KR101965191B1 - System for automatic placement simulation of solar panels using geographic information - Google Patents

Abstract

Disclosed is a system for automatic placement simulation of solar panels using geographic information. The system for automatic placement simulation of solar panels using geographic information comprises: a database server for storing geographic information including a ground area of a facility corresponding to an address or a land area of a specific area; and an information processing server for receiving geographic information on an inputted address from the database server when information on the address is inputted, calculating an installable area for the inputted address on the basis of the received geographic information, and generating simulation information on an installation view of a solar power generation facility for the address for which the installable area is calculated. Therefore, a user performs simulation according to a type of equipment of a solar module desired to be installed, an arrangement direction and inclination of solar panels, and the like before installation, thereby previously checking the number of installable solar panels, a maximum installation capacity at the time of maximum installation, and the like, and easily finding out an optimal installation method of a solar power generation facility in a desired region to install the same. In addition, it is possible to accurately calculate a necessary area required to install one solar panel according to the size, inclination, arrangement direction and the like of the solar panel, and to perform simulation to satisfy a desired installation capacity by using a calculated result and an installation area for a specific address, thereby easily finding out an optimal result.

Description

[0001] The present invention relates to a system for automatic placement of a solar panel using geographic information,

The present invention relates to a solar panel automatic layout simulation system, and more particularly, to a solar panel automatic layout simulation system for simulating the installation landscape in which a solar panel is arranged using geographic information in advance.

Photovoltaic power generation is preferred because it has the least space limitation if the sun is shining, and it can be manufactured in a variety of ways from the small size facility to the large size facility.

In order to install and operate such a solar power generation facility, a considerable amount of cost is required, the productivity of the power generated due to the arrangement direction and the inclination of the installed solar panel can be variably changed, Existing technologies are at a level where the photovoltaic power generation facility is installed, and there are limitations.

Therefore, it is necessary to confirm in advance the number of the actual installable solar panels and the maximum installation capacity at the time of installation in accordance with the equipment type of the solar module desired to be installed by the user, the arrangement direction of the solar panel, It is necessary to find a way to easily find the optimal solar power generation facility installation plan for the area to be installed.

Korean Registered Patent No. 10-1893340 (Name of invention: Site Feasibility Analysis System for Photovoltaic Power Generation Facilities) Korean Patent Laid-Open No. 10-2018-0094362 (title of the invention: support structure of roof non-perforated solar panel)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a solar cell module, a solar cell module, a solar cell module, , The number of actual installable solar panels, the maximum installed capacity at maximum installation, etc., and simulate the solar panel automatic layout that can easily find the optimal solar power installation installation plan for the area to install System.

It is another object of the present invention to provide a solar panel capable of calculating a distance from a specific point of a specific solar panel to a specific point of another solar panel among solar panels constituting an array of solar power generation facilities, The required area for installing one solar panel is accurately calculated according to the inclination, the arrangement direction, etc., and the simulation is performed so as to satisfy the desired installation capacity using the calculated result and the installable area for the specific address, The present invention provides a solar panel automatic layout simulation system that can easily find the result of a solar panel.

According to an embodiment of the present invention, there is provided a system for automatically arranging a solar panel using geographical information, the system comprising: a database server for storing geographical information including a site area of a facility corresponding to a street address or a land area of a specific area; ; And receiving the geographical information of the addressee inputted from the database server, calculating an installable area for the addressee based on the received geographical information, And an information processing server for generating simulation information of a photovoltaic installation-installed landscape with respect to the calculated address.

When the information about the photovoltaic module constituting the photovoltaic panel to be installed is input after the geographical information of the input address is received, The size information corresponding to the information on the photovoltaic module is selected and based on the information on the average inclination included in the selected size information and the geographical information on the street address, The number of solar panels that can be installed in the installable area can be calculated based on the calculated distance.

When the vertical length of the solar module is longer than the vertical length of the solar module, the number of solar modules for forming one solar panel is N The distance between the lowest end of the specific solar panel and the lowest end of the other solar panel spaced apart from the lower end of the specific solar panel in the vertical direction is D1 ) Is calculated as D1 = L * N * 2.16857, and when the horizontal and vertical lengths of the photovoltaic module are longer than the vertical length, the vertical length of the photovoltaic module is L, The number of solar modules is N, the inclination of the solar panel is set to 30 degrees, and if the average inclination of the address is 5 degrees or more, Gyeokdoen a distance (D2) to the bottom of the other solar panel can be so calculated to be, D2 = L * N * 1.72674.

When the distance is calculated according to the average inclination of the address, the information processing server sets an area spaced by a predetermined distance inward from a boundary line of the input address to an installable area, And the calculated distance is multiplied by the transverse length of the solar module to calculate the required area for installing one solar panel, The number of panels can be calculated.

When information on the inclination of the photovoltaic panel is input after the geographical information of the input address is received, the information processing server determines whether the inclination of the photovoltaic panel is in a vertical direction The distance to the lowermost end of the other solar panel spaced apart from the other solar panel can be calculated and the simulation information reflecting the calculated distance can be generated.

When the input address is a building, the information processing server determines that a direction of a walk is determined according to the structure of the building and other buildings and terrains around the building, If the information about the solar module constituting the solar panel to be installed or the information about the inclination of the solar panel is inputted after the direction of the solar panel is determined, The simulation information reflecting the information on the inclination of the optical panel can be generated.

In addition, when the input address is a land, the information processing server determines that the direction of the input address is determined based on the geographical information of the input address, When the information about the solar module constituting the solar panel to be installed or the information about the inclination of the solar panel is inputted in the direction of arrangement of the selected solar panel, The information about the input solar module, or the information about the inclination of the input solar panel may be generated.

Accordingly, the user performs simulation according to the equipment type of the solar module to be installed, the arrangement direction of the solar panel, the inclination, and the like before the installation so that the number of actually installed solar panels, the maximum installation capacity Etc., and can easily find out the best way to install a photovoltaic power generation facility in the area to be installed.

In addition, it is necessary to accurately calculate the required area for installing one solar panel according to the size, inclination, arrangement direction, etc. of the solar panel, and calculate the desired installation capacity using the calculated result and the installable area for the specific address Simulation is performed to satisfy the requirements, so that the optimum result can be easily found.

FIG. 1 is a diagram illustrating a configuration of a solar panel automatic layout simulation system using geographic information according to an embodiment of the present invention. Referring to FIG.
FIG. 2 is a flowchart illustrating a process of simulating a photovoltaic power generation installation landscape of a street address by inputting information on a street address for installing a solar power generation facility in a solar panel automatic placement simulation system using geographical information according to the present embodiment Fig. 6 is a view showing a screen outputted for explanation. Fig.
3 is a flowchart illustrating a process of selecting size information corresponding to information on input solar modules among size information of previously stored solar modules according to the solar panel automatic layout simulation system using the geographical information according to the present embodiment Fig.
4 is a view for explaining a solar module constituting a solar panel according to the present embodiment.
5 is a flowchart illustrating a process of calculating the distance between the bottom of the specific solar panel and the bottom of another solar panel spaced apart from the bottom in the vertical direction according to the embodiment of the present invention Fig.
FIG. 6 is a view illustrating a process of setting an installable area of the solar panel automatic layout simulation system using the geographical information according to the present embodiment.
FIG. 7 is a view showing an example in which when the type of a photovoltaic module to be installed on a building or the arrangement of a photovoltaic panel to be installed is changed, the modified simulation information is outputted Fig.
FIG. 8 is a view illustrating a manner in which when the inclination degree of a solar module to be installed on a building is changed, the simulation information is output again when the solar panel automatic placement simulation system using geographical information according to the present embodiment is changed.
FIG. 9 is a view illustrating a simulation system for automatically rearranging solar panels according to the present embodiment, when the inclination of a solar module to be installed on the land is changed.
FIG. 10 is a view showing a state in which simulation information is re-changed when the direction of the solar module to be installed on the land is changed, according to the solar panel automatic layout simulation system using the geographical information according to the present embodiment.
11 is a view for explaining a method of simulating a solar power generation installation landscape including a state in which a solar panel is automatically arranged using a system for automatically arranging a solar panel using geographical information according to the present embodiment.

Hereinafter, the present invention will be described in detail with reference to the drawings. The following embodiments are to be considered as illustrative and not restrictive, in order to enable those skilled in the art to fully understand the concept of the present invention. The present invention is not limited to the embodiments described below and may be embodied in other forms.

1 is a view for explaining a configuration of a solar panel automatic layout simulation system (hereinafter, referred to as a 'solar panel automatic layout simulation system') using geographical information according to the present embodiment, and FIG. 2 Is a schematic diagram illustrating a process of simulating the installation scenery of a photovoltaic power generation facility for a street address by inputting information on a street address for installing a solar power generation facility in a solar panel automatic placement simulation system according to the present embodiment, Fig.

The simulation system of the automatic arrangement of the solar panels according to the present embodiment performs simulation according to the equipment type of the solar modules to be installed by the user, arrangement direction of the solar panels, inclination of the solar panels, The number of panels and the maximum installation capacity at the time of maximum installation so that it is possible to easily find an optimum installation plan of the photovoltaic power generation facility in the area to be installed, A distance from a specific point of a specific solar panel to a specific point of another solar panel is calculated so that the necessary area necessary for installing one solar panel according to the size, And using the calculated result and the installable area for a specific address, By performing the simulation so as to satisfy the quantity, it is provided to make it easy to find the best results.

To this end, the present solar panel automatic layout simulation system comprises a database server 100 and an information processing server 200.

The database server 100 is provided to store geographical information including a site area of a facility corresponding to a street address or a land area of a specific area. For this purpose, the first communication unit 110, the first storage unit 120, And a first controller 130.

The first communication unit 110 is connected to the information processing server 200 through a wired or wireless network and is connected to the first storage unit 120 through a geographical area Information to the information processing server 200.

The first storage unit 120 is provided to store geographical information including a site area of a facility corresponding to an address or a land area of a specific area. In addition, the first storage unit 120 may store national spatial information such as national land use status, official land price, and national environmental evaluation map.

When the geographical information including the site area of a facility corresponding to a specific address or the land area of a specific area is requested from the information processing server 200, the first controller 130 transmits the information stored in the first storage unit 120 The information processing server 200 can selectively provide information corresponding to a specific address.

Incidentally, the database server 100 may be implemented as an information service operating server such as a national spatial information service operating server such as Vworld operated by the Ministry of Land, Transport and Maritime Affairs of the Republic of Korea.

2, the information processing server 200 receives the geographical information of the input address, from the database server 100, and transmits the geographical information to the input address based on the received geographical information , And is provided for generating simulation information of the PV installation surface of the address where the installable area is calculated.

To this end, the information processing server 200 may include a second communication unit 210, a second storage unit 220, and a second control unit 230.

The second communication unit 210 is connected to the first communication unit 110 in a wireless or wired manner. When the information about the specific address is input, the second communication unit 210 transmits the database area information to the database server 100, It is possible to request the geographical information including the land area or to receive the geographical information including the three-dimensional image information of the facility corresponding to the address and the land area of the facility corresponding to the address or the land area of the specific area from the database server 100 have.

The second storage unit 220 is provided to store programs and data necessary for operating the information processing server 200. [ Specifically, the second storage unit 220 stores the manufacturer name, the model name, the cell type, the output (W), the unit price, the horizontal and vertical size of the module, the thickness, the warranty period, The information of the solar module including the information of the power generation efficiency according to the inclination of the panel (the angle of the panel), the inverter information including the manufacturer name, model name, output (W) and price of the inverter, The slope distance, and the separation distance constant information for calculating the separation distance according to the inclination of the solar panel.

The second control unit 230 is provided for processing various matters of the information processing server 200.

Specifically, when the information on the address is inputted, the second controller 230 receives the geographical information of the input address, from the database server 100, and displays the installable area for the address on the basis of the received geographical information The distance calculation module 232, the installable area calculation module 233, the installable area calculation module 233, the installable area calculation module 233, and the installable area calculation module 233, ), An installable panel number calculation module 234, and an installed landscape simulation execution module 235.

The panel layout performing module 231 receives the geographical information of the addressee inputted from the database server 100 when the information about the addressee is inputted and displays the photographed sunlight When the information about the solar modules constituting the panel is inputted, the size information corresponding to the information about the solar modules input in the size information of the previously stored solar modules can be selected.

The panel layout performing module 231 sets a default value for the arrangement direction and the inclination of the photovoltaic panel composed of the inputted photovoltaic modules. However, the panel layout performing module 231 additionally inputs information about the placement direction and the slope of the inputted photovoltaic panel The information on the arrangement direction and the inclination of the solar panel can be transmitted to the separation distance calculation module 232.

The separation distance calculation module 232 can calculate the separation distance from the lowermost end of a specific solar panel to the lowermost end of another solar panel spaced apart in the vertical direction.

Specifically, the separation distance calculation module 232 determines whether the solar panel module 231 receives the information about the solar module, sets a default value, or determines the arrangement direction and the slope of the solar panel composed of the solar module The information about the layout direction and the inclination of the solar panel or the input information and the size information selected by the panel layout performing module 231 and the address information received from the database server 100 It is possible to calculate the separation distance from the lowermost end of a specific solar panel to the lowermost end of another solar panel spaced apart in the vertical direction based on the information on the average inclination included in the geographical information.

The installable area calculating module 233 can calculate the installable area for the input address.

Specifically, the installable area calculating module 233 calculates the installable area calculating module 233 based on the distance from the boundary line to the input address area by a predetermined distance, Can be set as the installable area, and the installable area of the set installable area can be calculated.

The installable panel number calculation module 234 can calculate the number of installable solar panels on the installable area based on the calculated distance.

Specifically, the installable panel number calculation module 234 multiplies the calculated distance by the horizontal length of the solar module, and calculates the required area required for installing one solar panel, The number of optical panels can be calculated.

The installation scenery simulation execution module 235 can generate simulation information in which the photovoltaic panel reflecting the calculated spacing distance is automatically arranged at the address.

3A and 3B illustrate a process of selecting size information corresponding to information on the input solar module among the size information of the previously stored solar modules according to the solar panel automatic layout simulation system according to the present embodiment, Respectively.

3A and 3B, the panel layout performing module 231 according to the present embodiment receives information on the photovoltaic module constituting the photovoltaic panel to be installed after the geographical information on the input address is received In the process of selecting the size information corresponding to the input information of the photovoltaic module inputted in the size information of the previously stored photovoltaic module, the separation distance is calculated in consideration of only the vertical length of the photovoltaic module, The longest length and the longest length of the inputted solar module can be changed to the horizontal length and the shorter one to the vertical length.

FIG. 4 is a view for explaining a solar module constituting a solar panel according to the present embodiment, and FIG. 5 is a schematic diagram of a solar panel automatic placement simulation system according to the present embodiment, FIG. 5 is a view illustrating a process of calculating a distance to the lowermost end of another solar panel spaced apart in the direction of FIG.

Referring to FIG. 4, the photovoltaic module according to the present embodiment has a long length and a short length, wherein a plurality of photovoltaic modules constitute one photovoltaic panel, And may be arranged in the lateral direction of the module.

5, when a plurality of solar panels are arranged in a plurality of rows along the lateral direction of the solar module, the solar panel automatic placement simulation system is configured such that the plurality of solar panels are arranged in a plurality of rows along the lateral direction of the solar module, Thus, it is possible to calculate the spacing distance to the lowermost end of another solar panel arranged in another column, and to calculate the necessary area necessary for installing one solar panel based on the calculated spacing distance.

Specifically, the distance calculation module 232 of the solar panel automatic layout simulation system determines that the vertical length of the photovoltaic module is L and the length of the photovoltaic module is L, When the number of solar modules for constitution is N, the inclination degree of the solar panel is set to 30 degrees, and the average inclination of the address area is less than 5 degrees, the other solar cells spaced from the lowermost end of the specific solar panel in the vertical direction The distance D to the lowermost end of the panel can be calculated as D = L * N * 2.16857 (first separation distance constant).

For example, in the case of a solar panel having three solar modules having a length of 2.02 m and a vertical length of 1.024 m, the vertical length is 3.072 m, and the inclination (α) of the solar panel is 30 degrees And the average inclination of the address area is less than 5 degrees, the spacing distance is calculated as 6.66 m by multiplying 3.072 m (vertical length) and 2.16857 (constant), and the necessary area required for installing one solar panel is 6.66 m Distance) and 2.02m (width) to calculate 13.45m2.

In another example, the distance calculation module 232 may be configured such that, when the horizontal length and the vertical length of the photovoltaic module are larger than the vertical length, the vertical length of the photovoltaic module is L and the photovoltaic module Is set to 30 degrees and the average inclination of the address paper is 5 degrees or more, the distance from the lowermost end of the specific solar panel to the lowermost end of the other solar panels spaced apart in the vertical direction The distance D can be calculated as D = L * N * 1.72674 (second separation distance constant).

Here, 2.16857 or 1.72674 corresponds to the stored distance constant information for calculating the separation distance according to the inclination of the solar panel, and when the inclination of the solar panel is changed, the constant value may be changed.

6 is a diagram illustrating a process of setting an installable area of the solar panel automatic layout simulation system according to the present embodiment.

As described above, the installable area calculating module 233 sets an area that is spaced apart from the boundary line of the input address by a predetermined distance as an installable area when the distance is calculated according to the average inclination of the address, The installable area of the installable area can be calculated.

Specifically, the installable area calculation module 233 can be set as an installable area by dividing an area within 5 m inward from a boundary line to a street address as shown in FIG.

When the installable area is set, the installable area calculating module 233 can calculate the installable area, which is the area of the installable area set based on the geographical information received from the database server 100. [

In addition, the installable panel number calculation module 234 calculates the installable area, and if the installable area and the required area necessary for installing one solar panel are calculated, the total installable area of the addressable area and the required per solar panel The number of solar panels that can be installed at the address can be calculated by reflecting the area.

Referring to FIG. 6, for example, when the solar panel in the lowest row is viewed, {[(maximum value of x) - (x value)] / length of array} = (22.5-10.0) /2.02 = , It is possible to arrange and arrange a total of six solar panels on the line from the coordinates (10, 5) to (22.5, 5).

In addition, the solar panel of the nearest distance from the bottom row may reflect the distance calculated in the above-described manner, depending on the average slope of the ground, if the average slope is less than 5 degrees or the average slope is 5 degrees or more, A solar panel can be arranged.

The installable panel number calculation module 234 calculates the installed capacity of the photovoltaic power generation facility to be installed at the address of the user, the desired installed capacity desired by the user, or the maximum When the installation capacity value is input, it is possible to calculate the number of solar panels adjusted according to the input desired installation capacity or the maximum installation capacity, not the maximum value of the number of installable solar panels.

This allows the installed landscape simulation to generate simulated information with automatically arranged solar panels of the adjusted number of solar panels.

FIG. 7 is a view showing a state in which when the type of a solar module to be installed on a building or the arrangement of a solar panel is changed, the simulation information of the solar panel automatic layout simulation system according to the present embodiment is outputted again And FIG. 8 is a view showing a state in which when the inclination degree of the solar module to be installed on the building is changed, the simulation information is output again.

The installation scenery simulation execution module 235 according to the present embodiment generates simulation information of an installation landscape in which a solar panel as a photovoltaic power generation facility is disposed based on geographical information of a street address according to the addressee inputted, The information on the photovoltaic module or information on the inclination of the photovoltaic panel is input or changed again, information on the photovoltaic module re-inputted or changed or the information on the inclination of the photovoltaic panel is reflected, Simulation information can be output.

At this time, the simulation information may be image information that reproduces the appearance of the installation landscape in which the solar panel is disposed.

Specifically, when the input address is a building, the installed landscape simulation execution module 235 receives the geographical information about the input address, and determines whether the direction of the direction of the building depends on the structure of the building and other buildings and terrains around the building When the information about the solar module constituting the solar panel to be installed or information on the inclination of the solar panel is inputted after the direction of the solar panel is determined, And information on the inclination of the solar panel may be generated and outputted. At this time, if the information about the solar module is changed, the changed simulation information can be output again.

In this case, the installed landscape simulation executing module 235 may output the number of the photovoltaic modules disposed at the installable area and the generated capacity through the installation.

In addition, the installed landscape simulation performing module 235 can change the arrangement of the solar panels individually for each of the solar panels.

For example, when the user clicks, double-clicks, or drags the solar panel with the mouse on the screen on which simulation information is output, the installation landscape simulation execution module 235 displays, as shown in FIG. 7B, The optical panel can be deleted or a solar panel can be additionally disposed in a specific area.

8A, when the information about the inclination of the solar panel is changed or re-inputted on the screen in which the simulation information is output as shown in FIG. 8A, the installed landscape simulation executing module 235 displays, The inclination degree of the optical panel is changed, and the simulation information can be generated again.

9 is a view showing a state in which the simulation information of the solar module to be installed on the land is changed again when the inclination of the solar module to be installed is changed, and FIG. FIG. 5 is a diagram illustrating a state in which the simulation system for automatically arranging the solar panel according to the exemplary embodiment outputs the changed simulation information when the direction of the solar module to be installed on the land is changed.

When the input address field is the land, the installation landscape simulation execution module 235 according to the present embodiment determines the direction of the input address field when the geographical information about the input address field is received, Or information on the solar module constituting the solar panel to be installed or the information on the inclination of the solar panel is input, the selected solar panel is selected as shown in FIG. 9A, It is possible to generate and output simulation information reflecting information on the arrangement direction of the optical panel, information on the selected direction, information on the input solar module, or information on the inclination of the solar panel. In this case, When the information is changed, the changed simulation information can be output again.

Specifically, FIG. 9B is a view showing a state in which simulation information reflecting the inclination of the changed solar panel is output, with information on the inclination of the solar panel being changed.

When the information on the arrangement direction and the direction of the solar panel of the solar panel is changed or re-inputted as shown in FIG. 10B, the installation scenery simulation execution module 235 displays the arrangement direction and the re- The simulation information reflecting the information on the simulation result can be output.

11 is a view for explaining a method of simulating a solar power generation installation landscape including a state in which a solar panel is automatically arranged using a solar panel automatic layout simulation system according to the present embodiment.

The database server 100 according to the present embodiment transmits the geographical information about the address to the information processing server 200. When the information server 200 receives the geographical information, When the information about the optical module is input, size information corresponding to the inputted information about the photovoltaic module among size information of the pre-stored photovoltaic module can be selected.

At this time, the information processing server 200 can calculate the distance by considering the vertical length of the solar module, by converting the length of the horizontal length and the vertical length into the horizontal length in the process of calculating the size information, The calculation for the distance calculation can be minimized.

When the size information of the photovoltaic module is selected, the information processing server 200 extracts photovoltaic cells arranged in different rows from a specific point of the specific photovoltaic panel based on the selected size information and information on the average slopes included in the geographical information The distance to the specific point of the panel can be calculated.

Also, the information processing server 200 can set an area that is spaced a predetermined distance inward from the boundary line of the area for the input address, as the installable area, and calculate the installable area of the installable area based on the area .

Then, the information processing server 200 can calculate the necessary area for installing one solar panel based on the calculated distance, and based on this, it is possible to calculate the number of solar panels that can be installed in the installable area have.

Through this, it is possible to generate simulation information reproduced by the installed landscape where the solar panel is automatically arranged, and to perform the first installation scenery simulation.

Further, even after the primary installation landscape simulation is performed, if the information about the solar module, the information about the inclination of the solar panel, the arrangement direction of the solar panel, and the like are changed or re-inputted, Simulation information reflecting the input information can be generated again, and the secondary installation landscape simulation can be performed.

In this way, the user can simulate the installation type of the solar module to be installed, the arrangement direction of the solar panel, the inclination of the solar panel, and the like to set the number of the actually installed solar panels, the maximum installation capacity And it is possible to easily find the optimum installation plan of the photovoltaic power generation facility in the area to be installed by itself and it is possible to easily find the necessary area for installing one photovoltaic panel according to the size, , And the simulation can be performed so as to satisfy the desired installation capacity by using the calculated result and the installable area for the specific address.

While the embodiments of the present invention have been described with reference to the accompanying drawings, it is to be understood that the present invention is not limited by the specific embodiments for effectively explaining the technical idea of the present invention. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. You can do it. Further, the scope of the present invention is indicated by the following claims rather than the above detailed description. Also, all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

100: database server 110: first communication unit
120: first storage unit 130: first control unit
200: information processing server 210: second communication unit
220: second storage unit 230: second control unit
231: Panel layout execution module
232: Distance calculation module
233: Installable Area Calculation Module
234: Number of Installable Panels Calculation Module
235: Install landscape simulation execution module

Claims (7)

A database server for storing geographical information including a site area of a facility corresponding to an address or a land area of a specific area; And
Receiving the geographical information of the addressee inputted from the database server and calculating an installable area for the addressee based on the received geographical information, And an information processing server for generating simulation information of a photovoltaic installation-installed landscape with respect to the calculated address,
The information processing server,
After the geographical information of the input address is received, information on the photovoltaic module constituting the photovoltaic panel to be installed is inputted. Then, among the size information of the previously stored photovoltaic modules, information about the inputted photovoltaic module Size information corresponding to < RTI ID = 0.0 >
Calculating a distance from the lowest end of the specific solar panel to the lowest end of the other solar panels spaced apart in the vertical direction based on the information about the selected size information and the average inclination included in the geographical information about the address,
Calculating a number of solar panels that can be installed on the installable area based on the calculated distance,
Wherein the vertical length of the solar module is L, the number of solar modules for forming one solar panel is N, the inclination of the solar panel Is set to 30 degrees and the average distance of the distance D1 from the lowermost end of the specific solar panel to the lowermost end of the other solar panels spaced apart in the vertical direction is smaller than the distance
D1 = L * N * 2.16857
Respectively,
Wherein the vertical length of the solar module is L, the number of solar modules for forming one solar panel is N, the inclination of the solar panel The distance D2 from the lowermost end of the specific solar panel to the lowermost end of the other solar panels spaced apart in the vertical direction from the lowermost end of the particular solar panel,
D2 = L * N * 1.72674
Wherein the geographical information is calculated based on the geographical information. delete delete The method according to claim 1,
The information processing server,
If the spacing distance is calculated according to the average inclination of the addressee, an area spaced by a predetermined distance inward from a boundary line of the input addressee is set as an installable area, and the installable area of the installable area is calculated and,
And the number of solar panels that can be installed in the installable area is calculated when the calculated distance is multiplied by the lateral length of the solar module to calculate a required area required for installing one solar panel. Solar panel automatic layout simulation system using geographic information. delete delete delete

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