JP2015007875A - Data gathering system, wired to wireless converter, and data gathering method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data gathering system, a wired to wireless converter, and a data gathering method that shorten communication time.SOLUTION: A data gathering system comprises: a data gathering device 11 as a master device; a measuring device 21 as a slave device; a master side wired to wireless converter 41 connected with the data gathering device 11 by cable; and a slave side wired to wireless converter 40A connected with the measuring device 21 by cable. According to a data acquisition command to the measuring device 21 transmitted from the data gathering device 11 to the wired to wireless converter 41, following processing can be executed in parallel: first processing by the wired to wireless converter 41 to store measurement data of the measuring device 21 in a storage device of the wired to wireless converter 41 via the wired to wireless converter 40A; and second processing by the data gathering device 11 to gather the measurement data of the measuring device 21 stored in the storage device.

Description

  The present invention relates to a data collection system, a wired / wireless converter, and a data collection method for collecting measurement data at a plurality of measurement points in one place via a wired / wireless converter, and for example, an electric energy, voltage, current, etc. This technique relates to a technique for collecting and monitoring the measurement data at one place.

FIG. 8 is a schematic configuration diagram of an energy monitoring system that measures electrical energy such as electric energy at a plurality of measurement points, collects the measurement data at one place, and centrally monitors the data.
In FIG. 8, 10 is a central monitoring room in the factory, 11 is a data collection device as a master device provided in the central monitoring room 10, and 20A and 20B are provided in separate buildings apart from the central monitoring room 10, respectively. Electric room. Reference numerals 21 to 25 denote electric energy measuring devices such as watt hour meters as slave devices installed in the respective electric chambers 20A and 20B. Station numbers 01 to 05 are assigned to the measuring devices.

  Further, the data collection device 11 and the measurement device 21 are connected by the communication cable 30 and the measurement devices 21 to 25 are also connected by the communication cables 30A and 30B. Is transmitted by wire to the data collection device 11 via the measuring device 21 of the station number 01.

  Here, FIG. 9 shows a timing chart at the time of data collection by the data collection device 11. For example, when a communication cable of the EIA-485 standard is used, and the bit rate of asynchronous serial communication is 4800 [bps], the bit length is 8 bits, odd parity, and 1 stop bit is used, 1 byte is used. The time required for data communication is about 2.29 [ms].

Also, when the master / slave type polling / selecting communication protocol is used and the data collection device 11 reads out 200 bytes of measurement data from one measurement device, for example, as shown in FIG. An 8-byte data acquisition command is sent to the measuring device, and 206-byte response data is returned from the measuring device. In this case, if the interval between the data acquisition command and the response data is 4 bytes, about 509 [ms] is required to collect data from one measuring device.
Therefore, in order to collect data from 30 measuring devices, it is sufficient to expect approximately 15.27 [s] as a whole. For example, measurement data is periodically transmitted from 30 measuring devices at a cycle of 30 [s]. Are collected.

Although the above-described data collection system using wired communication is less susceptible to noise and allows relatively stable communication, there is a problem that the cost of installing a communication cable increases as the distance between buildings increases.
For this reason, recently, a system has been proposed that reduces the cost of laying communication cables by performing wireless communication between the central monitoring room 10 and each building (electrical rooms 20A, 20B).

FIG. 10 shows a data collection system in which wireless communication is performed between the central monitoring room 10 and the electric rooms 20A and 20B. In this system, a master-side wired / wireless converter 41 is connected to a data collection device 11 in a central monitoring room 10 via a communication cable 31, and the master-side wired / wireless converter 41 and the electrical rooms 20A, 20B are connected. Wireless communication is performed between the slave-side wired / wireless converters 40A and 40B.
Communication between the wired / wireless converters 40A and 40B in the electrical rooms 20A and 20B and the measuring devices 21 to 25 is performed by wired communication via the communication cables 30A and 30B.

However, the wireless communication system shown in FIG. 10 has the following problems.
That is, when collecting the measurement data of the measuring device 21 in the electric room 20A from the data collecting device 11, first, the data collecting device 11 is wired to the wired / wireless converter 41 in the central monitoring room 10 as shown in FIG. sends data acquisition in the communication T ₁ command (8 bytes), then wired and wireless transducer 41 is electrically chamber 20A of wired and wireless converter in the radio communication T ₂ converts the data acquisition command for wireless communication feed to 40A, further wired and wireless converter 40A is sent to the measuring apparatus 21 by wire communication T ₃ converts the data acquisition command for wire communication. Then, the measuring device 21 the response data (206 bytes) by wire communication T ₃ sends to the wired-wireless converters 40A, wired and wireless converter 40A wireless communication T ₂ converts the response data for wireless communication at sent to wired or wireless transducers 41 of the central monitoring room 10, wired and wireless transducer 41 sends via a wire communication T ₁ converts the response data for wired communication to the data collection device 11.

Since the data collection device 11 collects measurement data from one measurement device 21 through the above procedure, if the same communication time is required for wireless communication and wired communication, one measurement device The time required to collect the measurement data from 3 is about 1527 [ms], which is three times that in the case of wired communication shown in FIGS.
As described above, in the wired communication system, for example, measurement data can be periodically collected from 30 measurement devices at a cycle of 30 [s]. However, in the wireless communication system shown in FIG. Operation is difficult in terms of time.
Further, in wireless communication, propagation characteristics change when a conductor such as an automobile passes through a communication path, so that communication is temporarily disabled. In this case, if the communication retry operation is performed several times to complete the communication, there is a problem that the communication time becomes long as a result.

Here, for example, Patent Documents 1 and 2 describe conventional techniques aimed at shortening the wireless communication time.
The prior art described in Patent Document 1 has a function in which each slave station intercepts that another slave station is responding to the master station, and broadcast notification is sent from the master station to a plurality of slave stations. In this case, each slave station responds to the master station as soon as the other slave stations complete the response to the master station, thereby eliminating the dead time that occurs between each slave station response. The time until the response signal is received from the station is shortened.
In the prior art described in Patent Document 2, when the data collection device collects data from a plurality of terminal wireless units, an express communication route with a small number of terminal wireless units passing through is set in addition to the normal basic communication route. When it is determined that the express communication is necessary, the data is collected by switching to the express communication route.

JP-A-10-51369 (paragraphs [0020] to [0037], FIG. 3 etc.) JP 2002-109675 A (paragraphs [0057] to [0061], FIG. 7 etc.)

In the conventional technique described in Patent Document 1, each slave station needs to have a function of intercepting a response signal from another slave station. In the conventional technique described in Patent Document 2, the basic communication route and the express communication are required. Switching to the root is necessary.
For this reason, each conventional technique has problems such as the complexity of the slave station hardware and the complexity of the communication program for switching the communication route.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a data collection system, a wired / wireless converter, and a data collection method capable of shortening the communication time without complicating hardware and communication programs.

In order to solve the above-described problem, a data collection system according to claim 1 includes a data collection device as a master device, a plurality of measurement devices as slave devices, and a master side connected to the data collection device by wire. A wired / wireless converter and a slave-side wired / wireless converter connected to the measuring device in a wired manner, between the master-side wired / wireless converter and the slave-side wired / wireless converter; In the data collection system in which the data collection device collects measurement data of the measurement device by performing wireless communication,
In accordance with a data acquisition command for each measuring device sent from the data collection device to the master-side wired / wireless converter, the master-side wired / wireless converter is connected to each measuring device via the slave-side wired / wireless converter. First processing for storing the measurement data in the storage device of the master-side wired / wireless converter, and second processing for collecting the measurement data of each measurement device stored in the storage device by the data collection device Can be executed in parallel.

  The data collection system according to claim 2 is the data collection system according to claim 1, wherein the slave-side wired / wireless converter includes a storage device that temporarily stores measurement data of each measurement device. Features.

The wired / wireless converter according to claim 3 is a wired / wireless converter connected by wire to a data collection device as a master device, and is connected by wire to a plurality of measuring devices as slave devices. In the wired / wireless converter for causing the data collecting device to collect the measurement data of the measuring device by performing wireless communication with the wired / wireless converter,
According to a data acquisition command sent from the data collection device to each measurement device, the measurement data of each measurement device is received via the wired / wireless converter on the measurement device side, and the measurement data is stored in a storage device. 1 processing and
A second process of transmitting measurement data of each measurement device stored in the storage device to the data collection device can be executed in parallel.

The data collection method according to claim 4 includes a master-side wired / wireless converter connected by wire to a data collection device as a master device, and a slave connected by wire to a plurality of measurement devices as slave devices In a data collection method in which the data collection device collects measurement data of the measurement device by performing wireless communication with the side wired / wireless converter,
In accordance with a data acquisition command for each measuring device sent from the data collection device to the master-side wired / wireless converter, the master-side wired / wireless converter is connected to each measuring device via the slave-side wired / wireless converter. First processing for storing the measurement data in the storage device of the master-side wired / wireless converter, and second processing for collecting the measurement data of each measurement device stored in the storage device by the data collection device Can be executed in parallel.

The data collection system according to claim 5 includes a data collection device as a master device, a plurality of first measurement devices as slave devices, and all loads whose power consumption is measured by the first measurement device. A power receiving point measuring device that measures the amount of power at the power receiving point of the facility, a master side wired / wireless converter connected to the data collection device by wire, and a wire to the first measuring device and the power receiving point measuring device Connected to the slave side wired / wireless converter, and performs wireless communication between the master side wired / wireless converter and the slave side wired / wireless converter to receive the first measuring device and the power receiving device. In a data collection system in which the data collection device collects measurement data of a point measurement device,
In accordance with the data acquisition command for the first measuring device and the power receiving point measuring device sent from the data collection device to the master side wired / wireless converter, the master side wired / wireless converter is connected to the slave side wired / wireless converter. A first process for storing measurement data of the first measurement device and the power receiving point measurement device in a storage device of the master-side wired / wireless converter via a converter; and the data collection device stores in the storage device And the second process of collecting measurement data of the first measuring device and the power receiving point measuring device being performed can be executed in parallel.

  A data collection system according to a sixth aspect is the data collection system according to the fifth aspect, wherein the master-side wired / wireless converter has a timing at which a data acquisition command is sent from the data collection device to the power receiving point measurement device. Immediately before, the measurement data of the power receiving point measuring device is collected via the slave-side wired / wireless converter and stored in the storage device.

The data collection method according to claim 7 includes a master side wired / wireless converter connected to a data collection device as a master device by wire,
Wired to a plurality of first measurement devices as slave devices and a power reception point measurement device that measures the power consumption of a power reception point of equipment including all loads whose power consumption is measured by the first measurement device In the data collection method in which the data collection device collects measurement data of the first measurement device and the power receiving point measurement device by performing wireless communication with the connected slave-side wired / wireless converter,
In accordance with the data acquisition command for the first measuring device and the power receiving point measuring device sent from the data collection device to the master side wired / wireless converter, the master side wired / wireless converter is connected to the slave side wired / wireless converter. First processing for storing measurement data of the first measurement device and the power receiving point measurement device in the storage device of the master-side wired / wireless converter via the converter, and the data collection device stored in the storage device The second process of collecting measurement data of the first measuring device and the power receiving point measuring device that are being performed can be executed in parallel.

According to the present invention, in parallel with the process of collecting measurement data of a certain measuring device via a wired / wireless converter, the data collecting device has already acquired another measuring device and stored it in the wired / wireless converter. It is possible to collect measured data. Therefore, the overall time required to collect data from multiple measurement devices can be reduced compared to the case where the processing from the start of the data acquisition command to the collection of measurement data is sequentially performed for each measurement device. Can do.
In addition, general-purpose products can be used for wired / wireless converters and data measurement devices, and there is no need for an intercept function for communication of other stations or a switching process for communication routes as described in the prior art documents. Therefore, it is possible to construct a system and collect data at low cost with less burden on hardware and software.
Furthermore, by adding a function of collecting the power amount at the power receiving point at a fixed period, it is possible to provide a data collection system optimal for so-called demand monitoring.

In 1st Embodiment of this invention, it is operation | movement explanatory drawing when a data collection device transmits the data acquisition command. It is a schematic block diagram of the wire / wireless converter in each embodiment of this invention. In 1st Embodiment of this invention, it is operation | movement explanatory drawing when a data collection device transmits the data acquisition command. In 1st Embodiment of this invention, it is operation | movement explanatory drawing when a data collection device transmits the data acquisition command. It is a block diagram of the data collection system in 2nd Embodiment of this invention. In 2nd Embodiment of this invention, it is explanatory drawing of the operation | movement which estimates the maximum electric energy of a receiving point. In 2nd Embodiment of this invention, it is operation | movement explanatory drawing when a data collection device transmits the data acquisition command with respect to a receiving point. It is a block diagram of the data collection system by wired communication. It is a timing chart of the data collection by wired communication. It is a block diagram of the data collection system by radio | wireless communication. It is a timing chart of the data collection by radio | wireless communication.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The overall configuration of the data collection system according to the first embodiment is the same as that shown in FIG. 10, for example, and is a central monitoring room having a data collection device 11 as a master device and a master-side wired / wireless converter 41. 10, an electrical room 20 </ b> A having a slave-side wired / wireless converter 40 </ b> A and electrical energy measuring devices 21 to 23 as slave devices, and a slave-side wired / wireless converter 40 </ b> B and electrical energy measuring devices 24 and 25 as slave devices. It is possible to perform wireless communication between the central monitoring room 10 and the electric rooms 20A and 20B. In addition, it cannot be overemphasized that the number of electrical rooms and the number of electrical energy measuring devices are not limited to said example, and names, such as a central monitoring room and an electrical room, are not specifically limited, either.

Hereinafter, an operation when the data collection device 11 of FIG. 10 collects measurement data such as electric energy data by the measurement devices 21 and 22 of the electric room 20A will be described. Here, it is assumed that the data collection device 11 recognizes in advance the station numbers (numbers) of the measurement devices in the electric chambers 20A and 20B.
First, FIG. 1 shows an operation when the data collection device 11 transmits a data acquisition command to the measurement device 21 with the station number 01 in the electric room 20A.

  In this case, the data acquisition command is sent from the data collection device 11 to the wired / wireless converter 41 (process 101), converted for wireless communication, and transmitted to the wired / wireless converter 40A in the electrical room 20A (process 201). ). The wired / wireless converter 40A converts the received signal for wired communication and sends it to the measuring device 21 with the station number 01 (process 301). The measuring device 21 measures the amount of electricity such as the amount of power, and sends the measured data together with its own station number 01 to the wired / wireless converter 40A (processing 302). The wired / wireless converter 40A converts the sent measurement data for wireless communication and transmits the converted data to the wired / wireless converter 41 (process 202). The wired / wireless converter 41 converts the received data for wired communication and sends it to the data collection device 11 (process 102).

Here, the wired / wireless converters 41 and 40A (same as the wired / wireless converter 40B of the electric room 20B) have an internal memory (RAM), and can hold the received data acquisition command and measurement data for a certain period. is there. In addition, the measurement device 21 (the same applies to the other measurement devices 22 to 25) also includes an internal memory (RAM), and can hold measurement data acquired in response to a data acquisition command for a certain period.
In FIG. 1, the time delay required for the wired / wireless conversion process or wireless / wired conversion process of signals and data in the wired / wireless converters 41 and 40A is omitted.

As described above, when the first measurement data request is made to the measuring device 21 with the station number 01, the data collection operation similar to the conventional FIG. 11 is executed by sequentially executing the processing 101, 201, 301, 302, 202, 102. Is done.
By receiving the measurement data of the measurement device 21 through this series of operations, the data collection device 11 recognizes that the communication path from the data collection device 11 to the measurement device 21 and the operations of each device and converter are normal. Is possible. Further, when the measurement data of the measuring device 21 cannot be received, it is determined that any of the communication path, each device, or the converter is abnormal, and retry is made after a certain time, or the measuring device 21 is abnormal. Assuming that the data acquisition command is transmitted to the measuring device 22 of the next station number 02.
Here, the description will be continued assuming that the communication channel or each device and the converter are normal and the data collection device 11 has received the measurement data of the measurement device 21 by the process 102.

  The wired / wireless converter 41 in the central monitoring room 10 starts a data acquisition command for the measuring device 21 of the station number 01 stored in the internal memory periodically thereafter, and then the wired / wireless converter 40A of the electric room 20A. (Processes 203 and 205), the wired / wireless converter 40A sends a data acquisition command to the measuring device 21 each time (processes 303 and 305). The measuring device 21 measures the electrical quantity data according to each data acquisition command, sends the measured data to the wired / wireless converter 40A and temporarily stores it in the internal memory (processing 304, 306), and further, wired / wireless. The data is transmitted from the converter 40A to the wired / wireless converter 41 and stored in the internal memory (processing 204, 206).

With the above operation, once the data acquisition command for the measuring device 21 is once sent from the data collection device 11 to the wired / wireless converter 41 in its own station, the data acquisition command is periodically sent to the wired / wireless converter in the electric room 20A. 40A is sequentially sent to the measuring device 21, and the measurement data of the measuring device 21 is collected each time and stored in the internal memory of the wired / wireless converter 41. Therefore, the data collection device 11 can collect the measurement data of the measurement device 21 by accessing only the internal memory of the wired / wireless converter 41 as necessary.
In the internal memory of the wired / wireless converter 41, the latest measurement data of the measurement device 21 may be stored by overwriting the previous measurement data, or the measurement data of each time in order to know the trend of the measurement data. You may remember.

  Here, the wired / wireless converters 41 and 40A are configured as shown in FIG. 2, for example, and both have the same configuration. For example, the wired / wireless converter 41 includes an RS485 driver 401 for exchanging messages such as data acquisition commands and measurement data by wired communication with the microcomputer 404, and an internal memory 402 for storing the data acquisition commands, measurement data, and the like. And a wireless communication module 403 that modulates and demodulates messages such as data acquisition commands and measurement data, and a microcomputer 404 that controls these units 401, 402, and 403 in an integrated manner. As an interface between the RS485 driver 401 and the wireless communication module 403 and the microcomputer 404, for example, a UART (Universal Asynchronous Receiver Transmitter) can be used. The configuration of the wired / wireless converters 41 and 40A is not limited to that shown in FIG.

Next, FIG. 3 shows an operation when the data collection device 11 transmits a data acquisition command to the measuring device 22 of the station number 02 following the measuring device 21 of the station number 01.
In FIG. 3, before the data collection device 11 generates a data acquisition command for the measurement device 22 with the station number 02, the wired / wireless converters 41 and 40A collect the measurement data of the measurement device 21 with the station number 01, and It is stored in the internal memory of the wireless converter 41 (processing 302, 202, 203, 303, etc.).

In this state, a data acquisition command for the measuring device 22 with the station number 02 is sent from the data collection device 11 to the wired / wireless converter 41 (process 101), and this command is converted for wireless communication to be wired / wired in the electric room 20A. It is transmitted to the radio converter 40A (process 205). Thereafter, the measurement data of the measuring device 22 is collected by the operation of the wired / wireless converter 40A, the measuring device 22, and the wired / wireless converter 40A, and stored in the internal memory of the wired / wireless converter 41 (processing 305). , 306, 206). Then, as a response to the processing 101 described above, the measurement data of the measuring device 22 is sent from the wired / wireless converter 41 to the data collection device 11 (processing 102).
Through the above-described operation, it is possible to recognize that the operation of the communication path, each device, and the converter from the data collection device 11 to the measurement device 22 is normal as in the case of starting the data acquisition command for the measurement device 21.

  Thereafter, since the data acquisition commands for the measuring devices 21 and 22 are stored in the internal memory of the wired / wireless converter 41, the data acquisition commands for the measuring devices 21 and 22 are alternately and periodically stored in the electric chamber 20A. Are sequentially sent to the wired / wireless converter 40A and the measuring devices 21 and 22, and the measurement data of the measuring devices 21 and 22 are collected each time and stored in the internal memory of the wired / wireless converter 41. Therefore, the data collection device 11 can collect the measurement data of the measurement devices 21 and 22 by accessing only the internal memory of the wired / wireless converter 41 as necessary.

FIG. 4 shows an operation in which the data collection device 11 alternately collects the measurement data of the measurement device 21 and the measurement data of the measurement device 22.
As shown in FIG. 3, after the data acquisition command for the measuring device 22 with the station number 02 is activated, each measurement data is transmitted by the wired / wireless converter 40 </ b> A and the measuring devices 21, 22 lower than the wired / wireless converter 41. Are alternately collected and stored in the internal memory of the wired / wireless converter 41 (processing 202, 204, 206, 208, 210). Therefore, the data collection device 11 can collect the measurement data of the measurement devices 21 and 22 by accessing only the internal memory of the wired / wireless converter 41.
Although not shown in the figure, the data acquisition command is sequentially sent from the data collection device 11 to the wired / wireless converter 41 to the other measuring devices 23 to 25, so that it is lower than the wired / wireless converter 41. The measurement data is sequentially collected by the wired / wireless converters 40A and 40B and the measuring devices 23 to 25 and stored in the internal memory of the wired / wireless converter 41.

  When there is no response from the measuring device that sent the data acquisition command (when the measuring device is abnormal or when the measuring device is missing), the internal memory of the wired / wireless converter 41 The previous measurement data of the measurement device stored in the memory may be responded, and if there is no response from the measurement device multiple times in succession, data collection is performed indicating that the measurement device is abnormal or missing. After that, in response to the device 11, activation of the data acquisition command for the measuring device may be skipped.

As described above, in the present embodiment, a plurality of measuring devices 21 to 25 are connected from the wired / wireless converter 41 in the central monitoring room 10 to the wired / wireless converters 40A, 40B in the electrical rooms 20A, 20B. In parallel with the process of collecting the measurement data by the wired / wireless converter 41, the data collection device 11 can collect the measurement data of each measuring device stored in the internal memory of the wired / wireless converter 41.
That is, in parallel with the process of collecting the measurement data of a certain measuring device by the wired / wireless converters 41, 40 </ b> A, 40 </ b> B, the data collecting device 11 has already acquired another measuring device and transferred it to the wired / wireless converter 41. It is possible to collect stored measurement data. Therefore, when the real-time property of measurement data is not particularly required, compared to the case where the processing from the start of the data acquisition command to the collection of measurement data is sequentially performed for each measurement device, multiple measurement devices are used. The overall time required for data collection can be reduced.

Next, FIGS. 5 to 7 show a second embodiment of the present invention.
In the second embodiment, the measurement devices 21 to 25 in the electric chambers 20A and 20B (the measurement devices 21 to 25 are referred to as first measurement devices in order to be distinguished from the power receiving point measurement device 51 described later) are the first. The measurement data is collected by the same operation as that of the first embodiment, the received power amount at the power receiving point from the power company is measured at a certain period, the power amount in a predetermined period is predicted, and the integrated value is the maximum power amount (contract power This is for so-called demand monitoring so as not to exceed (quantity).

FIG. 5 is a configuration diagram of the data collection system of the present embodiment. Components that are the same as those in FIG. 10 are assigned the same reference numerals, and descriptions thereof are omitted. Hereinafter, portions different from those in FIG. 10 will be mainly described. .
In FIG. 5, reference numeral 60 denotes a power receiving transformer connected to the power system, and a power receiving point 50 on the secondary side includes the received power amount (all loads whose power consumption is measured by the measuring devices 21 to 25). A power receiving point measuring device 51 for measuring the power consumption of the target facility is connected. Reference numeral 52 denotes a power cable for supplying power to the electric chambers 20A and 20B.
For example, a station number 00 is assigned to the power receiving point measuring device 51, and this measuring device 51 is connected to the wired / wireless converter 40A.

Here, FIG. 6 is an explanatory diagram of an operation for predicting the maximum power amount of the power receiving point 50. Demand monitoring measures the amount of power at the power receiving point at a constant period Δt (= 30 [s]) as shown in the figure so that the integrated value of the amount of power for a predetermined period (for example, 30 minutes) does not exceed the maximum power amount. The measurement data is used to predict the amount of power for a predetermined period.
Therefore, in the present embodiment, the power amount at the power receiving point 50 is collected at a period of 30 [s] by the operation as shown in FIG.

In FIG. 7, the process in which the data collection device 11 collects the measurement data of the measurement devices (first measurement devices) 21 and 22 in the electric chamber 20A is the same as that in FIGS.
In addition, in this embodiment, the data collection device 11 executes the data acquisition command activation and measurement data collection processing for the power receiving point measuring device 51 of the station number 00 of the power receiving point 50 at a cycle of 30 [s] ( Processing 151, 152 in FIG.
Specifically, the data collection device 11 sends a data acquisition command to the power receiving point measurement device 51 to the wired / wireless converter 41, and the wired / wireless converter 41 passes through the wired / wireless converter 40A in the electrical room 20A. The power receiving point measuring device 51 is operated to measure the amount of power at the power receiving point 50. The measurement data is transmitted from the wired / wireless converter 40 </ b> A to the wired / wireless converter 41 and stored in the internal memory of the wired / wireless converter 41. This measurement data is read from the internal memory of the wired / wireless converter 41 by the next data acquisition command from the data collection device 11 and sent to the data collection device 11.

Since there is a request for the data collection device 11 to collect the latest power consumption measurement data, for example, 5 [s] before the data collection device 11 activates the next data acquisition command for the power receiving point measurement device 51. When the wired / wireless converter 41 transmits a data acquisition command to the wired / wireless converter 40A, the receiving point is already received from the wired / wireless converter 40A when the next data acquisition command is sent from the data collection device 11. It is desirable that the power amount measurement data of the measuring device 51 is received and stored in the internal memory.
That is, since the timing at which the data acquisition command for the power measurement data is sent from the data collection device 11 to the wired / wireless converter 41 is known in advance, 5 [s] before the next data acquisition command is sent. The data acquisition command of the electric energy measurement data for the power receiving point measuring device 51 may be transmitted to the wired / wireless converter 40A (after 25 [s] from the previous reception of the data acquisition command).

  According to the present embodiment, the data collection device 11 can collect the measurement data of the plurality of measurement devices 21 to 25 in each of the electric chambers 20A and 20B in a short time, and the power amount measurement data by the power receiving point measurement device 51 is constant. Since it can be collected periodically, it can be used for demand monitoring of the entire power receiving facility.

  The present invention is not limited to the collection of electricity amount data such as the amount of electric power, but can also be used for a system that collects measurement data such as gas usage amount and water and sewage usage amount.

10: Central monitoring room 11: Data collection devices 20A, 20B: Electric rooms 21-25: Electric energy measuring devices 30, 30A, 30B, 31: Communication cables 40A, 40B, 41: Wired / wireless converter 50: Power receiving point 51 : Power receiving point measuring device 52: Power cable 60: Power receiving transformer 401: RS485 driver 402: Internal memory (RAM)
403: Wireless communication module 404: Microcomputer

Claims (7)

A data collection device as a master device, a plurality of measurement devices as slave devices, a master-side wired / wireless converter connected to the data collection device by wire, and a wire connected to the measurement device A slave-side wired / wireless converter, and the data collection device performs measurement data of the measuring device by performing wireless communication between the master-side wired / wireless converter and the slave-side wired / wireless converter. In the data collection system to collect,
In accordance with a data acquisition command for each measuring device sent from the data collection device to the master-side wired / wireless converter, the master-side wired / wireless converter is connected to each measuring device via the slave-side wired / wireless converter. First processing for storing the measurement data in the storage device of the master-side wired / wireless converter, and second processing for collecting the measurement data of each measurement device stored in the storage device by the data collection device And a data collection system that can be executed in parallel. The data collection system according to claim 1,
The slave-side wired / wireless converter includes a storage device that temporarily stores measurement data of each measurement device. A wired / wireless converter connected by wire to a data collection device as a master device, and wirelessly communicated with a wired / wireless converter connected by wire to multiple measuring devices as slave devices In a wired / wireless converter for making the data collection device collect the measurement data of the measurement device by performing
According to a data acquisition command sent from the data collection device to each measurement device, the measurement data of each measurement device is received via the wired / wireless converter on the measurement device side, and the measurement data is stored in a storage device. 1 processing and
A wired / wireless converter capable of executing, in parallel, a second process of transmitting measurement data of each measurement device stored in the storage device to the data collection device. Between the master-side wired / wireless converter connected by wire to the data collection device as the master device and the slave-side wired / wireless converter connected by wire to multiple measuring devices as slave devices In the data collection method in which the data collection device collects measurement data of the measurement device by performing wireless communication,
In accordance with a data acquisition command for each measuring device sent from the data collection device to the master-side wired / wireless converter, the master-side wired / wireless converter is connected to each measuring device via the slave-side wired / wireless converter. First processing for storing the measurement data in the storage device of the master-side wired / wireless converter, and second processing for collecting the measurement data of each measurement device stored in the storage device by the data collection device Can be executed in parallel. The power collection point of the equipment including the data collection device as the master device, the plurality of first measurement devices as the slave devices, and all loads whose power consumption is measured by the first measurement device is measured. Power receiving point measuring device, master side wired / wireless converter connected to the data collecting device by wire, slave side wired / wireless conversion connected to the first measuring device and the power receiving point measuring device by wire A wireless communication between the master side wired / wireless converter and the slave side wired / wireless converter to collect measurement data of the first measuring device and the power receiving point measuring device. In the data collection system that the device collects,
In accordance with the data acquisition command for the first measuring device and the power receiving point measuring device sent from the data collection device to the master side wired / wireless converter, the master side wired / wireless converter is connected to the slave side wired / wireless converter. First processing for storing measurement data of the first measurement device and the power receiving point measurement device in the storage device of the master-side wired / wireless converter via the converter, and the data collection device stored in the storage device And a second process of collecting measurement data of the first measurement device and the power receiving point measurement device, which is performed, can be executed in parallel. The data collection system according to claim 5,
The master side wired / wireless converter is:
Immediately before a data acquisition command is sent from the data collection device to the power reception point measurement device, the measurement data of the power reception point measurement device is collected via the slave-side wired / wireless converter and stored in the storage device. A data collection system characterized by A master side wired / wireless converter connected by wire to a data collection device as a master device;
Wired to a plurality of first measurement devices as slave devices and a power reception point measurement device that measures the power consumption of a power reception point of equipment including all loads whose power consumption is measured by the first measurement device In the data collection method in which the data collection device collects measurement data of the first measurement device and the power receiving point measurement device by performing wireless communication with the connected slave-side wired / wireless converter,
In accordance with the data acquisition command for the first measuring device and the power receiving point measuring device sent from the data collection device to the master side wired / wireless converter, the master side wired / wireless converter is connected to the slave side wired / wireless converter. First processing for storing measurement data of the first measurement device and the power receiving point measurement device in the storage device of the master-side wired / wireless converter via the converter, and the data collection device stored in the storage device A data collection method characterized in that the first processing device and the second process of collecting measurement data of the power receiving point measurement device can be executed in parallel.

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