KR102297416B1 - Deodorization device of multi-stage treatment method - Google Patents

Abstract

The present invention relates to a deodorization device of a multistage treatment method, in which supply of contaminated air is guided in the form of a vortex so that contact with a microbial culture solution and a drug is performed efficiently. According to the present invention, the deodorization device comprises: a polluted air supply pipe; a collecting unit spraying a microbial culture solution into contaminated air passing therethrough so that foreign substances adsorbed by a microbial reaction fall; a circulating water storage tank; a microbial processing unit; a first chemical processing unit; a second chemical processing unit; and a discharge port.

Description

Deodorization device of multi-stage treatment method

The present invention relates to a deodorizing device of a multi-stage treatment method, wherein the deodorization process using a microbial culture solution is subjected to two steps, and then the deodorization process is further performed two more steps through a chemical reaction using a chemical, It is a multi-stage deodorizing device that allows a total of 4 stages of deodorization process to be carried out by allowing different types of chemicals to be used, and the supply of contaminated air is guided in the form of a vortex so that contact with the microbial culture solution and chemicals is made efficiently. it's about

As the industry is advanced, a large amount of polluted air is generated in various factories, sewage treatment plants, excreta treatment plants, food treatment facilities, and livestock facilities. Since such polluted air is harmful to the human body as it produces a bad odor, it lowers the quality of life of people living in the vicinity of the facility and becomes the main culprit causing air pollution.

In order to treat the polluted air generated in this way, various methods or types of deodorization devices and deodorization facilities are being developed. As a method of removing the odor of the polluted air, there are methods using chemical cleaning, combustion, absorption, adsorption, oxidation, microorganisms, and the like.

Due to the nature of polluted air, it is difficult to remove odors with only one method, so that one deodorizing device is required to remove odors in various ways.

In particular, the flow of gas moves at a fairly high speed and does not react properly with the microbial reaction solution or chemical solution supplied to the inside of the deodorization tower, so there is a problem that the deodorization efficiency is lowered. In order to induce a proper reaction, there is only a way to increase the size of the deodorization tower, so there is a problem of cost and management difficulties due to equipment.

As a related prior art, Registered Patent No. 10-1502615 (deodorization device) includes an inlet chamber into which air containing odor gas is introduced; It is stacked on the upper part of the inlet chamber in multiple stages, and an odor discharge unit is installed on the floor so as to communicate with the lower layer, so that bad odors are introduced from the lower layer through the odor discharge unit, and a cleaning liquid spraying device is installed therein, and it flows through the odor discharge unit a plurality of cleaning chambers for sequentially cleaning and deodorizing the odor to be generated as it passes through each layer; and a plurality of cleaning liquid tanks in which cleaning liquids having different components are stored individually, each independently connected to the cleaning liquid spraying device installed in the cleaning chambers, and independently supplying the cleaning liquid to the cleaning liquid spraying device; a technology comprising a has been

However, the prior art consists of three stages and sprays different types of cleaning liquid, and the deodorization efficiency is lowered because the microbial reaction and the chemical reaction cannot be performed in a complex manner, and the air flow is made vertically in the reaction with the cleaning liquid. Therefore, there is a problem in that the reaction efficiency is lowered.

Korean Patent Registration No. 10-1502615

The present invention has been devised to solve the above problems, so that the deodorization process using a microbial culture solution is subjected to two steps, and then the deodorization process is further performed two more steps through a chemical reaction using a chemical. , it aims to provide a deodorizing device of a multi-stage treatment method that is configured so that different types of chemicals can be used, thereby increasing the efficiency of removing odors in a complex way.

Another object of the present invention is to increase the efficiency of removing odors by controlling the form of contaminated air supplied during the odor treatment process to be supplied while generating a vortex, so that the contact with the microbial culture solution and the drug is made efficiently.

The present invention relates to a contaminated air supply pipe to which contaminated air is supplied through a blower, and is coupled to the end of the contaminated air supply pipe so that the contaminated air passes in the lower direction, but the microbial culture solution is sprayed into the passing contaminated air to react and adsorb microorganisms A collecting unit for allowing foreign substances to fall, a circulating water storage tank in which the microbial culture solution formed at the lower end of the collecting unit and falling is recovered, and the microbial culture solution supplied from the external culture solution tank is filled to a certain level, and the circulating water storage It is formed on one side of the upper part of the tank and passes through the inside of the circulating water storage tank and the contaminated air moves upward and passes through the activated carbon filler containing the microbial culture solution, and the microorganism treatment unit is formed on the upper part of the microorganism treatment unit, and the biological reaction treatment is performed It includes a first chemical treatment unit that undergoes chemical reaction treatment while passing through the Pauling filler containing the first chemical, and a second chemical formed on the upper portion of the first chemical treatment unit and different from the first chemical used in the first chemical treatment unit. It is characterized in that it is composed of; a second chemical reaction treatment unit that undergoes a chemical reaction treatment while passing through the poling filler, and an exhaust port formed on the upper portion of the second chemical treatment unit for discharging clean gas to the outside.

In addition, the collecting unit; A reduction pipe extending in a gradually narrower diameter from the diameter of the contaminated air supply pipe, a connecting tube extending to the minimum diameter of the reduction tube at the end of the reduction tube, and a gradually widening end at the end of the connecting tube It is characterized in that it is composed of; an enlargement tube, and a first microbial liquid injection unit installed in the connecting tube to spray the microbial culture solution in the lower direction.

In addition, the microorganism processing unit; A first vortex supply unit for guiding the contaminated air supplied through the circulating water storage tank to form a vortex to be supplied to the inside, and an activated carbon filling layer on an upper portion of the first vortex supply unit in which a large amount of activated carbon filler is filled with respect to a certain area; , a second microbial solution spraying unit configured to spray the microbial culture solution of the circulating water storage tank on the activated carbon filling layer and supply it to the activated carbon filling material; characterized in that it comprises a.

In addition, the first chemical treatment unit uses an alkali-based first chemical, and the second chemical treatment unit uses an acid-based second chemical.

In addition, the first chemical processing unit; A first chemical liquid tank filled with chemicals, a second vortex supply unit configured to supply the inside by forming a vortex of contaminated air passing through the microorganism treatment unit, but collecting the falling chemicals and collecting the collected chemicals into the first chemical liquid tank; , a first poling filling layer in which a large amount of poling filler is filled with respect to a predetermined area on an upper portion of the second vortex supply unit, and the chemical liquid of the first chemical tank is sprayed on the upper portion of the first poling filler to be supplied to the poling filler It is characterized in that it is composed of; a first chemical liquid spraying unit.

In addition, the second chemical processing unit; A second chemical solution tank filled with chemicals, and a third vortex supply section configured so that the contaminated air that has passed through the microorganism treatment section is supplied to the inside by forming a vortex, so that the falling chemicals are collected and the collected chemicals are recovered into the second chemical solution tank; , a second poling filling layer in which a large amount of poling filler is filled with respect to a certain area on the upper portion of the third vortex supply unit, and the chemical liquid of the second chemical liquid tank is sprayed on the upper portion of the second poling filler to be supplied to the poling filler It is characterized in that it is composed of; a second chemical liquid spraying unit.

The present invention consists of primary treatment through the collection unit, secondary treatment through the microorganism treatment unit, tertiary treatment through the first chemical treatment unit, and quaternary treatment through the second chemical treatment unit. This has the advantage of increasing the odor removal efficiency by using a biological reaction and a chemical reaction in combination.

In addition, the present invention has the advantage of maximizing the reaction effect by allowing the contaminated air supplied to the microorganism treatment unit and the first and second chemical treatment units to be supplied while generating a vortex so that the contaminated air can stay in the filling layer for a long time.

1 is a view showing the overall configuration of the deodorizing device of the multi-stage treatment method of the present invention
Figure 2 is a view showing the configuration of the collecting unit in the deodorizing device of the present invention
Figure 3 is a view showing only the main configuration in the deodorizing device of the present invention
4 is a view showing a circulating water storage tank, a microorganism treatment unit, and first and second chemical treatment units in the present invention;
5 is an enlarged view of the microorganism processing unit of the present invention;
6 is a bottom perspective view showing the first spiral funnel in the microorganism treatment unit of the present invention;
7 is an enlarged view showing the first vortex supply unit in the microorganism treatment unit of the present invention;
8 is an enlarged view of the first chemical processing unit of the present invention;
9 is a bottom perspective view showing the shape of the second spiral funnel and the air inlet pipe in the first chemical treatment unit of the present invention;
10 is an enlarged view showing a second vortex supply unit in the first chemical processing unit of the present invention;
11 is an enlarged view of the second chemical processing unit of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

As shown in FIG. 1, the deodorization device of the multi-stage treatment method of the present invention is coupled to the polluted air supply pipe 100 through which the polluted air is supplied, and the polluted air supply pipe 100, and is coupled to the lower part of the polluted air. The collecting unit 200 in which the microbial reaction and adsorbed foreign substances fall by spraying the microbial culture solution into the passing contaminated air, and the microbial culture solution formed at the lower end of the collecting unit 200 and falling is recovered A circulating water storage tank 300 filled with a microbial culture solution supplied from an external culture solution tank 310 to a certain level, and a circulating water storage tank 300 formed on one side of the circulating water storage tank 300 The microorganism treatment unit 400, where the biological reaction treatment is performed while passing through the inside, the contaminated air moves upward and passes through the activated carbon filler containing the microbial culture solution, and the first drug is formed on the microorganism treatment unit 400 The first chemical treatment unit 500, which undergoes chemical reaction treatment while passing through the poling filler, and the first chemical formed on the first chemical treatment unit 500 and used in the first chemical treatment unit 500 is different from the first chemical used in the first chemical treatment unit 500 a second chemical treatment unit 600, which undergoes chemical reaction treatment while passing through the Pauling filler containing two chemicals, and an exhaust port 700 formed on the second chemical treatment unit 600 to discharge clean gas to the outside; It is characterized in that it is composed of

The deodorizing device of the present invention is a primary treatment through the collecting unit 200, a secondary treatment through the microorganism treatment unit 400, a tertiary treatment through the first chemical treatment unit 500, the second chemical treatment unit 600 through It consists of 4th treatment, and it is composed for a total of 4 steps of odor reduction.

The collecting unit 200 of the present invention is configured to spray a microbial culture solution into the firstly introduced contaminated air so that foreign substances are adsorbed and fall together, or to remove odor substances through a biological reaction through the microbial culture solution.

The structure of the collecting unit 200 is configured so that the polluted air can pass in the lower direction as shown in the drawing, and as shown in FIG. The reduced tube 210 is formed, a connector 220 extending to the minimum diameter of the reduced tube 210 at the end of the reduced tube 210, and a gradually widening end at the end of the connecting tube 220 It is composed of a; and an enlarged pipe 230 extending to, and a first microbial solution spraying unit 240 installed in the connection pipe 220 to spray the microbial culture solution in the lower direction.

The collection unit 200 is made in the form of a venturi tube as described above to give a change in flow rate, so that when passing through the connection tube 220, the flow rate of the contaminated air is 60 to 90 m/s. Therefore, the microbial culture solution injected from the first microbial solution spraying unit 240 installed in the connection pipe 220 can effectively collide with the polluted particles of the polluted air, thereby increasing the purification efficiency of the polluted air.

The circulating water storage tank 300 of the present invention is a configuration in which the microbial culture solution is filled from the external culture solution tank 310 to a certain level, and the microbial culture solution supplied to the collecting unit 200 and the microorganism processing unit 400 is filled. . The upper one side is connected to the end of the collecting unit 200 and the other side is connected to the beginning of the microorganism processing unit 400 so that the contaminated air passing through the collecting unit 200 passes through the inside of the circulating water storage tank 300 and the microorganisms It has a structure that moves to the processing unit 400 .

As described above, when the circulating water storage tank 300 of the present invention is configured in a form that connects the collecting unit 200 and the microorganism processing unit 400, efficient space utilization is possible and the microbial culture solution without interfering with the flow of contaminated air. has the structural advantage of easy recovery of

In addition, it is preferable that a heating device 320 is further installed in the circulating water storage tank 300 together with a temperature sensor (not shown), because the odor-decomposing microorganisms are most active under the conditions of 15 to 35 ° C. because it's good An excessively low temperature may decrease the activity of microorganisms, and an excessively high temperature may decrease the odor decomposition effect because the diversity of microorganisms is reduced. And it is possible to obtain the effect of preventing freezing in winter through the heating device (320).

In addition, the microorganism treatment unit 400 is formed on one side of the upper portion of the circulating water storage tank 300, and the contaminated air moves upward and passes through the activated carbon filler containing the microbial culture solution, and a biological reaction treatment is performed.

The configuration of the microorganism processing unit 400 is specifically, as shown in FIGS. 4 to 5, a first vortex supply unit 410 for guiding the contaminated air supplied through the circulating water storage tank 300 to form a vortex to be supplied to the inside. ) and an activated carbon filling layer 420 filled with a large amount of activated carbon filler for a certain area on the upper portion of the first vortex supply unit 410, and the activated carbon filling layer 420 on the upper portion of the circulating water storage tank 300 It characterized in that it is composed of; a second microbial liquid injection unit 430 such that the microbial culture liquid is sprayed and supplied to the activated carbon filler.

An activated carbon filler is used in the microorganism processing unit 400, and the activated carbon is easy to drain, has porous characteristics, has a low pressure loss, and corresponds to a material suitable for the growth environment of microorganisms. In this way, the biological reaction can be further promoted by using the microbial culture medium and the activated carbon filler together.

In the microorganism processing unit 400, the first vortex supply unit 410 has a form in which a plurality of first spiral funnels 411 are arranged as shown in FIG. The shape of the first spiral funnel 411 has a structure in which a plurality of spiral guide blades 411b are formed along the outer circumferential surface of the funnel-shaped body 411a as shown in FIG. 6 . And in the center of the main body 411a, as shown in FIGS. 6 to 7, a recovery hole 411c is formed through, so that the rising contaminated air rises while generating a vortex through the guide blade 411b, and falls vertically. The microorganism culture solution is to be recovered to the circulating water storage tank 300 through the recovery hole (411c).

When the polluted air is supplied while generating a vortex as described above, the polluted air can stay in the activated carbon filling layer 420 for a long time, thereby maximizing the reaction effect compared to the scale.

The second microbial liquid spraying unit 430 sprays the microbial culture solution of the circulating water storage tank 300 from the top of the activated carbon filling layer 420 through a pump, similarly to the first microbial liquid spraying unit 240 . The sprayed microbial culture solution is to be sufficiently supplied to the activated carbon filling layer 420, and since the supplied microbial culture solution is evaporated after a certain period of time, it must be continuously supplied.

The first chemical treatment unit 500 and the second chemical treatment unit 600 of the present invention are such that a chemical reaction treatment is performed while passing through the Pauling filler, and the first chemical and the second chemical treatment unit of the first chemical treatment unit 500 ( 600), different types of chemicals are used so that a complex chemical reaction occurs, thereby increasing the odor treatment efficiency.

Here, it is preferable that the first chemical treatment unit 500 uses an alkali-based first chemical, and the second chemical treatment unit 600 uses an acid-based second chemical. can be made in combination.

The first is a combination of acid and alkali, and the acid is used as a solution of sulfuric acid or hydrochloric acid with a pH of 2-3, and is used to remove ammonia and lower amines. Alkali is used to remove hydrogen sulfide and lower fatty acids, which are used as a solution of pH 12 to 13, centering on sodium hydroxide.

The second is a combination of acid and sodium hypochlorite, which uses relatively inexpensive sodium hypochlorite cleaning among oxidizing agents, which is suitable for deodorizing the smell of decay. After removing hydrogen sulfide and lower fatty acids in alkaline washing, methyl melcabutane and methyl sulfide are also removed substantially as oxidizing agents. And chlorine dioxide, potassium permanganate, hydrogen peroxide, etc. are used as oxidizing agents.

The third is a combination of sodium hypochlorite and sodium sulfite, which is used for oxidation treatment of sludge and manure, and deodorization when aldehydes such as sludge incinerator flue gas are mixed with putrefactive smell. In recent years, many difficult problems due to odor in sludge incinerators can be dealt with.

The configuration of the first chemical processing unit 500 is such that the first chemical liquid tank 510 filled with chemicals and the contaminated air passing through the microorganism processing unit 400 form a vortex to be supplied to the inside, but to collect the falling chemicals. and a second vortex supply unit 520 so that the collected drugs are recovered to the first chemical solution tank 510, and a first poling filling layer in which a large amount of poling filler is filled with respect to a predetermined area on the second vortex supply part 520. 530 and a first chemical liquid spraying unit 540 configured to spray the chemical liquid in the first chemical liquid tank 510 to be supplied to the Pauling filler on the upper portion of the first poling filling layer 530 .

The first chemical solution tank 510 is configured such that the chemical stock solution is supplied from the external first stock solution tank 511 and filled to a predetermined water level, and then continuously circulates. In addition, as shown in FIG. 8 , a second vortex supply unit 520 is installed at the beginning of the chemical processing unit. The second vortex supply unit 520 is the same as the first vortex supply unit 410 in that the polluted air is supplied in the form of a vortex, but there is a difference in the configuration in which the falling chemical is received and returned to the first chemical liquid tank 510 . There is this.

The second vortex supply unit 520 is formed with a drip plate 522 so as not to drop the chemicals as shown in FIGS. This is installed so that polluted air can be supplied, but each second spiral funnel 521 is installed on the upper portion of the air inlet pipe 523 .

The second spiral funnel 521 installed in the second vortex supply unit 520 has a plurality of spiral guide blades 521b along the outer circumferential surface of the funnel-shaped body 521a as shown in FIG. The lower part of (521a) has a non-penetrating closed structure. The second spiral funnel 521 is installed in the form of being placed on the upper part of the air inlet pipe 523 as shown in the figure, and it is possible to secure a gap through which the contaminated air can be supplied by the guide blade 521b.

In the second vortex supply unit 520 having such a structure, as shown in FIG. 10 , the contaminated air rising along the air inlet pipe 523 is supplied through a gap with the body 521a by the guide blade 521b. It vortexes and rises. And the falling drug falls outside of the second spiral funnel 521 and is immediately filled in the drip tray 522, or falls into the second spiral funnel 521 and the second spiral funnel 521 is filled with all the chemicals. It overflows outward from and is filled in the drip tray 522 . The medicines filled in the drip tray 522 are recovered again and supplied to the first chemical liquid tank 510 .

That is, the main body 521a of the second spiral funnel 521 serves to prevent the falling chemicals from entering the air inlet pipe 523 . Therefore, the diameter of the upper end of the second spiral funnel 521 is preferably formed to be larger than the diameter of the air inlet pipe 523 so that the overflowed chemical can be stably dropped onto the drip tray 522 .

The second chemical processing unit 600 of the present invention also has a structure similar to that of the first chemical processing unit 500, and the configuration is as shown in FIG. 11, a second chemical liquid tank 610 filled with chemicals, and a microorganism processing unit A third vortex supply unit 620 in which the contaminated air passing through 400 forms a vortex and is supplied to the inside, so that the falling chemicals are collected and the collected chemicals are recovered to the second chemical solution tank 610; The third vortex supply unit 620 has a second poling filling layer 630 filled with a large amount of poling filler for a certain region, and the second poling filling layer 630 is on the upper portion of the second chemical liquid tank 610. It consists of a second chemical liquid injection unit 640 that is sprayed and supplied to the Pauling filler.

The second chemical solution tank 610 is also supplied and filled with a chemical stock solution from a separate second stock solution tank 611, and goes through a circulation process. The third vortex supply unit 620 has the same structure as the second vortex supply unit 520 , and a drip tray 622 , an air inlet pipe 623 , and a third spiral funnel 621 are installed. Since the contents related to the air supply and chemical recovery of the second chemical processing unit 600 are the same as those of the first chemical processing unit 500 , a repetitive description will be omitted.

And when the first chemical solution tank 510 and the second chemical solution tank 610 of the present invention are formed inside the circulating water storage tank 300 as shown in the drawing, the space utilization is increased and the circulating water storage tank 300. Through the heating device 320 installed in the temperature is maintained together, it is possible to obtain the freezing prevention effect in winter together.

Finally, the clean gas that has passed through the second chemical treatment unit 600 is discharged to the outside through the exhaust port 700 at the top. Only the best clean gas is discharged by controlling the supply of the culture solution tank 310, the first stock solution tank 511, and the second stock solution tank 611 in which the stock solution is stored.

Although the present invention has been described above with reference to the above embodiments, it goes without saying that various modifications are possible within the scope of the technical spirit of the present invention.

100: polluted air supply pipe 200: collection part
210: reduction tube 220: connector
230: enlargement tube 240: first microbial liquid injection unit
300: circulating water storage tank 310: culture solution tank
320: heating device 400: microorganism treatment unit
410: first vortex supply unit 411: first spiral funnel
411a: body 411b: guide blade
411c: recovery hole 420: activated carbon filling layer
430: second microbial liquid spraying unit 500: first chemical processing unit
510: first chemical solution tank 511: first undiluted solution tank
520: second vortex supply unit 521: second spiral funnel
521a: body 521b: guide blade
522: drip plate 523: air inlet pipe
530: first poling filling layer 540: first chemical liquid injection unit
600: second chemical processing unit 610: second chemical liquid tank
611: second stock solution tank 620: third vortex supply unit
621: third spiral funnel 621a: main body
621b: guide blade 622: drip plate
623: air inlet pipe 630: second Pauling filling layer
640: second chemical liquid injection unit 700: exhaust port
710: odor concentration detection sensor

Claims (6)

A polluted air supply pipe 100 through which polluted air is supplied through a blower, and
A collecting unit 200 that is coupled to the end of the contaminated air supply pipe 100 so that the contaminated air passes in the lower direction, and the microbial culture solution is sprayed into the passing contaminated air so that the microbial reaction and the adsorbed foreign substances fall;
A circulating water storage tank 300 in which the microbial culture solution formed at the lower end of the collecting unit 200 and falling is recovered, and the microbial culture solution supplied from the external culture solution tank 310 is filled to a certain level;
A microorganism processing unit formed on one side of the circulating water storage tank 300 and performing a biological reaction treatment while passing through the activated carbon filler containing the microbial culture solution as the contaminated air moves upward through the inside of the circulating water storage tank 300 (400) and
A first chemical treatment unit 500 formed on the upper portion of the microorganism treatment unit 400 and subjected to a chemical reaction treatment while passing through the Pauling filler containing the first chemical;
A second chemical treatment unit ( 600) and
An exhaust port 700 formed on the second chemical processing unit 600 to discharge clean gas to the outside;
The method of claim 1,
The collecting unit 200 is;
A reduction pipe 210 extending in a gradually narrower diameter from the diameter of the contaminated air supply pipe 100, and
At the end of the reduction tube 210, a connecting tube 220 extending to the minimum diameter of the reduction tube 210,
An enlargement tube 230 extending in a gradually widening form at the end of the connection tube 220,
A deodorizing device of a multi-stage treatment method, characterized in that it is composed of; a first microbial liquid spraying unit 240 installed in the connection pipe 220 to spray the microbial culture solution in the lower direction
The method of claim 1,
The microorganism processing unit 400;
A first vortex supply unit 410 for guiding the contaminated air supplied through the circulating water storage tank 300 to form a vortex to be supplied to the inside;
An activated carbon filling layer 420 filled with a large amount of activated carbon filler for a predetermined area on an upper portion of the first vortex supply unit 410,
The activated carbon filling layer 420 has a second microbial liquid spraying unit 430 configured such that the microbial culture solution of the circulating water storage tank 300 is sprayed and supplied to the activated carbon filling material on the upper portion of the activated carbon filling layer 420; Device
The method of claim 1,
The first chemical treatment unit 500 uses an alkali-based first chemical, and the second chemical treatment unit 600 uses an acid-based second chemical.
The method of claim 1,
The first chemical processing unit 500;
A first chemical liquid tank 510 filled with medicines,
A second vortex supply unit 520 in which the contaminated air that has passed through the microorganism treatment unit 400 forms a vortex and is supplied to the inside, so that the falling drugs are collected and the collected drugs are recovered to the first chemical solution tank 510;
A first poling filling layer 530 filled with a large amount of poling filler for a predetermined area on an upper portion of the second vortex supply unit 520,
A multi-stage processing method characterized in that it is composed of; a first chemical liquid spraying unit 540 in which the chemical liquid of the first chemical liquid tank 510 is sprayed and supplied to the Pauling filler on an upper portion of the first poling filling layer 530 . deodorizer
The method of claim 1,
The second chemical processing unit 600 is;
A second chemical liquid tank 610 filled with medicines,
A third vortex supply unit 620 in which the contaminated air that has passed through the microorganism processing unit 400 forms a vortex and is supplied to the inside, so that the falling drugs are collected and the collected drugs are recovered to the second chemical solution tank 610;
A second poling filling layer 630 filled with a large amount of poling filler for a predetermined area on an upper portion of the third vortex supply unit 620,
A second chemical liquid injection unit 640 configured to spray the chemical liquid of the second chemical liquid tank 610 on the upper portion of the second poling filling layer 630 to be supplied to the poling filler; deodorizer

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