KR101323720B1 - Rotary flame burner for waste gas - Google Patents

Abstract

A flame rotary combustion burner for waste gas treatment is disclosed. The present invention provides a combustion burner for burning waste gas discharged after being used in a semiconductor manufacturing process or a chemical process, the waste gas supply manifold being connected to a waste gas supply unit and having a waste gas transfer path therein; A fuel supply body coupled to the outside of the waste gas supply manifold, a passage formed therein, and a fuel gas inlet for supplying fuel gas to one side in a tangential direction with the waste gas supply manifold; An outer body coupled to the outside of the fuel supply body, having a reaction gas supply port through which reaction air is supplied, and equipped with a burner tip on which a flame is generated, and having an outlet opening communicating with the waste gas transfer path; It is coupled to the inside of the outlet of the outer body, and comprises a flame discharge member for rotating the flame discharged to form a vortex.
According to this, sufficient mixing of waste gas and flame can be achieved, which enables high efficiency treatment, and can reduce operating cost by using reaction air, and can reduce fuel consumption and by-product generation through complete combustion. It works.

Description

ROTARY FLAME BURNER FOR WASTE GAS

The present invention relates to a flame rotary combustion burner for waste gas treatment, and more particularly, to provide a rotational force to the flame to improve the mixing of the flame and the waste gas, and to improve the treatment efficiency of the waste gas to significantly improve incomplete combustion. The present invention relates to a flame rotary combustion burner for waste gas treatment.

In general, waste gases emitted from chemical processes or semiconductor manufacturing processes are toxic, explosive, and corrosive, which is not only harmful to the human body but also causes environmental pollution when released into the atmosphere.

Therefore, such waste gas is required to purify the harmful components to lower than the allowable concentration, it is legally mandatory to discharge only harmless gas through the purification process to remove such toxic substances into the atmosphere.

There are three main methods for treating the noxious gas emitted from the semiconductor manufacturing process. The first is a burning method of decomposing, reacting or burning a flammable gas mainly containing hydrogen groups in a high temperature combustion chamber, and the second is mainly treating a water-soluble gas by dissolving it in water while passing water stored in the tank. Wetting is a method of wetting, and finally, an adsorption method for purifying by physical or chemical adsorption to an adsorbent while a harmful gas which does not ignite or is insoluble in water passes through the adsorbent.

More specifically, such waste gas purification treatment includes wet scrubber, thermal wet scrubber using electric heater, direct burn wet scrubber using fuel gas burner, and physical chemistry using adsorbent. It can be subdivided into adsorption method (Dry Scrubber) and electric discharge method (Plasma Scrubber).

1 and 2, the configuration of the gas burner nozzle of the waste gas purification apparatus according to the prior art is shown in plan and cross-sectional views, respectively.

The coaxial flow flame burner 2 according to the prior art has a plurality of nozzles arranged coaxially with each other and formed in the order of the waste gas supply nozzle 10, the fuel supply nozzle 20, and the oxidant supply nozzle 30 from the inside. It is.

The waste gas supply nozzle 10 supplies waste gas 12 discharged from a semiconductor manufacturing process or a chemical process, and the waste gas 12 is chemical vapor deposition (CVD) or etching (CVD). Exhaust gas emitted from the process and concentrated with a large amount of harmful substances. It is a substance that causes environmental pollution.

The fuel supply nozzle 20 injects a fuel gas 22 serving as a fuel of flame, and liquefied natural gas, liquefied petroleum gas, hydrogen gas, etc. are mainly used as the fuel gas 22.

The oxidant supply nozzle 30 injects an oxidization gas 32 that forms a flame by a combustion reaction with the fuel gas 22, and oxygen (O 2) or air ( Air is mainly used.

The process in which the waste gas 12 supplied by the waste gas supply nozzle 10 is burned by the burner for the coaxial flow flame is as follows.

The fuel gas 22 injected by the fuel supply nozzle 20 and the oxidizing gas 32 injected by the oxidant supply nozzle 30 are mixed and transferred to the combustion chamber. At this time, when the spark is ignited by a spark igniter (not shown), the fuel gas 22 and the oxidizing gas 32 are discharged by the spark, and the waste gas 12 is mixed with the fuel gas 22 and burned. Forcing to oxidation.

Since the fuel supply nozzle 20 and the oxidant supply nozzle 30 are coaxially arranged in parallel with each other, the fuel supply nozzle 20 and the oxidant supply nozzle 30 are injected from the fuel gas 22 and the oxidant supply nozzle 30. The oxidizing gas 32 to be injected is injected in parallel in the same direction.

On the other hand, the fuel gas 22 injected from the fuel supply nozzle 20 and the oxidizing gas 32 injected from the oxidant supply nozzle 30 are mixed with each other at a predetermined point due to the diffusion phenomenon, and ignited by the flame. By doing so, the combustion process generates a flame.

However, as the fuel gas 22 and the oxidizing gas 32 are injected in parallel to each other in this way, the diffusion of the fuel gas 22 and the oxidizing gas 32 is not performed properly, which causes some of the fuel gas 22 to oxidize. There was a problem in that the combustion chamber exited the combustion chamber in an unreacted state that did not react with the gas 32, resulting in incomplete combustion.

The present invention has been made to solve the above-mentioned problems of the prior art, by providing a rotational force to the flame can be effectively mixed with the flame and waste gas to obtain a high treatment efficiency, so that incomplete combustion phenomenon can be significantly improved It is an object to provide a flame rotary combustion burner for waste gas treatment.

An object of the present invention described above is a combustion burner for burning waste gas discharged after being used in a semiconductor manufacturing process or a chemical process, the waste gas supply manifold connected to a waste gas supply unit and having a waste gas transfer path therein; A fuel supply body coupled to the outside of the waste gas supply manifold, a passage formed therein, and a fuel gas inlet for supplying fuel gas to one side in a tangential direction with the waste gas supply manifold; An outer body coupled to the outside of the fuel supply body, having a reaction gas supply port through which reaction air is supplied, and equipped with a burner tip on which a flame is generated, and having an outlet opening communicating with the waste gas transfer path; It is coupled to the inside of the outlet of the outer body, it can be achieved by a flame rotary combustion burner for treating waste gas, characterized in that it comprises a flame discharge member for rotating the discharged flame to form a vortex.

The waste gas delivery path of the waste gas supply manifold is characterized in that the neck portion of the inlet side is formed in a conical shape in which the diameter is narrow and the diameter increases toward the outlet side.

The flame emitting member includes a panel mounted on a bottom surface of an outer body, and a plurality of twisted diaphragms formed perpendicular to the center of the panel and having a twist angle in the same direction, and the flames are emitted while passing through the plurality of diaphragms. It is characterized by forming this vortex.

The plurality of twisted diaphragm is composed of the first and second twisted diaphragm formed in the upper and lower, the first twisted diaphragm is disposed to correspond to the outlet of the outer body to enable the reaction air and fuel gas to obtain a rotational force, The second twisted diaphragm is characterized in that it is possible to obtain a rotational force to be burned by mixing the rotating flame and waste gas.

According to the present invention, sufficient mixing of the waste gas and the flame can be achieved, thereby enabling high efficiency treatment, and reducing the operating cost by using the reaction air, and reducing the amount of fuel used and by-products by inducing complete combustion. It can be effected.

Figures 1 and 2 show the prior art,
3 is a perspective view showing a flame rotary combustion burner for waste gas treatment according to the present invention;
4 is a cross-sectional view showing a flame rotary combustion burner for waste gas treatment according to the present invention;
5 is a perspective view showing a 'flame emitting member' of the flame rotary combustion burner for waste gas treatment according to the present invention;
Figure 6 is a drawing substitute photograph showing the flame emission of the flame rotary combustion burner for waste gas treatment according to the present invention.

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

3 is a perspective view showing a flame rotary combustion burner for waste gas treatment according to the present invention, Figure 4 is a cross-sectional view showing a flame rotary combustion burner for waste gas treatment according to the present invention, Figure 5 is a waste gas treatment according to the present invention Figure 6 is a perspective view showing a 'flame release member' of the flame rotary combustion burner, Figure 6 is a drawing substitute photograph showing the flame discharge of the flame rotary combustion burner for waste gas treatment according to the present invention.

As shown in Figures 3 to 6, the flame rotary combustion burner (A) for waste gas treatment according to the present invention,

By burning waste gas discharged after being used in semiconductor manufacturing process or chemical process,

A waste gas supply manifold 1 connected to the waste gas supply unit (not shown) and having a waste gas transport path 10 formed therein;

A fuel gas inlet 22 coupled to the outside of the waste gas supply manifold 1 and having a passage 20 formed therein and supplying fuel gas to one side thereof is tangentially mounted to the waste gas supply manifold 1. A fuel supply body 2;

It is coupled to the outside of the fuel supply body 2, the reaction gas supply port 32 is formed to supply the reaction air, the burner tip 100 is generated on the side of the flame is installed, the waste gas transfer path 10 An outer body 3 formed with a drawer 33 communicating with the outer body 3;

It is coupled to the inside of the outlet 33 of the outer body (3), and comprises a flame discharge member (4) for rotating the flame discharged to form a vortex.

The waste gas supply manifold 1 is formed in a cylindrical shape, an inlet 11 connected to a waste gas supply unit (not shown) is formed at an upper end thereof, an outlet 12 is formed at a lower end thereof, and the inlet 11 is formed therein. ) And the waste gas transfer path 10 is connected to the outlet 12 through.

The waste gas delivery path 10 is formed in a conical shape in which the neck portion of the inlet 11 side is narrow in diameter and the diameter of the inlet 12 extends toward the outlet 12, so that the waste gas passes through the neck portion to increase the conveying speed. Can be exerted.

In addition, by supplying nitrogen (N ₂ ) gas to the neck portion of the inlet 11 side, the venturi effect is increased, and thus the venturi effect is formed, thereby preventing the flame from spreading in the inlet 11 direction.

The fuel supply body 2 has a fuel gas inlet 22 mounted at one side in a tangential direction so that the fuel gas is introduced therethrough, and the fuel gas introduced into the passage 20 through the lower outlet 24. Inflow to the outlet 12 of the waste gas transport path 10 is mixed with the waste gas.

Preferably, the outlet 24 narrows the flow path so that the flow rate of the fuel gas mixed with the waste gas is faster than the flame propagation speed, thereby preventing the closed end of the flame backflow.

The flame emitting member 4 may be rotated in one direction by applying rotational force to the flame to improve the mixing efficiency of the waste gas and the fuel gas, thereby allowing complete combustion.

The flame release member 4 is formed perpendicular to the panel 42 mounted on the bottom surface of the outer body 3 and the passage communicating with the outlet 33 of the outer body 3 from the center of the panel 42. It consists of a plurality of twisted diaphragms 43 formed to have a torsion angle of about 5-15 degrees in the same direction.

Therefore, the waste gas and the fuel gas are rotated to form a vortex and mixed, and burned by the flame generated from the burner tip 100, but the flame also rotates to achieve complete combustion of the waste gas.

In addition, the plurality of twisted diaphragms 43 includes first and second twisted diaphragms 431 and 432 formed at an upper portion and a lower portion at a central upper portion of the panel 42 of the flame release member 4.

The second twist diaphragm 432 is disposed along the circumferential direction of the central through hole of the panel 42 to have a constant twist angle.

A ring-shaped first retainer 44 is coupled to an upper end of these second twist diaphragms 432.

Preferably, the second twist diaphragm 432 is disposed under the fuel supply body so as to rotate the fuel gas to be mixed with the waste gas.

Therefore, as the fuel gas passes through the second twist diaphragm 432, a rotational force may be obtained, and the mixing efficiency with the waste gas may be improved.

In addition, the first twisted diaphragm 431 is vertically disposed on the upper part of the first retainer 44 to have a constant torsion angle, similar to the second twisted diaphragm 432, and a ring-shaped second retainer 45 is disposed on the upper end thereof. Combined.

Preferably, the second twist diaphragm 432 is formed to be longer than the first twist diaphragm 431. The first twisted diaphragm 431 is shortly formed to be about 1/3 of the length of the second twisted diaphragm 432.

And a burner tip 100 in which a flame is generated is mounted on a part of the second twist diaphragm 432.

Therefore, the waste gas, fuel gas, and reaction air passing through the second twist diaphragm 432 are mixed and combusted, and the generated flame is rotated by forming a vortex.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that the claims fall within the scope of the claims.

1: waste gas supply manifold 2: fuel supply body
3: outer body 4: flame-emitting member
10: waste gas transfer path 22: fuel gas inlet
43: twisted diaphragm

Claims (9)

In the combustion burner which burns the waste gas discharged after being used in semiconductor manufacturing process or chemical process,
A waste gas supply manifold connected to the waste gas supply unit and having a waste gas transfer path formed therein;
A fuel supply body coupled to the outside of the waste gas supply manifold, a passage formed therein, and a fuel gas inlet for supplying fuel gas to one side in a tangential direction with the waste gas supply manifold;
An outer body coupled to the outside of the fuel supply body, having a reaction gas supply port through which reaction air is supplied, and equipped with a burner tip on which a flame is generated, and having an outlet opening communicating with the waste gas transfer path;
Flame release member is coupled to the inside of the outlet of the outer body, to rotate the flame discharged to form a vortex
Flame rotary combustion burner for waste gas treatment comprising a. The method of claim 1,
The flame release member
A panel mounted on a bottom surface of the outer body and a plurality of twisted diaphragms formed perpendicular to a passage communicating with the outlet of the outer body from the center of the panel and having a twist angle in the same direction;
The flame-burning flame burner for processing waste gas, characterized in that the flame discharged while passing through the plurality of diaphragm to form a vortex. 3. The method of claim 2,
The plurality of twisted diaphragm
And a first and second twisted diaphragm formed at upper and lower portions of the center of the panel of the flame release member. The method of claim 3, wherein
The second twist diaphragm is arranged to have a twist angle while being perpendicular to the circumferential direction of the central through hole of the panel,
A first retainer is coupled to an upper end of the second twist diaphragm,
The first twisted diaphragm is disposed to have a twist angle while being perpendicular to an upper portion of the first retainer.
Flame retardant combustion burner for waste gas treatment, characterized in that the second retainer is coupled to the upper end of the first twisted diaphragm. 5. The method of claim 4,
And a second twisted diaphragm disposed under the fuel supply body to rotate the fuel gas and mix the waste gas with the waste gas. 5. The method of claim 4,
A burner tip for generating a flame is mounted on a portion of the second twisted diaphragm, and waste gas, fuel gas, and reaction air passing through the second twisted diaphragm are mixed and combusted, and the flame forms a vortex. Flame-burning burners for waste gas treatment The method of claim 1,
The waste gas supply passage of the waste gas supply manifold is formed in a conical shape in which the neck portion of the inlet side is narrow in diameter and the diameter of the waste gas is increased toward the outlet side. Flame rotary combustion burner for waste gas treatment, characterized in that. 8. The method of claim 7,
Waste gas processing flame rotary combustion burner characterized in that to prevent the spread of the flame in the inlet direction by supplying nitrogen gas to the neck portion of the inlet side to increase the venturi effect. The method of claim 1,
The fuel supply body
An outlet is formed at a lower portion so that fuel gas introduced into the internal passage is supplied to the waste gas transport path.
And the outlet narrows the flow path so that the flow rate of the fuel gas mixed with the waste gas is faster than the flame propagation speed to block flame backflow.

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