KR20140128476A - Harmful gas removal device to remove harmful gases at room temperature using plasma and catalyst. - Google Patents

Abstract

A harmful gas removal device to remove harmful gas by using plasma at room temperature and a catalyst of the present invention is a harmful gas removal device to remove harmful gas included in atmosphere. Specifically, the present invention relates to a harmful gas removal device to remove carbon monoxide, hydrocarbon and volatile organic compounds included in exhaust gas of automobile by using a catalyst. The harmful gas removal device comprises a container opened in the direction of polluted air moving, and having an installation space therein; a first plasma production unit consisting of a multi-cross pin ionizer; an induced voltage collector consisting of an induced voltage plate causing an induced voltage; a second plasma production unit consisting of a multi-cross pin ionizer; and a catalyst unit. The harmful gas removal device to remove harmful gas by using plasma at room temperature and a catalyst of the present invention can effectively remove harmful gas, in particular, carbon monoxide in an environment wherein particles such as fine dust are abundant in the polluted air, and can prevent the degradation of performance of the catalyst. Furthermore, the harmful gas removal device has effects capable of removing carbon monoxide and organic compounds at room temperature at 25°C or under, and capable of effectively removing harmful gas in a place such as a tunnel or an underground traffic facility where the concentration of particles such as fine dust is relatively high.

Description

Technical Field [0001] The present invention relates to a harmful gas removing device for removing harmful gas using a room temperature plasma and a catalyst.

The present invention relates to a harmful gas removing apparatus for removing harmful gas contained in the atmosphere, and more particularly, to a harmful gas removing apparatus for removing carbon monoxide, hydrocarbon, and volatile organic compounds contained in automotive exhaust gas using a catalyst.

Carbon monoxide, hydrocarbons and volatile organic compounds (VOCs) emitted from automobiles or industrial processes are not only harmful to humans but also strongly regulate them as a cause of smog in the atmosphere.

Particularly, carbon monoxide is a harmful gas that causes dizziness or heart attack when it enters the human body through the respiratory tract and leads to death in severe cases. It mainly occurs when incomplete combustion of fuel occurs. Especially, And has become one of the major air pollutants.

Such carbon monoxide is not easy to remove, which leads to complete combustion in industrial process control and combustion, and it is also effective in reducing the carbon monoxide emission by attaching a carbon monoxide reduction device such as a three- There is no way to reduce it.

There is a method of oxidizing carbon monoxide to carbon dioxide by using a catalyst, but there is a problem that it is difficult to constitute a device for continuously maintaining the efficiency of the catalyst.

In the method of oxidizing carbon monoxide to carbon dioxide by using a catalyst, it is crucial that the efficiency of the catalyst can not be maintained constantly because the particles include particles such as fine dust, moisture and metal in addition to harmful gas in the air, And the contact of the noxious gas oxidized through contact with the catalyst is prevented, resulting in a problem that the efficiency of the catalyst drops sharply.

Particularly, since there are many particles contained in the air at the time of the underground facility or the dust case, there is a problem that the apparatus is not able to process the harmful gas removing device using the catalyst for one hour and the function is lost.

In case of tunnel or underground traffic facility, the concentration of carbon monoxide is very high because the ventilation is not smooth and the concentration of particles is very high. Therefore, the environment where the harmful gas treatment device can not function properly can not treat carbon monoxide. , Which causes the problem of pollution of inside air of tunnel or underground traffic facility due to high concentration of carbon monoxide as well as environmental pollution problem.

In the case of the above volatile organic compounds, there is a method of removing them physically, chemically and biologically. The chemical method has a direct combustion method in which harmful gas is collected and burned, but there is a risk of explosion. In the physical method, However, since the contact combustion method is mainly used in which carbon monoxide is removed by using a catalyst such as carbon monoxide, there is a problem in that performance maintenance is difficult due to the above problems. have.

Although various methods for preventing adhering substances such as dust from adhering to the catalyst have been proposed in the construction of the apparatus for removing noxious gases due to the above problems, there is a problem in that it is difficult to effectively remove the particles contained in the air .

It is an object of the present invention to provide a device for removing harmful gas using a catalyst, which is capable of maintaining the catalytic efficiency even in an environment where particles such as fine dust are present.

It is an object of the present invention to provide a device for removing harmful gases which can effectively remove carbon monoxide as well as volatile organic compounds.

It is also an object of the present invention to provide a harmful gas removing device capable of removing carbon monoxide and an organic compound at room temperature.

It is another object of the present invention to provide a device for removing harmful gas which is capable of effectively removing carbon monoxide at a relatively high concentration of particles such as a tunnel.

It is also an object of the present invention to provide a harmful gas removing apparatus which is structurally simple and easily manages the catalyst.

Means for solving the above-mentioned problems of the present invention are as follows.

The present invention relates to a harmful gas removing apparatus for removing harmful gas using a catalyst, comprising: a housing opened in a direction in which contaminated air flows and providing an installation space therein; The plasma processing apparatus is vertically installed on the front end of the enclosure through which contaminated air is introduced. The plasma processing apparatus is connected to the high-voltage applying means to generate a room-temperature plasma for charging the object to be trapped in the contaminated air. A primary plasma generator comprising at least one multi-cross fin ionizer in which side projections are formed in the longitudinal direction; A plurality of grounded vertical metal plates arranged in parallel behind the primary plasma generating unit and arranged between the dust collecting electrodes for collecting the charged objects to be collected and the vertical metal plates of the dust collecting electrodes, An induction voltage collector formed of an induction voltage plate for generating a voltage induced by the energizer; A plurality of side projections formed on both sides in a longitudinal direction and connected to the high voltage applying means to generate a room temperature plasma for removing harmful gas, A secondary plasma generator comprising a multi-cross fin ionizer; And a catalytic part installed at the rear of the secondary plasma generating part and including a metal oxidation catalyst for oxidizing the noxious gas contained in the polluted air.

In addition, the enclosure is divided into an enclosure of an induction voltage collector provided with the primary plasma generator, an induction voltage dust collector, and a secondary plasma generator, and a catalyst part enclosure provided with the catalyst part, Are separated and combined with each other.

In addition, the primary plasma generator and the secondary plasma generator may include insulating means provided on the housing, a coupling hole formed on the upper side or lower side of the multi-cross fin ionizer, A power supply supporter for electrically connecting and fixing the multi-cross fin ionizer in combination with a combiner of a first plasma generator and a second plasma generator for electrically connecting the first plasma generator and the second plasma generator, And a power connection unit coupled to the power supply support and the other of which is connected to the power supply support of the secondary plasma generator.

The catalytic unit may include a catalyst box having a plurality of perforations formed therein to allow contaminated air to flow in a box shape in which a pellet-shaped metal oxidation catalyst is filled, a pellet-shaped metal oxidation catalyst filled in the catalyst box, As a technical feature.

Further, the metal oxidation catalyst is barium titanate (BaTiO ₃ ).

The apparatus for removing noxious gas using a normal-temperature plasma and a catalyst according to the present invention can effectively remove noxious gas, particularly carbon monoxide, even in an environment where fine particles such as fine particles are present in the contaminated air, There is an effect that can be.

Also, carbon monoxide and an organic compound can be removed even at a room temperature of 25 DEG C or lower.

In addition, it is possible to effectively remove harmful gas even at a relatively high concentration of particles such as fine dusts such as tunnels and underground traffic facilities.

Further, the overall structure of the apparatus is simple and the catalyst can be easily managed.

In addition, since the neutralized neutralized dust is instantaneously attached to the dust collecting electrode by its own weight at the dust collecting electrode, it is possible to remove the dust adhering to the dust collecting electrode without any dust removing means such as a cleaning device or a chattering device Dust adhering to the dust collecting electrode can be removed, and maintenance can be easily performed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual diagram of a harmful gas removing apparatus for removing harmful gas using a room temperature plasma and a catalyst according to an embodiment of the present invention;
2 is a view showing a configuration according to an embodiment of a noxious gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to an embodiment of the present invention;
3 is a view for explaining an enclosure of a noxious gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to the present invention,
4 is a view for explaining a multi-cross fin ionizer of a harmful gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to an embodiment of the present invention;
5 is a view for explaining a power supply supporter of a harmful gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to the present invention,
6 is a view for explaining an induction voltage dust collection unit of a harmful gas removing apparatus for removing harmful gas using a room temperature plasma and a catalyst according to the present invention;
7 is a view for explaining a principle of dust collection using an induction voltage of a harmful gas removing apparatus for removing harmful gas using a room temperature plasma and a catalyst according to the present invention;
8 is a view for explaining a catalytic part of a harmful gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced, and these embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It should also be understood that the position or arrangement of individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a diagram showing a conceptual configuration of a harmful gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to the present invention. As shown in FIG. 1, the present invention can be applied to a large-sized air conditioner installed in a tunnel or an underground traffic facility, a duct for ventilation or a ventilation hole, and is provided with harmful gases such as carbon monoxide, hydrocarbon, The induction voltage collector 20, the secondary plasma generator 40 and the catalytic part 50 in the housing 10 as a harmful gas removing device for removing the harmful gas, And are arranged in the order as shown in the drawing.

By arranging the above-described structures as shown in FIG. 1, the object to be trapped such as fine dust contained in the contaminated air is firstly removed, and the noxious gas contained in the contaminated air from which the object to be trapped is removed, 50).

In this way, the object to be collected such as fine dust is preferentially removed from the induction voltage dust collection unit 20, thereby preventing the function of the catalyst unit 50 from being deteriorated due to fine dust or the like.

Particularly, by removing more than 99% of fine dust contained in the polluted air through the induction voltage dust collection unit 20, it is possible to maintain a substantial harmful gas removal efficiency of the catalyst unit 50.

Further, by operating the primary plasma generator 10 and the secondary plasma generator 20 together, the overall structure of the apparatus for removing harmful gases can be simplified.

FIG. 2 is a view showing a configuration according to an embodiment of a noxious gas removing apparatus for removing noxious gas using a room temperature plasma and a catalyst according to the present invention. As shown in FIG. 2, the enclosure 10 is opened in the direction in which the contaminated air flows and is provided vertically on the front end of the enclosure 10 into which the contaminated air flows, One or more multi-cross pin ionizers connected to the high-voltage applying means to form a plurality of side projections in the longitudinal direction on both sides in a saw-like shape having a predetermined length for generating a room-temperature plasma for charging a trapped object in the contaminated air And a plurality of grounded vertical metal plates arranged in parallel to collect a charged object to be collected, and a dust collecting electrode disposed at a rear of the primary plasma generating unit 20, An induction voltage plate located between the vertical metal plates and inducing a voltage induced by the multi-cross pin ionizer without electrical connection And a plurality of gas supply pipes 30 disposed vertically to the pressure-collecting unit 30 and the induction voltage collecting unit 30 and connected to the high-voltage applying unit to generate a room-temperature plasma for removing harmful gas, A secondary plasma generator 40 composed of at least one multi-cross fin ionizer in which side projections are formed in the longitudinal direction, and a noxious gas generator 40 installed at the rear of the secondary plasma generator 40, And a catalyst portion 50 including a metal oxidation catalyst for oxidizing the catalyst.

As shown in FIG. 3, the enclosure 10 includes a first plasma generator 20, a second plasma generator 20, The second plasma generating unit 40 and the catalytic unit 50, and has a structure that can be installed in the ventilating apparatus through which the air flows, Rear), and both sides are closed to provide an installation space inside.

As shown in FIG. 3, the housing 10 may be formed of a metal such as a primary plasma generator 20, induction coils 20, The portion where the voltage collection portion 30 and the secondary plasma generation portion 40 are installed may be formed in an open shape in order to facilitate installation. In particular, the bottom surface allows the collected dust to be discharged by its own weight.

 The enclosure 10 includes an induction voltage collector housing 110 in which the first plasma generator 20, the induction voltage collector 30 and the second plasma generator 40 are installed, The induction voltage collector 110 and the catalyst enclosure 120 are separated from each other and connected to each other. The coupling between the dust collecting unit housing 110 and the catalyst unit housing 120 is coupled by a conventional fastening means such as a bolt / nut and can be separated.

The enclosure 10 is divided into two parts by the dust collecting housing 110 and the catalyst housing 120 so that the primary plasma generating part 20, the induced voltage dust collecting part 30, the secondary plasma generating part 40, There is an advantage that the maintenance of the catalyst part 50 is easy.

Particularly, the secondary plasma generator 40 having an organic relationship with the catalyst unit 50 is installed on the dust collecting unit housing 110 side to simplify the structure, improve the convenience of maintenance, Thereby improving the ease of installation of the catalytic portion 50.

The housing 10 further includes a guide 130 guiding the contaminated air to the induction voltage collector 30 so that air can be smoothly introduced into the open front sheath.

The guide 130 is installed on the upper side and the lower side of the first plasma generating part 20 so that the direction of the introduced air can be directed toward the induction voltage dust collection part 30. By doing so, the charged dust can sufficiently pass through the inside of the induction voltage dust collection unit 30, and additionally, the dust is prevented from scattering in the space between the first plasma generation unit 20 and the induction voltage dust collection unit 30 .

4 is a cross-sectional view of a multi-cross fin ionizer of a noxious gas removing apparatus for removing noxious gas using a normal-temperature plasma and a catalyst according to an embodiment of the present invention. The ionizers 70 are electrically connected in parallel as shown in FIGS. 1 to 3 above.

The primary plasma generating unit 20 is connected to the high voltage supplying unit and receives electric charges at a high voltage to discharge (corona discharge) the plasma to generate plasma.

The multi-cross fin Ionizer 70 used in the primary plasma generator 20 and the secondary plasma generator 40 of the present invention has a saw-like shape as shown in FIG. 4 (a) Like discharge electrode 60 having a plurality of side surface protrusions 710 for generating a corona discharge in the longitudinal direction is provided on both sides of the projection-type discharge electrode 60 having the discharge electrode 610 formed thereon. The discharge electrode has protrusions for causing corona discharge in four directions .

In this way, the corona discharge is generated in four directions to generate plasma more efficiently.

4 (b), the side projections 710 of the multi-cross fin Ionizer 70 may be joined to both sides of the side projections 710 by welding or the like. Alternatively, as shown in FIG. 4 the main body of the projection-type discharge electrode 60 may be cut in a protruding shape and then bent so as to be formed.

As described above, the multi-cross fin Ionizer 70 is a type of protruding discharge electrode that is improved from the conventional projection type discharge electrode 60 by adding a plurality of side projections 710 in the longitudinal direction to cause corona discharge, And the dust collection efficiency is relatively increased.

5, the multi-cross fin Ionizer 70 includes a coupling hole (not shown) for supporting the power supply supporter of the harmful gas removing device for removing harmful gas using the room temperature plasma and the catalyst, 720, and is electrically connected through a power supply supporter 730 made of a metal material having high electrical conductivity such as aluminum, and is fixed to the housing 10 at the same time.

The coupling holes 720 are formed on the upper side or lower side of the multi-cross fin Ionizer 70, and the power supply support 730 fixes one or more multi-cross fin Ionizers 70, And the multi-cross pin ionizer 70 are electrically connected to each other.

That is, a plurality of multi-crossover pinionizers 70 are fixed to a power supply support 730 that penetrates through the coupling holes 720 and is engaged with the multi-cross pin ionizer 80, and the power supply supports 730 Is electrically coupled to the high voltage supply means such that the plurality of multi-cross pin Ionizers (70) receive charge from the high voltage supply means through the power supply support (730) to a high voltage.

At this time, the power supply support 730 is coupled to the filter housing 10 through the insulating means 740 installed in the housing 10. The insulation means 740 is a solid insulator commonly referred to as an insulator, which is used to insulate and support an electrical conductor.

That is, the power supply supporter 730, which is a conductor, is insulated from the enclosure 10 through the insulation means 740 and is coupled to the enclosure 10 at the same time.

In order to electrically connect the primary plasma generator 20 and the secondary plasma generator 40, one end of the power supply support 730 is connected to a power supply supporter of the primary plasma generator 20, And the power supply connection means 750 is connected to the power supply supporter 730-2 of the secondary plasma generator 40. The power supply supporter 730-2 is connected to the power supply supporter 730-1.

The power supply connection means 750 is made of a metal material having a high electrical conductivity, like the power supply support 730, and has one side and the other side of which can be engaged with the power supply support 730, Forming a coating for insulation.

The induction voltage collector 30 shown in FIGS. 2 and 3 is disposed behind the primary plasma generator 20, and induction voltage plates having no electrical connection with a plurality of grounded vertical metal plates are arranged alternately And collects the collected target (fine dust, etc.) charged by the plasma generated through the primary plasma generator 20.

As shown in FIG. 6, the induction voltage collector 500 is disposed between the primary discharge unit 300 and the secondary discharge unit 400, and a grounded parallel metal plate is continuously installed, And an induction voltage plate disposed in parallel with the multi-cross fin ionizer between the dust collecting electrode for collecting the fine particles and the metal plate of the dust collecting electrode and generating a voltage induced by the multi-cross fin ionizer without electrical connection.

More specifically, as shown in the figure for explaining the induction voltage dust collection unit of the harmful gas removing apparatus for removing noxious gas using the room temperature plasma and the catalyst according to the present invention, the vertical dust collecting electrode 300 And the plate-shaped induction voltage plate 310 also has a coupling hole and a through hole 330 at a position different from the coupling hole and the through hole 320 of the vertical dust collection electrode 300 The vertical dust collecting electrode 300 is electrically connected to the dust collecting electrode supporter 340 so as to be grounded and fixed to the enclosure 10 while the induced voltage plate 310 is also connected to the induction voltage supporter 350 And is fixedly coupled to the housing 10 at the same time.

That is, the induced voltage dust collection unit 30 is formed by alternately stacking the plate-shaped vertical dust collecting electrodes 300 and the plate-shaped induced voltage plates 310, and the vertical dust collecting electrodes 300 And the induction voltage plate 310 is also electrically coupled to and supported by the induction voltage plate supporter 350. The induction voltage plate supporter 350 is formed of a conductive material.

The principle of collecting the object to be collected by the induction voltage dust collector 30 will be described with reference to FIG. 7. FIG. 7 is a view for explaining the principle of dust collection using the induction voltage of the apparatus for removing harmful gas using the room- As shown in the drawing, the multi-cross fin Ionizer 70 of the primary plasma generator 20 is connected to the high voltage supply means to receive charges at a high DC voltage of 11,000 volts or more, The charge is charged at the projection of the multi-cross pin ionizer 70 and discharged by the corona discharge phenomenon to form a plasma region (charge region).

The fine particles 1 such as dust, dust or moisture contained in the contaminated air flowing from the outside are in an electrically neutral state, and when the fine particles 1 in a neutral state enter the charged region, they are in a neutral state Charged fine particles (2) in a negative state due to collision or adsorption with an anion-bearing gas molecule.

Briefly describing the principle of the charging of fine particles, the multi-cross pin ionizer 70 forms a strong electric field around the multi-cross pin ionizer 70 through corona discharge, and such a strong electric field is generated by a multi-cross pin ionizer 70) plasma is generated by accelerating free electrons present in the surrounding gas.

Accelerated free electrons move at high speed and collide with other gas molecules, and gas molecules colliding with accelerated free electrons become positive ions by discharging one more free electron.

The thus formed cationic gas molecules collide with the gas molecules or multi-cross pin ionizer 70 surrounding the multi-cross pin ionizer 70 while moving toward the negative multi-cross pin ionizer 70, The free electrons generated at this time move toward the grounded vertical dust collecting electrodes 300 and 300-1 along the electric field. If the free electrons thus moving out of the charged region, the electric field weakens and the moving speed rapidly drops. As a result, Is adsorbed on the surface of the gas molecules in a collision with the gas molecules at a rate that can not ionize them to form an anion-like gas molecule.

The anion-like gas molecules collide with or adsorb the fine particles 2 in the charged region to charge the fine particles 2.

At the same time, the plate-shaped inductive voltage plate 310 spaced apart from the multi-cross pin ionizer 70 at a predetermined interval is charged with a high voltage by the multi-cross pin ionizer 70 to generate an induced voltage of the cathode, Both vertical dust collecting electrodes 300 and 300-1 are charged to the anode by electrostatic induction and electrostatic discharge.

Therefore, an electric field is formed between the induction voltage plate 310 and each of the vertical dust collecting electrodes 300 and 300-1, and the charged fine particles 2-1 introduced into the electric field are collected by the dust collecting electrodes 300 and 300- 1 and the induction voltage plate 310 are acted upon by a repulsive force and attached to the dust collecting electrodes 300 and 300-1.

By attaching to the grounded dust collecting electrodes 30 and 30-1, the collected fine particles 3 become electrically fine particles by losing charge.

In this case, the repulsive force and the attraction force are caused by the Coulomb's law, and a detailed description thereof will be omitted.

As described above, in the harmful gas removing apparatus for removing noxious gas using the room temperature plasma and the catalyst according to the present invention, the primary plasma generating unit 20 and the induction voltage dust collecting unit 30 are operated by the above- Thereby collecting and collecting the object such as fine dust contained in the contaminated air.

The contaminated air that has been subjected to the primary purification by removing the object such as fine dust while passing through the primary plasma generating portion 20 and the induction voltage dust collecting portion 30 of the present invention is hereinafter referred to as the means 2 for removing the harmful gas And is oxidized and removed through the secondary plasma generating portion 40 and the catalytic portion 50.

The secondary plasma generator 40 is located behind the induction voltage collector 30 as shown in the drawings and generates a room temperature plasma with the same structure and principle as the primary plasma generator 20 The room-temperature plasma intrinsically oxidizes the metal oxidation catalyst of the catalytic portion 50 to smoothly oxidize the harmful gas even at room temperature.

Therefore, the present invention can prevent the catalyst unit 50 from reacting with carbon monoxide, carbon-hydrogen, and volatile organic compounds contained in the contaminated air introduced into the room-temperature plasma generated in the secondary plasma generator 40 even at room temperature Thereby oxidizing the noxious gas.

Specifically, the carbon monoxide is 2CO + O ₂ + Me (metal oxidation catalyst) 2CO ₂ + Me reaction, and the volatile organic compounds are removed by VOCs + O ₂ + Me (metal oxidation catalyst) H ₂ O + CO ₂ + Me reaction.

That is, the catalytic portion 50 of the present invention completely oxidizes carbon monoxide into harmless carbon dioxide by using a metal oxidation catalyst, and the volatile organic compound is completely oxidized and removed with water and carbon dioxide.

The metal oxidation catalyst may be various materials used in a contact combustion method for removing harmful gases such as carbon monoxide, hydrocarbons and volatile organic compounds by using a catalyst, and is not limited to any specific metal oxidation catalyst.

However, it is preferable that the metal oxidation catalyst is barium tinate (BaTiO ₃ ) having a relatively high oxidation (removal) rate of carbon monoxide.

As shown in the figure for explaining the catalyst part of the harmful gas removing apparatus for removing noxious gas using the room temperature plasma and the catalyst of the present invention as described above, the catalytic part 50 has a pellet- A catalyst box 510 in which a plurality of perforations 511 are formed and a pellet-shaped metal oxidation catalyst 520 to be filled in the catalyst box 510 so that contaminated air can be circulated in the form of a box to be filled .

The catalyst box 510 is preferably made of a synthetic resin material such as acryl or a Teflon-coated material excellent in chemical resistance. In order to fill the metal oxidation catalyst therein, as shown in FIG. 8, It is preferable that the cut portion 512 is finished with a cover 513 that is detachably attached.

Further, it is preferable to be able to be inserted into the housing 10 through the opening of the housing 10.

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, And such variations and modifications are intended to fall within the scope of the appended claims.

1: Fine particles
2: charged fine particles
3: Collected fine particles
10: Enclosure
20: primary plasma generating unit
30: Induction voltage collector
40: secondary plasma generating unit
50:
110: Dust collector housing
120: catalyst part enclosure
130: Guide
300: vertical dust collecting electrode
310: Induced voltage plate
320: coupling ball
330: coupling ball
340: Collector electrode support
350: Induced voltage plate support
510: catalyst box
511: Perforation
512: open area
513: cover
520: metal oxidation catalyst
610:
710: side projection
720: Combination ball
730: Power supply support
740: Insulation means
750: power connection means

Claims (5)

A harmful gas removing apparatus for removing harmful gas using a catalyst,
An enclosure opening in a direction in which contaminated air flows and providing an installation space therein;
The plasma processing apparatus is vertically installed on the front end of the enclosure through which contaminated air is introduced. The plasma processing apparatus is connected to the high-voltage applying means to generate a room-temperature plasma for charging the object to be trapped in the contaminated air. A primary plasma generator comprising at least one multi-cross fin ionizer in which side projections are formed in the longitudinal direction;
A plurality of grounded vertical metal plates arranged in parallel behind the primary plasma generating unit and arranged between the dust collecting electrodes for collecting the charged objects to be collected and the vertical metal plates of the dust collecting electrodes, An induction voltage collector formed of an induction voltage plate for generating a voltage induced by the energizer;
A plurality of side projections formed on both sides in a longitudinal direction and connected to the high voltage applying means to generate a room temperature plasma for removing harmful gas, A secondary plasma generator comprising a multi-cross fin ionizer; And
And a catalytic part installed at a rear side of the secondary plasma generation part and including a metal oxidation catalyst for oxidizing harmful gas contained in the polluted air, wherein the harmful gas is removed using a room temperature plasma and a catalyst Hazardous gas removal device. The connector according to claim 1, wherein the housing
The induction voltage collector and the catalytic converter are provided with the induction voltage collector and the induction voltage collector, the induction voltage collector and the second plasma generator, respectively, Wherein the harmful gas is removed using a room temperature plasma and a catalyst. The plasma processing apparatus according to claim 1, wherein the first plasma generating unit and the second plasma generating unit
Crossing pin ionizer and an insulator provided on the housing and a coupling hole formed on an upper side or a lower side of the multi-cross fin ionizer and a coupling hole formed on the lower side of the multi-cross fin ionizer, A power supply support for connection and fixing;
And a second power supply supporter connected to the second power supply supporter of the second plasma generator to electrically connect the first plasma generator to the second plasma generator, The apparatus for removing harmful gas according to claim 1, further comprising: 2. The catalyst according to claim 1,
And a pellet-shaped metal oxidation catalyst filled in the catalyst box, wherein the pellet-shaped metal oxidation catalyst is filled in the catalyst box, And a harmful gas removing device for removing the harmful gas using the atmospheric plasma and the catalyst. The method of claim 1, wherein the metal oxidation catalyst
Barium titanate (BaTiO ₃ ), characterized in that the harmful gas is removed using a room temperature plasma and a catalyst.

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