KR100989430B1 - Appratus for preventing pollution of probe for gas measuring of in-situ type - Google Patents

Abstract

The present invention relates to an apparatus for preventing contamination of an in-situ gas measurement probe. To this end, the present invention includes a transceiver 10 provided to transmit and receive light, and a portion thereof connected to the transceiver 10 to penetrate vertically. A gas check of the sensing unit 20 positioned inside the chimney as a sensing unit 20 having a double pipe structure of the inner pipe 21 and the outer pipe 22 forming the gas check region 23. In the pollution prevention device of the in-situ gas measurement probe provided to detect the exhaust gas passing through the area 23, the air curtain area provided on both ends of the gas check area 23 of the sensing unit ( A shielding valve 40 is provided in the light passage 210 provided to allow light on the 30 side to pass, and the shielding valve 40 is configured to provide air between the inner pipe 21 and the outer pipe 22. Feed passage (2 The light path 210 is rotated by rotating the shielding valve 40 by the rotation of the blade 41 by the air supplied to the air supply passage 220 and axially connected to the blade 41 provided at 20. Bar is to be opened and closed, so that the inflow of contaminated exhaust gas into the light passage 210 due to the absence of a sudden air curtain function is blocked so that the damage caused by the exhaust gas of the expensive optical equipment components can be prevented in advance. It is characterized by.

Industrial chimneys, emissions, gas pollution measurement, light passage closure

Description

Apparatus for preventing pollution of probe for gas measuring of in-situ type}

The present invention relates to a pollution prevention device of an in-situ gas measurement probe, and more particularly, to discharge into an optical measurement path when an accident occurs in which an operation of an air pump that generates air for air curtain is stopped while measuring the pollution level of the exhaust gas. An apparatus for preventing contamination of an in-situ gas measurement probe which enables the gas inlet to be automatically shut off, thereby preventing damage to optical component parts due to contact with contaminated gas.

In general, the measurement of gas in an industrial chimney is performed by a sampling method of gas and an in-situ method of measuring in the field.

In the in situ method of performing the gas concentration measurement in real time in the field, optical is mainly used, and the optical gas measuring method is a part of the part where light passes between the transmitter (transmitter) and the reflector. An open path method is used to open the gas for passage.

The open-pass gas measuring apparatus is mounted in the shape which inserted the probe penetrating from one side in the industrial chimney normally.

1 is a side cross-sectional view illustrating a state in which a gas measuring apparatus of a general open pass method is installed, and FIG. 2 is an enlarged cross-sectional view of a main part of the gas measuring apparatus of FIG.

As shown in the figure, the open-pass gas measuring device is composed of a transmitting and receiving unit 10 and a sensing unit 20 from one side of the chimney 50.

The transceiver 10 is configured to include a plurality of optical device components therein.

That is, the transmitting and receiving unit 10 is provided with a variety of sensing means for generating a light by the light source (ultraviolet) and at the same time the signal is reflected, the detection unit 20 is located on one side of these transceiver 10 One end is a tubular configuration.

The sensing unit 20 is horizontally inserted into the inside through a hole formed in one main surface of the chimney 50, and the transceiver 10 is located at the outside of the chimney 50, one end of the transceiver 10 The flange surface formed in the close contact with the outer peripheral surface of the chimney 50 to be fastened and fixed by a bolt or the like.

The sensing unit 20 is usually provided with an inner pipe 21 for providing a light passage 210 through which light passes, and an air supply passage through which the high pressure air curtain air is supplied while surrounding the inner pipe 21. It is provided as the double pipe | tube structure which consists of the outer pipe 22 which provides 220. As shown in FIG.

The sensing unit 20 is provided in a shape that is suspended in the air horizontally in the interior of the chimney 50, such that the sensing unit 20 passes through a predetermined length vertically so that the discharge gas passes through, the sensing unit ( The optical signal passes through the gas check region 23 through which the exhaust gas passes through 20) to detect the pollution degree of the exhaust gas.

On the other hand, in order to prevent the inflow of gas into the inner pipe 21 through which the optical signal is transmitted from the gas check region 23 through which the exhaust gas passes, an air curtain region 30 is formed at both ends of the gas check region 23. The air curtain is formed by the high pressure air supplied through the air supply passage 220 between the inner pipe 21 and the outer pipe 22.

However, the high-pressure air generating pump supplied for the air curtain may cause a case in which the driving is stopped due to a sudden power failure, failure, or poor maintenance, etc. At this time, the air curtain is not formed, thus contaminating the gas check area 23. Part of the exhaust gas is introduced through the light passage 210 to cause a problem of damaging expensive optical component parts and the reflector for reflecting light on the transceiver 10 side.

The present invention is to solve the above problems, the present invention is to provide a shielding valve rotatably in the inner pipe by the supply pressure of the air supplied to the air supply passage between the inner pipe and the outer pipe air for air curtain It is an object of the present invention to provide a pollution prevention device for an in-situ gas measurement probe which prevents damage to optical component parts due to exhaust gas by shielding the inner pipe when the supply of the gas is stopped or the supply pressure is excessively weakened.

In order to achieve the above object, the present invention is provided with a double pipe structure of an inner pipe and an outer pipe which transmit and receive a light, and an inner pipe and an outer pipe which form a gas check area by allowing a part of the light to pass vertically while one end is connected to the transceiver. In the contamination prevention device of the in-situ gas measurement probe is provided to detect the exhaust gas passing through the gas check region of the sensing unit is formed as a sensing unit which is located inside the chimney, at both ends of the gas check region of the sensing unit A shielding valve is provided inside the light passage provided to allow light from the air curtain region side to be provided, and the shielding valve is axially connected to a blade provided in an air supply passage between the inner pipe and the outer pipe. Rotation of the blade by air supplied to the supply passage Thereby rotating the shielding valve to open and close the light path.

According to the above configuration, the pollution prevention device of the in-situ gas measurement probe of the present invention is a shielding valve provided in the light path when the air curtain air is not supplied or is supplied at a predetermined pressure or less while measuring the pollution level of the exhaust gas. By rotating the light path to be in a closed state, the inflow of contaminated exhaust gas into the light path due to the sudden absence of the air curtain function is blocked, thereby preventing damage of the expensive optical device components by the emission gas. To help.

In addition, the present invention is characterized in that when the air curtain function is not achieved, immediately stop the contamination measurement, and provide an economic advantage to minimize the damage to the parts while performing an immediate repair.

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

The pollution prevention device of the in-situ gas measurement probe according to the present invention includes a transceiver 10 provided to transmit and receive light as shown in FIG. 1, and a detector configured to check the emission gas while the optical signal of the transceiver 10 passes. It is a structure which consists of the combination of (20).

The transceiver 10 has various expensive optical device components therein to function to generate and transmit light from a light source (not shown) therein, and to receive an optical signal reflected and returned.

The sensing unit 20 is a tubular configuration in which one end is coupled to the transceiver 10 as shown in FIG.

The sensing unit 20 includes an inner pipe 21 providing an optical passage 210 through which an optical signal passes, and an outer pipe providing an air supply passage 220 at regular intervals outside the inner pipe 21. It is a double pipe configuration consisting of a combination of 22).

However, the sensing unit 20 forms a gas check area 23 through which a portion of the outer circumferential surface penetrates vertically in the longitudinal direction so that the exhaust gas passes upward from the bottom.

Preferably, the gas check area 23 is formed to have a width larger than the outer diameter of the inner pipe 21 and smaller than the inner diameter of the outer pipe 22, and the length of the gas check area 23 is about the information of the exhaust gas passing through the gas check area 23. It is more preferable to be formed to such an extent that a stable and accurate gas quantity can be passed.

On the other hand, in the gas check region 23 of the sensing unit 20, the reflector 24 is provided to reflect the light irradiated through the transceiving unit 10 in a direction corresponding to the side of the transceiving unit 10.

In addition, the gas check area 23 of the sensing unit 20 includes air curtain areas 30 at both ends.

The air curtain region 30 is a space between the air guides 300 spaced apart from each other by both end portions of the gas check region 23.

That is, the portion through which the actual discharge gas passes in the gas check region 23 is a portion that vertically penetrates between the air guides 300 on both sides.

The air curtain area 30 has a configuration in which the lower end is blocked and the upper end is open at both sides of the discharge gas passage portion, respectively, and the light passage 210 allows light to pass through both sides of the air curtain area 30. The light passing hole 310 is formed so as to be formed on the same center line horizontally.

However, the air guide hole 31 is formed at the lower end of the light passage 210 on the surface facing the air guide 300 in the air curtain region 30 so that the high pressure air is guided to the air curtain region 30. .

Therefore, when the high pressure air is led from the lower part of the air curtain area 30 and discharged upward through the air induction hole 31 at a pressure more powerful than the discharge gas, the inflow of the discharge gas from the gas check area 23 is inherent. To block.

On the other hand, in the present invention, the configuration of supplying high-pressure air to the air supply passage 220 is a conventional air compressor, and the air compressor is interrupted by electric power, so if the power failure occurs, the air compressor stops driving. Becomes

When the operation of the air compressor is stopped, the air curtain function in the air curtain area 30 is eventually stopped, and when the air curtain action is stopped, a part of the exhaust gas that has moved upward through the gas check area 23 is lost in the air curtain area 30. A portion thereof is introduced into the light path 210 to affect the transceiver 10 and the reflector 24, 25.

That is, the loss of the air curtain function in the air curtain area 23 is contaminated by the expensive optical component parts provided on the side of the transceiver 10 on the light passage 210 and the reflectors 24 and 25 provided on the opposite side. As the components come in contact, they shorten component life or degrade functionality.

Figure 3 is an enlarged cross-sectional view illustrating a main configuration according to the present invention, Figure 4 is a half sectional perspective view illustrating a connection structure of the shielding valve and the blade according to the present invention.

Accordingly, the present invention has the most prominent feature in that the shielding valves 40 are provided in the light passages 210 on the air curtain area 23 side, respectively.

The shielding valve 40 is a thin plate having a vertical cross-sectional shape of the light passage 210 provided to open and close the light passage 210. Since the light passage 210 is formed in a circular cross section, the shield valve 40 ) Is most preferably formed in the same disk shape.

The shielding valve 40 is axially supported in the radial direction and provided to be rotatable in the inner pipe 21, but the shielding valve 40 is rotatable only at an angle of 90 ° in one direction.

The shielding valve 40 is connected to the same axis as the blade 41 on the air supply passage 220 side.

The blade 41 is rotatably connected to the shielding valve 40 and the air supply passage 220 on one side or the air supply passage 220 provided on both sides corresponding to each other by the shaft 42.

At this time, the blade 41 provided in the air supply passage 220 is formed in a configuration that is eccentrically axially supported with respect to the shaft 42 so that the high-pressure air is in a state parallel to the direction of movement of the air. When the pressure is less than or less than the abnormal supply state of the air supply is made by rotating the plate 90 ° in a direction perpendicular to the radial direction, that is, the air movement direction of the air supply passage 220.

The shielding valve 40 and the blade 41 is such that the rotation angle is limited to 90 °, the shaft 42 connecting the shielding valve 40 and the blade 41 is always a constant pressure by the spring 43 To be elastically supported.

On the other hand, the movement direction of the light through the light passage 210 and the movement direction of the air through the air supply passage 220 have a common point of the longitudinal direction of the inner pipe 21 and the outer pipe 22.

However, when the air is not normally supplied through the air supply passage 220, the light passage 210 should be blocked, so the shielding valve 40 and the blade 41 should be operated in the same direction.

That is, when air is normally supplied through the air supply passage 220, the blade 41 is in a direction parallel to the air supply direction by the pressure of the air, and the shielding valve 40 provided to interlock with the blade 41 also has a plate surface. The light passage 210 is opened while being provided side by side in this light movement direction so that safe gas measurement is performed.

On the other hand, the blade 41 is rotated at an angle of 90 ° by the high pressure air pressure and the restoring force of the spring 43.

At this time, the blade 41 is to be limited to the rotation angle by 90 ° range by the stopper 44 as shown in Figure 5, the stopper 44 is a projection 440 formed on the shaft 42 is the inner pipe 21 It may be formed in a shape that moves along the groove 441 of the 90 ° angle formed on the main surface of the), in addition to it can be formed in various configurations.

In addition, the circular outer diameter of the shielding valve 40 rotating in the light passage 210 is formed to be smaller than the inner diameter of the light passage 210, as shown in Figure 6, the O ring 400 as the outer peripheral surface of the shielding valve 40 It is more preferable that the seal is provided with the inner diameter surface of the light path 210 to be provided.

In particular, the shielding valve 40 may be applied as a transparent material through which light can pass, and when the transparent shielding valve 40 is applied, the light path 210 is blocked even though the air curtain function is not normally performed. As a result, the contamination of the contaminated gas from the gas check region 23 may be blocked while the gas contamination measurement may be normally performed.

The present invention according to the above configuration is intended to block the inflow of polluting gas into the light passage 210 when the supply of air for the air curtain is interrupted or the supply pressure is below a certain.

When the gas measuring device of the present invention is installed in the industrial chimney and the power is applied, the pollution degree of the polluted exhaust gas discharged through the industrial chimney by various device components together with the light source on the transceiver 10 side is checked.

The air compressor is driven by the power applied at the same time as the pollution degree check to generate a constant high pressure air to check the gas through the air supply passage 220 between the inner pipe 21 and the outer pipe 22 of the present invention. It is supplied to the air curtain area | region 30 formed in the both ends of 23.

Therefore, when the air compressor is normally driven, the blade 41 provided in the air supply passage 220 by the high pressure air moving through the air supply passage 220 has a plate surface in the direction of air movement as shown in FIG. 7. It will rotate side by side.

At this time, the shielding valve 40 connected to the coaxial line by the blade 41 and the shaft 42 also rotates by 90 ° and is in a state parallel to the direction of light movement in the light passage 210 inside the inner pipe 21.

In this state, the pollution degree of the exhaust gas from the industrial chimney is measured by the optical signal reflected and reflected through the light passage 210, and the air curtain region is formed by the high pressure air supplied through the air supply passage 220. In 30, the exhaust gas induced from the gas check region 23 is blocked.

On the other hand, if a sudden power failure or failure of an air compressor for generating air at high pressure occurs while measuring the pollution degree of the exhaust gas using the gas measuring device of the present invention, no air is supplied through the air supply passage 220 or the air is supplied at a very low pressure. Is supplied.

When the air supply becomes poor in this way, the blade 41 rotates in a direction perpendicular to the air moving direction as shown in FIG. 4 by the restoring force of the spring 42, and at the same time, a shielding valve connected to the blade 41 ( 40 also rotates by 90 ° and the light path 210 is blocked by the shielding valve 40.

If the light path 210 is blocked, the transmission of the optical signal is blocked and at the same time, the function of the air curtain area 30 is lost. Therefore, a large amount of contaminated gas is removed from the gas check area 23. Although it may be introduced from one end, the polluted gas introduced into the light passage 210 of the inner pipe 21 can no longer be entered by the shielding valve 40 of the present invention, so expensive optics on the transmission / reception unit 10 side. It is possible to safely protect the reflector 24 at the end of the device component or the corresponding sensing unit 20 side.

Therefore, the present invention, when the high-pressure air for the air curtain is not normally supplied to the state that does not properly perform the air curtain function in the air curtain area 30, the measuring device of the present invention is automatically turned off, the light path The block 210 is blocked by the valve 40 to prevent damage to the expensive equipment by the polluted exhaust gas and thereby to minimize the economic loss.

Meanwhile, in the present invention, when the shielding valve 40 is used as a transparent material, the light passage 210 is blocked when the air curtain function is stopped or defective, thereby blocking the inflow of polluted exhaust gas, but stably measuring gas contamination. It can be done.

1 is a side cross-sectional view showing a state in which a gas measuring apparatus of a general open pass method is installed;

FIG. 2 is an enlarged cross-sectional view illustrating main parts of the gas measuring device of FIG.

3 is an enlarged cross-sectional view illustrating a main part configuration according to the present invention;

Figure 4 is a half sectional perspective view illustrating a connection structure of the shielding valve and the blade according to the invention,

5 is a bottom view illustrating the configuration of the stopper according to the present invention;

6 is a vertical sectional view illustrating a sealing structure with an inner pipe of a shielding valve according to the present invention;

7 is an operational state diagram of the present invention.

Explanation of symbols on the main parts of the drawings

10: transceiver 20: detector

21: inner pipe 22: outer pipe

23 gas check region 24 reflector

30: air curtain area 40: shielding valve

41: blade 42: shaft

43: spring 44: stopper

210: light passage 220: air supply passage

Claims (10)

Transmitting and receiving unit provided to transmit and receive, and the inner end of the chimney consisting of a double pipe structure of the inner pipe and the outer pipe to form a gas check area by connecting a part through the vertically connected one end to the transceiver In the contamination prevention device of the in-situ gas measurement probe is provided to detect the exhaust gas passing through the gas check region of the sensing unit, A shielding valve is provided inside the light passage provided to allow light from the air curtain region side provided at both ends of the gas check region of the sensing unit to pass therethrough. The shielding valve is axially connected to a blade provided in an air supply passage between the inner pipe and the outer pipe to rotate the shielding valve by rotation of the blade by air supplied to the air supply passage to open and close the light passage. Contamination prevention device for in-situ gas measurement probes. The contamination prevention device of the in-situ gas measurement probe according to claim 1, wherein the shielding valve has a disc shape having a diameter and a shape equal to a cross section of the light passage. The contamination prevention device of claim 1, wherein the shielding valve is provided with an O-ring on an outer circumferential surface thereof so as to be in close contact with the inner diameter surface of the light passage in a state of blocking the light passage. The contamination prevention device of an in-situ gas measurement probe according to claim 1, wherein the shielding valve is provided as a transparent material through which light can pass. The contamination prevention apparatus of claim 1, wherein the blade is configured to be rotatably connected by a shaft in the air supply passage on one side of the shielding valve. The contamination prevention apparatus of claim 1, wherein the blade is rotatably connected by a shaft in the air supply passage provided on both sides of the shielding valve and the corresponding valve. The contamination prevention device of claim 1, wherein the blade is returned by a spring to a right angle with respect to the direction of movement of the air when the supply of air is stopped or when air of a predetermined pressure or less is supplied. The contamination prevention device of claim 1, wherein the shielding valve and the blade rotate at a 90 ° angle. The contamination prevention device of claim 8, wherein the shaft connecting the shielding valve and the blade to the same axis is limited by a stopper. 10. The in situ of claim 9, wherein the stopper comprises a pair of protrusions formed to protrude to the outer circumferential surface at an angle of 90 ° of the shaft, and an inner pipe outer circumferential side groove for accommodating the protrusions and providing a moving space of the protrusions. Contamination prevention device for gas measurement probes.

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