KR100369540B1 - Method for analyzing the duration of sunshine for building - Google Patents

Abstract

According to the present invention, for a building such as an apartment in which several buildings are formed in one complex, the building shape is realized in a real form on a computer, and the sun form is calculated for each apartment unit household according to the position of the sun, and also the sunshine time. A method for analyzing the sunshine time of buildings automatically obtained

The sunshine time analysis method of the building of the present invention comprises: a site information input step of inputting information on the area of the site and the elevation of the site as information on the site where each building of the general building or apartment is located; A site three-dimensional shape generation step of shaping the computer so as to recognize it as one surface based on the site information; Building unit information input step of inputting information of each building of the building such as the plane outline shape of the building, the building name, the height of each floor, the shape and size of the roof such that the computer can recognize the building; A unit generation symbol generation step of generating a symbol constituting a unit generation shape such as the exterior shape and shape of the veranda, the position and size of the balcony window, the shape of the exterior wall and the back porch shape, and the position and size of the rear window; Unit household that inputs the unit generation symbol created in the unit generation symbol generation step into the inside of the building type information input in the building unit information input step and designates the belonging building, the household number and the number of households for the unit household that entered the unit household symbol. Information input step; A staircase room information input step of designating a shape of a staircase room and a shape and a size of a rooftop to be generated at an upper portion of the staircase room in an inside of the house shape input in the building unit information step; A building three-dimensional shape generation step in which a program automatically generates a three-dimensional shape of a building by using the inputted building information, generation information, and stairs information; A calculation reference information input step of specifying the longitude and latitude of the building, the calculation reference date, the calculation time zone, and the calculation time interval as basic information for calculating the sunshine time; A solar position calculation step of calculating azimuth and elevation angles of the sun by using the calculated reference information; If the specific location of each generation is specified, the program finds the location to be calculated by using the three-dimensional shape information of each generation and calculates the sunshine time according to the change in the position of the sun. It includes.

Description

Sunshine time analysis of buildings {METHOD FOR ANALYZING THE DURATION OF SUNSHINE FOR BUILDING}

The present invention relates to a method of analyzing the sunshine time of a building for analyzing the time of the sun light on a building such as an apartment, in which a plurality of coppers are formed as a single complex. It is related to the sunshine time analysis method of building that obtains the sunshine form for each apartment unit household according to the position of the sun and automatically calculates the sunshine time.

Recently, due to the improvement of living standard, the interest in sunshine right for buildings such as apartments has increased, so many apartments are preferred. Therefore, the sunshine type and sunshine time analysis of apartments have emerged as an important issue.

Conventionally, a method of analyzing sunshine time using a program providing a computer graphic function is used.

The conventional sunshine time analysis method is to model the shape of a building and show the sun shape by shaping only the overall appearance of the building without the technology of shaping each generation such as an apartment. Such a conventional method cannot express the actual shape of various buildings, including, for example, the roof of the apartment, the roof, and the like, and thus cannot accurately represent the shadow of the sun. However, since the conventional technology does not shape a building for each generation, it was not possible to analyze the sunshine time for each generation.

In addition, the conventional sunshine time analysis method is difficult to analyze unless it is an expert, and it takes a lot of time to implement the three-dimensional shape of the building. Since time should be measured, the sunshine time analysis is inaccurate and the analysis takes a lot of time.

The present invention has been made to solve the above-mentioned problems of the prior art, and the general user can easily shape the unit generation of the building without using a computer graphic program and use it to automatically correct the correct sunshine time for each generation. The purpose is to provide a method of analyzing the sunshine time of buildings that calculate

A sunshine time analysis method of a building of the present invention for achieving the above objects comprises: a site information input step of inputting a range of land on a plane of the site and elevation information of the site as information on the site of each building of a general building or apartment; A site three-dimensional shape generation step of shaping the computer so as to recognize it as one surface based on the site information; Building unit information input step of inputting information of each building of the building such as the plane outline shape of the building, the building name, the height of each floor, the shape and size of the roof such that the computer can recognize the building; A unit generation symbol generation step of generating a symbol constituting a unit generation shape such as the exterior shape and shape of the veranda, the position and size of the balcony window, the shape of the exterior wall and the back porch shape, and the position and size of the rear window; Unit household that inputs the unit generation symbol created in the unit generation symbol generation step into the inside of the building type information input in the building unit information input step and designates the belonging building, the household number and the number of households for the unit household that entered the unit household symbol. Information input step; A staircase room information input step of designating a shape of a staircase room and a shape and a size of a rooftop to be generated at an upper portion of the staircase room in an inside of the house shape input in the building unit information step; A building three-dimensional shape generation step in which a program automatically generates a three-dimensional shape of a building by using the inputted building information, generation information, and stairs information; A calculation reference information input step of specifying the longitude and latitude of the building, the calculation reference date, the calculation time zone, and the calculation time interval as basic information for calculating the sunshine time; A solar position calculation step of calculating azimuth and elevation angles of the sun by using the calculated reference information; If the specific location of each generation is specified, the program finds the location to be calculated by using the three-dimensional shape information of each generation and calculates the sunshine time according to the change in the position of the sun. It includes.

1 is a flowchart showing a method of analyzing the sunshine time of a building of the present invention;

2 is a plan view of a building and a site for explaining an embodiment of the present invention,

3 is a three-dimensional shape diagram of the site generated in the site three-dimensional shape generation step of the present invention,

4 is a plan view of a specific building showing a plane outline shape of the specific building input in the building-specific information input step of the present invention;

5 is a state diagram of a display showing a state of designating a name of a building in the building unit information input step of the present invention;

6 is a state diagram of a display showing a state of setting a floor height of a building in the building unit information input step of the present invention;

7 is a state diagram of a display showing a state of designating a roof shape of a building in a building unit information input step of the present invention;

Figure 8 is a unit generation symbol geometry of one embodiment generated in the unit generation symbol generation step of the present invention.

9 is a state diagram of a display showing a state of inputting an outline shape and a shape of a veranda in a unit generation symbol generation step of the present invention;

10 is a state diagram of a display showing a state of inputting a position and a size of a balcony window in a unit generation symbol generation step of the present invention;

11 is a state diagram of a display showing a state of designating a unit household symbol inside a building shape in a generation information input step of the present invention;

12 is a state diagram of a display showing a state in which lake designation and floor number designation are performed for a unit household for which a unit generation symbol is designated in the generation information input step of the present invention;

13 is a state diagram of a display showing a state of designating a position of a staircase in a staircase room information input step of the present invention;

14 is a state diagram of a display showing a state specifying a shape of a rooftop in the staircase room information input step of the present invention;

FIG. 15 is a perspective view of the entire building in which a three-dimensional shape of a building is generated by using inputted site information, building identification information, household information, and stairs information in a building three-dimensional shape generation step of the present invention;

16 is a state diagram of a display showing a state of inputting calculation reference information in the calculation reference information input step of the present invention;

FIG. 17A is a shadow floor shape generation step of the present invention, using the inputted site information, building identification information, generation information and stairs information, and calculated using the calculated azimuth and elevation angles of the sun on the floor by time zones. The shadow bottom shape that represents the shape of the shadow being

Figure 17b is generated in the shadow floor shape of the present invention, by using the input site information, building identification information, household information and stair room information, the calculated azimuth and elevation angle of the sun on the floor by the whole building by time zone The shadow bottom shape that represents the shape of the shadow being

FIG. 18A illustrates a wall surface of a specific building at 09 o'clock using the input site information, building apartment information, household information, stairs information, and calculated azimuth and elevation angles in the shadow wall shape generation step of the present invention. Shadow wall shape diagram showing the shape of the shadow,

FIG. 18B is a shadow wall shape generating step of the present invention, which is generated on the wall of a specific building at 12 o'clock by using inputted site information, building identification information, generation information, and stairs information, and the calculated azimuth and elevation angles of the sun; Shadow wall shape diagram showing the shape of the shadow,

FIG. 19 is a view of a sun at a specific location of a building using inputted site information, building apartment information, household information, stairs information, and calculated azimuth and elevation angles in a generation point-specific one-ildo degree generation step of the present invention; Three-dimensional shape diagram of day zero with time

20 is a result of calculating the sunshine time using the inputted site information, building unit information, household information, stairs information and calculated azimuth and elevation angles in a specific point sunshine time collective calculation step for each generation of the present invention; Is a state diagram of a display.

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

1 is a flowchart showing a method of analyzing the sunshine time of a building of the present invention.

As shown in Figure 1, the sunshine time analysis method of the building of the present invention site information input step, site three-dimensional shape generation step, building unit information input step, unit generation symbol generation step, generation information input step, stair room information input Step, building three-dimensional shape generation step, calculation reference information input step, solar position calculation step, shadow floor shape generation step, shadow wall shape generation step, specific point daily zero generation step by generation, specific point sunshine time generation by generation It includes the calculation step.

The sunshine time analysis method of the present invention uses a program that automatically calculates sunshine time when inputting necessary data into a computer.

2 is a plan view of a building and a site for explaining an embodiment of the present invention, Figure 3 is a three-dimensional shape of the site generated in the site three-dimensional shape generation step of the present invention.

In the site information input step, site information is input to a computer. The site information is information on the location of each building in a general building or apartment, and means the range of the site and the elevation of the site.

For example, in the case of a site as shown in FIG. 2, a point is set at four corners specifying a site, the point is designated with a mouse point, a site shape is input, and an altitude value for the site is input.

When the site information is input as described above, the site 3D shape as shown in FIG. 3 is generated in the site 3D shape generation step.

Next, in the building unit information input step, the building unit information is input.

4 is a plan view of a specific building showing a flat outline of a specific building inputted in the building wing information input step of the present invention, and FIG. 5 is a state diagram of a display showing a state of designating a building name in the building wing information input step of the present invention. 6 is a state diagram of a display showing a state of setting a floor height of a building in a building unit information input step of the present invention, and FIG. 7 shows a state of designating a roof shape of a building in a building unit information input step of the present invention. The state diagram of the display.

For building building information, first enter the plane outline of the building. For example, in the case of a building having a floor plan as shown in FIG. 4, a point of four corners is designated as a mouse point to input a plane outline of the building.

And designate the name of the building. For example, if the type of the building is an apartment and the number of 102 apartments, enter the apartment and 102 buildings as shown in FIG.

Next, set the height of the building. As shown in FIG. 6, the number of building floors is input, the height difference between the ground and the lower slab of the first floor of the building is input, and the floor height is input.

And enter the roof shape of the building as shown in FIG. As shown, if the roof is in the form of a slope, it is input until the slope.

Next, the unit generation symbol is input by inputting the elements constituting the unit generation in the unit generation symbol generation step.

8 is a unit generation symbol shape of an embodiment generated in the unit generation symbol generation step of the present invention, Figure 9 is a display showing the state of entering the shape and shape of the veranda in the unit generation symbol generation step of the present invention 10 is a state diagram of a display showing a state of inputting a position and a size of a balcony window in a unit generation symbol generation step of the present invention.

A symbol as shown in FIG. 8 is generated by inputting the shape and size of a balcony, a front window, an outer wall, and a rear window, which constitute the unit generation.

For example, the shape and size of the balcony are input as shown in FIG. 9, and the position and size of the front window are input as shown in FIG. 10. In this way, all the elements constituting the unit generation are input and the unit generation symbol shown in FIG. 8 is stored. When the unit generation symbol is generated, the unit generation size (square) is set.

The unit generation symbol is prepared in advance in order to easily input the size and shape of the unit household in the generation information input step, which will be described later, in the case of an apartment, the unit size and shape of each unit household are the same.

Next, in the household information input step, the unit household information is input into the apartment shape generated in the building unit information input step.

FIG. 11 is a state diagram of a display showing a state in which a unit generation symbol is designated inside a building shape in a generation information input step of the present invention, and FIG. 12 is a diagram of a unit generation in which a unit generation symbol is designated in a generation information input step of the present invention. It is a state diagram of a display which shows the state of designation and floor designation.

First, unit generation symbols are designated as shown in FIG. 11 using unit generation symbols prepared in the previous step, and unit generation lakes and floor numbers are designated for each building as shown in FIG. 12.

Next, in the stair room information input step, the stair room information is input.

FIG. 13 is a state diagram of a display showing a state specifying a position of a staircase in a staircase room information input step of the present invention, and FIG. 14 is a state diagram of a display showing a state specifying a shape of a rooftop in a staircase room information input step of the present invention.

First, the staircase room position is designated as shown in FIG. 13, and the shape of the rooftop is designated as shown in FIG.

Then, the three-dimensional shape of the building is modeled using the information input so far in the three-dimensional shape generation step of the building as shown in FIG. 15.

The information input in the above steps and the generated site 3D shape, unit generation symbol and building 3D shape are stored in a database.

16 is a state diagram of a display showing a state of inputting calculation reference information in the calculation reference information input step of the present invention.

In the calculation reference information input step, as shown in FIG. 16, the latitude / longitude coordinates of the building, the calculation reference date, the calculation reference time, and the calculation reference interval are input. This calculation reference information is the basic information for calculating the position (azimuth, altitude) of the sun.

Next, in the sun position calculation step, the azimuth and elevation angles of the sun are obtained based on the calculation reference information input in the step. Depending on the location of the building, the formula for calculating the azimuth and elevation angles of the sun at specific times and at specific times can be found in the academia. Therefore, using these formulas, the azimuth and elevation angles of the sun can be easily obtained.

FIG. 17A is a shadow floor shape generation step of the present invention, using the inputted site information, building identification information, generation information and stairs information, and calculated using the calculated azimuth and elevation angles of the sun on the floor by time zones. Figure 17b is a shadow floor shape diagram showing the shape of the shadow to be, in the shadow floor shape generation step of the present invention, the input site information, building identification information, generation information and stairs information, the calculated azimuth and elevation angle of the sun Shadow floor shape diagram showing the shape of the shadow generated on the floor by the whole building by time zone using.

In the shadow floor shape generation step, the shadow of the building is formed on the ground by the sun at regular intervals based on the azimuth and elevation angles of the sun calculated in the above step.

The shadow floor diagram may show a shadow shape generated by a specific building (right vertically arranged building) among all buildings as shown in FIG. 17A, and a shadow shape generated by the whole building as illustrated in FIG. 17B.

According to the shadow floor shape, the shape of the shadow generated on the ground in the complex can be grasped at each time zone, and the sun shape of the whole building can be known.

FIG. 18A illustrates a wall surface of a specific building at 09 o'clock using the input site information, building apartment information, household information, stairs information, and calculated azimuth and elevation angles in the shadow wall shape generation step of the present invention. 18B is a shadow wall shape diagram showing a shape of a shadow, and FIG. 18B illustrates inputted site information, building identification information, generation information, and stairs information, and calculated azimuth and elevation angles of the sun in the shadow wall shape generating step of the present invention. It is a shadow wall surface diagram which shows the shape of the shadow which is created on the wall of a specific building by 12 o'clock.

In the shadow wall shape creation step, shadows generated on a specific motion wall are generated by time zone. 18A shows the shape of the shadow formed on the wall of the specific building at 09 o'clock and FIG. 18B shows the shape of the shadow formed on the wall of the specific building at 12 o'clock.

Based on the input site information, building information, and the position of the sun, the shape of the shadow formed on the wall of the building can be grasped at a predetermined time interval, thereby roughly knowing the sunshine environment of the building.

FIG. 19 is a view of a sun at a specific location of a building using inputted site information, building apartment information, household information, stairs information, and calculated azimuth and elevation angles in a generation point-specific one-ildo degree generation step of the present invention; It is the three-dimensional shape diagram of the sun zero according to the change of time.

In the generation point specific point ilyeongdo generation step, as shown in FIG. 19, the shadow generated at a specific position (for example, the middle point of the veranda of a specific unit generation) is shown in three dimensions according to time change. The specific point day zero may be represented based on the already inputted site information, building building information, household information, stair room information, and calculation reference information.

19 shows a specific point day zero which is generated from 09:00 to 15:00, wherein a time zone with a building part covering the sun at a specific point is a time at which a shadow is generated at a specific point and a time zone without a building part covering the sun is specified. This is the time when no shadow is created at the point.

Therefore, it is possible to easily grasp the sun rise time and the sun shape at a specific position of a certain birds.

20 is a result of calculating the sunshine time using the inputted site information, building unit information, household information, stairs information and calculated azimuth and elevation angles in a specific point sunshine time collective calculation step for each generation of the present invention; Is a state diagram of a display.

In the collective calculation step for specific point sunshine time for each household, the sunshine time for specific point for each household is calculated based on the already inputted site information, building building information, household information, stairs room information and calculation standard information.

If you specify a specific location of each generation (for example, the middle of the veranda), the program finds the location to be calculated using the three-dimensional information of each generation and automatically calculates the sunshine time according to the change of the sun's position as shown in FIG. do. Fig. 20 shows the total provisioning time and continuous provisioning time of each household for the second floor of 101 building.

In this way, it is possible to know the sunshine period and sunshine hours on each day for each household, so it is easy to grasp the sunshine environment for each household, and based on it, the price of the apartment can be differentiated. In consideration, you can choose a family and a generation that suit your taste.

In the sunshine time analysis method of the building of the present invention, the general user can easily shape the same as the actual building to the unit generation of the building, the roof shape, etc., and automatically calculate the sunshine time for each generation automatically by using this to generate each generation. It is possible to easily understand the sunshine environment by building, and accordingly, the building supplier can set an appropriate sale price for each household, and the tenant can select the copper, floor, and lake that suits their taste by taking into account the sunshine environment and the sale price. It is effective.

Although the invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various changes or modifications can be made within the spirit and scope of the invention, and such changes or modifications are consequently claimed. It will have to belong to the scope of.

Claims (4)

Building unit information input step of inputting information of each building of the building such as plane outline shape, building name, height of each floor, roof shape and size so that the computer can recognize the building; A calculation reference information input step of specifying the longitude and latitude of the building, the calculation reference date, the calculation time zone, and the calculation time interval as basic information for calculating the sunshine time; In the sunshine time analysis method of a building comprising the step of calculating the position of the sun to calculate the azimuth and altitude angle of the sun by using the calculated reference information input, A site information input step of inputting the site information on the area of the site and the elevation of the site as information on the site where each building of the general building or apartment is located; A site three-dimensional shape generation step of shaping the computer so as to recognize it as one surface based on the site information; A unit generation symbol generation step of generating a symbol constituting a unit generation shape such as the exterior shape and shape of the veranda, the position and size of the balcony window, the shape of the exterior wall and the back porch shape, and the position and size of the rear window; Unit household that inputs the unit generation symbol created in the unit generation symbol generation step into the inside of the building type information input in the building unit information input step and designates the belonging building, the household number and the number of households for the unit household that entered the unit household symbol. Information input step; A staircase room information input step of designating a shape of a staircase room and a shape and a size of a rooftop to be generated at an upper portion of the staircase room in an inside of the house shape input in the building unit information step; A building three-dimensional shape generation step in which a program automatically generates a three-dimensional shape of a building by using the inputted building information, generation information, and stairs information; And If you specify a specific location of each generation, the program finds the location to be calculated by using the three-dimensional shape information of each generation, and calculates the sunshine time batch step for each specific point that automatically calculates the sunshine time according to the change of the position of the sun. Sunlight analysis method of the building, characterized in that it comprises. delete delete According to claim 1, Three-dimensional shape according to the change of the time of the sun at a specific location of the building using the input site information, building identification information, household information and stairs information, and calculated azimuth and elevation angle of the sun Sunlight time analysis method for a building, characterized in that it further comprises a generation point specific generation zero zero generation step.