JP7086013B2 - Data collection system and secondary master unit - Google Patents

Description

The present invention relates to a data collection system and a sub-master unit that collect data such as electric energy from a watt-hour meter installed in each consumer by power line carrier communication.

Conventionally, in a data collection system that collects data such as electric energy from a watt-hour meter using power line carrier communication, the master unit receives data from the watt-hour meter that functions as a slave unit by power line carrier communication. , Collect electricity meter data.

Power line carrier communication is performed by superimposing a transmission signal having a frequency higher than the frequency of a commercial power source that supplies power to the power line on the power line. When the master unit and the slave unit are connected to power lines of different systems, a transformer is interposed between the master unit and the slave unit. Therefore, when the frequency of the transmission signal becomes several hundred kHz or more, the inductor component of the transformer acts as a resistor and the transmission signal is attenuated. Due to such attenuation, power line carrier communication beyond the transformer may not be possible between the master unit and the slave unit.

Patent Document 1 discloses a technique of connecting between power lines via an optical coupler and performing power line carrier communication between the power lines, and communication between different power lines can be performed by such a technique.

Japanese Unexamined Patent Publication No. 8-149053

However, when trying to collect data not only from a watt-hour meter connected to one power line but also from a watt-hour meter connected to another power line, the number of watt-hour meters that one master unit collects data is large. turn into. Further, when there are many watt-hour meters connected to one power line, the number of watt-hour meters for which one master unit collects data also increases.

The collection of data from electricity meters is required to be real-time in order to respond to contract menus of various electricity charges or to visualize the amount of electricity used by consumers, for example, it is cycled every 30 minutes. Is executed. Therefore, if the number of watt-hour meters for which one master unit collects data is too large, there is a problem that data can not be collected from the watt-hour meters in time.

The present invention has been made in view of the above, and an object of the present invention is to obtain a data collection system capable of quickly collecting data of a plurality of watt-hour meters.

In order to solve the above-mentioned problems and achieve the object, the data collection system of the present invention is connected to the main master unit connected to the first power line, the first power line and the second power line, and the first power line. It is provided with an auxiliary master unit having an optical coupler that transmits / receives data to / from the second power line. The main master unit collects data from a plurality of first electric energy meters connected to the first electric energy line via the first electric power line by power line carrier communication. The sub-master unit is data from a plurality of second watt-hour meters connected to the second watt-hour meter via the second watt-hour line by power line carrier communication during the period when the main master unit collects data from the plurality of first watt-hour meters. Then, the collected data of the plurality of second watt-hour meters are transmitted to the main master unit via the first power line.

According to the present invention, there is an effect that data of a plurality of watt-hour meters can be quickly collected.

The figure for demonstrating the data collection system which concerns on Embodiment 1 of this invention. The figure which shows the configuration example of the data collection system which concerns on Embodiment 1. The figure which shows the configuration example of the main master unit which concerns on Embodiment 1. The figure which shows an example of the collected data table stored in the main master unit which concerns on Embodiment 1. The figure which shows the structural example of the secondary master unit which concerns on Embodiment 1. The figure which shows an example of the collection data table of the secondary master unit which concerns on Embodiment 1. A sequence diagram showing a data collection process of the data collection system according to the first embodiment. The figure for demonstrating the data acquisition method from the watt hour meter when the coupler is provided instead of the sub-master unit which concerns on Embodiment 1. The figure for demonstrating the average time required for data collection which concerns on Embodiment 1. The figure for demonstrating the time required to acquire the data from the electric energy meters of all the grids by the data collection system which concerns on Embodiment 1. A flowchart showing an example of processing of the main master unit according to the first embodiment. A flowchart showing an example of processing of the sub-master unit according to the first embodiment. The figure which shows an example of the hardware composition of the main unit of the main master unit which concerns on Embodiment 1. The figure which shows the structural example of the data collection system which concerns on Embodiment 2 of this invention.

Hereinafter, the data collection system and the sub-master unit according to the embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

Embodiment 1.
FIG. 1 is a diagram for explaining a data collection system according to the first embodiment of the present invention. As shown in FIG. 1, the data collection system 100 according to the first embodiment is connected to a first power line 7 to perform power line carrier communication, and is connected to a second power line 8 to perform power line carrier communication. It is provided with a sub-master unit 2 to perform. The first power line 7 and the second power line 8 are power lines of different power supply systems. The sub-master unit 2 has an optical coupler 24 that transmits / receives data between the first power line 7 and the second power line 8.

A plurality of first electric energy meters 3 ₁ , 32, ..., _{3 n} that perform power line carrier communication are connected to the first power line 7. A plurality of _second watt-hour meters 4 ₁ , 42, ..., 4 _n that perform power line carrier communication are connected to the second power line 8. Each of the plurality of first watt-hour meters 3 ₁ , 3 ₂ , ..., 3 _n and the plurality of _second watt-hour meters 4 ₁ , 42, ..., 4 _n corresponds to a plurality of consumers. It is installed in the consumer who does. n is, for example, an integer of 3 or more.

The main master unit 1 collects data from a plurality of first electric energy meters 3 ₁ , 32, ..., _{3 n} via the first electric power line 7 by power line carrier communication. The data of the first watt-hour meter 3 ₁ , 3 ₂ , ..., 3 _n collected by the main master unit 1 is measured by, for example, the first watt-hour meter 3 ₁ , 3 ₂ , ..., 3 _n . Includes data such as the amount of power to be generated.

A plurality of sub-master units 2 are provided via the second power line 8 by power line carrier communication during the period in which the main master unit 1 collects data from a plurality of first electric energy meters _{3 1} , 32, ..., _3n . Data is collected from the second watt-hour meter 4 ₁ , 4 ₂ , ..., 4 _n . The data of the second watt-hour meter 4 ₁ , 4 ₂ , ..., 4 _n collected by the sub-master unit 2 is measured by, for example, the second watt-hour meter 4 ₁ , 4 ₂ , ..., 4 _n . Includes data such as the amount of power to be generated.

The sub-master unit 2 collects the collected data of the plurality of second watt-hour meters 4 ₁ , 42, ..., 4 _n , and then collects the plurality of _second watt-hour meters 4 ₁ , 4 ₂ , ... ..., 4 _n data is transmitted to the main unit 1 via the first power line 7.

In this way, the sub-master unit 2 has a plurality of second watt-hour meters 4 during the period in which the main master unit 1 collects data from the plurality of first watt-hour meters 3 ₁ , 3 ₂ , ..., 3 _n . Collect data from ₁ , 4 ₂ , ..., 4 _n . After that, the sub-master unit 2 transmits the collected data of the plurality of _second watt-hour meters 4 ₁ , 42, ..., 4 _n to the main master unit 1. As a result, the main master unit 1 has a plurality of first watt-hour meters 3 ₁ , 32, ..., 3 _n and a plurality of _second watt-hour meters 4 ₁ , _{42, ..., 4 n ,} respectively. Compared to the case of collecting data by communicating with one by one, a plurality of first watt-hour meters 3 ₁ , 3 ₂ , ..., 3 _n and a plurality of second watt-hour meters 4 ₁ , 4 ₂ , ...・, 4 _n data can be collected quickly.

Hereinafter, the configuration of the data collection system 100 according to the first embodiment will be described more specifically. FIG. 2 is a diagram showing a configuration example of the data collection system according to the first embodiment. The data collection system 100 shown in FIG. 2 includes a main master unit 1 connected to the first power line 7, an auxiliary master unit 2 ₁ connected to the first power line 7 and the second power line 81, and a _first power line 7. And the sub-master unit 2 ₂ connected to the second power line 8 ₂ . The first power line 7, the second power line 81, and the second power line 8 ₂ are connected to different transformers _{6 1} , 6 ₂ , ₆₃ , and are power lines of different power systems. Hereinafter, when each of the _second power lines 8 ₁ and 82 is shown without distinction, it may be described as the second power line 8. Further, the first power line 7 may be described as a power line of the _first system, the second power line 81 may be described as a power line of the second system, and the _second power line 82 may be described as a power line of the third system.

A plurality of first electric energy meters 3 ₁ , _{32, ..., 3 n ,} which perform power line carrier communication and have a function as a slave unit of the main master unit 1, are connected to the first electric power line 7. A plurality of second electric energy meters 4A ₁ , 4A ₂ , ..., _4An , which perform power line carrier communication and function as slave units of the sub-master unit ₂₁ , are connected to the _second power line 81. .. A plurality of _second watt-hour meters 4B ₁ , 4B ₂ , ..., 4B _n , which perform power line carrier communication and function as slave units of the sub-master unit 22, are connected to the _second power line 82. ..

In the following, when each of the plurality of first watt-hour meters 3 ₁ , 32, ..., _{3 n} is shown without distinction, it may be described as the first watt-hour meter 3, and the plurality of second watt-hour meters may be described. When each of the watt-hour meters 4A ₁ , 4A ₂ , ..., _4An is shown without distinction, it may be described as the second watt-hour meter 4A. Further, when each of the plurality of second watt-hour meters 4B ₁ , 4B ₂ , ..., _4Bn is shown without distinction, it may be described as the second watt-hour meter 4B. Further, when each of the second watt-hour meter 4A and 4B is shown without distinction, it may be described as the second watt-hour meter 4. The plurality of first watt-hour meters 3 and the plurality of second watt-hour meters 4 have the same configuration, but may have different configurations. Further, in the example shown in FIG. 2, the first watt-hour meter 3, the second watt-hour meter 4A, and the second watt-hour meter 4B have the same number, but may be different numbers from each other.

The main master unit 1 acquires data from a plurality of first electric energy meters 3 via the first electric power line 7 by power line carrier communication. The main master unit ₁ acquires the data of the plurality of second watt- _hour meters 4A collected by the sub-master unit 21 from the sub-master unit 21. The main master unit 1 acquires the data of the plurality of second watt-hour meters 4B collected by the sub-master unit _{2 2 from} the sub-master unit 22.

The sub-master unit 2 ₁ collects data from the plurality of second watt-hour meters 4A via the second watt-hour meter 8 ₁ by power line carrier communication during the period when the main master unit 1 collects data from the plurality of first watt-hour meters 3. To get. The sub-master unit 2 ₂ collects data from the plurality of second watt-hour meters 4B via the second watt-hour meter 8 ₂ by power line carrier communication during the period when the main master unit 1 collects data from the plurality of first watt-hour meters 3. To get. The sub-master units 2 ₁ and 2 ₂ have the same configuration as each other, and when each of the sub-master units 2 ₁ and 2 ₂ is shown without distinction, it may be described as the sub-master unit 2.

FIG. 3 is a diagram showing a configuration example of the main master unit according to the first embodiment. As shown in FIG. 3, the main master unit 1 according to the first embodiment includes an AC (Alternating Current) coupling portion 11, an analog front end portion 12, and a main unit 13.

The AC coupling unit 11 is connected to the first power line 7, and superimposes an analog transmission signal for power line carrier communication on the first power line 7 or extracts it from the first power line 7. The AC coupling portion 11 is configured by, for example, a transformer. The analog front end unit 12 converts the analog transmission signal extracted by the AC coupling unit 11 into a digital transmission signal and outputs it to the main unit 13, and converts the digital transmission signal output from the main unit 13 into an analog transmission signal. Is output to the AC coupling unit 11.

The main unit 13 includes a PLC (Power Line Communications) communication unit 14, a storage unit 16, a control unit 15, and a higher-level communication unit 17. The PLC communication unit 14 generates a digital transmission signal according to the data output from the control unit 15, and outputs the generated digital transmission signal to the analog front end unit 12. Further, the PLC communication unit 14 extracts data from the digital transmission signal output from the analog front end unit 12, and outputs the extracted data to the control unit 15.

When the data acquisition timing comes, the control unit 15 sequentially outputs data including a data transmission request for requesting data transmission to each of the plurality of first watt-hour meters 3 to the PLC communication unit 14. As a result, the PLC communication unit 14 sequentially generates digital transmission signals including data transmission requests, and the AC coupling unit 11 sequentially outputs analog transmission signals including data transmission requests to the first power line 7. The storage unit 16 stores the identification information of the plurality of first watt-hour meters 3, and the control unit 15 sequentially sets the identification information of the plurality of first watt-hour meters 3 stored in the storage unit 16 as the destination. The data of the data transmission request is sequentially generated, and the generated data is sequentially output to the PLC communication unit 14.

The control unit 15 acquires data sequentially transmitted from the plurality of first electric energy meters 3 to the first power line 7 in response to a data transmission request via the PLC communication unit 14, and the acquired plurality of first electric energy meters 3 Data is stored in the storage unit 16. Further, when the data collection from the plurality of first watt-hour meters 3 is completed, the control unit 15 sequentially outputs a data transmission request requesting data transmission to the sub-master units _{2 1} and 22 to the PLC communication unit 14. .. As a result, the analog transmission signal including the data transmission request to the sub-master units _{2 1} and 22 is sequentially output to the first power line 7. The control unit 15 acquires data of a plurality of second watt-hour meters 4A transmitted from the sub-master unit 21 to the _second power line 81 in response to _a data transmission request via the PLC communication unit 14, and a plurality of acquired data. The data of the second watt hour meter 4A is stored in the storage unit 16. Further, the control unit 15 acquires and acquires the data of the plurality of second watt-hour meters 4B transmitted from the sub-master unit 22 to the _second power line ₈₂ in response to the data transmission request via the PLC communication unit 14. The data of the plurality of second watt-hour meters 4B is stored in the storage unit 16.

The above-mentioned data acquisition timing occurs at a fixed cycle. For example, the data acquisition timing occurs every 30 minutes. As a result, the control unit 15 can collect the data of the first watt-hour meter 3, the data of the second watt-hour meter 4A, and the data of the second watt-hour meter 4B at a fixed cycle.

The storage unit 16 stores the identification information of each first watt-hour meter 3, which is the above-mentioned identification information for communication. Further, the storage unit 16 stores a collected data table including the data of the first watt-hour meter 3, the data of the second watt-hour meter 4A, and the data of the second watt-hour meter 4B collected by the control unit 15.

FIG. 4 is a diagram showing an example of a collected data table stored in the main master unit according to the first embodiment. The collected data table shown in FIG. 4 contains a plurality of data in which "identification information" and "measured value" are associated with each other. The "identification information" is information including the identification information of the master unit for which data is directly collected from the watt-hour meter and the identification information of the watt-hour meter. The identification information of the master unit is, for example, the serial number of the master unit or the identification information for communication, and the identification information of the watt-hour meter is the serial number of the watt-hour meter or the identification information for communication.

In the example shown in FIG. 4, the identification information of the main master unit 1 is "A1", the identification information of the sub-master unit 2 ₁ is "B1", and the identification information of the sub-master unit 2 ₂ is "B2". ". The identification information of the _first watt-hour meter 31 is "0001", and the identification information of the _first watt-hour meter 32 is "0002". The identification information of the second watt-hour meter 4A ₁ is "0011", and the identification information of the second watt-hour meter 4A ₂ is "0012". The identification information of the second watt-hour meter 4B ₁ is "0021", and the identification information of the second watt-hour meter 4B ₂ is "0022".

In the example shown in FIG. 4, the identification information "A1_0001" includes the identification information of the main master unit 1 and the identification information of the _first watt-hour meter 31, and data is collected from the _first watt-hour meter 31. Indicates that the master unit is the master master unit 1. Further, for example, the identification information "B1_0012" includes the identification information of the sub-master unit 21 and the identification information of the _second watt-hour meter 4A ₂ , and the master unit for which data is collected from the _second watt-hour meter 42. Indicates that is the sub _- master unit 21. Further, for example, the identification information "B2_0021" includes the identification information of the sub-master unit 22 and the identification information of the _second watt-hour meter 4B ₁ , and the master unit for which data is collected from the second watt-hour meter 4B ₁ . Indicates that is the sub _- master unit 22.

"Measured value" indicates a value measured by a watt-hour meter. For example, the "measured value" is the amount of electric power measured by the watt-hour meter and is the value of the amount of electric power supplied to the consumer. Such "measured value" may also be referred to as a meter reading value or an indicated value. The "measured value" is not limited to the amount of electric power, and may include, for example, information on the measurement time, which is the time when the measured value is obtained, and also includes the values of the voltage and current supplied to the consumer. But it may be. In the example shown in FIG. 4, for example, the data of the _first watt-hour meter 31 collected by the main master unit 1 includes the measured value “12871”, and the second watt- _hour meter collected by the sub-master unit 21 It is shown that the data of 4A ₁ includes the measured value "28453".

The higher-level communication unit 17 is a communication unit that communicates wirelessly or by wire with a higher-level management device (not shown). The control unit 15 can transmit the collected watt-hour meter data from the higher-level communication unit 17 to a higher-level management device (not shown). Specifically, the control unit 15 stores the data of the first watt-hour meter 3, the data of the second watt-hour meter 4A, and the data of the second watt-hour meter 4B stored in the storage unit 16 at regular intervals. It is transmitted from the higher-level communication unit 17 to a higher-level management device (not shown). Such a fixed cycle is a cycle synchronized with the above-mentioned data acquisition timing, and is, for example, a 30-minute cycle.

FIG. 5 is a diagram showing a configuration example of the sub-master unit according to the first embodiment. As shown in FIG. 5, the sub-master unit 2 according to the first embodiment includes a first AC coupling unit 21, a first analog front end unit 22, a _first unit 23, and optical couplers 24 ₁ , 242. , A second AC coupling portion 25, a second analog front end portion 26, and a second unit 27.

The first unit 23 includes a first communication unit 31, a third communication unit 32, a first control unit 33, and a storage unit 34. Further, the second unit 27 includes a second communication unit 41, a fourth communication unit 42, a second control unit 43, and a storage unit 44.

The first AC coupling unit 21 is connected to the first power line 7 and superimposes an analog transmission signal for power line carrier communication on the first power line 7 or extracts it from the first power line 7. The first AC coupling portion 21 is configured by, for example, a transformer. The first analog front end unit 22 converts the analog transmission signal extracted by the first AC coupling unit 21 into a digital transmission signal and outputs it to the first unit 23, and the digital transmission signal output from the first unit 23 is analog. It is converted into a transmission signal and output to the first AC coupling unit 21.

The first communication unit 31 is connected to the first power line 7 via the first AC coupling unit 21 and the first analog front end unit 22, and performs power line carrier communication with the main master unit 1 via the first power line 7. conduct. The third communication unit 32 is connected to _one end of the optical couplers 24 ₁ and 242, and communicates with the fourth communication unit 42 of the second unit 27. The optical couplers 24 ₁ and 242 are the optical couplers 24 shown in _FIG .

The first control unit 33 adds the data received from the second unit 27 to the _third communication unit 32 via the optical coupler 241 to the collected data table stored in the storage unit 34. When the sub-master unit ₂ is the sub-master unit 21, the data received from the second unit 27 to the _third communication unit 32 via the optical coupler 241 is the data of the plurality of second watt-hour meters 4A. .. When the sub-master unit 2 is the sub-master unit ₂ , the data received from the second unit 27 to the _third communication unit 32 via the optical coupler 241 is the data of the plurality of second watt-hour meters 4B. ..

The data of the second watt- _hour meter 4A received by the sub-master unit 21 includes the measured value of the second watt-hour meter 4A and the identification information of the second watt-hour meter 4A. Similarly, the data of the _second watt-hour meter 4B received by the sub-master unit 22 includes the measured value of the second watt-hour meter 4B and the identification information of the second watt-hour meter 4B.

The first control unit 33 sequentially adds the identification information of the sub-master unit 2 to the data of the second watt-hour meter 4. Then, the first control unit 33 compresses the data of the second watt-hour meter 4 to which the identification information of the sub-master unit 2 is added, and stores the compressed data in the storage unit 34. When the sub-master unit 2 is the sub-master unit 21, the _{first control unit 33 generates data of the second watt-hour meter 4A to which the identification information of the sub-master unit 2 1 is} added, and the sub-master unit 2 is the sub-master. In the case of the machine 2 ₂ , the data of the second watt-hour meter 4B to which the identification information of the sub-master unit 2 ₂ is added is generated.

FIG. 6 is a diagram showing an example of a collected data table of the sub-master unit according to the first embodiment. As shown in FIG. 6, the collected data table stored in the storage unit 34 of the sub-master unit 2 includes a plurality of data in which the “identification information” and the “measured value” are associated with each other. The "identification information" is information including the identification information of the sub-master unit 2 for which data is collected from the second watt-hour meter 4 and the identification information of the second watt-hour meter 4. The collected data table is compressed data collectively compressed by the first control unit 33, but the data of each second watt-hour meter 4 in the collected data table may be individually compressed.

In the example shown in FIG. 6, the data stored in the storage unit 34 of the sub _- master unit 21 is shown, and the data in which the identification information “B1_0011” and the measured value “28453” are associated with each other and the identification information “B1_0012” are shown. And the data associated with the measured value "71542". The identification information "B1_0011" indicates that the data was collected by the sub-master unit 2 ₁ from the second watt-hour meter 4A ₁ , and the identification information "B1_0012" indicates that the data was collected from the second watt-hour meter 4A ₂ by the sub-master unit 2. ₁ indicates that it has been collected.

Returning to FIG. 5, the description of the first control unit 33 will be continued. Communication with the second unit 27 of the third communication unit 32 is ₁ -bit transmission because the signal is exchanged by light emission in the optical coupler 241. The first control unit 33 has a data conversion unit, converts the serial data output from the third communication unit 32 into parallel data, and stores the converted parallel data in the storage unit 34. By providing the sub-master unit ₂ with a plurality of optical couplers 241, communication with the second unit 27 of the third communication unit 32 can be made into parallel communication.

Based on the data transmission request from the main master unit 1, the first control unit 33 transmits the compressed data stored in the storage unit 34 from the first communication unit 31 to the main parent by power line carrier communication via the first power line 7. Send to machine 1. The data transmitted by the first control unit 33 from the first communication unit 31 to the main unit ₁ is compressed data of a plurality of second watt-hour meters 4A when the sub-master unit 2 is the sub-master unit 21 and is subordinate. When the master unit 2 is the sub-master unit 2 ₂ , it is compressed data of a plurality of second watt-hour meters 4B.

The optical couplers 24 ₁ and 242 are optical couplers for connecting the _third communication unit 32 and the fourth communication unit 42 by optical communication. _The optical couplers 24 ₁ and 242 are configured by, for example, a photocoupler. With the optical couplers 24 ₁ , 242, the _first AC coupling portion 21, the first analog front end portion 22, and the first unit 23, the second AC coupling portion 25, the second analog front end portion 26, and the second unit 27 is electrically isolated.

The second AC coupling unit 25 is connected to the second power line 8 and superimposes the analog transmission signal of the power line carrier communication on the second power line 8 or extracts it from the second power line 8. The second AC coupling portion 25 is configured by, for example, a transformer. The second analog front end unit 26 converts the analog transmission signal extracted by the second AC coupling unit 25 into a digital transmission signal and outputs it to the second unit 27, and the digital transmission signal output from the second unit 27 is analog. It is converted into a transmission signal and output to the second AC coupling unit 25.

The second communication unit 41 is connected to the second power line 8 via the second AC coupling unit 25 and the second analog front end unit 26, and performs power line carrier communication via the second electric energy meter 4 and the second power line 8. .. For example, when the sub-master unit ₂ is the sub-master unit 21, the second communication unit 41 performs power line carrier communication via the second watt- _hour meter 4A and the second power line 81, and the sub-master unit 2 is the sub-master unit. In the case of the master unit 22, power line carrier communication is performed via the _second electric energy meter 4B and the _second power line 82. The fourth communication unit 42 is connected to the other _ends of the optical couplers 24 ₁ and 242, and communicates with the first unit 23.

When the data acquisition timing comes, the second control unit 43 outputs the data including the data transmission request to the plurality of second power meters 4 connected to the second power line 8 in sequence to the second communication unit 41, and the second control unit 43 outputs the data to the second communication unit 41. 2 The data transmission request is transmitted from the communication unit 41 by power line carrier communication via the second power line 8. The storage unit 44 stores the identification information of the plurality of second power meter 4s as the identification information for communication, and the second control unit 43 stores the plurality of second power meter 4 stored in the storage unit 44. The data of the data transmission request with the identification information of the above is sequentially generated, and the generated data is sequentially output to the second communication unit 41. The second control unit 43 acquires data sequentially transmitted from the plurality of second watt-hour meters 4 via the second power line 8 from the second communication unit 41 in response to the data transmission request.

The data collection timing at which the second control unit 43 starts collecting data is a timing that occurs at the same time as the data collection timing at which the control unit 15 starts collecting data, and occurs, for example, at a cycle of 30 minutes. The data acquisition timing of the control unit 15 and the data acquisition timing of the second control unit 43 may be different timings according to the difference in the number of watt-hour meters for which data is to be collected. For example, when the number of the second watt-hour meter 4 is larger than the number of the first watt-hour meter 3, the data collection timing of the second control unit 43 may be generated earlier than the data collection timing of the control unit 15. can.

When the sub-master unit ₂ is the sub-master unit 21, the data acquired by the second control unit 43 via the second communication unit 41 is the data of the plurality of second watt-hour meters 4A, and the sub-master unit 2 has the data. In the case of the sub-master unit 2 ₂ , it is the data of a plurality of second watt-hour meters 4B. Every time the second control unit 43 acquires the data of the second watt-hour meter 4, the acquired data of the second watt-hour meter 4 is transmitted from the fourth communication unit 42 to the first unit 23.

The first control unit 33 can transmit data from the third communication unit 32 to the _second unit 27 via the optical coupler 242. For example, the first control unit 33 acquires data transmitted from the main unit 1 to the first power line 7 from the first communication unit 31, and outputs the acquired data from the _third communication unit 32 to the optical coupler 242. can do. In this case, the _second control unit 43 acquires the data from the first control unit 33 via the optical coupler 242 and the fourth communication unit 42. When the acquired data is the control data of the second watt-hour meter 4, the second control unit 43 can output the control data to the second watt-hour meter 4 from the second communication unit 41. Further, when the acquired data is the identification information of the second watt-hour meter 4, the second control unit 43 can store the acquired identification information of the second watt-hour meter 4 in the storage unit 44. The identification information of the second watt-hour meter 4 is used, for example, as the destination of the above-mentioned data transmission request.

FIG. 7 is a sequence diagram showing a data collection process of the data collection system according to the first embodiment. As shown in FIG. 7, the control unit 15 of the main unit 1 collects data from the first _watt -hour meter _{3 1} , 32, ..., 3n. Specifically, the control unit 15 of the main master unit 1 sequentially requests data transmission to the first _watt -hour meter 3 ₁ , ₃₂ , ..., 3n (steps S11 ₁ , S11 ₂ , ... , S11 _n ), 1st watt-hour meter 3 ₁ , 32, ..., _{3 n} to sequentially acquire data (steps S12 ₁ , S12 ₂ , ..., S12 _n ). Then, the master master unit 1 adds the identification information of the master master unit 1 to the collected data, and stores the data to which the identification information of the master master unit 1 is added (step S13). When the identification information of the first watt-hour meter 3 is not added to the collected data, the master master unit 1 adds the identification information of the main master unit 1 and the identification information of the first watt-hour meter 3 to the collected data. The data to which the identification information of the main master unit 1 and the identification information of the first watt-hour meter 3 are added is stored.

Further, the _second control unit 43 of the sub-master unit 21 has a plurality of second watt-hour meters 4A during the period (steps S11 ₁ to S12 _n ) in which the main master unit 1 collects the data of the first watt-hour meter 3. Collect data from. Specifically, the _second control unit 43 of the sub-master unit 21 sequentially requests data transmission to the second watt-hour meter 4A ₁ , 4A ₂ , ..., _4An (steps S21 ₁ , S21 ₂ and ..., S21 _n ), the second watt-hour meter 4A ₁ , 4A ₂ , ..., 4A _n , sequentially acquire data (steps S22 ₁ , S22 ₂ , ..., S22 _n ). Then, the _first control unit 33 of the sub-master unit 21 sequentially adds identification information to the collected data (step S23), and performs data compression (step S24). Specifically, the first control unit 33 of the sub-master unit 21 sequentially adds the identification information of the sub-master unit _{2 1} to the data of the second watt-hour meter 4A ₁ , 4A ₂ , ..., _4An . , The data of the second watt-hour meter 4A ₁ , 4A ₂ , ..., _4An to which the identification information of the sub-master unit 2 ₁ is added is compressed collectively or individually. The first control unit 33 stores the compressed data in the storage unit 34. If the second control unit 43 of the sub-master unit 21 does not have the identification information of the second watt- _hour meter 4A added to the collected data, the _second control unit 43 of the sub-master unit 21 has the identification information of the sub-master unit 21 and the second. The identification information of the watt-hour meter 4A is added.

Further, the _second control unit 43 of the sub-master unit 22 has a plurality of second watt-hour meters 4B during the period (steps S11 ₁ to S12 _n ) in which the main master unit 1 collects the data of the first watt-hour meter 3. Collect data from. Specifically, the _second control unit 43 of the sub-master unit 22 sequentially requests data transmission to the second watt-hour meter 4B ₁ , 4B ₂ , ..., _4Bn (steps S31 ₁ , S31 ₂ , ..., S31 _n ), the second watt-hour meter 4B ₁ , 4B ₂ , ..., 4B _n to sequentially acquire data (steps S32 ₁ , S32 ₂ , ..., S32 _n ). Then, the _first control unit 33 of the sub-master unit 22 sequentially adds identification information to the collected data (step S33) and compresses the data (step S34). Specifically, the first control unit 33 of the sub-master unit 22 sequentially adds identification information to the data of the _second watt-hour meter 4B ₁ , 4B ₂ , ..., _4Bn , and adds the identification information. The data of the second watt-hour meter 4B ₁ , 4B ₂ , ..., _4Bn is compressed collectively or individually. The first control unit 33 stores the compressed data in the storage unit 34. If the second control unit 43 of the sub-master unit 22 does not have the identification information of the second watt-hour meter 4B added to the collected data, the second control unit 43 will add the identification information of the sub-master unit 2 ₂ and the _second identification information to the collected data. The identification information of the watt-hour meter 4B is added.

After that, the control unit 15 of the main master unit ₁ collects data from the sub _- master unit 21 and the sub-master unit 22. Specifically, the control unit 15 of the main master unit ₁ makes a data transmission request to the sub-master unit 21 (step S14), and acquires compressed data of a plurality of second watt- _hour meters 4A from the sub-master unit 21. (Step S15). Further, the control unit 15 of the main master unit 1 makes a data transmission request to the sub-master unit 22 (step S16), and acquires compressed data of a plurality of second watt-hour meters 4B from the sub-master unit _{2 2 (} step). S17).

After that, the control unit 15 of the main master unit 1 decompresses the compressed data acquired in steps S15 and S17 (step S18), and stores the data of the plurality of decompressed second watt-hour meters 4A and 4B. The data to be stored in 16 is stored (step S19).

As described above, in the data collection system 100, the sub-master unit 2 ₁ collects the data of the second watt-hour meter 4A while the sub-master unit 2 ₂ collects the data of the first watt-hour meter 3 while the main master unit 1 collects the data of the first watt-hour meter 3. The data of the second watt-hour meter 4B are collected in parallel. After that, the main master unit ₁ collects the data of the second watt-hour meter 4A from the sub-master unit 21 and collects the data of the _second watt-hour meter 4B from the sub-master unit 22. As a result, the main master unit 1 communicates with each of the plurality of first electric energy meters 3 and the plurality of second electric energy meters 4A and 4B one by one to collect data, as compared with the case where a plurality of first electric energy meters are collected. Data of a plurality of watt-hour meters including the watt-hour meter 3 and a plurality of second watt-hour meters 4A and 4B can be quickly collected. The master unit 1 may collect data from the second watt-hour meter 4A of the second system and the second watt-hour meter 4B of the third system in addition to the data of the first watt-hour meter 3 of the first system. can.

FIG. 8 is a diagram for explaining a method of collecting data from an watt-hour meter when a coupler is provided instead of the sub-master unit according to the first embodiment. In FIG. 8, the number of the first watt-hour meter 3, the second watt-hour meter 4A, and the second watt-hour meter 4B is 150 for a total of 450, the amount of measured value data is 30 bytes, and the communication speed is high. An example of 5 kbps is shown. Further, the couplers 9 ₁ and 9 ₂ shown in FIG. 8 are parts or devices such as photocouplers that enable power line carrier communication between different systems while maintaining insulation between the systems, and have a function of storing data. I don't have it.

In the example shown in FIG. 8, the master unit 1 has data in each of the first watt-hour meter 3 ₁ to 3 _n , the second watt-hour meter 4A ₁ to 4A _n , and the second watt-hour meter 4B ₁ to 4B _n . Make a transmission request. Therefore, it takes the same amount of time to collect the data of the first watt-hour meter 3 ₁ to 3 _n , the data collection of the second watt-hour meter 4A ₁ to 4 _An , and the data collection of the second watt-hour meter 4B ₁ to 4B _n . ing. In the example shown in FIG. 8, the average time required to collect data from one watt-hour meter is 10.576 seconds, and the time required to collect data from all watt-hour meters is 1586.4 seconds. = 10.576 seconds x 150.

Here, the average time required for data collection, which is the average time required for collecting data from one watt-hour meter, will be described. FIG. 9 is a diagram for explaining the average time required for data collection according to the first embodiment, and shows an example in which the main master unit 1 collects data from a plurality of first electric energy meters _{3 1} to 34.

Since the power line carrier communication used in the data collection system 100 uses the power line as a communication line, it may not be possible to perform long-distance communication due to the influence of the electric equipment connected to the power line. Therefore, in the data collection system 100, multi-hop communication is adopted in which the watt-hour meter also relays the communication.

Assuming that the data collection time, which is the time required for data collection, is "Ta", the data collection time Ta can be obtained by the calculation of the following equation (1). In the formula (1), "N" is a hops, "Tcm" is a data communication time which is a time for transmitting and receiving data, and "Tcn" is a communication connection between devices for transmitting and receiving data. It is the communication connection time, which is the time to be spent.
Ta = Tcm × 2 × N + Tcn × 2 × (N-1) ・ ・ ・ (1)

The data communication time Tcm is calculated by the following formula (2). In the following formula (2), "Da" is the amount of data to be transmitted and received, and "Vcm" is the communication speed.
Tcm = Da / Vcm ・ ・ ・ (2)

Here, if the data amount of the measured value is 30 bytes, that is, 240 bits, and the communication speed is 5 kbps, the data communication time Tcm is 48 milliseconds as shown in FIG. 9 from the above equation (2). Is. Here, assuming that the communication connection time Tcn is 1 second and the average number of hops is "6", it is the average time required to collect data from one power meter from the above equation (1). The average time required for collecting data is 10.576 seconds = 0.048 × 2 × 6 + 1 × 2 × (6-1). Therefore, as shown in FIG. 8, the time required to collect data from 150 watt-hour meters is 1586.4 seconds = 10.576 seconds × 150. Therefore, the time required to acquire data from the watt-hour meters of all three systems is 4759.2 seconds = 1586.4 seconds × 3.

Next, the time required to acquire data from the watt-hour meters of all three systems by the data collection system 100 according to the first embodiment will be described. FIG. 10 is a diagram for explaining the time required to acquire data from all the watt-hour meters of the system by the data collection system according to the first embodiment, and the coupler shown in FIG. 8 is used as the sub-master unit 2. The conditions other than the replacement are the same as in the case of FIG.

As shown in FIG. 10, in the data collection system 100 according to the first embodiment, during the period in which the main master unit 1 collects data from a plurality of first watt-hour meters 3, the sub-master unit 21 is a plurality of _second units. Data is collected from the watt-hour meter 4A, and the sub-master unit 2 ₂ collects data from a plurality of second watt-hour meters 4B. Further, the sub-master units 2 ₁ and 2 ₂ perform data compression on the collected data. In the example shown in FIG. 10, the time required for data compression is 5 seconds.

Assuming that the compression rate of the data by the sub-master unit _{2 1} and the sub-master unit 2 2 is 50%, the data for 150 units is 150 × 30 × 0.5 = 2550 bytes. Assuming that the data collection request is 30 bytes, the time required for the main master unit 1 to collect the compressed data from the sub-master unit 2 is 7.296 seconds. Further, in the example shown in FIG. 10, the time for the main master unit 1 to decompress the compressed data acquired from the sub-master unit 2 ₁ and the sub-master unit 2 ₂ is 10 seconds.

Therefore, the time required for the master unit 1 to acquire data from the watt-hour meters of all three systems is 1608.696 seconds = 1586.4 seconds + 5 seconds + 3.648 seconds × 2 + 10 seconds. In the example shown in FIG. 8, the time required for the main unit 1 to acquire data from the watt-hour meters of all three systems is 4759.2 seconds, and in the data collection system 100, the main unit 1 has the amount of power. It can be seen that the time required to acquire data from the electricity meter is significantly reduced. In this way, the data collection system 100 can quickly collect data of a plurality of watt-hour meters including a plurality of first watt-hour meters 3 and a plurality of second watt-hour meters 4.

In the above-mentioned example, the data collection system 100 collects data from the first watt-hour meter 3 and the second watt-hour meter 4 by polling, whereby the main master unit 1 and the sub-master unit 2 ₁ are collected. , 22 _The control program can be simplified. The data collection method by the data collection system 100 is not limited to this example. For example, the data collection system 100 can collect call-type data. In this case, the control unit 15 of the main master unit 1 receives the data autonomously transmitted by the first watt-hour meter 3, and the second control unit 43 of the sub-master unit 2 is autonomous by the second watt-hour meter 4. Receives the data to be transmitted. It should be noted that the timings at which the first watt-hour meters 3 transmit data are different from each other. Similarly, the second watt-hour meter 4A has different timings for transmitting data, and the second watt-hour meters 4B have different timings for transmitting data. The data transmission cycles of the first watt-hour meter 3 and the second watt-hour meter 4A and 4B are the same as in the case of polling.

Further, in the above example, the sub-master unit 2 compresses the collected watt-hour meter data and transmits it to the main master unit 1, while the sub-master unit 2 transmits the collected watt-hour meter data as it is. You can also do it. For example, when the number of data collection target power meters is less than the preset number, the sub-master unit 2 transmits the collected power meter data as it is, and the number of data collection target power meters is increased. When the number is equal to or more than a preset number, the collected power meter data can be compressed.

Next, the operation of the main master unit 1 will be described with reference to a flowchart. FIG. 11 is a flowchart showing an example of processing of the main master unit according to the first embodiment. The process shown in FIG. 11 is repeatedly executed by the master master unit 1.

As shown in FIG. 11, the control unit 15 of the master unit 1 determines whether or not the data acquisition timing has come (step S40). The data collection timing occurs in a preset cycle. When the control unit 15 determines that the data acquisition timing has come (step S40: Yes), the control unit 15 selects one of the first watt-hour meters 3 (step S41). The control unit 15 makes a data transmission request to the selected first watt-hour meter 3 (step S42), and acquires data from the first watt-hour meter 3 of the data transmission request destination (step S43).

The control unit 15 generates data in which identification information is added to the data of the first watt-hour meter 3 acquired in step S43 and stores it in the storage unit 16 (step S44). The data stored in the storage unit 16 by the control unit 15 in step S44 includes the measured value of the first watt-hour meter 3, the identification information of the first watt-hour meter 3, and the identification information of the main master unit 1. After the process of step S44 is completed, the control unit 15 determines whether or not all the first electric energy meters 3 connected to the first power line 7 have been selected (step S45). When the control unit 15 determines that all the first watt-hour meters 3 have not been selected (step S45: No), the process shifts to step S41.

When the control unit 15 determines that all the first watt-hour meters 3 have been selected (step S45: Yes), the control unit 15 selects one sub-master unit 2 (step S46). The control unit 15 makes a data transmission request to the selected sub-master unit 2 (step S47), and acquires compressed data from the sub-master unit 2 of the data transmission request destination (step S48). The control unit 15 determines whether or not all the sub-master units 2 connected to the second power line 8 have been selected (step S49). When the control unit 15 determines that all the sub-master units 2 have not been selected (step S49: No), the control unit 15 shifts the process to step S46.

When the control unit 15 determines that all the sub-master units 2 have been selected (step S49: Yes), the control unit 15 decompresses the compressed data acquired from the sub-master unit 2 and stores the decompressed data in the storage unit 16 (step). S50). When it is determined that the data acquisition timing has not been reached (step S40: No), or when the process of step S50 is completed, the control unit 15 ends the process shown in FIG. In addition, instead of the process of step S50, the control unit 15 can also perform a process of decompressing the acquired compressed data every time the compressed data is acquired from the sub-master unit 2 in step S48.

Next, the operation of the sub _- master unit 21 will be described using a flowchart. FIG. 12 is a flowchart showing an example of processing of the sub-master unit according to the first embodiment. The process shown in FIG. 12 is repeatedly executed by the sub _- master unit 21. The operation of the sub-master unit _{2 2} is the same as the operation of the sub-master unit 21.

As shown in FIG. 12, the _second control unit 43 of the sub-master unit 21 determines whether or not the data acquisition timing has come (step S60). The data collection timing occurs in a preset cycle. When the second control unit 43 determines that the data acquisition timing has come (step S60: Yes), the second control unit 43 selects one second watt-hour meter 4A connected to the _second power line 81 (step S61). The second control unit 43 makes a data transmission request to the selected second watt-hour meter 4A (step S62), and acquires data from the second watt-hour meter 4A of the data transmission request destination (step S63).

The second control unit 43 outputs the acquired data of the second watt-hour meter 4A to the _other end of the optical coupler 241 (step S64). The _first control unit 33 of the sub-master unit 21 acquires the data of the second watt-hour meter 4A output from _one end of the optical coupler 241 (step S65), and the acquired data of the second watt-hour meter 4A. The identification information is added to the storage unit 34 and stored in the storage unit 34 (step S66). The data stored in the storage unit 34 by the first control unit 33 in step S66 includes the measured value of the second watt-hour meter 4A, the identification information of the second watt- _hour meter 4A, and the identification information of the sub-master unit 21. included.

The second control unit 43 determines whether or not all the second watt-hour meters 4A in the same system connected to the _second power line 81 have been selected (step S67). When the second control unit 43 determines that all the second watt-hour meters 4A have not been selected (step S67: No), the process shifts to step S61. Further, when the first control unit 33 determines that all the second watt-hour meters 4A have been selected by the second control unit 43 (step S67: Yes), the first control unit 33 acquires the data from the second control unit 43 and stores it in the storage unit 34. All the stored data of the second watt-hour meter 4A is read out and compressed, and the compressed data is stored in the storage unit 34 (step S68).

After that, the first control unit 33 determines whether or not there is a data transmission request from the master master unit 1 (step S69). When the first control unit 33 determines that there is no data transmission request from the main master unit 1 (step S69: No), the first control unit 33 repeats the process of step S69. When the first control unit 33 determines that there is a data transmission request (step S69: Yes), the first control unit 33 transmits the compressed data, which is the data of all the compressed second watt-hour meters 4A, to the main master unit 1 (step S70). ). When it is determined that the data collection timing has not been reached (step S60: No), or when the process of step S70 is completed, the sub _- master unit 21 ends the process shown in FIG.

FIG. 13 is a diagram showing an example of the hardware configuration of the main unit of the main master unit according to the first embodiment. As shown in FIG. 13, the main unit 13 of the main master unit 1 includes a computer including a processor 101, a memory 102, and a communication device 103. The processor 101, the memory 102, and the communication device 103 can send and receive data to and from each other by, for example, the bus 104. The PLC communication unit 14 and the upper communication unit 17 are realized by the communication device 103. The storage unit 16 is realized by the memory 102. The processor 101 executes the function of the control unit 15 by reading and executing the program stored in the memory 102. The processor 101 is an example of a processing circuit, and includes, for example, one or more of a CPU (Central Processing Unit), a DSP (Digital Signal Processer), and a system LSI (Large Scale Integration).

The memory 102 includes one or more of RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable Read Only Memory), and EEPROM (registered trademark) (Electrically Erasable Programmable Read Only Memory). include. Further, the memory 102 includes a recording medium in which a computer-readable program is recorded. Such recording media include one or more of non-volatile or volatile semiconductor memories, magnetic disks, flexible memories, optical discs, compact discs, and DVDs (Digital Versatile Discs).

Further, the first unit 23 of the sub-master unit 2 also has the hardware configuration shown in FIG. 13 like the main unit 13 of the main master unit 1. The first communication unit 31 and the third communication unit 32 are realized by the communication device 103, and the storage unit 34 is realized by the memory 102. The processor 101 executes the function of the first control unit 33 by reading and executing the program stored in the memory 102. Further, the second unit 27 of the sub-master unit 2 also has the hardware configuration shown in FIG. 13 like the main unit 13 of the main master unit 1. The second communication unit 41 and the fourth communication unit 42 are realized by the communication device 103, and the processor 101 executes the function of the second control unit 43 by reading and executing the program stored in the memory 102. The main master unit 1 and the sub master unit 2 may include integrated circuits such as an ASIC (Application Specific Integrated Circuit) and an FPGA (Field Programmable Gate Array).

As described above, the data collection system 100 according to the first embodiment is connected to the main master unit 1 connected to the first power line 7, the first power line 7, and the second power line 8, and the first power line 7 and the first power line 7. 2 The sub-master unit ₂ having optical couplers 24 ₁ and 242 for transmitting and receiving data to and from the power line 8 is provided. The main master unit 1 collects data from a plurality of first electric energy meters 3 connected to the first electric energy line 7 via the first electric power line 7 by power line carrier communication. The sub-master unit 2 is connected to a plurality of second power lines 8 via a second power line 8 by power line carrier communication during a period in which the main master unit 1 collects data from a plurality of first electric energy meters 3. After collecting data from the watt-hour meter 4, the collected data of the plurality of second watt-hour meters 4 are transmitted to the main master unit 1 via the first power line 7. Compared with the case where the main master unit 1 communicates with each of the plurality of first electric energy meters 3 and the plurality of second electric energy meters 4 one by one to collect data, the plurality of first electric energy meters 3 and the plurality of units 1 Data of a plurality of watt-hour meters including the second watt-hour meter 4 of the above can be quickly collected.

Further, the sub-master unit 2 is optically coupled to the first communication unit 31 which is connected to the first power line 7 and performs power line carrier communication, and the second communication unit 41 which is connected to the second power line 8 and performs power line carrier communication. A third communication unit 32 connected to _one end of the devices 24 ₁ and ₂₄₂ and a fourth communication unit 42 connected to the other end of the optical couplers 24 ₁ and 242 are provided. Further, the sub-master unit 2 communicates with the first control unit 33 that communicates with the main master unit 1 via the first communication unit 31, and with a plurality of second watt-hour meters 4 via the second communication unit 41. 2 A control unit 43 is provided. The second control unit 43 collects the data of the plurality of second watt-hour meters 4 sequentially acquired via the second communication unit 41 during the period in which the main master unit 1 collects data from the plurality of first watt-hour meters 3. It is sequentially output from the _fourth communication unit 42 to the optical coupler 241. The first control unit 33 sequentially acquires the data of the plurality of second watt-hour meters 4 from the second control unit 43 via the third communication unit 32, and stores the acquired data of the plurality of second watt-hour meters 4. After temporarily storing in the storage unit 34, the data of the plurality of second watt-hour meters 4 stored in the storage unit 34 is transmitted to the main master unit 1 via the first communication unit 31. Since the collected data of the second watt-hour meter 4 is stored in the storage unit 34 on the first control unit 33 side in this way, the first control unit 33 receives a data transmission request from the main master unit 1. In this case, the data of the second watt-hour meter 4 can be read from the storage unit 34 and transmitted to the main master unit 1 via the first communication unit 31. Therefore, for example, as compared with the case where the second unit 27 stores the data of the second watt-hour meter 4, the first control unit 33 responds to the data transmission request of the main master unit 1 and collects the data of the second watt-hour meter 4. Can be quickly transmitted to the main master unit 1 via the first communication unit 31.

Further, the first control unit 33 adds the identification information of the sub-master unit 2 to each of the data of the plurality of second watt-hour meters 4, and the plurality of second power quantities to which the identification information of the sub-master unit 2 is added. A total of 4 data are transmitted to the main master unit 1 via the first communication unit 31. This makes it possible to easily grasp in which system the second watt-hour meter 4 exists. For example, the data of the second watt- _hour meter 4 to which the identification information of the sub-master unit 21 is added can be easily grasped as the data of the second watt-hour meter 4A in the second system. Therefore, it is possible to determine which watt-hour meter is connected in the grid, and there is no need to investigate the watt-hour meter connected in the grid, such as when a power failure occurs due to maintenance work of electrical equipment. Will be.

Further, the first control unit 33 compresses the data of the plurality of second watt-hour meters 4 to generate compressed data, and transmits the generated compressed data to the main master unit 1 via the first communication unit 31. As a result, the data of the second watt-hour meter 4 can be quickly collected by the main master unit 1.

Further, the second control unit 43 starts collecting the data of the second watt-hour meter 4 at the timing synchronized with the timing when the main master unit 1 starts collecting the data of the first watt-hour meter 3. As a result, the data of the second watt-hour meter 4 can be quickly collected by the main master unit 1.

Further, the first power line 7 and the second power line 8 are power lines of different systems. As a result, the master unit 1 can collect the data of the watt-hour meters connected to different systems.

Embodiment 2.
In the data collection system according to the second embodiment, the sub-master unit 2 collects the data of the second watt-hour meter connected to the system to which the main master unit 1 is connected. It is different from the first embodiment in which the data of the second watt-hour meter connected to the system different from the system connected to 1 is acquired. In the following, the same components as those of the data collection system 100 according to the first embodiment are designated by the same reference numerals and the description thereof will be omitted, and the configurations different from the data collection system 100 according to the first embodiment will be mainly described. And.

FIG. 14 is a diagram showing a configuration example of the data collection system according to the second embodiment of the present invention. The data collection system 100A shown in FIG. 14 includes a main master unit 1 and a sub master unit 2 like the data collection system 100, but the main master unit 1 and the sub master unit 2 are connected to the same system. It differs from the data collection system 100 in that it acquires data from a power meter.

In the example shown in FIG. 14, the first watt-hour meter 3 ₁ , 32, ..., _{3 n} is connected to the first power line 7, and the _second watt-hour meter 4 ₁ , 42 ,.・ ・, 4 _n is connected. The first power line 7 and the second power line 8 are power lines connected to the same transformer 6, and are power lines of the same system as each other. The second watt-hour meter 4 ₁ , 4 ₂ , ..., 4 _n is located at a position away from the first power line 7 connected to the main master unit 1, and a data transmission request from the main master unit 1 arrives. It is in a difficult position.

The sub-master unit 2 is connected to the second power line 8 during the period in which the main master unit 1 is connected to the first power line 7 and collects data of the first _watt -hour meter _{3 1} , 32, ..., 3n. Data is collected from the _second watt-hour meter 4 ₁ , 42, ..., 4 _n . The sub-master unit 2 compresses the collected data of the _second watt-hour meter 4 ₁ , 42, ..., 4 _n to generate compressed data, and stores the generated compressed data. Then, when the sub-master unit 2 receives a data transmission request from the main master unit 1, the sub-master unit 2 transmits the stored compressed data to the main master unit 1.

As described above, in the data collection system 100A, the first power line 7 to which the main master unit 1 is connected and the second power line 8 to which the sub-master unit 2 is connected are power lines of the same system. Therefore, for example, even if there is a _second watt-hour meter 4 ₁ , 42, ..., 4 _n at a position where it is difficult for the data transmission request from the main master unit 1 to reach, the sub-master unit 2 is used. Data can be collected through. Moreover, the sub-master unit 2 has a plurality of second powers connected to the second power line 8 during the period in which the main master unit 1 collects data of the plurality of first electric energy meters 3 connected to the first power line 7. Since the data is collected from the watt-hour meter 4, the data of the second watt-hour meter 4 can be quickly collected by the main master unit 1. In the above example, the sub-master unit 2 collects the data of the _second watt-hour meter 4 ₁ , 42, ..., 4 _n at a position where the data transmission request from the master master unit 1 is difficult to reach. , Not limited to such examples. 2nd watt-hour meter 4 ₁ , 4 ₂ , ..., 4 _n is not the position where the data transmission request from the master unit 1 is difficult to reach, but the second watt-hour meter by the master unit 1 The data of 4 can be collected quickly.

The configuration shown in the above embodiments shows an example of the contents of the present invention, can be combined with another known technique, and is one of the configurations as long as it does not deviate from the gist of the present invention. It is also possible to omit or change the part.

1 Main master unit, 2, 2 ₁ , 2 ₂ Sub master unit, 3, 3 ₁ , 3 ₂ , 3 ₃ , 3 ₄ , ..., 3 _n 1st electricity meter, 4, 4 ₁ , 4 ₂ , ..., 4 _n , 4A, 4A ₁ , 4A ₂ , ..., 4A _n , 4B, 4B ₁ , 4B ₂ , ..., 4B _{n second} watt-hour meter, 6, 6 ₁ , 62, 6 ₃ transformer, 7 1st power line, 8, 8 ₁ , 8 ₂ 2nd power line, 11 AC coupling part, 12 analog front end part, 13 main unit, 14 PLC communication part, 15 control part, 16, 34, 44 storage Unit, 17 Upper communication unit, 21 1st AC coupling unit, 22 1st analog front end unit, 23 1st unit, 24, 24 ₁ , 24 ₂ optical coupling unit, 25 2nd AC coupling unit, 26 2nd analog front end unit , 27 2nd unit, 31 1st communication unit, 32 3rd communication unit, 33 1st control unit, 41 2nd communication unit, 42 4th communication unit, 43 2nd control unit, 9 ₁ , 9 ₂ coupler, 100,100A data collection system.

Claims (10)

The main unit connected to the first power line and
A sub-master unit connected to the first power line and the second power line and having an optical coupler for transmitting and receiving data between the first power line and the second power line is provided.
The main master unit is
Data is collected from a plurality of first electric energy meters connected to the first electric energy line via the first electric power line by power line carrier communication.
The sub-master unit is
Data from a plurality of second watt-hour meters connected to the second watt-hour meter via the second power line by the power line carrier communication during a period in which the main master unit collects data from the plurality of first watt-hour meters. A data collection system characterized in that the collected data of the plurality of second watt-hour meters is transmitted to the main master unit via the first power line. The sub-master unit is
With the first communication unit connected to the first power line and performing the power line carrier communication,
With the second communication unit connected to the second power line and performing the power line carrier communication,
A third communication unit connected to one end of the optical coupler,
With the fourth communication unit connected to the other end of the optical coupler,
A first control unit that communicates with the main master unit via the first communication unit,
A second control unit that communicates with the plurality of second watt-hour meters via the second communication unit is provided.
The second control unit
During the period when the main master unit collects data from the plurality of first electric energy meters, the data of the plurality of second electric energy meters sequentially acquired via the second communication unit is collected from the fourth communication unit. Output to the optical coupler in sequence,
The first control unit is
The data of the plurality of second watt-hour meters was sequentially acquired from the second control unit via the third communication unit, and the acquired data of the plurality of second watt-hour meters was temporarily stored in the storage unit. The data collection system according to claim 1, further comprising transmitting the data of the plurality of second watt-hour meters stored in the storage unit to the main master unit via the first communication unit. The first control unit is
The identification information of the sub-master unit is added to each of the data of the plurality of second watt-hour meters, and the data of the plurality of second watt-hour meters to which the identification information of the sub-master unit is added is the data of the main master unit. The data collection system according to claim 2, wherein the data is transmitted via the first communication unit. The first control unit is
Claim 2 or 3 characterized in that the data of the plurality of second watt-hour meters is compressed to generate compressed data, and the generated compressed data is transmitted to the main master unit via the first communication unit. The data collection system described in. The second control unit
Any of claims 2 to 4, wherein the main master unit starts collecting data of the second watt-hour meter at a timing synchronized with the timing of starting collecting data of the first watt-hour meter. The data collection system described in one. The data collection system according to any one of claims 1 to 5, wherein the first power line and the second power line are power lines having different systems. The data collection system according to any one of claims 1 to 5, wherein the first power line and the second power line are power lines having the same system. The first communication unit, which is connected to the first power line and performs power line carrier communication,
The second communication unit, which is connected to the second power line and performs power line carrier communication,
The third communication unit connected to one end of the optical coupler,
With the fourth communication unit connected to the other end of the optical coupler,
The first control unit that communicates with the main unit via the first communication unit,
A second control unit that communicates with a plurality of second watt-hour meters connected to the second power line via the second communication unit is provided.
The second control unit
During the period when the main master unit collects data from a plurality of first watt-hour meters connected to the first power line, the data of the plurality of second watt-hour meters sequentially acquired via the second communication unit is collected. Sequentially output from the 4th communication unit to the optical coupler,
The first control unit is
The data of the plurality of second watt-hour meters was sequentially acquired from the second control unit via the third communication unit, and the acquired data of the plurality of second watt-hour meters was temporarily stored in the storage unit. After that, the sub-master unit is characterized in that the data of the plurality of second watt-hour meters stored in the storage unit is transmitted to the main master unit via the first communication unit. The first control unit is
The identification information of the sub-master unit is added to each of the data of the plurality of second watt-hour meters, and the data of the plurality of second watt-hour meters to which the identification information of the sub-master unit is added is the data of the main master unit. The sub-master unit according to claim 8, wherein the data is transmitted via the first communication unit. The first control unit is
8. Sub-master unit described in.

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