KR20190020269A - VOLATILE ORGANIC COMPOUNDS(VOCs)-REMOVING APPARATUS - Google Patents

Abstract

An apparatus for removing volatile organic compounds according to the present invention comprises: a plurality of reactors sequentially arranged in one direction; a microwave generator located at one side of the individual reactor; and an air flow-in/out slider located on the other side of the individual reactor and linearly reciprocating along the plurality of reactors while sandwiching the individual reactors. The amount of clean gas secured from the plurality of reactors can be maximized by using the air flow-in/out slider.

Description

VOCALTILE ORGANIC COMPOUNDS (VOCs) -REMOVING APPARATUS}

The present invention eliminates volatile organic compounds that can save energy by chemically treating volatile organic compounds before they are discharged from industrial facilities to the atmosphere to prevent air pollution and recover waste heat during chemical treatment of volatile organic compounds. Relates to a device.

Generally, volatile organic compounds (VOCs) are waste gases generated after the manufacturing process in semiconductor production plants or chemical industry plants. Here, since the volatile organic compound has a very high vapor pressure, it is easily evaporated in the atmosphere and simultaneously receives sunlight when coexisted with nitrogen oxides to generate ozone and photochemical oxidizing materials during photochemical reactions, causing photochemical smog.

In addition, the volatile organic compounds are harmful air substances and odor causing substances, causing harmful effects on the human body such as respiratory disorders and carcinogenicity. Therefore, as a method of treating the volatile organic compounds, a technique for separating and desorbing volatile organic compounds using microwaves has recently attracted much attention.

On the other hand, the separation and desorption technology of the volatile organic compounds using the microwave has been disclosed in the prior art in the volatile organic compound adsorption and desorption apparatus using a microwave, which is the name of the invention in Korea Patent Publication No. 10-2006-0011580. In the prior art, the adsorption and desorption apparatus includes a reactor for receiving a waveguide for introducing microwaves and filling an adsorbent around the waveguide, and a connection tube positioned around the reactor to induce the flow of gas into and out of the reactor.

Here, the connecting tube has an inlet, an outlet and an outlet which are branched toward the reactor in the vicinity of the reactor and connected to the reactor. The inlet allows gas containing volatile organic compounds from the industrial site to flow into the reactor through the connector. The microwave is irradiated to the adsorbent through the waveguide to heat the volatile organic compound adsorbed on the adsorbent to separate the volatile organic compound from the adsorbent.

The discharge port allows clean air to flow from the reactor toward the connecting pipe after separation of the volatile organic compound from the adsorbent inside the reactor. However, the connecting tube surrounds the reactor and thus limits the volume of the reactor. In addition, the amount of clean air secured from the reactor is limited by the flow time of the gas containing volatile organic compounds in the reactor.

Korean Patent Publication No. 10-2006-0011580

The present invention has been made to solve the conventional problems, has a design margin for increasing the volume of the reactor for adsorbing volatile organic compounds, clean gas from the reactor during the flow time of the gas containing volatile organic compounds in the reactor It is an object of the present invention to provide a device for removing volatile organic compounds, which is suitable not to limit the amount secured.

An apparatus for removing volatile organic compounds according to the present invention includes a plurality of reactors in which individual reactors are sequentially arranged along one direction; A microwave generator located on one side of the individual reactor; And an air inlet slider positioned on the other side of the individual reactor and reciprocating linearly moving along the plurality of reactors while sandwiching the individual reactors.

The plurality of reactors are first to third reactors, and each of the individual reactors includes a porous adsorbent therein, and receives a gas containing volatile organic compounds (VOCs) flowing from the outside toward the inside. In addition, while adsorbing the volatile organic compound-containing gas and the adsorbent therein, the volatile organic compound may be adsorbed to the adsorbent to generate a clean gas, and the clean gas may be discharged from the inside toward the atmosphere.

The individual reactors may be shielded from neighboring individual reactors in the batch direction of the first to third reactors.

The adsorbent may include zeolite or activated carbon.

The microwave generator irradiates microwaves to the adsorbent during contact between the volatile organic compound-containing gas and the adsorbent within the individual reactor to heat the volatile organic compound adsorbed on the adsorbent while heating the volatile organic compound adsorbed on the adsorbent. Can be separated.

The air inlet slider introduces hot air from the outside of the individual reactor toward the inside through one side of the individual reactor, and during irradiation of the microwaves to the adsorbent in the interior of the individual reactor, The separated volatile organic compound may be discharged together with the hot air from the inside of the individual reactor to the outside through the other side.

The air inlet slider includes a first air inlet slider on the individual reactor and a second air inlet slider below the individual reactor, wherein the first air inlet slider, the individual reactor and the second air inlet slider are stacked in a stacking direction. In communication with each other, the hot air may flow along the first air inlet slider and the individual reactor and the second air inlet slider.

The first air inlet slider includes a supply pipe receiving the hot air, and a supply chamber connected to the supply pipe to communicate with the supply pipe and the individual reactor, and the second air inlet slider is connected to the individual reactor. It may include a receiving chamber in communication with, and a discharge pipe connected to the receiving chamber.

The hot air and the separated volatile organic compounds may flow along the receiving chamber and the discharge pipe.

When the air inlet slider sandwiches the first reactor, the air inlet slider discharges the hot air and the separated volatile organic compounds from the first reactor, and the second reactor and the third reactor are the individual reactors. Receiving the volatile organic compound-containing gas flowing from the outside to the inside, adsorbing the volatile organic compound to the adsorbent while contacting the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor to clean the clean gas may be produced and the clean gas may be vented from the interior of the individual reactor towards the atmosphere.

When the air inlet slider sandwiches a second reactor, the air inlet slider discharges the hot air and the separated volatile organic compounds from the second reactor, and the first reactor and the third reactor are the individual reactors. Receiving the volatile organic compound-containing gas flowing from the outside to the inside, adsorbing the volatile organic compound to the adsorbent while contacting the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor to clean the clean gas may be produced and the clean gas may be vented from the interior of the individual reactor towards the atmosphere.

When the air inlet slider sandwiches the third reactor, the air inlet slider discharges the hot air and the separated volatile organic compounds from the third reactor, and the first reactor and the second reactor are the individual reactors. Receiving the volatile organic compound-containing gas flowing from the outside to the inside, adsorbing the volatile organic compound to the adsorbent while contacting the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor to clean the clean gas may be produced and the clean gas may be vented from the interior of the individual reactor towards the atmosphere.

The air inlet slider further includes a first catalytic reactor, a second catalytic reactor, and a heat exchanger, which are sequentially connected in gas flow view, wherein the first catalytic reactor is connected to the second catalytic reactor through one stage. Located between the first air inlet slider and connected to the second catalytic reactor and the heat exchanger and the supply pipe, the other end is connected to the outlet pipe of the second air inlet slider, the second catalytic reactor is A first end connected to the first catalytic reactor, the heat exchanger and the first air inlet slider, a second end connected to the heat exchanger, and the heat exchanger connected to the second catalytic reactor through one end; Connected to the first catalytic reactor, the second catalytic reactor and the first air inlet slider via an intermediate stage, and to the atmosphere through the other stage. Can be released.

The first catalytic reactor receives the hot air and the separated volatile organic compounds from the discharge pipe of the second air inlet slider, and reacts the first catalyst and the separated volatile organic compounds therein with the first water. And a first carbon dioxide and an unreacted volatile organic compound, the remaining hot air and the first water and the first carbon dioxide toward the second catalytic reactor while delivering a portion of the hot air toward the first air inlet slider. And the non-reactive volatile organic compound.

The second catalytic reactor receives the remaining hot air, the first water, the first carbon dioxide, and the unreacted volatile organic compound from the first catalyst reactor, and internally regenerates the second catalyst and the unreacted volatile organic compound. Reacting to produce a second water and a second carbon dioxide, and the remaining hot air, the first water, the second water, the first idealized carbon and the second carbon dioxide can be delivered toward the heat exchanger.

The heat exchanger receives the remaining hot air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide from the second catalytic reactor, and supplies the hot air into cold air and renewable hot air. The cold air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide may be discharged to the atmosphere while being divided, and the renewable hot air may be delivered to the first air inlet slider.

The first catalyst and the second catalyst may include a palladium (Pd) catalyst, a platinum (Pt) catalyst, a ruthenium (Ru) catalyst, or a rhodium (Rh) catalyst.

The present invention includes an air inlet slider for sandwiching individual reactors in a plurality of reactors, adsorbing volatile organic compounds to the adsorbent while supplying volatile organic compound-containing gas to the plurality of reactors for the same time, and air along the plurality of reactors. Sliding the inlet and outlet sliders supply hot air to the individual reactors through the inlet and outlet sliders, allowing easy design of volatile organic compounds from the individual reactors through the hot air, regardless of the number of reactors. Can be.

According to the present invention, after the volatile organic compound-containing gas is collectively supplied to a plurality of reactors sequentially disposed along one direction for the same time, the air inlet slider is slid onto the plurality of reactors along the arrangement direction of the plurality of reactors. To supply hot air to the individual reactors and to easily discharge volatile organic compounds from the individual reactors through the hot air, so that the volatile organic compound-containing gas is not sequentially supplied along the plurality of reactors. The amount of clean gas can be maximized.

1 is a schematic view partially showing an apparatus for removing volatile organic compounds according to the present invention.
2 and 3 are schematic views illustrating a method of operating the volatile organic compound removing device of FIG.

DETAILED DESCRIPTION OF THE INVENTION The following detailed description of the invention refers to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It is to be understood that the various embodiments of the invention are different, but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be embodied in other embodiments without departing from the spirit and scope of the invention with respect to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is defined only by the appended claims, along with the full range of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several aspects, and length, area, thickness, and the like may be exaggerated for convenience.

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 can easily implement the present invention.

1 is a schematic view partially showing an apparatus for removing volatile organic compounds according to the present invention.

Referring to FIG. 1, the volatile organic compound removing device 150 according to the present invention includes a plurality of reactors 10, 20, 30, a microwave generator 40, an air inlet and outlet slider 110, and a first one. A catalytic reactor (120 in FIG. 3), a second catalytic reactor (130 in FIG. 3) and a heat exchanger (140 in FIG. 3) are included.

In the volatile organic compound removal apparatus 150, the plurality of reactors 10, 20, 30, the microwave generator 40 and the air inlet and outlet slider 110 are described first. The plurality of reactors 10, 20, 30 are divided into a first reactor 10, a second reactor 20, and a third reactor 30 to simplify the description of the present invention, but are not limited thereto. . The first to third reactors 10, 20, and 30 are arranged in sequence along one direction.

The first reactor 10, the second reactor 20, or the third reactor 30 includes a porous adsorbent 5 therein, and flows volatile organic compounds from the outside toward the inside. VOCs) is supplied along the first flow line A1, and volatile organic compounds are adsorbed to the adsorbent 5 while contacting the volatile organic compound-containing gas and the adsorbent 5 therein to generate a clean gas. The clean gas is discharged along the second flow line A2 from the inside toward the atmosphere.

The first reactor 10 is shielded from the neighboring second reactor 20 and the third reactor 30 in the arrangement direction of the first to third reactors 10, 20, 30. The adsorbent 5 comprises zeolite or activated carbon. The microwave generator 40 is located on one side of the first reactor 10, the second reactor 20, or the third reactor 30.

The microwave generator 40 applies microwaves to the adsorbent 5 during contact between the volatile organic compound-containing gas and the adsorbent 5 in the first reactor 10, the second reactor 20, or the third reactor 30. The volatile organic compounds are separated from the adsorbent 5 while being heated to heat the volatile organic compounds adsorbed on the adsorbent 5.

The air inlet slider 110 is located at the other side of the first reactor 10, the second reactor 20, or the third reactor 30, so that the first reactor 10, the second reactor 20, or the third reactor 30 is located. Reciprocating linear motion (M) along the first to third reactors (10, 20, 30) while sandwiching the reactor (30).

The air inlet slider 110 is connected to the first reactor 10, the second reactor 20, or the third reactor through one side of the first reactor 10, the second reactor 20, or the third reactor 30. During the irradiation of microwaves to the adsorbent 5 in the interior of the first reactor 10, the second reactor 20, or the third reactor 30, hot air is introduced from the outside of the interior to the inside. Hot from the inside of the first reactor 10, the second reactor 20, or the third reactor 30 to the outside through the other side of the reactor 10, the second reactor 20, or the third reactor 30. Emission of volatile organic compounds separated with air.

The air inlet slider 110 includes a first air inlet slider 70, a first reactor 10, and a second reactor on the first reactor 10, the second reactor 20, or the third reactor 30. 20 or a second air inlet slider 100 below the third reactor 30. The first air inlet slider 70, the individual reactors 10, 20 or 30, and the second air inlet slider 100 communicate with each other according to the stacking direction.

The hot air flows like a third flow line B1 along the first air inlet slider 70, the individual reactors 10, 20, or 30 and the second air inlet slider 100. The first air inlet slider 70 is connected to a supply pipe 50 receiving hot air, and a supply chamber connected to the supply pipe 50 to communicate with the supply pipe 50 and the individual reactors 10, 20, or 30. (60).

The second air inlet slider 100 includes an accommodating chamber 80 in communication with individual reactors 10, 20 or 30, and an exhaust pipe 90 connected to the accommodating chamber 80. The volatile organic compound separated from the hot air flows along the receiving chamber 80 and the discharge pipe 90 together with the fourth flow line B2. Meanwhile, the first catalytic reactor 120, the second catalytic reactor 130, and the heat exchanger 140 will be described in detail with reference to FIGS. 2 and 3.

2 and 3 are schematic views illustrating a method of operating the volatile organic compound removing device of FIG. 2 and 3 will be described with reference to FIG. 1.

1 to 3, when the air inlet slider 110 sandwiches the first reactor 10, the air inlet slider 110 may provide a volatile organic compound separated from hot air in the first reactor 10. The second reactor 20 and the third reactor 30 are supplied along the first flow line A1 with a volatile organic compound-containing gas flowing inwardly from the outside of the individual reactors 20 or 30. Receive.

In addition, the second reactor 20 and the third reactor (30). While adsorbing the volatile organic compound-containing gas and the adsorbent 50 inside the individual reactor 20 or 30, the volatile organic compound is adsorbed to the adsorbent 5 to generate a clean gas, and the individual reactor 20 or 30. Clean gas is discharged along the second flow line A2 from the inside of the glass toward the atmosphere.

When the air inlet slider 110 sandwiches the second reactor 20, the air inlet slider 110 discharges volatile organic compounds separated from the hot air from the second reactor 20. The first reactor 10 and the third reactor 30 are supplied with a volatile organic compound-containing gas flowing inward from the outside of the individual reactor 10 or 30 along the first flow line A1.

In addition, the first reactor 10 and the third reactor 30, the volatile organic compound to the adsorbent (5) while contacting the volatile organic compound-containing gas and the adsorbent (5) inside the individual reactor (10 or 30) Adsorption produces a clean gas and discharges clean gas along the second flow line A2 from the interior of the individual reactors 10 or 30 toward the atmosphere.

When the air inlet slider 110 sandwiches the third reactor 30, the air inlet slider 110 discharges volatile organic compounds separated from the hot air from the third reactor 30. The first reactor 10 and the second reactor 20 are supplied with a volatile organic compound-containing gas flowing inward from the outside of the individual reactor 10 or 20 along the first flow line A1.

The first reactor 10 and the second reactor 20 adsorb volatile organic compounds to the adsorbent 5 while contacting the volatile organic compound-containing gas and the adsorbent 5 within the respective reactors 10 or 20. Clean gas is produced and discharged along the second flow line A2 from the interior of the individual reactors 10 or 20 toward the atmosphere.

The air inlet slider 110 is sequentially connected to the first catalytic reactor 120, the second catalytic reactor 130, and the heat exchanger 140 in a gas flow view. The first catalytic reactor 120 is positioned between the second catalytic reactor 130 and the first air inlet slider 70 through one end to supply the second catalytic reactor 130, the heat exchanger 140, and the supply pipe. It is connected to the 50, and is connected to the discharge pipe 90 of the second air inlet slider 100 through the other end.

The second catalytic reactor 120 is connected to the first catalytic reactor 120, the heat exchanger 140, and the first air inflow slider 70 through one end, and to the heat exchanger 140 through the other end. Connected. The heat exchanger 140 is connected to the second catalytic reactor 130 through one stage, and the first catalytic reactor 120, the second catalytic reactor 130, and the first air inlet slider 70 through the intermediate stage. Is exposed to the atmosphere through the other end.

In more detail, the first catalytic reactor 120 receives volatile organic compounds separated from hot air from the discharge pipe 90 of the second air inlet slider 100 along the fourth flow line B4. The volatile organic compound separated from the first catalyst is first reacted inside to generate the first water and the first carbon dioxide and the unreacted volatile organic compound.

In addition, the first catalytic reactor 120 transfers a portion of the hot air toward the first air inlet slider 70 along the third flow line B1 and the remaining hot air toward the second catalytic reactor 130. Delivers first water, first carbon dioxide, and unreacted volatile organic compounds. The second catalytic reactor 130 receives the remaining hot air, the first water, the first carbon dioxide, and the unreacted volatile organic compound from the first catalytic reactor 120 to secondary the second catalyst and the unreacted volatile organic compound therein. To produce a second water and a second carbon dioxide.

In addition, the second catalytic reactor 130 delivers the remaining hot air, the first water, the second water, the first idealized carbon, and the second carbon dioxide toward the heat exchanger 140. The heat exchanger 140 receives the remaining hot air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide from the second catalytic reactor 130 as cold air and renewable hot air. While dividing, cold air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide are discharged to the atmosphere, and the renewable hot air is delivered to the first air inlet slider.

The first catalyst and the second catalyst include a palladium (Pd) catalyst, a platinum (Pt) catalyst, a ruthenium (Ru) catalyst or a rhodium (Rh) catalyst.

5; Adsorbents, 10, 20, 30; Reactor
40; Microwave generator, 50; Supply piping
60; Feed chamber, 70; First air inlet slider
80; Receiving chamber, 90; Exhaust piping
100; A second air inlet slider, 110; Air inlet slider
150; Volatile Organic Compound Removal Device
A1, A2, B1, B2; Streamline

Claims (17)

A plurality of reactors in which individual reactors are sequentially arranged along one direction;
A microwave generator located on one side of the individual reactor; And
And an air inlet slider positioned on the other side of the individual reactor and reciprocating linearly moving along the plurality of reactors while sandwiching the individual reactors.
According to claim 1,
The plurality of reactors are first to third reactors,
The individual reactor includes a porous adsorbent therein and is supplied with a gas containing volatile organic compounds (VOCs) flowing from the outside to the inside, and the gas containing the volatile organic compound and the adsorbent therein. The volatile organic compound removal apparatus which adsorb | sucks a volatile organic compound to the said adsorbent, produces | generates a clean gas, and discharges said clean gas from the inside toward the atmosphere.
The method of claim 2,
Wherein said individual reactors are shielded from neighboring individual reactors in a batch direction of said first to third reactors.
The method of claim 2,
The adsorbent volatile organic compound removal device comprising zeolite or activated carbon.
The method of claim 2,
The microwave generator irradiates microwaves to the adsorbent during contact between the volatile organic compound-containing gas and the adsorbent within the individual reactor to heat the volatile organic compound adsorbed on the adsorbent while heating the volatile organic compound adsorbed on the adsorbent. A volatile organic compound removal device for separating the.
The method of claim 5,
The air inlet slider introduces hot air from the outside of the individual reactor toward the inside through one side of the individual reactor, and during irradiation of the microwaves to the adsorbent in the interior of the individual reactor, And removing the separated volatile organic compounds with the hot air from the inside of the individual reactor toward the outside through the other side.
The method of claim 6,
The air inlet slider includes a first air inlet slider on the individual reactor and a second air inlet slider below the individual reactor,
The first air inlet slider, the individual reactor and the second air inlet slider communicate with each other along the stacking direction,
The hot air flows along the first air inlet slider, the individual reactor and the second air inlet slider.
The method of claim 7, wherein
The first air inlet slider includes a supply pipe receiving the hot air, and a supply chamber connected to the supply pipe to communicate with the supply pipe and the individual reactor,
The second air inlet slider includes a receiving chamber in communication with the individual reactor, and a discharge pipe connected to the receiving chamber.
The method of claim 8,
And removing the hot air and the separated volatile organic compounds along the receiving chamber and the discharge pipe.
The method of claim 7, wherein
When the air inlet slider sandwiches the first reactor,
The air inlet slider discharges the hot air and the separated volatile organic compounds from the first reactor,
The second reactor and the third reactor receive the volatile organic compound-containing gas flowing from the outside of the individual reactor toward the inside, and contact the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor. While adsorbing the volatile organic compound to the adsorbent to generate the clean gas, and discharge the clean gas from the inside of the individual reactor toward the atmosphere.
The method of claim 7, wherein
When the air inlet slider sandwiches the second reactor,
The air inlet slider discharges the hot air and the separated volatile organic compounds from the second reactor,
The first reactor and the third reactor receive the volatile organic compound-containing gas flowing from the outside of the individual reactor toward the inside, and contact the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor. While adsorbing the volatile organic compound to the adsorbent to generate the clean gas, and discharge the clean gas from the inside of the individual reactor toward the atmosphere.
The method of claim 7, wherein
When the air inlet slider sandwiches the third reactor,
The air inlet slider discharges the hot air and the separated volatile organic compounds from the third reactor,
The first reactor and the second reactor receive the volatile organic compound-containing gas flowing from the outside of the individual reactor toward the inside, and contact the volatile organic compound-containing gas and the adsorbent in the interior of the individual reactor. While adsorbing the volatile organic compound to the adsorbent to generate the clean gas, and discharge the clean gas from the inside of the individual reactor toward the atmosphere.
The method of claim 8,
The air inlet slider further comprises a first catalytic reactor, a second catalytic reactor and a heat exchanger, which are sequentially connected in gas flow view,
The first catalytic reactor is located between the second catalytic reactor and the first air inlet slider through one end and connected to the second catalytic reactor, the heat exchanger and the supply pipe, and the second through the other end. Connected to the outlet pipe of the air inlet slider,
The second catalytic reactor is connected to the first catalytic reactor, the heat exchanger and the first air inlet slider through one end, and connected to the heat exchanger through the other end.
The heat exchanger is connected to the second catalytic reactor through one end, connected to the first catalytic reactor, the second catalytic reactor and the first air inlet slider through an intermediate stage, and exposed to the atmosphere through the other end. Volatile Organic Compound Removal Device.
The method of claim 13,
The first catalytic reactor receives the hot air and the separated volatile organic compounds from the discharge pipe of the second air inlet slider, and reacts the first catalyst and the separated volatile organic compounds therein with the first water. And a first carbon dioxide and an unreacted volatile organic compound, the remaining hot air and the first water and the first carbon dioxide toward the second catalytic reactor while delivering a portion of the hot air toward the first air inlet slider. And a volatile organic compound removing device for delivering the non-reactive volatile organic compound.
The method of claim 14,
The second catalytic reactor receives the remaining hot air, the first water, the first carbon dioxide, and the unreacted volatile organic compound from the first catalyst reactor, and internally regenerates the second catalyst and the unreacted volatile organic compound. To generate second water and second carbon dioxide, and to remove the volatile organic compounds that transfer the remaining hot air, the first water, the second water, the first idealized carbon, and the second carbon dioxide toward the heat exchanger. Device.
The method of claim 15,
The heat exchanger receives the remaining hot air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide from the second catalytic reactor, and supplies the hot air into cold air and renewable hot air. Volatile organic compounds that remove the cold air, the first water, the second water, the first carbon dioxide, and the second carbon dioxide from the atmosphere to the atmosphere and deliver the renewable hot air to the first air inlet slider while dividing. Device.
The method of claim 15,
The first catalyst and the second catalyst is a volatile organic compound removal device comprising a palladium (Pd) catalyst, platinum (Pt) catalyst, ruthenium (Ru) catalyst or rhodium (Rh) catalyst.

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