Source: https://patents.google.com/patent/JP4611172B2/en
Timestamp: 2020-02-26 02:07:15
Document Index: 149758541

Matched Legal Cases: ['art 14', 'art 2', 'arts 31', 'arts 31', 'art 2', 'art 2', 'art 2', 'art 2', 'art 2', 'art 2', 'art 2', 'art 2', 'arts 30', 'arts 30', 'art 2', 'art 11', 'art 12', 'art 31', 'art 31', 'art 19']

JP4611172B2 - Power line carrier communication equipment - Google Patents
Power line carrier communication equipment Download PDF
JP4611172B2
JP4611172B2 JP2005306133A JP2005306133A JP4611172B2 JP 4611172 B2 JP4611172 B2 JP 4611172B2 JP 2005306133 A JP2005306133 A JP 2005306133A JP 2005306133 A JP2005306133 A JP 2005306133A JP 4611172 B2 JP4611172 B2 JP 4611172B2
JP2005306133A
JP2007116464A (en
直哉 中山
浩二 前川
心司 山本
2005-10-20 Application filed by パナソニック電工株式会社, 関西電力株式会社 filed Critical パナソニック電工株式会社
2005-10-20 Priority to JP2005306133A priority Critical patent/JP4611172B2/en
2007-05-10 Publication of JP2007116464A publication Critical patent/JP2007116464A/en
2011-01-12 Publication of JP4611172B2 publication Critical patent/JP4611172B2/en
The present invention relates to a power line carrier communication device that performs communication by power line carrier communication, and in particular, receives a communication signal of power line carrier communication by electromagnetic induction without being joined to a conductor metal of the power line without receiving power supply from the power line as a driving power source. The present invention relates to a power line carrier communication device for injecting power lines.
In recent years, networking has progressed in various technical fields due to advances in communication technology, and various devices in a building are being connected to the network. Such devices are networked by organically linking these devices, and by connecting the network outside the building and the network inside the building to operate these devices from an external communication terminal. By instructing it, it is intended to provide a safe and comfortable life as well as energy saving and remote control.
There are various communication signal transmission methods, but the advantage that there is no need to lay a new transmission line because the existing wiring is used, and the initial cost associated with the introduction is accordingly low, Power line communication (hereinafter abbreviated as “PLC”) using wiring (power line) for supplying power to these devices as a transmission line is adopted because of the advantage that the aesthetics of the building is not impaired. Sometimes. This PLC, for example, superimposes and transmits a PLC communication signal having a frequency higher than the commercial frequency (hereinafter abbreviated as “PLC signal”) on the power waveform of the commercial frequency, This is a communication method for transmitting and receiving a PLC signal via a power line by separating and receiving the PLC signal.
In such a power line carrier communication apparatus (hereinafter, abbreviated as “PLC apparatus”) that performs communication using PLC, for example, as disclosed in Patent Document 1, power is supplied from a power line and a power line is used. PLC signals are transmitted and received.
FIG. 22A is a block diagram showing a first configuration of the power line carrier communication system described in Patent Literature 1. FIG. FIG. 22B is a block diagram showing a second configuration of the power line carrier communication system described in Patent Document 1.
In FIG. 22A, a power line carrier communication system 1000A according to the first configuration is provided in a device main body 1010 such as a PC or a household electric device, and supplies power to a circuit such as a control unit in the device main body 1010. A power transformer unit 1011 connected to a power line outlet, a PLC signal circuit of a PLC modem (not shown) for the PLC, and the power transformer unit 1011 are connected between the power transformer unit 1011 and the PLC signal is transmitted through the power transformer unit 1011 to the power line. And a signal superimposing transformer unit 1012 for separating the PLC signal from the power line and transferring it to the PLC signal circuit. The power transformer unit 1011 includes a power transformer T101. In the signal superimposing transformer unit 1012, Zener diodes D101 and D102 connected in series in the reverse direction are connected to the secondary winding T102-2 so that the surge voltage from the commercial power supply side does not affect the PLC circuit. The signal superimposing transformer T102 is connected in series with the primary winding T102-1 to which capacitors C101 and C102 that cut off the commercial frequency are connected. In the power line carrier communication system 1000A having such a configuration, the power transformer unit 1011 receives power supplied from the power line via the outlet and supplies power to each unit of the device main body 1010. When a PLC signal is transmitted, the PLC signal related to the transmission is input to the signal superimposing transformer unit 1012 via the PLC signal circuit of the PLC modem. The input PLC signal is superimposed on the power line via the power transformer 1011 and the outlet, and is transmitted through the power line. On the other hand, when a PLC signal is received, it is received by the reverse process.
22B, the power line carrier communication system 1000B according to the second configuration includes a PLC signal coupling power line side transformer unit 1023 connected to a power line outlet, a PLC signal coupling main unit transformer unit 1021, and The same configuration as the signal superimposing transformer unit 1012 described with reference to FIG. 22A connected between the PLC signal circuit of the PLC modem (not shown) for the PLC and the aforementioned PLC signal coupling main body transformer unit 1021. And a device main body 1020 that is operated by a secondary battery such as a notebook PC, a PDA, or a small household appliance having a signal superimposing transformer 1022. The PLC signal coupling power line side transformer section 1023 is configured by a coil L101, and the PLC signal coupling main body side transformer section 1021 is configured by a coil L102, and electromagnetic induction through a space between these coils L101 and L102 Receives commercial power supply and transmits PLC signal. In power line carrier communication system 1000B having such a configuration, when a PLC signal is transmitted, the PLC signal related to transmission is input to signal superimposing transformer 1022 via the PLC signal circuit of the PLC modem. Then, the input PLC signal is transmitted to the PLC signal coupling power line side transformer unit 1023 by electromagnetic induction via the PLC signal coupling main body side transformer unit 1021, superimposed on the power line via the outlet, and transmitted through the power line. To do. On the other hand, when a PLC signal is received, it is received by the reverse process. In the power line carrier communication system 1000B having such a configuration, when commercial power is supplied, the commercial power is input from the power line to the PLC signal coupling power line transformer 1023 via an outlet. Then, the input commercial power is supplied to the PLC signal coupling main body transformer section 1021 by electromagnetic induction to charge the secondary battery. The secondary battery supplies power to each part of the device main body 1020. The power line carrier communication system 1000B is a so-called contactless charging system.
Thus, since the PLC apparatus receives power supply from the power line and transmits and receives PLC signals using the power line, it needs to be connected to the power line. The connection between the PLC device and the power line is performed by an outlet as disclosed in Patent Document 1 or by direct attachment as disclosed in Patent Document 2.
FIG. 23 is a block diagram of a system for transmitting digital data via a general power supply main line using the transmission circuit described in Patent Document 2. FIG. 23A is a block diagram of the entire system, and FIG. 23B is a circuit diagram of a transmission circuit.
In FIG. 23A, in the system 1000C, the main line side terminals 1034 and 1035 of the transmission circuit 1036 are respectively connected to the neutral line 1032 and the phase line 1033 of the power supply main line 1031. The transmission circuit 1036 transmits a signal modulated with digital data from the power supply main line 1031 to the first application side terminal 1037 and transmits the signal from the second application side terminal 1038 to the power supply main line 1031 in the reverse direction. The first application side terminal 1037 is connected to the modem 1040 by a receiving circuit 1039 provided with a receiving amplifier circuit. The modem 1040 is also coupled to the second application side terminal 1038 of the transmission circuit 1036 via the transmission amplifier 1041. For input and output of digital data, the modem 1040 includes a data line 1042. These transmission circuit 1036, reception circuit 1039, transmission amplifier 1041, and modem 1040 are coupled to a ground (not shown). The modem 1040 receives data to be transmitted from the data line 1042 and generates a signal modulated corresponding to the frequency range used for the PLC. The modulated signal is supplied to the transmission circuit 1036 through the transmission amplifier 1041. The transmission circuit 1036 superimposes the modulated signal on the voltage of the power supply main line 1031. On the other hand, the signal transmitted through the power supply main line 1031 by the equivalent system is separated from the main frequency used for power transfer by the transmission circuit 1036 and transmitted to the modem 1040 through the reception circuit 1039. The modem 1040 acquires data included in the signal by demodulation and outputs the data to the data line 1042. As shown in FIG. 23B, the transmission circuit 1036 includes a first winding T201-1, which is directly disposed between the main line side terminals 1034 and 1035, and the first terminal T201-1, a ground terminal 1044, and a first application. A transformer T201 including a second winding T201-2 and a third winding T201-3 connected in series with the side terminal is provided. The connection point between the second winding T201-2 and the third winding T201-3 is connected to the second application side terminal 1038, and the second winding T201-2 and the third winding T201-3. A second capacitor 202 is connected in parallel to the series circuit.
JP 2004-112301 A JP 2000-353991 A
By the way, when connecting a PLC apparatus and a power line by direct attachment like patent document 2, in order to connect a PLC apparatus to a power line, the conductor metal of a power line is stripped excluding the coating of a power line, or this stripping It is necessary to process the power line such as providing a terminal on the conductive metal. In particular, when this processing is performed in a state where commercial power is supplied to the power line, there is a disadvantage that there is a risk of electric shock or the like, and processing in such a state is performed by a qualified person having a predetermined qualification. Therefore, there are inconveniences such as securing qualified personnel and high personnel costs for qualified personnel.
On the other hand, if the power line is cut off and this processing is performed, the above inconvenience is solved, but it is easy to cut off the power line that is already in operation because it requires a procedure for that and causes trouble for consumers. is not. In particular, when a PLC device is installed in a distribution board of an apartment house that branches a power line from the power system to each dwelling unit, or when a PLC device is installed in the power system, it is difficult to power out the power line.
The present invention has been made in view of the above circumstances, and without receiving power supply from the power line as a driving power source, the power line carrier communication signal is injected into the power line by electromagnetic induction without being joined to the conductor metal of the power line. It is an object of the present invention to provide a power line carrier communication device that can be used.
As a result of various studies, the present inventor has found that the above object is achieved by the present invention described below. That is, the power line carrier communication device according to one aspect of the present invention includes an electromagnetic induction coupling unit that transmits a communication signal of power line carrier communication to and from the power line by electromagnetic induction, and the power line via the electromagnetic induction coupling unit. The power line carrier communication is extracted by demodulating the communication signal of the power line carrier communication extracted from the information extracted from the communication signal of the power line carrier communication and modulating the carrier wave of the power line carrier communication according to the information to be transmitted. A power line carrier communication modem unit that generates a communication signal for communication and injects the generated power line carrier communication signal into the power line via the electromagnetic inductive coupling unit, and supplies power to the power line carrier communication modem unit as a driving power source. winding a supply battery, the electromagnetic induction coupling portion is a signal line wound around the power line, the signal line is wound around the power line Minutes, is divided into a lead portion of the remainder, between them and said available Der Rukoto connected by a connector.
Further, in the above-described power line carrier communication device, the signal lines are characterized in that one end is connected to each other with two power lines of the same system as one set.
In the above-described power line carrier communication device, the signal line is formed in a spiral shape having an inner diameter larger than the outer diameter of the power line by a predetermined value, and the power line spirals between the spiral loops. Then, both ends of the signal line are pulled in a direction away from the power line, so that the signal line is in close contact with the power line, and the intimate part becomes the winding part and is in close contact with the power line. The part which is not used becomes the said drawer part, It is characterized by the above-mentioned.
Further, in the above power line carrier communication devices, at least a winding start end and a winding end end of the signal line are provided with a fastening member through which the signal line is inserted, and an inner peripheral surface of the fastening member and the signal line At least one of the outer peripheral surface and the outer peripheral surface has a check piece for preventing the loop from loosening so that the power line is fastened by the loop of the signal line at the end thereof.
Further, in the above-described power line carrier communication device, the tube wound around the power line is divided into approximately half in the axial direction of the power line, and the signal line is loosely inserted into the tube. The apparatus further includes a member.
And in the above-mentioned power line carrier communication apparatus, a check piece for preventing the loop from loosening so that the power line is fastened to at least one pair of adjacent pipes by a loop of signal lines routed between the pipes. It is characterized by having.
The power line carrier communication device according to another aspect of the present invention includes an electromagnetic induction coupling unit that transmits a communication signal of power line carrier communication to and from the power line by electromagnetic induction, and the electromagnetic induction coupling unit. By demodulating the communication signal of the power line carrier communication extracted from the power line, the information contained in the communication signal of the power line carrier communication is extracted, and by modulating the carrier wave of the power line carrier communication according to the information to be transmitted A power line carrier communication modem unit that generates a power line carrier communication signal and injects the generated power line carrier communication signal into the power line via the electromagnetic inductive coupling unit, and a drive power source to the power line carrier communication modem unit and a battery for supplying electric power, the electromagnetic induction coupling part is made of electrically insulating material, substantially a pair of curved members curved in a semi-circular arc, the concave Are arranged so that they face each other, one end in the circumferential direction is connected by a hinge, and the other end side can be freely opened and closed, so that the mounting portion formed so that the power line can be held in the recess, A plurality of attachment members connected at the hinge portion, and from the bending member to the hinge portion, electrically connected to the signal line of the bending member paired on the other end side of the closed bending member to form a loop; A signal line that is electrically connected to a signal line of an adjacent mounting portion at a hinge portion and connected to the next loop is formed, and a communication signal of the power line carrier communication is injected from the signal line to the power line. And
Furthermore, in the above-described power line carrier communication device, the pair of bending members can be crossed at an arbitrary angle by being shifted in the axial direction of the hinge, and the signal lines in the bending members are It is characterized in that it is electrically connected in sliding contact with a signal line of a pair of bending members on opposite end surfaces of the member.
And in these above-mentioned power line carrier communication apparatuses, the attachment part is detachable at the hinge part.
The power line carrier communication device according to another aspect of the present invention includes an electromagnetic induction coupling unit that transmits a communication signal of power line carrier communication to and from the power line by electromagnetic induction, and the electromagnetic induction coupling unit. By demodulating the communication signal of the power line carrier communication extracted from the power line, the information contained in the communication signal of the power line carrier communication is extracted, and by modulating the carrier wave of the power line carrier communication according to the information to be transmitted A power line carrier communication modem unit that generates a power line carrier communication signal and injects the generated power line carrier communication signal into the power line via the electromagnetic inductive coupling unit, and a drive power source to the power line carrier communication modem unit and a battery for supplying electric power, the electromagnetic induction coupling portion, a plurality and a signal line extending along the longitudinal direction of the power line to the outer circumference in the circumferential direction of the power line It is characterized in.
In the above power line carrier communication devices, the electromagnetic inductive coupling unit further includes an impedance matching unit having an impedance value that substantially matches the characteristic impedance of the power line.
Furthermore, in the above-described power line carrier communication device, the impedance matching unit has a variable impedance value.
And in these above-mentioned power line carrier communication apparatuses, the electromagnetic induction coupling part and the power line carrier communication modem part are provided with a connector, and are detachable by the connector.
The power line carrier communication device having such a configuration does not need to receive power supply from the power line as a drive power source, and can inject a communication signal of power line carrier communication into the power line by electromagnetic induction without being joined to the conductor metal of the power line. .
FIG. 1 is a block diagram illustrating a configuration of a power line carrier communication apparatus according to an embodiment. In FIG. 1, the PLC device A includes a power line carrier communication device main body (hereinafter abbreviated as “PLC device main body”) 1 and an electromagnetic induction coupling unit 2.
The electromagnetic induction coupling unit 2 is a member that transmits a PLC signal to and from the power lines N and M by electromagnetic induction. In a distribution board or a distribution board of a detached house or an apartment house, or on a power pole, It is attached to a part accessible to the power lines N and M. For example, in the first embodiment, the electromagnetic induction coupling unit 2 includes a pair of signal lines 21 and 22 corresponding to the pair of power lines N and M. The signal lines 21 and 22 are wound around the power lines N and M, respectively. It is not connected to the conductor metal of the power lines N and M.
The PLC device main body 1 is a device that performs communication by PLC, and includes a power line carrier communication modem unit (hereinafter abbreviated as “PLC modem unit”) 11 and a battery 12. The PLC device main body 1 and the electromagnetic induction coupling unit 2 are connected by, for example, a coaxial cable because the PLC signal has a high frequency.
The PLC modem unit 11 demodulates the PLC signal extracted from the power lines N and M via the electromagnetic inductive coupling unit 2 to extract information contained in the demodulated PLC signal and according to information to be transmitted. This is a device that generates a PLC signal by modulating a carrier wave of the PLC and injects the generated PLC signal into the power lines N and M via the electromagnetic induction coupling unit 2. The information extracted from the PLC signal and the information to be transmitted are input / output from the PLC device A to other devices via an input / output interface circuit (I / O) (not shown). In the present embodiment, the PLC modem unit 11 includes, for example, a coupling circuit 13, an analog front end unit 14, a power line carrier communication LSI 15, and a control unit 16.
The coupling circuit 13 is a circuit that mutually transmits alternating current between the signal lines 21 and 22 and the analog front end unit 14, and includes a transformer T1 including a primary winding T11 and a secondary winding T12, and two It comprises diodes D1 and D2 that are Zener diodes. Signal lines 21 and 22 are respectively connected to both ends of the primary winding T11, and diodes D1 and D2 are respectively connected in series in opposite directions between both ends of the secondary winding. The transformer T1 cuts off direct current between the electromagnetic inductive coupling unit 2 (signal lines 21 and 22) and the analog front end unit 14, and the diodes D1 and D2 have surge voltages from the power lines N and M side that are analog front ends. The influence given to the part 14 is suppressed.
The analog front end unit 14 is connected to the coupling circuit 13, and is a device that converts a PLC signal between an analog signal and a digital signal, and includes a modulation / demodulation circuit 17 and an oscillation circuit 18. Composed. The oscillation circuit 18 is a circuit that oscillates a sine wave having a predetermined frequency. For example, a known oscillation circuit such as a Colpitts oscillation circuit, a Hartley oscillation circuit, or a PLL (Phase Lock Loop) oscillation circuit is used. The modulation / demodulation circuit 17 demodulates the analog PLC signal input from the coupling circuit 13 into a digital signal and outputs the digital signal to the power line carrier communication LSI 15, and also according to the digital signal of information to be transmitted input from the power line carrier communication LSI 15. For example, a sine wave (PLC carrier wave) from the oscillation circuit 18 is modulated to generate an analog PLC signal and output it to the coupling circuit 13. Note that spectrum spreading using a direct spreading method is also applicable.
The power line carrier communication LSI 15 is connected to the analog front end unit 14, generates a digital signal corresponding to information to be transmitted based on the format of the PLC signal, and generates the generated digital PLC signal as an analog front end unit. 14 is an integrated circuit that extracts information contained therein from a digital signal input from the analog front end unit 14 based on the format of the PLC signal.
Here, the format of the PLC signal is a structure in which a header for power line carrier communication is added to an upper layer communication signal such as an Ethernet frame, for example, and the header for power line carrier communication is a PLC such as a transmission source address or a destination address. This is a part that accommodates information necessary for performing transmission, and accommodates a MAC address for power line carrier communication of a transmission source, a MAC address for power line carrier communication of a destination, and the like. The Ethernet frame has a structure in which an Ethernet header is added to an IP datagram, and the IP datagram has a structure in which an IP header is added to information to be transmitted.
The control unit 16 includes, for example, a microprocessor, a storage element such as a RAM and a ROM, and peripheral circuits thereof, and the analog front end unit 14 and the power line carrier communication LSI 15 are connected to the function according to a control program stored in the ROM. Control according to each.
The battery 12 supplies power to the analog front end unit 14, the power carrier communication LSI 15, and the control unit 16 in the PLC modem unit 11 as a driving power source. The battery 12 is, for example, a chemical battery that converts chemical energy into electrical energy, such as a primary battery, a secondary battery, or a fuel cell, and a solar battery that converts light into electrical energy.
In the PLC device A having such a configuration, each part of the analog front end unit 14, the power carrier communication LSI 15, and the control unit 16 in the power line carrier communication modem unit 11 operates by receiving power supply from the battery 12. For this reason, it is not necessary to receive power supply from the power lines M and N as a drive power source.
In the PLC device A having such a configuration, when information to be transmitted is input, the power line carrier communication LSI 15 in the PLC modem unit 11 analogizes a digital signal corresponding to the information to be transmitted based on the format of the PLC signal. The data is output to the modulation / demodulation circuit 17 of the front end unit 14. The modem circuit 17 generates an analog PLC signal by modulating the sine wave (PLC carrier wave) from the oscillation circuit 18 in accordance with the digital signal input from the power line carrier communication LSI 15, and outputs the analog PLC signal to the coupling circuit 13. The coupling circuit 13 outputs the PLC signal input from the modulation / demodulation circuit 17 of the analog front end unit 14 to the signal lines 21 and 22 via the transformer T1. The signal lines 21 and 22 inject and transmit the PLC signal to the power lines N and M by electromagnetic induction.
On the other hand, the PLC signal transmitted through the power lines N and M is extracted from the power lines N and M to the signal lines 21 and 22 by electromagnetic induction and transmitted. The PLC signals extracted from the power lines N and M are output from the signal lines 21 and 22 to the coupling circuit 13. The coupling circuit 13 outputs the PLC signal to the modulation / demodulation circuit 17 of the analog front end unit 14 via the transformer T1. The modem circuit 17 demodulates the analog PLC signal into a digital signal and outputs it to the power line carrier communication LSI 15. The power line carrier communication LSI 15 extracts information contained in the digital signal input from the analog front end unit 14 based on the format of the PLC signal.
As described above, in the PLC device A according to the present embodiment, the analog front end unit 14, the power carrier communication LSI 15, and the control unit 16 in the PLC modem unit 11 are supplied with power from the battery 12. There is no need to receive power. Since the PLC device A transmits the PLC signal to each other by electromagnetic induction through the signal lines 21 and 22 wound around the power lines N and M, the power line N is connected to connect the PLC device A to the power lines N and M. By removing the coating of M, it is not necessary to expose the conductor metal of the power line, or to perform processing such as providing a terminal on the exposed conductor metal. For this reason, the PLC apparatus A can be safely and easily applied to the power lines N and M as compared with the prior art. It is also possible to construct the power lines N and M that are already in operation without power failure.
Note that, as described in the background art with reference to FIG. 22B, Patent Document 1 describes using electromagnetic induction, but the power line carrier communication system 1000B includes a non-contact charging device. It is a system devised to enable PLC and does not utilize electromagnetic induction between the power line and the PLC device. The power line carrier communication system 1000B is connected to the power line using an outlet.
Here, in the above-described embodiment, the signal lines 21 and 22 can be linearly formed along the long direction of the power lines N and M, but the power lines N and M are the same as in the present embodiment. When the signal lines 21 and 22 are wound around, the coupling section H1 of the signal lines 21 and 22 along which the non-junction high-frequency PLC signal is transmitted to the power lines N and M can be shortened. The connecting section H1 is required to be about 1 m as long as it is aligned along the conventional way, but can be shortened to about 10 cm by winding. In addition, since the coupling section H1 can be shortened, a small space is required, so that the risk of electric shock can be reduced.
2A and 2B are graphs showing the experimental results. These graphs change the winding pitch of the signal lines 21 and 22 wound around the power lines N and M and the gap between the power lines N and M and the signal lines 21 and 22 (the winding diameter of the signal lines 21 and 22). The injection loss at each frequency is shown. FIG. 2A shows data when the development length of the signal lines 21 and 22 is 1 m, and FIG. 2B shows data when the development length of the signal lines 21 and 22 is 50 cm. The diameter is 6 mm. FIGS. 2A and 2B also show data when signal lines having the same length are run in parallel.
The experimental method is as shown in FIG. 3. A noise cut transformer 515 and a LISN (Line Impedance Stabilisation Network) 516 are interposed in the power lines N and M, and the signal lines 21 and 22 are transmitted from the tracking generator of the spectrum analyzer 517. Then, a signal (2 to 30 MHz, output power: 0 dBm) obtained by sweeping the measurement frequency band is injected as the PLC signal. The signal is taken into the spectrum analyzer 517 from an outlet 518 provided on the lead-in line 519 and analyzed.
Further, the winding pitch of the signal lines 21 and 22 and the gap between the power lines N and M and the signal lines 21 and 22 shown in the graphs of FIGS. 2A and 2B can be schematically represented. This is shown in FIG.
From FIG. 2 (a) and FIG. 2 (b), if there is no gap between the power lines N and M and the signal lines 21 and 22, it is possible to obtain a coupling characteristic substantially equivalent to that when the power lines N and M are aligned in parallel. It is understood that the injection loss is about −30 dB at a minimum and about −30 dB at a minimum of 50 cm. In addition, when there is a gap, the characteristic is reduced by about 5 to 20 dB, and in any case, it is understood that there is no large characteristic drop at a specific frequency. In this way, the coupling section H1 can be shortened, and a high-frequency signal for PLC can be injected in a non-junction manner even if the area accessible to the power lines N and M is small in the distribution board and distribution board. it can.
Here, in the above-described embodiment, the signal lines 21 and 22 of the electromagnetic inductive coupling unit 2 have two power lines N and M of the same system as one set, and their free ends are indicated by broken lines in FIG. The signal lines 21 and 22 and the short-circuit line 23 may be formed in a loop shape by being connected by the short-circuit line 23.
If the signal lines 21 and 22 are provided on the two power lines N and M in any combination as long as they are of the same system, a high-frequency PLC signal is similarly superimposed on the remaining one line. In some cases, a combination of two hot-side wires or a combination of one of the hot-side one wires and a ground wire may be used. The winding direction of the signal lines 21 and 22 is also arbitrary. In such a PLC apparatus A, the two signal lines 21 and 22 are not necessarily required, and one of them may be provided.
FIG. 5A to FIG. 5C are graphs showing experimental results. In these graphs, the free ends of the signal lines 21 and 22 are opened with the winding pitch of the signal lines 21 and 22 wound around the power lines N and M and the gap between the power lines N and M and the signal lines 21 and 22 being constant. It is a graph which shows the injection | pouring loss in the case where it short-circuits with a case and the short circuit wire 23. FIG. 5A shows data when the development length of the signal lines 21 and 22 is 1 m, and FIG. 5B shows data when the development length of the signal lines 21 and 22 is 50 cm. (C) is data when the development length of the signal lines 21 and 22 is 2 m.
By configuring in this way, the coupling section H1 can be reduced to approximately ½ compared to the case where there is one signal line. Moreover, even with the same two, as shown in FIGS. 5A to 5C, the drop in injection loss at a specific frequency is small as compared with the PLC device A in the case of an open end, and the injection is generally performed. Since loss is small, it is more suitable. Furthermore, it is understood that, by forming in a loop shape, the signal lines 21 and 22 used in this experiment have substantially the same frequency characteristics regardless of the length.
Moreover, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 6 is a diagram illustrating another configuration of the electromagnetic induction coupling unit in the power transfer device. In FIG. 6, the signal lines 31 and 32 of the electromagnetic induction coupling unit 30 according to the other configuration are wound around the power lines N and M, respectively, and are wound (curled) wound portions 31a and 32a. And the remaining straight lead-out portions 31b and 32b, which are connectable by connectors 33 and 34. By comprising in this way, at the time of winding to the electric power lines N and M of the winding parts 31a and 32a, the drawer | draw-out parts 31b and 32b do not become obstructive, and it can wind with favorable workability | operativity.
Furthermore, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 7 is a diagram illustrating a method of winding a signal line around a power line in an electromagnetic induction coupling unit having another configuration of the power transfer device. Similarly to the signal lines 31 and 32 described above, the signal line 41 in the electromagnetic induction coupling portion having the other configuration is also divided into a winding portion 41a and a drawing portion 41b. In this signal line 41, as shown in FIGS. 7A and 7B, the entire length of the signal line 41 is spirally brazed (curled), and connectors 33 and 34 are provided near both ends. It is being done. Then, as shown in FIGS. 7A to 7B, between the spiral loops of the signal line 41 formed by bending a spiral having an inner diameter larger than the outer diameter of the power line N by a predetermined value. Then, after the power line N is inserted inside the spiral, as shown in FIG. 7C, both ends of the signal line 41 are pulled in directions away from the power line N, whereby the signal line 41 is The portion that is in close contact with N and that is in close contact becomes the wound portion 41a, and the portion that is not in close contact is the drawer portion 41b. At both ends of the winding portion 41 a, the lead-out portion 41 b is separated by the connector 33 and is connected to the lead-out line from the PLC device main body 1 by the connector 33. With this configuration, when installing the signal line 41, the power line N is sequentially inserted into the spiral from between the spiral loops, and both ends of the signal line 41 are pulled after completion of the interruption. Installation can be performed. Although not shown, winding around the power line M can be performed in the same manner.
And in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 8 is a diagram illustrating a method of winding a signal line around a power line in an electromagnetic induction coupling unit having another configuration of the power transfer device. In the signal line 51 in the electromagnetic induction coupling portion having another configuration, as shown in FIG. 8A, a fastening member 53 through which the signal line 51 is inserted at least at the winding start end and winding end of the signal line 51. , 54 are provided. The fastening members 53 and 54 are connected by a connecting piece 55. FIG. 8B shows an enlarged view of the vicinity of the fastening member 53.
Then, as shown by the fastening member 53a shown in FIGS. 9 (a) and 9 (b) and the fastening member 53b shown in FIGS. 9 (c) and 9 (d), the fastening members 53 and 54 are connected. At least one of the inner peripheral surface and the outer peripheral surface of the signal line 51 (only in the fastening members 53a and 53b side in FIG. 9), the power line N is tightened by the loops 51c and 51d at the end of the signal line 51. Check pieces 56a and 56b for preventing the loop from loosening are provided. Therefore, as shown in FIGS. 9 (a) and 9 (c) to 9 (b) and 9 (d), the check pieces 56a and 56b are connected to the signal line 51 with respect to the fastening members 53a and 53b. The check pieces 56a and 56b are engaged with the outer peripheral surface of the signal line 51, thereby preventing the slip in the direction opposite to the insertion direction. By using the fastening members 53a and 53b configured as described above, the winding operation can be performed smoothly and the signal line 51 can be prevented from slipping down due to use. Although not shown, the signal line 52 can be wound around the power line M in the same manner.
Moreover, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 10 is a diagram illustrating a method of winding a signal line around a power line in an electromagnetic induction coupling unit having another configuration of the power transfer device. FIG. 10A is a perspective view showing a method of winding a signal line around a power line, and FIGS. 10B and 10C are cross-sectional views perpendicular to the axis and an axis-parallel cross section of the power line schematically showing the method. FIG. The signal line 61 in the electromagnetic induction coupling portion having this other configuration is wound around the power line N by the guide member 63.
As shown in FIG. 10C, the guide member 63 is formed by dividing a tubular body 64 wound around the power line N into approximately half in the axial direction of the power line N, and the signal line is provided in the tubular body 64. 61 is loosely inserted. Then, when winding the signal line 61 around the power line N, after the guide member 63 is turned from the front side to the back side of the power line N, the signal line 61 is sequentially inserted into the tubular body 64, whereby the power line A signal line 61 is wound around N. By using such a guide member 63, if the guide member 63 can be turned from the front side even in a place where the back side of the power line N cannot be reached, the signal line 61 can be simply passed through the tube body 64, so that Winding can be performed. Further, since the winding can be performed only from the front surface, the winding operation can be performed more efficiently and safely. Note that the above-described check pieces 53a and 53b may be provided in at least one pair of adjacent inlets on the end side among the pipe bodies 64 arranged in large numbers. As a result, the winding operation can be performed smoothly and the signal line 61 can be prevented from slipping down due to use. Although not shown, the signal line 62 can be wound around the power line M in the same manner.
Furthermore, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 11 is an exploded perspective view illustrating a method of winding a conductive member around a power line in an electromagnetic induction coupling unit having another configuration of the power transfer device. FIG. 12 is a diagram schematically showing the winding method. In the electromagnetic induction coupling portion having the other configuration, the conductive member 71 serving as the signal lines 21 and 22 is formed on the attachment member 72 that is attached to the power lines N and M. The mounting member 72 is made of an electrically insulating material, and a pair of curved members 73 and 74 that are curved in a substantially semicircular arc shape are disposed so that the concave portions thereof face each other, and one end in the circumferential direction is connected by a hinge 75, Since the other end side can be freely opened and closed, a plurality of attachment portions 76 formed so that the power lines N and M can be held in the concave portion are connected by a hinge 75 portion.
The conductive member 71 is formed from the curved members 73 and 74 to the hinge 75 portion, and is electrically connected to the conductive member 71 of the curved members 74 and 73 paired on the other end side of the closed curved members 73 and 74 and loops. And is electrically connected to the conductive member 71 of the adjacent mounting portion 76 at the hinge 75 portion and connected to the next loop. For this reason, as the conductive member 71, a spiral pattern 71 a is formed from one end side to the other end side on the inner circumference or outer circumference (inner circumference in FIG. 11) surface of the bending members 73 and 74. A connection pattern 71b is formed with the attachment portion 76 adjacent to the end surface of the hinge 75 portion, and a connection pattern 71c is formed on the other end side to contact the open ends of the corresponding bending members 74 and 73.
The connection pattern 71c is not formed on the end face on the other end side of the bending members 73, 74 on the outer peripheral side and the edge part on the adjacent bending member 73, 74 side in order to prevent a short circuit. This region is formed wider than the width of the spiral pattern 71a. Further, a locking projection 77 is formed on one end surface of the bending members 73 and 74, and a locking recess 78 is formed on the other end surface, and the end surfaces of the bending members 73 and 74 are abutted and engaged. By fitting the stop protrusion 77 into the locking recess 78, the connection pattern 71c on the bending member 73 side and the connection pattern 71c on the bending member 74 side are securely connected.
Accordingly, as shown in FIG. 12A, after the power lines N and M are disposed in the recesses with the other end sides of the bending members 73 and 74 of the mounting portions 76 open, in FIG. As shown, the mounting member 72 and the conductive member 71 formed thereon can be attached to the power line 2 by closing the other end, and the conductive member 71 is substantially spiral around the power lines N and M. It will be wound into a shape. Thus, the conductive member 71 can be easily wound around the power lines N and M.
If the conductive member 71 is cut at any one of the attachment portions 76, the free end side from the attachment portion 76 does not function as the signal lines 21 and 22, so that the curved members 73 and 74 after attachment are opened. In order to prevent this, a strong locking structure other than the locking protrusion 77 and the locking recess 78 described above may be used, or the entire mounting member 72 may be covered with a spiral electric wire binding tool.
And in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 13 is an exploded perspective view illustrating a method of winding a conductive member around a power line in an electromagnetic induction coupling unit having another configuration of the power transfer device. The conductive member 81 serving as the signal lines 21 and 22 is formed on the attachment member 82 that is attached to the power lines N and M. This mounting member 82 is similar to the mounting member 72 described above. The mounting member 82 is made of an electrically insulating material, and a pair of curved members 83 and 84 curved in a substantially semicircular arc shape are arranged so that the concave portions thereof are opposed to each other and shifted in the axial direction of the hinge 85, A plurality of mounting portions 86 formed so that the power lines N and M can be held in the concave portions are connected by hinges 85.
Accordingly, the pair of bending members 83 and 84 are arranged so as to be shifted in the axial direction of the hinge 85 so that they can intersect at an arbitrary angle, and have an arbitrary diameter within the inner diameter of the bending members 83 and 84. The power lines N and M can be carried. Then, after holding the power lines N and M, the other end sides of the bending members 83 and 84 are fixed so as not to be opened by a fastening band 87 or the like, as shown in FIG.
Therefore, as the conductive member 81, as shown in the exploded perspective view of the bending members 83 and 84 in FIG. 15 and the current path diagram in FIG. 16, the inner periphery or the outer periphery of the bending members 83 and 84 (in FIGS. 15 and 16). On the inner circumferential surface, a connection pattern 81a is formed from one end side to the other end side in the vicinity of the hinge 85, and a connection pattern 81b with a mounting portion 86 adjacent to the end face of the hinge 85 portion is formed on one end side. A connection pattern 81c is formed on the end face on the other end side so as to be in sliding contact with and electrically connected to the end faces of the corresponding bending members 84 and 83, and this connection pattern 81c forms a loop.
By comprising in this way, the electroconductive member 81 can be wound around the electric power lines N and M of arbitrary diameters around it. In addition, it is desirable that the connection pattern 81b and the connection pattern 81c that are in sliding contact with each other between the adjacent bending members 83 and 84 are subjected to conductive brushing or the like so that electrical connection is more reliably performed.
Moreover, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 17 is an exploded perspective view illustrating a structure of a mounting member in an electromagnetic induction coupling portion having another configuration of the power transfer device. This mounting member 92 is similar to the mounting member 82 described above. In the mounting member 82 shown in FIG. 13 to FIG. 16, a plurality of the bending members 83 and 84 are connected by the connecting members 83a and 84a, and a plurality of mounting portions 86 are connected. In the embodiment shown in FIG. 2, the attachment portions 96 made of the bending members 93 and 94 are connected to each other in a desired number at the hinge 85 portion. In the conductive member 81, as shown in FIG. 18, the connection pattern 81 b is provided on one end (hinge 85) side of the bending members 93 and 94 rather than the tangent line 97 of the bending members 93 and 94 passing through the hole 95 corresponding to the hinge 85. The connection pattern 81c is provided on the other end (open end) side of the bending members 93 and 94, so that the connection pattern 81c is located between the adjacent mounting portions 96 on one end (hinge 85) side of the bending members 93 and 94. It is formed so as not to short-circuit. With this configuration, each mounting portion 96 can be attached and detached at the hinge 85 portion. Therefore, the mounting portion 96 formed by forming the conductive member 81 on the pair of bending members 93 and 94 is used as one unit. As a result, it is possible to realize a mounting member capable of adjusting the length (number of turns) by connecting the units.
Furthermore, in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 19 is a diagram illustrating a structure of an electromagnetic induction coupling unit having another configuration of the power transfer device. FIG. 19A is a plan view, and FIG. 19B is a perspective view showing a state wound around a power line. As shown in FIG. 19A, the electromagnetic induction coupling unit 100 includes a main electric wire 101-1 connected to the primary winding T11 of the transformer T1 in the coupling circuit 13, and a plurality of sub branches branched from the main electric wire 101-1. A conductive wire 101-2, a sheet-like support member 102 for supporting the lead wire 101-1 and the plurality of sub-conductive wires 101-2, and for winding the plurality of sub-conductive wires 101-2 around the outer periphery of the power line N; It is configured with. The plurality of sub-conductive lines 101-2 correspond to the signal line 21, and are suitable for transmitting a high-frequency PLC signal (seven lines 101-21 to 101-27 in FIG. 19A), and are mutually connected. The support member 102 is disposed on one side or inside of the support member 102 at a predetermined interval in parallel. The support member 102 is made of a material that transmits electromagnetic waves, for example, resin. In the electromagnetic induction coupling portion 100 having such a configuration, the support member 102 is wound around the power line N so that the plurality of sub conductive wires 101-2 are along the longitudinal direction of the power line N, as shown in FIG. Thus, a plurality of sub conductive lines 101-2 are provided in the circumferential direction on the outer periphery of the power line N. Although not shown, the electromagnetic induction coupling unit 100 having the same configuration shown in FIG. With such a configuration, a plurality of sub conductive wires 101-2 along the longitudinal direction of the power lines N and M are provided in the circumferential direction on the outer periphery of the power lines N and M. Since 101-2 can interact with the power lines N and M, a high-frequency PLC signal propagating on the surface of the metal conductor in the power lines N and M by the so-called skin effect is generated by the signal lines 21 and 22 (the plurality of sub conductive lines 101). -2) and the power lines N and M are efficiently transmitted to each other in a non-junction manner.
And in the above-mentioned embodiment, you may comprise the electromagnetic induction coupling part 2 as follows. FIG. 20 is a diagram illustrating a structure of an electromagnetic induction coupling unit having another configuration of the power transfer device. FIG. 20A shows a case where a loop is not formed, and FIG. 20B shows a case where a loop is formed. In FIG. 20, the electromagnetic induction coupling unit 110 includes signal lines 111 and 112 along the longitudinal direction of the power lines N and M, and annular magnetic cores 113 and 114 through which the power lines N and M and the signal lines 111 and 112 are inserted, respectively. Composed. The annular magnetic cores 113 and 114 are made of a magnetic material such as ferrite, for example. The signal lines 111 and 112 correspond to the signal lines 21 and 22. Even with such a configuration, a non-junction high-frequency PLC signal can be transmitted between the signal lines 111 and 112 and the power lines N and M. As shown in FIG. 20B, the signal lines 111 and 112 of the electromagnetic induction coupling unit 110 have two power lines N and M of the same system as one set, and their free ends are connected by a short-circuit line 115. The signal lines 111 and 112 and the short-circuit line 115 may be formed in a loop shape.
Further, in the above-described embodiment, the electromagnetic induction coupling unit 2 is connected between the free ends of the signal lines 21 and 22, as shown in FIG. 21, and impedance that substantially matches the characteristic impedance of the power lines N and M. An impedance matching unit 24 having a value may be further provided. Since the electromagnetic inductive coupling unit 2 further includes such an impedance matching unit 24, the PLC device A performs impedance matching (matching) with the characteristic impedance of the power lines N and M. Transmission between the power lines N and M is more efficient. And the electromagnetic induction coupling parts 30, 100, and 110 can be similarly configured.
The impedance matching unit 24 may be manufactured by matching the impedance value with the characteristic impedance of the power lines N and M on which the electromagnetic induction coupling unit 2 is arranged, but may be configured so that the impedance value can be changed. The impedance matching unit 24 includes, for example, a series circuit of a capacitor and a coil whose inductance can be changed, or a parallel circuit thereof. By providing the impedance matching unit 24 having such a variable impedance value, the impedance value can be adjusted to the characteristic impedance of the power lines N and M on which the electromagnetic induction coupling unit 2 is arranged. , The impedance value can be matched to the characteristic impedance of M. Moreover, since the impedance value can be matched with the characteristic impedance of each of the power lines N and M on which the electromagnetic induction coupling unit 2 is arranged, versatility can be given to the electromagnetic induction coupling unit 2.
Furthermore, in the above-described embodiment, the PLC device main body 1 and the electromagnetic induction coupling unit 2 are each provided with connectors 19-1 and 19-2 indicated by broken lines in FIG. The connector 19 may be connected. And the electromagnetic induction coupling parts 30, 100, and 110 can be similarly configured.
It is a block diagram which shows the structure of the power line carrier communication apparatus which concerns on embodiment. (A) is a graph showing the injection loss at each frequency when the winding pitch of the signal line wound around the power line and the gap between the power line and the signal line (the winding diameter of the signal line) are changed, (B) is a graph showing the injection loss at each frequency when the winding pitch of the signal line wound around the power line and the gap between the power line and the signal line (the winding diameter of the signal line) are changed. It is a figure for demonstrating the experimental method for obtaining the data of Fig.2 (a) and FIG.2 (b). It is a figure which illustrates typically the winding pitch of the signal line for obtaining the data of Drawing 2 (a) and Drawing 2 (b), and the crevice between a power line and a signal line. (A) The case where the signal wire winding pitch and the gap between the power line and the signal line are fixed, and the signal line free end is opened (FIG. 1), and the signal line is short-circuited (FIG. 1). 5 (b)) is a graph showing an injection loss. (B) shows the injection loss when the signal wire winding pitch around the power line and the gap between the power line and the signal line are constant, and when the free end of the signal line is opened and when the signal line is short-circuited. It is a graph. (C) shows the injection loss when the signal line winding pitch and the gap between the power line and the signal line are constant and the signal line free end is opened and when the signal line is short-circuited. It is a graph. It is a figure which shows the other structure of the electromagnetic induction coupling part in an electric power carrier. It is a figure which shows the winding method to the power line of the signal wire | line in the electromagnetic induction coupling part of the other structure of an electric power carrier. It is a figure which shows the winding method to the power line of the signal wire | line in the electromagnetic induction coupling part of the other structure of an electric power carrier. It is sectional drawing which shows an example of the internal structure of the fastening member used for the winding shown in FIG. It is a figure which shows the winding method to the power line of the signal wire | line in the electromagnetic induction coupling part of the other structure of an electric power carrier apparatus. It is a disassembled perspective view which shows the winding method to the electric power line of the electrically-conductive member in the electromagnetic induction coupling part of the other structure of an electric power conveying apparatus. It is a figure which shows typically the winding method of FIG. It is a disassembled perspective view which shows the winding method to the electric power line of the electrically-conductive member in the electromagnetic induction coupling part of the other structure of an electric power conveying apparatus. It is a figure which shows the winding method of FIG. It is a disassembled perspective view of the bending member which implement | achieves the winding method of FIG. FIG. 16 is a current path diagram of FIG. 15. It is a disassembled perspective view which shows the structure of the attachment member in the electromagnetic induction coupling part of the other structure of an electric power carrier apparatus. It is a figure for demonstrating the formation method of the signal wire | line in the attachment member shown in FIG. It is a figure which shows the structure of the electromagnetic induction coupling part of the other structure of an electric power carrier apparatus. It is a figure which shows the structure of the electromagnetic induction coupling part of the other structure of an electric power carrier apparatus. It is a figure which shows the structure of the electromagnetic induction coupling part provided with an impedance matching part. (A) is a block diagram which shows the 1st structure of the power line carrier communication system of patent document 1. FIG. (B) is a block diagram showing a second configuration of the power line carrier communication system described in Patent Literature 1. FIG. It is a block diagram of a system for transmitting digital data via a general power supply main line using the transmission circuit described in Patent Document 2.
DESCRIPTION OF SYMBOLS 1 Power line carrier communication main-body part 2, 30, 100, 110 Electromagnetic induction coupling part 11 Power line carrier communication modem part 12 Battery 21, 22, 31, 32, 41, 51, 61, 111, 112 Signal line 23, 115 Short-circuit line 24 Impedance matching part 31a, 32a, 41a Winding part 31b, 32b, 41b Drawer part 19, 33, 34 Connector 51, 51a, 51b, 52 Fastening member 53a, 53b Non-return piece 54 Connecting piece 61 Guide member 62 Tube 71 81 Conductive member 71a Spiral pattern 71b Connection pattern 71c Connection pattern 72, 82, 92 Mounting member 73, 74, 83, 84, 93, 94 Bending member 75, 85 Hinge 76, 86, 96 Mounting portion 77 Locking projection 78 Locking recess 81a Connection pattern 81b Connection pattern 81c Connection pattern 87 Wearing band 101 conductive wire 102 supporting members 113, 114 annular electromagnetic core
An electromagnetic induction coupling unit that transmits a communication signal of power line carrier communication to and from the power line by electromagnetic induction;
By demodulating the communication signal of the power line carrier communication extracted from the power line via the electromagnetic inductive coupling unit, information contained in the communication signal of the power line carrier communication is extracted, and the power line carrier according to the information to be transmitted A power line carrier communication modem unit that generates a communication signal of power line carrier communication by modulating a carrier wave of communication and injects the generated communication signal of power line carrier communication into the power line via the electromagnetic inductive coupling unit;
A battery for supplying power to the power line carrier communication modem unit as a driving power source,
The electromagnetic induction coupling portion is a signal line wound around the power line ,
The signal line is a winding portion wound around the power line, it is divided into a lead portion of the residual, power line communication apparatus between them and said available Der Rukoto connected by a connector.
2. The power line carrier communication device according to claim 1, wherein one end of each of the signal lines is connected to each other with a pair of two power lines of the same system.
The signal line is formed in a spiral shape having an inner diameter that is larger than the outer diameter of the power line by a predetermined value, and after the power line is inserted inside the spiral from between the spiral loops, By pulling both ends of the signal line in the direction away from the power line, the signal line is in close contact with the power line, the tightly attached portion becomes the winding portion, and the non-contacted portion becomes the lead-out portion. The power line carrier communication apparatus according to claim 1 or 2 , wherein
At least a winding start end and a winding end end of the signal line include a fastening member through which the signal line is inserted,
At least one of the inner peripheral surface of the fastening member and the outer peripheral surface of the signal line has a check piece for preventing the loop from loosening so that the power line is fastened by the loop of the signal line at the end thereof. The power line carrier communication device according to any one of claims 1 to 3 , wherein the power line carrier communication device is characterized by the following.
Claim wherein comprises a tubular body which is wound around the power line is divided into approximately half the axial direction of the power line, the said tube body, characterized by further comprising a guide member in which the signal line is loosely inserted The power line carrier communication apparatus according to claim 1 or 2 .
At least one pair of tubular body adjacent to tighten the power lines routed signal lines of the loop between those of the tube, according to claim characterized in that it has a check piece locking of said loop 5 power line communication apparatus according to.
An electromagnetic induction coupling unit that transmits a communication signal of power line carrier communication to and from the power line by electromagnetic induction ;
By demodulating the communication signal of the power line carrier communication extracted from the power line via the electromagnetic inductive coupling unit, information contained in the communication signal of the power line carrier communication is extracted, and the power line carrier according to the information to be transmitted A power line carrier communication modem unit that generates a communication signal of power line carrier communication by modulating a carrier wave of communication and injects the generated communication signal of power line carrier communication into the power line via the electromagnetic inductive coupling unit ;
A battery for supplying power to the power line carrier communication modem unit as a driving power source ,
The electromagnetic induction coupling portion is made of an electrically insulating material, and a pair of curved members curved in a substantially semicircular arc are arranged so that the concave portions face each other, and one end in the circumferential direction is connected by a hinge, and the other end By providing a mounting member formed by connecting a plurality of mounting portions formed by the hinge portion so that the power line can be held in the concave portion by allowing the side to be opened and closed, from the bending member to the hinge portion, A loop is formed by electrically connecting to the signal line of the bending member that forms a pair on the other end side of the closed bending member, and the next loop is electrically connected to the signal line of the adjacent mounting portion at the hinge portion. A signal line to be connected is formed, and a communication signal of the power line carrier communication is injected from the signal line to the power line.
The pair of bending members are arranged so as to be shifted in the axial direction of the hinge so that they can intersect at an arbitrary angle, and the signal lines in the bending members are paired at the opposing end surfaces of the bending members. The power line carrier communication device according to claim 7 , wherein the power line carrier communication device according to claim 7 , wherein the power line carrier communication device is slidably contacted with a signal line of a member and electrically connected.
The power line carrier communication device according to claim 7 or 8 , wherein the attachment portion is detachable at the hinge portion.
The electromagnetic induction coupling unit includes a plurality of signal lines along the longitudinal direction of the power line in the circumferential direction on the outer periphery of the power line.
The power line according to any one of claims 1 to 10 , wherein the electromagnetic inductive coupling unit further includes an impedance matching unit having an impedance value that substantially matches an impedance of a characteristic impedance of the power line. Carrier communication device.
The power line carrier communication device according to claim 11 , wherein the impedance matching unit has a variable impedance value.
Wherein the electromagnetic induction coupling portion and the power line communication modem unit is provided with a connector, power line communication apparatus according to any one of claims 1 to 12, characterized in that detachable by the connector .
JP2005306133A 2005-10-20 2005-10-20 Power line carrier communication equipment Expired - Fee Related JP4611172B2 (en)
JP2005306133A JP4611172B2 (en) 2005-10-20 2005-10-20 Power line carrier communication equipment
JP2007116464A JP2007116464A (en) 2007-05-10
JP4611172B2 true JP4611172B2 (en) 2011-01-12
ID=38098244
JP2005306133A Expired - Fee Related JP4611172B2 (en) 2005-10-20 2005-10-20 Power line carrier communication equipment
JP (1) JP4611172B2 (en)
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