KR20160073007A - Scrubber for plasma burner having an aqua barrier from being formed on the inner part of the reactor - Google Patents

Abstract

The present invention relates to a scrubber for a plasma burner in which a water screen is formed inside a reactor. The scrubber for a plasma burner comprises: a reactor where waste gas is inserted into the interior through a waste gas inlet installed on the upper side downwards; a burner unit to supply fuel gas and air inside the reactor by being installed on the upper side of the reactor downwards and to generate a flame inside the reactor through ignition of an ignition unit; an internal path included inside the reactor; and a water supply unit to form the water screen inside the internal path by supplying water to the internal path of the reactor. The present invention as above can improve process efficiency of the waste gas by forming the water screen inside the reactor and preventing foreign substances such as powder or the like generated when the waste gas is burned inside the reactor from being stacked inside the reactor, prevent corrosion of a peripheral part including the reactor, and reduce costs related to maintenance of the scrubber.

Description

[0001] The present invention relates to a scrubber for a plasma burner in which a water film is formed in a reactor,

The present invention relates to a scrubber for a plasma burner in which a water film is formed in a reactor to prevent foreign substances such as powder from adhering to the inside of the reactor.

In general, a semiconductor process repeatedly performs various processes such as photo, diffusion, etching, chemical vapor deposition, and metal deposition on a silicon substrate, and processes such as diffusion, etching, and chemical vapor deposition are performed in a sealed process chamber The process gas is supplied to cause these process gases to react on the wafer.

On the other hand, the gas used in the semiconductor manufacturing process has a strong characteristic such as toxicity, flammability and corrosiveness, and this process gas only participates in the reaction process of about 10% in the manufacturing process, and the remaining 90% Is discharged from the manufacturing facility in an unreacted state.

Therefore, if the toxic waste gas, which is a fixed gas, is discharged into the air without any purification process, it will cause damage to the surrounding manufacturing equipment, serious environmental pollution, and worker safety accidents. Therefore, each manufacturing facility is equipped with a gas discharge line A scrubber is installed which decomposes or purifies the exhaust gas into a safe state.

The scrubber utilizes the properties of the waste gas, such as explosive reactivity when contacted with ordinary air, combustibility, reactivity with a gas treating agent, and properties dissolving in water, which are largely dry and wet, Mixed type.

A wet type scrubber is a structure for collecting waste gas by using water, followed by cleaning and cooling, has a relatively simple structure, and is easy to manufacture and has a large capacity. However, the water-insoluble gas is not processable, and is inadequate for the treatment of waste gas containing a hydrogen group, which is particularly highly ignitable.

The dry type scrubber has a structure in which waste gas is passed through the burner to directly burn it, or a high-temperature chamber is formed by using a heat source, and waste gas is passed through the chamber to indirectly burn the gas. Such a dry type scrubber has an excellent effect in the treatment of flammable gas, but is unsuitable for the treatment of gas which is not well burned, such as a water-soluble gas.

The mixed-type scrubber has a structure in which waste gas is firstly combusted in a combustion chamber to remove ignitable gas and explosive gas, and then the water is secondarily contained in a water tank to dissolve a water-soluble toxic waste gas into water. As a prior art of such a mixed scrubber, Has already been disclosed in Japanese Patent No. 10-2010-0021135 entitled " Waste Gas Treatment Apparatus ".

In the process of treating the waste gas by the gas scrubber, the waste gas generated in the process chamber of the semiconductor equipment is transferred to the burner of the reactor through the injection unit, and burned / oxidized or pyrolyzed Burned) and unburned gases such as some gases and dust particles that are not burned are transferred to the wet zone, where the water is sprayed to separate the powder in the oxidant gas, A wetting process is carried out so as to fall to the water tank, and the cleaned process gas is discharged to the atmosphere through the filter and the duct.

However, conventionally, in the burning process of waste gas, foreign substances such as powder easily accumulate inside the reactor, so that a pressure change occurs inside the reactor. Such a pressure change causes the waste gas treatment efficiency to be lowered and the operation of the scrubber may be stopped

In addition, there is a problem that the foreign material deposition in the reactor causes corrosion on the peripheral part as well as the reactor, thereby increasing the cost associated with the maintenance of the scrubber.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a reactor for efficiently preventing foreign materials such as powder generated in a burning process of waste gas flowing into a reactor from being stacked in a reactor. And a scrubber for a plasma burner in which a water film is formed.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. It can be understood.

According to a preferred embodiment of the present invention, there is provided a plasma processing apparatus comprising: a reactor in which waste gas flows into an interior of a reactor through an off-gas inlet port provided on an upper side; A plasma burner part for generating a flame inside the reactor through DC arc discharge while being supplied with water and a water supply part for supplying water to the inner and inner passages provided in the reactor to form a water film on the inner surface of the inner passageway .

More preferably, a manifold is provided at an upper portion of the reactor, and cooling water is supplied to the inside of the manifold to prevent thermal erosion of the plasma burner portion passing through the manifold.

More preferably, the inner passage is formed to have a lower inner diameter than the upper inner diameter; And an outlet portion extending downward from a lower portion of the inlet portion and having an inner diameter that is the same as or smaller than the lower inner diameter of the inlet portion.

More preferably, the water supply portion is provided so as to be inclined downwardly in the tangential direction of the circumferential surface from the upper side of the inlet portion and the upper side of the outlet portion through the surface of the reactor, so that water supplied into the upper side of the inlet portion and the upper side of the outlet portion causes vortex Thereby forming a water film on the surface of the inlet portion and the surface of the outlet portion.

More preferably, a plurality of water supply portions are provided on the circumferential surface of the inner passage in a tangential direction, and the water supplied from each of the water supply portions is configured to rotate in the same direction.

The present invention is characterized in that a funnel-shaped inner passage is formed in a reactor and water is sprayed on the inner passage to form a water film on the inner surface of the inner passage. Accordingly, foreign matter such as powder generated when the waste gas is burnt in the reactor The problem of accumulation on the surface of the inner passage can be solved.

In addition, since the effect of the present invention described above is expected to be exerted by the composition of the contents regardless of whether or not the inventor perceives it, the effect described above is only some effects according to the contents described, Should not be recognized.

Further, the effect of the present invention should be grasped further by the entire description of the specification, and even if it is not stated in an explicit sentence, a person having ordinary skill in the art to which the written description belongs, It should be seen as an effect described in this specification.

1 is a side view illustrating a scrubber having a plasma burner unit according to an embodiment of the present invention.
2 is a schematic view illustrating a reactor having a plasma burner unit according to an embodiment of the present invention.
FIG. 3 is a cut-away perspective view illustrating a reactor having a plasma burner unit according to an embodiment of the present invention.
4 is a cross-sectional top view illustrating the flow of water supplied to the inner passage of the reactor according to one embodiment of the present invention.

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

It is to be understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the scope of the present invention being indicated by the appended claims rather than by the foregoing description.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined in particular in consideration of the structure and operation of the contents described may vary depending on the intention or custom of the user or the operator And the definitions of these terms should be based on the contents throughout this specification.

First, the construction of a scrubber for a plasma burner in which a water film is formed in a reactor according to the present invention comprises a reactor in which burning of waste gas is performed, a plasma burner section for generating a flame in the reactor, And a water supply unit for supplying water to the inner passage to form a water film on the inner surface. The components will be described in detail with reference to FIGS.

The reactor (100)

The waste gas supplied to the upper side is reacted with a flame produced by the plasma burner unit 200 to be described below to burn / oxidize or pyrolyze.

The plasma burner unit 200 and the waste gas inlet 130 may be directly installed on the upper side of the reactor 100. Preferably, the manifold 110 is installed on the upper part of the reactor 100 as shown in FIG. .

When the manifold 110 is installed in the reactor 100, the plasma burner unit 200 is installed at the center of the manifold 110. The burner nozzle 210 of the plasma burner unit 200 is connected to the manifold 110, And is installed toward the interior of the reactor 100. One or more waste gas inlets 130 are provided on one side of the upper surface of the manifold 110 so that waste gas can be introduced into the reactor 100.

The cooling water 111 may be supplied to the inside of the manifold 110 to prevent thermal corrosion of the plasma burner unit 200 and the burner nozzle 210 described later.

In the plasma burner unit 200,

The flame is radiated into the reactor 100 to burn / oxidize or pyrolyze the waste gas supplied into the reactor 100.

The plasma burner unit 200 generates a flame into the reactor 100 through DC arc discharge while supplying nitrogen to the plasma generated by applying a voltage between the anode member and the cathode member.

Nitrogen serves as a source of ignition of the plasma and also serves as a guide to move the plasma into the reactor.

As an ignition source of the plasma, not only nitrogen but also inert gas such as argon and oxygen may be used.

The plasma burner unit 200 may be directly installed in the reactor 100 described above, but may be installed at the upper center of the manifold 110 as illustrated in FIG.

The internal passageway (120)

Is formed in the inside of the reactor (100) in a double structure, and has approximately the shape of a funnel.

The inner passage 120 is composed of an upper inlet portion 121 and an outlet portion 122 extending downwardly from the inlet portion 121.

The upper end of the inlet portion 121 is connected to the upper inner surface of the reactor 100 and the inner diameter gradually becomes smaller toward the lower end of the inlet portion 121. [

The upper end of the outlet portion 122 may be connected to the lower end of the inlet portion 121 either integrally or by assembling or the like and the inner diameter of the outlet portion 122 may be connected to the inlet portion 121 The inner diameter of the outlet portion 122 may be configured to be smaller than the inner diameter of the inlet portion 121 or may be configured to be gradually smaller.

The waste gas flowing through the waste gas inlet 130 is transferred to the reactor 100 through the inlet 121 of the inner passage 120 and then discharged to the outlet 122. At this time, And the flame of the plasma burner unit 200 which is radiated downward toward the plasma burner unit 200.

The water supply unit 140,

Water or water circulating continuously supplied from the outside is supplied to the internal passage 120 to form a water film having a certain thickness on the inner surface of the internal passage 120.

The water supply part 140 penetrates from the outer surface of the reactor 100 and the end of the water supply part 140 is positioned inside the inner passage 120. The end of the water supply part 140 may be in the shape of a nozzle.

The end of the water supply unit 140 located inside the internal passage 120 is located above the inlet 121 of the internal passage 120 and the water supplied through the water supply unit 140 flows into the inlet 121, And flows downward from the inner side of the upper side of the lower side.

As an example in which the water supplied from the water supply unit 140 forms a water film evenly on the inner surface of the internal passage 120, as shown in FIG. 4, the water supply unit 140 is passed through the surface of the reactor 140 When the water supplied from the water supply part 140 is supplied to the inlet part 121 of the internal passageway 120, the water supplied from the water supply part 140 is circulated along the inner circumferential surface of the inlet part 121 The water flowing along the inner circumferential surface of the inlet portion 121 is moved downward along the downwardly inclined surface of the inlet portion 121 so that the water is discharged along the inner surface of the outlet portion 122 do.

The water supply part 140 may be formed on the inner surface of the inlet part 121 as well as on the inner surface of the outlet part 122. In this case, It is preferable to maintain the injection pressure of a predetermined size and to adjust the pressure of the nozzle at the end of the water supply part 140 in order to maintain the injection pressure.

The water supply part 140 installed in the tangential direction to the internal passage 120 may be installed horizontally, but it may be constructed so as to be more easily swirled by the supplied water by inclining the water supply part 140 downward with a predetermined angle.

The water supply part 140 installed in the tangential direction of the internal passage 120 is installed on the upper side of the inlet part 121 and the upper side of the outlet part 122 so that the water film is more effectively May be constructed to be made.

A plurality of water supply units 140 may be installed in the internal passage 120 irrespective of the inlet 121 and the outlet 122.

The plurality of water supply units 140 may be arranged to face each other or to be close to each other so as to be symmetrical with respect to each other when the water supply units 140 are installed in the inner passage 120. Here, In the installation direction, it is preferable that the rotation directions of water supplied from the respective water supply units 140 are provided so as to have the same rotation direction.

The water supply part 140 is not limited to being installed in the tangential direction on the circumferential surface of the internal passage 120. [

Water may be supplied to the internal passages 120 at a constant pressure in a state where a plurality of water is vertically disposed in the direction of the center of the reactor 100 along the circumferential surface of the internal passages 120. At this time, It is preferable that water is supplied to the water supply part 140 adjacent to the water supply part 140 so that water is superposed on the water supply part 140 so that water forms an even water film in the internal passage 120.

The operation of the scrubber in which the water film is formed in the reactor according to the present invention will be described below.

First, it is necessary to form a water film in the inner passage 120 of the reactor 100 before the waste gas is introduced into the reactor 100.

Accordingly, when water is supplied through the water supply unit 140, the water moves downward along the inclined surface of the inlet unit 121 while being rotated on the inner surface of the inlet unit 121 of the internal passage 120, so that the water spontaneously swirls A continuous water film is formed on the inner surface of the inlet portion 121 of the inner passage 120 and the inner surface of the outlet portion 122.

A water film is formed on the inner surface of the inner passage 120 of the reactor 100 and a waste gas inlet 130 is formed in a state where the flame is radiated from the plasma burner 200 toward the inner passage 120 of the reactor 100 The waste gas flowing into the internal passage 120 of the reactor 100 reacts with the flame to burn or oxidize or pyrolyze the waste gas. When the foreign substance such as powder is burned during the burning process, 120 can not be stacked on the surface of the inner passage 120 due to the water flowing while forming the water film on the surface of the inner passage 120.

As described above, according to the present invention, a water film is formed in a reactor to effectively prevent a foreign substance such as a powder, which may be generated in a burning process of a waste gas, from accumulating in an internal passage of a reactor by forming a water film in an inner passage of the reactor It is a basic technical idea to provide a scrubber for a plasma burner.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the disclosed contents should not be limited to the described embodiments, but should be determined by the appended claims and equivalents thereof.

100: Reactor 110: Manifold
111: cooling water 120: internal passage
121: inlet part 122: outlet part
130: waste gas inlet port 140: water supply section
200: plasma burner part 210: burner nozzle

Claims (5)

A reactor in which waste gas flows into the reactor through an off-gas inlet port installed on the upper side;
A plasma burner unit installed downward on the reactor for generating a flame in the reactor through DC arc discharge while nitrogen is supplied to a plasma generated by applying a voltage between an anode member and an anode member;
An internal passage provided inside the reactor; And
And a water supply part for supplying water to the inner passage to form a water film on the inner surface of the inner passage. [5] The scrubber for a plasma burner according to claim 1,
The method according to claim 1,
Wherein a manifold is installed at an upper portion of the reactor and cooling water is supplied to the inside of the manifold to prevent thermal erosion of the plasma burner portion passing through the manifold. Scrubber for plasma burners.
The method according to claim 1,
Wherein the inner passage has an inlet portion having a lower inner diameter than the upper inner diameter; And
And an outlet portion extending downward from a lower portion of the inlet portion and having an inner diameter equal to or smaller than a lower inner diameter of the inlet portion.
The method of claim 3,
The water supply unit is installed to the upper side of the inlet and the upper side of the outlet through the surface of the reactor so as to be inclined downward in the tangential direction of the circumferential surface so that water supplied into the upper side of the inlet and the upper side of the outlet is vortexed And a water film is formed on a surface of the inlet portion and a surface of the outlet portion, the water film being formed in the reactor.
The method according to claim 3 or 4,
Wherein a plurality of water supply portions are provided in a tangential direction on a circumferential surface of the inner passage, and a rotation direction of water supplied from each of the water supply portions is the same rotation direction. For scrubbing.

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