JP6127349B2 - Distribution board - Google Patents

Description

  The present invention generally relates to a distribution board, and more particularly to a distribution board provided with a communication adapter for performing power line communication with an external device.

  2. Description of the Related Art Conventionally, a system that performs communication between devices by power line communication (PLC) is known, and is disclosed in, for example, Patent Document 1. The system described in Patent Document 1 uses a terminal (communication module) that receives a power line communication signal (hereinafter referred to as “PLC signal”) from a watt-hour meter (power meter) having a communication function through power line communication.

  The communication module transmits the PLC signal received from the power meter by power line communication to an information panel that performs centralized control of the electrical devices in the house. A control line is connected between the communication module and the information board, and a PLC signal is transmitted from the communication module to the information board via the control line.

JP 2010-004389 A

  However, in the distribution board of the conventional example, a communication module is provided on the primary side (system power supply side) of the main breaker. For this reason, when attaching a communication module to a distribution board, the main breaker must be disconnected from the system power supply. Therefore, there has been a problem that power supply to the secondary side (load side) of the main breaker is stopped during the work of attaching the communication module to the distribution board.

  The present invention has been made in view of the above points, and an object thereof is to provide a distribution board to which a communication module can be attached without disconnecting a main breaker from a system power supply.

  The distribution board of the present invention includes a main breaker, a plurality of branch breakers electrically connected to the secondary side of the main breaker, and an external device electrically connected to the primary side of the main breaker. A communication module that performs power line communication using a power line as a transmission path between the plurality of branch breakers, and the communication module performs power line communication with the external device via any one of the branch breakers. It is characterized by performing.

  In this distribution board, it is preferable that the communication module performs power line communication with the external device via a branch breaker located closest to the main breaker among the plurality of branch breakers.

  In the present invention, a communication module is provided so as to perform power line communication with an external device via a branch breaker. For this reason, in this invention, a communication module can be attached to a distribution board by disconnecting a branch breaker from a system power supply. Therefore, in the present invention, the communication module can be attached without disconnecting the main breaker from the system power supply.

1A is a schematic diagram illustrating a distribution board according to an embodiment of the present invention, and FIG. 1B is a diagram illustrating wiring between the first branch breaker and the first communication adapter in the configuration illustrated in FIG. 1A. . It is the schematic which shows the other structure in the distribution board which concerns on embodiment of this invention. FIG. 3A is a schematic diagram illustrating a configuration in which power line communication is performed via a measurement unit in the distribution board according to the embodiment of the present invention, and FIG. 3B is a diagram illustrating the first branch breaker and the first in the configuration illustrated in FIG. It is a figure which shows the wiring between communication adapters. FIG. 4A is a schematic diagram showing a configuration in which a self-supporting distribution board is connected in the distribution board according to the embodiment of the present invention, and FIG. 4B is provided in the self-supporting distribution board in the configuration shown in FIG. 4A. It is a figure which shows a measurement unit. FIG. 5A is a schematic diagram showing a configuration in which the power line communication path can be switched in the distribution board according to the embodiment of the present invention, and FIG. 5B shows the configuration of the first communication adapter in the configuration shown in FIG. 5A. FIG.

  As shown in FIGS. 1A and 1B, the distribution board 1 according to the embodiment of the present invention includes a main breaker 3, a plurality of branch breakers 4, and a first communication adapter 6 (communication module). The plurality of branch breakers 4 are electrically connected to the secondary side of the main breaker 3. The first communication adapter 6 performs power line communication using a power line as a transmission line with a power meter 8 (external device) electrically connected to the primary side of the main breaker 3. The first communication adapter 6 performs power line communication with the power meter 8 via any one of the plurality of branch breakers 4.

  Hereinafter, the distribution board 1 which concerns on embodiment of this invention is demonstrated using drawing. In the distribution board 1 of the present embodiment, power is supplied from the system power supply by a single-phase three-wire low-voltage distribution system. However, for example, a single-phase two-wire low-voltage distribution system may be used. As shown in FIGS. 1A and 1B, the distribution board 1 of the present embodiment includes a cabinet 2, a main breaker 3, a plurality of branch breakers 4, a measurement unit 5, and a first communication adapter 6 (communication module). And a second communication adapter 7. A power meter 8 (external device) is connected between the main breaker 3 and the system power supply (not shown).

  The cabinet 2 is formed of a synthetic resin molded product or the like, and includes a main body 20 and a lid (not shown). The main body 20 is formed in a box shape with one surface open. The lid is formed in a shape that covers the opening of the main body 20. The lid is attached to the main body 20 so as to be rotatable between a position for closing the opening of the main body 20 and a position for opening the opening of the main body 20.

  One end of three main wirings CB1 is connected to the primary side (system power supply side) of the main circuit breaker 3. The other end of the main wiring CB <b> 1 is connected to a system power supply provided by an electric power company via a power meter 8. The secondary side (load side) of the main breaker 3 is connected to a conductive bar (not shown).

  The primary side of each branch breaker 4 is electrically connected to the secondary side of the main breaker 3 by plug-in connection to the conductive bar. Further, one end of the branch wiring CB2 is electrically connected to the secondary side of each branch breaker 4. For example, an electric device (not shown) such as a television, an audio device, a refrigerator, a dishwasher, an air conditioner, and a lighting device is electrically connected to the other end of the branch wiring CB2. On the secondary side of each branch breaker 4, as shown in FIG. 1B, three terminals corresponding to the three power lines constituting the branch wiring CB2 are provided. In the figure, the terminal corresponding to the power line of the neutral phase is “N”, the terminal corresponding to the power line of the first voltage phase is “L1”, and the terminal corresponding to the power line of the second voltage phase is “L2”. It is described.

  The measurement unit 5 measures the current flowing through each branch line CB2 by a current sensor (not shown) provided for each branch line CB2, and calculates the power used to be supplied to the electrical equipment for each branch line CB2. In other words, the measuring unit 5 measures the power used for each branch circuit branched by the plurality of branch breakers 4. For example, a Rogowski sensor or a current transformer is used as the current sensor. In addition, when the photovoltaic power generation unit is connected to the distribution board 1, the measurement unit 5 may be configured to measure the power generated by the photovoltaic power generation or the sold power. The measurement result of the power consumption is transmitted by a wired signal according to a standard such as RS-485, for example, by connecting the measurement unit 5 and the second communication adapter 7 with a cable (not shown).

  Here, the measuring unit 5 is electrically connected to any one of the plurality of branch breakers 4 (hereinafter referred to as “first branch breaker 40”) via the branch wiring CB2. As shown in FIG. 1B, the measurement unit 5 receives an AC voltage (100 V) applied between the neutral phase (N phase) and the second voltage phase (L2 phase) as a first branch breaker. 40 is input. As shown in FIG. 1B, the measurement unit 5 operates by converting an input AC voltage into a desired DC voltage (for example, 4.5 V) by a built-in power supply circuit 50 configured by, for example, an AC / DC converter. Getting power. Further, the measurement unit 5 and the second communication adapter 7 are connected by a power line. Accordingly, the second communication adapter 7 obtains an operating power supply by being supplied with a DC voltage from the measurement unit 5 via the power supply line.

  Further, a board-to-board (BtoB) connector (not shown) is provided between the board (not shown) of the first communication adapter 6 and the board (not shown) of the second communication adapter 7. Connected through. Accordingly, the first communication adapter 6 obtains an operating power supply by being supplied with a DC voltage from the second communication adapter 7 via the board-to-board connector. In addition, communication data is transmitted and received between the first communication adapter 6 and the second communication adapter 7 via the board-to-board connector.

  The first communication adapter 6 is connected to the main line CB1 of the main breaker 3 via any one of the plurality of branch breakers 4 and the branch line CB2 connected to the branch breaker 4. . The first communication adapter 6 includes a first communication circuit 60 that performs bidirectional power line communication with the power meter 8 using a power line as a transmission path. The first communication circuit 60 has a function of separating and receiving a PLC signal superimposed on an alternating current flowing through the power line and transmitting communication data included in the PLC signal to the second communication adapter 7. In addition, the first communication circuit 60 has a function of superimposing a PLC signal including communication data transmitted from the second communication adapter 7 on an alternating current flowing through the power line and transmitting it to the power meter 8. In the distribution board 1 of the present embodiment, the PLC signal is superimposed on the alternating current flowing through the first voltage phase (L1 phase) power line and the second voltage phase (L2 phase) power line to perform power line communication. ing. The “PLC signal” is a signal transmitted / received by power line communication, and is a signal having a frequency higher than the power supply frequency of the system power supply.

  The second communication adapter 7 includes a second communication circuit 70 that performs bidirectional wireless communication using a radio wave as a medium with a device management apparatus (not shown). The second communication circuit 70 transmits a radio signal including data of measurement results in the measurement unit 5 and communication data transmitted from the electric utility via the power meter 8 and the first communication adapter 6 to the device management apparatus. It has a function to do. The second communication circuit 70 has a function of receiving a radio signal transmitted from the device management apparatus and transmitting communication data included in the radio signal to the first communication adapter 6. The specification of the radio signal is selected from conventionally known standards such as a specific low power radio (for example, 400 MHz band and 920 MHz band) and a wireless LAN (Local Area Network).

  The device management apparatus is a controller that manages a plurality of electrical devices in a building. This device management apparatus controls the operation of each electrical device and manages the power usage of each electrical device. That is, a HEMS (Home Energy Management System) network as a customer-side network is constructed by a device management apparatus and a plurality of electrical devices having a communication function. Note that it is not necessary for all the electric devices connected to each branch wiring CB2 to have a communication function, and some of the electric devices may have a communication function.

  Note that the second communication adapter 7 may be configured to perform wireless communication not only with the device management apparatus but also with a mobile terminal such as a smart phone. In this configuration, the user can acquire information such as hourly rate information, power supply information, and demand response notifications transmitted from the electric utility through the mobile terminal.

  The power meter 8 is an electronic power meter having a measurement function for measuring power consumption and a communication function for communicating with other devices, and is a so-called smart meter. The electric power meter 8 is installed in a consumer in order for an electric power company to collect a power charge. The electric power meter 8 measures the total amount of electric power supplied from the electric power company to the consumer, and transmits meter reading information including the total used amount to the electric power company. Moreover, the power meter 8 receives hourly charge information and power provision information transmitted from the electric power company, and transmits these information to the first communication adapter 6 by power line communication. Further, the power meter 8 receives communication data transmitted from the device management apparatus via the first communication adapter 6 and the second communication adapter 7 and transmits the communication data to the electric utility.

  Here, the first communication circuit 60 of the first communication adapter 6 includes a first voltage phase (L1 phase) power line and a second voltage phase (L2 phase) in the branch wiring CB2, as shown in FIG. 1B. Are electrically connected to the first branch breaker 40 via the power line. For this reason, the first communication adapter 6 performs power line communication with the power meter 8 using the transmission path via the first branch breaker 40 and the main breaker 3. In other words, the first communication adapter 6 (communication module) performs power line communication with the power meter 8 (external device) via any one of the plurality of branch breakers 4.

  As described above, in the distribution board 1 of the present embodiment, the first communication adapter 6 (communication module) is provided so as to perform power line communication with the power meter 8 (external device) via the branch breaker 4. Yes. Therefore, in the distribution board 1 of the present embodiment, the first communication adapter 6 can be attached to the distribution board 1 by disconnecting the branch breaker 4 from the system power supply. Therefore, in the distribution board 1 of the present embodiment, the first communication adapter 6 can be attached without disconnecting the main breaker 3 from the system power supply.

  In the distribution board 1 of the present embodiment, the first communication adapter 6 performs power line communication with the power meter 8 via the first branch breaker 40 to which the measurement unit 5 is connected. The power line communication may be performed via the branch breaker 4. For example, the first communication adapter 6 may be electrically connected to the branch breaker 4 closest to the main breaker 3, as shown in FIG. In other words, the first communication adapter 6 (communication module) communicates with the power meter 8 (external device) via the branch breaker 4 located closest to the main breaker 3 among the plurality of branch breakers 4. The structure which performs may be sufficient. In this configuration, since the transmission path between the power meter 8 and the first communication adapter 6 is shortened, it is difficult to be affected by noise, and power line communication can be stabilized.

  Further, as shown in FIG. 2, the first communication adapter 6 performs power line communication with the power meter 8 via the branch breaker 4 located closest to the first communication adapter 6 among the plurality of branch breakers 4. The structure to perform may be sufficient. Also in this configuration, since the transmission path between the power meter 8 and the first communication adapter 6 is shortened, it is difficult to be affected by noise, and power line communication can be stabilized.

  By the way, the 1st communication adapter 6 may be the structure which performs power line communication between the electric power meter 8 via the 1st branch breaker 40 and the measurement unit 5, as shown to FIG. 3A and FIG. 3B. In this configuration, the measurement unit 5 includes a conversion circuit 51 in addition to the power supply circuit 50. The conversion circuit 51 has a function of separating the PLC signal superimposed on the alternating current flowing through the power line and transmitting it to the second communication adapter 7. The conversion circuit 51 has a function of superimposing a PLC signal including communication data transmitted from the second communication adapter 7 on an alternating current flowing through the power line.

  The PLC signal output from the conversion circuit 51 is transmitted to the first communication circuit 60 of the first communication adapter 6 via a conductor (not shown) printed on the substrate of the second communication adapter 7. The first communication circuit 60 receives the PLC signal transmitted from the conversion circuit 51 and transmits communication data included in the PLC signal to the second communication adapter 7. Further, the PLC signal transmitted from the first communication circuit 60 is also transmitted to the conversion circuit 51 via the conductor printed on the substrate of the second communication adapter 7 in the same manner as described above.

  As described above, in this configuration, the first communication adapter 6 (communication module) is provided so as to perform power line communication with the power meter 8 (external device) via the first branch breaker 40 and the measurement unit 5. Yes. For this reason, in this configuration, the first communication adapter 6 can be attached to the distribution board 1 by disconnecting the first branch breaker 40 from the system power supply. Therefore, in this configuration, the first communication adapter 6 can be attached without disconnecting the main breaker 3 from the system power supply. Further, in this configuration, the PLC signal is transmitted to the first communication adapter 6 via the conductor of the substrate of the second communication adapter 7. Therefore, in this configuration, it is not necessary to newly connect the first branch breaker 40 and the first communication adapter 6 with the branch wiring CB2.

  By the way, as shown to FIG. 4A, the self-supporting distribution board 10 may be connected to the distribution board 1 of this embodiment. The self-supporting distribution board 10 includes a main breaker 100, a plurality of branch breakers 101, and a measurement unit 5. In addition, the self-supporting distribution board 10 includes a power switch (not shown) that switches between a path that receives power supply from the system power supply and a path that receives power supply from the distributed power supply. The distributed power source includes, for example, a solar power generation device, a power storage device, an electric vehicle equipped with a storage battery, and the like, and supplies power to the independent distribution board 10 independently of the system power source.

  The primary side of the main breaker 100 is electrically connected to the secondary side of any branch breaker 4 of the distribution board 1. In addition, any one of the plurality of branch breakers 101 is electrically connected to the second communication adapter 7 via the measurement unit 5 and the measurement unit 500 of the distribution board 1. As shown in FIG. 4B, the measurement unit 5 has the same configuration as the measurement unit 5 shown in FIG. 3B. Further, the measurement unit 500 does not have the power supply circuit 50 and the conversion circuit 51, and has a function of sending a DC voltage supplied from the measurement unit 5 to the second communication adapter 7 and a PLC signal transmitted from the measurement unit 5. To the second communication adapter 7.

  In this way, the self-supporting distribution board 10 connected to the distribution board 1 is normally supplied with power from the system power supply via the branch breaker 4 and the main breaker 100. On the other hand, when the supply of power from the system power supply is stopped, the power distribution switch 10 switches the route manually or automatically, so that the self-supporting distribution board 10 receives the supply of power from the distributed power supply.

  Here, in the configuration shown in FIGS. 4A and 4B, the first communication adapter 6 performs power line communication with the power meter 8 via the measurement unit 5 of the self-supporting distribution board 10. For this reason, the transmission line for power line communication (that is, the transmission line for transmitting the PLC signal) becomes long, and power line communication may become unstable. Therefore, in view of stabilization of power line communication, the first communication adapter 6 performs power line communication with the power meter 8 via the branch breaker 4 of the distribution board 1 without using the measurement unit 5. A configuration to perform is desirable.

  In addition, the distribution board 1 of this embodiment is the structure which the 1st communication adapter 6 is provided with the switch part 9, and switches the path | route which performs power line communication between the power meters 8, as shown to FIG. 5A and FIG. 5B. There may be. As illustrated in FIG. 5B, the switching unit 9 includes a pair of switches 90 and a detection unit 91. Each switch 90 is configured by a c contact. A common terminal of each switch 90 is electrically connected to the first communication circuit 60. The normally closed terminal of each switch 90 is electrically connected to the measurement unit 5 via the conductor of the substrate of the second communication adapter 7. The normally open terminal of each switch 90 is electrically connected to the secondary side of the second branch breaker 41. Here, the second branch breaker 41 is a branch breaker 4 different from the first branch breaker 40 among the plurality of branch breakers 4.

  The detection unit 91 is configured to detect whether or not the second branch breaker 41 is electrically connected to the first communication adapter 6. The detection unit 91 is connected to a pair of input terminals (not shown) to which the second branch breaker 41 is connected in the first communication adapter 6. The detection unit 91 compares the input voltage between the input terminals with a predetermined voltage value (here, 200 V). The detection unit 91 detects that the second branch breaker 41 is connected to the first communication adapter 6 if the input voltage is equal to or higher than a predetermined voltage value. Moreover, the detection part 91 will detect that the 2nd branch breaker 41 is not connected to the 1st communication adapter 6, if an input voltage is smaller than a predetermined voltage value.

  The switching unit 9 is configured to automatically switch between the first route and the second route according to the detection result of the detection unit 91. The first route is a route for performing power line communication between the first communication adapter 6 and the power meter 8 via the first branch breaker 40 and the measurement unit 5. The second route is a route for performing power line communication between the first communication adapter 6 and the power meter 8 via the second branch breaker 41.

  When the switching unit 9 detects that the second branch breaker 41 is not connected by the detection unit 91, the switching unit 9 maintains a state in which the common terminal and the normally closed terminal of each switch 90 are conducted. Therefore, in this case, power line communication is performed between the first communication adapter 6 and the power meter 8 through the first path. On the other hand, when the detection unit 91 detects that the second branch breaker 41 is connected, the switching unit 9 makes the common terminal and the normally open terminal of each switch 90 conductive. Therefore, in this case, power line communication is performed between the first communication adapter 6 and the power meter 8 through the second path.

  The first communication circuit 60 is configured to switch processing according to the detection result of the detection unit 91. That is, when the detection unit 91 detects that the second branch breaker 41 is not connected, the PLC signal is supplied to the first communication circuit 60 via the first path. For this reason, the first communication circuit 60 executes a process of receiving a PLC signal transmitted from the measurement unit 5. On the other hand, when the detection unit 91 detects that the second branch breaker 41 is connected, an alternating current is supplied to the first communication circuit 60 via the second path. For this reason, the 1st communication circuit 60 performs the process which isolate | separates and receives a PLC signal from the supplied alternating current.

  As described above, in this configuration, for example, when the signal strength of the PLC signal transmitted from the measurement unit 5 is weak and the communication quality of the power line communication in the first path is poor, the second branch breaker 41 is connected to the first communication adapter. 6 can be automatically switched to the second route.

  Further, the switching unit 9 may be configured to include an operation unit (not shown) that manually switches the contact of each switch 90 without including the detection unit 91. In this structure, if the 2nd branch breaker 41 is connected to the 1st communication adapter 6, a contractor will operate the operation part, for example, will switch the contact of each switch 90, and a 1st path | route and a 2nd path | route Can be switched at a desired timing.

1 Distribution board 3 Master breaker 4 Branch breaker 5 Measurement unit 6 1st communication adapter (communication module)
8 Electricity meter (external equipment)

Claims (2)

With the main breaker,
A plurality of branch breakers electrically connected to the secondary side of the main breaker;
A communication module that performs power line communication using a power line as a transmission path with an external device electrically connected to the primary side of the main breaker;
The distribution module, wherein the communication module performs power line communication with the external device via any one of the plurality of branch breakers. 2. The distribution board according to claim 1, wherein the communication module performs power line communication with the external device via a branch breaker located closest to the main breaker among the plurality of branch breakers. .

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