JP6159623B2 - Automatic meter reading system - Google Patents

Description

  The present invention relates to a power usage metering system using PLC (Power Line Communication).

  In recent years, in electric power companies, introduction of an automatic meter-reading system that collects the amount of power used by each consumer from a remote location is being advanced (for example, see Patent Document 1).

  In the automatic meter reading system, a master PLC modem (hereinafter referred to as a master meter PLC modem for meter reading) is attached to a utility pole or the like, and a slave PLC modem for transmitting meter reading data to the master PLC modem (hereinafter referred to as a slave meter slave meter). A PLC modem) is built into each consumer's power meter. Since these PLC modems use a power line connecting a power pole and a power meter as a communication path, there is no need to newly lay a communication line, which is very advantageous in terms of introduction cost.

  On the other hand, interest in power saving is increasing from an ecological point of view, and an increasing number of homes are introducing HEMS (Home Energy Management System) that realizes optimal energy management using IT (for example, Patent Document 2).

  In HEMS, a HEMS server as a central control device is used. The HEMS server automatically controls the home appliances such as air conditioners while monitoring the operating status and power consumption. According to HEMS, energy supply and demand can be visualized, and electricity can be automatically controlled to save electricity while maintaining the comfort of life.

JP 2011-223063 A JP 2011-254229 A

  In HEMS, there is a demand for acquiring power amount data from a power meter in order to grasp the total power consumption in the home. However, since the electric power meter and the automatic meter reading system are operated under the control of the electric power company and the HEMS is a closed system in each home, mutual cooperation is difficult.

  Therefore, a method in which a HEMS slave PLC modem is installed in the power meter, the HEMS master PLC modem is connected to the HEMS server, and the HEMS server communicates with the power meter regardless of the automatic meter reading system is being studied. . In this case, when a transmission request for power amount data is transmitted from the HEMS server to the power meter via the master-slave device PLC modem, the procedure is previously performed so that the power meter transmits the power amount data to the HEMS server. Just set it up. According to this method, it is possible to use power amount data on the HEMS side.

  However, when the power meter transmits power amount data to the HEMS server via the HEMS slave PLC modem and the HEMS master PLC modem, the transmission signal of the HEMS slave PLC modem is connected to the same power line. There is a problem in that it reaches the PLC modem of the other customer's meter reading. At this time, if another meter-reading slave device PLC modem is communicating with the meter-reading master device PLC modem, there is a possibility that signals interfere with each other, resulting in a communication failure. An automatic meter reading system is required to reliably collect meter reading data with an extremely high yield. To that end, it is necessary to thoroughly eliminate the cause of communication failure.

  Therefore, an object of the present invention is to realize power line communication using a PLC modem between a power meter and a HEMS server, while suppressing a communication failure between a master unit and a slave unit PLC modem on the meter reading system side. An object of the present invention is to provide an automatic meter reading system capable of increasing the yield.

  In order to solve the above-mentioned problems, an automatic meter reading system according to the present invention includes a plurality of power meters that measure power consumption of a power consumer, and a first power amount data collected from each of the plurality of power meters. A first PLC modem connected to the first server, and a plurality of first modems connected to each of the plurality of power meters and communicating with the first PLC modem via a power line. 2 PLC modems, a second server for managing household power, a third PLC modem connected to the second server, and the second server among the plurality of power meters. A fourth PLC modem connected to the first power meter in the home and communicating with the third PLC modem via the power line, wherein the first power meter is connected to the first server; And said Information about a communication period with a number of power meters is transmitted to the second server, and the second server transmits the power amount data transmission request to the first power meter before the communication. It is determined whether or not a period during which the transmission request is transmitted overlaps with a communication period between the first server and one of the plurality of power meters based on information regarding a period, and if there is an overlap, the transmission request is transmitted. And the transmission request is transmitted when there is no duplication.

  According to the present invention, the transmission request is transmitted only when the period during which the second server attempts to transmit the transmission request for the electric energy data does not overlap with the communication period on the meter reading side system side. The communication meter between the first and second PLC modems on the meter reading system side can be suppressed while increasing the yield of meter reading data while realizing power line communication using a PLC modem between the power meter and the second server. it can.

  In the present invention, each of the plurality of power meters holds communication schedule data for the first server to collect the first power amount data from each of the plurality of power meters. The first power meter generates a communication prohibition period setting signal for setting a period for prohibiting communication between the second server and the first power meter as information on the communication period with reference to the communication schedule data. The second server transmits the transmission request based on the communication prohibition period setting signal, the first server and the plurality of power meters. It is preferable to determine whether or not the communication period overlaps with either one. According to this configuration, communication timing between the second server on the HEMS side and the first power meter can be generated using the communication schedule used on the meter reading system side, and the first meter on the meter reading system side can be generated. -A communication failure between the second PLC modems can be reliably avoided.

In the present invention, it is preferable that the first power meter transmits the communication prohibition period setting signal every time when the first server does not communicate with any of the plurality of power meters. According to this, since it is only necessary to set the communication prohibition period at the timing when the communication prohibition period setting signal is received, the communication prohibition period can be easily set and managed.

  In the present invention, each of the plurality of power meters holds communication schedule data for the first server to collect the first power amount data from each of the plurality of power meters. The server acquires and holds the communication schedule from the first power meter as information relating to the communication period, and the period for transmitting the transmission request is based on the communication schedule and the plurality of the transmission period. It is preferable to determine whether or not it overlaps with the communication period with any of the power meters. According to this, the second server itself can grasp the communication schedule on the meter reading system side and can reliably prevent communication troubles in the meter reading system.

  In the present invention, before the first power meter transmits the second power amount data to the second server in response to the transmission request for the power amount data transmitted from the second server. , Determining whether a period for transmitting the second power amount data overlaps with a communication period between the first server and another power meter, and if it overlaps, does not respond to the transmission request, When there is no overlap, it is preferable to transmit the second power amount data in response to the transmission request. According to this, even if the first power meter receives the transmission request of the power amount data from the second server, it tries to transmit the power amount data from the first power meter to the second server. When the period to be overlapped with the communication period on the meter reading side system side, the transmission request is ignored and the second power amount data is not transmitted from the first power meter. Therefore, it is possible to further suppress the communication failure between the first and second PLC modems on the meter reading system side and increase the yield of meter reading data.

  In the present invention, the first server creates in advance communication schedule data for periodically collecting the first power amount data from each of the plurality of power meters, and the communication schedule data is stored in the plurality of power meters. It is preferable to distribute toward the power meter. According to this configuration, automatic meter reading to the plurality of power meters by the first server can be reliably performed according to the communication schedule, and meter-reading data can be reliably collected with a very high yield.

  According to the present invention, while realizing power line communication using a PLC modem between a power meter and a HEMS server, a communication failure between a master unit and a slave unit PLC modem on the meter-reading system side is suppressed, and the yield of meter-reading data is increased. It is possible to provide an automatic meter-reading system capable of increasing the speed.

FIG. 1 is a schematic diagram showing a configuration of an automatic meter reading system according to a preferred embodiment of the present invention. FIG. 2 is a block diagram functionally showing the configuration of the PLC modem. FIG. 3 is a sequence diagram for explaining the transmission procedure of the electric energy data.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic diagram showing a configuration of an automatic meter reading system according to a preferred embodiment of the present invention.

  As shown in FIG. 1, the automatic meter reading system 1 according to the present embodiment is for measuring the amount of power used in each of the doors 10 a to 10 d of the apartment house 10, for example. PLC modem 11 (first PLC modem), meter-reading cordless handset PLC modems 13a-13d (second PLC modem) and HEMS cordless handset PLC modems 14a-14d built in the power meters 12a-12d of each house (Fourth PLC modem), a HEMS server 17 installed in a home where HEMS is introduced, and a HEMS master PLC modem 18 (third PLC modem) for realizing power line communication in the HEMS server 17 I have.

  The electric power supplied from the substation 3 is supplied to the consumer electronics devices 9a to 9d of the respective consumers a to d via the pole transformer 4, the power lead-in wire 5a, the power meters 12a to 12d, and the breakers 16a to 16d. . One communication terminal of the meter-reading master device PLC modem 11 is connected to the meter-reading server 7 (first server) via the optical network 6, for example, and the other communication terminal is connected to the power lead-in line 5a.

  One communication terminal of the meter-reading slave PLC modems 13a to 13d in the power meters 12a to 12d is connected to the controllers 15a to 15d of the corresponding power meters 12a to 12d, respectively, and the other communication terminal is the power lead-in wire 5a. It is connected to the. Similarly, the HEMS handset PLC modems 14a to 14d have one communication terminal connected to the controller 15a to 15d of the corresponding power meter 12a to 12d, and the other communication terminal connected to the power lead-in line 5a. ing.

In the case where the handset PLC modem is built into the power meter 12 a to 12 d, the controller 15a~15b is positioned as narrow sense of the power meter to those of the PLC modem, meter reading handset PLC modem 13a~13d and HEMS The slave unit PLC modems 14a to 14b are connected to a power meter in a narrow sense, and the operation of the controllers 15a to 15d can be considered to be equivalent to the operation of the power meters 12a to 12d.

  In this embodiment, the consumer a has introduced HEMS, and the HEMS server (second server) 17 is installed only in the customer a's home. The HEMS server 17 is connected to individual home appliances 9a in the home via a short-range wireless network 8 such as ZigBee (registered trademark). One communication terminal of the HEMS main unit PLC modem 18 is connected to the HEMS server 17, and the other communication terminal is connected to the power line 5b in the house. In many cases, the HEMS server 17 and the HEMS master PLC modem 18 are installed near a distribution board (not shown).

  FIG. 2 is a block diagram functionally showing the configuration of the PLC modem (power line modem). The PLC modem 20 is a general-purpose one that can be used as the meter-reading master device PLC modem 11, meter-reading slave device PLC modems 13a to 13d, HEMS slave device PLC modems 14a to 14d, and HEMS master device PLC modem 18. It is.

  As shown in FIG. 2, the PLC modem 20 includes a control unit 21, a memory 22, an interface (I / F) 23, a communication unit 24, a modulation unit 25, a transmission unit 26, a demodulation unit 27, a reception unit 28, and a multiplexer 29. Have.

  The control unit 21 acquires various types of information from the host device and controls each unit of the PLC modem 20 based on the acquired information. The host device here refers to the meter-reading server 7 for the meter-reading master device PLC modem 11, and the HEMS server 17, the meter-reading slave device PLC modem 13 a and the HEMS slave device PLC modem for the HEMS master-device PLC modem 18. If it is 14a, it is the controller 15a of the electric power meter 12a.

  The memory 22 is a storage unit that stores data input from the host device in accordance with an instruction from the control unit 21. Various information including setting information is recorded in the memory 22.

  The interface unit 23 is an interface with a higher-level device, receives higher-layer data from the higher-level device, and outputs it to the communication unit 24. Also, the upper layer data is received from the communication unit 24 and is output to the upper device.

  The communication unit 24 is a functional unit that processes transmission / reception signals including a header, and is configured by, for example, a DSP (Digital Signal Processor). Specifically, the upper layer data to be transmitted is received from the interface unit 23, a header including pilot data, a destination MAC address, and the like, and redundant data for error correction are added, and the modulation unit is transmitted as transmission data. 25. In addition, receiving data including a header and higher layer data is input from the demodulator 27, and processing and error correction processing corresponding to the header in the received data are performed, and higher layer data is output to the interface unit 23.

  The modulation unit 25 selects one modulation method from the OFDM modulation method and the phase modulation method in accordance with an instruction from the control unit 21. Then, using one selected modulation method, the carrier signal is modulated based on the transmission data, a predetermined preamble including a known synchronization signal corresponding to the modulation method is added, and the radio wave law enforcement regulations (carrier output) ), The amplitude of the signal is controlled in accordance with the communication method used for the modulation process, and then output to the transmitter 26.

  The transmission unit 26 has a function of converting the signal input from the modulation unit 25 into a signal that can be transmitted to the power line, and then transmitting the signal to the power line. Specifically, the digital signal input from the modulation unit 25 is converted into an analog signal, an unnecessary frequency band component is removed using a bandpass filter, and the multiplexer 29 is further amplified by a predetermined amplification factor. To the power line.

  The receiving unit 28 has a function of receiving a signal arriving on the power line, converting it to a digital signal, and outputting the digital signal to the demodulating unit 27. Specifically, unnecessary high and low frequency components are removed from the signal received through the multiplexer 29 using a band pass filter, further amplified with a predetermined amplification factor, sampled and converted into a digital signal, and demodulator 27.

  The demodulator 27 has a function of demodulating the digital signal input from the receiver 28 using an OFDM modulation scheme and a phase modulation scheme. The demodulator 27 outputs a signal obtained by demodulation to the communication unit 24. The demodulator 27 has a synchronization detection function for detecting a known synchronization signal from the signal input from the receiver 28. The synchronization signal detected here is an OFDM modulation system synchronization signal or a phase modulation system synchronization signal, and the demodulation unit 27 determines a modulation system to be used for demodulation from the detected synchronization signal.

  In the automatic meter reading system, power line communication in a low frequency band of 10 kHz to 450 kHz is used. Among the modulation schemes used in this power line communication, the OFDM (Orthogonal Frequency Division Multiplexing) modulation scheme uses the full band of 10 kHz to 450 kHz and can perform adaptive modulation for each subcarrier. Although it has an advantage that it can realize relatively high-speed and highly reliable communication, the total output value of all subcarriers is limited to 100 mW or less in the Radio Law Enforcement Rules. Further, in the phase modulation method (including phase amplitude modulation method) using 115 kHz or 132 kHz, the carrier wave output is limited to 350 mW or less. The phase modulation method can only communicate at a lower speed than the OFDM modulation method, but is effective for communication in a noisy environment and communication with a distant place. Furthermore, the carrier wave output is limited to 10 mW or less in the spread spectrum method of 200 kHz to 450 KHz, and the carrier wave output is limited to 30 mW or less in the spread spectrum method of 10 kHz to 200 kHz.

  Thus, although the maximum level of the carrier wave output is defined in the power line communication, the meter reading system side usually performs communication at the maximum level for reliable communication. On the other hand, in order to prevent signal interference with the meter reading system side on the HEMS side, it is preferable to output the transmission signal at a lower output level than the transmission signal on the meter reading system side. Is possible. This is because, as will be described later, communication between the HEMS server and the power meter is not performed during the communication period on the meter-reading system side, but only during idle time.

  In the configuration of FIG. 1, the automatic meter reading method by the electric power company is the same as the conventional one. That is, meter reading data (first power amount data) of each door is measured by the power meters 12a to 12d, transmitted to the meter reading master unit PLC modem 11 via the meter reading slave unit PLC modems 13a to 13d, and further to the optical network. 6 to the meter reading server 7 via The power amount data may be transmitted in response to a request from the meter-reading server 7, or the power meters 12a to 12d may spontaneously transmit at a predetermined timing. Thereby, meter reading data of each house is automatically collected.

  Next, a method for acquiring power amount data by the HEMS server 17 will be described.

  The HEMS server 17 can communicate with the power meter 12a (first power meter) via the HEMS master device PLC modem 18 and the HEMS slave device PLC modem 14a. When the HEMS server 17 transmits a transmission request for the power amount data to the power meter 12a, the power meter 12a returns the power amount data (second power amount data) to the HEMS server 17. However, the power amount data transmitted from the HEMS handset PLC modem 14a is not limited to the power meter 12a, but the power meters of other consumers b to d connected to the same power line 5 (5a, 5b). 12b-12d will be reached. Therefore, if the meter-reading server 7 is communicating with any one of the power meters 12a-12d via the meter-reading master PLC modem 11 and the meter-reading slave PLC modems 13a-13d, the signal interferes and communicates. As described above, it becomes an obstacle. Therefore, in this embodiment, the following measures are taken to suppress such interference.

  FIG. 3 is a sequence diagram for explaining the transmission procedure of the electric energy data.

As shown in FIG. 3, the meter-reading server 7 first generates a communication schedule (meter-reading schedule) with the power meters 12a to 12d of each consumer, and performs automatic remote meter-reading according to the schedule. Communication schedule is a repeating unit a predetermined time (e.g. 30 minutes), in which the meter reading time of each power meter is assigned to the unit period T within _0. Then, the remaining time of meter reading time is not assigned one of the unit period T ₀ is the "free time". The time allotted to the meter reading of one electric power meter is several seconds or less. Here, four power meters 12a to 12d are targeted, and the number thereof is very small, but actually, more power meters can be targeted for meter reading.

  The communication schedule can be arbitrarily set within the unit period T0. For example, as shown in the figure, the meter readings of the four power meters 12a to 12d may be performed continuously. Also, after the meter readings of the two power meters 12a and 12b are continuously performed, a free time is provided, and then the meter readings of the other two power meters 12c and 12d are continuously performed, and then a free time is provided again. It may be. Furthermore, a free time may be provided each time meter reading of each power meter is completed.

  The meter-reading server 7 distributes the communication schedule data to the power meters 12a to 12d when a communication schedule is newly created or changed. The communication schedule data from the meter-reading server 7 is transmitted to the power meters 12a to 12d of the respective consumers a to d via the meter-reading master device PLC modem 11 and the meter-reading slave devices PLC modems 13a to 13d. ˜12d hold this communication schedule data in advance.

Next, the controller 15a of the power meter 12a refers to the communication schedule held by itself and determines whether or not the current time is “free time”. If it is determined that the present time is idle time, the controller 15a of the power meter 12a transmits a communication prohibition period setting signal S1 to the HEMS server 17 immediately before the idle time ends. Information Here, "transmission prohibition period setting signal" is a signal for setting the transmission prohibition period between HEMS server 17 and the power meter 12a, in the present embodiment for defining the meter reading time end time t ₂ Is included.

In the present embodiment, the communication prohibition period setting signal S1 is transmitted immediately before the idle time ends, and the communication prohibition period is started using the reception of this signal as a trigger. Information regarding the start time t ₁ may not be included, but information regarding the meter reading time start time t ₁ may be included. In the present embodiment, the HEMS server 17 itself does not hold the communication schedule data, and simply determines whether or not to allow communication according to a command from the power meter 12a.

HEMS server 17 which has received the transmission prohibition period setting signal, during the period from the reception of the transmission prohibition period setting signal to the meter reading time completion time t _2, the do not communicate with the power meter 12a. Therefore, the HEMS server 17 that tries to acquire the power amount data first determines whether or not the current time is the communication prohibited period, and does not transmit the power amount data transmission request R1 if it is the communication prohibited period. If it is idle time, a transmission request R1 of power amount data is transmitted to the power meter 12a. That is, before transmitting the transmission request R1 of the electric energy data to the power meter 12a, the HEMS server 17 has a period during which the transmission request R1 is transmitted as a communication period between the meter-reading server 7 and one of the power meters 12a to 12d. It is determined whether or not they overlap. If they overlap, the transmission request R1 is not transmitted. If they do not overlap, the transmission request R1 is transmitted.

  The transmission request R1 of the electric energy data from the HEMS server 17 is sent to the controller 15a of the power meter 12a via the HEMS main unit PLC modem 18 and the HEMS sub unit PLC modem 14a. The controller 15a of the power meter 12a that has received the power amount data transmission request R1 refers to the communication schedule and determines whether or not the present time is a free time. As shown in the figure, when it is determined that the present time is idle time, the power meter 12a transmits the power amount data D1 to the HEMS server 17 in response to the request. The electric energy data D1 is sent to the HEMS server 17 via the HEMS slave device PLC modem 14a and the HEMS master device PLC modem 18. On the other hand, when it is determined that the present time is not the idle time but the communication period (meter reading time) between the meter reading server 7 and one of the power meters 12a to 12d, the power meter 12a ignores the transmission request R1 and does not respond. And

  As described above, when the timing at which the HEMS server 17 transmits the transmission request R1 of the electric energy data overlaps with the timing at which one of the meter-reading slave PLC PLC and the meter-reading master PLC modem 11 communicates, Since transmission of the transmission request R1 is not performed, it is possible to reliably prevent interference with communication on the meter-reading system side.

  The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention, and it goes without saying that these are also included in the present invention. Yes.

  For example, in the above-described embodiment, the power meter 12a transmits a communication prohibition period setting signal S1 for setting the next communication prohibition period every time a free time comes, and the HEMS server 17 itself does not hold communication schedule data. Although communication permission / inhibition is simply determined according to a command from the power meter 12a, the present invention is not limited to such a configuration. Therefore, for example, the HEMS server 17 acquires and holds the communication schedule data from the power meter 12a, and the period during which the transmission request for the power amount data is transmitted based on the communication schedule is the meter reading server 7 and the plurality of power meters 12a to 12m. You may make it determine whether it overlaps with the communication period with either of 12d. In this case, the power meter 12a does not need to transmit the communication schedule data until the communication schedule is changed, and the HEMS server 17 refers to the communication schedule data to set the communication prohibition period. Troubles can be avoided in advance, and the reliability of the system can be improved. Therefore, it is effective when the number of meter readings is very large and the idle time is small.

  In the above embodiment, the meter-reading slave device PLC modems 13a to 13d and the HEMS slave device PLC modems 14a to 14d are built in the power meters 12a to 12d. It may be an external type. The power meters 12a to 12d incorporate two PLC modems, a meter reading slave unit PLC modems 13a to 13d and a HEMS slave unit PLC modems 14a to 14d, respectively. You may use both. In this case as well, the timing at which the slave PLC modem communicates with the HEMS master PLC modem should not overlap with the timing at which the slave PLC modem communicates with the meter-reading master PLC modem.

  In the above embodiment, for convenience of explanation, only the consumer a introduces HEMS, and the HEMS server (second server) 17 is installed only in the customer a's home. It goes without saying that the persons b to d may introduce HEMS.

DESCRIPTION OF SYMBOLS 1 Automatic meter-reading system 2 Electric pole 3 Substation 4 Pole transformer 5a, 5b Power line 6 Optical network 7 Meter-reading server 8 Short-range wireless network 9a-9d Home appliance 10 Apartment house 10a-10d Electric power consumer's door 11 PLC for meter-reading PLC Modem 12a-12d Electric power meter 13a-13d Slave meter PLC modem (second PLC modem)
14a to 14d HEMS slave PLC modems 15a to 15d Controllers 16a to 16d Breaker 17 HEMS server 18 HEMS master PLC modem 20 PLC modem 21 Controller 22 Memory 23 Interface unit 24 Communication unit 25 Modulator 26 Transmitter 27 Demodulator 28 Receiver 29 Multiplexer

Claims (6)

A plurality of power meters that measure the power consumption of power consumers;
A first server for collecting first power amount data from each of the plurality of power meters;
A first PLC modem connected to the first server;
A plurality of second PLC modems connected to each of the plurality of power meters and communicating with the first PLC modem via a power line;
A second server for managing power in the home;
A third PLC modem connected to the second server;
A fourth PLC modem that is connected to a first power meter in a home where the second server is introduced among the plurality of power meters and communicates with the third PLC modem via the power line; Prepared,
The first power meter transmits information related to a communication period between the first server and the plurality of power meters to the second server,
The second server transmits the transmission request based on information related to the communication period before transmitting a transmission request for power amount data to the first power meter. It is determined whether or not it overlaps with a communication period with any one of a plurality of power meters. system. Each of the plurality of power meters holds communication schedule data for the first server to collect the first power amount data from each of the plurality of power meters,
The first power meter refers to the communication schedule data, and sets a period during which communication between the second server and the first power meter is prohibited as information related to the communication period. And send it to the second server,
The second server determines, based on the communication prohibition period setting signal, whether a period during which the transmission request is transmitted overlaps with a communication period between the first server and one of the plurality of power meters. The automatic meter reading system according to claim 1.   The automatic meter reading system according to claim 2, wherein the first power meter transmits the communication prohibition period setting signal every time when the first server does not communicate with any of the plurality of power meters. . Each of the plurality of power meters holds communication schedule data for the first server to collect the first power amount data from each of the plurality of power meters,
The second server acquires and holds the communication schedule data from the first power meter as information relating to the communication period, and a period during which the transmission request is transmitted is based on the communication schedule data . The automatic meter-reading system according to claim 1, wherein it is determined whether or not a communication period between the server and any of the plurality of power meters overlaps. The first power meter transmits the second power amount data to the second server in response to the transmission request for the power amount data transmitted from the second server. It is determined whether or not the period for transmitting the power amount data overlaps with the communication period between the first server and any of the plurality of power meters , and in the case of overlap, does not respond to the transmission request, The automatic meter-reading system according to any one of claims 1 to 4, wherein when there is no duplication, the second power amount data is transmitted in response to the transmission request.   The first server creates in advance communication schedule data for periodically collecting the first power amount data from each of the plurality of power meters, and directs the communication schedule data to the plurality of power meters. The automatic meter reading system according to any one of claims 2 to 5, wherein the automatic meter-reading system is distributed.

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