KR20220026665A - Harmful Toxic Substance and Non-Biodegradable Malodor Gas Treatment System - Google Patents

Abstract

The present invention relates to a system for treating harmful toxic substances and hardly decomposable malodorous gas. The system for treating harmful toxic substances and hardly decomposable malodorous gas of the present invention can efficiently remove malodorous gas. The system for treating harmful toxic substances and hardly decomposable malodorous gas of the present invention includes a malodor removing device, a first reactor, a second reactor, a plasma combustion oxidation system combustor, and a pressure control unit.

Description

Harmful Toxic Substance and Non-Biodegradable Malodor Gas Treatment System

This application relates to a treatment system that can effectively remove VOCs, PAHs, non-decomposable gases, and malodorous gases among harmful toxic substances in waste gas, and which can efficiently remove odor gases including hazardous toxic substances and hardly decomposable waste gas components In more detail, it relates to a dual plasma system and a Plasma Thermal Oxidation System (PTO), which are pre-treatment devices for removing harmful toxic substances and odors.

Global warming, extreme weather, and environmental pollution are acting as important factors in the international community, and are emerging as global problems transcending regions and countries. In Korea, problems such as rapid economic and industrial development, urbanization, increase in automobile and energy consumption, increase in industrial activity, energy source diversification policy, and excessive use of fossil fuels are emerging. In particular, many environmental pollutants are emitted from industrial complexes and various industrial facilities. The need for countermeasures to these problems is being raised in Korea and around the world. With the development of industry, volatile organic compounds (VOCs) and polycyclic aromatic hydrocarbons (PAHs, polycyclic aromatic hydrocarbons) are continuously generated among hazardous toxic substances in various industrial processes. PAHs, which are hazardous and toxic substances, are aromatic hydrocarbons having two or more benzene rings. Substances with 2 to 4 benzene rings are adsorbed to gas or solids, and substances with 5 or more benzene rings are adsorbed to solids. Among them, Benzo(a)anthracene, Benzo(b)fluoranthene, Benzo(k)fluoranthene, Benzo(a)pyrene, Indeno(1,2,3-c,d)pyrene, Dibenzo(a,h) Anthracene is known as a carcinogen, and PAHs are carcinogenic and genetically modified substances, widely distributed in the environmental atmosphere, and WHO manages Benzo(a)pyrene as a carcinogen. Among harmful toxic substances, the main sources of VOCs emission are paint, paint and plastic related factories, chemical factories, oil refineries, gas stations, and laundries. It is affected by the Photochemical Ozone Creation Potential (POCP). The ozone generation potential, ozone generation contribution rate, and concentration throughout Korea are high. Among VOCs, Toluene, Ethylene, n-Butane, Propane, m,p-Xylene, i-Pentane, Ethylbenzene, n-Pentane, Propylene, and o-Xylene The concentration was high, and it was confirmed that management measures were required. In particular, incombustible waste gases (VOC _S , PFC _S , NF ₃ , SF ₆ ) including hazardous toxic substances VOCs are evaluated as major causes of air pollution such as atmospheric warming and extreme weather, and international regulations are spreading. In general, odor gas removal and reduction facilities for VOCs, PAHs, non-decomposable waste gas, and malodorous gas among the harmful toxic substances generated in the industrial field include VOCs, PAHs, non-decomposable gas, and odor gas among hazardous toxic substances. It is running into a limit that cannot be effectively eliminated.

The present invention is to solve the problems of the prior art, and 1) efficiently removes VOCs, PAHs, difficult-to-decompose waste gas, and malodorous gas among harmful toxic substances in waste gas, 2) VOCs, PAHs, It is a malodorous gas treatment system that effectively treats difficult-to-decompose waste gases (VOC _S , PFC _S , NF ₃ , SF ₆ ), etc. The purpose is to provide a device for treating harmful toxic substances, difficult-to-decompose waste gas, and odor gas.

VOCs, PAHs, incombustible waste gas, and malodorous gas treatment system among harmful toxic substances in waste gas according to the present invention for solving the above problems A pre-treatment device was installed to remove harmful toxic substances and odors.

In the apparatus for treating harmful toxic substances, incombustible gas, and odor gas, the inlet 110 through which the non-decomposable odor gas is introduced, the odor removal gas outlet 111 formed at the rear end, and the particles installed adjacent to the outlet. Filters for removal (131, 132), a photocatalyst filter 140 for decomposing and removing odor components, a UV lamp 150 for irradiating the surface of the photocatalyst filter directly, and a blower fan 120 installed at the rear end of the outlet to blow air is composed of

In the plasma combustion oxidation system (PTO) device for purifying the incombustible waste gas from which the harmful toxic substances and odors have been removed, a purification space 311 for accommodating the large-capacity odor removal gas is formed therein, and the purified a first reactor 310 having a purification gas outlet 312 through which gas is discharged; Both ends are penetrated and an inner space 321 is formed therein, and one end of the first reactor 310 is such that the inner space 321 and the purification space 311 of the first reactor 310 communicate with each other. It is installed on the outer peripheral surface, the other end is formed with a flame inlet hole 322 through which a plasma combustion oxidation system (PTO) flame for purifying the removal of the harmful toxic substances and odor gas is formed, and the harmful toxic substances and odor gas supplied from the outside are formed. a second reactor 320 for mutually reacting removal and the plasma combustion oxidation system (PTO) flame in the inner space 321; And it is installed at the other end of the second reactor 320, the plasma by microwave plasma electromagnetic wave oscillation is generated inside the second reactor ( Plasma combustor 330 radiating to the internal space 321 of 320; includes.

A plurality of the second reactors 320 are installed at regular intervals along the circumference of the first reactor 310 , and each second reactor 320 is located on the peripheral surface of the first reactor 310 . Installed in a tangent line to the second reactor 320, the gas reacts with the plasma combustion oxidation system (PTO) flame and the primarily purified gas is the inner wall surface of the first reactor 310 ( 313) to form a vortex, and may be secondarily purified while flowing into the purification space 311 of the first reactor 310.

The second reactor 320 is formed in a cylindrical shape, and a waste gas inlet 323 to which the gas is supplied from the outside is formed on one side of the outer circumferential surface, and communicates with the flame inlet 322 inside the inner space 321 A cylindrical inner tube portion 324 is formed to divide the gas into a waste gas space portion 321b, a space to which the gas is supplied, and a flame space portion 321a, a space to which the plasma combustion oxidation system (PTO) flame is supplied. , in the inner tube portion 324, the gas supplied to the waste gas space portion 321b flows into the flame space portion 321a so that the gas space portion can interact with the plasma combustion oxidation system (PTO) flame. A slit portion 325 having a slit hole 325a for mutually communicating the 321b and the flame space portion 321a may be disposed.

In addition, in the slit hole 325a of the slit part 325, the gas vortexed into the waste gas space 321b is guided into the flame space part 321a and the wall surface is tapered so that it flows. The inclined surface 325b may be formed in the shape of an inclined plane.

In addition, in the lower portion of the first reactor 310, by controlling the pressure inside the purification space 311 to control the plasma combustion oxidation system (PTO) vortex formation of the gas discharged from the second reactor 320 A pressure control unit 340; may be further installed.

In addition, the gas storage tank 220 may be installed before the odor removal gas discharged from the odor removal device is supplied to the post-stage plasma combustion oxidation system (PTO) device.

According to the treatment system that effectively removes harmful toxic substances, VOCs, PAHs, non-decomposable gas, and odor gas according to the present invention, the gas from which harmful toxic substances, difficult decomposable waste gas, and odor are removed from the front end is converted into a plasma combustion oxidation system (PTO) The flame can be used to efficiently purify the incombustible gas.

1 is a block diagram of a system for treating hazardous toxic substances, incombustible waste gas, and malodorous gas according to an embodiment of the present invention.
2 is a configuration cross-sectional view of a first reactor according to an embodiment of the present invention.
3 is a configuration cross-sectional view of a second reactor according to an embodiment of the present invention.
4 is a cross-sectional view illustrating a configuration of a slit portion of a second reactor according to an embodiment of the present invention.
5 is a configuration cross-sectional view of a plasma combustion oxidation system (PTO) combustor according to an embodiment of the present invention.

Hereinafter, embodiments in which those of ordinary skill in the art to which the present invention pertains can easily practice the present invention will be described in detail with reference to the accompanying drawings. However, in the detailed description of the principle of operation of the preferred embodiment of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the present application, terms such as “comprising” or “comprising” are intended to designate that the features, numbers, components, parts, or combinations thereof described in the specification exist, and include one or more other features, numbers, operations, It should be understood that the possibility of the presence or addition of components, parts or combinations thereof is not precluded in advance.

In addition, the inclusion of any component does not exclude other components unless otherwise stated, but means that other components may be further included.

In addition, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a block diagram of a system for treating hazardous toxic substances, recalcitrant waste gas, and malodorous gas according to an embodiment of the present invention.

Referring to the present invention, in the system for treating harmful toxic substances, difficult-to-decompose waste gas, and odor gas of the present invention, the first filter 131 and the second filter 132 mainly to remove particulate matter, and the photocatalyst odor component to decompose the odor component A first reactor 310, a second reactor 320, a plasma combustor 230 and a malodor gas removal device consisting of a photocatalytic filter 140 for decomposing and removing the photocatalytic filter and a UV lamp 150 for irradiating the surface of the photocatalytic filter directly. It was composed of a plasma combustion oxidation system (PTO) including a pressure control unit 340 and a combustion device.

The difficult-to-decomposable odor gas containing harmful toxic substances and difficult-to-decompose waste gas is supplied through the inlet 110, and then particulate matter and foreign substances are removed by the filter 131, and the photocatalyst filter 140 and the photocatalyst filter surface at the rear end are directly connected. After removing harmful toxic substances and odorous substances by the irradiating UV lamp 150 , it passes through the second filter 132 at the last stage to remove other remnants, and then is discharged to the rear stage. The photocatalyst can exclude secondary contamination by completely oxidizing/decomposing pollutants, can treat pollutants in liquid and gaseous phases, and has excellent odor removal ability. The UVC of the UV lamp is irradiated to the surface of the photocatalytic filter to generate ozone (O3), and odorous substances can be primarily oxidized and removed by the ozone. In addition, the UV lamp irradiates UVA to the surface of the photocatalytic filter, which causes a photocatalytic reaction to generate OH radicals. The OH radical has a stronger oxidizing power than chlorine or ozone, and can oxidatively decompose unreacted pollutants into water and carbon dioxide gas.

2 is a configuration cross-sectional view of a first reactor according to an embodiment of the present invention.

The first reactor 310 is configured to receive harmful toxic substances, incombustible waste gas, and odor removal gas discharged from the odor gas removal device by the second reactor 320 and react in the internal space for secondary purification As an element, a purification space 311 for accommodating a large-capacity gas is formed therein, and a purification gas outlet 312 through which the purified gas is discharged is formed at the top.

Here, a microbubble plasma wet type scrubber 360 is disposed at the purification gas outlet 312 to mix solids and harmful gas components that can be included in the purified gas discharged from the purification gas outlet 312 with the reaction solution. It may be provided to be removed by reaction.

In addition, the first reactor 310 has a cylindrical shape with a hole in it, and the upper and lower sides are relatively narrow compared to the central part, that is, the inner diameter is narrowed from the central part to the upper and lower sides. desirable.

This expands the volume of the space in which the odor removal gas is reacted so that the gas discharged from the second reactor 320 installed in the first reactor 310 can be processed in a large capacity, as well as by the pressure control unit 340 . This is to facilitate pressure control.

The second reactor 320 is a component that primarily purifies the gas by mixing and reacting the gas introduced therein with the plasma combustion oxidation system (PTO) flame, both ends are penetrated and there is an internal space ( 321) is formed, and one end is installed on the outer circumferential surface of the first reactor 310 so that the inner space 321 and the purification space 311 of the first reactor 310 communicate with each other, and the other end has the gas A flame inlet hole 322 through which a plasma combustion oxidation system (PTO) flame for purifying is formed is formed so that the gas supplied from the outside and the plasma combustion oxidation system (PTO) flame are mutually in the inner space 321 react

3 is a structural cross-sectional view of a second reactor according to an embodiment of the present invention, and FIG. 4 is a structural cross-sectional view of a slit portion of the second reactor according to an embodiment of the present invention.

The second reactor 320 is formed in a cylindrical shape, and a gas inlet 323 through which odor removing gas is supplied from the outside is formed on one side of the outer peripheral surface, and communicates with the flame inlet hole 322 inside the inner space. Plasma combustion oxidation system (PTO) ignited from the plasma combustion oxidation system (PTO) combustor 330 through the flame inlet hole 322 and the waste gas space portion 321b, which is a space to which the odor removal gas is supplied (321) A cylindrical inner tube portion 324 that is divided into a flame space portion 321a, which is a space to which a flame is supplied, is formed. Here, in the inner tube portion 324, the odor removal gas and the flame space portion 321a are provided so that the odor removal gas supplied to the waste gas space portion 321b flows into the flame space portion 321a and reacts with the plasma flame. ), a slit portion 325 having a slit hole 325a to communicate with each other is disposed.

Accordingly, the high-pressure odor removing gas supplied to the waste gas space 321b through the odor removing gas inlet 323 is introduced into the relatively low pressure flame space 321a through the slit hole 325a. The odor removal gas and the plasma combustion oxidation system (PTO) flame supplied to the inside of the flame space 321a and the odor removal gas react while being mixed with each other, thereby being able to be primarily purified in the second reactor 320. .

And, one end of the second reactor 320 is provided with a connection part 326a fastened to the first reactor 310, and the connection part 326a communicates with the flame space part 321a and is primarily A discharge hole 326 for discharging the purified odor removing gas to the purification space 311 of the first reactor 310 is formed.

At this time, in the slit hole 325a of the slit part 325, as shown in FIG. 4, the odor removal gas vortexes into the odor removal gas space 321b and the introduced odor removal gas flows into the flame space 321a. It is preferable that the inclined surface 325b is formed with a tapered wall surface so as to be guided and introduced therein.

In addition, the second reactor 320 is installed in a plurality of numbers above and below the horizontal center line of the first reactor 310, respectively, and the second reactor 320 installed below the horizontal center line is It is disposed in a state inclined at a certain angle upward with respect to the horizontal center line and discharges the odor removal gas that vortexes while ascending to the purification space 311 of the first reactor 310, and is installed below the horizontal center line The second reactor 320 is disposed to be inclined at a predetermined angle downward with respect to the horizontal center line, and is disposed to discharge the odor removing gas that is vortexed while descending in the purification space 311 of the first reactor 310 . it is desirable to be

5 is a configuration cross-sectional view of a plasma combustion oxidation system (PTO) combustor according to an embodiment of the present invention.

Accordingly, as shown in FIG. 5, the purified gas is discharged to the odor removal gas purification gas outlet 312 discharged from the second reactor 320 installed below the horizontal center line in the direction of the flow of the purified gas. Acts as a forward vortex (Conventional Vortex flow), and the odor removal gas discharged from the second reactor 320 installed above the horizontal centerline acts as a reverse vortex flow with respect to the moving direction of the purified gas will do

Those of ordinary skill in the art to which the present invention pertains will be able to perform various applications and modifications within the scope of the present invention based on the above contents.

The odor removal device includes an inlet 110 through which harmful toxic substances, non-decomposable waste gas, and non-decomposable odor gas are introduced, an odor removal gas outlet 111 formed at the rear end, and particle removal installed adjacent to the outlet. Filters 131 and 132 for decomposition, a photocatalytic filter 140 for decomposing and removing odor components, a UV lamp 150 for irradiating the surface of the photocatalyst filter directly, and a blower fan 120 installed at the rear end of the outlet to blow air. Consists of.

110: inlet
110: outlet
120: blower fan
131: first filter
132: second filter
140: photocatalytic filter
150: UV lamp
220: gas storage tank
310: first reactor
311: purification space unit
312: purification gas outlet
312: purification gas outlet
320: second reactor
321: inner space
321a: flame space part
321b: odor removal gas space part
322: flame inlet hole
323: odor removal gas inlet
324: inner tube part
325: slit
325a: slit ball
325b: slope
326: exhaust hole
326a: connection
327: insulation member

Claims (1)

a odor removal device comprising a filter that removes harmful toxic substances, incombustible waste gas, and particulate matter in odor gas, a photocatalyst filter and a UV lamp;
a first reactor 310 having a purification space 311 for accommodating the odor removing gas and having a gas outlet 312 through which the purified gas is discharged;
Both ends are penetrated and an internal space 321 is formed therein, and one end of the first reactor 310 is such that the internal space 321 and the purification space 311 of the first reactor 310 communicate with each other. It is installed on the outer circumferential surface, and at the other end, a flame inlet hole 322 through which a plasma combustion oxidation system (PTO) flame for purifying the odor removal gas is introduced is formed, and the odor removal gas and the plasma flame supplied are formed in the inner space ( 321) a second reactor 320 to react with each other;
It is installed at the other end of the second reactor 320, a plasma by microwave electromagnetic wave oscillation is generated inside, and a plasma combustion oxidation system (PTO) flame ignited by the plasma is supplied with fuel from the outside to the second Plasma combustion oxidation system (PTO) combustor 330 radiating to the inner space 321 of the reactor 320; and
a pressure control unit 340 at a lower portion of the first reactor 310 to control the pressure inside the purification space 311 to control the formation of a vortex of the odor removal gas discharged from the second reactor 320;
A non-decomposable malodorous gas treatment system comprising a.

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