KR101787402B1 - Industrial deodorizer - Google Patents

Abstract

The present invention relates to an industrial deodorizer, and more particularly, to an industrial deodorizer, and more particularly, to a deodorizer for industrial use, in which, as a pretreatment process, moisture contained in air is condensed through a cooler to remove some odor components, The present invention relates to an industrial deodorizer capable of maximizing deodorization efficiency by successively performing adsorption through a neutralization section and neutralization through a neutralization section neutralization section.

Description

Industrial deodorizer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an industrial deodorizer, and more particularly, to a process for pretreatment and deodorization of waste disposal technology to remove odors generated in a sewage treatment plant, a manure disposal plant, or a large-scale waste disposal environment establishment. The present invention is particularly directed to the treatment of air with a high degree of moisture and odor. After passing through the cooler, the present process can remove odorous components through the UV deodorization unit, adsorption through the activated carbon adsorption unit, The present invention relates to an industrial industrial waste deodorizer technique capable of maximally reducing the processing cost while maximizing the deodorization efficiency of odors of industrial waste containing a large amount of moisture and odor.

As the industry develops, the problem of environmental pollution becomes increasingly serious. In accordance with these trends, there is a growing demand for regulations on pollutants to be further strengthened. In fact, various devices for removing environmental pollutants are being developed. Conventional air purifiers have adopted a method of filtering dust or odor by filtering or adsorbing pollutants by a conventional filter while forcibly circulating indoor air by driving a fan operated by a power source have.

However, in the conventional air purifying apparatus, when the filter is clogged by the pollutant, the efficiency is lowered and it causes troubles. Therefore, it is troublesome to clean the filter frequently after decomposing the air purifying apparatus, When a filter with contaminated material is left for a long time, there is a problem that fungi and bacteria live in the pollutants, causing bad odors and acting as a pollutant source of air, and in severe cases, causing diseases. Conventional deodorizing apparatuses for treating recyclable separated garbage, food waste, garbage, sewage sludge, and the like from business establishments are very inefficient and require a fundamental countermeasure thereto.

These odor and VOCs (volatile organic compound) components generated from industrial waste are known to not only cause discomfort by stimulating the smell of the human body, but also have a very harmful effect on the health. Especially, the volatile organic compounds have high vapor pressure It evaporates readily into the atmosphere and causes photochemical reaction with nitrogen oxides in the air to cause photochemical smog. It is known as a very harmful substance to the human body by destroying the ozone layer in the atmosphere. Especially, Some volatile organic compounds can be present at high concentrations even in the absence of the associated combustion-related pollutants, thus emphasizing the importance of elimination in terms of environmental health.

Among industrial wastes, especially manure and food wastes have very strong moisture and odor characteristics, and therefore, there is a demand for a new technology to replace them, because the effect of the commonly known deodorizing means is very low.

The thermal incineration method is a method of treating volatile organic compounds that are practically applied in the field, such as thermal incineration, adsorption method, and catalytic incineration method. The thermal incineration method is disadvantageous in that the load fluctuation is large and low concentration, In the adsorption method, the adsorption ability of the adsorbent decreases when ketone, aldehyde, and ester are included, and the adsorption efficiency decreases due to the contamination of dust. The catalyst incineration method has a relatively low flow rate of medium / low temperature volatile organic compounds There is a problem that it is not economical to apply to the removal of the compound due to an excessive initial investment cost, a high operating cost, and the like, and is difficult to apply to a process having a risk of explosion.

 In the case of the recent air pollution, the pollution sources are diversified and new pollutants are continuously generated. Thus, the conventional simple treatment method has encountered a limit. Also, in the conventional air purification apparatus, But also a second pollutant source is generated by simple filtration or adsorption so that it takes a lot of time and cost to maintain and manage.

Photocatalyst is a compound of photo and catalyst. It means a catalyst for accelerating the light reaction or a catalyst using light. It is widely used because it can promote the catalytic reaction using light as an energy source. However, the photocatalyst satisfies the basic condition of a general catalyst that can accelerate the reaction rate by providing a mechanism different from that of the existing reaction even though it is not consumed by directly participating in the reaction. In addition, (TiO ₂ ) is the most frequently used photocatalyst for the photochemical reaction. The photochemical reaction of the photochemical reaction is usually performed using a semiconductive metal oxide or a sulfur compound. The photocatalyst is able to treat secondary pollution by completely oxidizing / decomposing the pollutants and can treat pollutants in the liquid phase and the vapor phase, can be treated at room temperature / atmospheric pressure and low temperature, and can be treated with BOD (Biochemical Oxygen Demand), COD (Chemical Oxygen Demand), chromaticity, SS (Settleable Solids) and deodorizing ability. It is also excellent in removal of heavy metals, removal of defective organic substances, and sterilization effect of various microorganisms. In the sterilization apparatus using photocatalyst, It has the advantage of narrow area and its use is expanding in various industrial and real life fields. Accordingly, there is a need for an air purifier having excellent deodorization efficiency, which effectively cleans contaminated indoor air while preventing secondary pollutants by directly decomposing contaminants in the air using ultraviolet rays and photocatalyst.

In order to solve such a problem, Korean Patent Registration No. 10-1000306 discloses, as shown in FIG. 4, a main body 10 having an air inlet 11 and an air outlet 12; A pretreatment filter unit 20 and an intermediate filter unit 30 for removing fine solid matter in the contaminated air flowing through the air inlet 11; A cartridge filter unit (40) incorporating a plurality of air purifying members (50) for removing odorous components in contaminated air by a photo-oxidation and a catalytic oxidation reaction of an ultraviolet lamp and a photocatalyst; And a suction filter unit (60) for preventing the recombination of visible light decomposed through the cartridge filter unit (40), wherein the cartridge filter unit (40) comprises a fixed frame (43) for constituting a filter; A fixed frame lid 41 positioned at and connected to the fixed frame 43; A fixing member 42 fixed to the fixed frame lid 41 by fixing the fixing frame 43 to the fixed frame 43 and being disassembled; An air purifying member (50) which is fastened to the stationary frame (43) to remove odorous components by photocatalytic reaction of air contaminated with odor; And a UV lamp hole (44) formed on the fixed frame and allowing the UV lamp (55) to be easily drawn into the air purifying member (50). A deodorizing apparatus using ultraviolet rays and a photocatalyst is disclosed .

However, in the case of the registered patent, when the rate of inflow of air generated from food waste, sewage sludge, etc. is increased or the amount of inflow of air is large due to a large amount of moisture and odor components such as food waste, It is necessary to develop a high-efficiency, high-capacity industrial deodorizer because the unprocessed odor components can not be removed and cumulative increase in the odor components may occur.

On the other hand, typical conventional industrial deodorization methods include a biofilter system, an activated carbon adsorption system, and a chemical solution cleaning system.

The biofilter method is a malodor treatment method using a microorganism attached to a synthetic polymer carrier. However, since it uses microorganisms, it is sensitive to temperature and applicable odor substances are limited. There is a disadvantage that it rapidly decreases. Therefore, the maintenance is difficult and the cost is very high, so it is very difficult to introduce it in the field.

On the other hand, the activated carbon adsorption method is a method of adsorbing odor by chemically treating the surface of activated carbon. However, the device structure is simple and the manufacturing cost is low, while a pretreatment facility necessary for removing tar and dust is separately required. In case of treatment of odor with high concentration and high humidity It has a disadvantage that the replacement cycle is fast, the effect is low, and the cost is high. Also, it is troublesome to separately install a water removal facility in the deodorization tower, and maintenance cost is excessively increased due to frequent replacement of parts.

The chemical liquid cleaning method that is routinely used in many environmental establishments is the odor treatment method by the oxidation, reduction and neutralization reaction by the chemical liquid washing water. The installation cost is rather low, and even when the gas to be introduced is high temperature or contains dust However, the installation cost of the chemical liquid cleaning method is relatively lower than that of the biofilter method, but the installation cost is as high as about 1.5 times that of the present invention, and the additional wastewater treatment Cost, and the need for extra facilities, strict supply and drainage management, and the risk of environmental pollution caused by the use of chemical solutions have been pointed out as problems.

Accordingly, it is urgent to develop a low-cost industrial-purpose deodorizer capable of effectively purifying air including moisture and odor at the same time as food waste and manure.

Korean Patent No. 10-1000306 Korean Patent No. 10-0851590

In order to solve the above-described problems, the present invention has been developed, in particular, for the purpose of deodorizing industrial wastes containing moisture and odor in the air, in particular, a very strong odor and a large amount of odor. The object of the present invention is to provide a method and apparatus for removing odorous components by partially removing odorous components by condensing moisture contained in the air through a cooler in a process of a full deodorization process and then removing odorous components through UV deodorization, And an object of the present invention is to provide an industrial deodorizer capable of maximizing deodorization efficiency by designing the neutralization process through the neutralization section to be sequentially and efficiently performed. As a result, a very effective deodorizing performance can be achieved unlike the conventional method.

The object of the present invention is also to provide an energy-saving industrial deodorizer which can quickly and efficiently remove moisture from humid odor air by employing a heat pipe, .

In addition, the object of the present invention is to provide a method and apparatus for deodorization, which can be applied to various industrial deodorization machines, and which is less expensive than conventional industrial deodorization technologies such as a biofilter system and a chemical solution cleaning system, Since the cycle is longer than other deodorizing methods, it is intended to provide a technique that is easy to maintain. The present invention also provides an industrial deodorizer that can be operated without any separate water treatment facility, water removal facility, and pretreatment facility, and is easy to expand and operate.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

To this end, the industrial deodorizer according to the present invention comprises a main body; A first frame to a third frame which define an inner space of the main body and in which openings are formed; A suction fan installed at one side of the main body and sucking outside air; A filter installed at one side of the first frame to remove dust in the air introduced through the suction fan; A cooler installed on the other side of the first frame to cool air passing through the filter to condense and deodorize moisture contained in the air; A UV deodorizing unit installed at one side of the second frame for irradiating ultraviolet rays; An activated carbon adsorption unit disposed on the other side of the second frame; A malodor component neutralizing part installed at one side of the third frame and containing a deodorizing active component for neutralizing a malodor component contained in the air; And an exhaust fan installed on the other side of the main body in association with the malodor component neutralizing part and discharging the deodorized air to the outside.

Further, in the industrial deodorizer according to the present invention, the cooler is made of a heat pipe, and the heat pipe is composed of a container, a wick formed on the inner surface of the container, and a working fluid accommodated in the wick, And a condensing portion for condensing the working fluid is provided and the condensed working fluid is absorbed by the wick and moved to the evaporator portion. .

In the industrial deodorizer according to the present invention, the UV deodorizing unit may include a UV irradiating unit installed in the lattice frame, and a photocatalyst disposed behind the UV irradiating unit and formed on the surface of the metal mesh.

Further, in the industrial deodorizer according to the present invention, the photocatalyst portion includes silica particles having a hollow mesoporous structure, and photocatalyst particles contained therein.

Further, in the industrial deodorizer according to the present invention, the malodor component neutralizing part may include a plurality of casings having a structure in which upper and lower layers are stacked with a spacing space, and an opening hole is formed; And a polymer matrix containing a polymer resin contained in the casing and a deodorizing active component in the form of a gel.

Further, in the industrial deodorizer according to the present invention, the deodorizing active component is characterized by comprising a plant extract.

Industrial deodorizer according to the present invention having the above-described structure is a pretreatment process for industrial waste such as industrial waste which is very strong in moisture and odor in the air and condenses moisture contained in air through a cooler to remove some odor components, The deodorization efficiency can be maximized by removing odor components through the UV deodorization unit, adsorption through the activated carbon adsorption unit, and neutralization through the neutralization unit in sequence. This can be particularly effective in the treatment of wet food garbage.

In addition, the industrial deodorizer according to the present invention is less expensive than the biofilter system and the chemical solution cleaning system in terms of equipment cost and maintenance cost, and the replacement cycle is longer than other deodorizing systems, thereby simplifying maintenance. And it can be operated without separate water treatment facility, water removal facility, and pretreatment facility, and it is easy to expand and operate.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing the structure of an industrial deodorizer according to the present invention.
2 is a sectional view showing the structure of an industrial deodorizer according to the present invention.
3 is a cross-sectional view showing the heat pipe structure of the present invention.
4 is a view showing the structure of a conventional deodorizing apparatus.

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

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the terms described below are defined in consideration of the functions of the present invention, and these may vary depending on the intention of the user, the operator, or the precedent. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a perspective view showing the structure of an industrial deodorizer according to the present invention, FIG. 2 is a sectional view showing the structure of a deodorizer according to the present invention, and FIG. 3 is a sectional view showing a heat pipe structure of the present invention.

1 to 3, an industrial deodorizer 100 according to the present invention includes a main body 101, a first frame 2, a second frame 3, and a third A frame 107c, a suction fan 103 installed at one side of the main body 101 for sucking outside air, and a fan 107 installed at one side of the first frame 107a, A cooler 120 installed at the other side of the first frame 107a to cool the air passing through the filter 110 to condense and deodorize moisture contained in the air, A UV deodorization unit 130 installed at one side of the second frame 107b for irradiating ultraviolet rays, an activated carbon adsorption unit 150 installed at the other side of the second frame 107b, ), And a malodor component containing a deodorizing active component which neutralizes a malodor component contained in the air Comprises a conversion unit 160, the body 101 is installed in connection with the neutralization portion odor component to the other side for discharging the deodorizing air to the outside exhaust fan 105.

The main body 101 forms an outer shape of the deodorizer 100, and the suction fan 103 is installed at one end and the exhaust fan 105 is formed at the other end.

The first frame, the second frame, and the third frames 107a, 107b, and 107c are sequentially and continuously spaced from one side of the suction fan 103. [

A filter 110 and a cooler 120 are installed in the first frame 107a and a UV deodorization unit 130 and an activated carbon adsorption unit 150 are installed in the second frame 107b, In the third frame 107c, the malodor component neutralizing unit 160 is provided.

The openings 108 are formed in the frames 107a, 107b, and 107c so that the air can pass through the frames 107a, 107b, and 107c.

The filter 110 may be HEPA (High Efficiency Particulate Air Filter). The filter 110 removes dust or the like in the air, and has a collection ability of 85 to 99.975% or more with respect to 0.05 to 0.5 탆 particles. A glass fiber having a diameter of 1 to 10 mu m or less can be exemplified, but it can be adjusted according to the size of the dust and the necessity.

The cooler 120 functions to rapidly remove odors and moisture mixed in the air having a high moisture content generated from food waste, etc., to rapidly form a droplet, and to remove moisture. As a result, it is possible to remove not only the moisture but also the odor contained within a few minutes. Further, the cooler can be constructed using a normal air conditioner.

In addition, the cooler 120 may include a heat pipe 121. Among the cooling methods, when the heat pipe 121 is used, the structure includes a container 122, a wick 123 formed on the inner surface of the container 122, and a working fluid accommodated in the wick 123 do. The wick 123 may be a porous material such as a mesh, foaming agent, felt, fiber or sintered metal, and the working fluid may be HCFC (hydrochlorofluorocarbon).

The heat pipe 121 includes an evaporator 121a, a condenser 121b and a heat insulating portion 121c disposed between the evaporator 121a and the condenser 121b.

The heat pipe 121 is provided at one end with a condensing portion 121b for evaporating the working fluid by absorbing external heat and the other end is provided with a condensing portion 121b for radiating heat to the outside and condensing the working fluid And the condensed working fluid is absorbed by the wick 123 and moved back to the evaporator 121a. That is, the working fluid condensed in the condensing part 121b is absorbed by the wick 123 and moves toward the evaporating part 121a by the capillary phenomenon, and the working fluid of the evaporating part 121a flows into the heat of the passing air And then the latent heat is given to the steam, the steam moves to the low-pressure condensate part, the heat is discharged, and the process of absorbing the heat to the wick 123 is repeated. However, this operation takes place very quickly without extra power consumption, so that the cost and convenience of maintenance are greatly improved. In addition, the heat pipe 121 can be installed to suit various kinds of on-site situations, which is advantageous in that it can be manufactured in a field-customized manner.

The heat pipe 121 has a high heat recovery rate because heat can be exchanged between the outer surface of one heat pipe and the outer surface of the heat pipe so that a secondary heat transfer surface fin can be added, There is an advantage that the power is saved because the circulation pump, the rotary motor, the total heat exchanger, and the like are not necessary in the heat recovery.

In addition, it is compact and simple structure, there is no driving part, there are few faults, each heat pipe is independent, there is no mutual influence in case of failure, and it is compact and lightweight so that it can be installed in the middle of pipe and workability is excellent. So that it is easily adjustable to fit the odor generating place as in the present invention.

Through this, it is possible to effectively treat the first stage of odor removal by effectively removing the moisture in the air while passing very strong odorous odor coming from the environmental facilities such as food waste and manure, which is very strong in moisture and odor, And further finely processed by a subsequent deodorization process.

On the other hand, the material of the heat pipe is preferably stainless steel which does not cause a problem even in contact with the strong acid and the strong alkali, and it is possible to coat the heat pipe with a material strong against a specific chemical ingredient. This is because, when water evaporated from food waste is condensed, it often has a strong acid or strong alkali property, so that it easily dissolves when using ordinary metals and greatly degrades its durability.

The UV deodorization unit 130 includes a UV irradiation unit 133 installed on the grid frame 131 and a photocatalyst unit 137 disposed on the rear surface of the UV irradiation unit 133, Can be exemplified.

The UV irradiation unit 133 may be a plurality of UV lamps installed on the grid frame 131. The UV lamp 130 irradiates ultraviolet rays onto the surface of the photocatalyst unit disposed on the rear side.

The photocatalyst 137 may be formed by spraying particles on the surface of a metal or plastic net material while applying an adhesive.

The particles to be coated here can be exemplified by silica particles having a mesoporous structure inside, and photocatalyst particles.

More preferably, TiO _{2, which} is a photocatalyst particle, is disposed on the surface of the core and porous silica particles are disposed on the outer surface of the core, and it can be manufactured using a self-assembly method using a known aerosol Can be exemplified.

Korean Patent No. 10-1000306, which is a technique of using photocatalyst, discloses that the porous soil, yellow soil, is spherical and its surface is coated with titanium dioxide to maximize the contact area. However, in this case, due to the titanium dioxide coating on the surface, It has been described that the adsorption performance due to the yellow soil does not disappear and the titanium dioxide has a porous property. However, since the titanium dioxide itself has no porous property, the effect of utilizing the porous material is almost It is difficult to expect and the photocatalyst function can be expected only. However, in the case of the registered patent, even if the air containing the malodorous component is momentarily exposed to ultraviolet rays, a considerable amount of air passes through the UV deodorizer without being removed by ultraviolet rays.

On the other hand, in the present invention, since the silica particles are made of a meso-porous structure, ultraviolet rays are irradiated through the pores with TiO ₂ contained in the mesoporous structure to remove the odor components, It acts to adsorb odorous components in innumerable pores. Therefore, the odor components (ammonia, primary amine, hydrogen sulfide, etc.) adsorbed on the pores formed on the surface of the silica particles temporarily are decomposed by the photocatalytic action of TiO ₂ . That is, in the present invention, since the adsorption of odorous components, ultraviolet ray irradiation, and photocatalytic decomposition are simultaneously carried out organically, there is an advantage that the deodorizing effect can be greatly improved as compared with the above patent.

The air having passed through the UV deodorizer 130 passes through the activated carbon adsorption unit 150, and the odor component is secondarily adsorbed and removed.

The air passing through the activated carbon adsorption unit 150 passes through the space between the malodor component neutralization unit 160, that is, the adjacent casing, and the remaining odor components are finally neutralized.

The malodor neutralizing unit 160 has a plurality of casings 161 having a structure in which the openings are formed in the upper and lower portions with a spacing space and the polymer resin and the deodorizing active component contained in each casing 161 are in a gel form And a polymer matrix 163 made of a polymer matrix.

3B, air may be introduced into the lower portion of the malodor neutralizing portion 160, and air may be discharged from the upper portion of the malodor neutralizing portion 160. Specifically, the cylindrical casing 161 may have a net- And is divided into a plurality of shelves 161a, and a plurality of polymer matrices 163 are placed in each shelf 161a. However, the polymer matrix 163 may not be placed on the left end or the right end of each shelf 161a so that air can move in a zigzag fashion, alternatively, alternatively, the flow paths may be staggered on the left and right sides of the shelf.

If the malodor neutralizing unit 160 is configured to move in a staggered manner, the contact area between the air containing odor and the polymer matrix 163 and the connection time are significantly increased, So that the deodorizing performance can be further improved greatly. In addition, when the air passes straight horizontally as shown in FIG. 2, unevenness of consumption of each polymer matrix 163 occurs due to the unbalance of the air volume. However, in the case of designing as shown in FIG. 3B, The polymer matrix 163 is uniformly consumed even when the polymer matrix 163 differs from place to place, so that the maintenance can be simplified and the cost can be reduced.

In addition, the malodor neutralizing unit 160 may be provided with a circulation pipe 165 for recirculating the air discharged to the upper side of the casing 161 to the lower side, which enables the treated air to be inspected and reprocessed if necessary Thereby making it possible to more effectively support air deodorization containing high-concentration odor components.

The polymeric resin of the polymer matrix 163 may be obtained by polymerizing monomers. Examples of the monomer include polyethylene glycol dimethyl ether, polyethylene glycol diethyl ether, polyethylene glycol dimethacrylate, polyethylene glycol diacrylate, polypropylene glycol Dimethacrylate, and polypropylene glycol diacrylate can be exemplified. When the monomer is polymerized, a deodorizing active component is added, and 1 to 10 parts by weight, based on 100 parts by weight of the monomer, may be added.

In addition, the deodorizing active ingredient may be a plant extract extracted from leaves, stems, roots, etc. of plants. For example, pine needles, persimmon leaves, green tea leaves, and Ginkgo biloba extract. However, the present invention is not limited thereto. Such an extract can be exemplified by a liquid phase obtained by extraction with hot water and then filtration. In addition to the deodorizing active component, a specific fragrance may be added if necessary.

According to the malodor neutralizing unit 160, the reaction of the malodor component to neutralize ammonia, the first amine and the hydrogen sulfide is as shown in the following reaction formulas (1) to (3).

Ammonia-Reaction (1)

The first amine-reaction formula (2)

Hydrogen sulfide - reaction formula (3)

The deodorizer 100 according to the present invention can control the optimum processing capacity by adjusting the air flow rates of the suction fan 103 and the exhaust fan 105. The deodorizer 100 filters the fine dust from the introduced air into the filter 110, A pretreatment for removing some odor components while condensing the moisture contained in the air through the cooler 120, an oxidation of the odor component through the UV deodorization unit 130, and an adsorption through the activated carbon absorption unit 150 , And the neutralization treatment through the neutralization unit 160 to maximize the deodorization efficiency of the organic gas and the like.

In addition, the industrial deodorizer of the present invention is advantageous in that the installation cost is lower than that of the conventional biofilter and chemical solution cleaning method, the operation and maintenance are easy, and the deodorization efficiency is also excellent. The industrial deodorizer of the present invention is advantageous in that it can be operated independently without requiring any additional facilities or equipment in comparison with the activated carbon adsorption and chemical solution cleaning method.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities. Accordingly, the scope of the present invention should be construed as being limited to the embodiments described, and it is intended that the scope of the present invention encompasses not only the following claims, but also equivalents thereto.

100: Deodorizer 101: Body
103: Suction fan 105: Exhaust fan
107a: first frame 107b: second frame
107c: third frame 108: opening
110: filter 120: cooler
121: Heat pipe 121a:
121b: Condenser 121c:
122: container 123: week
130: UV deodorization unit 131: grid frame
133: UV irradiation part 137: Photocatalyst part
150: activated carbon adsorption unit 160: odor component neutralizing unit
161: casing 161a: shelf
163: Polymer Matrix 165: Circulation tube

Claims (6)

A body;
A first frame to a third frame which define an inner space of the main body and in which openings are formed;
A suction fan installed at one side of the main body and sucking outside air;
A filter installed at one side of the first frame to remove dust in the air introduced through the suction fan;
A cooler installed at the other side of the first frame to cool the air passing through the filter to condense and deodorize moisture contained in the air;
A UV deodorizing unit installed at one side of the second frame for irradiating ultraviolet rays;
An activated carbon adsorption unit disposed on the other side of the second frame;
A malodor component neutralizing part installed at one side of the third frame and containing a deodorizing active component for neutralizing a malodor component contained in air;
And an exhaust fan installed on the other side of the main body in connection with the malodor neutralizing part and discharging the deodorized air to the outside,
The cooler comprises a heat pipe,
The heat pipe includes a container, a wick formed on the inner surface of the container, and a working fluid accommodated in the wick, wherein one end is provided with an evaporation portion for evaporating the working fluid by absorbing external heat, And the condensed working fluid is absorbed by the wick and moved to the evaporator,
The UV deodorization unit includes a UV irradiation unit installed in the lattice frame and a photocatalyst unit disposed behind the UV irradiation unit and formed on the surface of the metal mesh,
The malodor neutralizing unit includes a plurality of casings having a structure in which upper and lower layers are stacked with a spacing space and an opening hole is formed; And a polymer matrix containing a polymer resin contained in the casing and a deodorizing active component in a gel form.
delete delete The method according to claim 1,
Wherein the photocatalyst unit comprises:
Wherein the interior of the deodorizer comprises hollow silica particles of mesoporous structure and photocatalyst particles contained therein.
delete The method according to claim 1,
Wherein the deodorizing active ingredient is a plant extract.

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