JP2020155145A - Evaluation support device, evaluation support system, program, and method - Google Patents

Abstract

To provide an evaluation support device capable of quantitatively evaluating a solar power plant.SOLUTION: An evaluation support device is the evaluation support device of a solar power plant, and stores equipment information and an actual amount of power generation regarding equipment of plural solar power plants, stores weather-related information regarding weather in a predetermined area, calculates an expected amount of power generation as an amount of power generation expected during a predetermined period of an object solar power plant on the basis of weather-related information of a predetermined area including a position of the solar power plant and equipment information of the solar power plant, and generates evaluation information on the basis of comparison between the expected amount of power generation and the actual amount of power generation in the object solar power plant.SELECTED DRAWING: Figure 1

Description

The present invention relates to an evaluation support device and the like, and particularly to an evaluation support system for a photovoltaic power plant.

Currently, many solar power plants are installed in the country. In addition to solar power generation for general housing, large-scale solar power plants with a large number of solar cell panels installed on a vast site have also been put into practical use in various places. For owners of photovoltaic power plants, it is desirable that the power generation device generate stable power over a long period of time. In such a situation, there is a request from the owners of the photovoltaic power plants and the like to evaluate their own photovoltaic power plants. For example, Patent Document 1 discloses a photovoltaic power generation system evaluation device that mainly evaluates the performance of a solar cell panel.

Japanese Unexamined Patent Publication No. 2018-019567

The amount of power generated by a photovoltaic power plant differs depending on the power plant, such as location conditions, natural conditions, and equipment conditions of power generation equipment. Conventionally, regarding such a photovoltaic power plant, there is no database that summarizes the power generation capacity and the power generation record of the photovoltaic power plant, and there is a problem that it is difficult to evaluate each photovoltaic power plant. For example, there is a problem that it is not possible to quantitatively compare or analyze the amount of past power generation actually generated for any solar power plant.

The present invention has been made to solve such a problem, and an object of the present invention is to provide an evaluation support device or the like capable of quantitatively evaluating a photovoltaic power plant.

In order to achieve the above object, the photovoltaic power plant evaluation support device as one aspect of the present invention stores facility information and actual power generation amount related to the facilities of a plurality of photovoltaic power plants, and relates to the weather in a predetermined area. Meteorological information is stored, and the expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant, is calculated by the weather-related information in the predetermined area including the location of the solar power plant and the solar power. It is characterized in that it is calculated based on the above equipment information of the power plant and evaluation information is generated based on the comparison between the calculated expected power generation amount and the actual power generation amount at the target solar power plant.

Further, preferably, in the present invention, the meteorological information includes the total amount of solar radiation per unit area in the predetermined area including the position of the target solar power plant, and the facility information includes the plurality of above. The DC rated output of the solar panel, the AC rated output of the power conditioner, the correction coefficient for the installation orientation and the installation tilt angle of the solar panel, and the DC rated output with respect to the AC rated output in each of the photovoltaic power plants. Includes a correction coefficient for the ratio of and a system output coefficient.

Further, preferably in the present invention, the meteorological information includes an output analysis value of a solar panel for a unit time per unit area in the predetermined area including the position of the target photovoltaic power plant, and the facility information is , The DC rated output of the solar panel, the AC rated output of the power conditioner, the correction coefficient for the installation orientation and the installation tilt angle of the solar panel, and the AC rated output in each of the above-mentioned plurality of photovoltaic power plants. Includes correction factors for the ratio of DC rated output.

Further, preferably in the present invention, the evaluation support device generates individual evaluation information indicating the ratio of the actual power generation amount to the expected power generation amount in the target solar power plant in chronological order as the evaluation information. ..

Further, preferably, in the present invention, the evaluation support device uses the ratio of the actual power generation amount to the expected power generation amount in the target solar power plant and the ratio in other solar power plants as the evaluation information. Generate relative evaluation information indicating the comparison of.

Further, preferably, in the present invention, the other photovoltaic power plant is a photovoltaic power plant in the predetermined area where the total amount of solar radiation in the predetermined area including the position of the target solar power plant is close.

Further, preferably, in the present invention, the relative evaluation information indicates the plurality of photovoltaic power plants in a ranking format.

Further, preferably, in the present invention, the equipment information includes the unit price of electricity sold, the asset information, and the operation start date in each of the plurality of photovoltaic power plants, and the evaluation support device is the target photovoltaic power generation. Based on the actual power generation amount, the power sale unit price, the asset information, and the operation start date at the plant, profitability assessment information indicating the profitability of the target photovoltaic power plant is generated as the evaluation information.

Further, in order to achieve the above object, the evaluation support system as one aspect of the present invention is an evaluation support system for a photovoltaic power plant including a server and a terminal connected to the server via a network and having a display. The server stores equipment information and actual power generation amount related to the facilities of a plurality of photovoltaic power plants, stores weather-related information related to the weather in a predetermined area, and is expected for a predetermined period of the target photovoltaic power plant. The expected amount of power generated, which is the amount of power generated, is calculated based on the weather-related information in the predetermined area including the location of the solar power plant and the equipment information of the solar power plant, and the photovoltaic power generation of the target The evaluation information is generated based on the comparison between the expected power generation amount calculated at the place and the actual power generation amount, and the terminal displays the evaluation information on the display.

Further, in order to achieve the above object, the photovoltaic power plant evaluation support method as one aspect of the present invention sets the expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant. The steps to be calculated based on the weather-related information of the predetermined area including the location of the photovoltaic power plant and the equipment information related to the facilities of the photovoltaic power plant, and the expected power generation amount calculated in the target photovoltaic power plant. It is characterized by having a step of generating evaluation information based on a comparison with the actual power generation amount of the photovoltaic power plant.

Further, in order to achieve the above object, the program as one aspect of the present invention is characterized in that a computer is made to execute each step of the method described above.

According to the present invention, a photovoltaic power plant can be evaluated quantitatively.

It is a hardware block diagram of the electronic device by one Embodiment of this invention. It is a functional block diagram of the electronic device by one Embodiment of this invention. This is an example showing a part of the solar radiation database. It is one of examples of the value of the correction coefficient C2'calculated at three different places. It is a figure which shows how the calculation result of FIG. 4 was plotted on the coordinate of DC / AC ratio, and the vertical axis is the correction coefficient C2, and the approximate curve was obtained. It is a figure which shows an example of the evaluation information display website which displays individual evaluation information. It is a figure which shows an example of the evaluation information display website which displays the relative evaluation information. It is a figure which shows an example of the evaluation information display website which displays the relative evaluation information. It is a figure which shows an example of the evaluation information display website which displays the relative evaluation information. It is a figure which shows an example of the evaluation information display website which displays profitability evaluation information. It is a flowchart which showed the information processing of the evaluation support system 1 by one Embodiment of this invention.

Hereinafter, the evaluation support system 1 according to the embodiment of the present invention will be described with reference to the drawings. In the present specification, for convenience of explanation, an unnecessarily detailed description may be omitted. For example, detailed explanations of already well-known matters and duplicate explanations about substantially the same configuration may be omitted.

In general, a photovoltaic power plant includes a solar cell, a storage battery, and a power conditioner to which the solar cell and the storage battery are connected. The solar cell includes a plurality of solar cell panels arranged in an array. A power conditioner converts a frequency or voltage into AC power so as to be compatible with a commercial power system in order to be connected to a commercial power system for use. For convenience of explanation, the evaluation support system 1 of the present embodiment targets such a general photovoltaic power plant installed in Japan. However, it is not limited to this.

FIG. 1 is an overall configuration diagram of an evaluation support system 1 for a photovoltaic power plant according to an embodiment of the present invention. As shown in FIG. 1, the evaluation support system 1 includes an evaluation support device 10, a weather-related information server 20, and a user terminal 30. The evaluation support device 10, the weather-related information server 20, and the user terminal 30 are connected to a network 2 such as the Internet and can communicate with each other. However, each may be connected individually as needed. In the present embodiment, the service provider or administrator of the evaluation support system 1 (hereinafter referred to as "administrator") uses the evaluation support device 10, and the end user who uses the service of the evaluation support system 1 is the user terminal 30. To use.

FIG. 2 is a block diagram showing a hardware configuration of the evaluation support device 10 according to the embodiment of the present invention. The evaluation support device 10 according to the present embodiment includes the same configuration as a general server, PC, or the like. The evaluation support device 10 includes a processor 11, an input device 12, an output device 13, a storage device 14, and a communication device 15. Each of these components is connected by a bus 16. It is assumed that an interface is interposed between the bus 16 and each component device as needed. The evaluation support device 10 may be composed of a plurality of computers (servers).

The processor 11 controls the operation of the entire evaluation support device 10. For example, the processor 11 is a CPU. The processor 11 executes various processes by reading and executing a program or data stored in the storage device 14. In one example, the processor 11 is composed of a plurality of processors. In another example, the processor 11 uses an electronic circuit such as an MPU. In the present embodiment, various functions of the evaluation support device 10 are realized by executing the program by the processor 11.

The input device 12 is a user interface that receives input from the user to the evaluation support device 10, and is, for example, a touch panel, a touch pad, a keyboard, or a mouse. The output device 13 outputs or displays the output information of the evaluation support device 10 to the user, and is, for example, a display that outputs an image. The output device 13 may also include a printer.

The storage device 14 includes a main storage device and an auxiliary storage device. The main storage device is a semiconductor memory such as RAM. The RAM is a volatile storage medium capable of reading and writing information at high speed, and is used as a storage area and a work area when the processor 11 processes information. The main storage device may include a ROM, which is a read-only non-volatile storage medium. In this case, the ROM stores programs such as firmware. The auxiliary storage device stores various programs and data used by the processor 11 when executing each program. The auxiliary storage device is, for example, a hard disk device, but may be any non-volatile storage or non-volatile memory as long as it can store information, and may be removable. The auxiliary storage device stores, for example, an operating system (OS), middleware, application programs, various data that can be referred to when these programs are executed, and the like.

The communication device 15 exchanges data with another computer such as a server via a network. For example, the communication device 15 performs wireless communication such as mobile communication or wireless LAN, and connects to the network 2. In one example, the evaluation support device 10 downloads the program from the server by the communication device 15 and stores it in the storage device 14. However, the communication device 15 may perform known wired communication.

The evaluation support device 10 generates evaluation information about the photovoltaic power plant. The evaluation information includes individual evaluation information of one photovoltaic power plant, relative evaluation information comparing one photovoltaic power plant with another photovoltaic power plant, and profitability assessment showing the profitability of one photovoltaic power plant. Contains information.

In the present embodiment, the evaluation support device 10 includes a database server function. The storage device 14 stores data (for example, a table) and a program for various databases, and the various databases are realized by executing the program. The evaluation support device 10 may be configured to include a database server as a separate device.

In the present embodiment, the evaluation support device 10 includes a web server function. The evaluation support device 10 performs processing such as generation and transmission of an evaluation information display website that displays evaluation information about the photovoltaic power plant in response to a request from the evaluation support device 10 or the user terminal 30. The evaluation support device 10 can also function as an application server, and can control the connection to the database. In this case, the storage device 14 can store data for providing a web page, for example, an HTML document, an image, a program for an application server function, and the like. The evaluation information display website is displayed on the display of the user terminal 30 and the output device 13 of the evaluation support device 10.

The weather-related information server 20 provides weather-related information in response to access from any terminal including the evaluation support device 10. The meteorological information server 20 accumulates meteorological information from the past to the present based on observation data by meteorological satellites such as meteorological satellite images. The weather-related information is data related to the weather for each predetermined area, and includes the total amount of solar radiation in a unit time per unit area. For example, meteorological information includes the monthly total solar radiation (kW / m ² ) per square meter for each 1 km square area. The evaluation support device 10 acquires the weather-related information in the predetermined area from the weather-related information server 20 and stores it in the storage device 14.

In one preferred example, the meteorological information server 20 has a total solar radiation amount (kW / m ² ) for each 1 km square area calculated using observation data of meteorological satellite images acquired from the meteorological satellite Himawari. Provides weather-related information, including. In one example, a corporation such as a solar radiation consortium has a weather-related information server 20, and the evaluation support device 10 acquires weather-related information from the weather-related information server 20.

The user terminal 30 is a computer provided with a display, and can be a personal computer, a tablet terminal, a smartphone, a mobile phone, or the like. A web browser is pre-installed on the user terminal 30. The end user can browse the web page using a web browser and send the data to the web server using the input form on the web page.

The evaluation support device 10 includes a power plant database (hereinafter referred to as “power plant DB”) that stores facility information and actual power generation amount related to the facilities of a plurality of photovoltaic power plants. The power plant DB stores each of the photovoltaic power plants in association with a unique equipment ID. Equipment information includes power plant name, owner, installation position, solar panel installation orientation and installation tilt angle, solar panel DC rated output, power conditioner AC rated output, correction coefficient, and system output coefficient. Each item is associated with the equipment ID.

The installation position is the position where the photovoltaic power plant is installed, and includes the address and latitude / longitude. The DC rated output of the solar panel is the DC rated output (KWp) of all module panels in the corresponding photovoltaic power plant, for example, the spectral distribution AM1.5 specified by JISC, the irradiance 1,000 W / m2, and the module temperature 25. It is the value of the rated capacity at ° C. The AC rated output of the power conditioner is the AC rated output (kW) of all the power conditioners in the corresponding photovoltaic power plant. The correction coefficient includes a correction coefficient C1 regarding the installation orientation and installation inclination angle of the solar panel, and a correction coefficient C2 regarding the ratio of the DC rated output to the AC rated output. The system output coefficient indicates the performance of a photovoltaic power generation system in consideration of the loss of a certain amount of power generation generated by an external factor, and is generally called PR (Performance Ratio).

The actual power generation amount is the amount of power sold for each predetermined period and is associated with the equipment ID. The actual amount of power generation is, for example, the amount of active power sold every month.

The evaluation support device 10 stores the input of the equipment information and the actual power generation amount from the user received from the input device 12 or the user terminal 30 in the power plant DB. When the evaluation support device 10 receives the input of the equipment information regarding the new power plant, the evaluation support device 10 generates a new equipment ID and associates it with the input item. For example, the end user can register his / her own photovoltaic power plant through the evaluation information display website using the user terminal 30, and can also provide the facility information and the actual power generation amount of the photovoltaic power plant. You can register. The registered data is associated with the equipment ID and stored in the power plant DB.

The power plant DB further stores the user ID and is associated with the equipment ID. The user ID is unique identification information for identifying the end user. For example, the evaluation information display website requires the user terminal to log in and access using the user ID when the end user accessing from the user terminal 30 browses the evaluation information. When the user terminal 30 logs in using one user ID, only the items associated with the equipment ID generated by the one user ID can be input and output, and the evaluation information associated with the equipment ID can be input and output. Can only be obtained. On the other hand, the end user cannot view the input / output of the item associated with the equipment ID generated by the other user ID and the evaluation information associated with the equipment ID via the user terminal 30. By configuring the evaluation support system 1 in this way, it is possible to prevent a third party from acquiring information about the photovoltaic power plant owned by the end user of the evaluation support system 1. It is preferable to configure the evaluation support system 1 so that the end user cannot input the correction coefficient and the system output coefficient of the equipment information via the user terminal 30.

In this embodiment, the system output coefficient uses the same value in all photovoltaic power plants. Therefore, the evaluation support device 10 can store the system output coefficient in another memory area in the storage device 14 without storing it in the power plant DB in association with the equipment ID.

The evaluation support device 10 calculates the expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant. When calculating the expected power generation amount in a predetermined period, the evaluation support device 10 acquires the total amount of solar radiation for a unit time per unit area in a predetermined area including the position of the target photovoltaic power plant and a storage device. It is stored in 14, and calculated based on the total amount of solar radiation and the equipment information associated with the equipment ID of the photovoltaic power plant stored in the power plant DB. The target photovoltaic power plant is one of a plurality of photovoltaic power plants stored in the power plant DB for convenience of explanation, and is the photovoltaic power plant for which the expected power generation amount and the like are calculated. It shall indicate the power plant or the photovoltaic power plant to be evaluated that generates the evaluation information. For example, when an end user accesses a website for displaying evaluation information using the user terminal 30, designates one photovoltaic power plant, and browses the evaluation information of the photovoltaic power plant, the photovoltaic power plant It will be the target solar power plant.

Evaluation support apparatus 10 uses the equation (1), calculates the monthly expected amount of power generation P _A (Kwh / month) during a predetermined period of solar power plant of interest.
_{P A = GHI × C1 × PV} × C2 × PR
(1)
Here, GHI is the monthly total solar radiation per 1 m ² (kWh / m ² months), PV is the DC rated output (kWp) of the solar panel, and C1 is the correction coefficient C1. , C2 is the correction coefficient C2, and PR is the system output coefficient PR.

When calculating a monthly expected amount of power generation P _A, evaluation support apparatus 10 acquires the GHI in a predetermined area including the location of the solar power plant of interest from the weather-related information server 20 in the storage device 14. Also when calculating the monthly expected amount of power generation P _A, evaluation support apparatus 10, stored in the power plant DB, PV associated with equipment ID of the solar power plant of interest, using the C1, C2, PR. As shown below, the correction coefficients C1 and C2 are calculated by the evaluation support device 10 based on the data stored in the power plant DB and stored in the power plant DB. However, if the same calculation method is used, the administrator or the like may input the correction coefficient via the input device 12 and store it in the power plant DB, or the correction coefficient calculated by another system may be stored. The evaluation support device 10 may acquire it and store it in the power plant DB.

The correction coefficient C1 is a correction coefficient for calculating the amount of solar radiation that actually contributed to power generation in the solar panel among the total amount of solar radiation in consideration of the installation direction and the installation inclination angle of the solar panel. The evaluation support device 10 acquires the installation orientation and installation inclination angle of the solar panel of the target photovoltaic power plant from the power plant DB, and corrects it using the solar radiation amount database (not shown) provided in the evaluation support system 1. Calculate the coefficient C1. For example, the solar radiation amount database stores the azimuth angle, inclination angle, and total monthly solar radiation amount of a plurality of points for each point, and also stores the latitude and longitude of each point.

Specifically, the evaluation support device 10 includes the total amount of solar radiation (horizontal plane) A in the calculation target month at the point closest to the position of the target solar power plant, and the target solar power plant. The solar radiation amount B corresponding to the installation orientation and the installation orientation angle of the solar panel is acquired from the solar radiation amount database. The evaluation support device 10 calculates the correction coefficient C1 from the ratio of the amount of solar radiation B to the amount of solar radiation A.

In one preferred example, a corporation such as NEDO has a solar radiation amount database, and the evaluation support device 10 acquires data of the solar radiation amount A and the solar radiation amount B from the solar radiation amount database. FIG. 3 is one of the examples showing a part of the solar radiation amount database, and shows the total monthly solar radiation amount by azimuth, inclination angle, and monthly in Abashiri. For example, when the target photovoltaic power plant is installed in Abashiri and the solar panel of the photovoltaic power plant has an azimuth angle of 0 degrees and an inclined surface of 30 degrees, the correction coefficient C1 of the photovoltaic power plant in June. Consider the case of calculating. In this case, the correction coefficient C1 is calculated by C1 = 5.02 / 5.23, and C1 = 0.960.

The correction coefficient C2 is the power lost due to the rated capacity of the power generated by the solar panel from the ratio of the DC rated output of the solar panel to the AC rated output of the power conditioner (hereinafter referred to as "DC / AC ratio"). It is a correction coefficient considering. In general, the amount of power generated by a solar panel depends on the amount of solar radiation, so there are many times when the output is equal to or less than the DC rated output of the solar panel. Therefore, in a photovoltaic power plant, a power conditioner having an AC rated output smaller than the DC rated output of the solar panel is often installed. On the other hand, in such a case, the amount of power generated by the solar panel may exceed the AC rated output of the power conditioner, and the amount of power generated may be a loss. The correction coefficient C2 is a correction coefficient that takes this loss into consideration.

In the present embodiment, the evaluation support device 10 calculates in advance the ratio of the amount of power generated by the solar panel to be output from the power conditioner without loss by using a simulation. Simulations are performed at different locations in Japan with different DC / AC ratios. The calculated ratio is a value corresponding to the correction coefficient C2 (correction coefficient C2'). The evaluation support device 10 plots the calculated correction coefficient C2'for each of various DC / AC ratios on the coordinates where one axis is the DC / AC ratio and the other axis is the correction coefficient C2, and approximates the plot. Calculate the curve. The evaluation support device 10 calculates the DC / AC value from the AC rated output of the power conditioner of the target photovoltaic power plant and the DC rated output of the solar panel acquired from the power plant DB, and the DC / AC value. The correction coefficient C2 is calculated from the value of the approximate curve at the time of.

FIG. 4 is an example of the value of the correction coefficient C2'calculated in advance using simulation at various DC / AC ratios in three different places where photovoltaic power plants are installed, Tomakomai, Nagoya, and Shimonoseki. It is one of. In FIG. 4, it can be confirmed that the correction coefficient C2'when the DC / AC ratio is 100%, 120%, 140%, 160%, 180%, 200%, 250%, and 300% is calculated. ..

FIG. 5 is a diagram showing a state in which the calculation result of FIG. 4 is plotted on the coordinates of the DC / AC ratio on the horizontal axis and the correction coefficient C2 on the vertical axis to obtain an approximate curve. The approximate curve is preferably a curve of a quintic function as shown in FIG. 5, but it may be another nth-order function or another function may be used.

The system output coefficient PR is the ratio of the actual power generation amount to the power generation amount when operating in an ideal state. As described above, in the present embodiment, the same value is used for the system output coefficient in all the photovoltaic power plants. In one example, the value of the system output factor is 0.8.

Evaluation support apparatus 10 stores the calculated monthly expected amount of power generated by the solar power plant of interest P _A a (Kwh / month) power plants DB. In one example, the evaluation support device 10 stores the monthly expected power generation amount for the past one year from the present in each of the photovoltaic power plants stored in the power plant DB in the power plant DB in association with the equipment ID. .. In one example, the evaluation support device 10 determines the expected power generation amount for a period that can be calculated using the equipment information and the weather-related information stored in the power plant DB at each of the photovoltaic power plants stored in the power plant DB. It is stored in association with the equipment ID.

The evaluation support device 10 generates evaluation information based on a comparison between the calculated expected power generation amount and the actual power generation amount at the target photovoltaic power plant. The evaluation support device 10 generates an evaluation information display website that displays the generated evaluation information, and provides the website to the user terminal 30 that has received access.

In one example, the user transmits a request such as an HTTP request including the specified URL by operating a web browser on the user terminal 30, for example, by inputting the URL of the evaluation information display website. When the evaluation support device 10 receives the request transmitted from the user terminal 30, the evaluation support device 10 reads the corresponding web page from the storage device 14 in response to the request, and makes a response such as an HTTP response including the read web page. Is transmitted to the user terminal 30 of the transmission source of. When the user terminal 30 receives the web page, the user terminal 30 displays the evaluation information display website screen on the display by the web browser. For example, every time a necessary image data or the like is found in the received HTML document, the user terminal 30 requests the image data or the like from the evaluation support device 10, and the evaluation support device 10 responds to the request. The corresponding image data or the like can be transmitted to the user terminal 30 that is the source of the request.

In one example, the evaluation support device 10 uses the data stored in the power plant DB to chronologically generate a performance value represented by the ratio of the actual power generation amount to the expected power generation amount at the target photovoltaic power plant. Generate the individual evaluation information shown. For example, in this case, the evaluation information display website displays the expected power generation amount, the actual power generation amount, and the performance value in the target solar power plant designated by the user in chronological order according to the operation from the user terminal 30. The individual evaluation information shown in is displayed.

FIG. 6 is a diagram showing an example of an evaluation information display website that displays individual evaluation information. In this case, the evaluation information display website displays the expected monthly power generation amount, the actual power generation amount, and the performance value at the target photovoltaic power plant for one year. The evaluation information display website can also display only the performance value. The evaluation information display website can also be displayed by changing the display start time, time interval, or time range according to the operation from the user terminal 30. The evaluation information display website can also display other indicators based on the expected power generation amount and the actual power generation amount, such as the December moving average of the expected power generation amount.

In one example, the evaluation support device 10 uses the data stored in the power plant DB to determine the ratio of the actual power generation amount to the expected power generation amount at the target photovoltaic power plant and the ratio at another photovoltaic power plant. Generate relative evaluation information indicating comparison with. In this case, the other photovoltaic power plants can be all the photovoltaic power plants other than the target photovoltaic power plant among the plurality of photovoltaic power plants stored in the power plant DB, or the target. It is also possible to use only the photovoltaic power plants located within the area of the total solar radiation within a predetermined range from the total solar radiation of the photovoltaic power plants. For example, in this case, the evaluation information display website has the performance value of the target photovoltaic power plant for the period specified by the user and the performance value of another photovoltaic power plant according to the operation from the user terminal 30. Display relative evaluation information showing the comparison of. The performance value to be compared can be a value for a specific month or an average value for a specific period.

FIG. 7 is a diagram showing an example of an evaluation information display website that displays relative evaluation information. In this case, the evaluation information display website displays relative evaluation information indicating a plurality of photovoltaic power plants stored in the power plant DB in a ranking format arranged according to the magnitude of the performance value. For example, in this case, the evaluation information display website displays the number of power plants per range of default performance values for other photovoltaic power plants, and the target solar among multiple photovoltaic power plants. Clarify the position of the photovoltaic power plant. In this way, by configuring the evaluation information display website to display relative evaluation information so that a specific photovoltaic power plant cannot be identified, the sun registered in the power plant DB by the end user of the evaluation support system 1 It is possible to prevent information about the photovoltaic power plant from being acquired by a third party. In other embodiments as well, when the evaluation information display website displays relative evaluation information, it is preferable to display other photovoltaic power plants as described above.

Further, for example, the evaluation information display website has the actual power generation amount per 1 kWp at the target solar power plant designated by the user and the actual power generation amount per 1 kWp of other solar power plants according to the operation from the user terminal 30. Displays relative evaluation information that shows a comparison with the actual power generation amount of. The actual power generation amount to be compared can be the value of a specific month or the average value of a specific period.

FIG. 8 is a diagram showing an example of an evaluation information display website that displays relative evaluation information. In this case, the evaluation information display website displays relative evaluation information in a ranking format in which a plurality of photovoltaic power plants stored in the power plant DB are arranged according to the magnitude of the actual power generation amount per 1 kWp.

FIG. 9 is a diagram showing an example of an evaluation information display website that displays relative evaluation information. In this case, the evaluation information display website displays the relative evaluation information showing the above-mentioned performance value or the actual power generation amount per 1 kWp on the map. The relative evaluation information indicates the above-mentioned performance value or the actual power generation amount per 1 kWp for each district on the map corresponding to the location of the photovoltaic power plant. The division of the district can be arbitrarily determined by the manager, etc., but it is preferable that the division is large enough that individual solar power plants are not specified. The performance value or the magnitude of the actual power generation amount per 1 kWp can be displayed on the map by changing the color, shape, etc. according to the range of the magnitude.

In one example, the equipment information stored in the power plant DB further includes the power sale unit price (FIT unit price), the asset information, and the operation start date, and each item is associated with the equipment ID. Asset information includes information such as fixed assets and operation and maintenance costs. In this case, the evaluation support device 10 uses the data stored in the power plant DB, and the target solar power generation is based on the actual power generation amount, the unit price of power sold, the asset information, and the operation start date at the target solar power plant. Generate profitability assessment information to show profitability in a photovoltaic power plant. For example, when the evaluation support device 10 calculates the profit of selling electricity in a predetermined period, it calculates the amount of selling electricity using the actual amount of power generation and the unit price of selling electricity, calculates the depreciation cost from the asset information and the operation start date, and sells it. The profit on sale of electricity is calculated by subtracting the depreciation cost and operation maintenance cost from the amount of electricity. For example, the profitability assessment information includes the amount of electricity sold, the operation and maintenance cost, the depreciation cost, and the profit of selling electricity.

FIG. 10 is a diagram showing an example of an evaluation information display website that displays profitability evaluation information. In this case, the evaluation information display website responds to the operation from the user terminal 30, and the power sales amount (actual), operation maintenance cost, and depreciation cost at the target solar power plant for the period specified by the user. , Display profitability evaluation information showing the profit of selling electricity and the amount of selling electricity (forecast) in chronological order.

Next, the information processing of the evaluation support system 1 according to the embodiment of the present invention will be described with reference to the flowchart shown in FIG. The information processing shown in FIG. 11 is realized by causing the evaluation support device 10 to execute the program. In this information processing, the power plant DB stores the facility information and the actual power generation amount of a plurality of photovoltaic power plants that can be evaluated, and the evaluation support device 10 is a predetermined value including the respective positions of the photovoltaic power plants. It is assumed that the weather-related information of the area is stored.

When generating individual evaluation information in the target solar power plant for a predetermined period specified by the user, the evaluation support device 10 calculates the expected power generation amount in the target solar power plant in the predetermined period in step 101. Next, in step 102, the evaluation support device 10 generates individual evaluation information of the target photovoltaic power plant.

When generating relative evaluation information in a target solar power plant for a predetermined period specified by a user, in step 101, the evaluation support device 10 calculates the expected power generation amount of each of the plurality of solar power plants in the predetermined period. .. Next, in step 102, the evaluation support device 10 generates relative evaluation information of the target photovoltaic power plant.

Next, the action and effect of the evaluation support system 1 (evaluation support device 10) according to the embodiment of the present invention will be described. In the present embodiment, the evaluation support device 10 receives input of equipment information of a plurality of photovoltaic power plants and the actual power generation amount of each month, and stores the received data in the storage device 14. The evaluation support device 10 acquires the weather-related information for each month in a predetermined area including the positions of the plurality of photovoltaic power plants from the weather-related information server 20, and stores it in the storage device 14. The evaluation support device 10 calculates the expected power generation amount of each of the plurality of photovoltaic power plants in each month by using the equipment information and the weather-related information stored in the storage device 14, and corresponds to the calculated expected power generation amount. Evaluation information is generated based on comparison with the actual monthly power generation. The user terminal 30 acquires the evaluation information generated by the evaluation support device 10 and displays it on the display.

Conventionally, as the expected power generation amount in a predetermined period of the target solar power plant, the planned power generation amount calculated based on the solar radiation amount of the observatory of the Japan Meteorological Agency closest to the solar power plant is used. In the present embodiment, the expected power generation amount calculated by the evaluation support device 10 is different from the conventional planned power generation amount, and data such as the total amount of solar radiation for each predetermined area acquired from the weather-related information server 20 is used. Calculated based on the weather-related information included. Therefore, the expected power generation amount can be calculated by using the amount of solar radiation that more reflects the actual amount of solar radiation at the position of the target photovoltaic power plant, rather than the calculation of the planned power generation amount. It is possible to calculate the amount of power generation accurately.

Further, in the present embodiment, the evaluation support device 10 generates individual evaluation information of the target photovoltaic power plant. For example, the evaluation information display website generated by the evaluation support device 10 shows the December moving average value of the performance value together with the performance value, the expected power generation amount, and the actual power generation amount of each month according to the operation from the user terminal 30. The individual evaluation information can be displayed on the display or the like of the user terminal 30. With such a configuration, in the present embodiment, it is possible to perform a relative analysis of the amount of past power generation actually generated, and to catch signs of performance deterioration of the target photovoltaic power plant. Is possible.

Further, in the present embodiment, the evaluation support device 10 generates relative evaluation information of the target photovoltaic power plant. For example, the evaluation information display website generated by the evaluation support device 10 has performance values in the target photovoltaic power plant for a period specified by the user and other photovoltaic power plants in response to an operation from the user terminal 30. Relative evaluation information indicating the comparison with the performance value of can be displayed on the display or the like of the user terminal 30. The relative evaluation information may indicate a plurality of photovoltaic power plants in a ranking format, or may indicate a performance value or a magnitude of actual power generation on a map. With such a configuration, in the present embodiment, it is possible to more easily compare with other photovoltaic power plants. In this case, the other photovoltaic power plant may be only a photovoltaic power plant located within the area of the total solar radiation amount within a predetermined range from the total solar radiation amount of the target solar power plant. With such a configuration, it is possible to make a comparison with other photovoltaic power plants whose conditions are similar to those of the target photovoltaic power plant.

Further, in the present embodiment, the evaluation support device 10 generates profitability evaluation information of the target photovoltaic power plant. For example, the evaluation information display website generated by the evaluation support device 10 can be used for the amount of electricity sold (actual result) and operation maintenance at the target solar power plant for the period specified by the user in response to the operation from the user terminal 30. Profitability assessment information showing the cost, depreciation cost, power sale profit, and power sale amount (forecast) in chronological order can be displayed on the display of the user terminal 30 or the like. With such a configuration, in the present embodiment, it is possible to more easily create a report for investors of a photovoltaic power plant. Further, by generating profitability evaluation information in a plurality of photovoltaic power plants, it is possible to grasp the tendency of more profitable photovoltaic power plants.

In this way, by using the evaluation information presented to the user by the evaluation support system 1, it is expected that the interest and interest in the photovoltaic power plant will be increased, leading to the maintenance and improvement of the power generation capacity of the existing photovoltaic power plant. Will be done.

Unless otherwise specified, the above-mentioned action and effect are the same in other embodiments and examples.

In another embodiment of the present invention, a program that realizes the functions of the embodiment of the present invention described above and the information processing shown in the flowchart, or a computer-readable storage medium that stores the program can also be used. Further, in another embodiment, it is also possible to use a method for realizing the functions of the embodiment of the present invention described above and the information processing shown in the flowchart. In another embodiment, the server may be a server capable of supplying the computer with a program that realizes the functions of the embodiment of the present invention described above and the information processing shown in the flowchart. Further, in another embodiment, it can be a virtual machine that realizes the functions of the embodiment of the present invention described above and the information processing shown in the flowchart.

A modified example of the embodiment of the present invention will be described below. The modifications described below can be applied to any embodiment of the present invention in appropriate combinations as long as there is no contradiction.

In one variant, the weather-related information is the output analysis of the solar panel for a unit time per unit area, in addition to or instead of the total solar radiation, for each predetermined area. including. For example, the weather-related information server 20 provides weather-related information including an output analysis value (kW) per square meter for each area of 1 km square. The evaluation support device 10 acquires the output analysis value of the unit time per unit area in the predetermined area including the position of the target photovoltaic power plant and the predetermined period and stores it in the storage device 14, and the output analysis value and the power generation The expected power generation amount in a predetermined period is calculated based on the equipment information associated with the equipment ID of the photovoltaic power plant stored in the place DB.

In this case, the evaluation support device 10 uses the formula (2) instead of the formula (1) to calculate the monthly expected power generation amount P _B (Kwh / month) in the predetermined period of the target photovoltaic power plant.
P _B = PVA x C3 x PV x C2
(2)
Here, PVA is the monthly PV output analysis value per 1m _² (kWh / m ² · month), C3 is a correction coefficient C3, PV and C2 are to those used in equation (1) It is the same. Since PVA is a PV output analysis value, it includes the system output coefficient PR in the equation (1). When calculating a monthly expected power generation amount P _B, evaluation support apparatus 10 acquires the PVA in a predetermined area including the location of the solar power plant of interest from the weather-related information server 20 in the storage device 14.

The correction coefficient C3 is a correction coefficient for calculating the actual output amount of the solar panel among the PV output analysis values in consideration of the installation direction and the installation inclination angle of the solar panel. In the case of the correction coefficient C1, the total amount of solar radiation is a value based on the horizontal plane and 0 degrees southward, whereas in the case of the correction coefficient C3, the PV output analysis value is a value based on the horizontal plane and 10 degrees southward. Therefore, the correction coefficient C3 is different from C1. For example, when the target photovoltaic power plant is installed in Amirun and the solar panel of the photovoltaic power plant has an azimuth of 0 degrees and an inclined surface of 30 degrees, FIG. 3 is used to refer to 6 of the photovoltaic power plant. Consider the case of calculating the correction coefficient C3 in the month. In this case, the correction coefficient C3 is calculated by C1 = 5.02 / 5.25, and C1 = 0.956. In this way, the monthly expected power generation amount can be obtained.

In one modification, the power plant DB is composed of a plurality of database systems. In this case, each item stored in the power plant DB may be stored in a different database system. As described above, the database included in the evaluation support device 10 is an example, and the evaluation support device 10 does not have to include the database as long as it has equivalent functions.

In one modification, the evaluation support device 10 stores the weather-related information acquired from the weather-related information server 20 in the power plant DB in association with the equipment ID. The power plant DB can store weather-related information as a part of facility information.

In one variant, the weather-related information, actual power generation, expected power generation, and solar radiation database are not limited to monthly, but can be daily, weekly, quarterly, and so on. For example, the weather-related information can be a daily total solar radiation amount, a weekly total solar radiation amount, or a quarterly total solar radiation amount instead of the monthly total solar radiation amount. For example, the solar radiation database can store total solar radiation by day, week, or quarter.

In one modification, the evaluation support device 10 obtains the approximate curve obtained when calculating the correction coefficient C2 for each region, and uses the approximate curve of the region to which the target photovoltaic power plant belongs to obtain the correction coefficient C2. calculate.

In one modification, the evaluation information display website is an individual evaluation that further shows the conventional planned power generation amount at the target solar power plant designated by the user in chronological order according to the operation from the user terminal 30. Display information.

In one modification, the evaluation support device 10 displays the evaluation information to the user terminal 30 that has received access, instead of or in addition to generating the evaluation information display website that displays the generated evaluation information. Send data.

In one variant, the weather-related information server 20 stores future weather-related information. In this case, the evaluation support device 10 determines the amount of power generation expected in the future predetermined period of the target photovoltaic power plant, the weather-related information of the predetermined area including the position of the photovoltaic power plant, and the photovoltaic power plant. It can be calculated based on the equipment information.

Each of the examples described above is an example for explaining the present invention, and the present invention is not limited to these examples. The present invention can be carried out in various forms as long as it does not deviate from the gist thereof.

1 Network 10 Evaluation support device 11 Processor 12 Input device 13 Output device 14 Storage device 15 Communication device 16 Bus 20 Meteorological information server 30 User terminal

Claims (11)

It is an evaluation support device for solar power plants.
Memorize facility information and actual power generation amount related to the facilities of multiple photovoltaic power plants
Memorize weather-related information about the weather in a given area,
The expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant, is applied to the weather-related information in the predetermined area including the position of the solar power plant and the equipment information of the solar power plant. Calculated based on
Evaluation information is generated based on the comparison between the expected power generation amount calculated at the target solar power plant and the actual power generation amount.
Evaluation support device. The meteorological information includes the total amount of solar radiation per unit area in the predetermined area including the location of the target photovoltaic power plant.
The equipment information includes the DC rated output of the solar panel, the AC rated output of the power conditioner, the correction coefficient for the installation orientation and the installation inclination angle of the solar panel, and the AC in each of the plurality of photovoltaic power plants. The evaluation support device according to claim 1, further comprising a correction coefficient relating to the ratio of the DC rated output to the rated output and a system output coefficient. The meteorological information includes an output analysis value of a solar panel for a unit time per unit area in the predetermined area including the position of the target photovoltaic power plant.
The equipment information includes the DC rated output of the solar panel, the AC rated output of the power conditioner, the correction coefficient for the installation orientation and the installation inclination angle of the solar panel, and the AC in each of the plurality of solar power plants. The evaluation support device according to claim 1, further comprising a correction coefficient relating to the ratio of the DC rated output to the rated output. Any of claims 1 to 3, wherein the evaluation support device generates, as the evaluation information, individual evaluation information indicating the ratio of the actual power generation amount to the expected power generation amount in the target solar power plant in chronological order. The evaluation support device according to item 1. As the evaluation information, the evaluation support device provides relative evaluation information indicating a comparison between the ratio of the actual power generation amount to the expected power generation amount at the target solar power plant and the ratio at another solar power plant. The evaluation support device according to any one of claims 1 to 4, which is generated. The evaluation support according to claim 5, wherein the other photovoltaic power plant is a photovoltaic power plant in the predetermined area where the total amount of solar radiation in the predetermined area including the position of the target solar power plant is close. apparatus. The evaluation support device according to claim 5 or 6, wherein the relative evaluation information indicates the plurality of photovoltaic power plants in a ranking format. The facility information includes a unit price of electricity sold, asset information, and an operation start date at each of the plurality of photovoltaic power plants.
The evaluation support device is
Profitability indicating the profitability of the target photovoltaic power plant as the evaluation information based on the actual power generation amount at the target photovoltaic power plant, the power selling unit price, the asset information, and the operation start date. The evaluation support device according to any one of claims 1 to 7, which generates evaluation information. An evaluation support system for a server and a photovoltaic power plant having a terminal connected to the server via a network and having a display.
The server
Memorize facility information and actual power generation amount related to the facilities of multiple photovoltaic power plants
Memorize weather-related information about the weather in a given area,
The expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant, is applied to the weather-related information in the predetermined area including the position of the solar power plant and the equipment information of the solar power plant. Calculated based on
Evaluation information is generated based on the comparison between the expected power generation amount calculated at the target solar power plant and the actual power generation amount.
The terminal displays the evaluation information on the display.
Evaluation support system. It is an evaluation support method for solar power plants.
The expected power generation amount, which is the expected power generation amount in a predetermined period of the target solar power plant, is based on the weather-related information of the predetermined area including the location of the solar power plant and the equipment information related to the equipment of the solar power plant. And the steps to calculate
A step of generating evaluation information based on a comparison between the expected power generation amount calculated at the target solar power plant and the actual power generation amount of the solar power plant, and
Evaluation support method with. A program that causes a computer to perform each step of the method according to claim 10.