KR100729228B1 - Apparatus for determining gas in the device - Google Patents

Abstract

An apparatus for detecting the concentration of gas in an installation while maintaining a gas stream is disclosed. A housing mounted on an inner wall of a sealed facility filled with gas, the housing including a detector for measuring the intensity of the light emitting part and the reflected light and detecting the concentration of the gas; and a support extending from the housing into the interior of the facility. And a reflecting mirror mounted at an end of the support, the reflector reflecting light emitted from the light emitting unit to the detector, and a blocking window blocking the gas from entering the housing. The gas detection apparatus can measure the concentration of a predetermined gas flowing in the installation without changing the air flow of the gas in the installation by mounting the support and the reflector inside the installation.

Description

Apparatus for determining gas in the device

1 is a schematic configuration diagram showing a gas detection apparatus inside a facility according to an embodiment of the present invention.

FIG. 2 is a perspective view for explaining a supporter in the gas detection apparatus shown in FIG. 1.

3 is a cross-sectional view illustrating a light emitting unit and a detection unit in the gas detection apparatus shown in FIG. 1.

4 is a view showing the results of measuring the concentration of isopropyl alcohol in the drying apparatus used in the semiconductor cleaning equipment using the gas detection device of the present invention.

<Explanation of symbols for the main parts of the drawings>

12: support 14: reflector

16 light emitting unit 18 detecting unit

20: housing

The present invention relates to an apparatus for detecting a gas inside an installation, and more particularly, to an apparatus for detecting a concentration of gas flowing inside an enclosed installation.

In general, the concentration detection of the gas can be performed using an infrared spectrometer, which is a device for determining the molecular structure by examining the absorption spectrum of a substance against infrared rays. The infrared spectrometer may measure a degree of absorption occurring at all wavelengths of the light at once by irradiating light on a portion including a predetermined gas and Fourier transforming an interference fringe formed while the light passes through the gas. Therefore, there is an advantage that the qualitative analysis and quantitative analysis of the gas can be performed simultaneously. However, the infrared spectrometer is so large that it is difficult to mount it in a given facility. Therefore, it is not suitable to detect the gas flowing in the installation using the infrared spectrometer.

Therefore, in order to reduce the scale of the infrared spectrometer, the spectrometer limits the type of gas that can be detected and measures the intensity of the gas by filtering only the wavelength of light absorbed by the limited gas molecules, thereby measuring the concentration of the gas. Detect.

To detect the concentration of gas flowing in the plant using the spectrometer, first, a portion of the gas flowing in the plant is sucked and introduced into the spectrometer. Subsequently, infrared rays are irradiated to pass the gas introduced into the spectrometer. Then, the infrared light passes through the gas and reaches a detector after predetermined wavelengths are absorbed by the molecules of the gas. The concentration of the gas in the facility may be detected by irradiating light intensity for each wavelength in the detector.

However, when the spectrometer is used, the air flow of the gas in the facility is varied because the gas in the facility is sucked in and forced to enter the spectrometer. Therefore, in a facility in which fluctuations in the air flow in the facility become important variables of the process, the concentration of gas in the facility cannot be detected using the spectrometer. In addition, it is not possible to accurately detect whether or not gases are distributed at a uniform concentration in the installation.

It is therefore an object of the present invention to provide an apparatus for detecting the concentration of gas in an installation while maintaining the gas stream.

In order to achieve the above object, the present invention, the housing is provided on the inner wall of the sealed installation filled with gas, the housing including a detector for detecting the concentration of the gas by measuring the intensity change of the wavelength of the light emitting portion and the reflected light; And a support extending from the housing to the inside of the facility, a reflector mounted at an end of the support and reflecting light emitted from the light emitting unit to the detector, and a blocking window blocking the gas from entering the housing. It provides the gas detection apparatus in the installation equipped.

The gas detection apparatus can measure the concentration of a predetermined gas flowing in the installation without changing the air flow of the gas in the installation by mounting the support and the reflector inside the installation. In addition, by providing a plurality of the gas detection device in the facility, it is possible to determine the uniformity of the concentration by measuring the concentration of the gas for each position in the facility.

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

1 is a schematic configuration diagram showing a gas detection apparatus inside a facility according to an embodiment of the present invention.

Referring to FIG. 1, a housing 20 is installed on an inner wall of a sealed facility 10 filled with gas. The housing 20 includes a light emitter 16 and a detector 18 for measuring the wavelength of the reflected light to detect the concentration of the gas filled in the facility.

A support 12 extends from the housing 20 into the installation 10.

A reflector 14 is mounted at an end of the support 12 and reflects the light emitted from the light emitter 16 to the detector 18.

The support 12 is configured to allow the gas molecules 11 filled in the installation 10 to flow into the space between the reflector 14 and the housing 20. The support 12 is formed using a chemically stable material without reacting with gas molecules or processes performed in the installation 10. For example, it can form using a fluorocarbon resin.

2 is a perspective view showing a support that can be mounted to the gas detection apparatus of FIG.

As shown in FIG. 2, the support 12 is mounted to a plurality of support parts 12a having a columnar shape and both ends of the support parts 12a, and the support parts are fixed to one body while being spaced apart from each other. It can comprise with the flame | frame 12b. At this time, the fixing frame 12b has a ring shape so that both ends of the support 12 are open. In the support having the above configuration, the gas molecules 11 inside the facility 10 may flow freely between the support portions 12a.

In addition, the reflector 14 is mounted on the fixing frame 12b on the side of the support 12 that faces the inner wall of the facility. One end of the support 12 is blocked by the reflector 14.

FIG. 3 is an enlarged view of only a part of the gas detection device illustrated in FIG. 1.

Hereinafter, the light emitting unit and the detection unit included in the housing will be described with reference to FIGS. 1 and 3.

The light emitting unit 16 receives an electric current from the power supply unit 16a and emits infrared rays, and a condenser lens 16c installed in front of a portion where light is emitted from the infrared lamp 16b. Consists of

The condenser lens 16c prevents scattering of the emitted infrared rays to minimize the loss of light. Therefore, it is possible to reduce the power used to emit the infrared rays, and to minimize the temperature rise of each part of the gas and the facility due to the emission of the infrared rays.

When the infrared rays are irradiated, the infrared rays collide with the gas molecules 11 flowing into the space between the reflector 14 and the housing 20, and a predetermined wavelength I is absorbed to decrease the intensity. On the other hand, the wavelength II which is not absorbed by the gas molecules 11 in the infrared ray does not decrease in intensity.                     

The light irradiated from the light emitter 16 is reflected by the reflector 14 and proceeds toward the detector 18.

The detector 18 receives the reflected light reflected from the reflector 14 and detects the gas concentration in the facility.

Specifically, the detector 18 includes a filter 18a for filtering a predetermined wavelength among the reflected infrared rays, a measuring instrument 18b for measuring the intensity of the light passing through the filter 18a, and an analogue of the light intensity. Or an A / D converter 18c for converting to a digital signal, and a signal processing unit 18d for receiving the converted signal and displaying the signal and measuring the concentration of gas by the signal.

As shown in FIG. 3, a first blocking window 17 may be further provided to prevent the inflow of gas in the installation 10 toward the front of the filter 18a.

A process of detecting the concentration of gas in the facility 10 by the detector 18 will be described. First, the filter 18a filters only the wavelength I absorbed by the gas molecules 11 flowing in the facility 10 among the reflected infrared rays. The meter 18b then measures the intensity of the filtered light. The A / D converter 18c outputs the light intensity as a digital or analog signal, and grasps the degree of reduction of the light intensity in the signal processing unit 18d. The decrease in light intensity is due to the absorption of gas molecules 11 flowing into the support 12. Therefore, by determining the degree of reduction of the intensity of the light, it is possible to measure the concentration of the gas flowing between the reflector 14 and the housing 20.                     

The detector 18 may include a plurality of detectors, and each detector 18 includes a filter 18a for filtering different wavelengths.

For example, two detection units 18 may be provided. At this time, the filter 18a used for one detection unit 18 filters the wavelength I absorbed by the gas in the installation, and the filter 18a used for the other detection unit 18 is used for the gas in the installation. The wavelength (II) which does not absorb is filtered. As described above, by detecting the wavelength II at which the gas in the facility 10 does not absorb, the change in the condition of the detection unit 18 or the temperature change in the facility can be corrected in real time.

The filter 18a in the light emitting unit 16 and the detecting unit 18 may be provided inside the installation 10 or may be attached to the outside of the installation 10 so as to conduct with the interior of the installation 10. . However, the measuring device, the A / D converter 18c and the signal processing unit 18d are preferably provided outside the facility 10.

The angle at which the light is emitted from the light emitter 16 and the light incident at the detector 18 is set toward the reflector 14 to be within 180 °. That is, in consideration of the angle of reflection of the infrared rays emitted from the light emitter 16 and reflected by the reflector 14, the light is emitted from the light emitter 16 and the light is incident from the detector 18. Adjust the angle of the part. Therefore, the amount of light detected by the detector 18 can be increased.

A second blocking window 22 is provided to block the gas flowing into the facility from flowing into the housing 20. The second blocking window 22 should block only the inflow of gas flowing in the facility while emitting or entering light from the light emitting part 16 and the detecting part 18 included in the housing 20. . In order to satisfy this, the second blocking window 22 may be formed of a sapphire window.

If the apparatus for detecting the gas in the installation is formed as described above, it is possible to accurately detect the gas concentration in the installation without generating a change in the air flow of the gas in the installation. In addition, it is possible to accurately check the uniformity of the gas concentration in the facility by mounting the device for detecting the gas for each position in the facility.

4 is a view showing the results of measuring the concentration of isopropyl alcohol in the drying apparatus used in the semiconductor cleaning equipment using the gas detection device of the present invention.

In the drying apparatus illustrated in FIG. 4, after the wafer is cleaned in the inner tub 100, the wafer is raised to the outer tub 102 in which the isopropyl alcohol layer is formed, and the marangoni effect caused by the isopropyl alcohol is increased. Remove any moisture from the wafer. At this time, in order to uniformly dry the wafer, the isopropyl alcohol layer should have a uniform concentration of the isopropyl alcohol at each position of the outer tub 102.

In order to confirm the concentration of isopropyl alcohol at each position of the drying apparatus, three gas detecting apparatuses were installed, one for each position of the drying apparatus. And the concentration of isopropyl alcohol was measured in each detection apparatus. A, B, and C indicate the concentration of isopropyl alcohol at each position of the outer tank, and the concentration was about 29 to 31%. As a result, it was found that the isopropyl concentration in the region indicated by C was relatively small.                     

By introducing the gas detection device into the drying device, it is possible to grasp a portion where the concentration of isopropyl alcohol is relatively small. Therefore, it is possible to prevent defects caused by the non-uniform concentration of isopropyl alcohol for each position in the drying apparatus. In addition, the concentration of isopropyl alcohol in the drying apparatus can be accurately confirmed without changing the air flow of the isopropyl alcohol layer.

As mentioned above, according to this invention, the density | concentration of the gas which flows in a sealed installation can be detected correctly, without changing the airflow of gas. Therefore, there is an effect that the concentration of gas can be accurately detected even in a facility where the air flow change of the gas in the facility is an important factor. In addition, the uniformity of the gas in the facility can be detected by detecting the concentration of the gas at each position in the facility.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified without departing from the spirit and scope of the invention described in the claims below. And can be changed.

Claims (8)

A housing installed on an inner wall of a sealed facility filled with a gas, the housing including a detector for detecting a concentration of the gas by measuring a change in intensity of a wavelength of the light emitting part and the reflected light; A support including a plurality of pillars having a columnar shape, and a fixing frame mounted at both ends of the supports to fix the supports to one body while being spaced apart from each other, the support being formed to extend from the housing to the inside of the facility; A reflector mounted at an end of the support and reflecting light emitted from the light emitter to a detector; And And a blocking window for blocking the gas from flowing into the housing. delete The gas detection apparatus according to claim 1, wherein the light emitting portion and the detecting portion are installed such that the light emitting portion and the light receiving portion make an angle within 180 ° toward the reflecting mirror. The method of claim 1, wherein the light emitting unit, Infrared lamps that emit infrared light; And a condensing lens for preventing scattering of the emitted infrared rays. The method of claim 1, wherein the detection unit, A filter for filtering a predetermined wavelength among the reflected light; A measuring device for measuring the intensity of light passing through the filter; An A / D converter for converting the intensity of the light into an analog or digital signal; And And a signal processing unit for receiving the converted signal, displaying the signal, and measuring a concentration of a sample gas based on the signal. 6. The gas detection apparatus according to claim 5, wherein a plurality of detection units are provided, and each detection unit includes a filter for filtering different wavelengths. 6. The gas detection apparatus inside a facility according to claim 5, wherein the A / D converter and the signal processing unit are provided outside the facility. 2. The gas detection apparatus inside a facility according to claim 1, wherein the facility includes a drying device used for a semiconductor cleaning facility.

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