KR101847346B1 - Simulation System for Solar Power Generation Systems - Google Patents

Abstract

The present invention relates to a simulation system of a solar power generation facility. More specifically, the present invention relates to a simulation system of a solar power generation facility which can provide an analysis simulation for economic feasibility due to installation of a solar power generation facility by using the power generation amount according to conditions that a solar power generation facility is installed such as a latitude, a longitude, an installation area, etc. of a location where the power generation facility is installed, the installation costs to install the power generation facility, and the investment costs of an interest rate or the like.

Description

[0001] The present invention relates to a simulation system for a solar power generation facility,

The present invention relates to a simulation system for a photovoltaic power generation facility, and more particularly, to a simulation system for a photovoltaic power generation facility, and more particularly, to a simulation system for a photovoltaic power generation facility, The present invention relates to a simulation system for a photovoltaic power generation facility capable of providing analysis simulation of investment efficiency in the installation of a photovoltaic power generation facility by providing information on investment cost such as interest rate,

Solar power refers to the conversion of solar energy into electrical energy. Generally, there are two methods.

The first is a method in which solar cells are used to convert sunlight into electricity,

The second is the conversion of solar heat into electricity, a device that utilizes the Seebeck effect, or a method of collecting heat on a large scale to produce hot steam and turning the turbine to produce electricity.

The electric generation method which is mainly used is a solar power generation method which is a method of converting electricity into electricity using sunlight in the first method and a method of using solar cells.

Since the installation of such a photovoltaic power generation facility requires considerable cost, it is necessary to check the amount of photovoltaic power generation at the installation location where the generator is installed before installation.

The related document is 'Patent Document 1'.

Patent Document 1 is directed to an apparatus for accurately simulating solar power generation at an installation position by using a scan image scanned around a mounting position where a condenser is installed.

The 'patent document 1' can scan a position where a condenser plate is to be installed by using a video apparatus and test a power generation amount of a substantial surrounding environmental element to check a relatively accurate power generation amount. However, Therefore, it is difficult to acquire information on various locations, and it is difficult to provide practical profit information according to the installation of the photovoltaic device to the user who wants to install the solar cell device because it can not provide a profit relation according to the cost for installing the solar cell equipment. .

In addition, since the surrounding elements are fixed elements, it is difficult to predict the optimal installation method because it is impossible to estimate and calculate the possibility of fluctuation of the power generation amount when the change is made. Thus, it is possible to provide the installation method according to the change of the surrounding environment There is a problem that is difficult to present various methods.

As a method for measuring solar power generation, statistics such as the weather at the installation site and the amount of sunshine are used.

However, in the method using statistics, it is only possible to simulate the power generation amount at the level of simply comparing the total power generation amount and the power consumption amount by using the daylight time statistics in the area including the installation location, It is difficult to predict the generation amount depending on the specific environment of the installation location (for example, topographical land, etc.).

In addition, there is no means for predicting the generation amount and profit of the photovoltaic power generation facility in the installation of the photovoltaic power generation facility.

Korean Registered Patent No. 10-1210250 (2012.04.04)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems,

The object of the present invention is to provide a simulation system of a photovoltaic power generation facility capable of predicting the generation amount by simulating the generation amount due to the surrounding environment, installation structure, weather, and the like when the photovoltaic power generation facility is installed.

Also, it is an object of the present invention to provide a simulation system of a photovoltaic power generation facility capable of predicting the yield and break-even point of the photovoltaic power generation facility in comparison with the investment cost and the power generation amount.

According to the present invention, there is provided a simulation system for a photovoltaic power generation facility,

A location input unit (100) configured to input location information of a solar power plant installation location;

An area input unit 200 configured to input a photovoltaic power generation facility installation area;

A photovoltaic module number input unit 300 configured to input the photovoltaic module installation number of the installation area inputted to the area input unit 200;

An investment input unit 400 configured to input an investment cost of installing a photovoltaic power generation facility;

A sunrise time information acquisition and analysis unit 500 configured to acquire sunrise time information according to the positional information input to the position input unit 100 using an information communication network;

Using the daylight time information acquired by the daylight time information acquisition and analysis unit 500, the installation area input to the area input unit 200, and the installation number of the photovoltaic module input to the photovoltaic module number input unit 300 A power generation amount prediction calculation unit 600 configured to calculate a solar power generation amount;

And a profit calculation predicting unit 700 configured to calculate a yield rate and a break-even point using the solar power generation amount calculated by the power generation amount prediction calculation unit 600 and the investment cost applied to the investment cost input unit 400, .

In the simulation system of the solar power generation facility according to the present invention,

When the solar power generation facility is installed, the power generation amount can be predicted by simulating the generation amount due to the surrounding environment, the installation structure, and the weather.

In addition, it provides the effect of forecasting the yield and break-even point in comparison with the investment cost and power generation amount of the photovoltaic power generation facilities.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall configuration diagram of a simulation system of a photovoltaic power generation facility according to an embodiment of the present invention; FIG.
2 is a detailed block diagram of a position input unit according to an embodiment of the present invention.
3 is a detailed configuration diagram of a solar module number input unit according to an embodiment of the present invention.
4 is a detailed configuration diagram of an investment cost input unit according to an embodiment of the present invention.
5 is a detailed configuration diagram of a daylight time information acquisition and analysis unit according to an embodiment of the present invention.
6 is a detailed configuration diagram of a power generation amount prediction calculation unit according to an embodiment of the present invention.
7 is a detailed configuration diagram of a profit calculation predicting unit according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be described by way of example only and with reference to the accompanying drawings, in which: FIG. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. .

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by terms. Terms are used only for the purpose of distinguishing one component from another.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present invention, the term "comprises" or "having ", etc. is intended to specify that there is a feature, number, step, operation, element, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall configuration diagram of a simulation system of a photovoltaic power generation facility according to an embodiment of the present invention; FIG.

2 is a detailed block diagram of a position input unit according to an embodiment of the present invention.

3 is a detailed configuration diagram of a solar module number input unit according to an embodiment of the present invention.

4 is a detailed configuration diagram of an investment cost input unit according to an embodiment of the present invention.

5 is a detailed configuration diagram of a daylight time information acquisition and analysis unit according to an embodiment of the present invention.

6 is a detailed configuration diagram of a power generation amount prediction calculation unit according to an embodiment of the present invention.

7 is a detailed configuration diagram of a profit calculation predicting unit according to an embodiment of the present invention.

1 to 7, a simulation system of a photovoltaic power generation facility according to the present invention, as shown in FIGS. 1 to 7,

A location input unit 100 configured to input location information of a solar power plant installation location,

An area input unit 200 configured to input a PV installation area,

A solar module number input unit 300 configured to input the solar module installation number of the installation area input to the area input unit 200,

An investment input unit 400 configured to input an investment cost of installing a photovoltaic power generation facility;

A sunrise time information acquisition and analysis unit 500 configured to acquire sunrise time information according to the position information input to the position input unit 100 using an information communication network,

Using the daylight time information acquired by the daylight time information acquisition and analysis unit 500, the installation area input to the area input unit 200, and the installation number of the photovoltaic module input to the photovoltaic module number input unit 300 A power generation amount prediction calculation unit 600 configured to calculate a solar power generation amount,

And a profit calculation predicting unit 700 configured to calculate a yield rate and a break-even point using the solar power generation amount calculated by the power generation amount prediction calculation unit 600 and the investment cost applied to the investment cost input unit 400, .

The location input unit 100 is configured to input location information of a location where the solar power generation facility is to be installed

The location input unit 100 is configured to include detailed location input means 310 configured to input latitude and longitude to install the solar power generation facility.

Accordingly, it is possible to set an accurate position with respect to the position in which the solar power generation facility is installed.

The position input unit 100 is configured to include azimuth setting means 120 configured to input azimuth with respect to the position where the solar power generation facility is installed and to set the azimuth angle of the solar power generation facility.

This is a means for setting the azimuth angle of the solar power generation facility depending on the orientation in order to test the efficiency of the solar power generation according to the direction of the sun. The power generation efficiency of the solar power generation facility, It is possible to provide a method of installing the solar module in the highest direction.

At this time, when installing the photovoltaic power generation facilities, it is impossible to install new installations when KEPCO line capacity of KEPCO is exceeded at the installation location. Even if the KEPCO line capacity remains, Is impossible.

On the other hand, according to the present invention, in order to determine whether a new installation can be performed by checking at least one of a KEPCO line capacity of a nearby KEPCO and a capacity of a substation bank in accordance with the location information input from the location input unit 100,

(KEPCO) using the information communication network. By using the location information input to the location input unit 100, the KEPCO line capacity and the substation bank capacity corresponding to the location for installing the solar power generation facility And a new installation determination unit 800 configured to determine whether a new installation of the photovoltaic power generation facility can be installed by acquiring any one or more of the installation conditions.

The area input unit 200 is configured to input the installation area provided with the solar power generation facility.

The area input unit 200 is configured to input an installation area for installing the solar power generation facility, and is configured to set an area based on a location (latitude, longitude) set by the location input unit 100. [

The solar module number input unit 300 is configured to input the installation number of the solar modules with respect to the installation area input to the area input unit 200. [

The solar module number input unit 300 is configured to include a separation distance setting unit 310 configured to set a distance between the solar modules when the solar module is installed.

The spacing distance setting means 310 is a means for setting the left and right and front-back distances between the solar modules, and is a configuration for testing the power generation efficiency according to the installed distance of the solar modules.

The solar module number input unit 300 includes an angle setting unit 320 configured to set an angle formed between the solar module and the ground.

When the solar module is installed, the angle setting unit 320 sets the angle of the solar module to the angle of the solar module with respect to the angle of the solar module, It is an additional means for testing the installation state of the solar module which shows the best power generation efficiency by additionally setting an angle between the solar module and the ground.

The simulation system of the photovoltaic power generation facility according to the present invention is a system for testing the power generation efficiency of the photovoltaic module by shadows generated from the environmental elements at the location where the photovoltaic power generation facility is installed,

And an environment setting unit 900 configured to set the environmental factors surrounding the area where the solar power generation facility is installed.

The configuration of the surrounding environment setting unit 900 for setting the surrounding environment factors may be such that the shade is generated in a solar module such as a tree, a streetlight, a building, a telephone pole, etc., This means setting the element.

This is because, as described above, in order to test the power generation efficiency of the photovoltaic power generation facility, it is configured to arbitrarily set the surrounding environment. It tests the fluctuation of the power generation efficiency of the photovoltaic power generation facility according to the environmental factors, (Solar module) according to the environmental factors or environmental factors.

In the simulation system of the photovoltaic power generation facility of the present invention,

An inverter setting unit 1000 configured to set the number of inverters, the maximum power point of the inverter,

And a battery storage capacity setting unit 1100 configured to set a battery capacity configured to store generated power converted by the inverter.

Inverter is a device that transforms the generated power stored in the form of direct current in the photovoltaic panel of the inverter into AC that can be used in real life by converting the generated power into AC. It can limit the amount of generated power stored when storing the generated power in the battery, The power generation efficiency can be controlled by varying the number of power sources according to the number and capacity of power sources.

The present invention includes the above-described configuration for testing accurate power generation efficiency.

That is, even if the generated power is large, if the conditions such as the capacity of the battery, the number of batteries, the number of inverters for controlling the battery, The invention includes the above-described configuration to provide a simulation for presenting a correct power generation efficiency to a user and a profit relationship with respect to power generation efficiency.

The investment cost input unit 400 is configured to input the investment cost for installing the solar power generation facility.

The investment cost input unit 400 includes a total investment cost input means 410 configured to input a total investment cost,

An external borrowing rate input means 420 configured to input a ratio of the external borrowing amount to the total investment cost input to the total investment amount input means 410,

And interest rate input means 430 configured to input the interest rate of the external borrowed amount.

The total investment cost of the total investment amount input means 410 may include at least one of land, photovoltaic installation cost, and solar installation cost.

The investment cost input unit 400 calculates the total cost (land, equipment purchase, installation, and the like) for installing the photovoltaic power generation facility by the above-described configuration and the ratio of the total cost to the external borrowing amount, Condition, and so on to check the accurate investment cost.

The sunrise time information acquisition and analysis unit 500 is configured to acquire sunrise time information according to the position information input to the position input unit 100 using the information communication network.

The daylight time information acquisition and analysis unit 500 accesses the new and renewable energy data center (KIER) or the weather station (www.kma.go.kr) using the information communication network to acquire yearly, monthly, weekly, and seasonal daylight time information .

The daylight time information acquisition and analysis unit 500 is characterized in that it includes a period setting unit 510 configured to set a period and acquire daylight time information for a set period when acquiring daylight time information .

The amount of sunshine refers to the time and amount of sunlight shining on the ground without being affected by clouds, fog, air pollution, etc. In order to simulate solar power generation efficiency, (Statistics) on the average solar power generation efficiency.

Therefore, the present invention is configured to acquire the daylight time information by accessing the weather station or the renewable energy data center in order to accurately test the power generation efficiency in the daylight time information acquisition and analysis unit 500.

The daylight time information acquisition and analysis unit 500 accesses the new and renewable energy data center (KIER) or the weather station (www.kma.go.kr) to acquire daylight time information as described above, And is capable of acquiring daylight time information using public data.

The power generation amount prediction calculation unit 600 calculates the power generation amount based on the sunrise time information acquired by the sunrise time information acquisition and analysis unit 500, the installation area input to the area input unit 200, The solar power generation amount is calculated using the number of installed solar modules.

The power generation amount prediction calculation unit 600 tests the solar power generation amount using the sunlight time information, the installation area, and the number of installed solar modules, without considering other environmental factors, In order to prevent being done,

A set azimuth test means 610 configured to simulate the movement path of the sun using the azimuth set by the azimuth setting means 120 of the position input unit 100 to calculate the solar power generation amount,

The front and rear distances between the photovoltaic modules set by the spacing distance setting means 310 of the photovoltaic module number input unit 300 and the distance between the left and right front and back distances between the photovoltaic modules set by the angle setting means 320 of the photovoltaic module number input unit 300, A first shadow test means 620 configured to calculate a solar power generation amount by determining a light-scattering factor problem factor of a solar module by shadows that may be generated according to an angle formed by an angle formed by the light and the ground,

A secondary shadow test means configured to calculate a solar power generation amount by determining a light collecting rate problem factor of a solar module based on shadows that may be generated by an environmental factor of the installation area set by the environment setting unit 900 630),

A limit capacity generation amount calculating unit configured to calculate a substantial solar power generation amount by calculating a limit value of the solar power generation amount with respect to the maximum power point of the inverter set in the inverter setting unit 1000 and the battery capacity set in the battery storage capacity setting unit 1100, And test means (640).

Accordingly, the power generation amount prediction calculation unit 600 can calculate the power generation amount according to factors related to the efficiency of the photovoltaic power generation efficiency using at least one element, and can provide various accurate information to the user .

The limited capacity generation amount test means 640 is configured to test by dividing it into daily, weekly, monthly, and yearly,

으로 계산하고,Daily power generation,

Lt; / RTI >

으로 계산하고,For weekly power generation,

Lt; / RTI >

으로 계산하며,Monthly power generation,

Lt; / RTI >

로 계산하는 것을 특징으로 한다.Annual power generation,

.

The installed capacity refers to a set battery capacity. The daily power generation time (daylight saving amount h) means a time value representing the daylight saving time in terms of time. The monthly power generation amount 30 is calculated by setting the monthly average date to 30 days.

The profit calculation predicting unit 700 is configured to calculate the profit rate and the break-even point using the solar power generation amount calculated by the power generation amount prediction calculation unit 600 and the investment cost applied to the investment cost input unit 400.

The profit calculation predicting unit 700 is a means for providing a profit and a break-even point by installing a photovoltaic power generation facility to a user. In order to provide the user with approximate information about a profit, a break-even point,

An SMP unit price information acquisition and storing unit 710 configured to access the KEPCO homepage using an information communication network and to acquire SMP unit price information of KEPEC and to store the SEM unit price information on a monthly average and an annual average basis,

A REC unit price information acquisition and storage unit 720 configured to access the power exchange website (rec.kpx.info) by using an information communication network, to acquire REC unit price information of the power exchange, ,

The SMP-related revenue is calculated by dividing the SMP-related revenue by month and year by using the monthly average and annual average information of the SMP unit price information stored in the SMP unit price information acquisition and storing unit 710 and the solar power generation amount calculated by the power generation amount prediction calculation unit 600 SMP profit calculation means 730,

The monthly average and annual average information of the REC unit price information stored in the REC unit price information acquisition and storage unit 720 and the solar power generation amount calculated by the power generation amount prediction calculation unit 600, A REC revenue calculation means 740,

The monthly and annual SMP-related revenues calculated by the SMP revenue calculation means 730 and the monthly and annual REC-related revenues calculated by the REC revenue calculation means 740 are used to calculate the monthly and annual total revenues The total revenue calculation means 750,

The ratio of the external investment amount input to the external investment amount input means 420 to the total investment cost input to the total investment amount input means 410 of the investment amount input unit 400, And a breakeven point prediction calculation means 760 configured to calculate a breakeven point using the monthly and annual total returns calculated by the total profit calculation means 750 Or more.

Accordingly, the present invention can provide various and precise power generation by using elements that can change the generation rate such as the surrounding environment, the installation structure, the amount of sunshine, etc. at a position where a user intends to install a solar power generation facility However,

Provide users with information on accurate profit and breakeven point by using direct price factors such as SMP and REC related to profit, and provide users with a means to judge the return on investment cost in direct investment It will be possible to do.

In the simulation system of the photovoltaic power generation facility according to the present invention,

When installed in a position for installing a solar power generation facility, the power generation amount can be predicted by simulating the generation amount due to the surrounding environment, installation structure, weather, and the like.

Also, it is possible to simulate the profit rate and the break-even point in comparison with the investment cost and the power generation amount, such as the installation cost of the photovoltaic power generation facility, and to predict it.

100: position input unit 500:
200: area input unit 600: power generation amount prediction calculation unit
300: number of photovoltaic modules input unit 700:
400: investment cost input unit

Claims (9)

In a simulation system of a solar power plant,
A location input unit (100) configured to input location information of a solar power plant installation location;
An area input unit 200 configured to input a photovoltaic power generation facility installation area;
A photovoltaic module number input unit 300 configured to input the photovoltaic module installation number of the installation area inputted to the area input unit 200;
A sunrise time information acquisition and analysis unit 500 configured to acquire sunrise time information according to the positional information input to the position input unit 100 using an information communication network;
Using the daylight time information acquired by the daylight time information acquisition and analysis unit 500, the installation area input to the area input unit 200, and the installation number of the photovoltaic module input to the photovoltaic module number input unit 300 A power generation amount prediction calculation unit 600 configured to calculate a solar power generation amount;
An environment setting unit 900 configured to set an environmental factor surrounding the area where the photovoltaic power generation equipment is installed;
An inverter setting unit 1000 configured to set the number of inverters and the maximum power point of the inverter; And
And a battery storage capacity setting unit (1100) configured to set a battery capacity configured to store the generated power converted from the inverter,
In order to prevent a single result from being presented based on the daylight time information, the installation area, and the number of installed solar modules,
A set azimuth test means 610 configured to simulate the movement path of the sun using the azimuth set by the position input unit 100 to calculate the solar power generation amount,
A front-to-back distance between the photovoltaic modules set in the photovoltaic module number input unit 300 and an angle formed between the photovoltaic module set by the angle setting unit 320 of the photovoltaic module number input unit 300 and the ground A primary shadow test means 620 configured to calculate a solar power generation amount by determining a light collecting factor problem factor of a solar module by shadows that can be generated,
A secondary shadow test means configured to calculate a solar power generation amount by determining a light collecting rate problem factor of a solar module based on shadows that may be generated by an environmental factor of the installation area set by the environment setting unit 900 630),
A limit capacity generation amount test unit configured to calculate a solar power generation amount by calculating a limit value of the solar power generation amount with respect to the maximum power point of the inverter set in the inverter setting unit 1000 and the battery capacity set in the battery storage capacity setting unit 1100 And means (640) for providing a plurality of calculation results to provide improved accuracy results.
delete The method according to claim 1,
The simulation system of the solar power plant,
And an investment cost input unit (400) configured to input an investment cost of installing a photovoltaic power generation facility.
delete delete delete delete The method of claim 3,
The simulation system of the solar power plant,
And a profit calculation predicting unit 700 configured to calculate a yield rate and a break-even point using the solar power generation amount calculated by the power generation amount prediction calculation unit 600 and the investment cost input to the investment cost input unit 400 Simulation system of photovoltaic power plant.
The method according to claim 1,
The simulation system of the solar power plant,
It is configured to access Korea Electric Power Corporation (kepco) using information communication network,
By using the location information input to the location input unit 100, it is possible to acquire at least one of the KEPCO line capacity and the substation bank capacity corresponding to the location where the solar power generation facility is installed, And a new installation presence / absence determination unit (800) configured to determine whether the new installation exists.

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