KR20230159341A - System and method for optimal placement of solar panels in buildings - Google Patents

Abstract

The optimal design system for building solar power facilities of the present invention includes a selection unit for selecting a calculation mode for ZEB certification or a calculation mode for power generation prediction, and a drawing input unit for inputting the address and drawing of the measured building and expressing the surrounding terrain and surrounding buildings as a drawing. , a solar radiation input unit that divides the measured building into the size desired by the user using the drawing input unit and applies the solar radiation amount, a PV installation ranking unit that specifies a location where solar panels can be installed in the measured building, and a ZEB authentication unit. An information input unit for inputting information requested in calculation mode or calculation mode for predicting power generation, and 3D modeling of the installation area and detailed location of the solar panel in the measurement building required for ZEB certification or actual installation of the solar panel through the information input unit. It may be provided with a result output unit that outputs 3D modeling of the solar panel installation area and detailed location to calculate power generation or produce actual power generation for prediction.

Description

{System and method for optimal placement of solar panels in buildings}

The present invention relates to an optimal design system and method for solar power facilities in buildings. More specifically, the optimal design system and method for solar power facilities in buildings can be designed so that solar panels installed in buildings produce optimal solar power generation capacity. It's about.

Zero Energy Building (ZEB) is a building that minimizes the energy required for a building and minimizes energy consumption by utilizing renewable energy, ideally a building that has annual energy consumption of zero. In other words, it refers to a building that is self-sufficient in energy, but because there are technical and economic limitations, it is classified into zero energy buildings according to the ratio of power generation to energy consumption.

There are two major methods for constructing a zero energy building as described above: 'Passive technology' and 'Active technology'. Passive technology refers to the use of insulation, double glazing, etc. to penetrate the building envelope. The idea is to minimize the amount of energy leaking out, and active technology means using renewable energy such as geothermal heat and solar energy to self-solve all energy consumption, including power supply, heating and cooling, and cooking.

In particular, solar power generation has been actively developed in recent years by naturally supplying nearly infinite energy from the sun without consuming any fuel, and large-scale solar power generation complexes are being built and operated to increase the efficiency of solar power generation.

However, in general, in the process of designing a solar power generation system, the data used in the installation of the existing solar power generation system is collected and the radiation is designed and installed, so the initial investment cost is higher than that of other existing solar power generation systems. Problems are arising in which photovoltaic power generation systems do not work properly.

In addition, there is a problem that consumers may be dissatisfied with installing a solar power system without accurately analyzing how much electricity bills will be reduced after installing the solar power generation device.

Domestic Patent Publication No. 10-1628459 (2016.06.01)

The purpose of the present invention is to provide an optimal design system and method for building solar power facilities that can be calculated for zero energy building certification in the process of designing solar panels for buildings.

Another object of the present invention is to provide an optimal design system and method for building solar power facilities that can calculate the actual power generation of solar panels in the process of designing solar panels for buildings.

In order to achieve the above object, the optimal design system for building solar power facilities according to one aspect of the present invention includes a selection unit for selecting a calculation mode for ZEB certification or a calculation mode for predicting power generation, and inputting the address and drawing of the measured building. A drawing input unit that represents the surrounding terrain and surrounding buildings as a drawing, a solar radiation input unit that divides the measured building into the size desired by the user and applies solar radiation using the drawing input unit, and selects a location where solar panels can be installed in the measured building. PV location selection unit, an information input unit for inputting information requested in the calculation mode for ZEB certification or calculation mode for power generation prediction, and the solar panel installation area of the measurement building required for ZEB certification through the information input unit, and A result output unit may be provided to calculate detailed location 3D modeling or actual power generation of the solar panel, or output 3D modeling of the solar panel installation area and detailed location to produce actual power generation for prediction.

If the user does not select a location where the solar panel can be installed in the measured building, the PV location selection unit outputs the result based on the solar radiation of the entire measured building regardless of the location where the solar panel can be installed. It can be.

The information input unit can input primary energy production, efficiency, tilt, and orientation of the solar panel into the ZEB authentication calculation mode.

The ZEB authentication calculation mode further includes a ZEB authentication output unit that first outputs the solar panel installation area, location, and approximate estimate in a table using the information received from the information input unit, and the ZEB authentication calculation mode is further provided with a ZEB authentication output unit that first outputs the solar panel installation area, location, and approximate estimate in a table using the information received from the information input unit, and It may further include a PV installation ranking unit that allows the user to specify the priority of the solar panel installation location and transmits additional information to the 3D modeling output unit.

The selection unit may select the calculation mode for predicting the power generation and then select the actual power generation calculation mode for ZEB authentication or the actual power generation calculation mode for input.

The information input unit automatically inputs the value output from the ZEB authentication calculation mode into the actual power generation calculation mode for ZEB authentication, or inputs the actual power generation desired by the user into the actual power generation calculation mode for input, and inputs the actual power generation amount desired by the user into the actual power generation calculation mode for input. In the actual power generation calculation mode and the actual power generation calculation mode for input, the user can input inverter information and the number of solar panels connected to the inverter to increase the accuracy of the actual power generation.

In addition, the optimal design method for building solar power facilities according to another aspect of the present invention to achieve the above object includes the steps of selecting a calculation mode for ZEB certification or a calculation mode for predicting power generation (S100); Entering the address and drawing of the measured building and expressing the surrounding terrain and surrounding buildings in a drawing (S200); Dividing the measured building into user-desired sizes and applying solar radiation (S300); Selecting a location where solar panels can be installed in the measurement building (S400); Entering information requested in the ZEB authentication calculation mode or power generation prediction calculation mode (S500); And 3D modeling of the installation area and detailed location of the solar panel in the measured building required for ZEB certification or calculating the actual power generation of the solar panel through the information requested in the calculation mode for ZEB certification or calculation mode for power generation prediction, A step (S600) of outputting 3D modeling of the solar panel installation area and detailed location to produce actual power generation for prediction may be provided.

Before the step of selecting the calculation mode for ZEB certification (S100) is performed, a step of deriving the primary energy production per unit area of the measured building (S50) may be further included.

In the step of entering information requested in the ZEB authentication calculation mode (S500), primary energy production, efficiency, tilt, and orientation of the solar panel can be input.

After the step of inputting information requested in the ZEB certification calculation mode (S500), a step of first outputting the solar panel installation area, location, and approximate estimate in a table (S520) is further provided, and the ZEB authentication calculation mode In the step of transmitting additional information to the step (S600) of outputting the 3D modeling by specifying the priority of the solar panel installation location by the user through the measurement values output in a table of the solar panel installation area, location, and approximate estimate. (S530) may be further provided.

The step of selecting the calculation mode for predicting power generation (S100) may include the user selecting the actual power generation calculation mode for ZEB authentication or the actual power generation calculation mode for input.

In the step (S500) of inputting information requested in the calculation mode for power generation prediction, when the user selects the actual power generation calculation mode for ZEB authentication, the value output in the calculation mode for ZEB authentication is automatically input, and the user selects the actual power generation calculation mode for ZEB authentication. When selecting the actual power generation calculation mode for input, the user directly inputs the desired actual power generation, and the actual power generation calculation mode for ZEB certification and the actual power generation calculation mode for input are based on the inverter information and the inverter to increase the accuracy of the actual power generation. The user can input the number of solar panels to be connected.

In the step (S600) of calculating and outputting the actual power generation in the ZEB certification calculation mode, the actual power generation can be calculated and output in a table based on the solar panel installation area and detailed location 3D modeling output in the ZEB certification calculation mode. there is.

According to the optimal design system and method for building solar power facilities according to the present invention, the installation area and detailed location of solar panels required for zero energy building certification of the measured building are output and 3D modeling of the solar panel applied to the measured building is performed. It can be output as .

In addition, the solar panel installation area and detailed location for the actual power generation desired by the user can be output in the calculation mode for predicting power generation, or the actual power generation for ZEB certification can be output by automatically inputting the resulting information in the calculation mode for ZEB certification. You can.

Figure 1 is a flowchart showing an optimal design method for building solar power facilities according to an embodiment of the present invention.
Figure 2 is a flowchart showing the process of selecting the calculation mode for ZEB certification among the optimal design methods for building solar power facilities in Figure 1.
Figure 3 is a front view showing the calculation mode for ZEB certification among the optimal design methods for building solar power facilities in Figure 2 output through 3D modeling.
Figure 4 is a flowchart showing the process of selecting a calculation mode for predicting power generation among the optimal design methods for building solar power facilities in Figure 1.
Figure 5 is a front view showing the calculation results of the calculation mode for predicting power generation among the optimal design methods for building solar power facilities in Figure 4 output in a table.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the attached drawings. However, it goes without saying that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, parts not related to the description are omitted in order to clearly and briefly explain the present invention, and identical or extremely similar parts are denoted by the same drawing reference numerals throughout the specification. In addition, in the drawings, the thickness, area, etc. are enlarged or reduced in order to make the explanation more clear, so the thickness, area, etc. of the present invention are not limited to what is shown in the drawings.

And when a part is said to “include” another part in the entire specification, it does not exclude other parts and may further include other parts, unless specifically stated to the contrary.

The optimal design system for building solar power facilities according to an embodiment of the present invention includes a selection unit 100 for selecting the calculation mode 110 for ZEB certification or the calculation mode 120 for predicting power generation, and the address of the measurement building 10. and a drawing input unit 200 that inputs a drawing and expresses the surrounding terrain and surrounding buildings as a drawing, and a solar radiation input unit 300 that divides the measured building 10 into the size desired by the user using the drawing input unit 200 and applies the solar radiation amount. , a PV location selection unit 400 that selects a location where the solar panel 20 can be installed in the measurement building 10, and a calculation mode 110 for ZEB certification or a calculation mode 120 for power generation prediction. Through the information input unit 500, which inputs information, and the information input unit 500, 3D modeling of the installation area and detailed location of the solar panel 20 in the measurement building 10 required for ZEB certification or the actual installation of the solar panel 20 A result output unit 600 may be provided to calculate the amount of power generation or output 3D modeling of the installation area and detailed location of the solar panel 20 to produce actual power generation for prediction.

The selection unit 100 allows the user to use the calculation mode 110 for ZEB certification for Zero Energy Building (hereinafter: ZEB) certification of the measurement building 10 within the system or the solar panel 20 in the measurement building 10. You can be guided to select one of the power generation prediction calculation modes 120 that predict the actual amount of power generation.

Here, the calculation mode 120 for predicting power generation is the actual power generation calculation mode 121 for ZEB authentication, which calculates the actual power generation based on the results output from the calculation mode 110 for ZEB certification, or by inputting the actual power generation value desired by the user. The user can be guided to select one of the input actual power generation calculation modes 122 in which the installation area and detailed location of the solar panel are calculated according to the user's actual power generation amount.

The drawing input unit 200 allows the user to upload a 3D drawing of the measured building 10 to the system, input the address of the measured building 10, and input information about surrounding buildings, surrounding terrain, and overall direction for modeling.

*When uploading a 3D drawing to the system, the drawing input unit 200 can upload a sketch up plug-in or Revit-based file.

If there is no 3D drawing, the drawing input unit 200 allows the user to directly model the measured building 10 in 3D based on a 3D model program such as Sketch Up.

The solar radiation input unit 300 divides the external surface of the 3D modeled measurement building 10 into cells, and the cell size can be adjusted to be arbitrarily designated by the user or selected according to the solar panel database.

When inputting information about solar radiation, the solar radiation input unit 300 can use solar radiation meteorological data and select and adjust the accumulated solar radiation amount desired by the user (5-hour cumulative amount, summer cumulative amount, annual cumulative amount, etc.).

The PV location selection unit 400 can specify all locations where the solar panel 20 can be installed in the 3D modeled measurement building 10.

If the user does not select a location where the solar panel 20 can be installed in the measurement building 10, the PV location selection unit 400 selects the measurement building 10 regardless of the location where the solar panel 20 can be installed. The result can be input to the result output unit 600 to optimally design the solar panel 20 based on the total amount of solar radiation.

When the calculation mode 110 for ZEB certification is selected in the selection unit 100, the information input unit 500 can input the primary energy production per unit area, the efficiency, tilt, and orientation of the solar panel 20.

Here, the information input unit 500 must determine the possible installation orientation of the solar panel 20 in the ZEB authentication calculation mode 110, and since 45 degrees is an advantageous angle among horizontal and 45 degrees, the information input unit 500 can be set to a 45 degree angle.

In addition, when the calculation mode 120 for predicting power generation is selected in the selection unit 100, the information input unit 500 automatically inputs the result value output from the calculation mode 110 for ZEB certification. You can select either the calculation mode 121 or the input actual power generation calculation mode 122, in which the user directly inputs the desired actual power generation amount.

In addition, in the information input unit 500, which selects the calculation mode 120 for predicting power generation, the specifications of the inverter that is connected to the solar panel 20 and converts electricity are entered in order to increase accuracy in the process of predicting the actual power generation. The number of solar panels 20 connected to the inverter can be grouped and the grouped solar panel 20 and inverter connection information can be input to the measurement building 10.

When the calculation mode 110 for ZEB certification is selected in the selection unit 100, the result output unit 600 can output the installation area and detailed location of the solar panel 20 in accordance with ZEB certification.

In addition, when the calculation mode 120 for predicting power generation is selected in the selection unit, the result output unit 600 displays the actual power generation amount when the solar panel 20 is installed in accordance with the actual power generation calculation mode 121 for ZEB certification. You can calculate and output, or you can calculate and output the installation area and detailed location of the solar panel 20 required for the actual power generation according to the actual power generation calculation mode 122 for input.

The result output unit 600 can output the output 3D modeling as a file compatible with Sketch up and convert it to facilitate later work.

Next, an optimal design method for building solar power facilities according to another embodiment of the present invention will be described. In the following description, only parts that are different from the above-described embodiment will be described in detail, and detailed descriptions of parts that are the same or extremely similar will be omitted.

Figure 1 is a flowchart showing an optimal design method for building solar power facilities according to an embodiment of the present invention.

The optimal design method for building solar power facilities according to another embodiment of the present invention includes the steps of selecting a calculation mode 110 for ZEB certification or a calculation mode 120 for predicting power generation (S100); Entering the address and drawing of the measured building 10 and expressing the surrounding terrain and surrounding buildings in a drawing (S200); Dividing the measurement building 10 into sizes desired by the user and applying solar radiation (S300); Selecting a location where the solar panel 20 can be installed in the measurement building 10 (S400); Entering information requested in the calculation mode 110 for ZEB authentication or the calculation mode 120 for predicting power generation (S500); And 3D modeling or solar power of the installation area and detailed location of the solar panel (20) of the measurement building (10) required for ZEB certification through the information requested in the calculation mode (110) for ZEB certification or the calculation mode (120) for predicting power generation. A step (S600) of calculating the actual power generation of the panel 20 or outputting 3D modeling of the installation area and detailed location of the solar panel 20 to produce the actual power generation for prediction may be provided.

In the step of selecting the PV location (S400), if the user does not select a location where the solar panel 20 can be installed in the measurement building 10, the measurement building (20) is selected regardless of the location where the solar panel 20 can be installed. 10) The results can be input to the output step (S600) to optimally design the solar panel 20 based on the total amount of solar radiation.

Through this, the optimal design method for building solar power facilities allows the measuring building (10) to output the installation area and detailed location of the solar panel (20) required for Zero Energy Building (ZEB) certification through 3D modeling.

In addition, the optimal design method for building solar power facilities is for the user to directly input the actual power generation amount of the solar panel 20 required for the measurement building 10, and install the installation area and installation area of the solar panel 20 according to the input actual power generation amount. The detailed location is output through 3D modeling, or the information output as a result is automatically input in the ZEB certification calculation mode (110), and the actual power generation amount of the solar panel (20) according to the ZEB certification calculation mode (110) is output as a result. You can receive it.

Next, the step (S110) of selecting a calculation mode for ZEB certification among the optimal design methods for building solar power facilities according to another embodiment of the present invention will be described in more detail.

FIG. 2 is a flowchart showing the process of selecting the calculation mode for ZEB certification among the optimal design methods for building solar power facilities in FIG. 1, and FIG. 3 shows the calculation mode for ZEB certification among the optimal design methods for building solar power facilities in FIG. 2 through 3D modeling. This is a front view showing the printed appearance.

Referring to FIG. 2, before the step (S110) of selecting the calculation mode 110 for ZEB certification is performed, a step (S50) of deriving the primary energy production per unit area of the measurement building (10) may be further provided. there is.

The step (S50) of deriving the primary energy production per unit area of the measured building 10 is to determine the annual energy demand and consumption by checking the maximum output coefficient of the solar system through calculation analysis related to ECO2 (building energy evaluation program) solar panels. and energy independence rate can be calculated.

The step (S500) of entering the information requested in the calculation mode for ZEB certification (110) or the calculation mode for power generation certification (120) is when the calculation mode for ZEB certification (110) is selected, primary energy production, solar panel A step of inputting the efficiency, slope and orientation of (20) (S510), a step of first outputting the installation area, location and approximate estimate of the solar panel (20) in a table (S520), and the solar panel of the measurement building (10) ( 20) A step (S530) in which the user specifies the installation priority may be provided.

In the step (S510) of inputting the primary energy production, efficiency, tilt, and orientation of the solar panel 20, some of the values output in the step of deriving the primary energy production (S50) can be input.

The step (S520) of first outputting the solar panel 20 installation area, location, and approximate estimate in a table is an estimate when the user selects a wide range of locations where the solar panel 20 can be installed in the measurement building 10. You can first print out the quote as a table.

In the step (S530) in which the user specifies the installation priority of the solar panel 20 in the measurement building 10, the user can directly select the priority of the solar panel 20 to be installed in the measurement building 10. . For example, the user selects the entire roof of the measured building (10) as first priority, the east and west side walls as second priority, and then the southern living room side wall as third priority, so that solar panels are installed only in the required area. It can be guided as much as possible.

The step (S610) of outputting 3D modeling of the installation area and detailed location of the solar panel 20 of the measurement building 10 required for ZEB certification through the information requested in the calculation mode 110 for ZEB certification is performed on the measurement building 10. Through the information received in the step (S530) where the user specifies the installation priority of the solar panel 20, the final installation area and detailed location of the solar panel 20 can be output through 3D modeling. . Additionally, the shading of the measured building 10 can be confirmed through 3D modeling.

Referring to FIG. 3, the step of outputting the 3D modeling of the installation area and detailed location of the solar panel 20 (S610) outputs the largest 3D modeling to the user, and installs the solar panel 20 designated as a priority on the right. Installation areas can be listed in order of location.

Additionally, at the bottom right, the direction and slope of the detailed location of the solar panel 20 designated as a priority may be listed in order.

Next, the step (S120) of selecting a calculation mode for predicting power generation among the optimal design methods for building solar power facilities according to another embodiment of the present invention will be described in more detail.

Figure 4 is a flowchart showing the process of selecting the calculation mode for power generation prediction among the optimal design methods for building solar power facilities in Figure 1, and Figure 5 shows the calculation results of the calculation mode for power generation prediction among the optimal design methods for building solar power facilities in Figure 4. This is a front view showing the table printed out.

Referring to FIG. 4, the step of selecting the calculation mode 120 for power generation prediction (S120) is the step of the user selecting the actual power generation calculation mode for ZEB authentication (S121) or the step of selecting the actual power generation calculation mode for input ( A step may be provided to guide selection of one of S122).

Here, the step of selecting the actual power generation calculation mode for ZEB certification (S121) is to calculate the predictable actual power generation according to the installation area and detailed location of the solar panel 20 output as a result in the ZEB certification calculation mode 110. mode, and the step of selecting the actual power generation calculation mode for input (S122) is a mode in which the user directly inputs the actual power generation desired in the measurement building 10 and calculates the installation area and detailed location of the solar panel 20 required for this. It can be provided with .

In the step (S540) of inputting information in the step (S121) of selecting the actual power generation calculation mode for ZEB authentication, the value output as a result in the calculation mode for ZEB authentication (110) can be automatically input. The entered values can include primary energy production, solar panel installation area, and detailed location.

And, in the step (S550) of inputting information into the actual power generation calculation mode for input (S122), the actual power generation desired by the user can be directly input.

The step of selecting the actual power generation calculation mode for ZEB certification (S121) and the step of selecting the actual power generation calculation mode for input (S122) have in common a formula for predicting actual power generation, calculation of shading between buildings and obstacles, and construction cost per area of solar panels. You can enter data.

In addition, the step of entering information into the step of selecting the actual power generation calculation mode for ZEB certification (S121) (S540) and the step of entering information into the actual power generation calculation mode for input (S122) (S550) are performed in the measurement building (10). A 'solar panel grouping and inverter connection information input step (S560)' can be provided in which the user inputs how many solar panels (20) will be connected to the installed inverter to convert electricity, and also inputs the specifications of the inverter to be installed. there is.

The solar panel grouping and inverter connection information input step (S560) involves grouping the specifications of the inverter to be installed and the number of solar panels 20 to be connected to one inverter in order to calculate an accurate calculation value in the process of calculating the actual power generation. You can.

The step (S620) of outputting the results calculated in the step of selecting the actual power generation calculation mode for ZEB certification (S121) is a solar panel designed for ZEB certification through the information entered in the actual power generation calculation mode for ZEB certification (121). The actual power generation in (20) can be output in a table.

Referring to FIG. 5, the result output for the step (S121) of selecting the actual power generation calculation mode for ZEB certification is simply expressed in a table of the results output in the calculation mode for ZEB certification (110), and the actual power generation is calculated accordingly. It can be displayed with a table.

In the step of selecting the actual power generation calculation mode for input (S122), the step of outputting the calculated results (S630) involves 3D modeling the installation area and detailed location of the solar panel 20 to which the actual power generation directly entered by the user is applied. It can be printed and delivered to the user. At this time, the output 3D modeling may be output in the same form as the result output step (S610) of selecting the calculation mode for ZEB authentication shown in FIG. 3.

Through this, the step of selecting the calculation mode for power generation prediction (S120) selects the actual power generation calculation mode for ZEB certification, which predicts the actual power generation and expresses it in a table using the results output in the step of selecting the calculation mode for ZEB certification (S110). A step (S121) of selecting an actual power generation calculation mode for input that directly inputs the actual power generation desired by the user and outputs the installation area and detailed location of the solar panel 20 through 3D modeling (S122). It can be provided.

In addition, the optimal installation area and detailed location (slope, angle) of the solar panel 20 that can be applied to the measurement building 10 are identified using the optimal design method for building solar power facilities as described above, and for ZEB certification or By calculating the actual power generation desired by the user, it is possible to even predict the performance of the solar panel to be applied to the measurement building (10).

In the above, the optimal design system and method for solar power facilities in buildings according to embodiments of the present invention have been described, but the spirit of the present invention is not limited to the embodiments presented in this specification. Additionally, a person skilled in the art who understands the spirit of the present invention will be able to easily suggest other embodiments by adding, changing, deleting, or adding components within the scope of the same spirit, but this is also within the scope of the present invention. They will say it costs money.

10: measurement building 20: solar panel
100: selection unit 200: drawing input unit
300: solar radiation input unit 400: PV location selection unit
500: information input unit 600: result output unit

Claims (1)

A step in which the user selects a calculation mode for ZEB authentication or a calculation mode for predicting power generation (S100);
After step S100, the user inputs the drawing and address of the measured building and models the surrounding terrain and surrounding buildings (S200);
After step S200, the user divides the elevation of the measured building model into desired area sizes and inputs solar radiation (S300);
After step S300, the user selects a location where solar panels can be installed among the divided areas of the measured building (S400);
After step S400, the user inputs PV installation information including the primary energy production of the solar panel, PV efficiency, and the slope and orientation required for installation (S500); and
After step S500, the system outputs the solar panel installation area, installation location, rough estimate, and 3D modeling required for the measured building to derive the result of the calculation mode for ZEB certification, and the result of the calculation mode for ZEB certification A step (S600) of outputting a 3D modeling file compatible with Sketch up and the actual power generation amount of the solar panel based on the value to derive a result value of the calculation mode for predicting power generation;
In step S500, the user directly specifies the priority after dividing the solar panel installation location into the roof, east and west side walls, and south side wall of the measured building,
The S500 step inputs the actual power generation prediction formula, shading calculation between the measured building and obstacles, and construction cost data per area of the solar panel,
The calculation mode for ZEB certification verifies the maximum output coefficient through solar panel-related calculation analysis of ECO2 (Building Energy Evaluation Program) to calculate annual energy demand and consumption and energy self-sufficiency rate,
In step S100, the calculation mode for predicting power generation is selected, and then either the actual power generation calculation mode for ZEB certification or the actual power generation calculation mode for input is selected,
The actual power generation calculation mode for ZEB certification automatically inputs the solar panel installation area, installation location, and approximate estimate output from the ZEB certification calculation mode to calculate the actual power generation of the solar panel designed to suit the ZEB certification calculation mode. The power generation amount is derived from the table in step S600,
In the input actual power generation calculation mode, the user directly inputs the desired actual power generation and derives the installation area and detailed location of the solar panel in the S600 step using a 3D modeling file compatible with Sketch up. Equipment optimal design method.

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