KR20110126494A - Centrifugal separation type purification apparatus of air - Google Patents

Abstract

PURPOSE: A centrifugal-based air purifying apparatus is provided to effectively purify air by circularly moving air containing various harmful materials in a reactor and collecting the harmful materials based on neutralization and reduction. CONSTITUTION: A centrifugal-based air purifying apparatus includes a main body(20), a suction duct(30), a suction unit(40), an additive supplying part(90), a reactor(50), a collecting unit(60), and a discharging unit(70). The suction duct is in connection with a spraying chamber(25) and forms an air path. The suction unit sucks air from the suction duct. The additive supplying part sprays a chemical additive to air which is introduced into the main body through a nozzle(91). The reactor is installed at one side of the main body. The collecting unit sucks the introduced air to the crossing direction of the sucking direction of the suction unit. The discharging unit discharges air through the reactor to the outside through a discharging duct(100).

Description

Centrifugal separation type purification apparatus of air

The present invention relates to a centrifugal type air purifying apparatus, and more particularly, to an air purifying apparatus capable of decomposing various harmful substances such as odors and volatile organic compounds contained in the air using a centrifugal separation method to create a pleasant environment. It is about.

Various air purifiers are used at home or industrial sites to remove odors, volatile organic compounds and other harmful substances in the air. For example, in an incinerator or a chimney of a factory, an air purifier is used to remove harmful substances and dusts contained in exhaust gas.

Generally speaking, odors are those that stimulate the nervous system of a person and cause mental and physical damage. These odor-causing substances vary greatly depending on the source, and refineries, chemical plants, manure and livestock wastewater treatment plants, sewage treatment plants, and municipal waste landfills are considered to be major sources of odor in cities.

Volatile organic compounds are harmful substances and odor-causing substances that have harmful effects on the human body such as disorders of the respiratory organs and carcinogenicity. It is causing environmental pollution.

Volatile Organic Compounds (VOCs) are easily evaporated into the atmosphere due to their high vapor pressure, and when they coexist with nitrogen oxides in the atmosphere, they cause photochemical reactions to produce photochemical oxidizing substances such as ozone and peroxyacetylnitrate (PAN). Hydrocarbon compounds that cause smog.

These volatile organic compounds are mainly caused by incomplete combustion of fuels, volatilization of petroleum products, organic solvents and evaporation of paints. Especially, automobiles, reservoirs, gas stations, laundry, printing and publishing facilities, and various paints are easily found around our lives It is a large-scale workplace, such as facilities, petroleum refining, and petrochemical manufacturing facilities.

Since the treatment of odor or volatile organic compounds is similar, conventional odor removal methods are classified into physical, chemical and biological treatment methods. For example, odor, combustion, oxidation, adsorption, and microbial treatment are mainly used. Etc.

Combustion method is effective to remove almost all combustible odorous substances, but it is expensive to maintain fuel or catalyst, and there is a risk of nitrogen oxide and explosion if it is neglected in operation management.

In addition, the washing method is a method in which the malodorous gas is washed with water, an acid or an aqueous alkali solution and deodorized. This method has the advantages of relatively simple equipment and low operating cost, but it has a narrow application range, difficult treatment of complex odor, and measures to prevent corrosion of facilities by using chemical solution, and wastewater, which is a secondary pollution source, is generated. There is this.

In addition, the oxidation method is a method of oxidizing and removing odor components by utilizing the powerful oxidation of ozone, which is relatively efficient in removing a large amount of gas due to low power consumption and easy maintenance, but ozone alone has a small application range and insufficient performance. There are disadvantages.

Adsorption method is to remove odor by using activated carbon.In the pores of activated carbon, various odorous substances are accumulated and adsorbed in saturation state.Therefore, there is no deodorizing effect. When the concentration of the target material is high, there is a disadvantage in that the concentration of the pretreatment such as washing, absorption, cooling, and condensation is reduced in parallel, followed by activated carbon adsorption.

Microbial treatment is a method of decomposing odorous substances adsorbed using microorganisms when odors pass through wood chips or soil. When the growth conditions of microorganisms are properly formed, the ability to remove odors is excellent and secondary pollutants are generated. On the other hand, it takes up a lot of area and takes a lot of time.

The present invention has been made to improve the above problems, it is possible to effectively purify the air by neutralizing and reducing the harmful substances by the circular motion of the air containing various harmful substances such as odor, volatile organic compounds in the reaction chamber The purpose is to provide a device.

Centrifugal air purification apparatus of the present invention for achieving the above object is a cylindrical body; An intake duct connected to an injection chamber formed at an inlet side of the main body and having an air passage formed therein; A suction unit installed inside the main body to suck air from the intake duct; An additive supply unit for injecting a chemical additive into the air introduced into the main body through a nozzle installed in the injection chamber; a cylindrical reaction chamber installed at one side of the main body; The air flowing into the main body is sucked into the reaction chamber, and sucked in a direction crossing the suction direction of the suction unit, forming a concentric circle with the center of the reaction chamber and having a different air flow direction. A collection unit for forming a tonic region for neutralizing and reducing harmful substances between the fluid flow regions; And a discharge unit installed at an outlet side of the reaction chamber to discharge air passing through the reaction chamber to the outside through an exhaust duct.

The suction unit penetrates the center of the main body and is rotatably supported by the main body, a plurality of first suction blades coupled to the first rotational shaft to suck air, and connected to the first rotational shaft. And a first driving part for rotating the first rotary shaft.

The collection unit penetrates through the center of the reaction chamber and is disposed at a right angle with the first rotational shaft and is rotatably supported by the reaction chamber, and coupled to an end of the second rotational shaft and connected to an inlet of the reaction chamber. A second suction blade which is installed to blow air inside the main body into the reaction chamber, and a plurality of second suction blades are installed at a predetermined interval on the second rotation shaft and supply air introduced into the reaction chamber by the second suction blade. A plurality of blades for centrifugal separation which form an air flow region which is moved to form a flow opposite to the flow of the air flow region at a point adjacent to the inner circumferential surface of the reaction chamber with the circumferential region as the boundary; And a second driving part for rotating the second rotating shaft.

The chemical additive is characterized in that the acid solution dissolved ozone.

As described above, the air purifier of the present invention can effectively remove various harmful substances such as odors, volatile organic compounds, radon, and dioxins contained in the air.

In addition, there is no need to replace ancillary equipment such as a filter as in the prior art, and the energy consumed is low, so that maintenance costs are low and management is easy.

1 is a cross-sectional view schematically showing an air purifier according to the present invention;
2 is a cross-sectional view showing the inside of the reaction chamber,
3 is a cross-sectional view schematically showing an air purifier according to another embodiment of the present invention.

Hereinafter, an air purifier according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the air purifier 10 of the present invention is largely the main body 20, the intake duct 30, the suction unit 40, the additive supply unit 90, the reaction chamber ( 50, a collection unit 60, and a discharge unit 70 are provided.

The main body 20 is cylindrical and has an open structure with an inlet formed thereon. An injection chamber 25 is formed at an upper portion of the main body 20. The injection chamber 25 is connected to the upper end of the main body 20 and is formed in a dome shape in which the inner diameter gradually decreases as it proceeds upward. The intake duct 30 is connected to the upper portion of the injection chamber 25. An air passage is formed in the intake duct 30, and air to be purged along the air passage is introduced from the outside.

The additive supply unit 90 injects a chemical additive into the air introduced into the body 20 by the suction unit 40. The additive supply unit 90 is connected to at least one nozzle 91 installed in the injection chamber 25, an additive supply line 93 connected to the nozzle 91 to extend a predetermined length, and an additive supply line 93. Storage tank 95 in which a certain amount of additive is stored, and the pump 97 is installed on the additive supply line 93 to pressurize the chemical additive to the nozzle 91.

The nozzle 91 is installed to penetrate from the outside of the injection chamber 25 to the inside. Therefore, the end of the nozzle 91 is exposed to the interior of the injection chamber 25. The nozzle 91 atomizes the chemical additive in the form of fine droplets in the air passing through the spray chamber 25 and sprays the fine particles. The chemical additives applied to the present invention are mixed with the introduced air to trap or oxidize various harmful substances such as odors, volatile organic compounds radon and dioxin in the air.

In the context of the present invention 'odor' refers to the smell of hydrogen sulfide, mercaptans, amines, and other irritating gaseous substances to stimulate the olfactory human sense of discomfort and aversion. Odors include ammonia, methylmercaptan, hydrogen sulfide, methyl sulfide, methyl disulfide, trimethylamine, acetaldehyde, styrene and the like. The substances causing such odors vary greatly depending on the source, and refineries, chemical plants, manure and livestock wastewater treatment plants, sewage treatment plants, municipal waste landfills, etc. are the main sources of odors in cities.

In the specification of the present invention, 'Volatile Organic Compound (VOC)' has a high vapor pressure and is easily evaporated into the atmosphere and undergoes photochemical reaction under the action of sunlight when coexisted with nitrogen oxide in the atmosphere to cause photochemical reactions such as ozone and peroxyacetylnitrate (PAN). Hydrocarbon compounds that produce oxidative materials and cause photochemical smog. For example, 37 substances including benzene, formaldehyde, and chloroform were selected in consideration of volatility (raid vapor pressure of 10.3 kPa or more), amount of use, and human risk (carcinogenicity). Radon (Rn) is a colorless and odorless gas produced by radioactive decay of uranium naturally present in rocks and soils. The International Cancer Research Center (IARC) defines as a class 1 carcinogen with asbestos in terms of health risks. After smoking, it is known as a high-risk substance that causes lung cancer. Dioxine is a highly toxic organic chlorine compound that occurs when incineration of plastics or waste. Dioxins are known to cause cancer or cause birth defects. In addition to the above-mentioned harmful substances, it also includes other organic compounds that harm humans and the environment.

Chemical additives can be applied with different properties depending on the degree of contamination. That is, harmful substances may be removed by neutralization, oxidation, or reduction using acidic or alkaline aqueous solutions as chemical additives. For example, 20 g of potassium chloride, 50 g of calcium hydroxide, 20 g of aluminum hydroxide, and 30 g of ammonia may be mixed with 1000 g of water, or 100 g of sodium carbonate, 10 g of acetic acid, and 140 g of ammonia may be mixed with 1000 g of water. Or ozone water in which ozone is dissolved in water. The chemical additive is not limited to the above-described embodiment.

Preferably, ozone water which is an acidic liquid is applied as the chemical additive. The oxidizing power of ozone is a well known fact and is effective for treating various harmful substances in the air. As the acid solution applied to the present invention, ozone water in which 1 to 80 ppm of ozone is dissolved may be used.

The suction unit 40 installed in the main body 25 sucks air from the intake duct 30 and flows it into the main body 20.

In the illustrated example, the suction unit 40 penetrates the center of the body 20 and is rotatably supported by the body 20, and is coupled to the first rotation shaft 41 and air. It consists of a plurality of first suction blades 43 for sucking the first driving unit is connected to the first rotary shaft 41 to rotate the first rotary shaft 41.

The first rotary shaft 41 is supported by the upper end of the disc-shaped support panel 21 is installed across the inlet of the main body 20, the lower end is supported on the bottom of the main body 20. The support panel 21 is connected to and fixed to the plurality of connection bars 23 extending from the side wall of the main body 20. The first suction blades 43 are installed at regular intervals from the top to the bottom of the first rotation shaft 41. The first driving unit includes an electric motor 45 coupled to the lower portion of the main body 20, and power transmission means for transmitting the rotational force of the electric motor 45 to the first rotation shaft 41. It consists of a drive pulley coupled to the drive shaft of the electric motor 45 as a power transmission means, a driven pulley coupled to the end of the first rotary shaft 41, and a belt 47 connecting the drive pulley and the driven pulley. Unlike shown, the power transmission means may be made of a drive and driven sprocket, and a chain connecting both sprockets.

As the suction unit 40 operates, the pump 97 of the additive supply unit also moves together so that chemical additives are injected into the air passing through the spray chamber 25 through the nozzle 91. In addition, the air and the chemical additive are mixed by the rotation of the first suction blade 43 inside the main body 20, and the movement of the air particles increases as the air density increases. Therefore, as the contact between harmful substances and ozone in the air increases, the treatment efficiency of the hazardous substances is increased. In addition, the swirl flow is formed inside the main body 20 by the first suction blade 43, and the dust contained in the air is separated and settled by centrifugal force. Excess additive along with the settled dust is discharged through the drain pipe 29 formed on the bottom side of the body 20.

Partly processed air from the main body 20 flows into the reaction chamber 50 to process residual harmful substances. Treatment of harmful substances by ozone water in the main body 20 is effective for odorous components having large molecules and substances which react quickly with ozone, but harmful substances composed of small molecules such as ammonia, methane and hydrogen disulfide have low treatment efficiency. Therefore, the residual harmful substances are collected and removed in the reaction chamber 50.

The reaction chamber 50 is installed on one side of the main body 20. The reaction chamber 20 is formed in a cylindrical shape having a predetermined size space therein. The diameter of the reaction chamber 20 is designed to be equal to the height of the body 20. The reaction chamber 50 is coupled to the body 20 so that the center of the reaction chamber 50 is perpendicular to the center of the body 20.

The collection unit 60 installed in the reaction chamber 50 sucks air introduced into the main body 20 to collect harmful substances in the air and neutralize and reduce them. The collection unit 60 penetrates through the center of the reaction chamber 50 and is disposed at a right angle with the first rotation shaft 41 and is rotatably supported by the reaction chamber 50 and the second rotation shaft ( It is coupled to the end of the 61 and is installed at the inlet of the reaction chamber 50 to blow the air in the main body 20 into the reaction chamber 50 and the second suction blade 63 and the second rotary shaft 61 A plurality of centrifugal blades 65 are formed at regular intervals, and the blades 65 are centrifugal to form an isolating region by circularly moving the air introduced into the reaction chamber 50 by the second suction blade 63 and the second rotating shaft. And a second driving part connected to the 61 to rotate the second rotation shaft 61.

In the illustrated example, the reaction chambers 50 are installed one by one on both left and right sides of the main body 20. The reaction chamber 50 on both the left and right sides has the same configuration and function. 3, only one reaction chamber 50 may be installed at one side of the main body 920.

The second rotating shaft 61 is disposed to penetrate the center of the reaction chamber 50. Therefore, the second rotary shaft 61 is installed in the direction orthogonal to the first rotary shaft 41. The second rotary shaft 61 is supported by one end of the support panel 67 formed at the inlet of the reaction chamber 50 so as to be rotatable. The support panel 67 is fixed by a connection bar 69 connected to the reaction chamber 50. The other end of the second rotation shaft 61 is rotatably supported on the side wall of the housing 71 to be described later.

The second suction blade 63 installed at the inlet side of the reaction chamber 50 introduces air inside the body 20 into the reaction chamber 50. The second suction blade 63 is coupled to the end of the second rotation shaft 61. The second driving unit for driving the second rotary shaft includes an electric motor 81 installed outside the reaction chamber 50 and a power transmission means for transmitting the rotational force of the electric motor 81 to the second rotary shaft 61. do. It consists of a drive pulley coupled to the drive shaft of the electric motor 81 as a power transmission means, a driven pulley coupled to the end of the second rotary shaft 61, and a belt 85 connecting the drive pulley and the driven pulley. Unlike shown, the power transmission means may be made of a drive and driven sprocket, and a chain connecting both sprockets.

When the second rotating shaft 61 is rotated by the second driving unit, the second suction blade 63 sucks air in the main body 20 into the reaction chamber 50. At this time, the suction direction of the second suction blade 63 crosses the suction direction of the first suction blade 43. That is, if the first suction blade 43 sucks air in the vertical direction, the second suction blade 65 sucks air in the horizontal direction.

A plurality of centrifugal blades 65 installed on the second rotary shaft 61 are installed at regular intervals. The rotation radius of the centrifugal blade 65 is preferably formed from 6/10 to 8/10 of the radius of the reaction chamber. The centrifugal blade 65 reacts the air introduced into the reaction chamber 50 by the second suction blade 63 in the direction in which the radius of the reaction chamber 50 extends, that is, the second rotating shaft 61. It serves to push in the direction of the inner circumferential surface of the chamber 50. At this time, the inside of the reaction chamber 50 is formed with a flow of air pressurized in the direction of the inner circumferential surface by the rotation of the centrifugal blade 65 and a flow of air coming back to the inner circumferential surface of the reaction chamber 50.

That is, as shown in FIG. 2, two fluid flow regions are formed concentrically with the center of the rotation shaft 65. When the two fluid flow zones are referred to as first and second fluid flow zones, the first fluid flow zone 1 includes a rotation zone of the centrifugal blade 65 and is smaller than the rotation radius of the centrifugal blade 65. Is formed larger. The first fluid flow region 1 is a region in which centrifugal force generated by the rotation of the centrifugal blade 65 acts on the particles in the air. In the first fluid flow region 1, air flows in the direction of the inner circumferential surface of the reaction chamber 50 at the second rotation shaft 61. A second fluid flow region 3 is formed outside the first fluid flow region 1. The second fluid flow region 3 is formed adjacent to the inner circumferential surface of the reaction chamber 50. In the second fluid flow region 3, a flow of air that hits the inner peripheral surface of the reaction chamber 50 and returns is formed.

Between the first fluid flow region 1 and the second fluid flow region 3 having different flow directions, the flow of air flows in contact with each other to form an isolating region 5 in which the density of air is increased. In the tornating region 5, the harmful substances are compressed and induced in the neutralization reduction process, and the harmful substances collected together with the chemical additives are discharged through the outlet tube 57 formed at the lower portion of the reaction chamber 50. The speed of the neutralization reduction process of the toxic substance is determined by the rotational speed of the centrifugal blade 65 and the pressure of the tornating zone 5.

Air passing through the reaction chamber 50 is discharged to the outside through the exhaust duct 100 by the discharge unit 70. The discharge unit 70 includes a housing 71 installed at the outlet side of the reaction chamber 50 and an impeller 73 installed inside the housing 71 and coupled to the second rotating shaft 61. In the example shown, one discharge unit 70 is connected to each reaction chamber 50. The impeller 73 sucks air in the reaction chamber 50 and blows it into the exhaust duct 100. The discharge port is formed in the housing 71, and the exhaust duct 100 is connected to the discharge port. The air blown into the exhaust duct 100 is discharged to the outside through the outlet of the exhaust duct 100.

Preferably, the outlet of the exhaust duct 100 is preferably provided with post-treatment means for decomposing the chemical additive contained in the discharged air. For example, when ozone water is used as a chemical additive, a catalyst layer (not shown) filled with a solid catalyst may be applied to the outlet side of the exhaust duct 100 as a post-treatment means. It uses a catalyst that can decompose ozone as a solid catalyst. As an example of the catalyst, manganese oxide may be used as a main component, and vanadium oxide, copper oxide, copper oxide, or the like may be used as a component. The catalyst is used after being supported on activated carbon, silica, zeolite and the like. Ozone, which is in contact with the surface of the catalyst in the presence of a manganese oxide catalyst, is decomposed to oxygen at the active point of the catalyst as shown in the following scheme.

2O ₃ + MnO ₂ → 3O ₂ + MnO ₂

When the above-described configuration is applied, since ozone is decomposed into oxygen when passing through the catalyst layer, it has the advantage of increasing the amount of oxygen in the air discharged to the outside.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the invention.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

20: main body 25: spray chamber
30: Intake duct 40: Suction unit
41: first rotating shaft 43: first suction blade
50: reaction chamber 60: decomposition unit
61: second rotating shaft 63: second suction blade
65: blade for centrifugation 70: discharge unit
73: impeller 91: nozzle
100: exhaust duct

Claims (4)

A cylindrical body;
An intake duct connected to an injection chamber formed at an inlet side of the main body and having an air passage formed therein;
A suction unit installed inside the main body to suck air from the intake duct;
An additive supply unit for injecting a chemical additive into the air introduced into the main body through a nozzle installed in the injection chamber;
A cylindrical reaction chamber installed at one side of the main body;
The air flowing into the main body is sucked into the reaction chamber, and sucked in a direction crossing the suction direction of the suction unit, forming a concentric circle with the center of the reaction chamber and having a different air flow direction. A collection unit for forming a tonic region for neutralizing and reducing harmful substances between the fluid flow regions;
And a discharge unit installed at an outlet side of the reaction chamber and discharging the air passing through the reaction chamber to the outside through an exhaust duct. The apparatus of claim 1, wherein the suction unit comprises: a first rotating shaft penetrating the center of the main body and rotatably supported by the main body, and a plurality of first suction blades coupled to the first rotating shaft to suck air; And a first driving part connected to the first rotary shaft to rotate the first rotary shaft. The method of claim 2, wherein the collection unit is coupled to the second rotation axis and the end of the second rotation shaft which is disposed perpendicularly to the first rotation axis through the center of the reaction chamber and rotatably supported by the reaction chamber; A second suction blade installed at an inlet of the reaction chamber to blow air inside the main body into the reaction chamber, and a plurality of second suction blades are installed at a predetermined interval on the second rotation shaft, and inside the reaction chamber by the second suction blade; Centrifugal blades for forming an air flow region to form a flow opposite to the flow of the air flow region of the point adjacent to the inner circumferential surface of the reaction chamber by the circular motion of the air introduced into the circle; And a second driving part connected to a second rotating shaft to rotate the second rotating shaft. The centrifugal air purifier according to claim 1, wherein the chemical additive is an acid solution in which ozone is dissolved.

Images