KR20190109211A - Hybrid scrubber for separating and processing of deposition process gas and cleaning gas and system for operating the hybrid scrubber - Google Patents

Abstract

The present invention provides a hybrid scrubber which can save energy. According to the present invention, the hybrid scrubber comprises: a cold trap connected to a gas supply pipe connected to a semiconductor process chamber; and a plurality of scrubber chambers connected to the cold trap. The plurality of scrubber chambers include: a first dry scrubber chamber directly connected to a rear end of the cold trap; a second dry scrubber chamber connected to a cleaning gas inlet pipe while being isolated from the first dry scrubber chamber; and a third dry scrubber chamber directly connected to the second dry scrubber chamber. The cold trap removes a solid byproduct to protect chemicals accommodated on the dry scrubber chambers. The first dry scrubber chamber adsorbs and removes a hydrocarbon compound which is a reaction byproduct of TEOS by zeolite. The second dry scrubber chamber removes F2 gas by Ca(OH)2. The third dry scrubber chamber decomposes, adsorbs, removes NF3 which is not removed by the second dry scrubber chamber.

Description

Hybrid scrubber for separating and processing of deposition process gas and cleaning gas and system for operating the hybrid scrubber

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hybrid scrubber that can be applied to all areas of semiconductor processing including chemical vapor deposition, diffusion, and etching processes on semiconductor, LCD, LED, OLED, and solar collector plates.

Surface treatment of metals or polymers, various dielectric etching such as silicon wafers, glass, and plasma chemical vapor deposition techniques are well known using highly reactive chemical species generated by plasma.

Industrially active in accordance with the necessity of process miniaturization and low temperature is mainly atmospheric low-temperature plasma, which is useful for etching and deposition in the semiconductor process, surface treatment of metals and polymers, and synthesis of new materials.

The plasma may be generated in vacuum or at atmospheric pressure, and may be classified into a high temperature plasma having an average temperature of several tens of degrees and a high degree of ionization, and a low temperature plasma having an average temperature slightly higher than room temperature and having a low degree of ionization.

Here, in the manufacture of various semiconductor devices or in the manufacture of liquid crystals, the gases emitted after use are toxic or flammable and have a great effect on the human body and greatly affect global warming. There is.

On the other hand, the gas used in the manufacturing process of the semiconductor device in recent years as follows.

First, in the etching process, CF4, SF6, CHF3, C2F6, SiF4, F2, HF, which are mainly used to etch silicon oxide, silicon nitride, and polycrystalline silicon. Fluorine gases such as NF3, chlorine gases such as Cl2, HCl, BCl3, SiCL4, CCl4 and CHCl3 used to etch aluminum and silicon, and trench-etch etch) or bromine gases such as HBr and Br2 used for etching aluminum together with Cl2. Silane, N2 and NH3 are often introduced into the chamber during the next chemical vapor deposition (CVD) process. It is used.

In particular, in a PECVD process, PFC or ClF3 is used to clean the chamber, which can produce SiF4. These gases are toxic, corrosive, and oxidative, and when released as they are, there is a risk of causing a lot of problems for the human body, the global environment, and the production facilities themselves.

In the related art, since all gases generated from semiconductor processing equipment flow into the scrubber, the amount of processing gas increases, resulting in deterioration of energy efficiency.

In a facility for depositing a polysilicon film on a wafer during a semiconductor manufacturing process, toxic gases generated during the deposition process are safely treated without pre-reaction, and cleaning using toxic gases to remove contaminants remaining on the inner wall of the chamber after the process is performed. Dry scrubber device is used as a device for treating toxic gas generated during the process.

Conventionally, secondary reaction byproducts such as NOx, CF4, and SiF4 are generated during the process of mixing the deposition gas and the cleaning gas in the semiconductor process. In addition, since the gas is dissolved and discharged, a strong acid or strong hydrochloric acid wastewater is generated to require a secondary water treatment device, and corrosion and clogging of the drain line occurs.

Due to the above, the reactor inside the scrubber needs periodic replacement over two to twelve months due to the corrosion of components, and in the case of the energy required, about 10 to 12 kw is generated.

On the other hand, when looking at the temperature inside the reactor, the burn-wet type is 800C to 1500C, and the plasma type is about 10,000C to cause thermal nox.

Such gases are injected into a semiconductor manufacturing apparatus and used after etching, CVD, and the like, and are discharged. The exhaust gas contains a very small amount of unreacted gas. Conventionally, the exhaust gas containing such unreacted gas has been discharged to the atmosphere as it is, but due to the above-mentioned problem, the gas scrubber is used to treat the gas discharged from the semiconductor manufacturing process, etc. There is a trend to minimize the impact.

TEOS of the process gas used in the manufacturing process of the semiconductor device is generally consumed about 60% in the process chamber, and 90% of the remaining 40% is introduced into the scrubber with a separate trap removed. On the other hand, NF3, which is a cleaning gas, can be treated with Ca (OH) 2, which is a cheap drug.

As described above, the actual amount of process gas to be treated in the scrubber is a problem, when all the gas is carried out in a single scrubber in a significantly small state.

Referring to Korean Patent Laid-Open Publication No. 10-2010-0126167 (Plasma Gas Scrubber Apparatus), it provides a technique for treating unreacted gas using plasma, but directly with a chamber of a semiconductor processing apparatus operated in an actual vacuum state. In the connected plasma scrubber, there is a problem in that the process pressure is affected by a change in pipe pressure when the scrubber is operated, and there is also a problem in that unreacted gas such as PFC that is not processed is discharged due to an unavoidable ignition time delay during plasma ignition.

(Patent Document 1) KR 10-2010-0126167 A

It is an object of the present invention to provide a method of operating a hybrid scrubber that enables energy saving while simultaneously preventing the generation of secondary reaction byproducts by interlocking semiconductor process steps.

Hybrid scrubber according to the present invention for achieving the above object is a cold trap connected to the gas supply pipe connected to the semiconductor process chamber; And a plurality of scrubber chambers connected to the cold traps.

The plurality of scrubber chambers may include a first dry scrubber chamber directly connected to a rear end of the cold trap, a second dry scrubber chamber connected to a cleaning gas inlet pipe in an isolated state from the first dry scrubber chamber, and the first dry scrubber chamber. A third dry scrubber chamber connected directly to the two dry scrubber chambers,

The cold trap removes the solid by-product for the protection of the medicament contained on the dry scrubber chamber, the first dry scrubber chamber adsorbs and removes the hydrocarbon compound which is a reaction byproduct of TEOS with zeolite, and the second dry The scrubber chamber removes F2 gas with Ca (OH) 2, and the third dry scrubber chamber decomposes and removes the non-removed NF3 from the second dry scrubber chamber.

As described above, the present invention enables energy saving while at the same time preventing generation of secondary reaction by-products caused by mixing of the process gas and the cleaning gas by interlocking the deposition process and the cleaning process performed in the semiconductor process chamber. In particular, the average power consumption of the scrubber is reduced by about 40%.

The present invention separates the deposition process gas and the cleaning gas to prevent the risk of explosion caused by the mixing of TEOS, a silicon-containing material, and F2 gas, a fluorine gas, generated on the process chamber and to prevent the formation of secondary reaction byproducts.

In addition, in process steps where gas treatment is not required, the gas is bypassed to the exhaust line to reduce energy consumption.

By treating a large amount of reaction by-products during the deposition process with cold traps, the solid by-product is removed to improve the life of the chemical stored in the dry scrubber.

In addition, decomposition and adsorption for NF3 treatment on the third dry scrubber chamber by first treating a large amount of F2 gas generated during the cleaning process with low cost calcium hydroxide (Ca (OH) 2) stored on the second dry scrubber chamber. Improve the life of the drug.

In the present invention, there is no wastewater generation, so that strong acid or strong hydrochloric acid wastewater is generated in a conventional way of dissolving and discharging gas, thereby preventing the necessity of a secondary water treatment device and corrosion of the drain line.

1 shows an overall semiconductor processing system including a hybrid scrubber according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention, and to those skilled in the art the scope of the invention. It is provided for complete information. Like numbers refer to like elements on the drawings.

Hereinafter, a method of operating a hybrid scrubber with reduced average power consumption according to an embodiment of the present invention will be described with reference to the drawings.

Referring to Figure 1 describes the overall semiconductor processing system including a hybrid scrubber according to the present invention.

The semiconductor processing system includes a hybrid scrubber having a plurality of scrubber chambers, a gas supply pipe connected to the hybrid scrubber, and a plurality of control valves disposed on the gas supply pipe.

The hybrid scrubber includes a cold trap and a plurality of scrubber chambers connected on the gas supply pipe.

The gas supply pipe is provided with a process gas inlet pipe for guiding a large amount of reaction by-products generated during the deposition process on the process chamber and a cleaning gas inlet for guiding the introduction of a cleaning gas for cleaning impurities generated during the deposition process on the process chamber. Include plumbing.

The process gas pipe and the cleaning gas pipe are provided with the process gas and the cleaning gas in a state connected to a single inlet pipe on the process chamber. When the toxic process gas generated during the deposition process flows into the inlet pipe, the cleaning gas valve mounted on the cleaning gas pipe is automatically shut off, and the process gas valve mounted on the process gas pipe is automatically opened to open the SiH4 gas series and PH3 gas. Toxic process gas of any one of, and NH3 gas is introduced.

After the deposition process is completed, a cleaning process for removing contaminants generated on the inner wall of the chamber during the deposition process is performed, for example, the cleaning process is performed with ClF3 gas. When the toxic cleaning gas generated during the cleaning process is introduced, the process gas valve is automatically shut off, and the cleaning gas valve is automatically opened so that the toxic cleaning gas is introduced through the cleaning gas pipe.

The cold trap serves to remove the solid by-product for the protection of the medicament contained on the hybrid scrubber. In principle, cold traps operate at room temperature. Cold traps are cooled by PCW.

The plurality of scrubber chambers includes a first dry scrubber chamber directly connected to the rear end of the cold trap, a second dry scrubber chamber and a second dry scrubber chamber connected on the cleaning gas inlet pipe in an isolated state from the first dry scrubber chamber. And a third dry scrubber chamber that is directly connected.

The first dry scrubber chamber adsorbs and removes a hydrocarbon compound which is a reaction byproduct of TEOS with zeolite or the like. The first dry scrubber chamber undergoes an adsorption process at room temperature.

The second dry scrubber chamber removes F2 gas with calcium hydroxide (Ca (OH) 2). In the case of the second dry scrubber chamber, the adsorption process is performed at room temperature.

The third dry scrubber chamber decomposes and removes NF3 not removed from the second dry scrubber chamber in a state of using metal hydroxide (MHO) or the like. The third dry scrubber chamber undergoes a reaction and adsorption process at 200C.

The process gas introduced through the process gas pipe in the process chamber passes through the cold trap and the first dry scrubber chamber to remove impurities and adsorb at room temperature.

The cleaning gas introduced through the cleaning gas pipe in the process chamber passes through the second dry scrubber chamber and the third dry scrubber chamber to react and adsorb at room temperature and high temperature.

As described above, the deposition process gas and the cleaning gas are separated and processed through a plurality of dry scrubber chambers formed in the hybrid scrubber, thereby preventing explosion risk and secondary reaction by mixing TEOS gas in the deposition process and F2 gas in the cleaning process. To prevent the formation of by-products;

On the other hand, in a process step in which gas treatment is unnecessary, the gas is bypassed to the exhaust line to reduce energy consumption.

The reaction on the process chamber is as follows.

Si (OC2H5) 4 + 8O3 → SiO2 + 10H2O + 8CO2 + Unreacted gas (TEOS, O2) .. (1)

NF3 Plasma + SiO2 → SiF4 + O2 + N2 + Unreacted gas (NF3, F2) ....... (2)

Reaction formula (1) shows that SiO 2, H 2 O, and CO 2 are generated through the reaction of TEOS and O 3, and unreacted TEOS is generated.

Scheme (2) shows that SiF4, O2, and N2 are generated through reaction of NF3 Plasma and SiO2, and unreacted NF3 and F2 are generated.

As described above, the present invention enables energy saving while at the same time preventing generation of secondary reaction by-products caused by mixing of the process gas and the cleaning gas by interlocking the deposition process and the cleaning process performed in the semiconductor process chamber. In particular, the average power consumption of the scrubber is reduced by about 40%.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims (1)

A cold trap connected on a gas supply pipe connected to the semiconductor process chamber; And
And a plurality of scrubber chambers connected to the cold traps.
The plurality of scrubber chamber,
A first dry scrubber chamber directly connected to a rear end of the cold trap, a second dry scrubber chamber connected on a cleaning gas inlet pipe in an isolated state from the first dry scrubber chamber, and a direct connection to the second dry scrubber chamber A third dry scrubber chamber, wherein
The cold trap removes the solid by-product for the protection of the medicament contained on the dry scrubber chamber,
The first dry scrubber chamber adsorbs and removes a hydrocarbon compound which is a reaction byproduct of TEOS with zeolite,
The second dry scrubber chamber removes F2 gas with Ca (OH) 2,
Wherein the third dry scrubber chamber to decompose and remove the non-removed NF3 in the second dry scrubber chamber,
Hybrid Scrubber.

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