KR20130125744A - Method and apparatus for removing volatile organic compound - Google Patents

Abstract

As a method for treating volatile organic compounds in the atmosphere, a method for removing volatile organic compounds which includes a step of generating ozone and a step of generating reaction active species, whereby the volatile organic compounds are decomposed. [Reference numerals] (1) Ozone generator;(2) Air blower;(3) Catalyst layer;(AA) Polluted gas to be treated;(BB) Purified gas

Description

Method and apparatus for treating volatile organic compounds

Disclosed herein are methods and apparatuses for decomposing volatile organic compounds contained in the atmosphere.

Volatile organic compounds are classified as specific air pollutants due to their high impact on humans and ecosystems. Volatile organic compounds generate photochemical oxides, which are secondary pollutants such as ozone, through photochemical reactions. Volatile organic compounds are toxic to the human body because they contain many chemicals known to be highly carcinogenic and cause problems such as ozone layer destruction, global warming, photochemical smog and odors.

Common techniques for removing volatile organic compounds include adsorption by activated carbon, high temperature incineration, oxidation removal by catalyst, and plasma.

Adsorption by activated carbon is the most traditional method of removing volatile organic compounds, and is a technique for physically and chemically adsorbing volatile organic compounds to activated carbon. This method has a short exchange cycle since it is no longer adsorbed after a certain time. In addition, secondary contaminants are generated upon disposal after completion of use, and are disadvantageous for treating highly volatile organic compounds.

The high temperature incineration method is a method of combustion oxidation by heating to a high temperature. This method is efficient at removing high concentrations of volatile organic compounds, but disadvantageous at low concentrations. In addition, the processing cost is high because auxiliary fuel is required.

The oxidation removal method using a catalyst is a technique of oxidizing and removing a volatile organic compound using an oxidation catalyst. Unlike activated carbon, the catalyst has a long life, but since there is almost no reaction activity at room temperature, the contaminated air temperature has to be raised to a high temperature of about 300 ° C. or higher.

The plasma method has a fundamental disadvantage of generating ozone, another pollutant.

An object of one embodiment of the present invention is to remove volatile organic compounds in the atmosphere.

It is an object of another embodiment of the present invention to remove volatile organic compounds in the air at room temperature.

It is an object of another embodiment of the present invention to effectively remove not only high concentrations of volatile organic compounds but also low concentrations of volatile organic compounds.

It is an object of another embodiment of the present invention to remove volatile organic compounds in the air with simple equipment.

It is an object of another embodiment of the present invention to safely remove volatile organic compounds without the risk of generating secondary pollutants such as ozone generated by the process of removing volatile organic compounds.

A volatile organic compound treatment method according to an embodiment of the present invention, a method for treating a volatile organic compound contained in the atmosphere, comprising the steps of generating ozone; And treating the generated ozone with a catalyst to generate reactive active species, wherein the generated volatile organic compounds are decomposed by the generated reactive active species.

In the volatile organic compound treatment method according to another embodiment of the present invention, generating the ozone may include determining the ozone generation amount based on the concentration of the volatile organic compound contained in the atmosphere.

In the volatile organic compound treatment method according to another embodiment of the present invention, generating the ozone may include generating 10 to 15 times the ozone concentration of the volatile organic compound contained in the atmosphere.

In the volatile organic compound treatment method according to another embodiment of the present invention, the step of generating ozone may include generating ozone and decomposing the volatile organic compound primarily.

In the volatile organic compound treatment method according to another embodiment of the present invention, the step of generating ozone, by using an ultraviolet lamp reactor or a plasma reactor to generate ozone, and at the same time primarily the volatile organic compound Disassembly may include.

In the volatile organic compound processing method according to another embodiment of the present invention, the step of generating ozone may include adjusting the amount of ozone generated by adjusting the applied voltage applied to the ultraviolet lamp reactor or the plasma reactor. .

An apparatus for processing a volatile organic compound according to an embodiment of the present invention, an apparatus for treating a volatile organic compound included in the atmosphere, comprising: an ozone generator for generating ozone; And a catalyst which reacts with ozone generated in the ozone generator to generate reactive active species.

In the volatile organic compound processing apparatus according to another embodiment of the present invention, the catalyst may be provided in the form of a catalyst layer.

In the volatile organic compound processing apparatus according to another embodiment of the present invention, the ozone generator may be set to determine the ozone generation amount based on the concentration of the volatile organic compound contained in the atmosphere.

In the volatile organic compound processing apparatus according to another embodiment of the present invention, the ozone generator may be set to generate ozone of 10 to 15 times the concentration of the volatile organic compound contained in the atmosphere.

In the volatile organic compound processing apparatus according to another embodiment of the present invention, the ozone generator may be an ultraviolet lamp reactor or a plasma reactor.

By using the present invention, volatile organic compounds in the atmosphere can be removed at room temperature. In addition, it is possible to effectively remove not only a high concentration of volatile organic compounds but also a low concentration of volatile organic compounds. In addition, a simple plant can easily remove volatile organic compounds in the atmosphere. In addition, it is possible to safely remove the volatile organic compounds without the risk of the generation of secondary pollutants such as ozone generated by the removal process of the volatile organic compounds. In addition, the oxidation effect is excellent even if the residence time through the catalyst bed is short. In addition, it is possible to effectively treat various pollutants and polluted air of various concentrations by adjusting the ozone generation amount. In addition, since the installation area is small and can be used for low concentration polluted air, and can easily remove the contaminants at room temperature, it is possible to completely remove the indoor air pollutants represented by the sick house syndrome in recent years.

1 is a schematic diagram of an apparatus for removing a volatile organic compound according to an embodiment of the present invention.
2 is a graph showing the result of removing toluene according to an embodiment of the present invention.
3 is a graph showing the change in removal efficiency according to the change in toluene concentration and ozone concentration.

In the present specification, "volatile organic compound (VOC)", when coexisted with nitrogen oxides in the atmosphere, causes photochemical reactions under the action of sunlight to generate photochemical oxidizing substances such as ozone and pan (PAN: peroxyacetyl nitrate) to generate photochemical smog. It refers to the substance that causes the whole. It is an air pollutant, a carcinogenic toxic chemical and a precursor to photochemical oxides. It is also a cause of global warming and may cause odor. Petrochemical products, such as benzene, acetylene, and gasoline, or an organic solvent, etc. are contained. From solvents commonly used in industry to organic gases emitted from chemical and pharmaceutical plants or plastic drying processes, hydrocarbons commonly used in everyday life such as liquid fuels with low boiling point, paraffin, olefins, aromatic compounds, etc. Yes.

The ozone generator can be used as long as it is known in the art as a device for generating ozone. For example, an ultraviolet lamp reactor, a plasma reactor, etc. are included. The ultraviolet lamp reactor may be a short wavelength ultraviolet lamp reactor. In addition, any device known to generate ozone can be used in the present invention.

The catalyst for decomposing ozone can be used without any particular limitation as long as it is a catalyst known in the art. For example, platinum, Cr oxide, Al oxide, Co oxide, Cu oxide, Mn oxide, metal Pd or Pd compound etc. are mentioned. For example, there is such as _{MnO 2, NiO, CoO, CuO} , Fe 2 O 3, V 2 O 5, AgO 2 as the metal oxide. It is also possible to use not only monometal oxides but also mixtures of various metal oxides. For example, MnO ₂ -CuO, MnO ₂ -AgO ₂ , NiO-CoO-AgO _2, and the like can be used. The catalyst layer may be any catalyst layer known in the art as the catalyst layer used for ozone decomposition.

Reactive active species include various active species that occur upon decomposition of ozone. For ^{example, O (1 D), O} (3 P), OH * and the like can be mentioned active species.

In the volatile organic compound treatment method according to another embodiment of the present invention, generating the ozone may include determining the ozone generation amount based on the concentration of the volatile organic compound contained in the atmosphere. If the concentration of ozone is too low compared to the concentration of the volatile organic compound, the volatile organic compound cannot be effectively removed. This is because there are not enough reactive active species. On the other hand, when the ozone generation amount is too large, the removal of ozone by the catalyst does not occur sufficiently, and ozone may be discharged into the air. In this respect, the concentration of ozone generated in the ozone generator can be adjusted to 2 to 50 times, preferably 5 to 30 times, more preferably 10 to 15 times the concentration of volatile organic compounds.

The ozone generation amount can be adjusted by adjusting the applied voltage applied to the ultraviolet lamp reactor or the plasma reactor. The applied voltage applied to the ultraviolet lamp reactor or the plasma reactor can be adjusted manually or automatically. In the case of automatic adjustment, the apparatus according to an embodiment of the present invention may automatically set the concentration of the volatile organic compounds in the air, and set the applied voltage to be automatically adjusted according to the measured concentration. Conversely, the concentration of volatile organic compounds in the air may be preset in several steps (eg, high, medium, and low) in the manufacturing step of the device, and the applied voltage for each step may also be set in advance. Then, the user simply selects one of the concentrations of the volatile organic compounds, for example, high, medium, and low, and an applied voltage corresponding thereto is automatically applied. Otherwise, the user may be set to select the applied voltage directly. Further, the apparatus of the present invention may be provided in a state in which a predetermined applied voltage is set in advance according to the use of household, industrial, and the like.

When ozone is generated using an ultraviolet lamp reactor or a plasma reactor, when contaminated air including volatile organic compounds is introduced in the ozone generating step, ozone is generated and at the same time, volatile organic compounds may be primarily decomposed. The primary decomposed volatile organic compound-containing air is secondarily decomposed by ozone decomposing active species in the step of passing through the catalyst bed. However, it can also be installed so that contaminated air is introduced directly into the catalyst bed without passing through an ozone generator.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings and examples, but this is not intended to limit the scope of the present invention, but is intended to provide examples.

1 is a volatile organic compound processing apparatus according to an embodiment of the present invention. Contaminated air containing volatile organic compounds is first oxidized and deoxidized in an ozone generator 1 composed of a short wavelength ultraviolet lamp reactor or a plasma reactor. At this time, the ozone concentration generated in the ozone generator is maintained at 10 to 15 times the concentration of the volatile organic compound, which is possible by controlling the applied voltage applied to the short wavelength ultraviolet lamp reactor or the plasma reactor. The volatile organic compound that has not been removed from the ozone generator is finally oxidized and finally reacted with the reactive active species generated as ozone is decomposed when the ozone generated in the ozone generator passes through the catalyst layer 3. Since the catalyst layer 3 includes a catalyst for oxidizing and removing ozone, ozone is not included in the final discharged gas stream.

≪ Example 1 >

In this embodiment, toluene, which is a representative volatile organic compound, was removed using the volatile organic compound removing device shown in FIG. The concentration of toluene in the air entering the volatile organic compound removal unit was 50 ppm. The amount of air flowed in was 0.4 L / min, and the catalyst bed residence time of the reaction gas was operated at 0.18 seconds (GHSV = 20000 / hr). The ozone concentration generated in the ozone generator (Ozone Technician, LAB-2) was 450 ppm, which is 9 times the toluene concentration, and the catalyst bed temperature was room temperature (25 ° C.).

The result is as shown in FIG. When only 50 ppm of toluene was passed through the catalyst bed in "phase 1", toluene was continuously adsorbed to the catalyst bed, and after 20 minutes, the toluene concentration was 0 ppm. However, since the adsorption reaction is a state in which toluene is not permanently removed but is temporarily trapped in the catalyst layer, in this embodiment, when only toluene was passed through the catalyst layer, it was confirmed that toluene was no longer adsorbed after 2 hours.

On the other hand, when 450 ppm of ozone was passed through the catalyst bed in "phase 2", ozone was decomposed in the catalyst bed and the ozone concentration rapidly decreased, and ozone was no longer detected after about 20 minutes. is decomposed to CO ₂ has been found that the concentration of CO to CO ₂ continues to increase.

≪ Example 2 >

This embodiment is to determine the effect of the ratio of the concentration of volatile organic compounds and the concentration of ozone on the volatile organic compound removal efficiency. To this end, toluene-contaminated air was treated under the same conditions as in Example 1 using the volatile organic compound removal device shown in FIG. Here, toluene conversion and COx selectivity (COx) were increased when the ozone / toluene concentration ratio for ozone was increased from 1.0 to 15.0 while maintaining the toluene concentration at 20, 50, and 100 ppm, respectively. selectivity). As the toluene concentration is increased, the toluene removal rate of the catalyst layer adsorbing toluene tends to decrease little by little, which shows a typical adsorption curve in which concentration and adsorption performance are inversely proportional. On the other hand, as the ozone concentration increases, the concentration of reactive active species generated in the catalyst layer also increases, indicating that COx selectivity increases. Eventually, a certain level of ozone concentration must be ensured that sufficient reactive active species are generated in the catalyst layer to oxidize toluene.

1: ozone generator
2: blower
3: catalyst layer

Claims (11)

A method for treating volatile organic compounds contained in the atmosphere,
Generating ozone; And
Treating the generated ozone with a catalyst to generate reactive active species,
A volatile organic compound treatment method wherein a volatile organic compound is decomposed by the generated reactive active species. The method of claim 1,
The step of generating ozone is
A method of treating volatile organic compounds, the method comprising determining the amount of ozone generated based on the concentration of volatile organic compounds contained in the atmosphere. 3. The method of claim 2,
The step of generating ozone is
A method of treating volatile organic compounds, which generates ozone at 10 to 15 times the concentration of volatile organic compounds contained in the atmosphere. The method of claim 1,
The step of generating ozone is
A method for treating volatile organic compounds, which generates ozone and simultaneously decomposes volatile organic compounds. 5. The method of claim 4,
The step of generating ozone is
A method of treating volatile organic compounds by using ozone lamp reactor or plasma reactor to generate ozone and to decompose volatile organic compounds primarily. The method of claim 5, wherein
The step of generating ozone is
A method of treating volatile organic compounds, the method comprising adjusting the amount of ozone generated by adjusting an applied voltage applied to an ultraviolet lamp reactor or a plasma reactor. An apparatus for treating volatile organic compounds contained in the atmosphere,
Ozone generator for generating ozone; And
A volatile organic compound processing apparatus comprising a catalyst that reacts with ozone generated in an ozone generator to generate reactive active species. The method of claim 7, wherein
The catalyst is a volatile organic compound processing apparatus provided in the form of a catalyst layer. The method of claim 7, wherein
The ozone generator is a volatile organic compound processing apparatus set to determine the ozone generation amount based on the concentration of volatile organic compounds contained in the atmosphere. The method of claim 9,
The ozone generator is a volatile organic compound processing apparatus set to generate ozone 10 to 15 times the concentration of the volatile organic compound contained in the atmosphere. The method of claim 7, wherein
The ozone generator is a volatile organic compound processing device is an ultraviolet lamp reactor or a plasma reactor.

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