JP2018056850A - Communication system, termination device, and communication subsystem - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication system, a termination device, and a communication subsystem that can improve reliability of power line communication.SOLUTION: A communication system 1 comprises a plurality of power line communication devices 3 and two termination devices 2. The plurality of power line communication device 3 superimpose a communication signal S1 on AC power supplied to a pair of power lines 9. The two termination devices 2 terminate a transmission channel of a communication signal S1 in the pair of power lines 9. The plurality of power line communication device 3 are placed along the pair of power lines 9 between the two termination devices 2. The two termination devices 2 make impedance between the pair of power lines 9 in a frequency band of a communication signal S1 to be smaller than the impedance between the pair of power lines 9 in a frequency of AC voltage V1 applied to the pair of power lines 9.SELECTED DRAWING: Figure 1

Description

  The present invention generally relates to communication systems, termination devices, and communication subsystems. More particularly, the present invention relates to a communication system for performing power line communication, a termination device attached to a power line used for power line communication, and a communication subsystem used for a communication system for performing power line communication.

  2. Description of the Related Art Conventionally, a power line carrier communication device that communicates between power line carrier devices using a power line as a communication path is known (see, for example, Patent Document 1). The power line carrier communication device described in Patent Literature 1 includes a communication signal line, an electromagnetic coupler attached with the communication signal line and the power line penetrating, and a power line forward path on the opposite side of the power line carrier device. And a metal material connected to each other to cover the return path. The metal material is attached to the power line so as to cover the entire circumference of a part of the power line. By attaching the metal material, the capacitance between the conductor portion of the power line and the metal material is increased, so that the capacitance between the forward path and the return path of the power line is increased. The metal material increases the capacitance between the power line forward path and the return path covered by the metal material, and the power line forward path with respect to the high-frequency signal of the communication signal output from the power line carrier communication device to the communication signal line The impedance between the return path is reduced.

JP 2009-194782 A

  In the power line carrier communication device described in Patent Document 1, the capacitance between the forward path and the return path of the power line is, for example, the distance between the conductor of the power line and the metal material, the dielectric constant of the insulating portion covering the conductor, and the conductor It is determined by the area of the metal material covering. For example, the thickness of the insulating part of the power line may be different for each part of the power line, and the dielectric constant of the insulating part may be different for each part of the power line. In that case, when the metal material is attached to the power line from above the insulating portion of the power line, the capacitance between the portion covered with the metal material and the power line conductor does not become a predetermined size, and the communication signal There is a possibility that the impedance between the pair of power lines for the high-frequency signal does not become a predetermined value. In power line communication, the greater the impedance between power lines with respect to the high frequency signal of the communication signal, the more difficult it is to superimpose the communication signal on the AC power supplied to the power line, and the reliability of power line communication tends to decrease.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a communication system, a terminal device, and a communication subsystem that can improve the reliability of power line communication.

  A communication system according to an aspect of the present invention includes a plurality of power line communication devices and two termination devices. The plurality of power line communication devices superimpose communication signals on AC power supplied to a pair of power lines. The two termination devices terminate the transmission path of the communication signal in the pair of power lines. Each of the plurality of power line communication devices has a pair of cores respectively corresponding to the pair of power lines, and a signal line passing through a through hole provided in each of the pair of cores. Each of the plurality of power line communication devices includes a first function for transmitting the communication signal via the signal line, and the communication signal transmitted by another power line communication device among the plurality of power line communication devices. And a second function of receiving via the line. Between the two termination devices, the plurality of power line communication devices are arranged along the pair of power lines. The two termination devices are configured to make an impedance between the pair of power lines in a frequency band of the communication signal smaller than an impedance between the pair of power lines at a frequency of an alternating voltage applied to the pair of power lines. Has been.

  A termination device according to an aspect of the present invention is used as the termination device in the communication system described above.

  A communication subsystem according to an aspect of the present invention includes at least one power line communication device of the two power line communication devices described above and the termination device described above.

  The communication system, termination device, and communication subsystem of the present invention can improve the reliability of power line communication.

FIG. 1 is an explanatory diagram of a communication system according to Embodiment 1 of the present invention. FIG. 2 is an explanatory diagram of a main part in the communication system according to the first modification of the first embodiment of the present invention. FIG. 3 is an explanatory diagram of a main part in the communication system according to the second modification of the first embodiment of the present invention. FIG. 4A is a perspective view of a termination device in a communication system according to Modification 3 of Embodiment 1 of the present invention. FIG. 4B is a perspective view of a termination device connected to an outlet in the communication system according to Modification 4 of Embodiment 1 of the present invention. FIG. 5 is an explanatory diagram of a communication system according to Embodiment 2 of the present invention. FIG. 6 is an explanatory diagram of a main part in a communication system according to a modification of the second embodiment of the present invention.

  Hereinafter, a communication system, a termination device, and a communication subsystem according to an embodiment of the present invention will be described. However, Embodiments 1 and 2 described below (including modifications) are merely one of various embodiments of the present invention. The following embodiment can be variously modified according to the design or the like as long as the object of the present invention can be achieved.

(Embodiment 1)
(1) Outline of Communication System A communication system 1 according to this embodiment will be described. As illustrated in FIG. 1, the communication system 1 includes a plurality (here, two) of power line communication devices 3 and two termination devices 2. The plurality of power line communication devices 3 are, for example, modems for performing power line communication. The communication system 1 is a communication system in which a plurality of power line communication devices 3 perform power line communication with each other via a pair of power lines 9. Between the two termination devices 2, a plurality of power line communication devices 3 are arranged along a pair of power lines 9.

  The two termination devices 2 have the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 transmitted and received by the power line communication device 3 between the pair of power lines 9 at the frequency of the AC voltage V1 applied to the pair of power lines 9. The impedance should be smaller than. The "frequency band of communication signal S1" here means the frequency band of the carrier of communication signal S1. The two termination devices 2 terminate the transmission path of the communication signal S1 in the pair of power lines 9 to form a closed loop transmission path. The two termination devices 2 make the impedance of the transmission line smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V <b> 1 applied to the pair of power lines 9.

  The communication system 1 is used in a customer facility that includes a power source, a first distribution board 101, and a second distribution board 102 (distribution panel). The customer facility is an office building as an example, but may be a building such as a commercial facility, a factory, or a hospital.

  The power source is, for example, a high-voltage power receiving facility including a cubicle. The power source is installed, for example, on the roof of a customer facility or in an electrical room. The power supply is provided with a transformer (transformer), which transforms an AC voltage of 6600 [V] supplied from the power plant via the substation into an AC voltage of 200 [V] (or 100 [V]) ( Step down). As an example, the AC voltage distribution method is a single-phase three-wire distribution method.

  The first distribution board 101 and the second distribution board 102 are electrically connected by a pair of power lines 9. An L1 phase AC voltage is applied to one power line 9 and the N phase power line of the pair of power lines 9. An L2 phase AC voltage is applied to the other power line 9 and the N phase power line of the pair of power lines 9. An AC voltage V1 having an amplitude twice that of the L1 phase AC voltage is applied between the pair of power lines 9, for example. The frequency of the AC voltage V1 is a commercial power supply frequency, for example, 50 [Hz] or 60 [Hz]. In the following description, the description of the N-phase power line is omitted, and the description of the electrical connection relationship for the N-phase power line is also omitted.

  The first distribution board 101 includes a main breaker and a plurality of branch breakers (not shown). Three input terminals on the primary side of the first distribution board 101 are electrically connected to a power source. A pair of power lines 9 is connected to a pair of output terminals among the three output terminals on the secondary side of the branch breaker in the first distribution board 101.

  The second distribution board 102 includes a cabinet 103 and a distribution board internal unit. The cabinet 103 has a main body attached to a construction material such as a wall, and a lid that covers the main body from the side opposite to the wall. The cabinet 103 is formed of a material having electrical insulation. The internal device for distribution boards is arranged inside the main body of the cabinet 103 and the lid portion. The distribution board internal unit is, for example, a main breaker 110 (circuit breaker) and a plurality of branch breakers 120 (however, only one branch breaker 120 is shown in FIG. 1). That is, the second distribution board 102 includes a main breaker 110 and a plurality of branch breakers 120. The main breaker 110 has three primary terminals and three secondary terminals. Hereinafter, of the three primary terminals, two primary terminals to which the pair of power lines 9 are connected are referred to as “a pair of primary terminals 111”. Of the three secondary terminals, the two secondary terminals respectively corresponding to the pair of primary terminals 111 are referred to as “a pair of secondary terminals 112”. The pair of secondary terminals 112 are electrically connected to the pair of power lines 9.

  One end of each of the pair of power lines 9 is connected to a pair of primary terminals 111 of the main breaker 110. The other end of each of the pair of power lines 9 is connected to a pair of output ends on the secondary side of the branch breaker in the first distribution board 101. A plurality of loads 300 (only one load 300 is shown in FIG. 1) are electrically connected to the pair of secondary terminals 112 of the main breaker 110 via each of the plurality of branch breakers 120. The main breaker 110 is, for example, an earth leakage breaker, and can be switched between a state in which the pair of primary side terminals 111 and the pair of secondary side terminals 112 are electrically connected to each other and a state in which they are disconnected. That is, the main breaker 110 is configured to be switched between a state in which AC power is supplied to the plurality of branch breakers 120 and a state in which the supply is stopped.

  Each of the plurality of branch breakers 120 is, for example, an overcurrent circuit breaker. Each of the plurality of branch breakers 120 is configured to be switched between a state in which AC power is supplied to a load 300 electrically connected to a pair of output ends and a state in which the supply is stopped.

  The power supply supplies an alternating voltage V1 and an alternating current I1 to the pair of power lines 9 via the first distribution board 101. One of the pair of power lines 9 is electrically connected to the output terminal of the L1 phase of the branch breaker in the first distribution board 101, and the other power line 9 is connected to the branch breaker in the first distribution board 101. It is electrically connected to the output terminal of the L2 phase.

(2) Details (2.1) Power Line Communication Device Each of the plurality of power line communication devices 3 includes a pair of cores 4 and a signal line 6 respectively corresponding to the pair of power lines 9. Each of the pair of cores 4 is provided with a circular through hole 41 at the center, and the signal line 6 is passed through the through hole 41. The pair of cores 4 and the signal line 6 constitute a coupler 5. The signal line 6 is electrically connected to the corresponding power line communication device 3.

  The pair of cores 4 in the coupler 5 is formed in an annular shape from a magnetic material such as ferrite. One of the pair of power lines 9 (L1 phase) is passed through the through hole 41 of one of the pair of cores 4. The other (L2 phase) power line 9 of the pair of power lines 9 is passed through the through hole 41 of the other core 4 of the pair of cores 4. The signal line 6 is passed through the through holes 41 of both the cores 4. The coupler 5 superimposes the communication signal S1 output from the power line communication device 3 to the signal line 6 on the AC power supplied from the power source to the pair of power lines 9. The coupler 5 is an inductive coupling type coupler using a pair of cores 4.

  The power line communication device 3 has a first function of transmitting the communication signal S1 through the signal line 6. When the power line communication device 3 outputs the communication signal S <b> 1 to the signal line 6, a magnetic flux is generated in each core 4 when the communication signal S <b> 1 passes through each core 4 of the coupler 5. The communication signal S1 is superimposed on the alternating current I1 flowing through the power line 9 by the magnetic flux generated in each core 4. Therefore, the communication signal S <b> 1 is superimposed on the AC power supplied to the pair of power lines 9. In short, the first function of the power line communication device 3 is a function of superimposing the communication signal S1 on the AC power supplied to the power line 9.

  In addition, the power line communication device 3 has a second function of receiving the communication signal S <b> 1 transmitted from the other power line communication device 3 among the plurality of power line communication devices 3 via the signal line 6. Magnetic flux is generated in each core 4 when the communication signal S1 superimposed on the alternating current I1 passes through each core 4 of the coupler 5. The communication signal S1 is superimposed on the alternating current I1 flowing through the power line 9 by the magnetic flux generated in each core 4. The power line communication device 3 can receive the communication signal S <b> 1 via the signal line 6. In short, the second function of the power line communication device 3 is a function of receiving the communication signal S1 superimposed on the AC power supplied to the power line 9.

  Hereinafter, when each of the two power line communication devices 3 is distinguished, they are referred to as power line communication devices 31 and 32. When distinguishing each of the two couplers 5, they are called couplers 51 and 52. The signal line 6 included in the coupler 51 is also referred to as a signal line 61, and the signal line 6 included in the coupler 52 is also referred to as a signal line 62. The power line communication devices 31 and 32 can perform power line communication with each other via the pair of power lines 9 by the first function and the second function.

  A signal line 61 is electrically connected to the power line communication device 31. The power line communication device 31 is configured to be able to output the communication signal S1 to the signal line 61 by changing the magnitude of the current output to the signal line 61. For example, the power line communication device 31 outputs a communication signal S <b> 1 having an amplitude modulation carrier frequency of about 2 [MHz] to 30 [MHz] to the signal line 6. The frequency band of the communication signal S1 is, for example, a frequency band including 2 [MHz] to 30 [MHz]. The minimum frequency in the frequency band of the communication signal S1 is a frequency higher than the frequency of the AC voltage V1. The frequency band of the communication signal S1 described above is an example, and the frequency band of the communication signal S1 is not limited to the above frequency band.

  When the power line communication device 31 outputs the communication signal S1 to the signal line 61, a magnetic flux is generated in each core 4 by the communication signal S1. The power line communication device 31 superimposes the communication signal S1 on the AC power supplied to the pair of power lines 9 by outputting the communication signal S1 to the signal line 61 and changing the magnetic flux of each core 4 in the coupler 51.

  A signal line 62 is electrically connected to the power line communication device 32. When the communication signal S1 superimposed on the alternating current I1 passes through each core 4 of the coupler 52 in the power line communication device 32, a magnetic flux is generated in each core 4, and the communication signal S1 is output to the signal line 62 by the magnetic flux. The The power line communication device 32 receives the communication signal S1 output to the signal line 62.

  By the way, the frequency of the alternating current I1 is a commercial power supply frequency, for example, 50 [Hz] or 60 [Hz]. Since the alternating current I1 and the communication signal S1 are alternating signals, the directions of the alternating current I1 and the communication signal S1 illustrated in FIG. 1 are examples. In the above description, the power line communication device 31 transmits the communication signal S1 to the power line communication device 32. Conversely, the power line communication device 32 may transmit the communication signal S1 to the power line communication device 31. Is possible. In that case, the power line communication device 31, the signal line 61, and the coupler 51 may be read as the power line communication device 32, the signal line 62, and the coupler 52, respectively.

(2.2) Termination Device Each of the two termination devices 2 has a pair of connection ends 200 and a capacitor 7. The capacitor 7 is electrically connected between the pair of connection ends 200. Each of the two termination devices 2 is attached to the pair of power lines 9 in a state where the pair of connection ends 200 are electrically connected to the pair of power lines 9, respectively.

  Capacitor 7 has frequency characteristics such that the impedance between the pair of power lines 9 in the frequency band of communication signal S1 is relatively smaller than the impedance between the pair of power lines 9 at the frequency of AC voltage V1. Therefore, the termination device 2 makes the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1. In other words, the two termination devices 2 terminate the transmission path of the communication signal S1 in the pair of power lines 9. As a result, the transmission path of the communication signal S1 is a closed-loop transmission path including the two termination devices 2 and the pair of power lines 9. In the transmission line, since the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 is smaller than the impedance between the pair of power lines 9 in the frequency of the AC voltage V1, the communication signal S1 is easily superimposed on the transmission line. Become.

  Each of the two termination devices 2 further includes a voltage limiting unit 71. Both ends of the voltage limiting unit 71 are electrically connected to the pair of connection ends 200, respectively. The voltage limiting unit 71 is composed of, for example, a varistor. For example, when a surge voltage exceeding a predetermined voltage is applied between the pair of power lines 9 due to a lightning strike or the like, the voltage limiting unit 71 becomes conductive and causes the surge current to flow, whereby a voltage exceeding the predetermined voltage is applied to the capacitor 7. It suppresses that. In other words, when a surge voltage exceeding a predetermined voltage is applied between the pair of power lines 9, the voltage limiting unit 71 limits the voltage between the pair of power lines 9 to a predetermined voltage or less.

  One of the two termination devices 2 is electrically connected to a pair of power lines 9 between the first distribution board 101 and the coupler 51 of the power line communication device 31. The other of the two termination devices 2 is electrically connected to a pair of power lines 9 between the second distribution board 102 and the coupler 52 of the power line communication device 32. Therefore, a plurality of power line communication devices 3 are disposed between the two termination devices 2 along the pair of power lines 9. The two termination devices and the pair of power lines 9 form a closed loop transmission path through which an alternating current serving as a carrier of the communication signal S1 flows through each core 4 of the plurality of power line communication devices 32.

(2.3) Communication Subsystem The communication subsystem 10 according to this embodiment includes one power line communication device 3 and one termination device 2. In the communication system 1 of the present embodiment, two communication subsystems 10 are provided.

  In the communication system 1 of the present embodiment, one of the two communication subsystems 10 includes a power line communication device 31 and a termination on the side closer to the first distribution board 101 of the two termination devices 2. The apparatus 2 is provided. The other communication subsystem 10 of the two communication subsystems 10 includes a power line communication device 32 and the termination device 2 on the side close to the second distribution board 102 of the two termination devices 2.

(3) Effect of Termination Device The two termination devices 2 make the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1. As a result, the alternating current serving as the carrier of the communication signal S1 superimposed on the alternating current I1 is likely to flow between the pair of power lines 9 via the two termination devices 2. In other words, the two termination devices 2 transmit the communication signal S1 superimposed on the AC power between the pair of power lines 9. Therefore, the alternating current serving as the carrier of the communication signal S1 is relatively easy to flow through the closed-loop transmission path including the two termination devices 2 and the pair of power lines 9, so that the attenuation of the communication signal S1 is reduced. In other words, since the two termination devices 2 are electrically connected to the pair of power lines 9, a closed-loop transmission path having a smaller impedance is formed in the frequency band of the communication signal S1, and thus the attenuation of the communication signal S1. Is reduced. As a result, the signal loss of the communication signal S1 is reduced. Therefore, it is possible to improve the reliability of the power line communication when the plurality of power line communication devices 3 transmit / receive the communication signal S1 to each other through the power line communication.

(4) Summary As described above, the communication system 1 according to the present embodiment includes the plurality of power line communication devices 3 and the two termination devices 2. The plurality of power line communication devices 3 superimpose the communication signal S <b> 1 on the AC power supplied to the pair of power lines 9. The two termination devices 2 terminate the transmission path of the communication signal S1 in the pair of power lines 9. Each of the plurality of power line communication devices 3 includes a pair of cores 4 corresponding to the pair of power lines 9 and a signal line 6 passing through a through hole 41 provided in each of the pair of cores 4. Each of the plurality of power line communication devices 3 receives a first function for transmitting the communication signal S1 via the signal line 6 and a communication signal S1 transmitted by another power line communication device 3 among the plurality of power line communication devices 3. And a second function of receiving via line 6. Between the two termination devices 2, a plurality of power line communication devices 3 are arranged along a pair of power lines 9. The two termination devices 2 are set so that the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 is smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1 applied to the pair of power lines 9. It is configured.

  According to the above configuration, the two termination devices 2 can make the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 smaller than the impedance at the frequency of the AC voltage V1. The two termination devices 2 can suppress the attenuation of the communication signal S1 by terminating the transmission path of the communication signal S1 in the pair of power lines 9 and reducing the impedance of the transmission path of the communication signal S1. Therefore, the communication system 1 can improve the reliability of power line communication.

  In the communication system 1 of the present embodiment, each of the two termination devices 2 preferably includes a capacitor 7 that is electrically connected between a pair of power lines 9. Thereby, the termination device 2 makes the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1 applied to the pair of power lines 9. Can be realized by using the capacitor 7.

  By the way, each of the two termination devices 2 is not limited to having the capacitor 7. Each of the two termination devices 2 includes an appropriate electronic circuit in which the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 is smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1. Also good. Each of the two termination devices 2 may include an electronic circuit connected in series with the capacitor 7, or may include an electronic circuit instead of the capacitor 7.

  In the communication system 1 of the present embodiment, each of the two termination devices 2 limits the voltage between the pair of power lines 9 to a predetermined voltage or less when a surge voltage exceeding a predetermined voltage is applied between the pair of power lines 9. It is preferable that a voltage limiting unit 71 is provided. Thereby, even if a surge voltage exceeding a predetermined voltage is applied between the pair of power lines 9 due to a lightning strike or the like, the voltage limiting unit 71 limits the voltage between the pair of power lines 9 to a predetermined voltage or less. Therefore, the voltage limiting unit 71 can suppress a surge voltage exceeding a predetermined voltage from being applied to the capacitor 7 (or an appropriate electronic circuit or the like) connected to the pair of power lines 9. In addition, the voltage limiting unit 71 can suppress the occurrence of dielectric breakdown between the pair of power lines 9 when a surge voltage exceeding a predetermined voltage is applied between the pair of power lines 9 due to a lightning strike or the like. In addition, the voltage limiting unit 71 can suppress a surge voltage exceeding a predetermined voltage from being applied to the first distribution board 101 and the second distribution board 102.

  The termination device 2 of this embodiment is used as a termination device in the communication system 1 described above. Thereby, the termination device 2 can improve the reliability of power line communication.

  The communication subsystem 10 according to the present embodiment includes at least one power line communication device 3 out of the two power line communication devices 3 described above and the termination device 2 described above. Thereby, the communication subsystem 10 can improve the reliability of power line communication.

  By the way, the communication system 1 may include three or more power line communication devices 3. For example, the communication system 1 may include another power line communication device 3 between two communication subsystems 10 arranged along a pair of power lines 9.

  The communication system 1 is not limited to performing power line communication via a pair of power lines 9 that electrically connect the first distribution board 101 and the second distribution board 102. Two devices may be electrically connected. In that case, the plurality of power line communication devices 3 may be electrically connected to the pair of power lines 9 so as to be disposed between the two termination devices 2 along the pair of power lines 9. Further, the communication system 1 can be used even when AC power is supplied by a single-phase two-wire power distribution method.

(Modification 1 of Embodiment 1)
A communication system 1a according to the first modification of the first embodiment will be described with reference to FIG. 2, in the communication system 1a according to the first modification, the first distribution board 101 (see FIG. 1) and the two communication subsystems 10 (see FIG. 1) closer to the first distribution board 101. The communication subsystem 10 is not shown. In the communication system 1a according to the first modification of the first embodiment, the communication device of the first embodiment is that one of the two terminal devices 2 is provided on the second distribution board 102 (distribution board). Different from the system 1 configuration. Since the other configuration of the communication system 1a is the same as that of the communication system 1 of the first embodiment, the same reference numerals are given and description thereof is omitted.

  In the communication system 1a according to the first modification, one end of each of the pair of power lines 9 is connected to the second distribution board 102 (distribution board). One of the two termination devices 2 is provided in a main breaker 110 (distribution panel internal unit) disposed inside the cabinet 103 of the second distribution panel 102 (distribution panel). .

  In the communication system 1a according to the first modification, the distribution board internal unit includes a main breaker 110 (circuit breaker), and the termination device 2 is electrically connected to the main breaker 110 (circuit breaker). . More specifically, in the communication system 1a according to the first modification, one of the two termination devices 2 is connected to the main breaker 110 (circuit breaker) of the second distribution panel 102 (distribution panel). Built in.

  In the following description, one of the two termination devices 2 will be described. The terminal device 2 is accommodated in the main body of the main breaker 110. The termination device 2 is electrically connected between the pair of primary terminals 111 of the main breaker 110. A pair of power lines 9 are connected to the pair of primary terminals 111 of the main breaker 110, respectively. That is, the termination device 2 is electrically connected to the pair of power lines 9 via the pair of primary terminals 111 of the main breaker 110. For example, even when the main breaker 110 is turned off and the branch breaker 120 and the pair of power lines 9 are electrically disconnected, the termination device 2 is electrically connected to the pair of power lines 9. Therefore, even if the main breaker 110 is turned off, the termination device 2 is maintained in a state of being electrically connected to the pair of power lines 9.

  As described above, the terminating device 2 is provided in the main breaker 110 (distribution panel internal unit) disposed inside the cabinet 103 of the second distribution panel 102. As a result, the main breaker 110 is accommodated in the second distribution board 102 and connected to the pair of power lines 9, whereby the termination device 2 is accommodated in the cabinet 103 of the second distribution board 102, and the pair The power line 9 is electrically connected.

  The termination device 2 is preferably electrically connected to the main breaker 110 of the second distribution board 102. According to the above configuration, the trunk breaker 110 incorporating the termination device 2 is electrically connected to the pair of power lines 9, so that the termination device 2 is connected to the pair of power lines via the pair of primary terminals 111 of the trunk breaker 110. 9 is electrically connected. Therefore, the termination device 2 can be electrically connected to the pair of power lines 9 without attaching the termination device 2 to the pair of power lines 9.

  The termination device 2 is preferably built in the main breaker 110 of the second distribution board 102. As a result, even if the space for accommodating the termination device 2 is not secured in the second distribution board 102, the termination device 2 is accommodated in the second distribution board 102 by accommodating the main breaker 110 in the second distribution board 102. It is stored in the cabinet 103 of the board 102.

  By the way, the termination device 2 is not limited to being electrically connected to the pair of primary terminals 111 of the main breaker 110 but may be electrically connected to the pair of secondary terminals 112 of the main breaker 110. . As a result, the termination device 2 can be connected to the pair of secondary terminals 112 of the main breaker 110 that has been turned off. The worker turns off the main breaker 110 and electrically connects the terminating device 2 to the pair of secondary terminals 112 in a state where power is not supplied to the pair of secondary terminals 112 of the main breaker 110. be able to.

  Moreover, although the case where the internal device for distribution boards was the master breaker 110 was demonstrated above, it is not limited to this example. The distribution board internal unit may be, for example, the branch breaker 120 or another distribution board for the second distribution board 102 that is electrically connected to the pair of secondary terminals 112 of the main breaker 110. It may be a board internal device.

  The second distribution board 102 may have a current limiting breaker that limits the maximum value of the alternating current I1 of the pair of power lines 9 to a predetermined current value or less as an internal device for the distribution board. The current limiting breaker is connected to, for example, a pair of power lines 9 and a main breaker 110. When the maximum value of the alternating current I1 reaches a predetermined current value, the pair of power lines 9 and the main breaker 110 are electrically connected. Shut off. Termination device 2 may be built in the current limiting breaker, or may be electrically connected to the pair of power lines 9 by being connected to the current limiting breaker.

(Modification 2 of Embodiment 1)
A communication system 1b according to the second modification of the first embodiment will be described with reference to FIG. In FIG. 3, in the communication system 1b according to the first modification, the first distribution board 101 (see FIG. 1) and the communication subsystem 10 on the first distribution board 101 side (see FIG. 1) are not shown. Yes.

  A communication system 1b according to Modification 2 includes the communication subsystem 10 according to the first embodiment and the communication subsystem 10b. The communication subsystem 10b includes a power line communication device 3 and a termination device 2a.

  In the communication system 1b according to the second modification of the first embodiment, one termination device 2a of the two termination devices 2 is provided inside the cabinet 103 of the second distribution board 102, but is connected to the main breaker 110. It is different from the configuration of the communication system 1a of the first modification in that it is not built in. Since the other configuration of the communication system 1b is the same as that of the communication system 1 of the first embodiment, the same reference numerals are given and description thereof is omitted.

  In the communication system 1b of the second modification, the main breaker 110 (circuit breaker) includes a pair of primary terminals 111 that are electrically connected to the pair of power lines 9 and a pair of secondary terminals 112. The termination device 2 a includes a pair of first terminals 201 electrically connected to the pair of secondary terminals 112, and a pair of second terminals 202 electrically connected to the pair of first terminals 201 and the load 300. And have. The termination device 2a is configured to be provided inside the cabinet 103 of the second distribution board 102 (distribution board). The pair of primary side terminals 111 and the pair of secondary side terminals 112 of the main breaker 110 are arranged inside the cabinet 103 of the second distribution board 102.

  The pair of input terminals of the branch breaker 120 are connected to the pair of second terminals 202 of the termination device 2a. A load 300 is electrically connected to the pair of output ends of the branch breaker 120. Therefore, the pair of secondary side terminals 112 of the main breaker 110 are electrically connected to the load 300 via the terminating device 2a and the branch breaker 120.

  The termination device 2a is electrically connected to the pair of secondary terminals 112 of the main breaker 110. The termination device 2a is electrically connected to the pair of power lines 9 in a state in which the main breaker 110 is electrically connected between the pair of primary terminals 111 and the pair of secondary terminals 112.

  According to the above configuration, the terminal device 2a is electrically connected to the pair of power lines 9 by electrically connecting the pair of first terminals 201 of the terminal device 2a and the pair of secondary terminals 112 of the main breaker 110. Connected. Since the pair of first terminals 201 and the pair of secondary terminals 112 are terminals with each other, contact reliability between the terminals is easily secured when the terminals are directly and electrically connected to each other. Therefore, the reliability of the electrical connection between the termination device 2a and the main breaker 110 is increased. Further, by connecting the termination device 2 a between the main breaker 110 and the branch breaker 120, the termination device 2 a can be electrically connected to the pair of power lines 9 in a state where the termination device 2 a is provided inside the cabinet 103. For example, even when a distribution board internal unit such as the main breaker 110 cannot incorporate the termination device 2 a, the termination device 2 a can be electrically connected to the pair of power lines 9 in a state where the termination device 2 a is provided inside the cabinet 103. is there.

  By the way, in the communication system 1b according to the second modification of the first embodiment, the termination device 2a may be provided outside the cabinet 103 of the second distribution board 102.

  In the communication system 1b according to the second modification, one end of each of the pair of power lines 9 is electrically connected to the main breaker 110 (circuit breaker) of the second distribution board 102 (distribution board). The termination device 2a has a pair of first terminals 201 electrically connected to the main breaker 110 (circuit breaker) and a pair of second terminals 202 electrically connected to the load 300. It may be provided outside the cabinet 103 of the distribution board 102 (distribution board).

  More specifically, the pair of first terminals 201 of the termination device 2a may be electrically connected to the pair of output ends of the branch breaker 120. Therefore, the termination device 2 a is electrically connected to the pair of power lines 9 via the branch breaker 120 and the main breaker 110. Further, the pair of second terminals 202 of the termination device 2 a may be electrically connected to the load 300. That is, the termination device 2 a can relay the power line connected to the output end of the branch breaker 120 and the power line connected to the load 300.

  According to the above configuration, even when the terminating device 2a is provided outside the cabinet 103 of the second distribution board 102 (distribution panel), it is electrically connected to the main breaker 110 (circuit breaker). Thus, it can be electrically connected to the pair of power lines 9. Thereby, even when the space for accommodating the termination device 2a cannot be secured in the cabinet 103 of the second distribution board 102, the termination device 2a can be electrically connected to the pair of power lines 9.

(Modification 3 of Embodiment 1)
A terminating device 2b of a communication system according to Modification 3 of Embodiment 1 will be described with reference to FIGS. 4A and 4B. 4A and 4B are perspective views of the termination device 2b.

  The communication system according to the third modification includes the communication subsystem 10 (see FIG. 1) according to the first embodiment and the communication subsystem including the power line communication device 3 (see FIG. 1) and the termination device 2b. The terminal device 2b is provided with a pair of conductive portions 21 instead of the pair of connection ends 200 in the terminal device 2 (see FIG. 1). In the communication system of Modification 3, one end of each of the pair of power lines 9 is electrically connected to the main breaker 110 (circuit breaker) (see FIG. 1) of the second distribution board 102 (distribution board) (see FIG. 1). Connected. In addition, since the other structure of the communication system which concerns on the modification 3 is the same as that of the communication system 1 of Embodiment 1, it attaches | subjects the same code | symbol and abbreviate | omits description.

  As shown in FIGS. 4A and 4B, the termination device 2b further includes a pair of conductive portions 21 (contacts) and a container 22 having electrical insulation. The container 22 of the termination | terminus device 2b is formed in the substantially rectangular parallelepiped shape as an example. The container 22 houses the capacitor 7 and the voltage limiting unit 71. The pair of conductive portions 21 protrude from one surface of the container body 22.

  The outlet 12 (outlet) is attached to a construction material such as a wall, for example. The outlet 12 has, for example, two pairs of insertion holes 13. A conductive member corresponding to each insertion hole 13 is provided inside the container of the outlet 12. Each conductive member is in contact with each conductive portion 21 of the termination device 2 b inserted into each insertion hole 13. The conductive member corresponding to the pair of insertion holes 13 of the outlet 12 is electrically connected to one output end of the pair of output ends of the branch breaker 120 via a power line. The conductive member corresponding to the other insertion hole 13 of the pair of insertion holes 13 of the outlet 12 is electrically connected to the other output end of the pair of output ends of the branch breaker 120 via the power line. The termination device 2 b can be detachably connected to the outlet 12 by inserting the pair of conductive portions 21 into the pair of insertion holes 13 of the outlet 12.

  In the communication system according to the third modification, the terminating device 2b is configured to be detachably connected to the outlet 12 that is electrically connected to the main breaker 110 (circuit breaker). The terminal device 2b is electrically connected to the main breaker 110 when the pair of conductive portions 21 of the terminal device 2b are inserted into the pair of insertion holes 13 of the outlet 12 and contact each conductive member.

  In short, the termination device 2b in the communication system according to the modification 3 is electrically connected to the pair of output ends of the branch breaker 120 of the second distribution board 102. According to the above configuration, when the termination device 2 b is connected to the outlet 12, the termination device 2 b can be electrically connected to the pair of power lines 9, so that the operator can easily connect the termination device 2 b to the pair of power lines 9. Can be electrically connected.

  By the way, in the communication system of the modification 3, the pair of conductive parts 21 of the termination device 2b may be omitted, and the termination device 2b may be built in the outlet 12.

  In the communication system of Modification 3, one end of each of the pair of power lines 9 may be electrically connected to the main breaker 110 (circuit breaker) of the second distribution board 102 (distribution board). The termination device 2b in the communication system according to the third modification may be incorporated in the outlet 12 that is electrically connected to the main breaker 110 (circuit breaker). In that case, the container 22 of the termination device 2b can be omitted.

  The terminal device 2b in the communication system of the modification 3 may be accommodated in the receptacle 12 receptacle, for example. For example, the termination device 2b may be electrically connected to the conductive member corresponding to the pair of insertion holes 13 of the outlet 12 in a state of being accommodated in the body of the outlet 12. The termination device 2b is electrically connected to the main breaker 110 via a pair of output ends of the branch breaker 120 (see FIG. 1). According to the above configuration, when the termination device 2b is built in the outlet 12, the termination device 2b is connected to the outside of the outlet 12 when the termination device 2b is electrically connected to the pair of power lines 9 via the outlet 12. Need not be provided.

  In the communication systems according to the first and second modifications of the first embodiment, the example in which the termination device is provided inside the cabinet 103 of the second distribution board 102 has been described. However, the present invention is not limited to this example. Of the two termination devices, the termination device closer to the first distribution board 101 is for the distribution board housed in the cabinet of the first distribution board 101 or in the cabinet of the first distribution board 101. It may be provided in the inner unit.

(Embodiment 2)
A communication system 1c according to the second embodiment will be described with reference to FIG. The communication system 1c includes two communication subsystems 10c including the power line communication device 3 and the termination device 2c in the communication system 1 of the first embodiment. In the communication system 1c, the configuration of the termination device 2c is different from the configuration of the termination device 2 in the communication system 1 of the first embodiment. Since the other configuration of the communication system 1c is the same as that of the communication system 1 of the first embodiment, the same reference numerals are given and description thereof is omitted.

  Each of the two termination devices 2 c includes a pair of cores 8 (another pair of cores) corresponding to the pair of power lines 9 and a conducting wire 82. The pair of cores 8 is formed in an annular shape from a magnetic material such as ferrite, for example. One of the pair of power lines 9 (L1 phase) is passed through the through hole 81 of one of the pair of cores 8. The other (L2 phase) power line 9 of the pair of power lines 9 is passed through the through hole 81 of the other core 8 of the pair of cores 8. A conducting wire 82 is passed through the through holes 81 of both the cores 8. The pair of cores 8 and a part of the conductive wire 82 are housed in, for example, an electrically insulating case in a state where the pair of power lines 9 are respectively passed through the through holes 81 of the pair of cores 8.

  Each of the two termination devices 2c functions as an inductively coupled coupler that transmits a communication signal S1 composed of an alternating current between the pair of power lines 9. For example, when the alternating current that transmits the communication signal S1 is superimposed on the alternating current I1 of the power line 9 of one (L1 phase) of the pair of power lines 9, the conductor 82 is connected via the core 8 of the pair of cores 8. Inductive current flows through. An induced magnetic field is generated in the other core 8 of the pair of cores 8 by the induced current of the conductive wire 82, and the alternating current I 1 of the other (L2 phase) power line 9 out of the pair of power lines 9 through the other core 8. Is superimposed with an alternating current for transmitting the communication signal S1. That is, each of the two termination devices 2c reduces the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 by magnetically coupling the pair of power lines 9 by an inductive coupling method. More specifically, the two termination devices 2c make the impedance between the pair of power lines 9 in the frequency band of the communication signal S1 smaller than the impedance between the pair of power lines 9 at the frequency of the AC voltage V1.

  As described above, in the communication system 1 according to the second embodiment, each of the two termination devices 2 c includes the pair of cores 8 (another pair of cores) and the conductive wire 82. The pair of cores 8 (another pair of cores) are a pair of cores 8 (another pair of cores) different from the pair of cores 4 included in each of the plurality of power line communication devices 3. Correspond. The conducting wire 82 passes through each through hole 81 of the pair of cores 8 (the other pair of cores). According to the above configuration, each of the two termination devices 2c magnetically couples the pair of power lines 9 with the pair of cores 8 and the conductive wires 82, thereby connecting the pair of power lines 9 in the frequency band of the communication signal S1. Impedance can be reduced. Thereby, it is possible to reduce the impedance between the pair of power lines 9 in the frequency band of the communication signal S <b> 1 without attaching the termination device 2 to the pair of power lines 9. Further, when each core 8 is a split type core, each core 8 may be arranged with respect to the pair of power lines 9 in a laid state, so that the labor of branching the pair of power lines 9 is saved. You can also

  By the way, when the termination device 2c magnetically couples the pair of power lines 9 by the inductive coupling method, the operator simply connects the termination device 2c to the pair of power lines 9 by passing the power line 9 and the conductive wire 82 through the through hole 81 of the core 8. Can be attached to. Therefore, the construction time for attaching the termination device 2c to the pair of power lines 9 is shortened. In particular, when each core 8 is a split-type core, the operator can easily attach each core 8 to the pair of power lines 9 in a laid state. Therefore, there is also an advantage that the operator does not need to stop the power supply to the pair of power lines 9 when attaching the termination device 2 c to the pair of power lines 9.

(Modification of Embodiment 2)
A communication system 1d according to a modification of the second embodiment will be described with reference to FIG. In FIG. 6, in the communication system 1d according to the modification, the first distribution board 101 (see FIG. 5) and the communication subsystem 10c on the first distribution board 101 side (see FIG. 5) are not shown. .

  The communication system 1d according to the modification further includes a housing 11 that houses a pair of cores 8 (another pair of cores). Since the other configuration of the communication system 1d is the same as that of the communication system 1c of the second embodiment, the same reference numerals are given and description thereof is omitted.

  The housing 11 is made of a synthetic resin material having electrical insulation, for example. The housing 11 is formed in a rectangular box shape, and houses a pair of cores 8 in the housing 11. The housing 11 further stores a conductive wire 82. The pair of cores 8 are attached to the pair of power lines 9 while being housed in the housing 11. According to the above configuration, in the communication system 1d according to the modification, the pair of cores 8 can be stored in the single casing 11, so that each of the pair of cores 8 is individually stored in the case. The number of parts required for attaching the pair of cores 8 to the pair of power lines 9 is reduced. Moreover, it is preferable that the housing | casing 11 can protect the conducting wire 82 by accommodating the conducting wire 82 inside.

  By the way, the housing | casing 11 may be comprised so that a pair of core 8, the conducting wire 82, a pair of core 4, and a part of signal wire | line 6 can be accommodated. According to the above configuration, the housing 11 can accommodate the pair of cores 8 and the conductive wires 82 and a part of the pair of cores 4 and the signal wires 6. Therefore, one housing 11 is sufficient as compared with the case where each of the pair of cores 8 and the conductive wires 82 and the pair of cores 4 and part of the signal wires 6 is individually housed in the case. The number of parts required for attaching the pair of cores 4 to the pair of power lines 9 is reduced.

  By the way, Embodiments 1 and 2 (however, a modification is included) can be combined suitably. For example, the inductively coupled termination device 2c in the communication system 1c of the second embodiment may be disposed inside the cabinet 103 of the second distribution board 102 (see FIG. 6), or the main breaker 110 (see FIG. 1). ) Or the like. Further, the inductive coupling type termination device 2c may be connected to a pair of output ends or a pair of input ends in a distribution board internal unit such as the branch breaker 120 (see FIG. 1). The inductive coupling type termination device 2c may be configured to be connected to the outlet 12 (see FIG. 4B).

1, 1a to 1d Communication system 10, 10b, 10c Communication subsystem 2, 2a to 2c Terminating device 3 Power line communication device 4 Core 41 Through hole 6 Signal line 7 Capacitor 71 Voltage limiter 8 Core 82 Conductor 9 Power line (a pair of power lines )
11 Housing 12 Outlet 102 Second distribution panel (distribution panel)
103 Cabinet 110 Main breaker (distribution panel internal unit, circuit breaker)
111 Primary side terminal 112 Secondary side terminal 201 First terminal 202 Second terminal 300 Load S1 Communication signal

Claims (14)

A plurality of power line communication devices that superimpose communication signals on AC power supplied to a pair of power lines;
Two termination devices for terminating the transmission path of the communication signal in the pair of power lines;
With
Each of the plurality of power line communication devices has a pair of cores respectively corresponding to the pair of power lines, and a signal line passing through a through hole provided in each of the pair of cores, A first function for transmitting the communication signal; and a second function for receiving the communication signal transmitted by another power line communication device among the plurality of power line communication devices via the signal line;
Between the two termination devices, the plurality of power line communication devices are disposed along the pair of power lines,
The two termination devices are configured to make an impedance between the pair of power lines in a frequency band of the communication signal smaller than an impedance between the pair of power lines at a frequency of an alternating voltage applied to the pair of power lines. A communication system characterized by that. The communication system according to claim 1, wherein each of the two termination devices includes a capacitor electrically connected between the pair of power lines. Each of the two termination devices includes a voltage limiting unit that limits a voltage between the pair of power lines to the predetermined voltage or less when a surge voltage exceeding a predetermined voltage is applied between the pair of power lines. The communication system according to claim 1 or 2. Each of the two termination devices is another pair of cores different from the pair of cores included in each of the plurality of power line communication devices, and the other pair of cores respectively corresponding to the pair of power lines, The communication system according to claim 1, further comprising: a conducting wire that passes through each through hole of the other pair of cores. The communication system according to claim 4, further comprising a housing that houses the other pair of cores. One end of each of the pair of power lines is connected to a distribution board,
5. The terminal device according to claim 1, wherein one of the two terminal devices is provided in an internal device for a distribution board arranged inside a cabinet of the distribution board. The communication system according to 1. The distribution board internal unit includes a circuit breaker,
The communication system according to claim 6, wherein the termination device is electrically connected to the circuit breaker. The communication system according to claim 7, wherein the termination device is built in a circuit breaker of the distribution board. The circuit breaker has a pair of primary terminals electrically connected to the pair of power lines, and a pair of secondary terminals,
The terminator has a pair of first terminals electrically connected to the pair of secondary terminals, and a pair of second terminals electrically connected to the pair of first terminals and a load. The communication system according to claim 7, wherein the communication system is configured to be provided inside the cabinet of the distribution board. One end of each of the pair of power lines is electrically connected to a circuit breaker of a distribution board,
The termination device has a pair of first terminals electrically connected to the circuit breaker, and a pair of second terminals electrically connected to the pair of first terminals and a load, The communication system according to any one of claims 1 to 4, wherein the communication system is configured to be provided outside a cabinet of a distribution board. One end of each of the pair of power lines is electrically connected to a circuit breaker of a distribution board,
The communication system according to any one of claims 1 to 4, wherein the termination device is configured to be detachably connected to an outlet electrically connected to the circuit breaker. One end of each of the pair of power lines is electrically connected to a circuit breaker of a distribution board,
The communication system according to any one of claims 1 to 4, wherein the termination device is built in an outlet that is electrically connected to the circuit breaker. It is used as the said termination | terminus apparatus for the communication system of any one of Claims 1-12. The termination | terminus apparatus characterized by the above-mentioned. At least one power line communication device of the two power line communication devices according to claim 1,
A termination device according to claim 13;
A communication subsystem characterized by comprising:

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