JP2019140811A - Remote monitoring device, remote monitoring method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To collectively monitor power generation devices connected to a plurality of power conditioners of different models. SOLUTION: A remote monitoring device 106 is a collection program for creating power generation-related data based on acquisition data acquired from a power conditioner that converts electric power obtained by a power generation device that uses natural energy. By executing the collection program storage unit 110 in which the first program 110a and the second program 110b are stored, and the first program 110a and the second program 110b, respectively, the power generation related data based on the first acquisition data and the second A data creation unit that creates power generation related data based on each of the acquired data, and an output unit 113 that sequentially outputs the power generation related data created by the data creation unit to a predetermined device. The power generation related data is data including a plurality of predetermined types of power generation related information in a predetermined order. [Selection diagram] Fig. 3

Description

  The present invention relates to a remote monitoring device, a remote monitoring method, and a program.

  In power plants that use natural energy such as sunlight and wind power, various remote monitoring devices have been proposed for monitoring the amount of power generation and the presence or absence of defects in the power generation device.

  For example, Patent Literature 1 describes that a measurement data collection unit of a photovoltaic power generation system monitoring apparatus collects measurement data related to a power generation state from a power conditioner connected to a photovoltaic cell panel.

JP, 2015-121870, A

  However, various types of power conditioners are provided by manufacturers according to the scale of the power plant and the type of natural energy used by the power generation device. In the inverters of different models such as manufacturers and model numbers, the types of data that can be acquired from the inverters and the method for acquiring the data may differ. Therefore, it is difficult to collectively monitor the power generation devices connected to a plurality of power conditioners of different models.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a remote monitoring device that can collectively monitor power generation devices connected to a plurality of power conditioners of different models. To do.

In order to achieve the above object, a remote monitoring device according to the first aspect of the present invention provides:
A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A second collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy. A collected program storage unit for storing the program;
A data creation unit that creates the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program When,
An output unit that sequentially outputs the power generation related data created by the data creation unit to a predetermined device;
The power generation related data includes a plurality of predetermined types of power generation related information in a predetermined order,
The first program and the second program are different programs.

A remote monitoring method according to a second aspect of the present invention includes:
A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A second collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy. A remote monitoring method executed by a remote monitoring device including a collected program storage unit in which a program is stored,
Creating each of the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program;
Outputting the generated power generation related data sequentially to a predetermined device,
The power generation related data includes a plurality of predetermined types of power generation related information in a predetermined order,
The first program and the second program are different programs.

The program according to the third aspect of the present invention is:
On the computer,
A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy, A collection program storage unit for storing a second program different from the first program;
A data creation unit that creates the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program When,
For realizing an output unit that sequentially outputs the power generation related data created by the data creation unit to a predetermined device,
The power generation related data is a program for realizing to include a plurality of predetermined types of power generation related information in a predetermined order.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to monitor collectively the electric power generating apparatus connected to the several power conditioner from which a model differs.

It is a figure which shows the structure of the remote monitoring system which concerns on one embodiment of this invention. It is a figure which shows an example of a structure of electric power generation related data. It is a figure which shows the structure of the remote monitoring apparatus which concerns on one embodiment. It is a figure which shows an example of management information. It is a figure which shows the structure of the 1st process part which concerns on one embodiment. It is a figure which shows the structure of the 2nd process part which concerns on one embodiment. It is a figure which shows the structure of the server apparatus which concerns on one embodiment. It is a figure which shows an example of server management information. It is a flowchart which shows the flow of the program setting process which concerns on one embodiment. It is a flowchart which shows the flow of the remote monitoring process which concerns on one embodiment. It is a flowchart which shows the flow of the 1st process included in the remote monitoring process shown in FIG. It is a figure which shows the process of producing electric power generation related data from 1st acquisition data. It is a flowchart which shows the flow of the 2nd process included in the remote monitoring process shown in FIG. It is a figure which shows the process of producing electric power generation related data from 2nd acquisition data. It is a flowchart which shows the flow of the suppression command creation process which concerns on one Embodiment. It is a flowchart which shows the flow of the output suppression process which concerns on one Embodiment.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The same elements are denoted by the same reference symbols throughout the drawings.

  A remote monitoring system 100 according to an embodiment of the present invention is a system for monitoring a power generation situation in a power plant from a remote location. As shown in FIG. 1, the remote monitoring system 100 includes a plurality of terminal devices 101a and 101b, a plurality of first power generation devices 102, a plurality of second power generation devices 103, a first power conditioner 104, and a second power conditioner 104. A power conditioner 105, a remote monitoring device 106, and a server device 107 are provided.

  As shown in FIG. 1, the remote monitoring device 106 is typically installed in a power plant together with a plurality of first power generation devices 102, a plurality of second power generation devices 103, a first power conditioner 104, and a second power conditioner 105. Installed.

  Note that the number of power conditioners connected to the remote monitoring device 106 is not limited to two, the first power conditioner 104 and the second power conditioner 105, and may be three or more. Further, the number of the first power generation devices 102 and the number of the second power generation devices 103 connected to the first power conditioner 104 and the second power conditioner 105 are not limited to three, and there is at least one. That's fine.

  The terminal devices 101a and 101b are tablet terminals, notebook computers, smart phones, and the like.

  The terminal device 101a is a terminal device used by the user of the remote monitoring device 106.

  The terminal device 101 a has a function for making various settings in the remote monitoring device 106. The terminal device 101a is configured to be able to communicate with each other between the remote monitoring device 106 and the server device 107 via a network constructed by appropriately combining wireless and wired lines.

  The terminal device 101b is a terminal device used by a power plant owner or the like.

  When the power generation status information transmitted from the server device 107 is acquired, the terminal device 101b has a function of displaying numerical values, graphs, and the like based on the power generation status information. The terminal device 101b communicates with the server device 107 via a network constructed by appropriately combining wireless and wired lines.

  The power generation status information is information relating to the power generation status at the power plant, and includes, for example, instantaneous power generation [W], presence / absence of a malfunction in the first power generation device 102 or the second power generation device 103, and the amount of power sold.

  The plurality of first power generation devices 102 and the plurality of second power generation devices 103 are devices that generate power using natural energy such as sunlight and wind power. For example, the first power generation device 102 is a solar power generation panel, and the second power generation device 103 is a wind power generation device.

  The first power generation device 102 and the second power generation device 103 may be a power generation device that uses common natural energy, or may be a power generation device that uses natural energy other than sunlight and wind power.

  The first power conditioner 104 is a power conditioner that converts electric power obtained by the plurality of first power generation devices 102. The first power conditioner 104 continuously acquires the power generation related information of the plurality of first power generation devices 102.

  The first power conditioner 104 communicates with the remote monitoring device 106 via a network constructed by appropriately combining wireless and wired lines. Thus, the first power conditioner 104 transmits the power generation related information to the remote monitoring device 106 in response to a request from the remote monitoring device 106.

  The second power conditioner 105 is a power conditioner that converts electric power obtained by the plurality of second power generation devices 103. The second power conditioner 105 continuously acquires the power generation related information of the plurality of second power generation devices 103.

  The second power conditioner 105 communicates with the remote monitoring device 106 via a network constructed by appropriately combining wireless and wired lines. As a result, the second power conditioner 105 transmits power generation related information to the remote monitoring device 106 in response to a request from the remote monitoring device 106.

  Here, the power generation related information is information related to power generation.

Specific examples of power generation related information include instantaneous power generation [W], instantaneous current [A], instantaneous voltage [V], solar radiation [W / m ² ], temperature [° C.], wind power [m / s], ground fault An error code indicating a malfunction such as

  Each of the instantaneous power generation, the instantaneous current, and the instantaneous voltage is acquired as a measurement result of a wattmeter, an ammeter, a voltmeter, etc. installed in each of the first power conditioner 104 and the second power conditioner 105, for example.

  The amount of solar radiation, temperature, and wind power are acquired from, for example, a solar radiation sensor, a temperature sensor, and an anemometer installed in the power plant.

  An error code is acquired as an error code corresponding to a ground fault detected based on a comparison result between an instantaneous current and a predetermined threshold value. The error code is stored in advance in the first power conditioner 104 and the second power conditioner 105 according to the type of error.

  Generally, if the power conditioner is different, the type of power generation related information that can be acquired from the outside, the procedure and command for acquiring the power generation related information from outside, the procedure and command for controlling the output power from the outside Etc. may be different. The model here is specified by, for example, a combination of a manufacturer of the power conditioner and a model number determined by the manufacturer.

  The first power conditioner 104 and the second power conditioner 105 according to the present embodiment have different models, and the types of power generation related information that can be acquired from the remote monitoring device 106 and the power generation related information from the remote monitoring device 106 are acquired. It is assumed that the procedures and commands for doing so are different.

For example, the first power conditioner 104 includes the instantaneous power generation [W], the instantaneous current [A], the instantaneous voltage [V], the solar radiation [W / m ² ], the temperature [ [° C.] can be acquired. And in the 1st power conditioner 104, the command which can acquire all these electric power generation related information collectively shall be employ | adopted.

  On the other hand, the second power conditioner 105 includes the instantaneous power generation [W], the instantaneous current [A], the instantaneous voltage [V], the wind force [m / s], the temperature among the examples of the power generation related information. It is assumed that [° C.] can be acquired. And in the 2nd power conditioner 105, the command which can acquire these electric power generation related information separately shall be employ | adopted.

Note that the instantaneous power generation [W], the instantaneous current [A], the instantaneous voltage [V], the solar radiation amount [W / m ² ], and the air temperature [° C.] listed in the present embodiment are the first power conditioner 104. It is an example of the electric power generation related information which can be acquired from. Further, the instantaneous power generation [W], instantaneous current [A], instantaneous voltage [V], wind power [m / s], and air temperature [° C.] listed in the present embodiment are acquired from the second power conditioner 105. It is an example of possible power generation related information. The power generation related information that can be acquired from the first power conditioner 104 and the second power conditioner 105 is determined according to the model of each power conditioner, and may be different from the present embodiment.

  The remote monitoring device 106 acquires power generation related information from each of the first power conditioner 104 and the second power conditioner 105, and transmits it to the server device 107 as power generation related data in a unified format. Further, the remote monitoring device 106 controls the output power of the first power conditioner 104 and the second power conditioner 105.

  The power generation related data is data including a plurality of types of power generation related information determined in advance. The type of power generation related information included in the power generation related data is appropriately determined from power generation related information obtainable from a general power conditioner.

In the present embodiment, as shown in FIG. 2, as power generation related information included in power generation related data, instantaneous power generation [W], temperature [° C.], solar radiation [W / m ² ], wind power [m / s] Will be described using a predetermined example. In the present embodiment, the order of the power generation related information in the power generation related data is also determined in advance in the above order.

  When the error code is included in the power generation related data, an error code table for converting the error code may be stored in advance in the remote monitoring device 106 for each model of the power conditioner.

  As shown in detail in FIG. 3, the remote monitoring apparatus 106 includes a model acquisition unit 108, a collection program acquisition unit 109, a collection program storage unit 110, a management storage unit 111, a data creation unit 112, and an output unit. 113 and the output suppression part 114 are provided.

  The model acquisition unit 108 acquires model information of a power conditioner connected to the remote monitoring device 106 based on a user input or the like to the terminal device 101a. The model information is information indicating the model of the power conditioner.

  When the model information is acquired by the model acquisition unit 108, the collection program acquisition unit 109 acquires, from the server device 107, a collection program applied to the power conditioner of the model indicated by the model information.

  The collection program is a program for acquiring one or more acquired data from the power conditioner and creating power generation related data based on the one or more acquired data. The acquisition data is data acquired from the power conditioner. The one or more acquired data includes all of the power generation related information that can be acquired from the power conditioner among a plurality of types of power generation related information that are predetermined to be included in the power generation related data.

  Note that the program means a computer program.

  The collection program storage unit 110 is a storage unit in which the collection program acquired by the collection program acquisition unit 109 is stored. The collection program storage unit 110 stores a collection program corresponding to the model of the inverter connected to the remote monitoring device 106.

  As shown in FIG. 3, the collected program storage unit 110 according to the present embodiment stores a first program 110a and a second program 110b. The first program 110a and the second program 110b are collection programs applied to the first power conditioner 104 and the second power conditioner 105, respectively, and are different programs.

  In other words, the first program 110 a is a collection program for creating power generation related data based on the first acquisition data acquired from the first power conditioner 104.

  The first acquired data is acquired data from the first power conditioner 104, and is a type that can be acquired from the first power conditioner 104 among a plurality of types of power generation related information that is predetermined to be included in the power generation related data. Includes all power generation related information.

The first acquisition data according to the present embodiment includes all of instantaneous power generation [W], solar radiation [W / m ² ], and temperature [° C.].

  The second program 110b is a collection program for creating power generation related data based on a plurality of second acquisition data acquired from the second power conditioner 105.

  The plurality of second acquired data is acquired data from the second power conditioner 105, and can be acquired from the second power conditioner 105 among a plurality of types of power generation related information predetermined to be included in the power generation related data. Includes all kinds of power generation related information.

  Each of the second acquired data according to the present embodiment includes any one of instantaneous generated power [W], temperature [° C.], and wind power [m / s].

  The management storage unit 111 is a storage unit that stores management information 111 a for managing the collection program stored in the collection program storage unit 110.

  As shown in FIG. 4, the management information 111a is information for associating the above-described model information with identification information. The identification information included in the management information 111a is information for identifying the collection program stored in the collection program storage unit 110. The identification information included in the management information 111a is information indicating an address where the collection program is stored in the collection program storage unit 110, for example.

  The data creation unit 112 creates the power generation related data based on the first acquisition data and the power generation related data based on each of the second acquisition data by executing each of the first program 110a and the second program 110b.

  Specifically, as shown in FIG. 3, the data creation unit 112 includes a first processing unit 115, a second processing unit 116, and a processing control unit 117.

  The 1st process part 115 produces the electric power generation related data based on 1st acquisition data by running the 1st program 110a.

  More specifically, as shown in FIG. 5, the first processing unit 115 includes a first command creation unit 118, a first communication unit 119, and a first data creation unit 120.

  The first command creation unit 118 creates a first acquisition command by executing the first program 110a.

  The first acquisition command is a command that is transmitted to the first power conditioner 104 in order to acquire the first acquisition data. That is, the first command creation unit 118 collectively collects all types of power generation related information that can be acquired from the first power conditioner 104 among a plurality of types of power generation related information that are predetermined to be included in the power generation related data. A first acquisition command for acquiring from the first power conditioner 104 is created.

In the present embodiment, the first command creation unit 118 executes the first program 110a, thereby generating instantaneous generated power [W], instantaneous current [A], instantaneous voltage [V], and solar radiation [W / m ² ]. Then, a command that can acquire the temperature [° C.] in a batch is created as a first acquisition command.

  The first communication unit 119 transmits the first acquisition command created by the first command creation unit 118 to the first power conditioner 104. Then, the first communication unit 119 acquires the first acquisition data as a response to the transmission of the first acquisition command.

  The first data creation unit 120 extracts, from the first acquired data acquired by the first communication unit 119, each of a plurality of types of power generation related information determined in advance to be included in the power generation related data. Then, the first data creation unit 120 combines the extracted types of power generation related information. Accordingly, the first data creation unit 120 creates power generation related data.

Please refer to FIG. 3 again.
The second processing unit 116 creates power generation related data based on the plurality of second acquisition data by executing the second program 110b.

  More specifically, as illustrated in FIG. 6, the second processing unit 116 includes a second command creation unit 121, a second communication unit 122, and a second data creation unit 123.

  The second command creation unit 121 creates a second acquisition command by executing the second program 110b.

  The second acquisition command is a command that is transmitted to the second power conditioner 105 in order to acquire the second acquisition data. In other words, the second command creation unit 121 individually generates each type of power generation related information that can be acquired from the second power conditioner 105 among a plurality of types of power generation related information that are predetermined to be included in the power generation related data. A plurality of second acquisition commands to be acquired from the second power conditioner 105 are created.

  In the present embodiment, the second command creation unit 121 creates a plurality of second commands for acquiring each of instantaneous generated power [W], temperature [° C.], and wind power [m / s].

  The second communication unit 122 transmits a plurality of second acquisition commands created by the second command creation unit 121 to the second power conditioner 105. Then, the second communication unit 122 acquires a plurality of second acquisition data as a response to the transmission of each of the plurality of second acquisition commands.

  The second data creation unit 123 creates power generation related data based on the plurality of second acquisition data acquired by the second communication unit 122.

Please refer to FIG. 3 again.
The processing control unit 117 sequentially repeats the first processing unit 115 and the second processing unit 116 to execute the first program 110a and the second program 110b.

  The output unit 113 outputs the power generation related data created by the data creation unit 112 to the server device 107. In the present embodiment, when the power generation related data is generated by the data generation unit 112, the output unit 113 sequentially outputs the generated power generation related data to the server device 107.

  Here, the destination to which the output unit 113 outputs the power generation related data is not limited to the server device 107, and may be a predetermined device such as a terminal device, a printer, or a display device.

  When the output suppression unit 114 acquires the suppression command from the server device 107, the output suppression unit 114 transmits the suppression command to the power conditioner of the model corresponding to the suppression command. The suppression command is a command for suppressing the output power from the power conditioner. The suppression command is created by the server device 107 (to be described later) according to the model of the power conditioner connected to the remote monitoring device 106.

  In the present embodiment, when the output suppression unit 114 acquires the suppression command for the first power conditioner 104, the output suppression unit 114 transmits the suppression command to the first power conditioner 104. Further, when the output suppression unit 114 acquires the suppression command for the second power conditioner 105, the output suppression unit 114 transmits the suppression command to the second power conditioner 105.

Please refer to FIG. 1 again.
The server device 107 is a device for managing the remote monitoring system 100.

  Specifically, as shown in FIG. 7, the server device 107 includes a server program storage unit 124, a server management storage unit 125, a collection program transmission unit 126, a data aggregation unit 127, a suppression information acquisition unit 128, A suppression command storage unit 129, a suppression command creation unit 130, and a suppression command transmission unit 131 are provided.

  The server program storage unit 124 is a storage unit in which the collection program is stored in advance. The collection program stored in the server program storage unit 124 is created by the user. As shown in FIG. 7, the server program storage unit 124 according to the present embodiment stores a first program 110a, a second program 115, and a third program 124c.

  The third program 124c is a collection program applied to a third power conditioner (not shown). The third power conditioner is not connected to the remote monitoring device 106 according to the present embodiment.

  The server management storage unit 125 is a storage unit in which server management information 125a for managing the collection program stored in the server device 107 is stored.

  As shown in FIG. 8, the server management information 125a is information that associates model information with identification information.

  The model information included in the server management information 125a is information indicating the model of the inverter, similarly to the model information included in the management information 111a.

  The identification information included in the server management information 125a is information for identifying the collection program stored in the collection program storage unit 110. The identification information of the server management information 125a is information indicating an address where the collection program is stored in the server management storage unit 125, for example.

  As described above, the collection program applied to various power conditioners can be stored and managed in the server device 107 in advance. As a result, the server device 107 can efficiently manage a plurality of remote monitoring devices 106 to which various power conditioners are connected.

Refer to FIG. 7 again.
When the collection program transmission unit 126 receives a request from the remote monitoring device 106, the collection program transmission unit 126 refers to the server management information 125 a and the server program storage unit 124 and transmits a collection program corresponding to the request to the remote monitoring device 106.

  The data totaling unit 127 acquires the power generation related data of each of the first power conditioner 104 and the second power conditioner 105 connected to the remote monitoring device 106 from the remote monitoring device 106. The data totaling unit 127 accumulates the acquired power generation related data.

  When receiving a request from the terminal device 101b, the data totaling unit 127 totals the accumulated power generation related data by a predetermined method to create power generation status information. The data totaling unit 127 transmits the generated power generation status information to the terminal device 101b. Thereby, the power generation status information can be viewed on the screen of the terminal device 101b.

  The suppression information acquisition unit 128 acquires suppression information based on an input to an input unit (not shown). The suppression information is information indicating a schedule for suppressing the output of electric power from the power plant, and is typically input according to a request from a power company.

  The suppression command storage unit 129 is a storage unit in which suppression command information 129a is stored in advance. The suppression command information 129a is information indicating a rule for creating a suppression command for each power conditioner model.

  Based on the suppression information acquired by the suppression information acquisition unit 128 and the suppression command information 129a, the suppression command creation unit 130 includes the first power conditioner 104 and the second power conditioner 105 connected to the remote monitoring device 106. Create suppression commands for each.

  The suppression command transmission unit 131 transmits the suppression command created by the suppression command creation unit 130 to the remote monitoring device 106.

  Here, each of the remote monitoring device 106 and the server device 107 according to the present embodiment physically includes, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, It consists of a communication interface. The functions of the remote monitoring device 106 and the server device 107 are realized, for example, by executing a program incorporated in advance in the RAM as a work space.

  Further, the function of the server device 107 may be realized by sharing a plurality of computers that can communicate with each other via a network constructed by appropriately combining wireless and wired lines.

  So far, the configuration of the remote monitoring system 100 according to the embodiment of the present invention has been described. From here, the operation of the remote monitoring system 100 according to the present embodiment will be described.

(Program setting process)
As shown in FIG. 9, the program setting process is a process for setting the collection program of the power conditioner connected to the remote monitoring device 106 in the remote monitoring device 106. The program setting process is executed when the remote monitoring device 106 is operated for the first time, when the model of the power conditioner connected to the remote monitoring device 106 is changed, or the like.

  The model acquisition unit 108 acquires the model information “A-01” of the first power conditioner 104 from the terminal device 101a based on a user input or the like to the terminal device 101a (step S101).

  The model acquisition unit 108 requests the server device 107 for a collection program corresponding to the model information “A-01” acquired in step S101 (step S102).

  Although not shown, the collection program transmission unit 126 that has received the request refers to the server management information 125a and identifies the identification information “Q1” associated with the model information “A-01” included in the request. The collection program transmission unit 126 reads the collection program “first program 110 a” identified by the identified identification information “Q1” from the server program storage unit 124 and transmits it to the remote monitoring device 106.

  When the collection program acquisition unit 109 acquires the first program 110a transmitted from the server device 107 (step S103), the collection program acquisition unit 109 stores the acquired first program 110a in the collection program storage unit 110 (step S104). At this time, it is assumed that the first program 110 a is stored in a series of areas starting from the address “P1” of the collected program storage unit 110.

  The collection program acquisition unit 109 manages management information 111a that associates the model information “A-01” of the first power conditioner 104 with the identification information indicating the address “P1” where the first program 110a is stored. (Step S105).

  Thereby, the processing program setting process for setting the first program 110a in the remote monitoring device 106 is completed. As a result of this processing, the first program 110a, which is a collection program of the first power conditioner 104, is set in the remote monitoring device 106.

  Further, the second program 110b is set by executing the same program setting process for the second power conditioner 105 as well. As a result of this processing, the collected program storage unit 110 stores the first program 110a and the second program 110b, and the management storage unit 111 stores management information 111a shown in FIG.

(Remote monitoring process)
As shown in FIG. 10, each of the first power conditioner 104 and the second power conditioner 105 connected to the remote monitoring device 106 is used for the remote monitoring process, as shown in FIG. This is a process for outputting the power generation related data to the server device 107.

  The remote monitoring process is a process executed by the remote monitoring apparatus 106. For example, after the program setting process is performed, the remote monitoring process is started in response to a start instruction input by the user to the terminal device 101a. Thereafter, the remote monitoring processing is repeatedly executed by the remote monitoring device 106 until, for example, an end instruction input by the user to the terminal device 101a is received.

  The data creation unit 112 creates the power generation related data based on the first acquisition data and the power generation related data based on the second acquisition data by executing each of the first program 110a and the second program 110b ( Step S201).

  Specifically, the data creation process (step S201) includes a first process (step S301) and a second process (step S302), as shown in FIG.

  In step S301, the first processing unit 115 creates power generation related data based on the first acquired data by executing the first program 110a.

  A more detailed flow of the first process (step S301) is shown in FIG.

The first command creation unit 118 creates a first acquisition command by executing the first program 110a (step S401). As described above, the first acquisition command according to the present embodiment collectively includes instantaneous generated power [W], instantaneous current [A], instantaneous voltage [V], solar radiation [W / m ² ], and temperature [° C.]. This command can be acquired with.

  The first communication unit 119 transmits the first acquisition command created in step S401 to the first power conditioner 104 (step S402). Then, the first communication unit 119 acquires the first acquisition data as a response to the transmission of the first acquisition command in step S402 (step S403).

Since the first acquisition data according to the present embodiment is a response to the first acquisition command described above, as shown in FIG. 12, the instantaneous generated power [W], the instantaneous current [A], the instantaneous voltage [V], Including solar radiation [W / m ² ] and air temperature [° C.].

Refer to FIG. 11 again.
The first data creation unit 120 extracts each of a plurality of types of power generation related information predetermined to be included in the power generation related data from the first acquisition data acquired by the first communication unit 119 (step S404). .

In the present embodiment, the types of power generation related information predetermined to be included in the power generation related data are the instantaneous power generation [W], temperature [° C.], and solar radiation [W] as described above with reference to FIG. / M ² ] and wind power [m / s]. Therefore, as shown in FIG. 12, the first data creation unit 120 extracts the instantaneous generated power [W], the temperature [° C.], and the solar radiation [W / m ² ] from the first acquired data.

  Here, since the wind force [m / s] is not included in the first acquisition data, it is not extracted in step S404.

Refer to FIG. 11 again.
The first data creation unit 120 creates power generation related data by combining the extracted types of power generation related information (step S405).

  Specifically, as shown in FIG. 12, the first data creation unit 120 creates power generation related data by combining the extracted types of power generation related information so that they are arranged in a predetermined order.

  Here, since the wind power [m / s] cannot be acquired from the first power conditioner 104 as described above, in the power generation related data of the first power conditioner 104, dummy data is stored in the area where the wind power [m / s] is stored. Is stored. The dummy data indicates that the area cannot be acquired.

  Thereby, the first data creation unit 120 ends the first process (step S301) and returns to the remote monitoring process shown in FIG.

  In step S302, the second processing unit 116 generates power generation related data based on the plurality of second acquisition data by executing the second program 110b.

  A more detailed processing flow of the second processing (step S302) is shown in FIG.

  The second processing unit 116 repeats the processes of steps S502 to S504 three times (loop A; step S501).

  Here, the number of times the loop A is repeated is equal to the number of types of power generation related information determined in advance to be included in the power generation related data. For this reason, in the present embodiment, loop A is repeated three times.

  The second command creation unit 121 creates a second acquisition command by executing the second program 110b (step S502).

  As described above, the second acquisition command according to the present embodiment is a command for acquiring each of instantaneous generated power [W], temperature [° C.], and wind power [m / s]. In step S502 executed first, the second command creation unit 121 creates a second command for acquiring, for example, instantaneous generated power [W].

  The second communication unit 122 transmits the second acquisition command created in step S502 to the second power conditioner 105 (step S503). Then, the second communication unit 122 acquires the second acquisition data as a response to the transmission of the second acquisition command in step S503 (step S504).

  Since the second acquisition data acquired in the first loop A (step S501) is a response to the second command for acquiring the instantaneous generated power [W], as shown in FIG. Includes power [W].

  In the second loop A (step S501), the second command creation unit 121 creates, for example, a command for acquiring the temperature [° C.]. Then, steps S502 and S503 are executed again. Accordingly, as illustrated in FIG. 14, as a result of the execution of the second loop A (step S501), the second communication unit 122 acquires the second acquisition data including the temperature [° C.].

  In the third loop A (step S501), for example, the second command creation unit 121 creates a command for acquiring wind power [m / s]. Then, steps S502 and S503 are executed again. As a result, as shown in FIG. 14, as a result of the execution of the third loop A (step S501), the second communication unit 122 acquires second acquisition data including wind power [m / s]. Thereby, the loop A (step S501) ends.

  As shown in FIG. 14, the second data creation unit 123 creates power generation related data based on the second acquisition data acquired in step S504 (step S505).

  Specifically, as shown in FIG. 14, the second data creation unit 123 combines the power generation related information included in the second acquired data acquired in step S504 so that they are arranged in a predetermined order. Create electricity related data.

Here, since the solar radiation amount [W / m ² ] cannot be obtained from the second power conditioner 105, in the power generation related data of the second power conditioner 105, the solar radiation amount [W / m ² ] is dummy in the area where the solar radiation amount [W / m ² ] is stored. Data is stored.

  Thereby, the second data creation unit 123 ends the second process (step S302) and returns to the remote monitoring process shown in FIG.

  The output unit 113 outputs the power generation related data of the first power conditioner 104 and the second power conditioner 105 created in step S201 to the server device 107 (step S202), and ends the remote monitoring process. To do.

(Suppression command creation processing)
The suppression command creation process is a process for creating a suppression command based on a request from the electric power company as shown in FIG.

  The suppression command creation process is a process executed by the server device 107, and is appropriately executed based on, for example, information input by the user to the terminal device 101a in response to an output suppression request from an electric power company.

  The suppression information acquisition unit 128 acquires suppression information in accordance with a request from the electric power company (step S601). The suppression information indicates, for example, that output power in a specific time zone is suppressed to a certain value or less.

  The suppression command creation unit 130 creates a suppression command for each of the power conditioners connected to the remote monitoring device 106, based on the suppression information acquired in step S601 and the suppression command information 129a (step S602). ).

  For example, for each of the first power conditioner 104 and the second power conditioner 105, a command for suppressing the output in a specific time zone to a certain value or less is created according to the rule indicated by the suppression information suppression command information 129a. .

  The suppression command transmission unit 131 transmits the suppression command created in step S602 to the remote monitoring device 106 (step S603). Thereby, the suppression command creation process ends.

(Output suppression processing)
The output suppression process is a process for suppressing the output at the power plant as shown in FIG. The output suppression process is executed, for example, when the remote monitoring device 106 acquires a suppression command from the server device 107.

  The output suppression unit 114 acquires the suppression command transmitted by executing the above-described suppression command creation process from the server device 107 (step S701).

  The output suppression unit 114 repeatedly executes the process of step S703 for all power conditioners connected to the remote monitoring device 106 (loop B; step S702). In the present embodiment, the process of step S703 is executed for each of the first power conditioner 104 and the second power conditioner 105.

  The output suppression unit 114 instructs the power conditioner to suppress output by transmitting the suppression command acquired in step S701 to each of the power conditioners connected to the remote monitoring device 106 (step S703).

  For example, the output suppression unit 114 instructs the first power conditioner 104 to suppress output by transmitting a suppression command for the first power conditioner 104 to the first power conditioner 104. Thereby, the first power conditioner 104 receives and executes the suppression command, and as a result, the output power from the first power conditioner 104 is suppressed.

  Similarly, the output suppression unit 114 instructs the second power conditioner 105 to suppress output by transmitting a suppression command for the second power conditioner 105 to the second power conditioner 105. As a result, the second power conditioner 105 receives and executes the suppression command. As a result, the output power from the second power conditioner 105 is suppressed, and the output power of the power plant is suppressed.

  Thereby, the output suppression process ends.

  According to the present embodiment, by executing each of the first program 110a and the second program 110b, based on the acquired data acquired from each of the first power conditioner 104 and the second power conditioner 105. Common power generation related data is created.

  Thereby, even if the models of the first power conditioner 104 and the second power conditioner 105 are different, common power generation related data can be created and output. Therefore, it is possible to collectively monitor the power generators connected to a plurality of power conditioners of different models.

  According to the present embodiment, each of first processing unit 115 and second processing unit 116 sequentially repeats and executes first program 110a and second program 110b. Thereby, power generation related data can be output to the server device 107 in real time. Accordingly, it is possible to monitor in real time the power generation devices connected to a plurality of power conditioners of different models.

  According to the present embodiment, the first processing unit 115 includes a first command creation unit 118, a first communication unit 119, and a first data creation unit 120. Thereby, it can respond to the power conditioner for which the command which can acquire electric power generation related information collectively was prepared. Therefore, it is possible to collectively monitor the power generation devices connected to the power conditioner that employs a command that can collectively acquire power generation related information.

  According to the present embodiment, second processing unit 116 includes second command creation unit 121, second communication unit 122, and second data creation unit 123. Thereby, it can respond to the power conditioner for which the command which can acquire electric power generation related information separately was prepared. Therefore, it is possible to easily monitor the power generation devices connected to the power conditioner that employs a command that can individually acquire power generation related information.

  According to the present embodiment, when a suppression command that is a command for suppressing output power for each of the first power conditioner 104 and the second power conditioner 105 is acquired from the server device 107, the model corresponding to the suppression command is obtained. The suppression command is transmitted to the inverter. Thereby, the output power from different types of power conditioners can be suppressed by the remote monitoring device 106. Therefore, output power from a plurality of power conditioners of different models can be collectively managed by one remote monitoring device 106.

  According to the present embodiment, since the remote monitoring device 106 includes the management storage unit 111, the model acquisition unit 108, and the collection program acquisition unit 109, the collection program corresponding to the model of the inverter is automatically transmitted from the server device 107. Can be obtained. Accordingly, it is possible to easily monitor the power generation devices connected to a plurality of power conditioners of different models.

  In the embodiment, the example has been described in which power generation related information of a type that cannot be acquired depending on the model of the power conditioner is included in the power generation related data. However, the power generation related data may be determined in advance so as to include only power generation related information that can be acquired from a general power conditioner.

  In this case, the first command creating unit 118 executes the first program 110a to obtain all of a plurality of predetermined types of power generation related information from the first power conditioner in a lump. Create a get command.

  The second command creation unit 121 also executes a second program 110b to obtain a plurality of second acquisition commands for individually acquiring a plurality of predetermined types of power generation related information from the second power conditioner. Create

  This also has the same effect as the embodiment.

  Although the embodiments and modifications of the present invention have been described above, the present invention is not limited to these. For example, the present invention includes a form in which some or all of the embodiments and modifications described above are appropriately combined, and a form in which the form is appropriately changed.

DESCRIPTION OF SYMBOLS 100 Remote monitoring system 101a, 101b Terminal device 102 1st power generation apparatus 103 2nd power generation apparatus 104 1st power conditioner 105 2nd power conditioner 106 Remote monitoring apparatus 107 Server apparatus 108 Model acquisition part 109 Collection program acquisition part 110 Collection program Storage unit 111 Management storage unit 112 Data generation unit 113 Output unit 114 Output suppression unit 115 First processing unit 116 Second processing unit 117 Processing control unit 118 First command generation unit 119 First communication unit 120 First data generation unit 121 2 command creation unit 122 second communication unit 123 second data creation unit 124 server program storage unit 125 server management storage unit 126 collection program transmission unit 127 data aggregation unit 128 suppression information acquisition unit 129 suppression command storage unit 130 suppression command generation unit 13 1 Suppression command transmitter

Claims (8)

A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A second collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy. A collected program storage unit for storing the program;
A data creation unit that creates the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program When,
An output unit that sequentially outputs the power generation related data created by the data creation unit to a predetermined device;
The power generation related data includes a plurality of predetermined types of power generation related information in a predetermined order,
The remote monitoring device, wherein the first program and the second program are different programs. The data creation unit
A first processing unit that creates the power generation related data based on the first acquisition data by executing the first program;
A second processing unit that creates the power generation related data based on the plurality of second acquisition data by executing the second program;
A processing control unit that sequentially and repeatedly executes the first program and the second program in each of the first processing unit and the second processing unit;
The remote monitoring apparatus according to claim 1. The first processing unit includes:
By executing the first program, all the types of power generation related information that can be acquired from the first power conditioner 104 among the plurality of predetermined types of power generation related information are collectively displayed on the first power conditioner. A first command creation unit for creating a first acquisition command for obtaining from:
A first communication unit that transmits the first acquisition command to the first inverter and acquires the first acquisition data as a response to the transmission of the first acquisition command;
First generating the power generation related data by extracting each of the plurality of predetermined types of power generation related information from the first acquisition data and combining the extracted types of power generation related information. The remote monitoring device according to claim 2, further comprising a data creation unit. The second processing unit includes:
By executing the second program, out of the plurality of predetermined types of power generation related information, each type of power generation related information that can be acquired from the second power conditioner is individually received from the second power conditioner. A second command creation unit for creating a plurality of second acquisition commands for obtaining;
A second communication unit that transmits the plurality of second acquisition commands to the second inverter and acquires the plurality of second acquisition data as a response to transmitting each of the plurality of second acquisition commands; ,
The remote monitoring device according to claim 2, further comprising: a second data creation unit that creates the power generation related data based on the plurality of second acquisition data. A management storage unit storing management information for associating identification information for identifying the collection program stored in the collection program storage unit with model information indicating a model of the inverter;
A model acquisition unit that acquires model information indicating the model of the inverter;
When the model information is acquired by the model acquisition unit, it further comprises a collection program acquisition unit that acquires from the server device a collection program applied to a power conditioner of the model indicated by the model information. Item 5. The remote monitoring device according to any one of Items 1 to 4. For each of the first power conditioner and the second power conditioner, obtaining a suppression command that is a command for suppressing output power from each of the first power conditioner and the second power conditioner from the server device. The remote monitoring device according to any one of claims 1 to 5, further comprising an output suppression unit that transmits the suppression command to a power conditioner of a model corresponding to the suppression command. A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A second collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy. A remote monitoring method executed by a remote monitoring device including a collected program storage unit in which a program is stored,
Creating each of the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program;
Outputting the generated power generation related data sequentially to a predetermined device,
The power generation related data includes a plurality of predetermined types of power generation related information in a predetermined order,
The remote monitoring method, wherein the first program and the second program are different programs. On the computer,
A first program that is a collection program for creating power generation-related data based on first acquisition data acquired from a first power conditioner that converts electric power obtained by a first power generation device that uses natural energy; A collection program for creating the power generation related data based on a plurality of second acquisition data acquired from a second power conditioner that converts electric power obtained by a second power generation device that uses natural energy, A collection program storage unit for storing a second program different from the first program;
A data creation unit that creates the power generation related data based on the first acquired data and the power generation related data based on each of the second acquired data by executing each of the first program and the second program When,
For realizing an output unit that sequentially outputs the power generation related data created by the data creation unit to a predetermined device,
The power generation related data includes a plurality of predetermined types of power generation related information in a predetermined order.

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