 detects that the energization current exceeds the set current value, the control unit 101 controls the interruption unit 120 to interrupt the energization of the load, and the energization by the interruption unit 120 is performed. Control is performed so that the communication unit 102 transmits the interruption. In addition, when the detection result of the current detection unit 130 changes or when the state of the blocking unit 120 changes, the control unit 101 causes the communication unit 102 to send an identification signal to the detection result or the change in state. It controls to attach and transmit. Further, the control unit 101 causes the communication unit 102 to transmit at a predetermined communication frequency when a change occurs in the detection result of the current detection unit 130 or when the state of the blocking unit 120 changes. Control. In addition, the control unit 101 controls the communication unit 102 to transmit the detection result when the predetermined time elapses when no change occurs even if the detection result of the current detection unit 130 elapses for a predetermined time or longer. In addition, when there are a plurality of electronic breakers 100, different identification signals are given respectively. In addition, when the communication unit 102 receives a cutoff control signal from the terminal device 200, the control unit 101 controls the cutoff unit 120 to cut off the power supply to the load based on the cutoff control signal. Further, when the communication unit 102 receives the set current value from the terminal device 200, the control unit 101 updates the set current value in the storage unit 105, and based on the updated set current value, the blocking unit 120 controls the interruption of energization to the load by 120. Further, in the electronic breaker 100, in addition to the current detection unit 130, other detection units (not shown) such as a vibration sensor and a smoke sensor can be provided.

  Here, the terminal device 200 is composed of a computer having a communication function, preferably a portable device such as a tablet, a notebook PC, or a smartphone. And this terminal device 200 is the state (connection, interruption | blocking, electric current value, position) of the electronic breaker 100 in the state which the user possesses in space, such as a factory provided with a plurality of electronic breakers 100, an apartment house, and a commercial building. Etc.) on the display unit.

  As shown in FIG. 1, the terminal device 200 includes a control unit 201, a communication unit 202, an operation display unit 203, and a storage unit 205.

  The control unit 201 is configured by a CPU and various processors, and receives communication from the electronic breaker 100 and displays the state of the electronic breaker 100 on the operation display unit 203 by processing of a control program such as a breaker state display program. To control.

  The control unit 201 also has a position / direction calculation function that receives communication from the electronic breaker 100 and calculates the position and direction of the electronic breaker 100 from the change in electric field strength.

  The communication unit 202 has a reception function for receiving at least communication such as the detection result of the energized current from the electronic breaker 100 and the presence or absence of interruption. Note that the communication unit 202 also preferably includes a transmission function for transmitting an instruction to the electronic breaker 100 such as blocking. Note that the communication unit 202 may include a known direction detection antenna or a variable directivity antenna whose directivity can be switched in order to identify each direction of the electronic breaker 100.

  The operation display unit 203 displays various states of operation input to the control unit 201 via the touch panel and keys by the user who is the owner of the terminal device 200 and displays the state of the electronic breaker 100 processed by the control unit 201. It appears on the display.

The storage unit 105 stores the communication frequency used by each of the electronic breakers 100 in advance, and stores the state until the next time the state of the electronic breaker 100 processed by the control unit 201 is updated.
[Example of arrangement]

  FIG. 2 shows a state in which a plurality of m electronic breakers 100a to 100m are arranged with respect to the wiring 1 in a space A such as a factory, an apartment house, or a commercial building. Here, the wiring 1 is connected to the upstream wiring 1a, the electronic breaker 100a, the downstream wiring 1b, and the load 300a. The same applies to the other electronic breakers 100b to 100m.

  And in the space A, the terminal device 200 which a user uses may be one, and several n terminal devices 200a-200n may be used like FIG. In this case, in the plurality of n terminal devices 200a to 200n, the positions and states of the plurality of m electronic breakers 100a to 100m viewed from the position of each terminal are displayed on the screen.

FIG. 3 shows a state in which 16 electronic breakers 100 (# 01 to # 16) are arranged in a space A1 such as a factory, an apartment house, or a commercial building. A state in which the user U carrying the terminal device 200 is located near the center of the space A1 is shown as a specific example.
[Operation]

Hereinafter, the operation of the power distribution monitoring system 10 including the electronic breaker 100 and the terminal device 200 will be described with reference to the flowchart of FIG.
[Operation on the electronic breaker 100 side]

  A plurality of electronic breakers 100 can be arranged in a space such as a factory, an apartment house, or a commercial building. Therefore, identification signals that do not overlap at least in the same space are assigned and stored in the storage unit 105 so that each of the plurality of electronic breakers 100 can be identified (step S101 in FIG. 4). The identification signal may be set by a user or a contractor using a dip switch or the like, or may be assigned by the manufacturer of the electronic breaker 100 at the time of manufacture. Further, the communication frequency used by each of the electronic breakers 100 is stored in the storage unit 105 so as not to overlap in the same space. The communication frequency may be set by a user or a contractor using a dip switch or the like, or may be assigned by the manufacturer of the electronic breaker 100 at the time of manufacture.

  Then, the user or a construction contractor installs the electronic breaker 100 in which the identification signal and the communication frequency are set as described above at a necessary place as shown in FIGS. 2 and 3 (steps S102 and S103 in FIG. 4). . In addition, a qualified person installs this electronic breaker 100 as needed. With this installation, the power supply circuit 111 supplies power to each unit, and the control unit 101 starts operation according to the control program.

  When the installation is completed (YES in step S103 in FIG. 4), the user or the contractor operates a manually pressed reset switch (not shown) to turn on the electronic breaker 100 (contact point = connected) and load Is supplied with power (step S104 in FIG. 4).

  When the electronic breaker 100 enters an energized state and starts supplying power to the load, the control unit 101 changes the energized current value calculated by the current detection unit 130 or changes the state of the interrupting unit 120 (disconnection → connection, connection → interruption). ) Is monitored (step S105 in FIG. 4).

  When the current detection unit 130 detects that the energization current value has exceeded the set current value (YES in step S106 in FIG. 4 (exceeding the set value)), the interrupting unit 120 opens the contacts 121-123. Then, the power supply to the load is cut off (step S108 in FIG. 4). Then, the control unit 101 controls the communication unit 102 to transmit that the interruption unit 120 has interrupted energization (step S109 in FIG. 4). In addition, the control unit 101 controls the communication unit 102 to transmit the energization current at the time of interruption (step S109 in FIG. 4).

  On the other hand, when a change in state that the energization current value does not exceed the set current value is detected by the current detection unit 130 (YES in step S106 in FIG. 4 (below the set value)), the blocking unit 120 does nothing, The control unit 101 controls the communication unit 102 to transmit the energized current when the state change occurs (step S109 in FIG. 4).

  When the current detection unit 130 detects a state in which no change occurs in the energization current value (NO in step S106 in FIG. 4), the control unit 101 waits for a certain period of time (step S107 in FIG. 4). In step S109 in FIG. 4, the communication unit 102 is controlled to transmit the energized current when a certain time has elapsed. Here, the fixed time is a predetermined time, and is an arbitrary time such as 30 seconds or 1 minute.

  Hereinafter, the electronic breaker 100 repeatedly executes state change monitoring (step S105 in FIG. 4) to state transmission (step S109 in FIG. 4) according to instructions from the control unit 101. The state where the state change described above does not occur includes a case where the contact point 121-123 is opened by the blocking unit 120 and the state where the energization current value = 0 continues. Therefore, even if the blocking unit 120 is in the blocking state, the communication unit 102 continues to transmit that it is in the blocking state at regular intervals.

In addition, when the electronic breaker 100 is installed (steps S102 and S103 in FIG. 4) and energization is started (step S104 in FIG. 4), the state of the energization current changes from zero to a predetermined current value. This state is also transmitted as a state change by the communication unit 102.
[Operation on the terminal device 200 side]

  The terminal device 200 is used as shown in FIGS. 2 and 3 in a space such as a factory, an apartment house, or a commercial building where the electronic breaker 100 is disposed.

  First, in the terminal device 200, an application of a breaker state display program is started by the user (step S201 in FIG. 3). Note that this application may be activated by a user operation, or the application of the breaker state display program may be automatically activated when the terminal device 200 is turned on.

  When the application of the breaker state display program is started, the control unit 201 reads out if there is a breaker already registered in the storage unit 205 (step S202 in FIG. 4). Further, the communication unit 202 receives the scan from a predetermined communication frequency so as to receive the transmission from the electronic breaker 100 (step S203 in FIG. 4).

  Here, the control unit 201 compares the registered electronic breaker stored in the storage unit 205 with the received electronic breaker included in the reception result of the communication unit 202 using an identification signal or the like (step S204 in FIG. 4). The presence of a new unregistered electronic breaker 100 is confirmed (step S205 in FIG. 4).

  When the presence of the unregistered electronic breaker 100 is confirmed (YES in step S205 in FIG. 4), the control unit 101 receives communication from the unregistered electronic breaker 100, and from the change in the electric field strength, the electronic breaker 100 100 positions and directions are calculated. Here, the control unit 101 can calculate the distance from the terminal device 200 to the electronic breaker 100 based on the strength of the electric field strength.

  When the communication unit 202 includes a known direction detection antenna or variable directional antenna whose directionality can be switched, the electric field of communication from the electronic breaker 100 obtained using the direction detection antenna or variable directional antenna. In addition to the distance of the electronic breaker 100, the direction can be calculated by signal processing the intensity.

  At this time, if the communication unit 202 includes a general antenna with no directivity, the electric field strength of communication from the electronic breaker 100 obtained by changing the position of the terminal device 200 in the space is changed. By performing signal processing, in addition to the distance from the terminal device 200 to the electronic breaker 100, the direction of the electronic breaker 100 can be calculated based on the principle of triangulation. Here, the direction of the electronic breaker 100 can be calculated by performing signal processing on the electric field strength of communication from the three electronic breakers 100 obtained by changing the position of the terminal device 200 at two places. Moreover, the direction of the specific one new electronic breaker 100 can be calculated by performing signal processing on the electric field strength of communication from the electronic breaker 100 obtained by changing the position of the terminal device 200 at least three places.

  When the control unit 101 specifies the position (distance and direction from the terminal device 200) of the new breaker 100 as described above (step S206 in FIG. 4), the identification signal and position of the new electronic breaker 100 are identified. Are registered in the storage unit 205 as the registered electronic breaker 100, and additionally displayed on the display screen of the operation display unit 203 (step S208 in FIG. 4).

  Then, the control unit 101 refers to the communication from each of the registered electronic breakers 100 including the newly registered electronic breaker 100, changes in the energized current value, changes in the cutoff / connection state, and a certain period of time. The state (current value, cutoff / connection) when there is no change is displayed on the display screen of the operation display unit 203 (step S210 in FIG. 4). Note that the control unit 101 refers to the communication from each of the registered electronic breakers 100, and the state (current value, disconnection / connection) when there is no change over a certain period of time is similar to the state change in the operation display unit 203. Display on the display screen. If no state change occurs in the electronic breaker 100 and a certain time has not elapsed, it is necessary to update the display screen of the operation display unit 203 for the state (current value, cutoff / connection) of the electronic breaker 100. Absent.

  Then, the control unit 101 repeats the above-described processing from step S203 to step S210 in the terminal device 200 until the application of the breaker state display program is shut down or until the power of the terminal device 200 is turned off. (Step S211 in FIG. 4).

  When a shutdown operation of the application of the breaker status display program or a power-off operation of the terminal device 200 occurs on the operation display unit 203 (YES in step S211 in FIG. 4), the control unit 101 causes the newly registered electronic breaker to The position (distance and direction) and state of each registered electronic breaker 100 including 100 are stored in the storage unit 205, and then the application is terminated (step S212 in FIG. 4).

  In the series of processes described above, when the registered electronic breaker 100 cannot receive any communication from the electronic breaker 100 for a predetermined time or longer, the control unit 101 displays “ It is also preferable to display “communication not detected error”.

  Although not described in the above flowchart, when the terminal device 200 is used in another space, the storage of the registered electronic breaker 100 in the storage unit 205 can be reset. Then, by newly registering the electronic breaker 100 in the new space (steps S205 to S207 in FIG. 4), it is possible to display the electronic breaker 100 in the new space (step S209 in FIG. 4).

  Although not described in the above flowchart, it is assumed that both the communication unit 102 of the electronic breaker 100 and the communication unit 201 of the terminal device 200 can perform bidirectional (transmission and reception) operations. Here, the terminal device 200 transmits the cutoff control signal and the identification signal of the target electronic breaker 100 to the electronic breaker via the communication unit 202. The electronic breaker 100 receives the cutoff control signal and the identification signal from the terminal device 200 via the communication unit 102, and when the identification signal matches, the cutoff unit 120 supplies power to the load based on the cutoff control signal. Can be shut off. Thereby, after grasping the installation position and state of the electronic breaker 100 on the terminal device 200 side, the terminal device 200 can further control the cutoff of the electronic breaker 100.

  Although not described in the above flowchart, if both the communication unit 102 of the electronic breaker 100 and the communication unit 201 of the terminal device 200 are capable of bidirectional (transmission and reception) operation, the setting is made from the terminal device 200. By transmitting the current value, the electronic breaker 100 can receive the set current value from the terminal device 200 and update the set current value. In this case, not only can the installation position and state of the electronic breaker 100 be easily grasped by controlling the interruption of energization to the load by the interruption unit 120 based on the updated set current value. The set current value for interruption can be changed by remote operation, and flexible and appropriate response according to the use situation becomes possible.

Although not shown in FIGS. 1 and 4, in the electronic breaker 100, in addition to the current detection unit 130, it is possible to provide a detection unit other than the current such as a vibration sensor and a smoke sensor. In this case, the electronic breaker 100 transmits the state at the other detection unit, and the terminal device 200 receives the state from the other detection unit and displays it on the operation display unit 203. By doing in this way, various state detection becomes possible.
[Example of display in terminal device 200]

  FIG. 5 shows an example of a display screen 203G in the operation display unit 203 by the application of the breaker state display program in the terminal device 200. In FIG. 5, the terminal device 200 determines the direction and distance of each electronic breaker 100 in correspondence with the state in which 16 electronic breakers 100 (# 01 to # 16) are arranged in the space A1 as shown in FIG. 3. Calculates and lists ID (assigned identification signal), operation status (disconnection / connection), communication field strength, direction, distance, current energization current value, current value at disconnection according to communication contents The state displayed on the display screen is shown.

  FIG. 6 shows an example of another display screen 203G in the operation display unit 203 by the application of the breaker state display program in the terminal device 200. In FIG. 6, corresponding to the state in which 16 electronic breakers 100 (# 01 to # 16) are arranged in the space A1 as shown in FIG. 3, the terminal device 200 determines the direction and distance of each electronic breaker 100. According to the content of communication, the ID (assigned identification signal), the operation status (separation of disconnection / connection), distance, current energizing current value, current value at the time of interruption are determined according to the position of the electronic breaker 100. Shown on the graphic screen.

Note that when both the display screen of FIG. 5 and the display screen of FIG. 6 can be displayed, the control unit 101 controls to display either one according to the selection from the user.
[Effect obtained by this embodiment]

  As described above, in the power distribution monitoring system 10 including the electronic breaker 100 and the terminal device 200 configured as illustrated in FIG. 1, the operation display unit 203 of the terminal device 200 is performed by executing the processing illustrated in FIG. 4. The position and state of each electronic breaker 100 are displayed as shown in FIGS. This makes it possible to instantly grasp the position and state of the electronic breaker 100 visually even for users who are unfamiliar with machines in factories, apartment houses, commercial buildings, and the like having many breakers. As a result, quick restoration at the time of interruption and investigation of the cause leading to the interruption become easy, and it becomes possible to minimize the economic loss of the power failure due to the breaker interruption.

  In addition, the use of the power distribution monitoring system 10 by a construction worker, not a general user, can provide an advantage that work can be efficiently performed. For example, even when there is no drawing in which the electronic breaker 100 is installed or when the person in charge retreats, the work can be performed very efficiently. As a result, quick restoration at the time of interruption and investigation of the cause leading to the interruption become easy, and it becomes possible to minimize the economic loss of the power failure due to the breaker interruption.

  Further, in this power distribution monitoring system, when the current detection unit 130 detects that the energization current exceeds the set current value, the interrupting unit 120 interrupts energization to the load, and the communication unit 102 interrupts energization. The terminal device 200 displays the state of the electronic breaker 100 on the operation display unit 203 based on the content received from the electronic breaker 100, so that the load and wiring are protected from overcurrent, and the terminal device 200 side Thus, it is possible to easily grasp the installation position and state of the electronic breaker in which the overcurrent has occurred.

  In this power distribution monitoring system, the electronic breaker 100 transmits an identification signal, and the terminal device 200 identifies the electronic breaker 100 based on the identification signal, and displays the state of the electronic breaker 100 on the operation display unit 203. As a result, the terminal device 200 can easily grasp the installation position and state of the electronic breaker 100 in which the state change has occurred.

  In this distribution monitoring system, the electronic breaker 100 transmits at a predetermined communication frequency, and the terminal device 200 displays the state of the electronic breaker 100 on the operation display unit 203 based on the content received at the communication frequency. Accordingly, the terminal device 200 can reliably and easily grasp the installation position and state of the electronic breaker 100 in which the state change has occurred without being affected by interference.

  Further, in this power distribution monitoring system, the electronic breaker 100 causes the communication unit 102 to transmit the detection result when the predetermined time elapses when the detection result of the current detection unit 130 does not change even when the predetermined time elapses. Then, the terminal device 200 displays the state of the electronic breaker 100 on the operation display unit 203 based on the received content, so that the installation position and state of the electronic breaker can be kept alive even in a situation where no state change occurs. It is possible to reliably and easily grasp the terminal device side 200 including confirmation and abnormal neglect.

  Further, in this power distribution monitoring system, a plurality of electronic breakers each having a different identification signal are installed as the electronic breaker 100, and the terminal device identifies each of the plurality of electronic breakers based on the identification signal. By displaying each state of the breaker on the operation display unit 203, even when there are a plurality of electronic breakers, the installation position and state of the electronic breaker (state change, overcurrent occurrence, survival check, abnormal neglect, etc.) ) Can be easily grasped.

  In this power distribution monitoring system, the terminal device 200 transmits a cutoff control signal to the electronic breaker 100, and the electronic breaker 100 receives the cutoff control signal from the terminal device 200, and based on the cutoff control signal. The interruption | blocking part 120 interrupts | blocks the electricity supply to load. Thereby, after grasping the installation position and state of the electronic breaker 100 on the terminal device 200 side, the terminal device 200 can further control the cutoff of the electronic breaker 100.

  In this distribution monitoring system, the set current value is transmitted from the terminal device 200, the electronic breaker 100 receives the set current value from the terminal device 200, updates the set current value, and the updated set current value. By controlling the interruption of the energization to the load by the interruption unit 120 based on the above, not only can the installation position and state of the electronic breaker 100 be easily grasped, but also the set current value for interruption can be remotely It can be changed by operation, and a flexible and appropriate response according to the use situation becomes possible.

  Further, in the power distribution monitoring system, by using a plurality of terminal devices 200, a plurality of users can easily grasp the installation position and state of the electronic breaker 100 in parallel in the same space. That is, quick recovery at the time of interruption and investigation of the cause of the interruption are facilitated, and it is possible to minimize the economic loss of power outage due to the interruption of the player.

  Further, in this power distribution monitoring system, by providing the electronic breaker 100 with other detection units such as a vibration sensor and a smoke sensor in addition to the current detection unit 130, it is possible to detect various states.

1 Wiring 1a Wiring (upstream side)
1b Wiring (downstream side)
DESCRIPTION OF SYMBOLS 10 Power distribution monitoring system 100 Electronic breaker 101 Control part 102 Communication part 105 Storage part 110 Power supply part 120 Blocking part 130 Current detection part 200 Terminal device 201 Control part 202 Communication part 203 Operation display part 205 Storage part

Claims (13)

A current detector for detecting a current flowing to the load;
A shut-off section that shuts off the power to the load;
A communication unit for transmitting a detection result of the current detection unit;
A control unit that controls each unit according to the detection result of the current detection unit;
With
The control unit controls the communication unit to transmit the detection result when a change occurs in the detection result of the current detection unit;
An electronic breaker characterized by that. When the current detection unit detects that the energization current exceeds the set current value, the interrupting unit interrupts energization to the load,
The control unit controls the communication unit to transmit that the cut-off unit cuts off energization.
The electronic breaker according to claim 1. A storage unit for storing the identification signal;
The control unit controls the communication unit to transmit the identification signal.
The electronic breaker according to any one of claims 1 to 2, wherein the electronic breaker is provided. It is configured with a storage unit that stores the communication frequency,
The control unit controls the communication unit to transmit at the communication frequency;
The electronic breaker according to any one of claims 1 to 3, wherein: The control unit controls the communication unit to transmit the detection result when the predetermined time elapses when no change occurs even if the detection result of the current detection unit elapses a predetermined time or longer.
The electronic breaker according to any one of claims 1 to 4, wherein the electronic breaker is provided. A current detection unit that detects an energization current to the load, a blocking unit that interrupts energization to the load, a communication unit that transmits a detection result of the current detection unit, and a change in the detection result of the current detection unit An electronic breaker comprising a control unit that controls the communication unit to transmit a detection result;
A communication unit that receives the detection result transmitted from the electronic breaker, a display unit that displays various information, and a control unit that displays the distance, direction, and state of the electronic breaker on the display unit based on the received detection result A terminal device comprising:
A power distribution monitoring system comprising: The electronic breaker, when the current detection unit detects that the energization current exceeds the set current value, the interruption unit cuts off the energization to the load, and the communication unit transmits the interruption of energization,
The terminal device displays the state of the electronic breaker on the display unit based on the content received from the electronic breaker.
The power distribution monitoring system according to claim 6. The electronic breaker transmits with an identification signal,
The terminal device identifies the electronic breaker based on the identification signal, and displays the state of the electronic breaker on the display unit.
The power distribution monitoring system according to any one of claims 6 to 7, wherein The electronic breaker transmits at a predetermined communication frequency,
The terminal device displays the state of the electronic breaker on the display unit based on the content received at the communication frequency.
The power distribution monitoring system according to any one of claims 6 to 8, wherein The electronic breaker controls the communication unit to transmit the detection result when the predetermined time elapses when no change occurs even if the detection result of the current detection unit elapses a predetermined time or more,
The terminal device displays the state of the electronic breaker on the display unit based on the received content.
The power distribution monitoring system according to any one of claims 6 to 9, wherein As the electronic breaker, a plurality of electronic breakers with different identification signals are installed,
The terminal device identifies each of a plurality of electronic breakers based on the identification signal, and displays each state of the plurality of electronic breakers on the display unit.
The power distribution monitoring system according to any one of claims 6 to 10, wherein The terminal device transmits a blocking control signal to the electronic breaker via the communication unit,
The electronic breaker receives the cutoff control signal from the terminal device via the communication unit, and the cutoff unit cuts off power to the load based on the cutoff control signal.
The power distribution monitoring system according to any one of claims 6 to 11, wherein The terminal device transmits a set current value,
The electronic breaker receives the set current value from the terminal device, updates the set current value, and controls interruption of energization to the load by the interrupting unit based on the updated set current value.
The power distribution monitoring system according to any one of claims 6 to 12, wherein

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