KR102522367B1 - Method and System for Investment Valuation Forecasting of Solar Power Generation Apparatus - Google Patents

Abstract

The present invention relates to a method and system for forecasting the investment valuation of a solar power generation apparatus. The method includes the steps of: obtaining a reference set through simulation for each first solar panel; checking an actual parameter value for each second solar panel; checking an available generation amount for each first solar panel based on the remaining period for each first solar panel; checking actual power generation for each second solar panel; and checking an investment value for each second solar panel based on the available power generation and actual power generation. It can also be applied to other embodiments.

Description

Method and System for Investment Valuation Forecasting of Solar Power Generation Apparatus}

The present invention relates to a method and system for predicting the investment value of a solar power generation device.

The present invention is derived from research conducted as part of the Jiangsu Research and Development Special Zone Fostering Project Support Project of the Research and Development Special Zone Progress Foundation.

[Task management (professional) organization name] Research and development special zone progress foundation

[Research project name] Jiangsu R&D Special Zone Fostering Project in Naju, Jeollanam-do

[Research Project Title] Development of high-efficiency, high-output solar power solution with artificial intelligence

[Name of project performing organization] Jiguroo Co., Ltd.

[Research Period] 2022.06.13~2022.08.31

A photovoltaic power generation device refers to a power system that converts light energy into electrical energy using a plurality of solar panels. These solar power generation devices include a string inverter method, which converts DC power generated by each series string solar panel into AC power by connecting an inverter to each of a plurality of series string solar panels, and all solar panels in series and A central inverter method in which DC power generated by all solar panels is converted into AC power by connecting one inverter in parallel to the solar panels is widely used.

The solar power generation device monitors the photovoltaic power generation device in terms of voltage, current, efficiency, and the like, and determines whether to maintain, repair, or replace the panel constituting the photovoltaic power generation device according to the monitoring result. However, when determining whether or not to maintain, repair, or replace a photovoltaic power generation device, it is impossible to predict profitability due to this, resulting in disadvantageous problems in making an effective decision.

Embodiments of the present invention to solve these conventional problems are to provide a method and system for predicting the investment value of a photovoltaic device that can predict profitability when determining whether to maintain, repair, or replace a photovoltaic device.

A method for predicting the investment value of a photovoltaic device according to an embodiment of the present invention includes obtaining a reference set through simulation for each first solar panel, checking actual parameter values for each second solar panel, and 1 Checking the available power generation amount for each first solar panel based on the remaining period for each solar panel, checking the actual power generation amount for each second solar panel, and the third step based on the available power generation amount and the actual power generation amount 2 It is characterized by including the step of confirming the investment value of each solar panel.

In addition, the step of confirming the investment value for the second photovoltaic array includes the step of checking a difference value by comparing the available power generation amount and the actual power generation amount, and converting the difference value into a power generation cost. do.

The method may further include checking an investment cost related to repair or replacement of at least one second solar panel among the second solar panels.

In addition, the step of confirming the investment value of each second solar panel is characterized in that the step of confirming the investment value by comparing the power generation cost and the investment cost.

The method may further include checking an investment cost associated with repair or replacement of at least one second photovoltaic cell constituting the second photovoltaic panel.

The checking of available power generation may include checking the available power generation by applying the reference set, the remaining period for each first solar panel, and a weight corresponding to the remaining period.

In addition, the obtaining of the reference set may include performing a simulation for each of the first solar panels while changing a reference parameter value and deriving an I-V curve for each of the first solar panels based on the change in the reference parameter value. It is characterized by including steps.

The acquiring of the reference set may include identifying a maximum power point for each of the first solar panels based on the I-V curve for each of the first solar panels.

In addition, the system for predicting the investment value of a solar power generation device according to an embodiment of the present invention is based on the simulation device for obtaining a reference set through simulation for each first solar panel and the actual parameter value for each second solar panel. Determine the amount of power generation, determine the amount of available power generation for each of the first solar panels based on the remaining period for each of the first solar panels, and determine the investment value for each of the second solar panels using the actual amount of power generation and the amount of available power generation It is characterized in that it includes a control device for checking.

In addition, the control device is characterized in that the difference value confirmed by comparing the amount of power generation used and the amount of actual power generation is converted into a power generation cost.

In addition, the controller may check an investment cost associated with repair or replacement of at least one second solar panel among the second solar panels.

In addition, the control device is characterized in that the investment value is confirmed by comparing the power generation cost and the investment cost.

In addition, the controller may check an investment cost related to maintenance or replacement of at least one second solar cell constituting the second solar panel.

The controller may check the available power generation amount by applying the reference set, the remaining period for each first solar panel, and a weight corresponding to the remaining period.

The simulation device may perform simulation for each of the first solar panels while changing a reference parameter value, and derive an I-V curve for each of the first solar panels based on the change in the reference parameter value.

In addition, the simulation device may check a maximum power point for each first solar panel based on the I-V curve for each first solar panel.

As described above, the method and system for predicting the investment value of the photovoltaic device according to the present invention predicts the investment value of the photovoltaic device based on the predicted profitability when determining whether to maintain, repair, or replace the photovoltaic device. By doing so, there is an effect of operating the photovoltaic device more efficiently.

1 is a diagram showing a system for predicting the investment value of a photovoltaic device according to an embodiment of the present invention.
2 is a diagram showing a simulation device simulating a photovoltaic device according to an embodiment of the present invention.
3 is a diagram showing a control device for predicting the investment value of a photovoltaic device according to an embodiment of the present invention.
4 is a flowchart for a method of obtaining reference data according to an embodiment of the present invention.
5 is a flowchart illustrating a method for predicting the investment value of a photovoltaic device according to an embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. The detailed description set forth below in conjunction with the accompanying drawings is intended to describe exemplary embodiments of the present invention and is not intended to represent the only embodiments in which the present invention may be practiced. In order to clearly describe the present invention in the drawings, parts irrelevant to the description may be omitted, and the same reference numerals may be used for the same or similar components throughout the specification.

1 is a diagram showing a system for predicting the investment value of a photovoltaic device according to an embodiment of the present invention.

Referring to FIG. 1 , a system 100 according to the present invention may include a simulation device 200 and a control device 300 .

The simulation device 200 is a device for managing a simulation space, for example, a simulation lab in which a photovoltaic device is implemented with a plurality of first solar panels, and may be a device such as a computer. A more specific operation of the simulation device 200 will be described with reference to FIG. 2 below. 2 is a diagram showing a simulation device simulating a photovoltaic device according to an embodiment of the present invention.

Referring to FIG. 2, the simulation device 200 according to the present invention includes a first communication unit 210, a first input unit 220, a first display unit 230, a first memory 240 and a first control unit 250. can include

The first communication unit 210 communicates with the control device 300 . To this end, the first communication unit 210 performs wireless communication such as ^5th generation communication (5G), Long Term Evolution-Advanced (LTE-A), Long Term Evolution (LTE), and Wireless Fidelity (Wi-Fi). can

The first input unit 220 includes at least one input means for generating input data in response to a user input of the simulation device 200 . The first input unit 220 may include a keypad, a dome switch, a touch panel, a jog shuttle, a touch key, and a menu button.

The first display unit 230 displays display data related to the operation of the simulation device 200 . The first display unit 230 may include a Liquid Crystal Display (LCD), a Light Emitting Diode (LED) display, an Organic LED (OLED) display, and a Micro Electro Mechanical Systems (MEMS) display. ) displays and electronic paper displays. The first display unit 230 may be combined with the first input unit 220 and implemented as a touch screen.

The first memory 240 stores operating programs of the simulation device 200 . In particular, the first memory 240 may store a reference set for simulation results for each of a plurality of first solar panels. More specifically, the first memory 240 is derived from each of the plurality of first solar panels according to a reference parameter value for a reference parameter including illuminance, temperature, degree of shading (%), and the like, and a changed parameter value. A reference set including the I-V curve and the maximum power point for each of the first solar panels estimated from each I-V curve may be stored.

The first control unit 250 performs a simulation of a solar power generation device using a plurality of first solar panels. More specifically, the first control unit 250 changes reference parameter values including illuminance, temperature, and the degree (%) of shadowing in at least a part of the first solar panel that the cloud covers the first solar panel. simulation can be performed while

The first controller 250 derives the I-V curve for each of the plurality of first solar panels according to the changed reference parameter value. The first control unit 250 estimates the maximum power point for each first solar panel based on the plurality of derived I-V curves. In this case, the maximum power point may be the highest point in the derived I-V curve. The first controller 250 may store the reference set in the first memory 240 .

The control device 300 is a device for monitoring the second photovoltaic array installed in an actual site, and may be a device such as a computer or server. A more specific operation of the control device 300 will be described with reference to FIG. 3 below. 3 is a diagram showing a control device for predicting the investment value of a photovoltaic device according to an embodiment of the present invention. In addition, in the embodiment of the present invention, it is described as a device for monitoring the second photovoltaic array installed in a specific site, but this is for convenience of description and is not necessarily limited thereto. For example, the control device 300 may monitor a plurality of solar arrays installed in a plurality of locations.

Referring to FIG. 3 , the control device 300 according to the present invention includes a second communication unit 310, a sensor unit 320, a second input unit 330, a second display unit 340, a second memory 350 and A second controller 360 may be included.

The second communication unit 310 communicates with the simulation device 200 . To this end, the second communication unit 310 performs wireless communication such as ^5th generation communication (5G), Long Term Evolution-Advanced (LTE-A), Long Term Evolution (LTE), and Wireless Fidelity (Wi-Fi). can

The sensor unit 320 controls parameters such as illuminance applied to the second photovoltaic array, temperature, degree of shadow generation (%) in the plurality of second photovoltaic panels constituting the second photovoltaic array, wind speed, and wind direction. Sensing data may be transmitted to the second controller 360 by sensing the parameter value. In addition, the sensor unit 320 has been described as being included in the control device 300 as an example, but this is only for convenience of description and is not necessarily limited thereto, and the sensor unit 320 is separate from the control device 300. It may be implemented as a device of In addition, the sensor unit 320 may be installed in a plurality of second solar panels constituting the second solar array, and may be representatively installed only on any one of the second solar panels.

The second input unit 330 includes at least one input means for generating input data in response to a user input of the control device 300 . The second input unit 330 may include a keypad, a dome switch, a touch panel, a jog shuttle, a touch key, and a menu button.

The second display unit 340 displays display data related to the operation of the control device 300 . The second display unit 340 may include a Liquid Crystal Display (LCD), a Light Emitting Diode (LED) display, an Organic LED (OLED) display, and a Micro Electro Mechanical Systems (MEMS) display. ) displays and electronic paper displays. The second display unit 340 may be combined with the second input unit 330 and implemented as a touch screen.

The second memory 350 stores operating programs of the control device 300 . In particular, the second memory 350 may store a program capable of predicting the amount of available power generation of the plurality of second solar panels and a program capable of checking the actual amount of power generation of the plurality of second solar panels. In addition, the second memory 350 may store a program for checking the investment value of the plurality of second solar panels using the available generation amount and the actual generation amount.

The second controller 360 checks actual parameter values applied to the second solar array. In this case, the second photovoltaic array may mean a photovoltaic array installed in an actual site, and the second photovoltaic array may include a plurality of second photovoltaic panels, and the second photovoltaic panel may include a plurality of second photovoltaic panels. It may include a solar cell. The second controller 360 may receive sensing data from the sensor unit 320 to check actual parameter values applied to the plurality of second solar panels. The sensing data may mean illuminance, temperature, and degree (%) of shadowing on each of the second solar panels when clouds block the second solar array.

The second control unit 360 calls a reference set having a reference parameter value that is similar to or equal to or greater than a threshold value to the checked actual parameter value among the reference sets stored in the second memory 350 through communication with the simulation device 200. The second controller 360 checks the maximum power point included in the called reference set.

The second controller 360 may check the remaining period of each of the plurality of second solar panels. In this case, the remaining period may be confirmed based on the warranty period allocated to each of the second solar panels. The second controller 360 checks the weight to be applied to each of the second solar panels based on the checked remaining period. In general, since the performance of the second solar panel deteriorates over time after installation, the second controller 360 determines the amount of power generated over time from the second solar panel more accurately according to the remaining period. You can check the weight.

The second controller 360 checks the amount of available power generation for each second solar panel by applying a weight corresponding to the called reference set, the remaining period, and the remaining period. The second controller 360 may check the actual amount of power generation for each second solar panel for the plurality of second solar panels using the actual parameter value.

The second controller 360 may compare the confirmed amount of available power generation with the actual amount of power generation, calculate a difference between the amount of power generation, and convert the calculated amount of power generation into a power generation cost. The second controller 360 checks an investment cost for repair or replacement of at least one second solar panel or at least one second solar cell. In addition, the second controller 360 checks the panel or cell in which the error has occurred among at least one second solar panel or at least one second solar cell, and checks the investment cost for repair or replacement of the corresponding panel or cell. can

The second controller 360 may determine an investment value by comparing the power generation cost and the investment cost, and display the determined investment value on the second display unit 340 . At this time, the second controller 360 may determine that the investment value is lowered when the generation cost is greater than the investment cost, and determine that the investment value is high when the generation cost is greater than the investment cost, and determine this as a second display unit ( 340) can be displayed.

4 is a flowchart for a method of obtaining reference data according to an embodiment of the present invention.

Referring to FIG. 4 , in step 401, the first controller 250 performs a simulation for a plurality of first solar panels. More specifically, the first control unit 250 is a reference for parameters including illuminance, temperature, and degree (%) of shadowing in at least one first solar panel among a plurality of first solar panels. Simulation may be performed according to the changed reference parameter value while changing the parameter value. At this time, the plurality of first solar panels may be implemented in a space for simulation, for example, a simulation lab.

In step 403, the first controller 250 derives an I-V curve for each second solar panel according to the changed reference parameter value. In step 405, the first controller 250 checks the maximum power point for each first solar panel based on the derived I-V curve. In step 407, the first controller 250 checks the reference set and performs step 409. In step 409, the first control unit 250 stores the confirmed reference set in the first memory 240. In this case, the reference set may include a reference parameter value applied to each first solar panel, an I-V curve for each first solar panel according to the reference parameter value, and a maximum power point estimated by the I-V curve.

5 is a flowchart illustrating a method for predicting the investment value of a photovoltaic device according to an embodiment of the present invention.

Referring to FIG. 5 , in step 501, the second controller 360 checks actual parameter values applied to the second solar array. In this case, the second photovoltaic array may mean a photovoltaic array installed in an actual site, and the second photovoltaic array may include a plurality of second photovoltaic panels, and the second photovoltaic panel may include a plurality of second photovoltaic panels. It may include a solar cell. The second controller 360 may receive sensing data from the sensor unit 320 to check actual parameter values applied to the plurality of second solar panels. The sensing data may mean illuminance, temperature, and degree (%) of shadowing on each of the second solar panels when clouds block the second solar array.

In step 503, the second control unit 360 selects a reference set having reference parameter values that are similar to or equal to or greater than a threshold value to actual parameter values checked among the reference sets received through communication with the simulation device 200 and stored in the second memory 350. call

In step 505, the second controller 360 may check the remaining period of each of the plurality of second solar panels. In this case, the remaining period may be confirmed based on the warranty period allocated to each of the second solar panels.

In step 507, the second controller 360 checks the weight to be applied to each of the second solar panels based on the checked remaining period. In general, since the performance of the second solar panel deteriorates over time after installation, the second controller 360 determines the amount of power generated over time from the second solar panel more accurately according to the remaining period. You can check the weight.

In step 509, the second controller 360 may check the amount of available power generation for each second solar panel by applying a weight corresponding to the called reference set, the remaining period, and the remaining period. In step 511, the second control unit 360 may check the actual amount of power generation for each second solar panel for the plurality of second solar panels by using the actual parameter value.

In step 513, the second control unit 360 may check the investment value. More specifically, a difference between the confirmed amount of power generation and the actual amount of power generation may be compared to calculate a difference value of the amount of power generation, and the calculated amount of power generation may be converted into a power generation cost. The second controller 360 checks an investment cost for repair or replacement of at least one second solar panel or at least one second solar cell. In addition, the second controller 360 checks the panel or cell in which the error has occurred among at least one second solar panel or at least one second solar cell, and checks the investment cost for repair or replacement of the corresponding panel or cell. can

In step 515 , the second controller 360 compares the power generation cost and the investment cost to determine the investment value and displays the determined investment value on the second display unit 340 . At this time, the second controller 360 may determine that the investment value is lowered when the generation cost is greater than the investment cost, and determine that the investment value is high when the generation cost is greater than the investment cost, and determine this as a second display unit ( 340) can be displayed.

Embodiments of the present invention disclosed in the present specification and drawings are only presented as specific examples to easily explain the technical content of the present invention and help understanding of the present invention, and are not intended to limit the scope of the present invention. Therefore, the scope of the present invention should be construed as including all changes or modifications derived based on the technical idea of the present invention in addition to the embodiments disclosed herein.

Claims (16)

In the method of predicting the investment value using the investment value prediction system of the solar power generation device,
Acquiring, by a simulation device, a reference set through simulation for each first solar panel;
Checking, by a control device, actual parameter values for each second solar panel;
checking, by the control device, available power generation for each first solar panel by applying the reference set, the remaining period for each first solar panel, and a weight corresponding to the remaining period;
checking, by the control device, an actual amount of power generation for each of the second solar panels; and
checking, by the control device, an investment value for each second solar panel based on the available generation amount and the actual generation amount;
including,
The step of checking the available generation amount,
and confirming the available generation amount by applying a weight corresponding to the reference set, the remaining period for each first solar panel, and the remaining period. According to claim 1,
The step of confirming the investment value for the second solar array,
checking a difference value by comparing the available power generation amount with the actual power generation amount; and
converting the difference value into a power generation cost;
A method for predicting the investment value of a photovoltaic device comprising a. According to claim 2,
checking an investment cost related to repair or replacement of at least one second solar panel among the second solar panels;
A method for predicting the investment value of a photovoltaic device further comprising a. According to claim 3,
The step of checking the investment value for each second solar panel,
The method of predicting the investment value of a photovoltaic device, characterized in that the step of confirming the investment value by comparing the power generation cost and the investment cost. According to claim 3,
Checking an investment cost related to maintenance or replacement of at least one second solar cell constituting the second solar panel;
A method for predicting the investment value of a photovoltaic device further comprising a. delete According to claim 1,
Obtaining the reference set,
performing simulation for each of the first solar panels while changing a reference parameter value; and
deriving an IV curve for each first solar panel based on a change in the reference parameter value;
A method for predicting the investment value of a photovoltaic device comprising a. According to claim 7,
Obtaining the reference set,
Checking a maximum power point for each first solar panel based on the IV curve for each first solar panel;
A method for predicting the investment value of a photovoltaic device comprising a. A simulation device for obtaining a reference set through simulation for each first solar panel; and
Communication is performed with the simulation device, the actual power generation amount is checked based on the actual parameter value for each second solar panel, and the reference set, the remaining period for each first solar panel, and a weight corresponding to the remaining period are applied. a control device that checks available power generation for each of the first solar panels and checks an investment value for each of the second solar panels using the actual power generation and the available power generation;
including,
The control device,
The investment value prediction system of a solar power generation device, characterized in that for confirming the available power generation amount by applying the reference set, the remaining period for each first solar panel, and a weight corresponding to the remaining period. According to claim 9,
The control device,
Investment value prediction system of a solar power generation device, characterized in that for converting the difference value confirmed by comparing the available generation amount and the actual generation amount into generation cost. According to claim 10,
The control device,
An investment value prediction system for a solar power generation device, characterized in that for checking an investment cost related to repair or replacement of at least one second solar panel of the second solar panel. According to claim 11,
The control device,
An investment value prediction system for a solar power generation device, characterized in that for confirming the investment value by comparing the power generation cost and the investment cost. According to claim 11,
The control device,
An investment value prediction system for a solar power generation device, characterized in that for checking an investment cost related to repair or replacement of at least one second solar cell constituting the second solar panel. delete According to claim 9,
The simulation device,
Investment value of the solar power generation device characterized in that performing simulation for each of the first solar panels while changing the reference parameter value, and deriving the IV curve for each of the first solar panel based on the change in the reference parameter value prediction system. According to claim 15,
The simulation device,
The investment value prediction system of the solar power generation device, characterized in that for confirming the maximum power point for each of the first solar panels based on the IV curve for each of the first solar panels.

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