JP6841593B2 - Meter reading system - Google Patents

Description

The present invention relates to a meter reading system that collects and transmits meter reading data of electricity, gas, and water.

Meter reading data for electricity, gas, and water can be obtained from each meter terminal, but it is inefficient to obtain meter reading data separately from each meter terminal. Therefore, in recent years, these meter reading data have been collected and meter reading data. It has been proposed to transmit to the center. For example, Patent Document 1 describes a system that collects meter reading data of electricity, gas, and water from each meter terminal and transmits these to a meter reading data center.

Japanese Patent No. 3862638

Since the meter reading system of Patent Document 1 transmits the meter reading data of electricity, gas, and water collected from the meter terminal to the meter reading data center using a repeater, it is necessary to install a repeater, which increases the equipment cost. I will invite you. Further, since it is necessary to supply power to the repeater or replace the internal battery, not only troublesome work such as formation of a power supply path or battery replacement is required, but also equipment cost increases. In addition, currently known electronic water meter terminals have a function of detecting information other than normal integrated data, but they are not fully utilized, and increasing the amount of information to be transmitted shortens the replacement life of the internal battery. It has such a problem.

The present invention has been made in view of the above-mentioned circumstances, and it is possible to simplify the construction and maintenance of equipment by transmitting the meter reading data of water and gas using the information transmission system of the electric meter terminal. The purpose is to provide a flexible meter reading system.

In order to achieve the above object, the meter reading system according to the aspect of the present invention includes a plurality of electric meter terminals having a measuring unit for measuring the amount of electric power used by the user and a communication unit for communicating with a higher-level device. In the meter reading system, the communication unit is configured to be able to communicate by a communication line connecting at least one of the gas meter terminal and the water meter terminal, and the gas meter reading data and the water meter terminal regarding the amount of gas used transmitted from the gas meter terminal. Of the electricity meter reading data, gas meter reading data, and water meter reading data related to the electricity usage measured by the measuring unit, which receives at least one of the water meter reading data related to the water usage transmitted from When at least one meter reading data is transmitted to the higher-level device and the control unit provided in the electric meter terminal receives a control request from the higher-level device, the connection or disconnection of the power supply requested by the control request to the electric meter terminal is received. Or send a control request to at least one of the gas meter terminal and the water meter terminal, and the electric meter terminal communicates with a power supply unit that supplies power to at least one of the gas meter terminal and the water meter terminal. provided the parts, the power supply unit supplies power through at least one the communication line of the gas meter terminal and a water meter terminal, the communication line includes at least one of the reception of the gas meter reading data and water meter reading data, from the power supply unit It is characterized in that it is also used for supplying power to at least one of a gas meter terminal and a water meter terminal.
Further, the meter reading system according to the aspect of the present invention is a meter reading system including a plurality of electric meter terminals having a measuring unit for measuring the amount of power used by the user and a communication unit for communicating with a higher-level device. The communication unit is configured to be able to communicate with at least one of the gas meter terminal and the water meter terminal, and the gas meter reading data regarding the gas usage amount transmitted from the gas meter terminal and the water meter reading regarding the water usage amount transmitted from the water meter terminal. It is characterized by receiving at least one of the data and transmitting the power meter reading data regarding the amount of power used measured by the measuring unit and the meter reading data of at least one of the gas meter reading data and the water meter reading data to the host device. To do.

The electric meter terminal has a control unit that converts electric power meter reading data, gas meter reading data, and water meter reading data into a common data format, and the communication unit transmits the meter reading data converted by the control unit to a higher-level device. But it may be.

The control unit combines the power meter reading data, the gas meter reading data, and the meter reading data of at least one of the water meter reading data into one data, and the communication unit also has a configuration in which the data collected by the control unit is transmitted to a higher-level device. Good.

A power supply unit that supplies electric power to at least one of a gas meter terminal and a water meter terminal may be provided.

The configuration may include a data aggregation device that receives meter reading data from a plurality of electric meter terminals, aggregates the received meter reading data, and transmits the received meter reading data to a higher-level center device.

According to the present invention, it is possible to simplify the construction and maintenance of equipment by transmitting the meter reading data of water and gas using the information transmission system of the electric meter.

It is a block diagram which shows the structure of the meter reading system which concerns on 1st Embodiment. It is a figure which shows the data format (data format) of meter reading data. It is a sequence diagram which shows the procedure of sending and receiving data between a center device, a data summarizing device, and an electric meter terminal. It is a block diagram which shows the structure of the meter reading system which concerns on 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to this. In addition, in order to explain the embodiment in the drawings, the scale may be changed as appropriate, such as drawing a part in a large or emphasized manner.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to this. In addition, in order to explain the embodiment in the drawings, the scale may be changed as appropriate, such as drawing a part in a large or emphasized manner.

<First Embodiment>
FIG. 1 is a block diagram showing a configuration of a meter reading system 1 according to the first embodiment. The meter reading system 1 according to the first embodiment is a system that collects and transmits meter reading data of electricity, gas, and water. The meter reading system 1 includes at least a plurality of electric meters (electric meter terminals) 100 shown in FIG. 1, a plurality of communication master units 200, and a data aggregation device 300. The meter reading system 1 may include a plurality of gas meters (gas meter terminals) 10 and a plurality of water meters (water meter terminals) 20. Further, the meter reading system 1 may include a center device 400. Further, a system including a meter reading system 1 (a plurality of electric meters 100, a plurality of communication master units 200, a data aggregation device 300), a plurality of gas meters 10, a plurality of water meters 20, and a center device 400 is electrified. It may be called a management system that manages meter reading data for water and gas. The meter reading system 1 shown in FIG. 1 assumes a system installed in a condominium or other condominium.

The electric meter 100 is a meter terminal that measures (measures, measures) the amount of electric power used (also referred to as the amount of electricity or the amount of electric power consumption) used by a user (user of electricity, gas, or water) in a home or a company. .. A meter terminal that measures such power consumption is also called a watt-hour meter. The electric meter 100 has a two-way communication function, and unlike an analog meter terminal, it transmits meter reading data (hereinafter referred to as electric meter reading data) related to measured power consumption in real time, and is a server of a power company or the like. It is possible to connect / disconnect the power supply and control the amount of power supply according to the control request from. The electric meter 100 is installed, for example, on a pipe shaft of an apartment (a piping space between water and sewage and a gas pipe, which is also called a pipe space).

As shown in FIG. 1, the electric meter 100 includes a measuring unit 110, a memory 120, a communication unit 130, and a control unit 140. A plurality of electric meters other than the electric meter 100 also have the same configuration as the electric meter 100 shown in FIG. In the configuration shown in FIG. 1, the memory 120 and the control unit 140 are provided separately from the communication unit 130, but the memory 120 and the control unit 140 may be provided as a configuration inside the communication unit 130. In this case, the communication unit 130 has a memory, a control unit, and a signal I / F 131. The measuring unit 110 is a processing unit that measures the amount of power used by the user. The memory 120 stores power meter reading data regarding the amount of power used measured by the measuring unit 110. Further, the memory 120 stores gas meter reading data relating to the gas usage amount measured by the measuring unit 11 of the gas meter 10 described later, and water meter reading data relating to the water usage amount measured by the measuring unit 21 of the water meter 20. It also stores various setting information and control programs. If the memory and the control unit are provided in the communication unit 130, the gas meter reading data and the water meter reading data are stored in the memory in the communication unit 130.

The communication unit 130 is a processing unit that performs data communication with the communication master unit 200 using the existing power line as a communication line. The technology of using a power line as a communication line is called PLC (Power Line Communication). The communication unit 130 is provided with a signal I / F 131 which is an interface for receiving signals (gas meter reading data, water meter reading data) sent from the gas meter 10 and the water meter 20. The communication between the electric meter 100, the gas meter 10 and the water meter 20 may be wired communication or wireless communication. In the present embodiment, the signal I / F 131 includes a terminal for connecting a gas meter 10 and a water meter 20 and a wired communication line (including a signal line for transmitting a pulse signal), and performs wired communication through the communication line. Shall be done.

The communication unit 130 receives gas meter reading data regarding the amount of gas used transmitted from the gas meter 10 and water meter reading data regarding the amount of water used transmitted from the water meter 20. Further, the communication unit 130 communicates the power meter reading data regarding the amount of power used measured by the measuring unit 110, the gas meter reading data transmitted from the gas meter 10, and the water meter reading data transmitted from the water meter 20 through the power line. It transmits (transmits) to the master unit 200.

The control unit 140 is a processing unit that controls the entire electric meter 100. In the present embodiment, the control unit 140 performs a process of converting the power meter reading data, the gas meter reading data, and the water meter reading data into a common data format, respectively. Further, the control unit 140 performs a process of storing the power meter reading data measured by the measuring unit 110, the gas meter reading data transmitted from the gas meter 10 and the water meter 20, and the water meter reading data in the memory 120. If the memory and the control unit are provided in the communication unit 130, the control unit in the communication unit 130 performs the above processing.

The gas meter 10 is a meter terminal for measuring (measuring, measuring) the amount of gas used, which is installed by a gas company or the like. The gas meter 10 has a measuring unit 11 for measuring the amount of gas used by the user. The gas meter 10 transmits the gas meter reading data measured by the measuring unit 11 to the electric meter 100 as, for example, an 8-bit pulse signal. The water meter 20 is a meter terminal for measuring (measuring, measuring) the amount of water used, which is installed by a water company or the like. The water meter 20 has a measuring unit 21 for measuring the amount of water used by the user. The water meter 20 also transmits the water meter reading data measured by the measuring unit 21 to the electric meter 100 as, for example, an 8-bit pulse signal. The gas meter 10 and the water meter 20 are installed, for example, on a pipe shaft of an apartment.

The communication master unit 200 is connected to a plurality of electric meters by a power line, and performs data communication through the power line. Further, the communication master unit 200 is connected to the data aggregation device 300 by a communication line of a predetermined communication method, and performs data communication through the communication line. A plurality of communication master units other than the communication master unit 200 also have the same configuration as the communication master unit 200 shown in FIG.

As shown in FIG. 1, the communication master unit 200 has a communication unit 210 and a PLC control unit 220. The communication unit 210 receives the meter reading data of electric power, gas, and water transmitted from a plurality of electric meters through the power line, and transmits the received meter reading data to the data aggregation device 300 through the communication line. Further, the communication unit 210 receives the data transmitted from the data aggregation device 300, and transmits the received data to an electric meter (all electric meters or a predetermined electric meter). The PLC control unit 220 performs a process of converting a data format in communication between a plurality of electric meters (PLC system communication) and a data format in communication between the data aggregation device 300.

The data aggregation device 300 is connected to a plurality of communication master units by a communication line, and is also connected to a communication network (not shown) such as the Internet via a router or the like. Then, the data aggregation device 300 performs a process of aggregating the data transmitted from the plurality of communication master units and transmitting the data to the center device 400. Further, the data aggregation device 300 performs a process of transmitting data transmitted from the center device 400 to a predetermined electric meter (that is, a communication master unit connected to the predetermined electric meter). The data aggregation device 300 also acquires meter reading data transmitted from a plurality of electric meters (that is, a communication master unit connected to the plurality of electric meters), and also performs a process of managing the acquired meter reading data.

As shown in FIG. 1, the data aggregation device 300 includes a communication unit 310, a data management unit 320, and a memory 330. The communication unit 310 performs data communication with the center device 400 through a communication network such as the Internet. Further, the communication unit 310 performs data communication with a plurality of communication master units through a communication line. Further, the data management unit 320 stores the meter reading data transmitted from the plurality of electric meters in the memory 330. Further, the data management unit 320 reads desired meter reading data from the memory 330 in response to a request from the center device 400, and transmits the read meter reading data (via the communication unit 310). The memory 330 stores meter reading data transmitted from a plurality of electric meters.

The center device 400 is a device that controls the collection and management of meter reading data and the connection and disconnection of electric meters. The center device 400 is constructed by a server.

Next, the data format of the meter reading data will be described. FIG. 2 is a diagram showing a data format (data format, data structure) of meter reading data. In the data format shown in FIG. 2A, the meter reading data is configured as separate data (power meter reading data, gas meter reading data, water meter reading data) for each of electricity (electricity), gas, and water. "ID information" for identifying each user is added to the head of each meter reading data. Therefore, the same ID information is added to the power meter reading data, the gas meter reading data, and the water meter reading data of the same user. The "electricity" part in the power meter reading data stores the data of the measured value (meter reading value) of the power measured by the measuring unit 110, and the "gas" part in the gas meter reading data is measured by the measuring unit 11. The gas measurement value (meter reading value) data is stored, and the water measurement value (meter reading value) data measured by the measuring unit 21 is stored in the "water supply" part of the water meter reading data. In the case of the data format shown in FIG. 2A, it is possible to transmit only the meter reading values of the required types (electric power, gas, water supply) according to the request (for example, only the meter reading data of the electric meter is required). (Because it is possible to transmit only the meter reading data in some cases), it is possible to efficiently transmit the meter reading data.

In the data format shown in FIG. 2 (b), "additional information" is inserted after the storage unit of the measurement value data in each meter reading data (power meter reading data, gas meter reading data, water meter reading data) shown in FIG. 2 (a). A storage unit for storing is provided. Additional information includes, for example, information for identifying the type of meter reading data (that is, information indicating the type of power meter reading data, gas meter reading data, and water meter reading data), power meter reading data, gas meter reading data, and water meter reading data of the same user. When different ID information is added to the data, information for associating each meter reading data, measurement when meter reading data of different measurement values of measurement time (for example, 30 minutes, 1 hour, 4 hours, etc.) are provided. Information indicating the type of meter reading data for each hour can be considered. In the case of the data format shown in FIG. 2B, the user, type, and type of meter reading data can be specified.

In the data format shown in FIG. 2C, in one meter reading data, the data of the measured value of the electric power measured by the measuring unit 110, the data of the measured value of the gas measured by the measuring unit 11, and the data of the measured value of the gas measured by the measuring unit 21 are measured. The data of the measured value of the water supply is stored. That is, a storage unit for "ID information" is provided at the beginning of the meter reading data, a storage unit for data on the measured value of electric power is provided behind the storage unit for "ID information", and a storage unit for data on the measured value of electric power. A storage unit for gas measurement value data is provided behind, and a water supply measurement value data storage unit is provided behind the gas measurement value data storage unit. In the case of the data format shown in FIG. 2C, since the data of the measured values of electric power, gas, and water are stored in one meter reading data, the data of three types of measured values (meter reading values) are collectively collected by one data. Data can be easily acquired by the data aggregation device 300 and the center device 400. Further, the data aggregation device 300 and the center device 400 can manage three types of meter reading data with only one ID information.

Next, the procedure for transmitting and receiving data in the meter reading system 1 will be described. FIG. 3 is a sequence diagram showing a procedure for transmitting and receiving data between the center device 400, the data aggregation device 300, and the electric meter 100. As shown in FIG. 3, the data aggregation device 300 acquires meter reading data (at least one of power meter reading data, gas meter reading data, and water meter reading data) for a predetermined electric meter 100 (all or part of the electric meters). Send a meter reading request. The meter reading request is transmitted to a predetermined electric meter via the communication master unit 200. The data aggregation device 300 periodically transmits a meter reading request in order to periodically acquire meter reading data.

When the communication unit 130 receives the meter reading request in the predetermined electric meter 100, the received meter reading request is passed to the control unit 140. The control unit 140 reads the meter reading data requested by the meter reading request from the memory 120, and passes the read meter reading data to the communication unit 130. The communication unit 130 transmits the meter reading data requested by the meter reading request to the data aggregation device 300 via the communication master unit 200. The control unit 140 periodically converts the meter reading data measured by the measuring unit 110 into a predetermined data format (see FIG. 2) and stores it in the memory 120. Further, the control unit 140 converts meter reading data (for example, 8-bit pulse signal data) periodically transmitted from the gas meter 10 and the water meter 20 into a predetermined data format (see FIG. 2), and the memory 120. Remember in. When the control unit 140 receives the meter reading request, the control unit 140 causes the measuring unit 110 to measure and acquire the power meter reading data, and requests the gas meter 10 and the water meter 20 for the meter reading data to obtain the gas meter reading data and the water meter reading data. May be obtained.

In the data aggregation device 300, the data management unit 320 acquires meter reading data transmitted from the predetermined electric meter 100, and stores the acquired meter reading data in the memory 330. At this time, the data management unit 320 stores various meter reading data for each user based on the ID information and the like.

The center device 400 transmits a data request requesting meter reading data to the data aggregation device 300 at a predetermined timing (for example, periodically). In the data aggregation device 300, when the data management unit 320 receives the data request from the center device 400, the data management unit 320 reads the meter reading data requested by the data request from the memory 330 and transmits the read meter reading data to the center device 400. When the data management unit 320 receives the data request from the center device 400, the data management unit 320 may request the meter reading data requested by the data request from the electric meter and acquire the desired meter reading data.

When the center device 400 needs to control the electric meter 100, the center device 400 transmits a control request requesting the control of the electric meter 100 to the data aggregation device 300. In the data aggregation device 300, when the data management unit 320 receives the control request from the center device 400, the data management unit 320 transmits the control request to the electric meter to be controlled via the communication master unit 200. In the electric meter, when the control unit 140 receives the control request, the control unit 140 executes the control requested by the control request (for example, connection or disconnection of the power supply). The gas meter 10 and the water meter 20 may be configured to be controlled by a control request. In this case, if the control request is the control of the gas meter 10 or the water meter 20, the control unit 140 transmits the control request to the gas meter 10 or the water meter 20. Then, the gas meter 10 and the water meter 20 execute control according to the control request.

As described above, in the first embodiment, the meter reading system 1 includes a plurality of electric meters 100 having a measuring unit 110 and a communication unit 130, and the communication unit 130 is at least one of a gas meter 10 and a water meter 20. It is configured to be communicable with one, and receives at least one of the gas meter reading data regarding the gas usage amount transmitted from the gas meter 10 and the water meter reading data regarding the water usage amount transmitted from the water meter 20, and the measuring unit 110 receives at least one of them. The power meter reading data relating to the amount of measured power and the meter reading data of at least one of the gas meter reading data and the water meter reading data are transmitted to the host device (communication master unit 200 or data aggregation device 300 or center device 400). According to such a configuration, the electric meter 100 can transmit not only electric power meter reading data but also gas meter reading data and water meter reading data. Therefore, a plurality of types of meter reading data can be transmitted without providing a repeater, and the equipment cost can be suppressed. As a result, the construction and maintenance of equipment can be simplified.

Further, in the first embodiment, the electric meter 100 has a control unit 140 that converts electric power meter reading data, gas meter reading data, and water meter reading data into a common data format, and the communication unit 130 converts the power meter reading data, the gas meter reading data, and the water meter reading data into a common data format. The meter reading data is transmitted to the host device. According to such a configuration, data can be transmitted / received and managed in a common data format, and the processing load on the host device can be reduced.

Further, in the first embodiment, the control unit 140 combines the power meter reading data, the gas meter reading data, and the meter reading data of at least one of the water meter reading data into one data (see FIG. 2C), and the communication unit. The 130 transmits the data collected by the control unit 140 to the host device. According to such a configuration, the host device can acquire a plurality of types of meter reading data with one request.

Further, the first embodiment includes a data aggregation device 300 that receives meter reading data from a plurality of electric meters 100, aggregates the received plurality of meter reading data, and transmits the received meter reading data to a higher-level center device 400. According to such a configuration, the center device 400 can efficiently acquire meter reading data.

<Second Embodiment>
FIG. 4 is a block diagram showing a configuration of the meter reading system 1A according to the second embodiment. In the configuration shown in FIG. 4, the same configuration as that shown in FIG. 1 is designated by the same reference numerals, so that duplicate description will be omitted.

In the configuration shown in FIG. 4, the electric meter 100A includes a measuring unit 110, a memory 120, a communication unit 130A, and a control unit 140. The communication unit 130A includes a power supply unit 132 in addition to the signal I / F 131. The power supply unit 132 is a processing unit that supplies power to the gas meter 10A and the water meter 20A. In the present embodiment, the power supply unit 132 supplies power through a communication line connecting the signal I / F 131, the gas meter 10A, and the water meter 20A.

The gas meter 10A includes a battery 12 in addition to the measuring unit 11. The water meter 20A includes a battery 22 in addition to the measuring unit 21. The batteries 12 and 22 are storage batteries for storing the electric power supplied from the power supply unit 132. The gas meter 10A and the water meter 20A use the electric power stored in the batteries 12 and 22 to perform processing such as weighing and signal transmission.

According to such a configuration, it is not necessary to secure electric power separately for the electric meter 100, the gas meter 10A, and the water meter 20A, and it is possible to save the trouble of battery replacement in each meter. In addition, although the configuration was such that signal communication and power supply were performed via a communication line connecting the communication unit 130A, the gas meter 10A, and the water meter 20A (that is, the communication line was configured to combine communication and power transmission). In addition to the communication line connecting the communication unit 130A, the gas meter 10A, and the water meter 20A, the communication unit 130A, the gas meter 10A, and the water meter 20A may be connected by a power line for transmitting electric power. Further, although the power supply unit 132 is provided inside the communication unit 130A, it may be provided outside the communication unit 130A.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. Various changes or improvements can be made to the above embodiment without departing from the spirit of the present invention. In addition, one or more of the requirements described in the above embodiments may be omitted. Such modifications, improvements, or omitted forms are also included in the technical scope of the present invention. It is also possible to apply the above-described embodiments in combination as appropriate.

In the cases shown in FIGS. 1 and 2, the communication master unit 200 corresponds to a higher-level device located above the electric meters 100 and 100A. However, the electric meters 100 and 100A may transmit the meter reading data to the data aggregation device 300 without going through the communication master unit 200. In this case, the data aggregation device 300 corresponds to the host device. Further, the electric meters 100 and 100A may directly transmit the meter reading data to the center device 400 without going through the communication master unit 200 and the data aggregation device 300. In this case, the center device 400 corresponds to the host device.

Further, in each of the above embodiments, the electric meters 100 and 100A are configured to transmit meter reading data from any of the gas meters 10 and 10A and the water meters 20 and 20A to the host device. The meter reading data of at least one of the gas meters 10 and 10A and the water meters 20 and 20A may be transmitted to the host device. Further, the electric meters 100 and 100A may be configured to transmit meter reading data (measurement value, meter reading value) of meters other than the gas meters 10 and 10A and the water meters 20 and 20A. For example, data on the amount of power generated by private power generation, data such as a calorie meter (a meter that measures the amount of heat consumed by district heating and cooling, etc.) may be transmitted.

Further, the power supply unit 132 may be configured to supply electric power to at least one of the gas meter 10A and the water meter 20A.

Further, the electric meters 100 and 100A and the communication master unit 200 perform data transmission by a PLC communication method via a power line, but the data is not limited to such a configuration and communication is performed using a communication method other than the PLC method. Data may be transmitted via a line.

Further, the gas meters 10 and 10A and the water meters 20 and 20A transmitted the measured values to the electric meters 100 and 100A by pulse signals, but transmitted data in a data format other than the pulse signals to the electric meters 100 and 100A. May be good. Further, although the control unit 140 has converted the data format, the communication master unit 200 or the data aggregation device 300 may convert the data format.

1,1A meter reading system 10,10A gas meter (gas meter terminal)
20,20A Water meter (water meter terminal)
100,100A electric meter (electric meter terminal)
110 Weighing unit 130, 130A Communication unit 140 Control unit 200 Communication master unit (upper device)
300 Data aggregation device (upper device)
400 Center device (upper device)

Claims (4)

It is a meter reading system including a plurality of electric meter terminals having a measuring unit for measuring the amount of electric power used by the user and a communication unit for communicating with a higher-level device.
The communication unit
It is configured to be able to communicate by a communication line connecting at least one of the gas meter terminal and the water meter terminal.
At least one of the gas meter reading data regarding the amount of gas used transmitted from the gas meter terminal and the water meter reading data regarding the amount of water used transmitted from the water meter terminal is received via the communication line.
The power meter reading data regarding the amount of electric power used measured by the measuring unit, the gas meter reading data, and the meter reading data of at least one of the water meter reading data are transmitted to the higher-level device.
The control unit included in the electric meter terminal is
Upon receiving a control request from the host device, the electric meter terminal executes control regarding connection or disconnection of the power supply required by the control request, or at least one of the gas meter terminal and the water meter terminal. The control request is sent to
The electric meter terminal is
The communication unit is provided with a power supply unit that supplies electric power to at least one of the gas meter terminal and the water meter terminal.
The power supply unit
Power is supplied to at least one of the gas meter terminal and the water meter terminal through the communication line.
The communication line is
It is characterized in that it is also used for receiving at least one of the gas meter reading data and the water meter reading data, and supplying power from the power supply unit to at least one of the gas meter terminal and the water meter terminal. Meter reading system. The control unit converts the power meter reading data, the gas meter reading data, and the water meter reading data into a common data format, respectively.
The meter reading system according to claim 1, wherein the communication unit transmits meter reading data converted by the control unit to the higher-level device. The control unit collects the power meter reading data, the gas meter reading data, and at least one of the water meter reading data into one data.
The meter reading system according to claim 2, wherein the communication unit transmits data collected by the control unit to the higher-level device. The invention according to any one of claims 1 to 3, further comprising a data aggregation device that receives meter reading data from the plurality of electric meter terminals, aggregates the received meter reading data, and transmits the received meter reading data to a higher-level center device. Meter reading system.

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