JP2008141602A - Power line communication entity connection structure, power line communication outlet and method of using power line communication device - Google Patents

Abstract

An object of the present invention is to enable communication with a master unit at a uniform signal level no matter which outlet is connected to a slave unit of a power line communication device.
A non-grounded electric circuit R and B in a distribution board 5 for indoor wiring supplied with a single-phase three-wire power supply is directly connected to one of the electric circuits and a capacitor to the other electric circuit. 25, the power input line 20R in the PLC modem 20 (master unit) is connected, the power input line 20W is connected to the ground side electric circuit W, and the electric circuit R, W in the distribution board 5 or PLC modems 22 and 23 (slave units) are connected to the electric paths B and W to perform power line communication.
[Selection] Figure 4

Description

  The present invention relates to an actual connection structure for power line communication (PLC), a power line communication outlet used therefor, and a method of using the power line communication apparatus.

  Power line communication is a communication method in which a data communication signal is superimposed on a commercial AC voltage (current) using a power line as a signal transmission line, and has an advantage that it is not necessary to newly perform communication wiring. There may be various forms of power line communication depending on the usage range of the power line. For example, in a detached house, it is possible to construct a system that combines FTTH (Fiber To The Home) and LAN (Local Area Network) by power line communication. (For example, refer to Patent Document 1).

  In this case, indoor wiring is mainly used as a signal transmission path for power line communication, and terminal devices such as personal computers and information home appliances are connected to a plurality of PLC modems (power line communication devices) connected to an outlet, respectively. Is configured. On the other hand, an optical fiber is drawn into the house and connected to the home LAN via a media converter (ONU) and a PLC modem. As a result, each terminal device can be connected to an external network such as the Internet.

  Power line communication is performed by, for example, an OFDM (Orthogonal Frequency Division Multiplexing) system, and signals having their waveforms inverted with respect to each other are transmitted to two electric circuits (two lines of indoor wiring) that carry signals. A received signal is obtained from the signal. If the signal level is high (if the signal attenuation is small), many bits can be allocated, and high-speed transmission is possible.

Japanese Patent Laying-Open No. 2005-150975 (FIG. 5)

  When indoor wiring is used as a signal transmission line for power line communication as described above, if the power drawn into the house is a single-phase two-wire, two common wires are connected to all outlets. The electric circuit used as the signal transmission line is always common. However, when the single-phase three-wire power supply is drawn into the distribution board for indoor wiring, the non-grounded electric circuit R (red) and electric circuit B (black) and the grounded electric circuit W (white) Exists. The outlet for 100V is connected to the electric circuits R, W or B, W, which is arbitrarily determined at the time of construction of the electric work. Therefore, which outlet is connected to which electric circuit is unknown unless the wiring is examined.

  When the PLC modem's master unit and slave unit are connected to two common lines, the signal attenuation of power line communication between both modems is small, but two different lines (R, W vs. B, W) When connected to, signal attenuation is large (10 to 20 dB). As a result, the degree of signal attenuation differs depending on which outlet the slave unit is connected to, and uniform communication quality (communication speed) cannot be obtained.

  In view of such a problem, an object of the present invention is to enable communication with a parent device at a uniform signal level regardless of which outlet is connected to the child device of the power line communication device.

  The actual connection structure of the power line communication of the present invention is the one of the first electric circuit and the second electric circuit in the single-phase three-wire power source composed of the first and second electric circuits on the non-ground side and the third electric circuit on the ground side. One power line communication apparatus in which one of the two power input lines is directly connected to the other electric circuit via a capacitor and the other of the power input lines is connected to the third electric circuit. And other power line communication devices connected to the first and third electric circuits or the second and third electric circuits.

  In the actual connection structure of the power line communication as described above, the capacitor does not pass the voltage / current of the commercial frequency but passes the high frequency signal of the power line communication, so that one power line communication device transmits the signal of the power line communication through all the electric paths. You can send and receive. Therefore, even if the connection electric circuit of the other power line communication device is any of the first, third electric circuit and the second, third electric circuit, the two electric circuits can be shared with one power line communication device. That is, one power line communication device can perform power line communication with a uniform signal level with other power line communication devices connected to either the first, third electric circuit, or the second, third electric circuit.

  In addition, the power line communication outlet of the present invention includes a non-ground side terminal portion for connecting any one of the first and second electric paths on the non-ground side in the single-phase three-wire power source, A ground side terminal portion for connecting a third electric circuit; and a capacitor having one end connected to the non-ground side terminal portion and the other end connected to the other electric circuit of the first and second electric circuits. Is.

  In the power line communication outlet as described above, the capacitor does not pass the voltage / current of the commercial frequency but allows the high frequency signal of the power line communication to pass. Therefore, by connecting the first, third and second electric circuits, or the second, third and first electric circuits to the non-ground side terminal part, the ground side terminal part and the other end of the capacitor, respectively, it is connected to the outlet. One power line communication apparatus can transmit and receive power line communication signals through all the electric paths. Therefore, even if the connection electric circuit of the other power line communication device is any of the first, third electric circuit and the second, third electric circuit, the two electric circuits can be shared with one power line communication device. That is, one power line communication device can perform power line communication with a uniform signal level with other power line communication devices connected to either the first, third electric circuit, or the second, third electric circuit.

  In addition, the power line communication device according to the present invention can be used in a single-phase three-wire power source composed of the first and second electric circuits on the non-ground side and the third electric circuit on the ground side, and one of the first electric circuit and the second electric circuit. Is directly connected to the other electric circuit through a capacitor and one of the two power input lines in the power line communication device is connected to the third electric circuit, and the other power input line is connected to the third electric circuit. Furthermore, power line communication is performed by connecting another power line communication device to the first, third electric circuit, or the second, third electric circuit.

  In the method of using the power line communication device as described above, the capacitor does not pass the voltage / current of the commercial frequency, but passes the high frequency signal of the power line communication, so that one power line communication device transmits the power line communication signal through all the electric paths. You can send and receive. Therefore, even if the connection electric circuit of the other power line communication device is any of the first, third electric circuit and the second, third electric circuit, the two electric circuits can be shared with one power line communication device. That is, one power line communication device can perform power line communication with a uniform signal level with other power line communication devices connected to either the first, third electric circuit, or the second, third electric circuit.

  According to the actual connection structure of the power line communication device of the present invention or the method of using the power line communication device of the present invention, one power line communication device can transmit and receive power line communication signals through all the electric paths. It is possible to communicate with one power line communication device with a uniform signal level regardless of the outlet connected to the device.

  Further, according to the power line communication outlet of the present invention, one power line communication apparatus connected to the outlet can transmit and receive power line communication signals through all the electric paths, so that another power line communication apparatus It is possible to communicate with one power line communication device with a uniform signal level no matter which outlet is connected.

  FIG. 1 is a connection diagram illustrating an actual connection structure of power line communication according to an embodiment of the present invention. In the figure, it is assumed that this detached house H includes, for example, four illustrated rooms 1, 2, 3, and 4. A distribution line 5 for indoor wiring provided in the room 1 is connected to a lead-in wire 6 from an outdoor wiring via a watt hour meter (not shown). Cables (VVF) 7 to 14 are drawn out from the distribution board 5 and serve as outlet wirings for the rooms 1 to 4. The cable 9 has 3 cores, and the other has 2 cores.

Specifically, the destinations of the cables 7 to 14 are as follows.
Cable 7: General-purpose outlet 401 provided below the wall surface of the room 4
Cable 8: General-purpose outlet 301 provided below the wall surface of the room 3
Cable 9: Dedicated outlet 302 provided above the wall surface of the room 3
Cable 10: A dedicated outlet 303 provided above the wall surface of the room 3
Cable 11: General-purpose outlet 101 provided below the wall surface of the room 1
Cable 12: A general-purpose outlet 201 provided below the wall surface of the room 2
Cable 13: Dedicated outlet 202 provided above the wall surface of the room 2
Cable 14: Dedicated outlet 102 provided on the wall of the room 1

  Here, the cables 9, 10, 13, 14 are “dedicated electric circuits” wired from the distribution board 5 to the dedicated outlets 302, 303, 202, 102 in a non-branching manner. The dedicated outlets 202 and 303 are typically used for air conditioners, and the dedicated outlet 102 is used, for example, for household electric appliances (microwave oven, dishwasher, electromagnetic cooker, etc.) with high power consumption. The location and number of outlets are only examples. Further, although there are actually wiring for illumination, wiring for switches, and the like, they are omitted here.

  On the other hand, the two dedicated outlets 302 are not for home appliances but for power line communication. The dedicated outlet 302 is provided in the vicinity of the inlet 18 of the room 3 where the inlet 18 of the optical fiber 17 is provided, separately from the dedicated outlet 303 for home appliances (for example, for an air conditioner). A media converter (ONU: Optical Network Unit) 19 is connected to the end of the optical fiber 17 drawn into the house. The media converter 19 is connected to a PLC modem 20 (master unit) via a communication cable 21. The media converter 19 has an interface function with the PLC modem 20 by, for example, Ethernet (registered trademark).

  As described above, since the circuit 9 from the circuit breaker 52 of the distribution board 5 to the dedicated outlet 302 is the non-branched cable 9, the signal attenuation of power line communication due to branching is prevented. Signal attenuation in power line communication is suppressed. Strictly speaking, since there are two outlets in the dedicated outlet 302, there is a branch of the electric circuit here, but since the distance between the two outlets is short (less than ¼ of the wavelength λ used for power line communication), It will not be a fork.

The dedicated outlet 302 is provided on the same wall surface as the service entrance 18 or on a wall surface adjacent to the corner of the room 3 so as to be close to the service entrance 18. The media converter 19, the PLC modem 20, and the dedicated outlet 302 are arranged close to each other, and the power cords 19a and 20a of the media converter 19 and the PLC modem 20 are both connected to the dedicated outlet 302. Accordingly, the service port 18, the dedicated outlet 302, the media converter 19 and the PLC modem 20 are arranged on the same wall surface in the room 3 or adjacent wall surfaces in a state of being close to each other.
As for actual attachment, the media converter 19 and the PLC modem 20 may be installed on furniture such as a shelf, or may be installed on a wall.

With the arrangement as described above, the media converter 19, the PLC modem 20, and the dedicated outlet 302 are arranged in the vicinity of the inlet 18, so that the drawing length of the optical fiber 17 can be shortened. Easy to route.
Since the media converter 19 and the PLC modem 20 are close to each other, the communication cable 21 needs only a very short length. Although it is possible to make the communication cable 21 longer, it is preferable not to make it longer from the viewpoint of saving communication wiring, which is one of the advantages of power line communication.

  On the other hand, the PLC modem 22 installed in the room 2 of FIG. 1 can perform power line communication with the PLC modem 20 of the master unit via the distribution board 5 by connecting the power cord 22a to the general-purpose outlet 201. It becomes a state. Similarly, the PLC modem 23 installed in the room 4 can be connected to the general-purpose outlet 401 by connecting the power cord 23a to the general-purpose outlet 401 so that power line communication can be performed with the PLC modem 20 of the master unit via the distribution board 5. Become. Although not shown, terminal devices such as personal computers and information home appliances are connected to the PLC modems 20, 22, and 23 to form a home LAN using indoor wiring as a signal transmission path. Connection to an external network such as the Internet via the fiber 17 is possible. The arrangement and number of PLC modems 22 and 23 are merely examples.

  FIG. 2 is a connection diagram showing an internal configuration of the distribution board 5 while extracting and showing a portion related to the power line communication in FIG. 1. In the figure, the lead-in wire 6 is a single-phase three-wire system, and has a first electric circuit R (red) and a second electric circuit B (black) on the non-ground side, and a third electric circuit W (white) on the ground side. The voltage between RW and B-W is 100V, and the voltage between RB is 200V. The lead-in wire 6 is connected to a main circuit breaker 5M in the distribution board 5. The secondary circuit of the circuit breaker 5M branches into a plurality of (here, eight) circuits, and circuit breakers 50 to 57 are provided in each circuit. And power is supplied to various places in the house via these circuit breakers 50-57.

  In FIG. 2, other circuit breakers 50, 51, 53 to 57 except for the circuit breaker 52 are connected to the electric circuits R, W or B, W. Which is actually connected is arbitrarily determined at the time of construction of electric work, and is usually distributed equally to both. In this example, the circuit breakers 50, 51 and 53 are connected to R and W, and the circuit breakers 54 to 57 are connected to B and W. Accordingly, the PLC modem 22 connected to the general-purpose outlet 201 is connected to B and W, and the PLC modem 23 connected to the general-purpose outlet 401 is connected to R and W, respectively.

  On the other hand, the circuit breaker 52 for 3 wires is connected to all the electric circuits R, W, and B. FIG. 3 is a diagram showing details of a dedicated outlet 302 as a power line communication outlet, in which (a) is a front view, (b) is a back view, and (c) is a connection diagram. In (a), the dedicated outlet 302 includes an outlet body 302a, a mounting bracket 302b, and a decorative cover 302c. In (b), a non-grounding side terminal portion 302d, a grounding side terminal portion 302e, and a power line communication dedicated terminal portion 302f that can be fixed simply by inserting a cable core are provided on the back surface of the outlet main body 302a. Yes. The non-ground side terminal portion 302d has a pair of upper and lower sides, and they are connected to each other by a conductor 302h. Similarly, there are also a pair of upper and lower ground side terminal portions 302e, which are connected internally by a conductor 302j. The conductor 302j is integrally provided with a ground-side contact piece 302k shown in (c), and the conductor 302h is integrally provided with a non-ground-side contact piece 302m.

  Further, a capacitor 302g is built in the outlet main body 302a, and one end thereof is connected to the non-ground side terminal portion 302d and the other end is connected to the power line communication dedicated terminal portion 302f. One of the single-phase three-wire electric circuits R and B is provided in the non-ground side terminal portion 302d, the electric circuit W is provided in the ground-side terminal portion 302e, and the other of the electric circuits R and B is provided in the power line communication dedicated terminal portion 302f. Are connected to each other. In this example, the electric wires 9R (electric circuit R), 9W (electric circuit W), and 9B (electric circuit B) of the cable 9 are connected to the non-ground side terminal portion 302d, the ground side terminal portion 302e, and the power line communication dedicated terminal portion 302f, respectively. The In addition, although all the electric wires of the single-phase three wires are connected, the potential difference between the non-ground side terminal portion 302d and the ground side terminal portion 302e is 100V, and the outlet 302 is for 100V.

  When the power cord 20a (FIG. 1) of the PLC modem 20 is connected to the dedicated outlet 302 configured as described above, one of the two power input lines of the power cord 20a is directly connected to the electric wire 9R (electric circuit R). In addition to being connected, the electric wire 9B (electric path B) is also connected via a capacitor 302g. The other of the power input lines is connected to the electric wire 9W (electric circuit W).

  FIG. 4 is a circuit diagram showing a connection state from the outdoor transformer 60 to the PLC modems 20, 22, and 23 related to power supply to the distribution board 5, omitting the circuit breaker and the outlet in FIG. 2. is there. The power input line 20R of the power cord 20a in the PLC modem 20 which is the master unit is connected to the power input line 23R of the power cord 23a of the PLC modem 23 which is the slave unit through the electric circuit R in the distribution board 5. Is done. On the other hand, the other power input line 20 </ b> W of the PLC modem 20 is connected to the other power input line 23 </ b> W of the PLC modem 23 via the electric circuit W in the distribution board 5. Therefore, the PLC modem 23 can share the two electric circuits R and W with the PLC modem 20 which is the parent device.

  On the other hand, the capacitor 25 does not pass the voltage / current of the commercial frequency but allows the high-frequency signal of power line communication to pass. Therefore, although the electric circuits R and B are disconnected by the capacitor 25 with respect to the commercial frequency voltage, the high frequency signal of the power line communication flows through the capacitor 25. Therefore, the PLC modem 20 serving as the master unit can transmit and receive power line communication signals through all the electric circuits R, W, and B. As a result, the power input line 20 </ b> R of the PLC modem 20 is connected to the power input line 22 </ b> B of the power cord 22 a of the PLC modem 22, which is a slave, via the electric circuit B in the distribution board 5. On the other hand, the other power input line 20 </ b> W of the PLC modem 20 is connected to the other power input line 22 </ b> W of the PLC modem 22 via the electric circuit W in the distribution board 5. Therefore, the PLC modem 22 can share the two electric circuits B and W with the PLC modem 20 which is the parent device.

  As described above, when the capacitor 25 does not pass the voltage / current of the commercial frequency but passes the high frequency signal of the power line communication, the master unit can transmit / receive the signal of the power line communication through all the electric paths R, W, B. it can. Therefore, even if the connecting electric circuit of the slave unit is any of R, W or B, W, the two electric circuits can be shared with the master unit, so that the master unit can connect the electric circuits R, W and B, The power unit communication can be performed with a uniform signal level with the slave unit connected to either of the Ws.

  Note that, as described above, in power line communication, signals whose waveforms are inverted with respect to each other are transmitted to two electric circuits carrying signals, and a received signal is obtained from the difference signal. In FIG. 4, if the signal transmitted from the PLC modem 20 is v, for example, a signal of-(v / 2) is put on the power input line 20R, and a signal of v / 2 is put on the power input line 20W. The signal on the power input line 20W is directly on the electric circuit W. On the other hand, since the signal on the power input line 20R is shunted to the electric circuits R and B, a signal of − (v / 4) is applied to the electric circuits R and B, respectively.

As a result, the signal level that can be received by the slave PLC modem 22 is the difference signal between the signals on the electric circuits W and B, that is,
(V / 2)-{-(v / 4)} = 3v / 4
It becomes. Similarly, the signal level that can be received by the slave PLC modem 23 is a difference signal between the signals on the electric circuits W and R, that is, 3v / 4.
The same applies to transmission from the PLC modem 22 or 23 of the slave unit to the PLC modem 20 of the master unit.

Therefore, the signal level of the power line communication is always uniform regardless of the connection circuit of the slave unit. Power line communication can be performed with a uniform signal level.
For example, if the power line communication is performed between the PLC modems 20 and 23 connected to the electric paths R and W without providing the capacitor 25, −v / 2 and v / 2 are respectively connected to the electric paths R and W. The difference signal is v. Compared with this, when the signal is put on all the electric circuits using the capacitor 25, the signal level that can be received is lowered to 3/4. However, the benefit of stabilizing the signal level and ensuring stable communication quality is greater than the loss, regardless of the connection circuit of the slave unit.

In addition, in the said embodiment, although the capacitor | condenser 25 shall be incorporated in the outlet main body part 302a, it may not be built-in but an external attachment may be sufficient. In addition, the outlet uses a normal one, and apart from that, a relay like a capacitor is inserted between the electric circuit R-B, and the electric circuit is connected from the cable to the electric outlet through this. A simple connection structure may be realized.
Moreover, although the exclusive outlet 302 shown in FIG. 3 is a wall surface embedded type, this may be an exposed type. In the case of the exposed type, each terminal for connecting an electric wire is generally a screw type.

  In the above embodiment, the connection to the external network is FTTH (Fiber To The Home), but it is also possible to connect the above-mentioned PLC home LAN to an ADSL (Asymmetric Digital Subscriber Line) line terminator. is there.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined not by the above-mentioned meaning but by the scope of claims for patent, and is intended to include all modifications within the scope and meaning equivalent to the scope of claims for patent.

1 is a connection diagram illustrating an entity connection structure of power line communication according to an embodiment of the present invention. FIG. 2 is a connection diagram illustrating an internal configuration of a distribution board while extracting and showing a portion related to power line communication in FIG. 1. It is a figure which shows the detail of the exclusive outlet as an outlet for power line communication, (a) is a front view, (b) is a back view, (c) is a connection diagram. FIG. 3 is a circuit diagram illustrating a connection state from an outdoor transformer to each PLC modem, with the circuit breaker and the outlet in FIG. 2 omitted.

Explanation of symbols

17 Optical fiber 19 Media converter 20 PLC modem (power line communication device)
20R, 20W power input line 22 PLC modem (power line communication device)
22B, 22W Power input line 23 PLC modem (power line communication device)
23R, 23W Power input line 25 Capacitor 302 Dedicated outlet (power line communication outlet)
302d Non-ground side terminal portion 302e Ground side terminal portion

Claims (3)

In the single-phase three-wire power source consisting of the first and second electric circuits on the non-grounded side and the third electric circuit on the grounded side, a capacitor is directly connected to one of the first electric circuit and the second electric circuit, and to the other electric circuit. One power line communication device in which one of the two power input lines is connected and the other of the power input lines is connected to the third electric circuit;
A power line communication substantive connection structure comprising: the first, third electric circuit, or another power line communication device connected to the second, third electric circuit. A non-grounded terminal portion for connecting any one of the first and second electric circuits on the non-grounded side in the single-phase three-wire power source;
A ground side terminal portion for connecting the ground side third electric circuit;
An outlet for power line communication, comprising: a capacitor having one end connected to the non-ground side terminal portion and the other end connected to the other of the first and second electric circuits.   In the single-phase three-wire power source consisting of the first and second electric circuits on the non-ground side and the third electric circuit on the ground side, the first electric circuit and the second electric circuit are directly connected to each other and the other electric circuit is connected via a capacitor. Then, one of the two power input lines in one power line communication apparatus is connected, the other of the power input lines is connected to the third electric circuit, and the first, third electric circuit, or first 2. A method of using a power line communication device, wherein power line communication is performed by connecting another power line communication device to the third electric circuit.

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