KR20090001538A - Method for calculating of pollution level in the room - Google Patents

Abstract

An indoor pollution calculation method by extracting contaminant data with material data and environmental parameter data of indoor is provided to minimize exhaustion of contaminant by estimating an indoor pollution degree due to harmful material comes out from construction material. An indoor pollution calculation method by extracting contaminant data with material data and environmental parameter data of indoor comprises a step of inputting interior material data about a target building and the environmental parameter data of indoor by a user, a step of extracting contaminate data based on a database of contaminate exhaust value and a step for analyzing of the building indoor based on the environmental parameter data reflecting to the contaminate exhaust value. An indoor pollution calculation system by extracting contaminant data with material data and environmental parameter data of indoor includes a recorder recording a program capable of decoding a method for analyzing an indoor pollution level.

Description

Method for calculating of pollution level in the room}

1 is a flow chart of the indoor pollution degree calculation method according to the present invention.

2 is a screen for inputting data for performing the indoor pollution degree calculation method according to the present invention.

3 is a screen for inputting an environmental element in FIG.

4A is a screen for entering the material of the component of FIG.

4B is a screen for inputting a material of another component in FIG. 2.

5 is a screen for simulating the internal pattern shown in FIG.

6 is a screen for calculating indoor pollution degree values according to FIGS. 3, 4a, and 4b.

7 is a screen of a database in which pollutant emission values are stored for each material.

The present invention relates to an indoor environment, and more particularly, to a method for evaluating the environment of a building interior.

As the industry develops, the natural environment and living environment are rapidly damaged. In addition to pollution of water, air, and soil, pollution due to noise and vibration is also serious. In addition, the so-called sick house syndrome, which is a problem caused by harmful substances emitted from building materials and wallpaper used to build environmental hormones and buildings, which are recently detected in living containers, is also one of the new environmental pollutions. can do.

Among them, for example, because it is difficult to know the degree of pollutant discharge into the room according to the building material before building construction, such as a new house syndrome, there is a problem that effective coping, such as changing the building material to prevent it. In addition, it is difficult to predict the change of pollutant emission value according to the building environment such as pollution degree according to various environmental changes such as indoor structure, or the degree of pollutant emission according to the change of building materials, so that it is possible to reflect various variable factors. There is a problem that it is difficult to measure the pollution level.

The present invention has been made to solve the above problems, an object of the present invention, by predicting the indoor pollution level due to harmful substances generated in the building material in advance, it is possible to create an environment that can minimize the emission of pollutants It is to make it.

In addition, another object of the present invention, by predicting the indoor pollution degree according to various environmental changes or changes in the building material in advance, to enable the use of a structural composition or material that can minimize the indoor pollution.

Indoor pollution degree calculation method according to an aspect of the present invention for achieving the above object, (a) step of receiving from the user the material data for each component of the room and the environmental element data of the room for the building to be assessed pollution degree; ; (b) extracting a pollutant discharge value according to the received material data from a database of pollutant emission values for each material; and (c) calculating the pollution degree evaluation value of the interior of the building by reflecting the received environmental element data in the pollutant discharge value.

According to this, there is an advantage that the environmental composition that can minimize the emission of pollutants is possible by evaluating and predicting the indoor pollution degree according to the materials and environmental elements constituting the room in advance.

At this time, the indoor pollution degree evaluation value is characterized in that it is calculated as the concentration value of at least one of volatile organic compounds and formaldehyde in the room.

On the other hand, the component of the room is characterized in that it comprises at least one of the interior wall, ceiling, floor, opening of the room.

According to this, by considering the pollutant emission according to the actual structure when constituting the interior of the building, there is an advantage that the actual and accurate pollution degree can be calculated.

In addition, the environmental element data, characterized in that it comprises at least one or more of the size of the interior of the building and room temperature, indoor humidity, azimuth, ventilation amount and weather conditions.

According to this, by measuring the indoor pollution degree according to the variable real environment, it is possible to predict the change in pollution degree according to various environmental changes, it is possible to optimize the environment to minimize the pollution degree.

In addition, the material database is classified according to the criteria of at least one of the use part, use, and manufacturing company of the material.

The present invention also provides a recording medium on which a computer-readable program is recorded which records a program for performing the above-described indoor pollution degree calculation method.

As a result, the indoor pollution level can be calculated more quickly and conveniently.

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

1 is a flowchart of a method for calculating indoor pollution degree according to the present invention.

Indoor pollution degree calculation method according to the present invention comprises the step of inputting the material data and environmental element data for each indoor component (100), the step of extracting the pollutant discharge value according to the material data (200), the step of reflecting the environmental element data ( 300) and calculating the indoor pollution degree evaluation step (400). That is, when a user inputs indoor component data and indoor environmental component data on a building to be polluted, the pollutant discharge value according to the input material data is extracted, and the environmental component data input thereto is reflected. Finally, the indoor pollution degree evaluation value is calculated.

In short, the indoor pollution degree calculation method of the present invention can be programmed and executed, and the program has a database of pollutant emission values for each material data, and can be calculated through environmental factors and pollutant emission values for each material data. An algorithm exists. That is, data about the amount or rate of pollutant emitted per hour (eg TVOC: 0.04 μg / m ³ ) is stored in 1 square meter per material (eg, arbon, a type of flooring material), and temperature, A control module for calculating an indoor pollution level through an equation calculated using data on environmental factors such as humidity and ventilation amount and pollutant data for each material is provided.

Hereinafter, it will be described that the user inputs data necessary for performing the indoor pollution degree calculation method according to the present invention on the screen of the user terminal to calculate the pollution degree.

2 is a screen for inputting data for performing the indoor pollution degree calculation method according to the present invention.

The left side is a screen for inputting the environmental element 100a of the indoor space for which the pollution degree is to be evaluated, and the right side is a screen for selecting materials of the component 100b constituting the indoor space. After the environmental element 100a is input, the materials of the component 100b may be input, or the materials of the component 100b may be input first, and then the environmental element 100a may be input. A process of inputting data on materials for each of the environmental elements 100a and the components 100b will be described in detail with reference to FIGS. 3, 4A, and 4B.

3 is a screen for inputting the environmental element 100a of FIG. 2.

As illustrated, items input to the environmental element 100a may include a site name, a real name, a date, a width, a length, a height, a volume, a temperature, a humidity, an orientation, a ventilation amount, or a weather condition. Here, the site name, real name, and date are not data reflected in the pollution assessment, but are items for data management of the pollution assessment value in a specific environment by inputting the space name and date to measure the pollution. Indoor environment factors such as size, temperature, humidity, etc., such as width, length, height are reflected, and the range of error of pollution degree, ie, bake-out and insolation, is determined by the direction of space, indoor ventilation, and current weather conditions. The impact on diffusion can be considered. In addition, pollution degree can be evaluated by reflecting various environmental elements 100a, and a detailed process of calculating the degree of pollution by reflecting such environmental elements 100a will be described in detail with reference to FIG. 6.

4A is a screen for inputting the material of component 100b in FIG. 2.

The components 100b constituting the room were classified into inner walls, ceilings, floors, and openings. The inner wall means four walls constituting the room except the ceiling and the floor (inner walls 1, 2, 3, and 4), and inputs the building materials forming the inner wall. At this time, at least one or more materials are selected for each of the four inner walls, and each layer formed of the material is expressed as a layer (layer 1. 2. 3...). In other words, if the inner wall 1 uses wood, adhesive, and wallpaper as materials, each of the three layers is selected and the material of each layer is selected. The material of the component 100b includes flooring, wallpaper, paneling, wood, adhesive, paint, and the like, wherein each material is classified into various kinds and provided. A screen in which kinds of materials are classified will be described with reference to FIG. 7. In addition, by inputting the area occupied by the material forming each layer, the contamination degree is varied and reflected according to the material area. The ceiling and the floor can be input by selecting materials and areas forming each layer in the same manner as the inner wall.

4B is a screen for inputting the material of another component 100b in FIG. 2.

The opening of the component 100b refers to a window or a door that does not hit a wall for light, ventilation, ventilation, and entry and exit. The size of the window and the door can be determined by inputting the size of the window and the door. do. Although not shown, it is possible to input the materials of windows and doors, such as the inner wall and the ceiling, to reflect pollution and emission values according to these materials.

5 is a screen for simulating an internal pattern of FIG. 4A.

That is, in FIG. 4A, a pattern of materials forming a selected layer for each indoor component 100b is simulated and presented. As shown, the layers selected for the four inner walls are represented in different colors, and three layers of materials are selected and shown. Although the pattern of the layers is not simulated on the ceiling and the floor, it can be expressed as well. This makes it easy to visually check the material for each layer selected by the user.

6 is a screen for calculating indoor pollution degree values according to FIGS. 3, 4A, and 4B.

When the materials for each indoor environmental element 100a and the component 100b are selected as described above, an indoor pollution degree evaluation value is calculated. At this time, the pollution degree may be calculated as a concentration value of volatile organic compound (TVOC) or formaldehyde (HCHO).

The concentration of volatile organic compounds (TVOC) can be calculated by the following equation.

(C _TVOC : volatile organic compound concentration in air, Q: ventilation amount, EF _x : x discharge rate of volatile organic compound in material, S: area)

That is, the emission of volatile organic compounds of the material selected for each component 100b from the data on the indoor ventilation amount Q and the indoor area S, which are environmental elements 100a, and the database of pollutant emission values for each pre-stored material. The velocity (EF _x ) can be extracted to calculate the concentration of volatile organic compounds (TVOC). At this time, the concentration in the air of the volatile organic compounds generated for each component (100b) may be used to calculate and add the concentration for each component (100b). That is, as illustrated, it is used Min beanie roll and hits the ceiling material, by summing each of the volatile organic compound concentration of 21.4286㎍ / m ³ and 23.5714㎍ / m ³ to calculate the contamination level in 45㎍ / m ³ Can be.

Alternatively, the correlation may be calculated by considering the correlation for each component 100b. That is, for example, compared to the material forming the innermost layer of the inner wall, the material that forms the outermost layer may decrease the concentration emitted to the room relatively, so that only about 90% of the calculated value is as described above. It can be calculated by reflecting. Alternatively, if the ceiling of the component 100b can emit more volatile organic compounds relative to the other components 100b in position, it may be calculated by reflecting 120% of the calculated value as described above.

The concentration of formaldehyde (HCHO) can be calculated by the following formula.

(C _HCHO : concentration of formaldehyde in air, EF _x : formaldehyde emission in air of material x at temperature 25 ℃, humidity 50%, t: temperature, h: humidity, S: area, V: volume)

That is, from the data on the environmental temperature (t), the indoor temperature (t), the indoor humidity (h), the indoor area (S), and the indoor volume (V) of the environmental element 100a and the database of the pre-stored pollutant emission values for each material, The concentration value of formaldehyde (HCHO) can be calculated by extracting the emission (EF _x ) of formaldehyde (HCHO) under the conditions of 25 ° C. and 50% humidity of the selected material for each 100b). This may also be used in a manner of summing the concentrations of formaldehyde generated for each component 100b. That is, it is possible by summing the beanie roll and hits seeds formaldehyde concentration of 1.8360㎍ / m ³ and 1.0200㎍ / m ^3, as illustrated in calculating the contamination level 2.8560㎍ / m ^3. Alternatively, the same may be calculated in consideration of the correlation between the components 100b as in the volatile organic compound.

7 is a screen of a database in which pollutant emission values are stored for each material.

In the database, the types of materials used for each component 100b are classified according to the use site, use, manufacturer, etc., and each pollutant emission value, for example, volatile organic compound (TVOC) or formaldehyde (HCHO) ) The discharge value (concentration) is stored. The pollutant discharge value for each material stored as described above may be calculated using the concentration calculation equation as shown in FIG.

The data stored in the database can be updated from time to time when numerical changes, such as research or experiment, occur, and the materials used can be updated continuously. In addition to the illustrated indoor structure, the change value according to various structural changes can be reflected, and the change of various environmental factors can be reflected to perform more precise and accurate pollution degree evaluation.

In this way, by inputting materials to be used for each environmental element and component according to the structure of the building interior, it is possible to construct a structure that can minimize pollution by calculating the degree of pollution discharged to the room, and more easily and quickly. do.

According to the present invention, by predicting the indoor pollution degree due to harmful substances generated in the building material in advance, it is possible to create an environment that can minimize the emission of pollutants. In addition, according to another aspect of the present invention, by predicting the indoor pollution degree according to various environmental changes or changes in the building material in advance, it is possible to use a structural composition or material that can minimize the indoor pollution degree.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims described in the appended claims.

Claims (6)

(a) receiving, by a user, material data for each component of an indoor and environmental element data of the interior of the building to be evaluated for pollution degree; (b) extracting a pollutant discharge value according to the received material data from a database of pollutant emission values for each material; (c) calculating a pollution degree evaluation value of the interior of the building by reflecting the received environmental element data in the pollutant discharge value; Indoor pollution degree calculation method comprising a. The method of claim 1, The indoor pollution degree evaluation value is calculated as a concentration value of at least one or more of the volatile organic compounds and formaldehyde in the room. The method according to claim 1 or 2, The indoor component of the indoor pollution degree calculation method comprising at least one of the interior wall, ceiling, floor, opening of the room. The method according to claim 1 or 2, The environmental element data, indoor pollution degree calculation method comprising at least one of the size of the interior of the building and room temperature, indoor humidity, azimuth, ventilation amount and weather conditions data. The method according to claim 1 or 2, And the material database is classified according to at least one criterion of a material used part, a use, and a manufacturing company. A recording medium on which a computer-readable program is recorded, which records a program for performing the indoor pollution degree calculation method according to claim 1.

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