KR101983600B1 - Experimental apparatus and experimental method for measuring indoor and outdoor penetration coefficient of airborne - Google Patents

Abstract

More particularly, the present invention relates to an experimental apparatus and an experimental method for measuring indoor and outdoor penetration coefficients of airborne particulates. The apparatus includes a large cabin, a gap, a fuming device, an airflow mixing system, a pressure difference control system, a particulate test device, an on / humidity controller, and a filter. Large cabins are used to simulate indoor and outdoor environments, both connected through a gap mechanism. The fuming device is an aerosol generator and the particulates use ISO standard dust. Since the pressure difference controller is composed of a vacuum pump, control valve, micro-pressure gauge and flow meter, it is possible to precisely control the pressure difference on both sides of the gap. The device allows simulations of particulate indoor and outdoor penetration coefficients under various conditions (temperature / humidity, pressure difference, particle size, gap conditions) in a laboratory environment. In the application process, it is possible to set the various coefficients according to the specific requirements, to obtain the penetration coefficient under the corresponding conditions, to have easy and simple control, to change many coefficients, and to save human and physical assets .

Description

TECHNICAL FIELD The present invention relates to an apparatus and method for measuring indoor and outdoor penetration coefficients of airborne particulates,

More particularly, the present invention relates to an experimental apparatus and an experimental method for measuring indoor and outdoor penetration coefficients of airborne particulates.

In recent years, as China's airborne particulate contamination has become more severe, particulate contamination has become the most important contaminant in many China's metropolitan air quality environments. In modern society, people spend most of their time indoors, most of which are caused by outdoor particulates. Many pollutants of outdoor microparticles are pollutants that occur in traffic, industry, and life, which permeate the room through a gap in the ventilation or the surrounding structure, pollute the indoor environment and affect the health of indoor people. Epidemiological studies have shown that exposure to particulates, regardless of their exposure time, has a negative effect on many human systems. According to studies on indoor and outdoor pollutant relations, the concentrations of particulate mass penetrated into the indoor environment and the concentrations of suspended air particulates in outdoor are at the same level. It can be seen that atmospheric particulates are an important source of indoor particulate matter. Therefore, the study on the indoor and outdoor penetration coefficient of airborne particulate matter is very meaningful in reality.

Penetration coefficients represent the ability of particulates to penetrate the structure envelope. Current research methods include field tests and laboratory tests. Since field tests are conducted on specific buildings or rooms, there is no universality in testing, the influence of environmental factors on the test subject is very large, and the variation of experimental results is large, so that the influence of specific factors on penetration factors can not be secured. Laboratory testing is to measure the indoor and outdoor penetration coefficient of particulates under laboratory conditions. The coefficients used in the test process mainly include the pressure difference on both sides of the gap, the gap size, the gap roughness, the particle size, and the temperature / humidity. Before starting the experiment, select appropriate gap size and roughness, adjust the pressure difference on both sides of the temperature / humidity, gap according to specific requirements, and measure the result after completely discharging the fine particles. Compared to field tests, laboratory tests can measure penetration coefficients under various working conditions in a laboratory, control various conditions, convert the combinations according to actual requirements, There is an advantage that the influence can be considered. Currently, there are researchers in Korea who use laboratory to measure penetration coefficient, but there are still following disadvantages in the experiment. 1) Particulate supply selection: Participants use mosquitoes and tobacco-generated microparticles, and 95% of microparticles emitted from cigarettes are ultrafine (d <100nm) ). This is not consistent with the airborne particle size distribution, so this type of source can not simulate an accurate airborne particle size distribution. (2) The pressure difference on both sides of the gap is only used to adjust the flow rate, but it is unknown whether the pressure difference on both sides can be monitored in real time and therefore predicted control effect. ③ The temperature / humidity condition can not be controlled because the effect of temperature / humidity on the penetration coefficient is ignored. The experimental apparatus can improve the controllability and accuracy of the test coefficients by adopting the optimized design to solve the above problem.

In order to facilitate the accurate measurement of the infiltration coefficient of the building in the laboratory, the present invention proposes an experimental apparatus and an experimental method for measuring the indoor and outdoor infiltration coefficient of airborne fine particles. It combines all the coefficients (pressure differential, gap conditions, particle size, temperature / humidity, etc.) that affect the penetration coefficient and allows the penetration coefficient to be measured under various working conditions based on precise control of all the coefficients .

The present invention adopts the following technique. The present invention relates to an experimental apparatus for measuring indoor and outdoor penetration coefficients of airborne particulates, which comprises a large cabin, a small cabin and a gap mechanism, fixing a small cabin and a gap mechanism to a large cabin with a plurality of long screws, Comprises a first plate (7a), a second plate and a gasket, the first plate and the second plate being joined to a small cabin and forming a complete body with a small cabin, the gap being located between the second plate and the gasket ; The first opening is connected to the aerosol generator through a soft tube, the fine particle mixing mechanism is suspended at the center of the top, the second opening is provided below the right side of the large cabin, The second opening is connected to the filter through a soft tube and the third opening is provided at the right side of the large cabin and at the height of the gap mechanism. One end of the flexible tube enters the large cabin through the third opening, And the other end is connected to the first particulate test apparatus, and a fourth rectangular opening is connected to the gap mechanism at the front of the large cabin. The particulates are introduced into the gap in the gap mechanism through the fourth opening, Is mounted in the middle of the large cabin floor; A fifth opening in the front of the small cabin and a fifth opening in communication with the pressure differential regulator through a soft tube, the pressure differential regulator comprising a vacuum pump, a flow meter, a control valve and an immersion gage, The control valve and the vacuum pump are connected in order through a flexible tube, the joint portion is sealed with a sealant, the sixth opening is provided on the side of the small cabin, one end of the flexible tube enters the small cabin through the sixth opening, And the other end thereof is connected to the second particulate test apparatus, and a seventh rectangular opening which is connected to the gap mechanism is provided inside the small cabin, and the two soft pipes of the micrometer system are provided with the eighth opening and the ninth opening Respectively, to the front and rear sides of the gap.

An experimental method for measuring the indoor and outdoor penetration coefficient of the atmospheric fine particles includes the following steps.

(a) Open the particulate mixing mechanism and strengthen the airflow mixing in the large cabin.

(b) Adjust the temperature / humidity. Open the temperature / humidity controller and set the experimental temperature. If the air temperature in the large cabin is lower than the set value, the heating system is activated to raise the temperature. In the opposite case, the cooling system is operated to cool down. The humidity control range of the regulator is 40 to 100% RH, and the slope is 5% RH, so the humidity setting range is 40 to 100%. When the humidity reaches the set point and the temperature ripple value is less than 0.1 ℃ and the relative humidity ripple value is less than 2% RH, the temperature / humidity control is completed.

(c) Adjust the pressure difference on both sides of the gap. The pressure difference control is regulated through the flow rate and then monitored again with the pressure meter to reach the preset value by finely adjusting the pressure difference. The pressure difference interval on both sides of the gap is 4 to 10 Pa. After selecting the pressure difference, proceed with the vacuum pump operation and measure the gas flow rate extracted by the flowmeter. If the flow rate is larger than the set flow rate, the opening degree of the control valve is lowered. If the flow rate is smaller than the set flow rate, the opening degree of the control valve is increased to make the flow rate equal to the set value. The pressure difference on both sides of the gap is monitored by the unipolar system. When the flow rate on both sides of the gap reaches the set value, the pressure difference on both sides of the gap reaches the set value. When the pressure difference reaches the set value, the pressure difference adjustment operation is terminated.

(d) After the temperature / humidity and pressure control are completed, the fine particles are fired by the aerosol generator, and the fine particles rapidly spread under the action of the particulate mixing mechanism. Due to the pressure differential across the gap, the particulates enter the large cabin through the gap into the small cabin.

(e) When the particulates are uniformly mixed in a large cabin after releasing the particulate matter for a certain period of time, the first particulate test apparatus and the second particulate test apparatus are simultaneously opened to measure the concentration of particulates on both sides of the gap. The sample is taken every minute, and the result of each measurement is taken as the average value of the concentration of the particles within 1 minute.

Advantageous effects of the present invention are as follows.

1. Experimental apparatuses for measuring indoor and outdoor penetration coefficients of the above-mentioned airborne particulates include a large cabin, a gap, a fuming device, an air flow mixing system, a pressure difference control system, a particulate testing device, a temperature / humidity controller, It is possible to simulate the particulate indoor and outdoor penetration coefficient under various conditions (temperature / humidity, pressure difference, particle diameter, gap condition).

2. Large cabins are used to simulate indoor and outdoor environments, both of which are connected through a gap mechanism and can accurately simulate the shape of the infiltration path where particulates enter the room from the outdoor environment.

3. Because the fuming device is an aerosol generator and the fine particles use ISO standard dust, the compatibility with the particulate particle size that can be absorbed in the atmosphere is relatively high.

4. Since the pressure difference controller is composed of vacuum pump, control valve, pressure gauge and flow meter, it is possible to precisely control the pressure difference on both sides of the gap.

5. In the application process, it is possible to set the various coefficients according to the specific requirements, to obtain the penetration coefficient under the corresponding condition, to control easily and easily, to change many coefficients, and to save human and physical assets Have.

1 is a system explanatory view of an experimental apparatus for measuring indoor and outdoor penetration coefficients of airborne fine particles; And
2 is a structural view of the gap mechanism.

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

Fig. 1 shows an experimental apparatus for measuring indoor and outdoor penetration coefficients of airborne fine particles. In the figure, an experimental apparatus for measuring indoor and outdoor penetration coefficients of airborne particulates includes a large cabin 1, a small cabin 2 and a gap mechanism 7, and a small cabin 2 is provided with a plurality of long screws 10, And the gap mechanism (7) are fixed to the large cabin (1). The gap mechanism 7 includes a first plate 7a, a second plate 7b and a gasket 7c and the first plate 7a and the second plate 7b are joined to a small cabin 2 And forms a complete body with the small cabin 2, and the gap 7d is located between the second plate 7b and the gasket 7c. A first opening 1a is provided at the center of the top end of the large cabin 1 and the first opening 1a is connected to the aerosol generator 3 through a soft tube and a fine particle mixing mechanism 4 is installed at the center of the top The second opening 1b is connected to the filter 5 through the flexible pipe and the right side of the large cabin 1 and the gap mechanism 7 And one end of the soft tube enters the large cabin 1 through the third opening 1c and is fixed to the center of the front side of the gap 7d, 1 fine particle test apparatus 6 and a rectangular fourth opening 1d connected to the gap mechanism 7 is provided on the front surface of the large cabin 1 and the fine particles are passed through the fourth opening 1d to the gap mechanism 7, and the temperature / humidity regulator 8 is mounted in the middle of the floor surface of the large cabin 1. A fifth opening (2a) is provided in front of the small cabin (2), and the fifth opening (2a) is connected to the pressure difference regulator through a soft tube. The pressure difference regulator includes a vacuum pump 9, a flow meter 9a, a control valve 9b and a micromanipulator 11 wherein the flow meter 9a, the control valve 9b and the vacuum pump 9 The joint portion is sealed with a sealant and the sixth opening 2b is provided on the side of the small cabin 2 and one end of the soft tube is connected to the small cabin 2b through the sixth opening 2b, 2) and fixed to the center of the rear side of the gap 7d and the other end is connected to the second particulate test apparatus 6a and is connected to the gap mechanism 7 inside the small cabin 2, And the two soft tubes of the micro-pressure gauge 11 are fixed to the front side and the rear side center of the gap 7d via the eighth opening 1e and the ninth opening 2d, respectively.

An experimental method for measuring the indoor and outdoor penetration coefficient of the atmospheric fine particles includes the following steps.

(a) opening the particulate mixing mechanism 4 and enhancing the airflow mixing in the large cabin 1;

(b) Adjust the temperature / humidity. When the temperature of air in the large cabin 1 is lower than the set value, the heating / heating system is operated to raise the temperature / humidity controller 8, and in the opposite case, the cooling system is operated to cool down. The humidity control section is 40 to 100% RH, and the slope is 5% RH. When the humidity reaches the set point and the temperature ripple value is less than 0.1 ℃ and the relative humidity ripple value is less than 1% RH, the temperature / humidity control is completed.

(c) Adjust the pressure difference on both sides of the gap. The pressure difference control is first adjusted through the flow rate and then monitored again by the micro-pressure gauge (11) to reach the set value by finely adjusting the pressure difference. The operation of the vacuum pump 9 is carried out, and the gas flow rate extracted by the flow meter 9a is measured. If the flow rate is larger than the set flow rate, the opening degree of the control valve 9b is lowered. If the flow rate is smaller than the set flow rate, the opening degree of the control valve 9b is increased to make the flow rate equal to the set value. The pressure difference on both sides of the gap is monitored by the micro-pressure gauge 11, and when the flow rate of both sides of the gap reaches the set value, the pressure difference between both sides of the gap reaches the set value. When the pressure difference reaches the set value, the pressure difference adjustment operation is terminated.

(d) After the temperature / humidity and pressure control are completed, the fine particles are fired by the aerosol generator, and the fine particles rapidly spread under the action of the particulate mixing mechanism. Due to the pressure differentials on both sides of the gap, the particulates penetrate through the gap from the large cabin to the small cabin 2.

(e) the particulates are discharged for a certain period of time and mixed uniformly in a large cabin, and then the first particulate test apparatus 6a and the second particulate test apparatus 6b are simultaneously opened. The sample is taken every minute, and the result of each measurement is taken as the average value of the concentration of the particles within 1 minute.

In adopting the above technique, a large cabin is used to simulate an outdoor atmospheric environment in connection with a fuming device, and a small cabin is used to simulate an indoor environment, and the two are connected via a gap mechanism. An airflow mixing device is installed at the center of the large cabin top to be used for mixing particulates in the cabin. The pressure difference controller is connected to one side of the small cabin and flows air in both cabins through the air pump after operation. The on / humidity controller is located in the center of the large cabin. The penetration coefficient is obtained by detecting the mass concentration of both the fine particles in the gap in the particulate tester after the air streaming device fires the particulate matter under a constant temperature / humidity and gap condition.

The large cabin size is length x width x height 50cm x 50cm x 40cm and volume 0.1m3. There are mainly two factors considered in the size design. 1. Experiments can be carried out only when the concentration of fine particles in a large cabin reaches a certain level in the experiment. Therefore, a space of 0.1 m 3 larger than the large space can quickly reach the prescribed concentration of the fine particles. 2. With a volume of 0.1 m3, it is possible to simplify the calculation of the experimental results, provided that the experiment meets the conditions to operate in the space. The size of the small cabin is length x width x height 25cm x 4cm x 10cm and the volume is 0.001m3, which increases the convenience of calculation and operation. Seal the joints on each side of the cabin with a special sealant to prevent air leakage.

The large cabin and the small cabin are connected through a gap mechanism, the gap mechanism is inserted into a small cabin, the small cabin is connected to the large cabin through a long screw, and the long screw is disassembled to replace the gap. The gap can be separated and replaced, and the experiment can determine the gap size according to actual demand. Gap material changes its roughness using aluminum alloy, brick, concrete, plywood, red cedar, pine, particle board and so on. The gap is composed of upper and lower plates and gaskets. The gap material is selected to have a uniform roughness, and the length and width are sheared in a predetermined size. Then, the gap is pushed between the two plates, and the gap height is adjusted by the number of gaskets. The gasket thicknesses are 0.1mm, 0.25mm, 0.5mm, and 1mm, respectively.

The fuming device uses an aerosol generator and ISO standard dust (A1), which can simulate very good atmospheric adsorbable particulates because the particulate below 10 PM accounts for more than 97%. A fume inlet is installed at the top of the large cabin, connected with an aerosol, and the standard dust is uniformly transported through the aerosol generator into the large cabin. Before the particulate enters, the airflow mixing device located at the center of the large cabin top opens and airflow mixing is accelerated.

The particulate mixing mechanism is located at the center of the top of the large cabin and mainly plays the following two roles. 1. The particulates open before entry to accelerate airflow mixing. 2. After the particulates have fired and entered, they are quickly and uniformly distributed within the large cabin.

The pressure difference controller consists of a vacuum pump, a control valve, a pressure gauge, and a flow meter. According to the ASHER standard, since the indoor and outdoor pressure difference ranges from 4 to 10 pa, the pressure difference on both sides of the gap is controlled to 4 to 10 pa. The vacuum pump is connected to the small cabin through a pipe and the gas is flowed through the air extraction in the cabin, and the flow meter can indicate the flow rate value through which the airflow passes on both sides of the gap. The pressure gauge can measure the pressure difference on both sides of the gap. If there is a gap between the pressure difference and the set value, the pressure difference reaches the set value by changing the vacuum pump flow rate through the control valve.

The particulate testing device employs two TSI particulate counters, each of which is used to test the concentration of particulates on both sides of the gap. The on / humidity controller is used to control the temperature / humidity in the experiment. The temperature / humidity of the cabin can be adjusted to the set value and then the test can proceed. Once a group of experiments is completed, the next group test can be performed if the temperature / humidity is changed and stabilized.

The filter is used to filter the adsorbable particulate in the air entering the air inlet of the large cabin, ensuring that the aerosol generator is the only particulate source.

1: large cabin 1a: first opening
1b: second opening 1c: third opening
1d: fourth aperture 1e: eighth aperture
2: small cabin 2a: fifth opening
2b: sixth opening 2c: seventh opening
2d: ninth opening 3: aerosol generator
4: particulate mixing mechanism 5: filter
6: first particulate test apparatus 6a: second particulate test apparatus
7: Gap mechanism 7a: First plate
7b: second plate 7c: gasket
7d: gap 8: temperature / humidity controller
9: Vacuum pump 9a: Flow meter
9b: Control valve 10: Long screw
11:

Claims (2)

A small cabin 2 and a gap mechanism 7 are fixed to a large cabin 1 by a plurality of long screws 10 including a large cabin 1, a small cabin 2 and a gap mechanism 7, The gap mechanism 7 includes a first plate 7a, a second plate 7b and a gasket 7c. The first plate 7a and the second plate 7b are connected to a small cabin 2 And forms an integral body with the small cabin 2, the gap 7d being located between the second plate 7b and the gasket 7c; A first opening 1a is provided at the center of the upper end of the large cabin 1 and the first opening 1a is connected to the aerosol generator 3 through a soft tube and a fine particle mixing mechanism 4 And the second opening 1b is connected to the filter 5 through a soft tube and the second opening 1b is connected to the right side of the large cabin 1, , The third opening 1c is provided at the height position of the gap mechanism 7 and one end of the soft tube enters the large cabin 1 through the third opening 1c and is fixed to the center of the front side of the gap 7d And the other end is connected to the first particulate test apparatus 6 and a rectangular fourth opening 1d connected to the gap mechanism 7 is provided on the front surface of the large cabin 1. The particulates are introduced into the fourth opening 1d Into the gap 7d in the gap mechanism 7, and the temperature / humidity regulator 8 is mounted in the middle of the floor of the large cabin 1; A fifth opening (2a) is provided in front of the small cabin (2) and the fifth opening (2a) is connected to a pressure difference regulator through a soft tube. The pressure difference regulator is connected to a vacuum pump (9) The control valve 9b and the vacuum pump 9 are sequentially connected via a soft tube and the joint portion is sealed with a sealant 9a, a control valve 9b, and a micromanipulator 11. The flowmeter 9a, the control valve 9b, And a sixth opening 2b is provided on the side of the small cabin 2 so that one end of the flexible tube enters the small cabin 2 through the sixth opening 2b and is located at the center of the rear side of the gap 7d And the other end thereof is connected to the second particulate test apparatus 6a and a seventh rectangular opening 2c connected to the gap mechanism 7 is provided inside the small cabin 2, ) Are fixed to the front side and the rear side center of the gap (7d) through the eighth opening (1e) and the ninth opening (2d), respectively. Experimental apparatus for measuring penetration coefficient. An experimental method using an experimental apparatus for measuring indoor and outdoor penetration coefficients of the atmospheric fine particles of claim 1,
(A) opening the particulate mixing mechanism (4) and enhancing airflow mixing in the large cabin (1);
Adjust the temperature / humidity; If the air temperature in the large cabin 1 is lower than the predetermined value, the heating system is operated to raise the temperature. In the opposite case, the cooling system is operated to cool down ; The humidity control range of the regulator is 40 to 100% RH and the slope is 5% RH, so the humidity setting range is 40 to 100%. When the humidity reaches the set value, the temperature fluctuation value is lower than 0.1 캜 and the relative humidity fluctuation value (B) completing the temperature / humidity control when the temperature is lower than 2% RH;
Adjusting the pressure difference on both sides of the gap, adjusting the pressure difference through the flow rate, and then monitoring the pressure with the micro-pressure gauge (11) to finely adjust the pressure difference to reach the preset value; The pressure difference interval on both sides of the gap is 4 to 10 Pa, the vacuum pump 9 is operated after selecting the pressure difference, and the gas flow rate extracted by the flow meter 9a is measured; If the flow rate is larger than the set flow rate, the opening degree of the control valve 9b is lowered. If the flow rate is smaller than the set flow rate, the opening degree of the control valve 9b is increased to make the flow rate equal to the set value; The pressure difference on both sides of the gap is monitored by the micro-pressure gauge 11. When the flow rate of both sides of the gap reaches the set value, the pressure difference between both sides of the gap reaches the set value, (C) terminating the difference adjustment operation;
The particulates are rapidly diffused under the action of the particulate mixing mechanism 4 and the particulates are separated from the gap 7d due to the pressure difference on both sides of the gap, (D) through the large cabin (1) through the small cabin (2) through the second cabin (1);
The first particulate test apparatus 6a and the second particulate test apparatus 6b are simultaneously opened to measure the concentration of the particulates on both sides of the gap 7d when uniformly mixing the particulates in the large cabin 1 after releasing the particulates for a certain period of time (E) taking a sample every one minute, and taking a result of measurement as an average value of the concentration of particulate matter within one minute every minute.

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