JP2008141603A - Real connection structure of power line communication - Google Patents

Abstract

Signal attenuation in power line communication in indoor wiring is reliably suppressed.
A distribution board for indoor wiring, to which a single-phase three-wire power source composed of non-grounded electric circuits R and B and a grounded electric circuit W is supplied, and electric circuits B and B in the distribution board 5 A plurality of first type outlets connected to W and used for purposes other than power line communication, and a plurality of second type outlets 101, 201 connected to electric circuits R and W in distribution board 5 and used for power line communication The power line communication substantive connection structure includes 301, 302, 401 and PLC modems (power line communication devices) 20, 22, 23 connected only to these second type outlets. The electric circuits R and B may be reversed.
[Selection] Figure 2

Description

  The present invention relates to an actual connection structure for power line communication (PLC).

  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). If the signal level decreases due to attenuation, the desired communication quality (communication speed) may not be obtained.

  In view of this problem, an object of the present invention is to reliably suppress signal attenuation of power line communication in indoor wiring.

The actual connection structure for power line communication according to the present invention includes a first, a third electric circuit, a second electric circuit, and a third electric circuit 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. A plurality of first-type outlets that are connected to one of them and used for purposes other than power line communication, and are connected to the other of the first, third, second, and third electric circuits for power line communication A plurality of second type outlets to be provided, and a power line communication device connected only to the second type outlets.
In the actual connection structure of power line communication as described above, the power line communication circuits in the plurality of power line communication devices connected to the second type outlet are both two circuits (first, third circuit, or second, third circuit). All become common and signal attenuation is suppressed.

In the above-described actual connection structure, it is preferable that the second type outlet is provided with an identification display indicating that it is an outlet for power line communication.
In this case, when a power line communication device is newly connected, it is possible to reliably connect to the second type outlet by relying on the identification display.

Further, in the above-described actual connection structure, a filter that blocks noise coming from the downstream side is connected to a circuit that feeds power from a distribution board for indoor wiring to a supply destination other than the second type outlet. Alternatively, it may be configured to be provided in the distribution board.
In this case, high-frequency noise generated in home appliances and lighting equipment connected to a circuit of a system different from the second type outlet is blocked by the filter and does not reach the power line communication signal circuit. Therefore, such high frequency noise does not interfere with power line communication. Further, since the filter is provided in the distribution board, it is convenient to mount and safe.

  According to the actual connection structure of the power line communication device of the present invention, the power line communication circuit in the plurality of power line communication devices connected to the second type outlet is two circuits (the first, third circuit, or the second, third circuit). ) All in common and signal attenuation is suppressed. Therefore, signal attenuation of power line communication in indoor wiring can be reliably suppressed.

  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 rooms 1, 2, 3, 4 and a bathroom (including a washroom) B shown in the figure. 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). Two distribution cables (VVF) 7 to 16 are drawn out from the distribution board 5, and these are wiring for outlets and lighting for the rooms 1 to 4 and the bathroom B.

  The outlet includes a plurality of first type outlets used for purposes other than power line communication and a plurality of second type outlets used for power line communication. The second type outlet is provided with some sort of identification for identification with the first type outlet. Specifically, for example, a color, a pattern, or a shape different from the first type outlet may be provided on the front surface, or an identification mark (for example, “PLC” character) may be attached. Conversely, the identification indication may be given to the first type outlet. In FIG. 1, outlets 202, 303, and B1 are first-type outlets, and other outlets 101, 201, 301, 302, and 401 shown with hatching have, for example, a plate type of the first-type outlet. It is a type 2 outlet that is different from an outlet.

The destinations of the cables 7 to 16 are as follows.
Cable 7: Catch ceilings 304 and 402 in rooms 3 and 4
Cable 8: Type 2 outlet 401 provided below the wall of the room 4
Cable 9: Type 2 outlet 301 provided below the wall surface of room 3
Cable 10: Type 2 outlet 302 provided above the wall surface of the room 3
Cable 11: first-type outlet 303 provided above the wall surface of the room 3
Cable 12: Catch ceilings 102 and 203 in rooms 1 and 2
Cable 13: the second type outlet 101 provided below the wall surface of the room 1
Cable 14: Type 2 outlet 201 provided below the wall surface of the room 2
Cable 15: the first type outlet 202 provided above the wall surface of the room 2
Cable 16: Type 1 outlet B1 and hook ceiling B2 provided on the wall surface of the bathroom B

  Here, the cables 10, 11, 15 are “dedicated electric circuits” wired from the distribution board 5 to the outlets 302, 303, 202 in a non-branching manner. The outlets 202 and 303 are typically for air conditioners. The location and number of outlets are only examples. Further, although there are actually switch wirings and the like, they are omitted here.

  On the other hand, the two second-type outlets 302 are not for home appliances but for power line communication. This 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 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).

The outlet 302 is provided on the same wall surface as the service entrance 18 or a wall surface adjacent to the corner of the room 3 and is close to the service entrance 18. The media converter 19, the PLC modem 20 and the 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 outlet 302. Accordingly, the service entrance 18, the outlet 302, the media converter 19 and the PLC modem 20 are arranged on the same wall surface in the room 3 or adjacent to each other 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 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 is in a state where power line communication is possible with the PLC modem 20 of the master unit via the distribution board 5 by connecting the power cord 22a to the outlet 201. It becomes. Similarly, the PLC modem 23 installed in the room 4 is in a state in which power line communication is possible with the PLC modem 20 of the parent device via the distribution board 5 by connecting the power cord 23a to the outlet 401. . 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.

  Regarding the outlets, the condition of “first type” is that the use is limited from the place where the outlet is installed, and there is substantially no possibility of being used for power line communication. For example, the outlets 202 and 303 are located at a high position on the wall surface that is difficult to reach, and are practically dedicated to air conditioners. Further, since the outlet B1 is in the bathroom (toilet) B, no personal computer or the like is installed, and therefore there is virtually no possibility of being used for power line communication. On the other hand, the condition for the outlet to be “second type” is that the outlet is likely to be used for power line communication from the installation location. For example, the outlet 302 is provided for the media converter 19 and the PLC modem 20 as described above. In addition, the outlets 101, 201, 301, and 401 are easily accessible, and there is a high possibility that a personal computer or the like is installed near them and power line communication is performed.

  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, 10) circuits, and circuit breakers 50 to 59 are provided in each circuit. And power is supplied to various places in the house through these circuit breakers 50-59.

The illustrated example is a case where only 100 V is supplied, and the circuit breakers 50 to 59 are connected to R, W or B, W. Which of R, W and B, W is connected has regularity, and the circuit breakers 51, 52, 53, 56, 57 that place the second type outlets 401, 301, 302, 101, 201 under control. Are all connected to the electric circuits R and W. On the other hand, all the other circuit breakers 50, 54, 55, 58, 59 are connected to the electric circuits B, W. A filter 5F is connected in series on the secondary side of these circuit breakers 50, 54, 55, 58, 59.
FIG. 3 is a diagram illustrating an internal circuit of the filter 5F. The filter 5F is formed by connecting a coil (reactance) 5F1 and a capacitor 5F2 in a π type, and has a high-frequency noise blocking function.

In FIG. 2, when the media converter 19 and the PLC modem 20 are connected to the outlet 302, the PLC modem 22 is connected to the outlet 201, and the PLC modem 23 is connected to the outlet 401, respectively, power line communication for each PLC modem 20, 22, 23 is performed. The two electric circuits are common to both of the two electric circuits (R, W), and the signal attenuation of the power line communication is suppressed. Therefore, signal attenuation of power line communication in indoor wiring can be reliably suppressed.
Further, as described above, since the second type outlets 101, 201, 301, 401 are labeled with the first type outlets, when connecting a PLC modem (slave unit) newly, By relying on the identification display, it is possible to reliably connect to the second type outlet.

  In addition, with respect to the PLC modem 20 as the master unit, the signal line of the power line communication due to branching is prevented because the circuit breaker 53 of the distribution board 5 to the outlet 302 is a dedicated electric circuit cable 10 wired in a non-branching manner. In addition, signal attenuation of power line communication in this electric circuit is also suppressed. Strictly speaking, since the outlet 302 has two ports, there is a branch of the electric circuit here, but the distance between the two ports is short (less than ¼ of the wavelength λ used for power line communication). Don't branch.

  On the other hand, home appliances (not shown) connected to the first type outlets 202, 303, B1 of FIG. 1 and systems different from the second type outlets 101, 201, 301, 401, and the hooking ceilings 102, 203. , 304, 402, B2 may cause high-frequency noise in a lighting fixture (not shown) or the like (especially easily generated from an inverter device). However, such high-frequency noise is blocked by the filter 5F and does not reach the upstream of each circuit breaker 50, 54, 55, 58, 59 or more. Therefore, high frequency noise does not interfere with power line communication. Moreover, since the filter 5F is provided in the distribution board 5, attachment is convenient and it is safe.

  In the above embodiment, the second-type outlet system is connected to the electric circuits R and W, and the other systems are connected to the electric circuits B and W. Conversely, the second-type outlet system is connected to the electric circuits B and W. The other systems may be connected to the electric paths R and W.

  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 an internal circuit diagram of a filter.

Explanation of symbols

5F filter 20, 22, 23 PLC modem (power line communication device)
202, 303, 402, B1 Type 1 outlet 101, 201, 301, 302, 401 Type 2 outlet

Claims (3)

The power line communication is connected to one of the first, third, second, and third circuits in the single-phase three-wire power source including the first and second circuits on the non-ground side and the third circuit on the ground side. Multiple first-class outlets for use other than
A plurality of second-type outlets connected to the other of the first, third and second and third electric circuits, and used for power line communication; and
And a power line communication device connected only to the second type outlet.   The power line communication substantive connection structure according to claim 1, wherein the second type outlet has an identification indicating that it is an outlet for power line communication.   A filter that blocks noise coming from the downstream side is connected to a circuit that feeds power from a distribution board for indoor wiring to a supply destination other than the second type outlet, and this filter is connected to the distribution board. The entity connection structure of the power line communication according to claim 1 provided.

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