JP2001155052A - Method for selecting plate glass to be used for external wall surface for reflected solar radiation heat simulation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the danger of ignition or burn caused by the convergence of reflected light corresponding to the form of a building since not only luminosity, with which a walker or driver of an automobile feels dazzling, but also a thermal influence exerted upon the walkers, installations and plants around the building can not be ignored sometimes concerning the influence of light, which is reflected form the external wall of the building, exerted upon the periphery of the building. SOLUTION: A plate glass is selected by performing a reflected solar radiation heat simulation composed of a process for inputting the form data of the external wall of the building, the data of an atmospheric permeability in the area to construct the building, the optical characteristics data of the plate glass to be used for the wall surface of the building and the object time of calculation execution, process for finding the reflection angle of sunlight on the plate glass to be used for the wall surface of the building, process for finding the position of reflection of solar light, process for finding a reflected solar radiation heating value and process for finding the total of reflected solar radiation heating values.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sheet glass used for a wall surface of a building, which is used to determine whether there is a thermal defect due to sunlight reflected from the sheet glass by a computer calculation process (hereinafter referred to as simulation). Research on technologies to investigate and select types of flat glass.

[0002]

2. Description of the Related Art Various prediction means have been proposed for the relationship between solar energy and buildings in order to evaluate energy saving and to investigate comfort in a thermal environment. In particular, the energy saving effect and indoor comfort are simulated at the opening of the building when using double-glazed glass with excellent heat insulation or when using heat-reflector glass with high solar reflectance. .

When a glass or a metal panel that reflects sunlight at a high reflectance is used, there is a glare as an effect on the outdoors, and the reflection range of the sunlight and the illuminance of the place where the reflected light is applied are calculated. It became so.

[0004]

However, the influence of the light reflected from the outer wall of the building on the periphery of the building is not limited to the illuminance that pedestrians and car drivers feel dazzling. In some cases, thermal effects on objects and planting cannot be ignored. Depending on the shape of the building, the reflected light may condense and cause fire or burns.

[0005] There is no means for predicting the thermal effect of such building reflected light, and the present invention has been made in view of this problem.

[0006]

According to the present invention, there is provided a method for selecting a flat glass to be used for an outer wall surface of a building, comprising: data relating to the shape of the outer wall of the building;
The process of inputting the data of the air permeability in the area where the building is constructed, the optical property data of the flat glass used on the wall of the building, and the data of the calculation target time, and the unit of the flat glass used for the building wall A step of determining the angle of reflection of sunlight, a step of determining the position of the reflection of sunlight from the flat glass unit on an arbitrary surface around the building, and a step of calculating the amount of reflected solar radiation from the single sheet glass on any surface around the building A method of selecting a sheet glass, comprising performing a reflected solar radiation heat simulation including a step and a step of calculating the total amount of reflected solar radiation heat from the single sheet glass on an arbitrary surface around the building.

In the reflected solar heat simulation, a database of reflectance with respect to the incident angle and wavelength of the glass sheet is used, and the simulation result is displayed as three-dimensional CAD data.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION In order to simulate the amount of direct solar radiation reflected on the wall of a building, data on a building to be simulated is input to a computer.

The data relating to the building includes data relating to the outer wall surface, data relating to sheet glass used for the outer wall surface and subjected to simulation, data relating to a place where the building is being constructed or planned to be constructed, It is time to perform.

The data relating to the outer wall surface is the direction of the outer wall surface, and data such as a direction based on the coordinates provided in the building or a direction based on the horizontal direction, the vertical direction, and the azimuth is input.

The data relating to the glass sheet is data of the shape and size of a plane, a plane, a triangle and a quadrangle, etc., and further corresponds to the ultraviolet, visible and infrared wavelength ranges of solar radiation, and further to the incident angle. , Reflectance spectrum data.

It is preferable that the reflectance spectrum data corresponding to the wavelength ranges of ultraviolet, visible and infrared regions of the solar radiation of the sheet glass and further corresponding to the incident angle is made into a database so that it can be inputted.

The data of the place where the building is constructed or the place where the construction is planned is longitude, latitude and standard time longitude.

Further, the data of the time at which the simulation is performed may include month, day, and hour in units of minutes. A simulation based on weather data may be performed by inserting year data.

The step of calculating the angle of reflection from the glass sheet includes the step of obtaining the sun altitude from the position data of the building and the time data to be calculated, and the data of the shape of the glass sheet and the direction of the outer wall surface on which the glass sheet is used. Is a step of calculating the reflection angle of solar radiation of the single sheet glass from the above data.

In this calculation, if the glass sheet reflects the solar radiation on a plane, a vector perpendicular to the glass sheet is obtained by using a vector parallel to the two sides of the glass sheet, and the reflection angle is obtained. If the sheet glass is a curved surface, perform element division,
Each element is regarded as a flat plate glass, and the reflection angle is determined for each element.

This reflection angle is the incident angle of solar radiation, and is used for selecting the solar reflectance corresponding to the incident angle of the plate glass in the step of calculating the amount of reflected solar radiation of the plate glass.

The step of determining the reflection position of sunlight from the flat glass unit on an arbitrary surface around the building includes the step of calculating the reflection position on an arbitrary surface around the building from the reflection angle of the flat glass and the data of the shape of the flat glass. Ask.

Further, it is checked whether there is a device that blocks incident light on the plate glass and a device that blocks reflected light between the plate glass and the reflection position. The thing to be shielded is the unevenness of the wall surface of the building to be simulated or the existing object around the building.

If there is an object to be shielded, the glass sheet is divided into elements, and an element that blocks light and an element that is not blocked are divided to determine a reflection position.

In the step of calculating the amount of reflected solar radiation from a single sheet of glass on an arbitrary surface around a building, first, the direct solar radiation is determined from the solar constant, the atmospheric transmittance, and the solar altitude, and then the amount of solar radiation incident on the single sheet of glass is determined. The amount of reflected solar radiation of each sheet glass is obtained by dividing the amount of solar radiation by the area of the reflection position.

In the step of calculating the total amount of reflected solar radiation on any surface around the building, the total amount of reflected solar radiation from each of the above-mentioned glass sheets is calculated on any surface around the building.

A step of obtaining the position of reflection of sunlight from the flat glass unit on an arbitrary surface around the building, a step of obtaining the amount of reflected solar radiation from the flat glass alone on an arbitrary surface around the building, and The result obtained by the step of calculating the total reflected solar radiation is three-dimensional CA
It is displayed on the computer monitor as D data,
Print with a printer. For printing by a printer, the user can select whether to print or not by watching the display on the monitor.

The display of the three-dimensional CAD data is obtained by distributing the results obtained in each process to the shape of the building and the shape of the existing structure in the vicinity in the form of a pattern or color.

The results obtained in the step of calculating the reflection angle of the glass sheet are displayed by printing a list of numerical values for each glass sheet, and displaying the shape of the building by arrows or the like for each glass sheet in a three-dimensional CAD diagram. Is also good.

The above-described simulation is performed, for example, in FIG.
This is performed using the apparatus shown in FIG. The apparatus shown in FIG. 1 includes a controller 5 for reflected solar heat simulation, a keyboard 2 and a mouse 3 as input means, and a display 1 for displaying a result.
And a printer that prints the results. Further, the control unit 5 includes a CPU 6 for controlling a calculation process, each calculation means, a main storage device 7 for storing input data and calculation results, a RAM 8 for performing calculation work, and a display control unit 9.
It consists of.

The main storage device 7 includes a sun position / solar radiation amount calculating means 7a, a single glass reflection angle calculating means 7b, a single glass reflection position calculating means 7c, a single glass reflected heat amount calculating means 7d, and a total reflected heat amount calculating means. 7e, calculation result display means 7f, glass reflection characteristic storage means 7g, input data storage means 7h, and calculation result storage means 7i are stored, and further, glass reflection characteristic database storage device 7g ', input data storage device 7h', calculation result storage It comprises a device 7i 'and a solar radiation database storage device 7j'.

FIG. 2 is a flowchart showing a solar reflection simulation process performed by using the apparatus having the above-described configuration.

First, the visible light reflectance and the solar reflectance (hereinafter, these two reflectances are collectively referred to as reflection characteristic data) of the plate glass used for the building to be simulated are stored in the reflection characteristic storage device 7g '. It is checked whether or not the data is registered in the registered database. If the data is registered in the database, the reflection characteristic data of the glass sheet is selected (step 100). If the data is not registered, the reflection is performed using the keyboard 2 or the mouse 3. The characteristic data is input (step 110). Further, the input reflection characteristic data of the plate glass is encoded and stored in the plate glass reflection characteristic storage means 7.
g (step 120).

Next, the position of the building to be simulated and the time at which the simulation is performed,
The altitude and azimuth of the sun (hereafter, the altitude and azimuth of the sun will be called the position of the sun) and the amount of direct solar radiation on the radiation plane (hereafter called the amount of solar radiation)
Is registered in the solar radiation database stored in the solar radiation database storage device 7g ', and if it is registered, the data is called up (step 130). 3, the position of the building to be simulated and the time of the simulation are input, and the position of the sun and the amount of solar radiation are calculated (step 140). Further, the calculation result of the position of the sun and the amount of solar radiation is registered in the solar radiation database by the input data storage means 7h and stored in the solar radiation database storage device 7h '(step 150).

The position of the sun input in the simulation is preferably the longitude and latitude of the administrative district where the building is constructed.

Next, it is checked whether or not data relating to the shape and position of the glass used for the target building and the irregularities of the building wall such as eaves are registered in the input data storage device 7h '. Data relating to the shape and position of the glass and the irregularities on the wall surface are called and used (step 160). If not registered, the data of the shape and position of the glass and the irregularity of the wall surface are input using the keyboard 2 and the mouse 3 (step 170), and further registered in the input data storage means 7h '(step 180).

Steps 100 to 180 complete the process relating to the data necessary for the calculation, and then proceed to the process of calculating the amount of solar radiation.

First, the single glass reflection angle calculation means 7b calculates the reflection angle of each plate glass of the building to be simulated, and the reflection angle of sunlight with respect to the position of the building and the time when the simulation is performed (step). 190). In step 190, if there is an eave between the glass and sunlight, or if the window surface is retracted from the wall of the building to the indoor side, and sunlight enters only a part of the glass, based on the data in step 160, One glass is divided into a suitable size, a portion where sunlight is reflected and a portion where sunlight is not applied are divided, and a reflection angle calculation is performed.

Next, the position of the reflected light on an arbitrary surface is calculated by the single glass reflection position calculation means 7c (step 200). The arbitrary surface actually designates the ground around the building, the outer wall of the existing building, or the like. Step 19
0 and the calculation result of step 200 are calculated result storage means 7i.
Is stored in the calculation result storage device 7i '(step 2).
10).

Next, from step 100 to step 120
Using the reflection characteristic data of the glass up to and the solar radiation data of the sun from step 130 to step 150,
The amount of reflected heat of the sunlight glass reflected on any surface,
The calculation is performed by the glass single reflection calorie calculation means 7d (step 220). The calculation result of step 220 is glass 1
This is the amount of reflected solar radiation from the sheet, and the calculation result is stored in the calculation result storage device 7i 'by the calculation result storage means 7i (step 230). Further, the total reflected heat amount obtained by summing the reflected solar heat amounts from all the glass on the arbitrary surface is calculated by the total reflected heat amount calculating means 7e (step 24).
0), the calculation result is stored in the calculation result storage device 7i 'by the calculation result storage means 7i (step 250).

A simulation result of the total amount of reflected heat with respect to one time is obtained by the processes from Step 100 to Step 250. If there is a calculation of a time that requires the simulation, a NO determination is made in Step 260, and the flow proceeds to Step 100. If there is no time at which the simulation is required, the determination at step 260 is YES,
The operation proceeds to step 270.

The simulation is performed by selecting the date and time of the summer solstice when the solar altitude is the highest, the time when the solar altitude is the lowest, and selecting a spring equinox day or an autumn equinox day between the two days. Is preferred.

In step 270, the result calculated by the total reflection calorie calculation means 7e and stored in the calculation result storage device 7i 'by the calculation result storage means 7i in step 250 is plotted by the calculation result display means 7f, and the display control is performed. Part 9
To display on the display 1.

If the image data displayed on the display 1 is a result that achieves the purpose of the simulation, the image data is stored in the calculation result storage device 7i 'by the calculation result storage means 7i, and if necessary, a printer is used. In step 4, the image data is printed (step 290), and the flow advances to step 300 to determine whether the simulation is completed.

If it is determined in step 270 that the image data does not achieve the purpose of the simulation, the determination of YES / NO in step 280 is appropriately made, and NO is selected in step 300, and the process returns to step 100. Continue the simulation.

The apparatus and the flowchart described above are examples for carrying out the invention, and do not limit the present invention. Further, although the description relates to a sheet glass, the simulation of the present invention can be carried out also for a material having a high reflectance used for an outer wall surface of a building other than the sheet glass, such as a metal panel or a tile.

[0043]

EXAMPLE A solar reflection heat simulation was performed according to a flowchart shown in FIG. The plate glass is a heat ray reflective glass of gold color, and the plate thickness is 6 mm.
As the reflectance spectrum data corresponding to the incident angle, data registered in a glass reflection characteristic database was used.

FIG. 3 shows a three-dimensional image as an image of how the reflected light hits the sidewalk and the roadway near the building, and a two-dimensional plan view of the distribution of the amount of solar radiation.
FIG. 3 shows the result obtained at 11:00 of the summer solstice, and shows the maximum amount of reflected solar radiation at a point on the sidewalk around the building. Table 1 shows the results obtained by simulating the amount of reflected solar radiation by changing the time and obtaining the maximum value of the amount of reflected solar radiation and its reflection position.

The results shown in Table 1 were obtained for various sheet glasses, and sheet glasses used for buildings were selected.

[0046]

[Table 1]

[0047]

According to the method for simulating reflected solar heat of a building of the present invention, it is possible to easily examine, before construction, how the sunlight reflected on the wall surface of the building has a thermal effect on the periphery of the building. Made it possible. Further, the difference in the influence of the change of the sheet glass can be easily examined.

[Brief description of the drawings]

FIG. 1 is a diagram showing an apparatus for solar reflected heat simulation.

FIG. 2 is a flowchart showing an embodiment of solar reflected heat simulation.

FIG. 3 is a plan view showing a distribution of solar radiation reflection in the first embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Display 2 Keyboard 3 Mouse 4 Printer 5 Control part 6 CPU 7 Storage device 7a Sun position / solar radiation amount calculation means 7b Glass single reflection angle calculation means 7c Glass single reflection position calculation means 7d Glass single reflection calorie calculation means 7e Total reflection calorie calculation Means 7f Calculation result display means 7g Sheet glass reflection characteristic storage means 7h Input data storage means 7i Calculation result storage means 8 RAM 9 Display control unit 10 Calculation target building 11 Reflecting wall surface of building 12 Sidewalk around building 13 Roadway 14 Sidewalk opposite 15 Reflected sunlight Range where the amount is 1000 to 1250 W / m ² 16 Range where the reflected solar radiation is 1250 to 1500 W / m ² 17 Range where the reflected solar radiation is 1500 to 1750 W / m ²

Claims (3)

[Claims] 1. A method for selecting a flat glass to be used for an outer wall surface of a building, comprising: data relating to the shape of the outer wall of the building; data of a position where the building is to be constructed; data of atmospheric permeability in a region where the building is constructed; Inputting the optical property data and the calculation target time data regarding the flat glass used for the wall of the building, obtaining the reflection angle of sunlight of the unit of flat glass used for the building wall, Determining the position of the reflection of sunlight from the flat glass unit on the surface, obtaining the amount of reflected solar radiation from the flat glass alone on any surface around the building, and determining the amount of reflected solar radiation from the flat glass alone on any surface around the building. A method for selecting a sheet glass, comprising performing a reflected solar heat simulation including a step of calculating a total amount of reflected solar heat. 2. The method according to claim 1, wherein the simulation result is displayed as three-dimensional CAD data. 3. The method according to claim 1, wherein the simulation is performed using a reflectance database for the incident angle and the wavelength of the sheet glass.