KR102035218B1 - Microwave type plasma apparatus for treating gas and swirl generator for the same - Google Patents

Abstract

The present invention provides a microwave type plasma apparatus for gas treatment. The microwave type plasma apparatus for gas treatment comprises: a swirl generator changing a flow of a harmful gas to be treated into the harmful gas in a swirl form; and a plasma reaction unit treating the harmful gas by using plasma reaction using microwave against the harmful gas in the swirl form formed by the swirl generator. The swirl generator includes a housing in a tube form providing internal space in which the harmful gas to be treated flows, a gas inlet pipe through which the harmful gas to be treated is introduced into the internal space, a gas discharge pipe through which swirl gas is discharged from the internal space, and a swirl forming means forming a swirl in the harmful gas to be treated, which is introduced from the internal space through the gas inlet pipe.

Description

Microwave Plasma Apparatus and Swirl Generator for Gas Processing {MICROWAVE TYPE PLASMA APPARATUS FOR TREATING GAS AND SWIRL GENERATOR FOR THE SAME}

The present invention relates to a harmful gas treatment technology, and more particularly, to a microwave plasma apparatus and a swirl generator for treating the harmful gas using the plasma by the microwave.

In the manufacture of various semiconductor devices, the gas discharged from the process chamber is toxic or flammable, which is harmful to the human body and causes global warming.

Various types of devices such as dry, wet, and combustion are used as devices for processing harmful gases discharged from process chambers of semiconductor manufacturing facilities. Recently, devices for processing harmful gases using plasma reaction have been developed and widely used. have. In the case of a microwave plasma apparatus for treating noxious gases using plasma by microwaves, which is a technique of the present invention, it is very important to maintain a stable plasma reaction. In order to maintain a stable plasma reaction, the noxious gas generally forms a swirl and is supplied to the plasma reaction unit. Patent No. 10-0951631, which is a prior patent document of the present invention, describes a configuration of forming a swirl by arranging a plurality of harmful gas injection tubes in a tangential direction in a plasma reaction unit. However, the swirl generation method has a limitation in forming a uniform flow of swirl, and it is required to improve because it is not a structure directly connected to the pipe.

Republic of Korea Patent Registration No. 10-0951631 (2010.04.09.)

It is an object of the present invention to provide a microwave plasma apparatus for gas treatment and a swirl generator for the same.

Another object of the present invention is to provide a swirl generator for generating a swirl of uniform flow in the microwave plasma processing apparatus for gas treatment to improve the efficiency of harmful gas treatment.

In order to achieve the above object of the present invention, according to an aspect of the present invention, a swirl generator for changing the flow of the harmful gas to be treated in a swirl form; And a plasma reaction unit for processing the noxious gas by using a plasma reaction using microwaves with respect to the noxious gas in the form of swirl formed by the swirl generator, wherein the swirl generator is an internal space through which the noxious gas to be treated flows. A housing having a tubular shape to provide a gas, a gas inlet pipe into which the harmful gas to be treated is introduced into the internal space, a gas discharge pipe through which a swirl gas is discharged from the internal space, and flows through the gas inlet pipe in the internal space. There is provided a microwave plasma apparatus for gas treatment, comprising a swirl forming means for forming a swirl in the harmful gas to be treated.

The swirl forming means may include a plurality of swirl forming pins disposed in the circumferential direction in the inner space, and the plurality of swirl forming pins are all twisted in the same direction.

The swirl forming means may include a partition wall in which the inner space is divided into an upstream side and a downstream side, and a plurality of through holes are formed, and the plurality of through holes are twisted and extended in the same direction.

The gas discharge pipe may extend by a predetermined length in the internal space, and the swirl forming means may include a plurality of through holes formed in the gas discharge pipe in the internal space, and the plurality of through holes are all twisted in the same direction. Is extended.

According to the present invention, all the objects of the present invention described above can be achieved. Specifically, since the noxious gas swirl uniformly formed by the swirl generator having the swirl forming means disposed along the circumferential direction is supplied to the plasma reaction unit, the plasma can be stably maintained, thereby further improving the noxious gas treatment efficiency.

1 is a perspective view of a microwave plasma processing apparatus for gas treatment according to an embodiment of the present invention, and shows a part of the swirl generator in a cross-sectional view so that the inside of the swirl generator is visible.
FIG. 2 is a side view of the swirl generator shown in FIG. 1, showing the housing in cross section so that the interior thereof is visible.
3 is a cross-sectional view taken along line AA ′ of the swirl generator illustrated in FIG. 2.
4 is a cross-sectional view of the plasma flame generator shown in FIG.
Figure 5 is a side view of a swirl generator according to another embodiment of the present invention, shown in cross-sectional view so that the inside.
6 is a longitudinal cross-sectional view of the swirl generator shown in FIG.
7 is a side view of a swirl generator according to another embodiment of the present invention, which is shown in cross-section so that the inside thereof is visible.

Hereinafter, with reference to the drawings will be described in detail the configuration and operation of the embodiment of the present invention.

First, preferred embodiments of the present invention will be described in detail with reference to the drawings. 1 is a perspective view of a microwave plasma processing apparatus (hereinafter, abbreviated as "plasma apparatus") for gas treatment according to an embodiment of the present invention. Referring to FIG. 1, in the plasma apparatus 100 according to an embodiment of the present invention, a swirl generator 110 generating a swirl gas and a swirl gas generated by the swirl generator 110 may process plasma. The plasma reaction unit 160 is included. The plasma apparatus 100 processes harmful gas discharged from a process chamber of a semiconductor manufacturing facility. Although not shown, harmful gases are introduced into the plasma apparatus 100 and treated by a vacuum pump positioned upstream or downstream of the plasma apparatus 100, and then discharged. The gases discharged from the plasma apparatus 100 are discharged. It can be further processed by a scrubber. For convenience of explanation, a reference axis X extending in a straight line is introduced.

The swirl generator 110 forms a swirl on the harmful gas to be treated before the harmful gas to be treated flows into the plasma reaction unit 160. In FIG. 2 the swirl generator shown in FIG. 1 is shown as a side view and in FIG. 3 the swirl generator is shown as a cross sectional view taken along line AA ′ of FIG. 2. 1 to 3, the swirl generator 110 may include a housing 140 that provides an internal space in which a flow of harmful gas to be treated is changed into a swirl (vortex), and an internal space of the housing 140. The gas inlet pipe 120 for introducing the target harmful gas and the flow conversion member 130 for converting the harmful gas to be processed through the gas inlet pipe 120 into the annular flow in the inner space of the housing 140. And a plurality of swirl forming fins 150 for guiding the flow of the noxious gas so that the noxious gas converted into the annular flow by the flow conversion member 130 forms a swirl, and the noxious gas swirl is discharged. The gas discharge pipe 148 is provided.

The housing 140 is in the form of a tube extending around the reference axis X, and provides an internal space in which the flow of the harmful gas to be treated is changed to swirl. A portion of the gas inlet pipe 120, the flow converting member 130, and the plurality of swirl forming pins 150 are positioned in the inner space of the housing 140. The housing 140 includes an end wall 143, an outer circumferential wall 141 extending from the end wall 143, and an extension wall 146 extending from the end of the outer circumferential wall 141 to narrow the inner space. .

The end wall 143 is annular and is generally perpendicular to the reference axis X. As shown in FIG. An inlet connector is formed at the center of the end wall 143 and a gas inlet pipe 120 is connected to the inlet connector.

The outer circumferential wall 141 is in the form of a circular tube and is formed extending from the edge of the end wall 143 in a direction parallel to the reference axis X. The inner diameter of the outer circumferential wall 141 is kept constant. A portion of the gas inlet pipe 120, the flow conversion member 130, and the plurality of swirl forming pins 150 are positioned in a space corresponding to the inside of the outer circumferential wall 141 in the inner space of the housing 140.

The extension wall 146 is in the form of a truncated cone, extending in a direction away from the end of the outer circumferential wall 141 to the end wall 143, the inner diameter decreases and the inside becomes narrower toward the end. An outlet side connector is formed at the end of the extension wall 146 to communicate with the inner space of the housing 140, and a gas discharge pipe 148 is connected to the outlet side connector. The flow rate of gas increases in the section of the extension wall 146.

The gas inlet pipe 120 introduces harmful gas discharged from the process chamber (not shown) into the internal space of the housing 140. The gas inlet pipe 120 extends along the reference axis X and is disposed coaxially with the housing 140. The gas inlet pipe 120 passes through an inlet-side connector formed in the end wall 143 of the housing 140 and extends a predetermined length in the inner space of the housing 140. The harmful gas introduced into the internal space of the housing 140 through the gas inlet pipe 120 is converted into a ring-shaped flow by the flow conversion member 130.

The flow conversion member 130 is accommodated in the inner space of the housing 140 and changes the flow of harmful gas introduced into the inner space of the housing 140 through the gas inlet pipe 120 into a ring shape. The flow converting member 130 has a blocking wall 131 and a guide wall 137 extending from an edge of the blocking wall 131. The flow converting member 130 is disposed coaxially with the housing 140. The blocking wall 131 is in the form of a disc having a diameter larger than the outer diameter of the gas inlet pipe 120, is substantially perpendicular to the reference axis X, and is spaced apart from the end of the gas inlet pipe 120 by a predetermined distance. The gas discharged from the gas inlet pipe 120 by the blocking wall 131 is prevented from flowing while maintaining the flow direction. The guide wall 137 is in the form of a tube, and extends in a direction opposite to the flow direction of noxious gas discharged from the gas inlet pipe 120 from the edge of the blocking wall 131. The end of the guide wall 137 is spaced apart from the end wall 143 of the housing 140. The inner diameter of the guide wall 137 is greater than the outer diameter of the gas inlet pipe 120 so that an annular passage through which gas can pass is formed between the inner circumferential surface of the guide wall 137 and the outer circumferential surface of the gas inlet pipe 120. In addition, the outer diameter of the guide wall 137 is smaller than the inner diameter of the outer circumferential wall 141 of the housing 140 so that the gas can pass between the outer circumferential surface of the guide wall 137 and the inner circumferential surface of the housing 140. Is formed. Therefore, the harmful gas discharged from the gas inlet pipe 120 hits the blocking wall 131 and is reversed in flow direction, and flows through the annular passage between the guide wall 137 and the gas inlet pipe 120, and the housing ( After hitting the end wall 143 of the 140, the flow direction is reversed again to flow substantially parallel to the reference axis X through the annular passageway between the guide wall 137 and the outer circumferential wall 141 of the housing 140. do. Hazardous gases that flowed substantially parallel to the reference axis X through the annular passage between the guide wall 137 and the outer circumferential wall 141 of the housing 140 form swirls by the plurality of swirl forming pins 150. Done. In the present exemplary embodiment, the blocking wall 131 is described as having a flat plate shape. Alternatively, the barrier wall 131 may have a shape in which an inner space becomes narrower as it moves away from the gas inlet pipe 120. In this case, the gas discharged from the gas inlet pipe 120 may be more easily guided to a passage formed between the guide wall 137 and the gas inlet pipe 120.

The plurality of swirl forming pins 150 are arranged in the annular passage between the guide wall 137 and the outer circumferential wall of the housing 140 at equal intervals along the circumferential direction as one embodiment of the swirl forming means of the present invention. do. The plurality of swirl forming pins 150 are in the form of plates extending along the radial direction, and are inclined with respect to the reference axis X so as to be twisted in the same direction. The noxious gas to be processed passing through the annular passage between the guide wall 133 of the flow conversion member 130 and the outer circumferential wall 141 of the housing 140 forms a swirl while passing through the plurality of swirl forming pins 150. As it passes through the extending wall 146, the flow velocity increases.

The gas discharge pipe 148 extends downstream along the reference axis X from the end of the extension wall 146 where the outlet side connector of the extension wall 146 is formed so that the downstream end is connected to the plasma reaction unit 160. The swirl gas is supplied to the plasma reaction unit 160 through the gas discharge pipe 148. The gas discharge pipe 148 is generally the same as the gas inlet pipe 120 and directly.

The plasma reaction unit 160 processes the harmful gas introduced through the swirl generator 110 through a plasma reaction by microwaves. 4 is a cross-sectional view of the plasma reaction unit 160 shown in FIG. 1 and 4, the plasma reactor 160 includes a waveguide 180 and a pipe member 170 vertically installed at a position where microwaves are densely aggregated in the waveguide 180. Although not shown, the plasma reaction unit 160 may include a microwave generator such as a magnetron that generates microwaves transmitted through the waveguide 180, and an igniter installed inside the pipe member 170 to generate a flame. It is further provided. Since the waveguide 180 includes a configuration of one commonly used in the microwave plasma torch, a detailed description thereof will be omitted. The tube member 170 is formed of a dielectric such as alumina, zirconia (ZrO ₂ ), yttria (Y ₂ O ₃ ), sapphire, quartz or glass. The front end of the pipe member 170 is connected to the connecting pipe 148 of the housing 140, and the rear end of the pipe member 170 is connected to the exhaust pipe 199.

Referring now to the drawings, the embodiment of the present invention described above as the configuration center will be described with the center of action.

The noxious gas generated in the process chamber (not shown) is introduced into the internal space of the housing 140 through the gas inlet pipe 120 of the plasma torch device 100 to a gas transfer means such as a vacuum pump (not shown). The noxious gas to be treated introduced into the internal space of the housing 140 through the gas inlet pipe 120 strikes the blocking wall 131 of the flow conversion member 130 and then reverses the flow direction thereof so that the flow conversion member 130 It flows through the annular passage between the guide wall 137 and the gas inlet pipe 120, and after hitting the end wall 143 of the housing 140, the flow direction is reversed again, so that the guide wall of the flow conversion member 130 ( Through the annular passage between the 137 and the outer circumferential wall 141 of the housing 140 flows substantially parallel to the reference axis (X). Hazardous gases that flowed substantially parallel to the reference axis X through the annular passage between the guide wall 137 of the flow conversion member 130 and the outer circumferential wall 141 of the housing 140 may be provided with a plurality of swirl forming fins 150. Swirl is formed, and the flow velocity increases while passing through the section of the extension wall 146 where the inner space is narrowed. By supplying the harmful gas having a swirl-like flow through the connecting pipe 148 to the plasma reaction unit 160 at a high speed, the plasma reaction forming the plasma flame (F) in the plasma reaction unit 160 is stably maintained. Therefore, the harmful gas removal efficiency by the plasma reaction is also maintained stably.

5 and 6 illustrate a swirl generator according to another embodiment of the present invention. 5 and 6, a swirl generator according to another embodiment of the present invention includes a housing 140, a gas inlet pipe 120, a flow conversion member 130, and a partition wall 250. Since the housing 140, the gas inlet pipe 120, and the flow converting member 130 have the same configuration as the embodiments described with reference to FIGS. 1 to 3, a detailed description thereof will be omitted. The partition wall 250 is another embodiment of the swirl forming means of the present invention.

The partition wall 250 is formed to block a space between the housing 140 and the flow conversion member 130, thereby dividing the internal space of the housing 140 into an upstream side and a downstream side. A plurality of through holes 255 are formed in the partition wall 250 along the circumferential direction. Each of the plurality of through holes 255 is inclined with respect to the reference axis X to be twisted in the same direction and faces inward in the radial direction. The harmful gas to be treated forms a swirl while passing through the through hole 255 formed in the barrier rib 250.

7 shows another swirl generator in another embodiment of the present invention. Referring to FIG. 7, a swirl generator according to another embodiment of the present invention includes a housing 140, a gas inlet pipe 120, a gas discharge pipe 348, and a blocking wall 350. Since the housing 140 and the gas inlet pipe 130 have the same configuration as the embodiment described with reference to FIGS. 1 to 3, a detailed description thereof will be omitted.

The gas discharge pipe 348 is connected to the outlet connector of the housing 140 and is partially extended to the internal space of the housing 140. The gas discharge pipe 348 surrounds the end of the gas inlet pipe 120 in the inner space of the housing 140. The inner diameter of the gas discharge pipe 348 is larger than the outer diameter of the gas inlet pipe 120.

The blocking wall 350 is formed to be spaced apart from the end of the gas inlet pipe 120 in the gas discharge pipe 348. The blocking wall 350 is located in an area of the inner space of the housing 140. The harmful gas introduced through the gas inlet pipe 120 by the blocking wall 350 is bent in the opposite direction and flows into the passage between the gas inlet pipe 120 and the gas discharge pipe 348.

The gas discharge pipe 348 is formed with a plurality of through holes 355 located in the inner space of the housing 140 and located downstream from the blocking wall 350. The outside and the inside of the gas discharge pipe 348 communicate with each other by the plurality of through holes 355. The plurality of through holes 355 extend inclined with respect to the reference axis X so that the plurality of through holes 355 are directed downward and twist in the same direction. Toxic gas passes through the through hole 355 to form a swirl.

Although the present invention has been described through the above embodiments, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100: plasma apparatus 110: swirl generator
120: inlet pipe 130: flow conversion member
131: blocking wall 137: guide wall
140: housing 141: outer peripheral wall
143: end wall 146: extension wall
148 connector 150 swirl forming pin
160: plasma reaction unit 170: pipe member
180: waveguide

Claims (21)

A swirl generator for changing a flow of harmful gas to be treated into a swirl form; And
It includes a plasma reaction unit for processing the harmful gas by using a plasma reaction using a microwave to the harmful gas of the swirl form formed by the swirl generator,
The swirl generator,
A tubular housing having an end wall and an outer circumferential wall extending from the end wall and providing an inner space through which the harmful gas to be treated flows;
A gas inlet pipe extending in parallel with the outer circumferential wall from the end wall in the inner space such that the harmful gas to be treated enters the inner space;
A gas discharge pipe through which swirl gas is discharged from the internal space;
A flow conversion member for introducing the harmful gas to be treated introduced into the internal space through the gas inlet pipe radially outward from the internal space to change into a ring-shaped flow; And
And a swirl forming means for forming a swirl in the harmful gas to be treated which is changed into a ring shape by the flow converting member in the inner space,
The flow converting member includes a barrier wall spaced apart from an end of the gas inlet tube, and a guide wall extending in parallel with the gas inlet tube from a space between the gas inlet tube and the outer circumferential wall. ,
The end of the guide wall is located spaced apart from the end wall,
Microwave plasma apparatus for gas treatment. The method according to claim 1,
The swirl forming means has a plurality of swirl forming pins disposed along the circumferential direction in a space between the guide wall and the outer circumferential wall,
The plurality of swirl forming fins are all twisted in the same direction,
Microwave plasma apparatus for gas treatment. delete delete The method according to claim 2,
And said plurality of swirl forming fins protrude from an outer circumferential surface of said guide wall. The method according to claim 1,
The swirl forming means includes a partition wall which divides the space between the guide wall and the outer circumferential wall into an upstream side and a downstream side, and has a plurality of through holes formed therein,
The plurality of through-holes are gas-treated microwave plasma apparatus extending in a twisted direction in the same direction. delete delete The method according to claim 1,
The gas discharge pipe is formed to connect with the guide wall,
The swirl forming means has a plurality of through holes formed in the gas discharge pipe in the inner space,
The plurality of through holes extend in a twisted direction in the same direction,
Microwave plasma apparatus for gas treatment. delete The method according to claim 1,
The gas plasma processing apparatus for a gas treatment is formed in the inner space of the housing passageway is narrowed toward the downstream side so that the flow rate of the harmful gas to be treated increases. The method according to claim 1,
The plasma reaction unit includes a waveguide through which microwaves are transmitted, and a tube member installed at a location where microwaves are concentrated at a high density in the waveguide, and a pipe member through which a harmful gas swirl discharged from the swirl generator passes. Device. In the microwave plasma apparatus for treating harmful gases using a plasma reaction using microwaves to change the flow of the harmful gas into a swirl form to provide a region in which the plasma reaction occurs,
A tubular housing having an end wall and an outer circumferential wall extending from the end wall and providing an inner space through which noxious gas to be treated flows;
A gas inlet pipe extending in parallel with the outer circumferential wall from the end wall in the inner space such that the harmful gas to be treated enters the inner space;
A gas discharge pipe through which swirl gas is discharged from the internal space;
A flow conversion member for introducing the harmful gas to be treated introduced into the internal space through the gas inlet pipe radially outward from the internal space to change into a ring-shaped flow; And
A swirl forming means for forming a swirl in the harmful gas to be treated which is changed into a ring shape by the flow converting member in the inner space,
The flow conversion member includes a barrier wall spaced apart from an end of the gas inlet tube, and a guide wall extending in parallel with the gas inlet tube from a space between the gas inlet tube and the outer circumferential wall. ,
The end of the guide wall is located spaced apart from the end wall,
Swirl generator for microwave plasma device. The method according to claim 13,
The swirl forming means has a plurality of swirl forming pins disposed along the circumferential direction in a space between the guide wall and the outer circumferential wall,
The plurality of swirl forming fins are all twisted in the same direction,
Swirl generator for microwave plasma device. delete The method according to claim 14,
The plurality of swirl forming pins are formed to protrude from the outer peripheral surface of the guide wall,
Swirl generator for microwave plasma device. The method according to claim 13,
The swirl forming means includes a partition wall which divides the space between the guide wall and the outer circumferential wall into an upstream side and a downstream side, and has a plurality of through holes formed therein,
The plurality of through holes are all twisted in the same direction extends for the microwave generator for a microwave plasma apparatus. delete delete The method according to claim 13,
The gas discharge pipe is formed to connect with the guide wall,
The swirl forming means has a plurality of through holes formed in the gas discharge pipe in the inner space,
The plurality of through holes extend in a twisted direction in the same direction,
Swirl generator for microwave plasma device. delete

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