KR20050040085A - Method of scrubbing perfluorinated compounds - Google Patents

Abstract

The present invention relates to a method for treating fluorine-containing compounds of exhaust gas containing fluorine-containing compounds, which are gases used for etching, chemical vapor deposition (CVD) and equipment cleaning in semiconductor manufacturing processes.

The present invention includes an oxygen enrichment step of sucking the outside air through an oxygen enrichment apparatus to increase the concentration of oxygen and discharge the oxygen; Supplying gaseous fuel by the gaseous fuel source; Premixing the fuel-air and the fuel-fluorine compound in separate premixing chambers respectively using a premixing device; Injecting the premixed fuel-air mixed gas and fuel-fluorine compound into the combustion chamber through the inlets, respectively; Decomposing the fluorine-containing compound into a high temperature flame in the combustion chamber; Reducing nitrogen oxides (NOx) generated by decomposition of the fluorine-containing compound through a catalyst to minimize the concentration of the nitrogen oxides and to discharge the exhaust gas; Cooling the exhaust gas in the exhaust gas and wet treating harmful components in the exhaust gas; And controlling, by the electronic controller, the fuel from the air and gaseous fuel sources from the oxygen incubator and the monitoring and control of the flame temperature in the combustion chamber.

According to the above method, the present invention can maximize the decomposition rate of the fluorine-containing compound gas by inducing an efficient high temperature flame by raising the flame temperature to at least 1300 ° C. or more, and reducing a large amount of nitrogen oxides (NOx) to discharge nitrogen oxides. There is an effect to minimize the concentration.

Description

Method of treating fluorine-containing compounds {Method of scrubbing Perfluorinated compounds}

The present invention relates to a method for treating fluorine-containing compounds of exhaust gas containing fluorine-containing compounds, which are gases used for etching, chemical vapor deposition (CVD) and equipment cleaning in semiconductor manufacturing processes.

Perfluorinated compounds (PFCs) are gases used for etching, chemical vapor deposition (CVD) and equipment cleaning in semiconductor manufacturing processes. Representative fluorine-containing compound gases include CF ₄ , C ₂ F ₆ , C ₃ F ₈ , CHF ₃ , NF ₃ , SF ₆ , and the like. This fluorine-containing compound (PFC) is known as a gas that causes the global greenhouse effect by causing the global greenhouse effect. The global warming index (GWP) of these gases is a very stable compound that is about 6,000 to 24,000 times higher than carbon dioxide.

Accordingly, countries around the world have agreed to voluntarily reduce the amount of fluorine-containing compound gas discharge, and it is inevitable to reduce the amount of fluorine-containing compound gas discharged through the removal device like the present invention, which was discharged without treatment. Conventional methods of treating harmful gases in semiconductor manufacturing processes include the treatment of harmful gases by flowing them into high-temperature furnaces using electric heating wires. Some applications have been applied to the treatment of compounds such as HFC that are not applicable to treatment and are relatively less stable. In addition, the treatment technology of the fluorine-containing compound by the combustion technique is possible to apply a special design technique. In other words, in the case of combustors applied to other products such as boilers, the flame temperature is not high enough to process fluorine-containing gas, and the addition of hydrogen is very reluctant to use in semiconductor manufacturing plants due to the easy method or the risk of storage and use. It is impossible. Therefore, the application of the membrane-type oxygen enrichment apparatus, which is attached to the apparatus and ensures the safety and convenience of use as in the present invention, may be considered the best method.

Other methods include the separation and recovery of fluorine-containing compound gas in the off-gas using adsorbents or membranes, but they are not practical due to technical limitations and deterioration of separation efficiency. .

Therefore, the most suitable technique for treating such fluorine-containing compounds is combustion treatment technology. In order to burn these fluorine-containing compounds, a special high-temperature combustion technique and an increase in residence time for long contact with the fluorine-containing compound flame in the combustor This is the key.

An object of the present invention for solving the problems of the prior art as described above is to pre-mix fuel and air and fuel and fluorine-compound gas in the pre-mixing chamber to increase the concentration of oxygen in the air by using a separation membrane air for combustion The temperature of the flame is raised to at least 1300 ℃ to induce an efficient high temperature flame, and the structure of the combustion chamber is formed into a double-tubular combustion chamber composed of an outer tube and an inner tube to extend the residence time of the flame to reduce the decomposition rate of the fluorine-containing compound gas. To maximize.

Still another object of the present invention is to reduce a large amount of nitrogen oxides (NOx) by attaching a catalyst to the outlet portion of the exhaust gas to minimize the concentration of nitrogen oxides.

A fluorine-containing compound treatment method of the present invention for achieving the above object, the oxygen enrichment device that can be discharged by increasing the concentration of oxygen by sucking the outside air; A gas fuel supply source capable of supplying gas fuel; A fuel-air premixing chamber capable of mixing fuel supplied from the gaseous fuel source and enriched air containing a high concentration of oxygen discharged from the oxygen enrichment apparatus, and fuel and fluorine-containing compounds supplied from the gaseous fuel source A premixing apparatus including a fuel-fluorine compound premixing chamber capable of mixing the contained and discharged gases; The fuel-air mixed gas discharged from the fuel-air premixing chamber may be injected into the upper portion of the outer side surface of the outer shell to form at least one gas fuel-air inlet inclined with respect to the outer side surface of the outer shell. An upper portion having an outer surface having at least one fuel-fluorine compound inlet through which the fuel-fluorine compound discharged from the fuel-fluorine compound premixing chamber can be injected, and at least one burner mounted on an inner wall thereof; A combustion chamber including an inner tube having a catalyst installed therein and a honeycomb-shaped material disposed therein; An exhaust gas treatment apparatus capable of cooling the exhaust gas emitted from the combustion chamber and dissolving harmful components in water to treat the exhaust gas; By a fluorine-containing compound processing system comprising an electronic control unit for controlling the fuel from the air and gas fuel source from the oxygen enrichment device and the monitoring and control of the flame temperature in the combustion chamber,

An oxygen enrichment step of sucking the outside air through the oxygen enrichment apparatus to increase the concentration of oxygen and discharge the oxygen; Supplying gaseous fuel by the gaseous fuel source; Premixing fuel-air and fuel-fluorine compound in separate premixing chambers using the premixing apparatus; Injecting the premixed fuel-air mixture gas and fuel-fluorine compound into the combustion chamber through the inlets, respectively; Decomposing the fluorine-containing compound into a hot flame in a combustion chamber; Reducing nitrogen oxides (NOx) generated by the decomposition of the fluorine-containing compound through a catalyst to minimize the concentration of nitrogen oxides and to discharge the exhaust gas; Cooling the exhaust gas in the exhaust gas and wet treating harmful components in the exhaust gas; And controlling, by the electronic controller, control of the fuel from the air and gaseous fuel sources from the oxygen enrichment device and monitoring and controlling the flame temperature in the combustion chamber.

The method may further include installing a filter before removing the fluorine-containing compound gas to the fuel-fluorine compound pre-mixing chamber of the pre-mixing device to remove foreign substances from the exhaust gas containing the fluorine-containing compound. .

On the other hand, the pre-mixing the fuel-air and fuel-fluorine compound in a separate pre-mixing chamber using the pre-mixing device, the high concentration of the fuel supplied from the gas fuel source and the oxygen enrichment discharged from the oxygen enrichment device Oxygen-rich enriched air is mixed in the fuel-air pre-mixing chamber and pre-mixed in the fuel-fluorine-compound premixing chamber with the fuel supplied from the gaseous fuel source and the fluorine-containing compound discharged through the filter. Characterized in that it comprises a.

In addition, the step of wetly treating the harmful components in the exhaust gas is characterized in that it comprises the treatment by dissolving the harmful components in the exhaust gas in water.

In addition, the step of decomposing the fluorine-containing compound into a high temperature flame in the combustion chamber is characterized in that it comprises the decomposition of the fluorine-containing compound with a high temperature flame of at least 1,300 ㅀ C.

Hereinafter, with reference to the accompanying drawings will be described the present invention in more detail. Like reference numerals denote like elements in FIGS. 1 to 5 to be described below.

   1 is a circuit block diagram showing the configuration of a fluorine-containing compound processing method using the oxygen enrichment method according to the present invention, Figure 2 is a top view of the combustion chamber of the fluorine-containing compound processing method according to an embodiment of the present invention, 3 is a cross-sectional view taken along the line AA of FIG. 2.

    As shown in Figures 1 to 3, the fluorine-containing compound treatment method of the present invention, the oxygen enrichment apparatus 20 that can be discharged by inhaling the outside air to increase the concentration of oxygen; A gas fuel supply source 40 capable of supplying gas fuel; A fuel-air premixing chamber capable of mixing the fuel supplied from the gaseous fuel source 40 and the enriched air containing high concentration of oxygen discharged from the oxygen enrichment device 20, and the gaseous fuel source 40 A premixing device 30 including a fuel-fluorine compound premixing chamber capable of mixing the fuel supplied from the gas with the fluorine-containing compound to be discharged; At least one gaseous fuel-air inlet for injecting fuel-air mixture gas discharged from the fuel-air premixing chamber and inclined with respect to the outer surface of the facade 56 to an upper portion of the outer surface of the facade 56. 52, and at least one fuel-fluorine compound inlet 51 through which the fuel-fluorine compound discharged from the fuel-fluorine compound premixing chamber can be injected into the upper surface of the exterior 56. An inner tube 57 having one exterior 56, one or more burners 55 installed on the inner wall 57 ', a catalyst 54 on the top of the interior, and a honeycomb-like material 53 on the interior. Combustion chamber 50 and a; An exhaust gas treatment device 60 capable of cooling the exhaust gas from the combustion chamber 50 and then dissolving the hazardous component in water to treat the exhaust gas; And an electronic controller 70 capable of controlling the fuel from the air and gas fuel source 40 coming from the oxygen enrichment device 20 and monitoring and controlling the flame temperature in the combustion chamber 50. By fluorine compound treatment system,

An oxygen enrichment step of sucking the outside air through the oxygen enrichment apparatus 20 to increase the concentration of oxygen and discharge the oxygen; Supplying gaseous fuel by the gaseous fuel source (40); Premixing fuel-air and fuel-fluorine-containing compounds in separate premixing chambers using the premixing device (30); Injecting the premixed fuel-air mixture gas and fuel-fluorine compound into the combustion chamber through the inlets 52 and 51 respectively; Decomposing the fluorine-containing compound into a hot flame in a combustion chamber; Reducing nitrogen oxides (NOx) generated by decomposition of the fluorine-containing compound through a catalyst (54) to minimize exhaust concentration of nitrogen oxides to discharge the exhaust gas; Cooling the exhaust gas in the exhaust gas and wet treating harmful components in the exhaust gas; Performing control of the air from the oxygen enrichment device 20 and the fuel from the gas fuel supply source 40 by the electronic controller 70 and monitoring and controlling the flame temperature in the combustion chamber 50. do.

On the other hand, before sending the fluorine-containing compound gas to the fuel-fluorine compound pre-mixing chamber of the pre-mixing device 30, the filter 10 may be further installed to remove foreign substances in the exhaust gas containing the fluorine-containing compound. As (10), a prefilter, a carbon filter, a HEPA filter, a photocatalyst filter, or a nanosilver filter can be used, and it may not be provided as needed.

The oxygen enrichment device 20 is provided with a gas separation membrane therein, the gas separation membrane is a zeolite, flat membrane or hollow fiber membrane (membrane), etc., if the gas separation membrane can be discharged by increasing the concentration of oxygen in the intake air from the outside It may be of any type, including, and the production of a gas separation membrane and used as its raw material is well known, so a detailed description thereof will be omitted.

The gas fuel of the gas fuel source 40 may be any kind of gas as long as it can generate a high temperature flame when it is ignited in a combustion chamber, but LPG or LNG is preferably used in consideration of economical aspects. Do.

   The premixing device 30 is divided into two premixing chambers, a fuel-air premixing chamber and a fuel-fluorine compound premixing chamber. In the fuel-air premixing chamber, the fuel supplied from the gas fuel source 40 The enriched air containing the high concentration of oxygen discharged from the oxygen enrichment device 20 is mixed and sent to the fuel-air inlet 52 of the combustion chamber, and in the fuel-fluorine-compound premixing chamber, the gas fuel source 40 is supplied. The fuel supplied from the mixture and the fluorine-containing compound discharged through the filter 10 may be mixed and injected into the fuel-fluorine compound inlet 51 of the combustion chamber.

Although four fuel-fluorine compound inlets 51 are formed on the upper surface of the exterior 56 of the combustion chamber 50 at a predetermined interval, the present invention is not limited thereto and may be formed in one or more.

In addition, the fuel-air inlet 52 is shown to be inclined with respect to the outer surface of the outer surface 56 and two at regular intervals on the upper side of the outer surface 56 of the combustion chamber 50. However, one or more can be formed, for example, four can be formed as shown in the top view of the combustion chamber of the fluorine-containing compound treatment method according to another embodiment of the present invention of FIG.

The gas fuel-air inlet 52 is formed to be inclined with respect to the outer surface of the outer shell 56 at an upper portion of the outer surface of the outer shell 56 of the combustion chamber 50, but the inclination angle is preferably 10 °. It is not limited to this.

On the other hand, the reason for forming the gas fuel-air inlet 52 inclined with respect to the outer surface of the outer surface 56 of the combustion chamber 50 as described above is that the gas fuel-air is inclined at a constant flow rate through the inlet 52 This is to allow downward movement while rotating helically along the outer surface of the combustion chamber inner tube 57. At this time, the gas fuel-air moving downward in this way is mixed with the gas fuel-fluorine compound injected from the gas fuel-fluorine compound inlet 51 and moves downward to form a spiral flame upon ignition by the burner 55. It can move downward while the flame can enter the inner tube through the inner tube inlet 58 of the combustion chamber.

Referring to FIG. 3, the honeycomb-shaped material 53 is provided on the lower portion of the inner wall 57 ′ of the inner tube 57 of the combustion chamber 50 to enhance flame temperature and radiant heat. Although illustrated as being limited thereto, the present invention may be installed at the upper side or may be installed at both the upper side and the lower side. The honeycomb material 53 may be formed of a metal mesh or a ceramic mesh.

A catalyst 54 is installed at an upper portion of the inner tube 57, and gas fuel-air and gas fuel-fluorine compounds are mixed with each other and flow along the movement of the flame to decompose the fluorine-containing compounds by combustion. Nitrogen oxide (NOx), which is one of the by-products, is reduced before discharge to the inner tube outlet 59 to minimize the concentration of nitrogen oxides.

The exhaust treatment apparatus 60 may be of any type as long as it can cool the exhaust gas from the combustion chamber 50 and dissolve the harmful components in water.

The electronic controller 70 is capable of controlling the air from the oxygen enrichment device 20 and the fuel from the gas fuel supply source 40 and monitoring and controlling the flame temperature in the combustion chamber 50. Herein, the fuel supplied to the fuel-air premixing chamber and the fuel supplied to the fuel-fluorine compound premixing chamber may be separately controlled.

5 is a step-by-step diagram illustrating a fluorine-containing compound treatment method using the oxygen enrichment method of the present invention.

Referring to the description of the configuration of the fluorine-containing compound processing apparatus according to the present invention described above and the process of treating the fluorine-containing compound with reference to FIG.

First, gas fuel is supplied to the two premixing chambers of the premixing device 30 through the gas fuel supply source 40, respectively.

Separately, in FIG. 1, a filter 10 is further installed to remove solid components contained in the exhaust gas containing the fluorine-containing compound, and the exhaust gas is filtered and discharged by the filter 10. Since the filter 10 may not be provided as necessary, the exhaust gas containing the fluorine-containing compound may be sent directly to the fuel-fluorine-compound premixing chamber of the premixing device 30 without being filtered.

Subsequently, when the filter 10 is installed, the exhaust gas passing through the filter 10 is sent to the fuel-fluorine compound premixing chamber of the premixing device 30 through a tube, where a small amount of gas such as LNG or LPG The mixture with the fuel produces a mixed gas of fluorine-containing compounds and gaseous fuel.

On the other hand, the air (Air) is sent to the oxygen incubator 20 through the air intake pipe, the air containing a high concentration of oxygen, that is oxygen enriched is sent to the fuel-air premixing chamber and mixed with the gaseous fuel A mixture of fuel and air is produced.

The two mixed gases thus prepared are sent to the combustion chamber 50 through the fuel-air injection pipe 52 and the fuel-fluorine compound injection pipe 51, respectively. In the combustion chamber 50, the fuel-air mixture gas is complexed to form a high temperature flame, and the fuel-fluorine compound mixture gas is injected at two or four fuel-fluorine compound injection tubes 51 evenly to be injected into the combustion chamber at the top of the combustion chamber. Divided into) and sent into the combustion chamber. The fuel-air mixture gas is injected obliquely from two fuel-air injection pipes 52 to be injected from the upper side of the combustion chamber inclined along the tangential direction of the inner tube 57 in the combustion chamber 50 and forms a flame with the igniter. The flame and the fluorine-containing compound gas are formed in a spiral flame along a passage between the outer casing 56 and the inner tube 57 of the combustion chamber 50, and the flame descends from the upper part to the lower part, and arrives at the lower part of the outer part 56. The flame enters the inner tube 57. In the inner tube 57, a metal mesh is installed on at least one of the upper part and the lower part to promote radiant heat transfer, and an inner flame burner directed to the center is installed on the inner wall 57 'of the inner tube to maintain a high temperature state of the flame. During this process, the fluorine-containing gas reacts for a long residence time while flowing together along the flow of the flame to be completely decomposed, and the exhaust gas after the reaction is sent out of the combustion chamber through the inner tube outlet 59.

Subsequently, the exhaust gas composed of carbon dioxide (CO ₂ ), water vapor (H ₂ O), hydrofluoric acid (HF), and the like, which are by-products of the decomposition of the fluorine-containing compound at a high temperature, is sent to the exhaust gas treating apparatus.

In the exhaust gas treatment apparatus, first, the exhaust gas is cooled, and then the harmful components in the exhaust gas are treated wet. This wet treatment is preferably dissolved in water and treated.

In this series of processes, the control of air and fuel, the monitoring and control of flame temperatures, etc., are handled through control devices.

As a result of preparing a device according to the present invention and performing a preliminary experiment, C ₂ F ₆ in the fluorine-containing compound gas was diluted with nitrogen gas, and the removal rate of the fluorine-containing compound gas was measured to confirm that the removal rate was 99%. It demonstrated the possibility of the detoxification treatment of the fluorine-containing compound of this apparatus.

  As described above, those skilled in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features. Therefore, it is to be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention should be construed that all changes or modifications derived from the meaning and scope of the appended claims and their equivalents, rather than the detailed description, are included in the scope of the present invention.

The present invention according to the configuration as described above in the fuel and air and the fuel and the fluorine-containing compound gas in advance in the pre-mixing chamber to increase the concentration of oxygen in the air by using a separation membrane of the flame using the air for combustion Increase the temperature to at least 1300 ℃ to induce efficient high temperature flame, and by forming the structure of the combustion chamber into a double-tubular combustion chamber consisting of the appearance and inner tube to extend the residence time of the flame to maximize the decomposition rate of the fluorine-containing gas There is.

In addition, the present invention has the effect of minimizing the emission concentration of nitrogen oxides by reducing a large amount of nitrogen oxides (NOx) by attaching a catalyst to the exhaust gas outlet portion.

1 is a circuit block diagram showing the configuration of a fluorine-containing compound processing method using an oxygen enrichment method according to the present invention;

2 is a top view of a combustion chamber of a fluorine-containing compound treatment method according to an embodiment of the present invention;

3 is a cross-sectional view taken along the line A-A of FIG. 2;

4 is a top view of a combustion chamber of a method for treating fluorine-containing compounds according to another embodiment of the present invention;

5 is a view showing step by step treatment of the fluorine-containing compound treatment method using the oxygen enrichment method of the present invention.

* Description of the symbols for the main parts of the drawings *

10 filter 20 oxygen incubator

30: premixing device 40: gas fuel supply source

50: combustion chamber 51: fuel-fluorine compound inlet

52 fuel-air inlet 53: honeycomb-like material

54: catalyst 55: burner

56: combustion chamber appearance 57: combustion chamber inner tube

57 ': inner wall of combustion chamber inner pipe 58: inner pipe entrance

59: internal pipe outlet 60: exhaust treatment device

70: electronic control device

Claims (5)

An oxygen incubator 20 capable of sucking the outside air and increasing the concentration of oxygen to discharge the air; A gas fuel supply source 40 capable of supplying gas fuel; A fuel-air premixing chamber capable of mixing the fuel supplied from the gaseous fuel source 40 and the enriched air containing high concentration of oxygen discharged from the oxygen enrichment device 20, and the gaseous fuel source 40 A premixing device 30 including a fuel-fluorine compound premixing chamber capable of mixing the fuel supplied from the gas with the fluorine-containing compound to be discharged; At least one gaseous fuel-air inlet for injecting fuel-air mixture gas discharged from the fuel-air premixing chamber and inclined with respect to the outer surface of the facade 56 to an upper portion of the outer surface of the facade 56. 52, and at least one fuel-fluorine compound inlet 51 through which the fuel-fluorine compound discharged from the fuel-fluorine compound premixing chamber can be injected into the upper surface of the exterior 56. An inner tube 57 having one exterior 56, one or more burners 55 installed on the inner wall 57 ', a catalyst 54 on the top of the interior, and a honeycomb-like material 53 on the interior. Combustion chamber 50 and a; An exhaust gas treatment device 60 capable of cooling the exhaust gas from the combustion chamber 50 and then dissolving the hazardous component in water to treat the exhaust gas; And an electronic controller 70 capable of controlling the fuel from the air and gas fuel source 40 coming from the oxygen enrichment device 20 and monitoring and controlling the flame temperature in the combustion chamber 50. By fluorine compound treatment system, An oxygen enrichment step of sucking the outside air through the oxygen enrichment apparatus 20 to increase the concentration of oxygen and discharge the oxygen; Supplying gaseous fuel by the gaseous fuel source (40); Premixing fuel-air and fuel-fluorine-containing compounds in separate premixing chambers using the premixing device (30); Injecting the premixed fuel-air mixture gas and fuel-fluorine compound into the combustion chamber through the inlets 52 and 51 respectively; Decomposing the fluorine-containing compound into a hot flame in a combustion chamber; Reducing nitrogen oxides (NOx) generated by decomposition of the fluorine-containing compound through a catalyst (54) to minimize exhaust concentration of nitrogen oxides to discharge the exhaust gas; Cooling the exhaust gas in the exhaust gas and wet treating harmful components in the exhaust gas; Performing control of the air from the oxygen enrichment device 20 and the fuel from the gas fuel supply source 40 by the electronic controller 70 and monitoring and controlling the flame temperature in the combustion chamber 50. Fluorine-containing compound treatment method characterized in that. The method of claim 1, wherein a filter 10 is further installed before sending the fluorine-containing compound gas to the fuel-fluorine compound pre-mixing chamber of the pre-mixing device 30 to remove foreign substances in the exhaust gas containing the fluorine-containing compound. Fluorine-containing compound treatment method further comprising the step of. The method of claim 1, wherein the premixing of the fuel-air and the fuel-fluorine-containing compound in a separate premixing chamber by using the premixing device 30 comprises: a fuel supplied from the gas fuel source 40; Enriched air containing a high concentration of oxygen discharged from the oxygen enrichment device 20 is mixed in the fuel-air premixing chamber, and passes through the fuel supplied from the gas fuel supply 40 and the filter 10. And pre-mixing the fluorine-containing compound to be discharged in the fuel-fluorine compound pre-mixing chamber. The method of claim 1, wherein the step of wet treating the harmful components in the exhaust gas comprises dissolving the hazardous components in the exhaust gas in water to treat the harmful components in the exhaust gas. The method of claim 1, wherein decomposing the fluorine-containing compound into a high temperature flame in a combustion chamber comprises decomposing the fluorine-containing compound with a high temperature flame of at least 1,300 ° C. or more.