JP6032599B2 - Interphase coupler and distribution board - Google Patents

Description

  The present invention relates to an interphase coupler and a distribution board used for power line communication (PLC) using a single-phase three-wire line of a commercial power source.

  Conventionally, an interphase coupler used for power line communication using a single-phase three-wire line of a commercial power source is known (see, for example, Patent Document 1). Patent Document 1 discloses an inter-phase coupler that can be connected to three bus bars arranged in a distribution board.

JP 2009-231942 A

  However, the conventional interphase coupler described in Patent Document 1 is installed in the installation space of the branch breaker in the distribution board. For this reason, when there is no space in the installation space of the branch breaker in the existing distribution board, the interphase coupler cannot be installed. To install the interphase coupler, it was necessary to replace or increase the distribution board.

  The present invention is an invention made in view of the above points, and an object of the present invention is to provide an interphase coupler that can be installed in an existing distribution board even when there is no space in the installation space of the branch breaker, Another object of the present invention is to provide a distribution board in which the interphase coupler is installed.

The interphase coupler of the present invention is an interphase coupler installed in the distribution board, and the devices connected between the different phases of the single-phase three-wire commercial power supply perform power line carrier communication. A communication relay unit that relays between the devices, and a connection unit that electrically connects the communication path to which the device is connected and the communication relay unit, and includes the communication relay unit and the connection unit. The shape is a shape arranged between the main breaker and the branch breaker in the distribution board, and the connecting portion corresponds to the plurality of electric paths between the main breaker and the branch breaker on a one-to-one basis. was seen including a plurality of contacts which are connected to said plurality of contacts, said one-to-one correspondence with the plurality of load-side terminals of the main breaker is electrically connected to each of said plurality of contacts, the A bus bar to which the branch breaker is connected in the distribution board; Serial as pressed against the terminal screw for connecting the load terminal, characterized in that it is electrically connected to the load terminal.

  In the interphase coupler, a communication frequency of the power line carrier communication is higher than a commercial frequency of the commercial power source, and the plurality of contacts include a first contact connected to a first voltage line and a second voltage line. A second contact that is connected to the neutral line, and a third contact that is connected to the neutral wire, and the communication relay unit is inserted between the first contact and the third contact. 1 transformer, a transformer including a second winding inserted between the second contact and the third contact, and inserted between the connection portion and the transformer. It is preferable to include a first impedance circuit having a characteristic of having a high impedance with respect to a frequency and a low impedance with respect to the communication frequency.

  In the interphase coupler, the transformer is a three-winding transformer including the first winding, the second winding, and a third winding, and is connected to the third winding. It is preferable to further include an external connection unit to which an external device that inputs and outputs the communication signal of the power line carrier communication is connected to the communication relay unit.

In the interphase coupler, the external connection unit is an outlet for the commercial power supply, the communication relay unit is inserted between the connection unit and the external connection unit, and has a high impedance with respect to the communication frequency. And a second impedance circuit having the characteristic of having a low impedance with respect to the commercial frequency and the third winding inserted in series, and having a high impedance with respect to the commercial frequency, with respect to the communication frequency It is preferable to further include a third impedance circuit having a characteristic of low impedance.
The interphase coupler of the present invention is an interphase coupler installed in the distribution board, and the devices connected between the different phases of the single-phase three-wire commercial power supply perform power line carrier communication. A communication relay unit that relays between the devices, and a connection unit that electrically connects the communication path to which the device is connected and the communication relay unit, and includes the communication relay unit and the connection unit. The shape is a shape arranged between the main breaker and the branch breaker in the distribution board, and the connecting portion corresponds to the plurality of electric paths between the main breaker and the branch breaker on a one-to-one basis. A communication frequency of the power line carrier communication is higher than a commercial frequency of the commercial power supply, and the plurality of contacts are a first contact connected to a first voltage line; A second contact connected to the second voltage line; A third contact connected to a wire, and the communication relay section includes a first winding inserted between the first contact and the third contact, and the second contact And a transformer including a second winding inserted between the third contact and the connection portion and the transformer, and has a high impedance with respect to the commercial frequency, and the communication frequency A first impedance circuit having a low impedance characteristic, and the transformer is a three-winding transformer including the first winding, the second winding, and a third winding. , Further comprising an external connection unit connected to the third winding and connected to an external device that inputs and outputs a communication signal of the power line carrier communication to the communication relay unit, the external connection unit, An outlet for commercial power, the communication relay unit A second impedance circuit inserted between the connection portion and the external connection portion, having a characteristic of having a high impedance with respect to the communication frequency and a low impedance with respect to the commercial frequency, and the third And a third impedance circuit inserted in series in the winding and having a characteristic of having a high impedance with respect to the commercial frequency and a low impedance with respect to the communication frequency.
In the interphase coupler, the plurality of contacts are preferably electrically connected to the plurality of load-side terminals of the main breaker in a one-to-one correspondence.
In the interphase coupler, each of the plurality of contacts is fixed by a terminal screw for connecting the bus bar to which the branch breaker is connected and the load side terminal in the distribution board. It is preferable to be electrically connected to the load side terminal.

  In this interphase coupler, it is preferable that a fuse is further provided between the connection part and the communication relay part.

  The interphase coupler preferably further includes a display connected in series to the fuse.

  The distribution board of the present invention is characterized in that the interphase coupler is installed in a space between the main breaker and the branch breaker.

  In the present invention, a plurality of contact points connected in a one-to-one correspondence to a plurality of electric paths between the main breaker and the branch breaker are provided. Thereby, the inter-phase coupler can be installed between the main breaker and the branch breaker in the existing distribution board. Since the installation space for the branch breaker is not used, the interphase coupler can be installed in the existing distribution board even when the installation space for the branch breaker is not empty.

It is a conceptual diagram which shows the inside of the distribution board after installation of the heterophasic coupler which concerns on Embodiment 1. FIG. It is a perspective view which shows the positional relationship of the interphase coupler which concerns on Embodiment 1, and a branch breaker. It is a front view which shows the inside of the distribution board before installation of the heterophasic coupler which concerns on Embodiment 1. FIG. It is a side view which shows the positional relationship of the interphase coupler which concerns on Embodiment 1, and a branch breaker. FIG. 3 is a circuit diagram of the interphase coupler according to the first embodiment. It is a side view which shows the positional relationship of the interphase coupler which concerns on Embodiment 2, and a branch breaker. FIG. 5 is a circuit diagram of an interphase coupler according to Embodiment 2. FIG. 5 is a circuit diagram of an interphase coupler according to Embodiment 3.

  The inter-phase couplers according to the following first to third embodiments include a communication relay unit that relays between the devices so that the devices connected between the different phases of the single-phase three-wire commercial power supply perform power line carrier communication. I have. The overall shape of the interphase coupler is a shape that is disposed between the main breaker and the branch breaker in the distribution board. In the interphase coupler, a plurality of contacts are connected to a plurality of electric circuits between the main breaker and the branch breaker.

  Hereinafter, Embodiments 1 to 3 will be described with reference to the drawings.

(Embodiment 1)
The interphase coupler 1 of the present embodiment includes two single-phase three-wire voltage lines (L1 phase and L2 phase) and one neutral wire (N phase) from a commercial power supply (post transformer) (not shown). ) Is used for a power line carrier communication system that performs communication between phases at a predetermined communication frequency. As shown in FIG. 1, the interphase coupler 1 is installed in a space between the main breaker 3 and the branch breaker 4 in the distribution board 2.

  First, the distribution board 2 to which the interphase coupler 1 is attached will be described with reference to FIGS. The distribution board 2 is, for example, a synthetic resin molded product, and includes a rectangular frame-shaped box body 21 shown in FIG. 3 and a lid (not shown) coupled to the front side of the box body 21. . As shown in FIG. 3, the distribution board 2 includes one main breaker 3 and a plurality of branch breakers 4, 4,. A plurality of branch breakers 4, 4,... Are arranged in two upper and lower stages.

  A first base 22 and a second base 23 are installed on the box body 21. The main breaker 3 is attached to the first frame 22. A plurality of branch breakers 4, 4,... Are attached to the second frame 23. The first frame 22 and the second frame 23 are connected and integrated with each other. The first gantry 22 and the second gantry 23 are connected to form a rectangular shape as a whole, and support pieces 221 and 231 project from the upper and lower end portions of the left and right side edges, respectively. By inserting the mounting screws 223 and 233 into the mounting holes 222 and 232 of the support pieces 221 and 231 and tightening the mounting screws 223 and 233, the first base 22 and the second base 23 can be easily attached to the box body 21. Can be attached. The main breaker 3 is attached to the first frame 22 using fixing screws 224.

  The second frame 23 to which the branch breaker 4 is attached is formed of a sheet metal (iron plate) in the shape shown in FIG. 2, and is provided with support pieces 231 at the upper end and the lower end of the right end edge, and the upper end of the left end edge. The connection piece 234 is provided in the part and the lower end part.

  The connection piece 225 (see FIG. 3) of the first mount 22 is superimposed on the front surface side of the connection piece 234 of the second mount 23, and the connection protrusion 235 is inserted into the connection hole 226 (see FIG. 3). By screwing the screw 227 (see FIG. 3) into the set screw hole 236, the first frame 22 and the second frame 23 are coupled.

  The bar support member 25 shown in FIG. 2 simultaneously holds three bus bars 26 to 28 including two voltage bar bus bars 26 and 27 and a neutral pole bus bar 28.

  The bus bars 26 to 28 are provided for connecting the branch breakers 4, and eight branch breakers 4 are arranged in two upper and lower stages. As shown in FIG. 3, the bus bars 26 to 28 are electrically connected to the load side terminals 31 to 33 of the main breaker 3. The bus bar 26 and the load side terminal 31 are connected using a terminal screw 261 so as not to come off. The bus bar 27 and the load side terminal 32 are connected using a terminal screw 271 so as not to come off. The bus bar 28 and the load side terminal 33 are connected by using a terminal screw 281 so as not to come off.

  In addition, as shown in FIG. 3, a cover 29 is provided in the distribution board 2 to cover a connection portion between the load side terminals 31 to 33 of the main breaker 3 and the bus bars 26 to 28. The cover 29 is, for example, a synthetic resin product, and as shown in FIG. 4, as shown in FIG. 4, a rectangular upper surface portion 291 and a pair of side surface portions 292 provided extending downward from both longitudinal ends of the upper surface portion 291. 293. The front ends (lower ends) of the side surface portions 292 and 293 are fitted into the fitting holes 237 of the second frame 23. As a result, the cover 29 is attached to the second frame 23.

  As shown in FIG. 3, the main breaker 3 includes two power supply side terminals 34 and 35 connected to the voltage electrode of the low voltage distribution line, and a power supply side terminal 36 connected to the neutral electrode of the low voltage distribution line. ing. The main breaker 3 has two load-side terminals 31 and 32 that are voltage poles corresponding to the power-side terminals 34 and 35, respectively, and a load-side terminal 33 that is a neutral pole corresponding to the power-side terminal 36. And. Further, the main breaker 3 is provided with an open / close mechanism (not shown) for turning on / off the power supply between the power supply side terminals 34 to 36 and the corresponding load side terminals 31 to 33, respectively. An operation handle 37 is exposed on the front surface. In addition, the main breaker 3 has an overcurrent (overload current or short-circuit current) between the power supply side terminals 34 to 36 and the corresponding load side terminals 31 to 33, or a leakage current has occurred (that is, When an abnormal current occurs), the power supply side terminals 34 to 36 and the corresponding load side terminals 31 to 33 are disconnected, and the handle 37 is positioned on the off side. .

  The three power supply side terminals 34 to 36 are made of a conductive material, and are provided side by side in the horizontal direction on the upper side of the main breaker 3. The power supply side terminal 34, the power supply side terminal 36, and the power supply side terminal 35 are arranged in this order. A power line 51 (voltage lines 511, 512, neutral line 513) (see FIG. 1) is connected to each of the power supply side terminals 34 to 36 by terminal screws 341, 351, 361.

  The branch breaker 4 is electrically connected to the bus bars 26 to 28 by plug-in connection of power supply side connection portions (not shown) to the bus bars 26 to 28. The neutral electrode bus bar 28 is inserted into one power source side connection portion of the three power source side connection portions of the branch breaker 4, and the voltage source bus bar bars 26 and 27 are inserted into the remaining power source side connection portions. A piece (not shown) is inserted. However, each branch breaker 4 is electrically connected to only two of the bus bars 26 to 28, and the other one is treated as a dummy.

  The branch breaker 4 contains an open / close mechanism (not shown) for turning on / off the power supply between the power supply side connection portion and the load side connection portion (not shown). Furthermore, the branch breaker 4 has a circuit cutoff function that shuts off between the power supply side connection portion and the load side connection portion when an overcurrent flows between the power supply side connection portion and the load side connection portion. Yes. The dimensions of each branch breaker 4 are set to the so-called distribution board agreement dimensions (dimensions defined in the JIS standard as the standard of the internal device of the distribution board).

  In the distribution board 2, the power supply side (primary side) of the main breaker 3 is not passed through the main breaker 3 so that a power source such as a fire alarm can be secured even when the main breaker 3 is shut off. A power supply system for obtaining a power supply is provided. A primary feed switch (primary feed breaker) 5 as an internal unit housed in the box body 21 is inserted in the power supply system.

  Next, the interphase coupler 1 of the present embodiment will be described. The interphase coupler 1 of this embodiment includes a housing 11 as shown in FIGS. Further, as shown in FIG. 5, the interphase coupler 1 includes a connection unit 12, a communication relay unit 13, fuses 161 and 162, and indicators 171 and 172.

  The casing 11 is, for example, a synthetic resin product, and is formed in a shape that is disposed between the main breaker 3 and the branch breaker 4 in the distribution board 2. As shown in FIG. 4, a recess 111 is formed in the housing 11. As shown in FIGS. 2 and 4, the housing 11 includes a rectangular upper surface portion 112 and a pair of side surface portions 113 and 114 provided to extend downward from both longitudinal ends of the upper surface portion 112. A pair of side surface portions 115, 116 extending downward from both ends of the upper surface portion 112 in the short direction, and a lower surface portion 117 extending from the side surface portions 115, 116 so as to face the upper surface portion 112, 118 are integrally provided.

  The connection part 12 is provided in order to electrically connect the electric circuit to which the apparatus which performs power line carrier communication is connected, and the communication relay part 13. FIG. As shown in FIG. 4, the connection unit 12 includes a first contact 121, a second contact 122, and a third contact 123.

  The plurality of contacts 121 to 123 are connected to the plurality of electric circuits between the main breaker 3 and the branch breaker 4 so that the communication relay unit 13 is disposed between the main breaker 3 and the branch breaker 4 in the distribution board 2. They are connected in a one-to-one correspondence. In the present embodiment, the plurality of contacts 121 to 123 are electrically connected to the plurality of load side terminals 31 to 33 of the main breaker 3 in a one-to-one correspondence.

  The first contact 121 is a contact connected to the L1 phase voltage line (first voltage line). The first contact 121 is provided to be exposed downward from the lower surface portion 117 of the housing 11, and is electrically connected to the load-side terminal 31 of the main breaker 3. In this embodiment, the first contact 121 is pressed against the terminal screw 261 for connecting the bus bar 26 and the load side terminal 31 in the distribution board 2 so as to be electrically connected to the load side terminal 31. It is connected.

  The second contact 122 is a contact connected to the L2-phase voltage line (second voltage line). The second contact 122 is provided to be exposed downward from the lower surface portion 118 of the housing 11, and is electrically connected to the load side terminal 32 of the main breaker 3. In the present embodiment, the second contact 122 is pressed against the terminal screw 271 for connecting the bus bar 27 and the load side terminal 32 in the distribution board 2 so as to be electrically connected to the load side terminal 32. It is connected.

  The third contact 123 is a contact connected to the neutral wire (N phase). The third contact 123 is provided to be exposed downward from the bottom surface portion 119 of the recess 111 of the housing 11, and is electrically connected to the load side terminal 33 of the main breaker 3. In the present embodiment, the third contact 123 is pressed against the terminal screw 281 for connecting the bus bar 28 and the load-side terminal 33 in the distribution board 2, so that the third contact 123 is electrically connected to the load-side terminal 33. It is connected.

  Such an interphase coupler 1 is formed by attaching the cover 29 to the second mount 23 in a state where the contacts 121 to 123 are pressed against the terminal screws 261, 271, 281 using, for example, a spring or a pin. It is fixed to the board 2.

  The communication relay unit 13 shown in FIG. 5 is configured to relay between devices (not shown) connected between different phases of a single-phase three-wire commercial power supply so that the devices perform power line communication. Has been. The communication relay unit 13 of this embodiment includes a transformer 14 and a first impedance circuit 15.

  The transformer 14 is a two-winding transformer including a first winding 141 and a second winding 142. The first winding 141 is inserted between the first contact 121 and the third contact 123. The second winding 142 is inserted between the second contact 122 and the third contact 123. The first winding 141 and the second winding 142 are set to have the same polarity. Further, the turn ratio between the first winding 141 and the second winding 142 is, for example, 1: 1. The winding ratio between the first winding 141 and the second winding 142 is not limited to 1: 1.

  The first impedance circuit 15 is inserted between the connection unit 12 and the transformer 14. The first impedance circuit 15 has a characteristic that it has a high impedance with respect to a commercial frequency of a commercial power supply (not shown) and a low impedance with respect to the communication frequency of power line carrier communication. The communication frequency of power line carrier communication is higher than the commercial frequency of the commercial power source. The first impedance circuit 15 of this embodiment includes a capacitor 151 between the first contact 121 and the third contact 123. The capacitor 151 is inserted between the first contact 121 and the first terminal 143 of the transformer 14. The first impedance circuit 15 includes a capacitor 152 between the second contact 122 and the third contact 123. The capacitor 152 is inserted between the second contact 122 and the second terminal 144 of the transformer 14. The capacitors 151 and 152 have a function as a high pass filter.

  The fuse 161 is provided between the first contact 121 and the communication relay unit 13. The fuse 162 is provided between the second contact 122 and the communication relay unit 13.

  The indicators 171 and 172 are, for example, LEDs (Light Emitting Diodes). A resistor 173 for limiting the current of the display 171 is connected to the display 171 in series. A resistor 174 for limiting the current of the display 172 is connected to the display 172 in series. The display 171 and the resistor 173 are connected in series with the fuse 161 between the first contact 121 and the third contact 123. The indicator 172 and the resistor 174 are connected in series with the fuse 162 between the second contact 122 and the third contact 123.

  Next, an operation when the interphase coupler 1 according to the present embodiment is used in a power line carrier communication system will be described. A first communication device (not shown) is connected between the L1 phase voltage line and the neutral wire, and a second communication device (not shown) is connected between the L2 phase voltage line and the neutral wire. Suppose that

  Assuming that the first communication device outputs a communication signal between the L1-phase voltage line and the neutral line, the communication signal is input to the first winding 141 of the transformer 14 and wound around the same core by electromagnetic induction. In addition, an electromotive force is generated in the second winding 142 and a current flows. When the turns ratio of the first winding 141 and the second winding 142 is 1: 1, a current having the same amplitude as the communication signal input to the first winding 141 flows through the second winding 142. . As a result, the second communication device can normally receive the communication signal from the first communication device.

  The interphase coupler 1 of the present embodiment described above is provided with a plurality of contacts 121 to 123 connected to a plurality of electric paths between the main breaker 3 and the branch breaker 4 in a one-to-one correspondence. Thereby, the interphase coupler 1 can be installed between the main breaker 3 and the branch breaker 4 in the existing distribution board 2. Since the installation space for the branch breaker 4 is not used, the interphase coupler 1 can be installed in the existing distribution board 2 even when the installation space for the branch breaker 4 is not empty.

  Moreover, in the interphase coupler 1 of this embodiment, since the contacts 121-123 can be connected between the main breaker 3 and the branch breaker 4 using the load side terminals 31-33 of the existing main breaker 3. There is no need to separately prepare a member for connecting the contacts 121 to 123.

  Further, the interphase coupler 1 of the present embodiment presses the contacts 121 to 123 against the terminal screws 261, 271, 281 for connecting the load side terminals 31 to 33 of the main breaker 3 and the bus bars 26 to 28. Thus, the contacts 121 to 123 are electrically connected to the load side terminals 31 to 33 of the main breaker 3. Thereby, in the interphase coupler 1 of this embodiment, even if it is the existing distribution board 2, the electrical connection of the interphase coupler 1 and an electric circuit can be performed reliably.

  In the interphase coupler 1 of the present embodiment, a communication signal between the L1 phase voltage line (first voltage line) and the neutral line is transmitted between the L2 phase voltage line (second voltage line) and the neutral line. At the same time, the signal can be transmitted between the L1-phase voltage line and the L2-phase voltage line.

  Further, the interphase coupler 1 of the present embodiment includes a fuse 161 between the first contact 121 and the communication relay unit 13, and includes a fuse 162 between the second contact 122 and the communication relay unit 13. As a result, even if the interphase coupler 1 fails in the short mode, it is possible to make it difficult for overcurrent to flow through the interphase coupler 1, so that the main breaker 3 can be prevented from being interrupted.

  Further, in the interphase coupler 1 of the present embodiment, the indicators 171 and 172 are connected in series to the fuses 161 and 162. Thereby, in the interphase coupler 1 of the present embodiment, the user can confirm whether or not the fuses 161 and 162 are disconnected by the display units 171 and 172, so that the communication performance is deteriorated due to the failure of the interphase coupler 1 In addition, the problem location can be easily identified.

  Since the interphase coupler 1 of this embodiment is installed on the load side (secondary side) of the main breaker 3, there is a distributed power source (not shown) even when the main breaker 3 is cut off. The power line carrier communication can be continuously performed.

  As a modification of the interphase coupler 1 of the present embodiment, each of the plurality of contacts 121 to 123 is electrically connected to the load side terminals 31 to 33 so as to be fixed by terminal screws 261, 271, 281. It may be connected. The terminal screws 261, 271, 281 are screws for connecting the bus bars 26 to 28 and the load side terminals 31 to 33 of the main breaker 3.

  In the interphase coupler 1 of this modification, the contacts 121 to 123 are fixed by using terminal screws 261, 271, 281 for connecting the load side terminals 31 to 33 of the main breaker 3 and the bus bars 26 to 28. Thereby, in the interphase coupler 1 of this modification, even if it is the existing distribution board 2, the electrical connection and fixation of the interphase coupler 1 and an electric circuit can be performed reliably.

(Embodiment 2)
The interphase coupler 1 according to the second embodiment includes an external connection portion (connector) 6 for connecting an external device (not shown) as shown in FIG. 1 (see FIG. 4). In addition, about the component similar to the heterophasic coupler 1 of Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 7, the transformer 14 according to the present embodiment is a three-winding transformer including a first winding 141, a second winding 142, and a third winding 146. Note that description of functions similar to those of the transformer 14 (see FIG. 5) of the first embodiment is omitted.

  The interphase coupler 1 of this embodiment includes an external connection portion (connector) 6. The external connection unit 6 includes a first terminal unit 61 and a second terminal unit 62, and is provided so that an external device (not shown) is connected. The external connection unit 6 is electrically connected to the third winding 146 of the transformer 14. The external device connected to the external connection unit 6 is a device that inputs and outputs communication signals for power line carrier communication with respect to the communication relay unit 13.

  The interphase coupler 1 of the present embodiment described above includes the external connection unit 6 to which an external device that inputs and outputs a communication signal for power line carrier communication is connected to the communication relay unit 13. Thereby, in the interphase coupler 1 of this embodiment, the input / output of the communication signal of the power line carrier communication from the external device connected to the external connection unit 6 to the communication relay unit 13 can be realized. As a result, if the external device has a relay function, stable power line carrier communication can be performed for all phases.

(Embodiment 3)
The interphase coupler 1 according to the third embodiment is different from the interphase coupler 1 according to the second embodiment in that the external connection unit 6 is an outlet for commercial power. In addition, about the component similar to the interphase coupler 1 of Embodiment 2, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  The external connection unit 6 of the present embodiment is a commercial power outlet. That is, the external connection portion 6 of the present embodiment is an outlet having a shape standardized for commercial power. Note that a description of the same functions as those of the external connection unit 6 of Embodiment 2 is omitted.

  As shown in FIG. 8, the communication relay unit 13 of the present embodiment includes a second impedance circuit 18 and a third impedance circuit 19.

  The second impedance circuit 18 is inserted between the connection part 12 and the external connection part 6. The second impedance circuit 18 has a characteristic that the impedance is high with respect to the communication frequency of the power line carrier communication and is low with respect to the commercial frequency of a commercial power supply (not shown). The second impedance circuit 18 includes an inductance 181. One end of the inductance 181 is connected between the third contact 123 and the third terminal 145 of the transformer 14, and the other end is connected between the third impedance circuit 19 and the second terminal portion 62 of the external connection portion 6. Connected between. Further, the capacitor 152 and the fuse 162 are short-circuited, and the fifth terminal 148 of the transformer 14 and the first terminal portion 61 of the external connection portion 6 are short-circuited. Via such a second impedance circuit 18, commercial power having a voltage of 100 V can be supplied from a single-phase three-wire wiring to an external device connected to the external connection unit 6. On the other hand, the second impedance circuit 18 cuts off the communication signal.

  Although not shown, one end of the inductance 181 is not between the third contact 123 and the third terminal 145 of the transformer 14 but between the first contact 121 and the first terminal 143 of the transformer 14. It may be connected. In this case, commercial power having a voltage of 200 V can be supplied from the single-phase three-wire wiring to the external device connected to the external connection unit 6.

  The third impedance circuit 19 is inserted in series with the third winding 146 of the transformer 14. The third impedance circuit 19 has a characteristic of having a high impedance with respect to a commercial frequency of a commercial power supply (not shown) and a low impedance with respect to a communication frequency of power line carrier communication. The third impedance circuit 19 includes a capacitor 191. With such a third impedance circuit 19, the commercial power from the second impedance circuit 18 can be supplied to the external device without flowing through the third impedance circuit 19. On the other hand, since the third impedance circuit 19 passes the communication signal, the communication signal is transmitted to the third winding 146 side of the transformer 14.

  In the interphase coupler 1 of the present embodiment described above, commercial power can be supplied from the connection unit 12 (electric circuit) to the external device via the second impedance circuit 18. Further, in the interphase coupler 1 of the present embodiment, communication signals can be input and output between the external device and the communication relay unit 13 via the third impedance circuit 19. Thereby, for example, when the external device is a power line carrier modem, it is possible to supply commercial power to the power line carrier modem via the interphase coupler 1 only by connecting the power line carrier modem to the external connection unit 6. Communication signals can be input and output by the power line carrier modem. As a result, if it is necessary to install a power line carrying modem after installing the interphase coupler 1 on the distribution board 2, it is not necessary to carry out electrical work and only connect the power line carrying modem to the external connection unit 6. The power line carrier modem can be operated.

DESCRIPTION OF SYMBOLS 1 Interphase coupler 12 Connection part 121 1st contact 122 2nd contact 123 3rd contact 13 Communication relay part 14 Transformer 141 1st coil | winding 142 2nd coil | winding 146 3rd coil | winding 15 1st Impedance circuit 161, 162 Fuse 171, 172 Indicator 18 Second impedance circuit 19 Third impedance circuit 2 Distribution board 26, 27, 28 Bus bar 261, 271, 281 Terminal screw 3 Main breaker 31, 32, 33 Load Side terminal 4 Branch breaker 6 External connection

Claims (10)

An interphase coupler installed in a distribution board,
A communication relay unit that relays between the devices so that the devices connected between the different phases of the single-phase three-wire commercial power supply perform power line carrier communication;
A connection unit for electrically connecting the electric circuit to which the device is connected and the communication relay unit;
The overall shape including the communication relay unit and the connection unit is a shape arranged between the main breaker and the branch breaker in the distribution board,
The connecting portion seen including a plurality of contacts which are connected in one-to-one correspondence with the plurality of paths between the branch breakers and the main breaker,
The plurality of contacts are electrically connected to the plurality of load side terminals of the main breaker in a one-to-one correspondence,
Each of the plurality of contacts is pressed against a terminal screw for connecting the bus bar to which the branch breaker is connected in the distribution board and the load side terminal, and is electrically connected to the load side terminal. An interphase coupler, characterized in that it is connected to .   The communication frequency of the power line carrier communication is higher than the commercial frequency of the commercial power source,
  The plurality of contacts are
  A first contact connected to the first voltage line;
  A second contact connected to the second voltage line;
  A third contact connected to the neutral wire,
  The communication relay unit is
  A first winding inserted between the first contact and the third contact; and a second winding inserted between the second contact and the third contact. Including a transformer,
  A first impedance circuit that is inserted between the connecting portion and the transformer and has a characteristic of having a high impedance with respect to the commercial frequency and a low impedance with respect to the communication frequency.
  The heterophasic coupler according to claim 1.   The transformer is a three-winding transformer including the first winding, the second winding, and a third winding;
  An external connection unit connected to the third winding and connected to an external device that inputs and outputs a communication signal of the power line carrier communication to the communication relay unit is further provided.
  The heterophasic coupler according to claim 2.   The external connection part is an outlet for the commercial power supply,
  The communication relay unit is
  A second impedance circuit inserted between the connection portion and the external connection portion, having a characteristic of having a high impedance with respect to the communication frequency and a low impedance with respect to the commercial frequency;
  A third impedance circuit that is inserted in series with the third winding and has a characteristic of having a high impedance with respect to the commercial frequency and a low impedance with respect to the communication frequency.
  The heterophasic coupler according to claim 3. An interphase coupler installed in a distribution board,
A communication relay unit that relays between the devices so that the devices connected between the different phases of the single-phase three-wire commercial power supply perform power line carrier communication;
A connection unit for electrically connecting the electric circuit to which the device is connected and the communication relay unit;
The overall shape including the communication relay unit and the connection unit is a shape arranged between the main breaker and the branch breaker in the distribution board,
The connecting portion includes a plurality of contacts connected in a one-to-one correspondence to a plurality of electrical paths between the main breaker and the branch breaker,
The communication frequency of the power line carrier communication is higher than the commercial frequency of the commercial power source,
The plurality of contacts are
A first contact connected to the first voltage line;
A second contact connected to the second voltage line;
A third contact connected to the neutral wire,
The communication relay unit is
A first winding inserted between the first contact and the third contact; and a second winding inserted between the second contact and the third contact. Including a transformer,
Wherein the connecting portion is inserted between the transformer becomes a high impedance to the commercial frequency, viewing including a first impedance circuit having a characteristic as a low impedance to the communication frequency,
The transformer is a three-winding transformer including the first winding, the second winding, and a third winding;
An external connection unit connected to the third winding and connected to an external device that inputs and outputs a communication signal of the power line carrier communication to the communication relay unit;
The external connection part is an outlet for the commercial power supply,
The communication relay unit is
A second impedance circuit inserted between the connection portion and the external connection portion, having a characteristic of having a high impedance with respect to the communication frequency and a low impedance with respect to the commercial frequency;
Is inserted in series with the third winding, the impedance becomes high with respect to the commercial frequency, further comprising a third impedance circuit having a characteristic as a low impedance to the communication frequency different phase-to-phase coupler.   6. The interphase coupler according to claim 5, wherein the plurality of contacts are electrically connected to the plurality of load side terminals of the main breaker in a one-to-one correspondence.   Each of the plurality of contacts is electrically connected to the load side terminal so as to be fixed by a terminal screw for connecting the bus bar to which the branch breaker is connected and the load side terminal in the distribution board. The interphase coupler according to claim 6, wherein the interphase coupler is connected to.   The interphase coupler according to claim 1, further comprising a fuse between the connection unit and the communication relay unit.   The interphase coupler according to claim 8, further comprising a display connected in series to the fuse.   The distribution board according to claim 1, wherein the interphase coupler according to claim 1 is installed in a space between the main breaker and the branch breaker.

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