JP7390554B2 - Distribution board and filter device - Google Patents

Description

The present disclosure generally relates to a power distribution board and a filter device, and more specifically relates to a power distribution board capable of power line carrier communication and a filter device used therein.

BACKGROUND ART Communication (power line carrier communication) in which a high frequency signal is superimposed on a power line and transmitted is conventionally known (for example, see Patent Document 1).

Patent Document 1 describes a communication system that can suppress interference between transmission paths when performing power line carrier communication of a plurality of transmission paths. The communication system of Patent Document 1 includes a base unit and a slave unit, and performs power line carrier communication on a transmission path between the base unit and the slave unit. The parent device and the slave device each have a capacitor as a high-frequency filter that passes the signal frequency.

Since the parent device and the slave device have filters, it is possible to suppress deterioration in the quality of power line carrier communication.

Japanese Patent Application Publication No. 2015-95878

In Patent Document 1, a base unit and a slave unit that perform power line carrier communication need to have a filter. In other words, it is necessary to provide a filter in all devices that perform power line carrier communication. Therefore, the system configuration may become complicated.

The present disclosure has been made in view of the above-mentioned problems, and an object of the present disclosure is to provide a distribution board and a filter device that can prevent a system configuration for performing power line communication from becoming complicated while suppressing deterioration in the quality of power line communication. With the goal.

A power distribution board according to one aspect of the present disclosure is a power distribution board that can be used for power line carrier communication, which is communication using a power line that supplies electric power. The distribution board includes a master breaker and a filter for power line carrier communication. The filter is provided on at least one of the primary side of the main breaker and between the primary side and the secondary side of the main breaker , and attenuates noise in at least one direction in the power line carrier communication. . The filter includes at least one filter circuit electrically connected to the power line. The power line includes multiple poles. The filter is provided at at least one pole among the plurality of poles. The at least one filter circuit included in the filter and the at least one pole on which the filter is provided are in one-to-one correspondence.

A filter device according to one aspect of the present disclosure is used as the filter in the distribution board.

According to the present disclosure, it is possible to prevent a system configuration that performs power line communication from becoming complicated while suppressing deterioration in the quality of power line communication.

FIG. 1 is a diagram illustrating the configuration of a distribution board according to an embodiment. FIG. 2 is a diagram illustrating power line carrier communication via the same distribution board as above. FIG. 3 is a diagram illustrating the configuration of a filter device included in the distribution board. FIG. 4 is a diagram illustrating the configuration of a distribution board according to Modification 1. FIG. 5 is a diagram illustrating a connection form of a filter device according to a second modification.

The embodiments and modified examples described below are merely examples of the present disclosure, and the present disclosure is not limited to the embodiments and modified examples. Even other than the following embodiments and modifications, various changes can be made according to the design etc. as long as they do not deviate from the technical idea of the present disclosure.

(Embodiment)
Hereinafter, a power distribution board according to the present embodiment and a filter device as a filter provided in the power distribution board will be described using FIGS. 1 to 3.

(1) Overview The distribution board 1 according to the present embodiment is configured to be usable for power line communication (PLC), which is communication using power lines. Power line carrier communication (PLC) is communication in which a high frequency signal is superimposed and transmitted on a power line (power line 40) that supplies electric power. Hereinafter, a signal transmitted through PLC communication will be referred to as a PLC signal.

The facility 6 includes a distribution board 1. As shown in FIG. 1, the distribution board 1 includes a main breaker 10, a plurality of branch breakers 20, and a filter device 30. Here, in this embodiment, a case is illustrated in which the facility 6 is a detached house, but the present invention is not limited to this example. The facility 6 may be, for example, each residential unit of an apartment complex, an office, a store, a factory, a hospital, etc., as long as the distribution board 1 can be installed therein.

The main breaker 10 is connected to a system power supply 5 (commercial power supply) that supplies electric power via a power line 40 that is used for supplying electric power. The main breaker 10 is connected to a plurality of branch breakers 20 via conductive bars 21 (bus bars).

The plurality of branch breakers 20 are each connected to a plurality of loads (equipment 60). The plurality of branch breakers 20 each branch the main circuit into which the main breaker 10 is inserted into a plurality of branch circuits. Here, the main circuit means an electric path from the power line 40 to the power supply side terminal of each branch breaker 20 inside the distribution board 1, and the branch circuit is downstream from the power supply side terminal of each branch breaker 20. means the electrical circuit on the side. As an example, each branch circuit includes one load (device 60). The load receives power from the grid power supply 5 via the corresponding branch breaker 20 .

In this embodiment, signals are transmitted and received between a plurality of loads (devices 60) connected to the distribution board 1 in the facility 6 using power line carrier communication. Hereinafter, when it is necessary to distinguish between the plurality of devices 60, they will be referred to as device 61, device 62, and device 63.

For example, as shown in FIG. 2, communication is performed between a plurality of devices 61 to 63 connected to the distribution board 1 of the facility 6 using PLC. Here, the devices 61 to 63 are devices that can communicate using PLC.

In addition, in this embodiment, the primary side of the main breaker 10 means the electric path between the main breaker 10 and the system power supply 5. The secondary side of the main breaker 10 means the electric path from the main breaker 10 to the power supply side terminals of each branch breaker 20.

The filter device 30 is provided on at least one of the primary side of the main breaker 10 , the secondary side of the main breaker 10 , and between the primary side of the main breaker 10 and the secondary side of the main breaker 10 . The filter device 30 functions as a power line carrier communication filter that attenuates noise in at least one direction in PLC communication. In this embodiment, the filter device 30 attenuates both the noise input from the grid power supply 5 during PLC communication and the noise output to the grid power supply 5 during PLC communication, that is, in both directions during PLC communication. Attenuate noise.

In this embodiment, for example, the noise input from the system power supply 5 during PLC communication and the noise output to the system power supply 5 during PLC communication are each PLC signals. That is, the filter device 30 transmits the PLC signal inside the facility 6 to the outside of the facility 6 by attenuating the PLC signal in both directions in PLC communication as noise, and transmits the PLC signal outside the facility 6 to the facility 6. Suppress transmission within the network.

(2) Configuration In the following explanation, unless otherwise specified, the top, bottom, left, and right of FIG. (before). Specifically, the direction in which the main breaker 10 and branch breakers 20 are lined up is defined as the left-right direction, and the direction in which the bottom of the cabinet body 1100 and the main breaker 10 and branch breakers 20 are lined up is defined as the front-back direction. Further, a direction perpendicular to the left-right direction and the front-back direction is defined as the up-down direction.

As shown in FIG. 1, the distribution board 1 includes a cabinet 1000, a main breaker 10, a plurality of branch breakers 20, and a filter device 30.

The cabinet 1000 includes a box-shaped cabinet body 1100 with an open front, and a lid that closes the opening of the cabinet body 1100. In FIG. 1, illustration of the lid is omitted. Inside the cabinet 1000, a main breaker 10, a plurality of branch breakers 20, and a filter device 30 are housed.

(2.1) Main Breaker The main breaker 10 is connected to the system power supply 5 via the power line 40. In this embodiment, the power supply system from the grid power supply 5 is a single-phase three-wire system, and the power supply line 40 includes a first voltage line (L1 phase) 411, a second voltage line (L2 phase) 412, and a middle voltage line (L2 phase) 412. It is composed of three wires: a sex wire (N phase) 413. The first voltage line 411 includes electric wires 421 and 431. Second voltage line 412 includes electric wires 422 and 432. Neutral wire 413 includes electric wires 423 and 433.

The main breaker 10 includes a plurality (three in this embodiment) of primary terminals 11 and a plurality (three in this embodiment) of secondary terminals. Since the distribution board 1 of this embodiment assumes a single-phase three-wire type as the power distribution system, the single-phase three-wire type lead-in line of the grid power supply 5 is electrically connected to the primary terminal 11 of the main breaker 10. be done. Specifically, among the plurality of primary side terminals 11, the primary side terminal 111 is connected to the first voltage line (L1 phase) 411 as the first voltage pole, and the primary side terminal 112 is connected to the second voltage line (L1 phase) as the second voltage pole. The voltage line (L2 phase) 412 and the primary terminal 113 are electrically connected to a neutral line (N phase) 413 as a neutral pole, respectively.

Further, a plurality of (three in this embodiment) secondary terminals of the main breaker 10 are electrically connected to a plurality (three in this embodiment) of conductive bars 21, respectively. The plural (three in this embodiment) conductive bars 21 include a first conductive bar 211 of the first voltage pole (L1 phase), a second conductive bar 212 of the second voltage pole (L2 phase), and a neutral pole (L2 phase). (N phase) third conductive bar 213.

The first secondary terminal (first terminal) among the plurality of secondary terminals of the main breaker 10 is electrically connected to the first conductive bar 211 of the first voltage pole (L1 phase). The second secondary terminal (second terminal) is electrically connected to the second conductive bar 212 of the second voltage pole (L2 phase). The third secondary terminal (third terminal) is electrically connected to the third conductive bar 213 of the neutral pole (N phase). Each conductive bar 21 is formed of a conductive member into a long plate shape that is elongated in the left-right direction, and is arranged inside the cabinet 1000 at the vertical center and on the right side of the main breaker 10.

(2.2) Branch Breaker The plurality of branch breakers 20 are divided into upper and lower sides of the third conductive bar 213 of the neutral pole, and are arranged so as to be lined up in the left-right direction. In this embodiment, as shown in FIG. 1, ten branch breakers 20 are arranged in a row in the left-right direction above the third conductive bar 213 of the neutral pole. Further, ten branch breakers 20 are arranged below the third conductive bar 213 of the neutral pole so as to be lined up in the left-right direction.

Each branch breaker 20 includes a pair of primary side terminals and a pair of secondary side terminals. The branch breaker 20 is available for 100V and 200V. A pair of primary side terminals included in the 100V branch breaker 20 include one of the first conductive bar 211 of the first voltage pole and the second conductive bar 212 of the second voltage pole, and the third conductive bar of the neutral pole. 213, respectively. A pair of primary terminals of the 200V branch breaker 20 are electrically connected to the first conductive bar 211 of the first voltage pole and the second conductive bar 212 of the second voltage pole, respectively. Thereby, each branch breaker 20 is supplied with alternating current voltage from the system power supply 5 via the main breaker 10.

Each branch breaker 20 is plug-in connected to the conductive bar 21 from above or below, so that the primary side of the branch breaker 20 is electrically connected to the secondary side of the main breaker 10.

One or more devices 60 (loads) are electrically connected to the secondary side terminal of the branch breaker 20. For example, a device 61 is connected to the secondary terminal of the branch breaker 20a, a device 62 is connected to the secondary terminal of the branch breaker 20b, and a device 63 is connected to the secondary terminal of the branch breaker 20c.

When the device 61 and the device 62 communicate by PLC, the signal outputted from the device 61 during communication by the PLC (PLC signal) is transmitted via the branch breaker 20a and the conductive bar 21 (for example, the first conductive bar 211). and is input to the branch breaker 20b. The PLC signal input to the branch breaker 20b is received by the device 62.

(2.3) Filter Device As shown in FIG. 3, the filter device 30 includes a plurality of (three in this embodiment) filter circuits 301. If it is necessary to describe the plurality of filter circuits 301 individually, they will be described as a first filter circuit 311, a second filter circuit 312, and a third filter circuit 313. Filter device 30 includes connection terminals 321-323, 331-333.

The plurality of filter circuits 301 are filters that pass signals of a predetermined frequency and attenuate signals (noise) of other frequencies. The plurality of filter circuits 301 are, for example, low-pass filters, band-pass filters, or the like. Each filter circuit 301 functions as a filter for power line carrier communication that attenuates noise in at least one direction during PLC communication. In the present embodiment, each filter circuit 301 attenuates both the noise input from the grid power supply 5 during PLC communication and the noise output to the grid power supply 5 during PLC communication, that is, bidirectional in PLC communication. Attenuates noise in

Filter device 30 is provided between the primary side of main breaker 10 and the secondary side of main breaker 10 . In other words, each filter circuit 301 is provided between the primary side of main breaker 10 and the secondary side of main breaker 10 . In this embodiment, each filter circuit 301 is provided on the primary side of the main breaker 10. Specifically, the first filter circuit 311 is provided between the electric wire 421 and the electric wire 431 included in the first voltage line 411 (L1 phase). The second filter circuit 312 is provided between the electric wire 422 and the electric wire 432 included in the second voltage line 412 (L2 phase). The third filter circuit 313 is provided between the electric wire 423 and the electric wire 433 included in the neutral wire 413 (N phase).

The first filter circuit 311 is electrically connected to the connection terminal 321. The connection terminal 321 is connected to the electric wire 421. Here, the connection terminal 321 is provided on the terminal block, and the connection terminal 321 and the electric wire 421 are connected by screwing the electric wire 421 to the connection terminal 321 of the terminal block. Alternatively, the connection terminal 321 may be connected to the electric wire 421 as a quick connection terminal.

The first filter circuit 311 is electrically connected to the connection terminal 331. Connection terminal 331 is connected to electric wire 431. Here, the connection terminal 331 is provided on the terminal block, and the connection terminal 331 and the electric wire 431 are connected by screwing the electric wire 431 to the connection terminal 331 of the terminal block. Alternatively, the connection terminal 331 may be connected to the electric wire 431 as a quick connection terminal.

The second filter circuit 312 is electrically connected to the connection terminal 322. Connection terminal 322 is connected to electric wire 422 . Here, the connection terminal 322 is provided on the terminal block, and the connection terminal 322 and the electric wire 422 are connected by screwing the electric wire 422 to the connection terminal 322 of the terminal block. Alternatively, the connection terminal 322 may be connected to the electric wire 422 as a quick connection terminal.

The second filter circuit 312 is electrically connected to the connection terminal 332. Connection terminal 332 is connected to electric wire 432. Here, the connection terminal 332 is provided on the terminal block, and the connection terminal 332 and the electric wire 432 are connected by screwing the electric wire 432 to the connection terminal 332 of the terminal block. Alternatively, the connection terminal 332 may be connected to the electric wire 432 as a quick connection terminal.

The third filter circuit 313 is electrically connected to the connection terminal 323. Connection terminal 323 is connected to electric wire 423. Here, the connection terminal 323 is provided on the terminal block, and the connection terminal 323 and the electric wire 423 are connected by screwing the electric wire 423 to the connection terminal 323 of the terminal block. Alternatively, the connection terminal 323 may be connected to the electric wire 423 as a quick connection terminal.

The third filter circuit 313 is electrically connected to the connection terminal 333. Connection terminal 333 is connected to electric wire 433. Here, the connection terminal 333 is provided on the terminal block, and the connection terminal 333 and the electric wire 433 are connected by screwing the electric wire 433 to the connection terminal 333 of the terminal block. Alternatively, the connection terminal 333 may be connected to the electric wire 433 as a quick connection terminal.

In this embodiment, communication by PLC is assumed to be communication between devices within the facility 6. Therefore, each filter circuit 301 attenuates the PLC signal transmitted and received between devices as noise so that the PLC signal is not output outside the facility 6. Further, each filter circuit 301 attenuates signals generated outside the facility 6 (other PLC signals in other facilities) as noise.

In addition, in this embodiment, communication with equipment outside the facility 6 may be performed by communication using PLC. In this case, each filter circuit 301 passes PLC signals output from devices within the facility 6. Each filter circuit 301 attenuates signals of frequencies other than those used in the PLC signal as noise, and suppresses the noise from being output outside the facility 6. Furthermore, each filter circuit 301 passes the PLC signal output from outside the facility 6, attenuates signals with frequencies other than those used in the PLC signal as noise, and prevents the noise from being input to the main breaker 10. suppress. At this time, each filter circuit 301 also passes a commercial frequency current output from outside the facility 6.

(3) Advantages As explained above, the electricity distribution board 1 of this embodiment is a electricity distribution board that can be used for communication using power lines. The distribution board 1 includes a master breaker 10 and a filter for power line carrier communication (filter device 30). The filter is provided between the primary side of the main breaker 10 and the secondary side of the main breaker 10, and attenuates noise in at least one direction in power line carrier communication. More specifically, the filter is provided on the primary side of the main breaker 10 and attenuates noise in both directions in power line carrier communication.

According to this configuration, since the distribution board 1 has a filter, it is possible to prevent noise from being output to the outside of the facility 6 and from inputting noise from outside the facility 6. That is, by having the distribution board 1 with the filter, it is possible to suppress deterioration in the quality of power line carrier communication.

Furthermore, since the distribution board 1 has a filter, the devices 61 to 63 electrically connected to the branch breaker 20 do not need to have a filter. Therefore, since it is not necessary to provide a filter in all devices that perform power line carrier communication, it is possible to suppress the system configuration that performs power line carrier communication from becoming complicated.

(4) Modifications The above embodiment is just one of various embodiments of the present disclosure. The embodiments described above can be modified in various ways depending on the design, etc., as long as the objective of the present disclosure can be achieved. Modifications will be listed below. Note that the modified examples described below can be applied in combination with the above embodiment as appropriate.

(4.1) Modification example 1
In the embodiment described above, the filter device 30 was configured to be provided on the primary side of the main breaker 10, but the configuration is not limited to this.

The filter device 30 may be provided on the secondary side of the main breaker 10. For example, the filter device 30 may be provided between the main breaker 10 and the conductive bar 21 (see FIG. 4). In this case, the first filter circuit 311 is provided between the first terminal, which is the secondary side terminal of the main breaker 10, and the first conductive bar 211. The second filter circuit 312 is provided between the second terminal, which is the secondary side terminal of the main breaker 10, and the second conductive bar 212. The third filter circuit 313 is provided between the third terminal, which is the secondary terminal of the main breaker 10, and the third conductive bar 213.

A connection terminal 321 (see FIG. 3) electrically connected to the first filter circuit 311 is electrically connected to the first terminal. A connection terminal 331 (see FIG. 3) electrically connected to the first filter circuit 311 is electrically connected to the first conductive bar 211 (see FIG. 4).

A connection terminal 322 (see FIG. 3) electrically connected to the second filter circuit 312 is electrically connected to the second terminal. A connection terminal 332 (see FIG. 3) electrically connected to the second filter circuit 312 is electrically connected to the second conductive bar 212 (see FIG. 4).

A connection terminal 323 (see FIG. 3) electrically connected to the third filter circuit 313 is electrically connected to the third terminal. A connection terminal 333 electrically connected to the third filter circuit 313 is electrically connected to the third conductive bar 213 (see FIG. 4).

In this modification, as in the embodiment, it is possible to suppress noise from being output to the outside of the facility 6 and noise from outside the facility 6 from being input to the main breaker 10 during PLC communication. can.

(4.2) Modification 2
In the embodiment described above, the filter device 30 is electrically connected to the system power supply 5, which is a power source that supplies electric power, via a power line 40 (electric wire), and is connected to a power line that is different from the power line 40. It may have a terminal.

For example, the filter device 30 may be further connected to the external device 70 by having the connection terminals 331 and 332 function as sending terminals (see FIG. 5). In this case, the connection terminal 331 is connected to the first terminal of the external device 70 via an electric wire 451 that is different from the electric wire 431 of the power supply line 40 . The connection terminal 332 is connected to the second terminal of the external device 70 via an electric wire 453 that is different from the electric wire 433 of the power supply line 40 . External device 70 is, for example, a current sensor.

Note that in this modification, the connection terminals 331 and 332 are configured to function as sending terminals, but the configuration is not limited to this. Two of the connection terminals 331, 332, and 333 may function as sending terminals.

Alternatively, the filter device 30 may have two terminals different from the connection terminals 331, 332, and 333 as sending terminals.

Alternatively, the filter device 30 may have one terminal different from the connecting terminals 331, 332, and 333 as a sending terminal, and one of the connecting terminals 331, 332, and 333 may function as the sending terminal.

Note that the filter device 30 may be provided on both the primary side terminal and the secondary side of the main breaker 10.

(4.3) Modification 3
In the above embodiment, the filter device 30 may be integrally connected to the main breaker 10. Here, integral connection means that the respective terminals of two devices are directly connected.

For example, the plurality (three in this embodiment) of the primary side terminals 11 of the main breaker 10 and the connection terminals 331 to 333 of the filter device 30 are directly connected one-to-one without using the power line 40, respectively. More specifically, the primary side terminal 111 of the main breaker 10 is directly connected to the connection terminal 331 of the filter device 30 without using the electric wire 431. The primary side terminal 112 of the main breaker 10 is directly connected to the connection terminal 332 of the filter device 30 without using the electric wire 432. The primary side terminal 113 of the main breaker 10 is directly connected to the connection terminal 333 of the filter device 30 without using the electric wire 433.

In addition, when the filter device 30 is provided on the secondary side of the main breaker 10 as shown in Modification 1, a plurality of (three in this embodiment) secondary side terminals of the main breaker 10 and the connection terminals 321 to 323 of the filter device 30 are directly connected one-to-one without using electric wires.

(4.4) Modification example 4
In the embodiment described above, the filter device 30 was configured to be provided separately from the main breaker 10, but it is not limited to this configuration.

The filter device 30 may be built into the main breaker 10. In this case, the first filter circuit 311 is provided in a path between the primary side terminal 111 of the main breaker 10 and the secondary side terminal of the main breaker 10 that is electrically connected to the first conductive bar 211. A second filter circuit 312 is provided in a path between the primary terminal 112 of the main breaker 10 and the secondary terminal of the main breaker 10 that is electrically connected to the second conductive bar 212 . A third filter circuit 313 is provided in a path between the primary terminal 113 of the main breaker 10 and the secondary terminal of the main breaker 10 that is electrically connected to the third conductive bar 213 .

(4.5) Modification 5
In the embodiment described above, the filter device 30 includes a plurality of filter circuits 301 (first filter circuit 311, second Although the configuration is such that the filter circuit 312 and the third filter circuit 313 are provided, the present invention is not limited to this configuration.

The filter device 30 may provide a filter circuit at one or two of the plurality of poles (first voltage pole, second voltage pole, and neutral pole). That is, the filter device 30 may have a configuration in which at least one of the plurality of poles (first voltage pole, second voltage pole, and neutral pole) is provided with a filter circuit.

(4.6) Modification 6
In the above embodiment, the filter device 30 attenuates both the noise input from the grid power supply 5 during PLC communication and the noise output to the grid power supply 5 during PLC communication, that is, in both directions during PLC communication. The structure is designed to attenuate noise. However, the configuration is not limited to this.

The filter device 30 may attenuate noise input from the system power supply 5 during PLC communication, or may attenuate both noise output to the system power supply 5 during PLC communication. In other words, the filter device 30 may attenuate noise in one direction in PLC communication.

(4.7) Modification example 7
In the above embodiment, the filter device 30 may have a ferrite core as a filter circuit. In this case, the filter device 30 attenuates noise in both directions.

(4.8) Modification 8
In the above embodiment, the filter device 30 includes one filter circuit 301 for each pole (phase) of the first voltage pole (L1 phase), the second voltage pole (L2 phase), and the neutral pole (N phase). Although this configuration is provided, the present invention is not limited to this configuration.

The filter device 30 includes one filter circuit 301 for at least one of a plurality of phases, for example, a set of L1 phase and N phase, a set of L2 phase and N phase, and a set of L1 phase and L2N phase. Good too. In other words, the filter circuit 301 only needs to be provided in at least one phase (pole) among the plurality of phases.

(4.9) Modification 9
In the embodiment described above, the distribution board 1 has a configuration in which one filter circuit 301 is provided for bidirectional noise attenuation for each electric wire (for example, the power line 40), but the present invention is not limited to this configuration.

The distribution board 1 is individually equipped with a filter circuit that attenuates noise input from the grid power supply 5 and a filter circuit that attenuates noise output to the grid power supply 5 for each electric wire (for example, the power line 40). You can.

(4.10) Modification 10
In the above embodiment, when a communication signal is transmitted from any one of the L1 phase and N phase set, the L2 phase and N phase set, and the L1 phase and L2N phase set to the other set, the photo A coupler may also be provided.

In this case, the photo is placed on the downstream side of the communication device 50, that is, on the side of the connection terminal that is remote from the system power supply 5 among the two connection terminals (for example, connection terminals 521, 531) that are electrically connected in the communication device 50. A coupler is provided.

(summary)
As explained above, the electricity distribution board (1) of the first aspect is a electricity distribution board that can be used for power line carrier communication, which is communication using a power line that supplies electric power. The distribution board (1) includes a master breaker (10) and a filter (filter device 30). The filter is provided on at least one of the primary side of the main breaker (10), the secondary side of the main breaker (10), and between the primary side and the secondary side, and is provided on at least one of the primary side of the main breaker (10), and between the primary side and the secondary side. This is a filter for power line carrier communications that attenuates noise in both directions.

According to this configuration, it is possible to prevent the quality of power line carrier communication from deteriorating and to prevent the system configuration for performing power line carrier communication from becoming complicated.

In the distribution board (1) of the second aspect, in the first aspect, the filter attenuates noise only in one direction.

According to this configuration, it is possible to prevent noise from being output to the outside of the facility (6) or from inputting noise from outside the facility (6).

In the distribution board (1) of the third aspect, in the first aspect, the filter attenuates noise in both directions.

According to this configuration, it is possible to prevent noise from being output to the outside of the facility (6) and from inputting noise from outside the facility (6).

In the distribution board (1) of the fourth aspect, in any of the first to third aspects, the filter is a filter circuit (301) electrically connected to the power line (power line 40, conductive bar 21). including.

According to this configuration, the filter can be configured by a circuit.

In the distribution board (1) of the fifth aspect, in any one of the first to fourth aspects, the filter has a plurality of poles (a first voltage pole, a second voltage pole, a neutral at least one phase of the poles).

According to this configuration, the filter can be set according to the pole used for power line carrier communication.

In the distribution board (1) of the sixth aspect, in any of the first to fifth aspects, the filter is provided on the primary side of the main breaker (10).

According to this configuration, it is possible to arrange the filter in an empty space such as a limiter space.

In the distribution board (1) of the seventh aspect, in the sixth aspect, the filter is electrically connected to a power supply (system power supply 5) that supplies electric power via an electric wire (power supply line 40), and It has sending terminals (connection terminals 331 to 333) that are connected to electric wires other than the electric wires.

According to this configuration, it is possible to send the electric wire. In other words, it becomes possible to supply power to other devices.

In the distribution board (1) of the eighth aspect, in any of the first to fifth aspects, the filter is provided on the secondary side of the main breaker (10).

According to this configuration, the filter can be disposed on the secondary side of the main breaker (10) between the secondary side terminal of the main breaker (10) and the conductive bar (21).

The distribution board (1) of the ninth aspect has a bus bar (conductive bar 21) on the secondary side of the main breaker (10) in the eighth aspect. The filter is connected to the bus bar.

According to this configuration, space can be saved by arranging the filter between the main breaker and the bus bar.

In the distribution board (1) of the tenth aspect, the filter is integrally connected to the main breaker (10) in the sixth to eighth aspects.

According to this configuration, since the filter is directly connected to the main breaker (10), there is no need for an electric wire between the filter and the main breaker (10).

In the distribution board (1) of the eleventh aspect, in any one of the first to fifth aspects, the filter is built in the main breaker.

According to this configuration, by incorporating the filter into the main breaker (10), it is possible to save space and reduce costs during construction.

The filter device of the twelfth aspect is used as the filter in the distribution board (1) of any one of the first to eleventh aspects.

According to this configuration, it is possible to prevent the quality of power line carrier communication from deteriorating and to prevent the system configuration for performing power line carrier communication from becoming complicated.

1 Distribution board 5 System power supply 6 Facility 10 Main breaker 20, 20a, 20b, 20c Branch breaker 21 Conductive bar (bus bar)
211 First conductive bar (bus bar, first voltage pole)
212 Second conductive bar (bus bar, second voltage pole)
213 Third conductive bar (bus bar, neutral pole)
30 Filter device (filter)
40 Power supply line 301 Filter circuit 311 First filter circuit 312 Second filter circuit 313 Third filter circuit 331, 332, 333 Connection terminal (sending terminal)
411 First voltage line (L1 phase, first voltage pole)
412 Second voltage line (L2 phase, second voltage pole)
413 Neutral wire (N phase, neutral pole)

Claims (8)

A distribution board that can be used for power line carrier communication, which is communication using power lines that supply electricity,
Main breaker and
A device for power line carrier communication that is provided on at least one of the primary side of the main breaker and between the primary side and the secondary side of the main breaker , and that attenuates noise in at least one direction in the power line carrier communication. and a filter of
The filter includes at least one filter circuit electrically connected to the power line,
The power line includes a plurality of poles,
The filter is provided at at least one pole among the plurality of poles,
The at least one filter circuit included in the filter and the at least one pole on which the filter is provided are in a one-to-one correspondence,
Distribution board. the filter attenuates the noise in only one direction;
The distribution board according to claim 1. the filter attenuates the noise in both directions;
The distribution board according to claim 1. The filter is provided on the primary side of the main breaker,
The distribution board according to any one of claims 1 to 3. The filter is electrically connected to a power source that supplies power via an electric wire, and has a sending terminal that is connected to an electric wire different from the electric wire.
The electricity distribution board according to claim 4. the filter is integrally connected to the main breaker;
The distribution board according to claim 4 or 5. The filter is built in the main breaker,
The distribution board according to any one of claims 1 to 3. Used as the filter in the distribution board according to any one of claims 1 to 7,
filter device.

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