KR101255192B1 - Reaction chamber with auto experimental equipment of pollutant for evaluating indoor air pollutant - Google Patents

Abstract

Two reaction chambers, similar to the actual measurement space, can be used to accurately predict the degree of contamination in a real room, to monitor the decontamination process of a contaminant very reliably, and to control or remove contaminants. There is provided an automatic pollutant test apparatus having a reaction chamber for pollutant experiments capable of confirming the removal efficiency of functional materials. First and second reaction chambers each having a pollutant detecting unit and a pollutant venting unit to perform an experiment for detecting and removing the pollutant; First and second reaction chamber controllers installed outside the reaction chamber to control the reaction chamber; First and second pollutant generators connected to the reaction chamber controller, respectively, to generate pollutants introduced into the reaction chamber; And first and second contaminant input units connected to the reaction chamber controller, respectively, to introduce contaminants generated by the contaminant generating unit into the reaction chamber, wherein the first reaction chamber is installed after installing the contaminant removing unit. The experiment is performed in a state where the substance can be removed, and the second reaction chamber is characterized in that the experiment is performed while the pollutant is input without the pollutant removing unit installed.

Description

Reaction chamber for evaluation of indoor air quality with automatic test equipment for pollutants {REACTION CHAMBER WITH AUTO EXPERIMENTAL EQUIPMENT OF POLLUTANT FOR EVALUATING INDOOR AIR POLLUTANT}

The present invention relates to an indoor pollutant testing apparatus, and more specifically, to measure the concentration of indoor air pollutants such as microorganisms or harmful gases, and to control or remove indoor pollutants. It relates to an actual room-scale reaction chamber that can evaluate the actual decontamination performance for air cleaners, ventilation systems, low temperature plasmas) and functional materials (photocatalysts, phytoncides, etc.).

The reaction chamber according to the prior art is small in size and provides a constant limited experimental space to check how much contaminants such as microorganisms or harmful gases (toluene, etc.) are contained. The reaction chamber is conducted by detecting microorganisms or harmful gases in a confined space and detecting them. In this case, the experiment is conducted in a very limited space. You can get it.

However, these experimental results are too large to be considered to be the same as the measured results, and there is a limitation of the experimental results in comparing and predicting the degree of contamination in the actual room.

In addition, it is difficult to trust the test results because the method of injecting microorganisms or harmful gases into the reaction chamber which is a pollution reduction performance test body, the method of recovering microorganisms or harmful gases from the reaction chamber, and the method of venting the reaction chamber are not constant. There was this.

1) Republic of Korea Patent No. 10-0523560 (filed April 11, 2003), the title of the invention: "Contaminant collection device and method for measuring contaminants" 2) Republic of Korea Patent No. 10-0524344 (application date: January 19, 2004), the title of the invention: "Laboratory apparatus for measuring harmful substances emitted from building materials" 3) Republic of Korea Patent No. 10-0525515 (Application Date: February 27, 2004), the title of the invention: "Tester for measuring harmful substances in construction materials" 4) Republic of Korea Patent No. 10-0764519 (application date: March 03, 2006), the title of the invention: "large chamber type pollutant release material testing device" 5) Republic of Korea Patent No. 10-0688249 (application date: April 06, 2005), the title of the invention: "apparatus and method for treating odor and harmful air pollutants"

The technical problem to be solved by the present invention to solve the above-mentioned problems, the indoor air quality with an automatic pollutant experiment apparatus for accurately predicting the degree of contamination of the actual room using two reaction chambers similar to the measurement space It is to provide a reaction chamber for performance evaluation.

Another technical problem to be solved by the present invention is to monitor the decontamination process of contaminants very reliably, to control or remove contaminants (air cleaners, ventilation systems, low temperature plasma) and functional materials It is to provide a reaction chamber for evaluating the performance of indoor air quality equipped with an automatic test device for pollutants that can confirm the removal efficiency of (photocatalyst, phytoncide, etc.).

As a means for achieving the above-described technical problem, the reaction chamber for indoor air quality performance evaluation equipped with the automatic pollutant experiment apparatus according to the present invention, the microorganism and / or pollutant gas contaminants are introduced, and detecting and First and second reaction chambers each having a contaminant detecting unit and a contaminant ventilation unit so as to perform an experiment for removing the contaminant; First and second reaction chamber controllers disposed outside the first and second reaction chambers, respectively, to control the first and second reaction chambers; First and second pollutant generators connected to the first and second reaction chamber controllers, respectively, to generate pollutants introduced into the first and second reaction chambers; And first and second contaminant input units connected to the first and second reaction chamber controllers, respectively, to introduce contaminants generated by the first and second contaminant generating units into the first and second reaction chambers. Including, but the first reaction chamber is installed in the state in which the contaminant removal unit after the contaminant can be removed and the experiment proceeds, the second reaction chamber is not installed the contaminant removal unit in the state in which the contaminant is added Characterized in proceeding with the experiment.

Here, it is confirmed how much actual pollutants are removed by the pollutant removing unit in the first reaction chamber in which the pollutant removing unit is installed, and how much is naturally removed in the second reaction chamber in which the pollutant removing unit is not installed. By checking whether it is possible, the efficiency of the pollutant removal unit can be grasped.

Here, the first and second contaminant input unit, respectively, microbial contaminant input unit for introducing microbial contaminants into the first and second reaction chamber, respectively; And a contaminant input unit for contaminant gas for introducing contaminant gas contaminants into the first and second reaction chambers, respectively.

The microbial contaminant input unit may include a microbial measuring cylinder on which microorganisms are introduced into the first and second reaction chambers; A microorganism inlet tube formed to extend downward from a central upper surface of each of the first and second reaction chambers and connected to the microorganism measuring cylinder; And a microbial injection nozzle which is formed at an end of the microbial inlet tube and sprays the microorganism into the first and second reaction chambers.

The reaction chamber for evaluating indoor air quality having the automatic pollutant test apparatus according to the present invention includes first and second reaction chambers respectively introduced into the first and second reaction chambers to collect microorganisms introduced through the microorganism contaminant input unit. 2 may further include a microorganism collecting device.

Here, each of the first and second microorganism collecting device, the culture medium plate is cultured the microorganisms introduced through the microorganism contaminant input unit; And it may include an adjustment unit for adjusting the initial culture conditions and time of the microorganism.

Here, each of the first and second reaction chambers may further include a collecting device input unit for introducing the first and second microorganism collecting devices into the first and second reaction chambers, respectively.

Here, the collecting device input unit, the input box is formed to extend from the first and second reaction chamber, respectively, so that the microorganism collecting device can be introduced into the first and second reaction chamber, respectively; A shelf formed in the input box and mounted with the microorganism collecting device; And a foldable extension for pushing the shelf equipped with the microorganism collecting device into the first and second reaction chambers.

Here, the first and second contaminant generating unit, respectively, the microorganism generating unit for generating microorganisms to be put into the first and second reaction chamber, respectively; And a pollutant gas generating unit configured to generate pollutant gases to be introduced into the first and second reaction chambers, respectively.

Here, the polluting gas generating unit may be provided by vaporizing the polluting gas source provided in the liquid state to the gaseous polluting gas.

Here, the pollutant input unit for the pollutant gas may include a supply port communicating with each other so that the pollutant gas provided through the first and second pollutant gas generating units may be provided in the first and second reaction chambers; And it may include a rotary injection device for injecting the contaminated gas provided through the air supply in the first and second reaction chamber.

Herein, the first and second reaction chambers may initialize the inside of the first and second reaction chambers by operating the pollutant ventilation unit and the ultraviolet rays when the final experiment is completed.

Here, each of the first and second reaction chambers may further include an air purifier configured to purify the polluted gas ventilated from the pollutant ventilator and discharge it to the outside of the first and second reaction chambers.

The first and second reaction chambers may include observation windows for visually confirming the inside of the first and second reaction chambers by an experimenter; And a microorganism experiment may further include a sunshade to block the external light flowing into the observation window.

The reaction chamber for evaluating the indoor air quality having the automatic pollutant test apparatus according to the present invention includes the amount of microorganisms and the amount of microorganisms collected by recovering the first and second microorganism collecting devices from the first and second reaction chambers. Comparing with each other may further include a microbial change measurement unit for confirming the efficiency of the contaminant removal unit.

According to the present invention, two reaction chambers similar to the measurement space can be used to accurately predict the degree of contamination of the actual room.

According to the present invention, it is possible to reliably monitor the decontamination process of contaminants such as microorganisms or harmful gases, and to control or remove contaminants (air cleaners, ventilation systems, low temperature plasma) and functionalities. The removal efficiency can be confirmed for the material (photocatalyst, phytoncide, etc.). Based on this, competitive products and functional materials can be developed.

1 is a configuration diagram of a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an embodiment of the present invention.
2 is a view for explaining the operation when the pollutant is a microorganism in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.
3 is a view for explaining the operation when the pollutant is a pollutant gas in the indoor air quality performance evaluation chamber equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.
4 is a front view of the first and second reaction chamber for contaminant experiments according to an embodiment of the present invention.
5 is a plan view of the first and second reaction chamber for the pollutant experiment according to an embodiment of the present invention.
6a and 6b is a view showing before and after the microorganism collecting device is introduced into the contaminant experiment reaction chamber according to an embodiment of the present invention.
7A and 7B are views illustrating the observation window and the awning film of the reaction chamber for the pollutant experiment in accordance with an embodiment of the present invention.
8 is a photograph showing a microbial measuring cylinder in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an embodiment of the present invention.
9 is a photograph showing a microorganism collecting device in a reaction chamber for evaluating indoor air quality having an automatic pollutant testing device according to an embodiment of the present invention.
10 is a photograph showing a contaminant input unit for microorganisms in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an exemplary embodiment of the present invention.
11 is a photograph showing a contaminant input unit for a pollutant gas in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an exemplary embodiment of the present invention.
12 is a photograph showing a pollutant gas generating unit in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an exemplary embodiment of the present invention.
13 is a photograph showing a microorganism change measurement unit in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an embodiment of the present invention.
14 is a photograph showing a display screen of a reaction chamber controller in a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an exemplary embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a configuration diagram of a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the reaction chamber for evaluating indoor air quality having the automatic pollutant test apparatus according to an embodiment of the present invention includes first and second reaction chambers 110 and 120, and first and second pollutants. The input unit 120 and 220, the first and second pollutant generating units 130 and 230, and the first and second reaction chamber controllers 140 and 240 are included. In this case, the first and second reaction chambers 110 and 120 include pollutant detectors 111 and 211 and pollutant ventilators 112 and 212, respectively. 1 is formed only in the reaction chamber 110.

The reaction chamber for evaluating indoor air quality with the automatic pollutant test apparatus according to the embodiment of the present invention includes two first and second reaction chambers 110 and 210, and each reaction chamber 110 and 210. Are each manufactured and installed in the same size as the actual room, and the microorganisms and / or pollutant gas pollutants are introduced, and the pollutant detection units 111 and 211 and the pollution are performed so that an experiment for detecting and removing the pollutants is performed. Material vents 112 and 212 are provided respectively.

After the first reaction chamber 110 is installed with the contaminant removal unit 113, the experiment is performed in a state capable of removing the introduced microorganism and / or contaminant gas, and the second reaction chamber 210 is the contaminant. The experiment is conducted with the microorganisms and / or contaminated gas injected without the removal unit installed. In this case, in the case of the first reaction chamber 110 in which the contaminant removing unit 113 is installed, it is possible to check how much the actual contaminant has been removed by the contaminant removing unit 113. Also, the contaminant removing unit In the case of the second reaction chamber 210 in which the 114 is not installed, it is possible to check how contaminants can be naturally removed. In this case, the contaminant removing unit 113 installed in the first reaction chamber 110 may include, for example, a contaminant removing agent such as a fan, an ultraviolet sterilizer, and a phytoncide.

In addition, each of the first and second reaction chambers 110 and 210 may include pollutant detection units 111 and 211 and pollutant ventilation units 112 and 212, respectively, and may detect and vent pollutants. .

The pollutant detectors 111 and 211 may be used to measure the amount of conventional pollutants, and may be, for example, gas sensors. Specifically, the pollutant detection unit 111 and 211 measures the amount of pollutant introduced into the first and second reaction chambers 110 and 210, respectively, and the first and second reaction chambers 110 and 210. After measuring the amount of the contaminants remaining in the, by comparing the measured values with each other, it is possible to determine the efficiency of the contaminant removing unit 113.

Since the pollutant vents 112 and 212 are mixed with various pollutants in the first and second reaction chambers 110 and 210 after the experiment, the first and second reaction chambers may be used for further experiments. 110, 210) should be initialized. In order to initialize the first and second reaction chambers 110 and 210, a contaminant removing unit 113 such as a fan, an ultraviolet sterilizer, and a contaminant removing agent is used.

The first and second pollutant input units 120 and 220 are connected to the first and second reaction chamber controllers 140 and 240, respectively, and are generated by the first and second pollutant generators 130 and 230. The contaminated material is introduced into the first and second reaction chambers 110 and 210. For example, contaminants are introduced into the first and second reaction chambers 110 and 210 in a limited manner such as a few PPMs per cubic meter. In addition, the first and second contaminant input unit (120, 220), respectively, the microorganism contaminant input unit (120a) for introducing the microorganism contaminant into the first and second reaction chamber (110, 210), respectively ; And a contaminant input unit 120b for contaminant gas injecting contaminant gas contaminants into the first and second reaction chambers 110 and 210, respectively.

The first and second pollutant generators 130 and 230 are connected to the first and second reaction chamber controllers 140 and 240, respectively, and are introduced into the first and second reaction chambers 110 and 210. Produces substances, ie microorganisms and / or pollutants.

The first and second reaction chamber controllers 140 and 240 are installed outside the first and second reaction chambers 110 and 210, respectively, to control the first and second reaction chambers 110 and 210.

The first and second reaction chambers may include observation windows for visually confirming the inside of the first and second reaction chambers 110 and 210 by the experimenter, and external light introduced into the observation windows during the microbial experiment. It may further comprise a sunshade to block.

The reaction chamber for evaluating the indoor air quality with the automatic pollutant test apparatus according to the embodiment of the present invention basically manufactures a limited space as an actual measurement space, and injects microorganisms and gases that may cause actual pollution into the space. After that, by installing the contaminant removal unit and the ventilation unit that can remove it close to the actual measurement it can be confirmed whether the contamination in the more reliable space.

On the other hand, the pollutants in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention may be a microorganism or harmful gas, these microorganisms or harmful gases are generated, injected, detected differently And removed. Hereinafter, an experiment in the reaction chamber will be described for each of microorganisms and harmful gases with reference to FIGS. 2 and 3.

2 is a view for explaining the operation when the pollutant is a microorganism in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.

Referring to FIG. 2, when the pollutant is a microorganism, the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an exemplary embodiment of the present invention may include a pollutant removing unit 113 having a first reaction chamber ( Except for being installed in the 110, since the configuration and operation of the first and second reaction chambers 110 and 210 are substantially the same, the case of the first reaction chamber 110 will be described.

First, the first contaminant input unit 120 described above includes a microbial contaminant input unit 120a for injecting microbial contaminants into the first reaction chamber 110, respectively. At this time, the microbial contaminant input unit 120a includes a microbial measurement cylinder 121a, a microbial input tube 122a, and a microbial injection nozzle 123a.

The microorganism measuring cylinder 121a is loaded with microorganisms introduced into the first reaction chamber 110, and the microorganism injection tube 122a extends downward from a central upper surface of each of the first reaction chambers 110. And a microbial injection nozzle 123a is formed at an end of the microbial injection tube 122a to inject the microorganism into the first reaction chamber 110.

In addition, the reaction chamber for evaluating the indoor air quality with the automatic pollutant experiment apparatus according to the present invention, respectively, in the first reaction chamber 110 to collect the microorganisms introduced through the microorganism contaminant input unit (120a) The first microorganism collecting device 150 is further included.

Here, the first microorganism collecting device 150, respectively, the culture medium plate 151 is cultured the microorganisms introduced through the contaminant input unit for the microorganism, and the adjusting unit 152 for adjusting the initial culture conditions and time of the microorganisms It may include.

In addition, each of the first reaction chambers 110 further includes a collecting device input unit 160 for introducing the first microorganism collecting device 150 into the first reaction chamber 110. At this time, the collection device input unit 160, the input box 161, the shelf 162 and the folding extension portion 163.

The input box 161 is formed to extend from the first reaction chamber 110, respectively, so that the microorganism collecting device 150 can be introduced into the first reaction chamber 110, respectively, the shelf 162 Is formed in the input box 162 and the microorganism collecting device 150 is mounted. In addition, the folding extension part 163 is formed to be foldable so that the shelf 162 on which the microorganism collecting device 150 is mounted can be pushed into the first reaction chamber 110.

In addition, the above-described first pollutant generating unit 130 includes a microorganism generating unit 130 for generating microorganisms to be introduced into the first reaction chamber 110, respectively.

The reaction chamber for evaluating indoor air quality with the automatic pollutant test apparatus according to the present invention includes the amount of microorganisms and the amount of microorganisms collected by recovering the first microorganism collecting device 150 from the first reaction chamber 110. Comparing with each other may further include a microbial change measuring unit for confirming the efficiency of the contaminant removal unit, will be described later with reference to FIG.

On the other hand, Figure 3 is a view for explaining the operation when the pollutant is a pollutant gas in the indoor air quality performance evaluation chamber equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.

Referring to FIG. 3, when the pollutant is a polluted gas, a reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an exemplary embodiment of the present invention may include a pollutant removing unit 113 having a first reaction chamber. Except for being installed in the 110, since the configuration and operation of the first and second reaction chambers 110 and 210 are substantially the same, the case of the first reaction chamber 110 will be described.

First, the above-described first pollutant input unit 120 includes a pollutant input unit 120b for polluting gas, which respectively introduces a pollutant gas pollutant into the first reaction chamber 110. At this time, the pollutant input unit 120b for the polluting gas includes an air supply 121b and a rotary injector 122b.

The air supply 121b communicates with the pollutant gas provided through the first polluting gas generating unit 130 so that the pollutant gas may be provided in the first reaction chamber 110. The pollutant gas provided through the air supply 121a is rotated and sprayed into the first reaction chamber 110.

In addition, the above-described first pollutant generating unit 130 includes a pollutant gas generating unit 130b for generating pollutant gases to be introduced into the first reaction chamber 110, respectively, and the polluting gas generating unit 130b. The gas may be provided by vaporizing the polluting gas source provided in the liquid state into the polluting gas in the gas state.

Specifically, the pollutant gas, for example, toluene gas that causes atopy may be used by purchasing pure toluene gas. Since such polluted gas is very expensive, the pollutant gas generating unit, which is a vaporization apparatus that can be manufactured in a gaseous state, 130a). That is, the liquefied polluted gas is vaporized through the polluted gas generating unit 130a serving as an evaporator, and the vaporized polluted gas is introduced through the air supply 121b provided in the first reaction chamber 110. At this time, the air supply 121b is connected to the rotary spray device 122b of the sprayer type installed on the upper surface of the first reaction chamber 110 and is introduced in such a manner that pollutant gas is injected into the first reaction chamber 110. Vaporized polluted gases will diffuse naturally.

The pollutant gas may be measured by measuring the amount of change by the pollutant removing unit 113 over time using the first pollutant detecting unit 111 pre-installed in the first reaction chamber 110 to confirm its efficiency. .

In addition, in the reaction chamber for evaluating the indoor air quality with the automatic pollutant testing device according to an embodiment of the present invention, the first reaction chamber 110, respectively, when the final experiment is completed, the pollutant ventilator 112 The inside of the first reaction chamber 110 may be initialized by operating and activating ultraviolet rays. In addition, each of the first reaction chambers 110 may further include an air purifier 214 that purifies the polluted gas ventilated from the pollutant ventilation unit 122 and discharges it to the outside of the first reaction chamber 110. It can be included as. That is, since the vaporized polluted gas remains in the first reaction chamber 110 over time, such polluted gas may be discharged to the outside through the first pollutant ventilator 112 and the air cleaner 114 Purify the polluting gas discharged to the outside by using).

On the other hand, Figure 4 is a front view of the first and second reaction chamber for the pollutant experiment according to an embodiment of the present invention, Figure 5 is a plan view of the first and second reaction chamber for the pollutant experiment according to an embodiment of the present invention.

4 and 5, the first and second reaction chambers 110 and 120 for experimenting with pollutants according to the exemplary embodiment of the present invention have two chambers (structures in the form of boxes) in contact with each other laterally. The doors 116 and 216 and the observation windows 115 and 215 are installed, respectively, so that the experimenter 300 can perform the experiment while checking the inside.

That is, the first and second reaction chambers 110 and 210 are each made of a structure such as a container box in which the inside and the outside are sealed, and the inner space is finished with a stainless finish to maintain cleanliness due to moisture. Corrosion can be prevented.

In addition, as illustrated in FIGS. 7A and 7B, the sunscreens 117 and 217 may be installed in the observation windows 115 and 215 to block light flowing from the outside.

Near the first and second reaction chambers 110 and 120, first and second pollutant generating units capable of generating desired pollutants are installed, respectively, and the air supply 121b in the first and second pollutant input units is installed. ), And control the progress of the experiment while controlling the degree of contamination in the first and second reaction chambers (110, 210) through the rotary injector and the contaminant ventilator 112, controlling the experimental environment such as temperature and humidity The first and second reaction chamber controllers are installed in front of the first and second reaction chambers, respectively.

6A and 6B are views illustrating before and after the microorganism collecting device is introduced into the pollutant experiment chamber according to an embodiment of the present invention.

In the reaction chamber for evaluating the indoor air quality with the automatic pollutant test apparatus according to the embodiment of the present invention, the microorganism collecting device is put into the first and second reaction chambers 110 and 120 under substantially the same conditions and operations. Therefore, the first microorganism collecting device 150 is introduced into the first reaction chamber 110 through the first collecting device input unit 160 by way of example.

FIG. 6A illustrates a state before the first microorganism collecting device 150 is introduced into the first reaction chamber 110 according to the embodiment of the present invention, and FIG. 6B illustrates the first reaction chamber 110 according to the embodiment of the present invention. Each after the first microorganism collecting device 150 is introduced into the container is shown.

As described above, the contaminants are largely divided into microorganisms and contaminant gases, and the contaminant input unit 120 may include a contaminant input unit 120a for microorganisms. In this case, the microorganism may be a harmful virus existing in the internal space of the first reaction chamber 110. Such microorganisms are those prepared for experiments, and in order to directly introduce the microorganisms into the first reaction chamber 110, the microorganism measuring cylinder 121a and the microorganism collecting device 150 are used in the first reaction chamber 110. do.

First, the microorganism measuring cylinder 121a is loaded with microorganisms introduced into the first reaction chamber 110, and the microorganism inlet tube 122a is downward from the central upper surface of each of the first reaction chambers 110. Is formed to extend, is connected to the microbial measuring cylinder, the microbial injection nozzle 123a is formed at the end of the microorganism injection tube 122a is injected into the first reaction chamber 110, the microorganisms do.

7A and 7B are views illustrating an observation window and a awning film of a reaction chamber for contaminant experiment according to an embodiment of the present invention.

In the contaminant experiment reaction chamber according to the embodiment of the present invention, the observation window 115 is formed as shown in FIG. 7A to allow the experimenter to check the inside of the reaction chamber. Also, as shown in FIG. 7B, the observation is performed. The sunscreen 117 may be installed on the window 115 to block light flowing from the outside. That is, since the amount of change of microorganisms may vary depending on the light flowing from the outside during the microbial experiment, the experiment is performed in a state in which light flowing from the outside is blocked.

On the other hand, Figure 8 is a photograph showing a microbial measuring cylinder in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.

Referring to FIG. 8, in the reaction chamber for evaluating indoor air quality having an automatic pollutant test apparatus according to an embodiment of the present invention, the microorganism measuring cylinder 121a is loaded with microorganisms that are introduced into the reaction chamber. The inlet tube 122a is formed to extend downwardly from a central upper surface of each of the first reaction chambers 110 and is connected to the microbial measuring cylinder, and the microbe injection nozzle 123a is the microbe inlet tube 122a. Is formed at the end of the injection to the microorganisms injected into the first reaction chamber (110).

On the other hand, Figure 9 is a photograph showing a microorganism collecting device in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant experiment apparatus according to an embodiment of the present invention, Figure 10 is an automatic pollutant experiment according to an embodiment of the present invention It is a photograph showing the contaminant input unit for microorganisms in the reaction chamber for indoor air quality performance evaluation equipped with a device.

Referring to Figure 9, the microorganism collecting device 150 is formed in a cylindrical box shape, the inside of the plate-shaped culture medium plate 151 of the plastic material that can be cultured microorganisms and the initial culture conditions of the microorganisms can be adjusted An adjusting unit 152 having a timer is provided.

Injecting the microorganism collecting device 150 into the first and second reaction chambers 110 and 210 directly by the experimenter may affect the experimental result, and thus, the collecting device inputting unit 160 may be provided in the embodiment of the present invention. Will be used. Referring to FIG. 10, a collecting device inlet box 161 that may extend to the first reaction chamber 110 is formed below the first reaction chamber control unit 140, and inside the inlet box 161. By using the shelf 162 on which the microorganism collecting device 150 is loaded and the folding extension 163 that can push the shelf 162 into the first reaction chamber 110, the microorganism collecting device 150 is It may be automatically added to the first reaction chamber 110.

Thereafter, the microorganism collecting device 150 operated by the timer is infiltrated with the microorganisms introduced into the first reaction chamber 110, is deposited in the culture solution on the culture plate 151, and subsequently, The change can be measured. Subsequently, as time passes, the microorganisms are changed by the pollutant removing unit 113, and when the degree of the changed microorganisms is collected by the microorganism collecting device 150, the microorganisms thus changed may be recovered. . That is, the microorganism collecting device 150 may be recovered by returning the folding extension part 163 constituting the collecting device feeding unit 160 back into the feeding box 161.

On the other hand, Figure 11 is a photograph showing the contaminant input unit for the pollutant gas in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention, Figure 12 is a pollution according to an embodiment of the present invention This is a picture showing the polluting gas generating unit in the reaction chamber for evaluating the performance of indoor air quality equipped with the automatic material testing device.

The pollutant input unit 120b for the pollutant gas in the indoor air quality performance evaluation chamber including the automatic pollutant test apparatus according to the embodiment of the present invention includes an exhaust port 121b and a rotary injection device 122b. As shown in FIG. 12, when the polluted gas vaporized through the polluting gas generating unit 130b is supplied through the exhaust port 121b, the rotary spray device 122b rotates and sprays the polluting gas into the reaction chamber.

On the other hand, Figure 13 is a photograph showing a microbial change measuring unit in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention.

The experimental procedure described above is controlled by the reaction chamber controller. Furthermore, the recovered microorganism collecting device 150 and the contaminant detecting unit 113 may check the final test result through separate procedures outside the first and second reaction chambers 110 and 210. For example, the microorganisms collected from the microorganism collecting device 150 recovered using the microbial change measuring unit 170 are collected and provided to a laboratory. The amount of microorganisms collected and the amount of microorganisms collected are checked to determine the efficiency of the contaminant removal unit 113.

That is, the microbial change measuring unit 170 in the reaction chamber for indoor air quality performance evaluation equipped with an automatic pollutant test apparatus according to an embodiment of the present invention is a microorganism collecting device from the first and second reaction chamber (110, 210) Each of the 150 may be recovered to compare the amount of the introduced microorganisms with the amount of the collected microorganisms to determine the efficiency of the contaminant removing unit 113.

In addition, the efficiency of the pollutant removal unit 113 may be confirmed by comparing the amount of the pollutant gas input by the pollutant detection units 111 and 211 and the amount of the detected pollutant gas.

Subsequently, when the final experiment is completed, the pollutant ventilators 112 and 212 installed in the first and second reaction chambers 110 and 210 are operated to ventilate, and the ultraviolet rays are operated to operate the first and second reagents. 2 Initialize the inside of the reaction chamber (110, 210).

On the other hand, Figure 14 is a photograph showing a display screen of the reaction chamber control unit in the reaction chamber for indoor air quality performance evaluation equipped with the automatic pollutant experiment apparatus according to an embodiment of the present invention.

The reaction chamber control unit according to an embodiment of the present invention controls the reaction chamber for evaluating the indoor air quality performance with the automatic pollutant experiment apparatus, as shown in FIG. It is possible to control the input into the chamber, to control the temperature and humidity in the two reaction chambers, and also to block the observation window by operating the sunscreen.

As a result, according to the reaction chamber for evaluating the indoor air quality with the automatic pollutant experiment apparatus according to the embodiment of the present invention, it is possible to accurately predict the degree of contamination of the actual room using two reaction chambers similar to the measurement space. It is possible to reliably monitor the decontamination process of contaminants such as microorganisms or harmful gases, and confirm the effectiveness of the decontaminant.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

110: first reaction chamber
210: second reaction chamber
120, 220: contaminant input unit
120a: Microbial contaminant input unit
120b: Pollutant input part for pollutant gas
130, 230: pollutant generating unit
130a: microorganism generation unit
130b: pollutant gas generating unit (vaporizer)
140, 240: reaction chamber control unit
150: first microorganism collecting device
160: collecting device input
170: microbial change measurement unit
111, 211: pollutant detection unit
112, 212: contaminant ventilation
113: pollutant removal unit
114, 214: Air Purifier
115, 215: observation window
116, 216: door
117: Awnings
121a: microbial measuring cylinder
122a: microbial input tube
123a: spray nozzle
121b: exhaust vent
122b: rotary jet
151: culture plate
152: adjustment unit
161: input box
162: shelf
163: folding extension

Claims (15)

First and second reaction chambers each including a contaminant detecting unit and a contaminant venting unit, to which microorganisms and / or contaminant gas contaminants are introduced and an experiment for detecting and removing the contaminants is performed;
First and second reaction chamber controllers disposed outside the first and second reaction chambers, respectively, to control the first and second reaction chambers;
First and second pollutant generators connected to the first and second reaction chamber controllers, respectively, to generate pollutants introduced into the first and second reaction chambers; And
A first and second contaminant input unit connected to the first and second reaction chamber controllers, respectively, for introducing contaminants generated by the first and second contaminant generating units into the first and second reaction chambers; But
After the first reaction chamber is installed with the contaminant removal unit, the experiment is performed in such a state that the contaminants can be removed. ,
The first and second contaminant input unit, respectively, the microbial contaminant input unit for introducing microbial contaminants into the first and second reaction chamber, respectively; And a contaminant input unit for contaminant gas for introducing contaminant gas contaminants into the first and second reaction chambers, respectively.
The microbial contaminant input unit may include a microbial measuring cylinder loaded with microorganisms introduced into the first and second reaction chambers; A microorganism inlet tube formed to extend downward from a central upper surface of each of the first and second reaction chambers and connected to the microorganism measuring cylinder; And a microbial spray nozzle which is formed at an end of the microbial inlet tube and sprays the microorganism into the first and second reaction chambers. chamber. The method of claim 1,
Check how much actual contaminants are removed by the contaminant removal unit in the first reaction chamber in which the contaminant removal unit is installed, and determine how naturally the contaminant removal is possible in the second reaction chamber in which the contaminant removal unit is not installed. The reaction chamber for evaluating the performance of the indoor air quality with the automatic pollutant experiment apparatus, characterized in that the efficiency of the pollutant removal unit is determined. delete delete The method of claim 1,
Evaluation of indoor air quality with an automatic pollutant testing device further comprising first and second microbial collecting devices respectively injected into the first and second reaction chambers to collect microorganisms introduced through the microbial contaminant input unit Reaction chamber. The method of claim 5, wherein the first and second microorganism collecting device, respectively
A culture plate in which the microorganisms introduced through the microorganism contaminant input unit are cultured; And
Adjusting unit for adjusting the initial culture conditions and time of the microorganism
Reaction chamber for indoor air quality performance evaluation with an automatic pollutant experiment apparatus comprising a. The method of claim 5,
The first and second reaction chambers, respectively, the indoor air quality having an automatic pollutant testing device further includes a collecting device input unit for introducing the first and second microorganism collecting device into the first and second reaction chamber, respectively. Reaction chamber for performance evaluation. The method of claim 7, wherein the collecting device input unit,
An input box extending from the first and second reaction chambers so as to respectively insert the microorganism collecting device into the first and second reaction chambers;
A shelf formed in the input box and mounted with the microorganism collecting device; And
Folding extension part for pushing the shelf equipped with the microorganism collecting device into the first and second reaction chamber
Reaction chamber for indoor air quality performance evaluation with an automatic pollutant experiment apparatus comprising a. The method of claim 1, wherein the first and second pollutant generating unit, respectively,
A microorganism generation unit generating microorganisms to be respectively introduced into the first and second reaction chambers; And
Polluted gas generating unit for generating polluted gas to be introduced into the first and second reaction chamber, respectively
Reaction chamber for indoor air quality performance evaluation with an automatic pollutant experiment apparatus comprising a. 10. The method of claim 9,
The pollutant gas generating unit is a reaction chamber for evaluating indoor air quality with an automatic pollutant testing device, characterized in that the pollutant gas source provided in the liquid state is provided by vaporizing the pollutant gas in the gas state. According to claim 1, The pollutant input unit for polluting gas, respectively,
An air supply port in communication with the first and second pollutant gas generators so that the polluted gas may be provided in the first and second reaction chambers; And
Rotary injection device for injecting the contaminated gas provided through the air supply in the first and second reaction chamber
Reaction chamber for indoor air quality performance evaluation with an automatic pollutant experiment apparatus comprising a. The method of claim 1,
Each of the first and second reaction chambers is equipped with an automatic pollutant testing device, characterized in that when the final experiment is completed, operating the pollutant ventilator and operating ultraviolet rays to initialize the inside of the first and second reaction chambers. Reaction chamber for indoor air quality performance evaluation. The method of claim 12,
Each of the first and second reaction chambers may further include an air purifier to purify the polluted gas ventilated from the pollutant ventilator and discharge it to the outside of the first and second reaction chambers. Reaction chamber for evaluation of indoor air quality. The method of claim 1, wherein the first and second reaction chambers, respectively,
Observation windows for visually confirming the inside of the first and second reaction chambers by an experimenter; And
Sunshade to block external light entering the observation window during microbial experiment
Reaction chamber for indoor air quality performance evaluation with an automatic pollutant experiment apparatus further comprising a. The method of claim 1,
Further comprising a microbial change measuring unit for recovering the first and second microorganism collecting device from the first and second reaction chamber to compare the amount of the introduced microorganisms and the amount of the recovered microorganisms with each other to confirm the efficiency of the contaminant removal unit. Reaction chamber for evaluating indoor air quality with automatic test equipment for pollutants.

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