KR20180138561A - Exhausting Gas Analysis Device With A Thermal Desorption Portion And A NDIR Portion And Analysis Method Thereof - Google Patents

Abstract

The present invention relates to an exhaust gas analysis device to measure concentration of pollutant of exhaust gas and, more specifically, relates to an exhaust gas analysis device with a thermal desorption portion and an NDIR portion and an analysis method thereof. To achieve this, the exhaust gas analysis device comprises: an outdoor air suction port (25) into which exhaust gas flows; a flow means to enable exhaust gas to flow; a thermal desorption portion (330) connected to the flow means, and collecting exhaust gas; and an NDIR portion (400) connected to the thermal desorption portion (330) to analyze concentration of a component. Moreover, a plurality of NDIRs (100) analyzing one component of exhaust gas in the NDIR portion (400) are connected to the thermal desorption portion (330) in parallel, and each NDIR (100) is formed to analyze each of different components (BTEX).

Description

TECHNICAL FIELD [0001] The present invention relates to an exhaust gas analyzing apparatus having a thermal desorption unit and an NDIR unit,

The present invention relates to an exhaust gas analyzer for measuring the concentration of pollutants in exhaust gas, and more particularly to an exhaust gas analyzer having a thermal detach portion and an NDIR portion and an analysis method thereof.

While the rapid development of modern industrial society has improved the quality of life of human beings, it caused various environmental problems due to indiscreet natural degradation and development. Particularly, due to the rapid increase of energy consumption due to industrial development, the emission of air pollutant gas has increased rapidly, and the pollution problem caused by this is facing serious situation. In order to prevent this, it is essential to understand the concentration of gases and the kinds of gases emitted from various pollutants such as factories and automobile exhaust pipes.

Currently, gas chromatography (hereinafter, abbreviated as "GC") is used for analyzing volatile harmful substances and odor components. In addition, in collecting the volatile harmful substances and odor component samples to be analyzed and injecting the collected samples to the GC by a predetermined amount, in addition to the liquefaction concentrated sample injection method, the gaseous sample is collected in the solid adsorption tube without liquefaction, A so-called thermal desorption method in which heat is applied to the adsorption tube and directly injected into the GC is used.

1 is a schematic diagram of a conventional vacuum thermal desorption system (Korean Patent Registration No. 10-0846190). As shown in FIG. 1, the conventional vacuum thermal desorption system includes a desiccant / dry gas storage tank 10 storing a sample desorption / drying gas, a volatile toxic and odorous substance in the air through a vacuum pump 23 The moisture is removed from the desiccant-drying gas storage tank 10 while the moisture is removed from the desiccant-drying gas storage tank 21 while the moisture is removed by the flow controller 24, A sample storage and supply unit 30 for temporarily storing the sample and supplying it to the sample loop unit while vacuuming the sample to be vacuumed while heating the sample to be removed and a low temperature adsorption tube A first control valve 20 for allowing the sample in the air and the desiccant / dryer body to be alternately transferred to the adsorbent 14, a cooling pipe 15 for keeping the temperature of the adsorbent 14 of the low temperature adsorption pipe 13 at a low temperature, To the storage and supply unit 30 A carrier gas storage tank 60 for storing and supplying a carrier gas for pushing and discharging the sample accommodated in the loop to two or more sample analyzers, A second flow control valve 31 for supplying or shutting off the sample to the sample storage and supply unit 30 and a second flow control valve 31 for supplying or shutting off the sample passing through the second flow control valve 31 to the sample loop unit, A second control valve 40 for feeding or shutting off the sample loop portion and a third and fourth flow control valves 61 and 62 for regulating the flow rate of the carrier gas supplied to the respective loops 50 and 51 .

In the conventional vacuum thermal desorption system, when the sample is detached from the adsorbent of the sample, the sample can be vacuumed using the sample storage and supply unit 30 at a low temperature without increasing the initial temperature, thereby enabling thermal desorption at a low temperature. When the vacuum thermal desorption at such a low temperature is performed, analysis of a thermally unstable compound becomes possible. In addition, since a certain amount of sample is always supplied to each independent sample analyzer through two or more loops (50, 51), it is possible to prevent the tailing phenomenon of the sample in the GC (65) However, there is an advantage that the reproducibility can be greatly improved while various materials can be analyzed. In addition, the GC (65) can transfer the sample to multiple columns from a single GC (65) without using expensive equipment such as the GC (65), and the analysis can be performed by an independent detector. There was an advantage.

However, the conventional vacuum thermal desorption system as shown in FIG. 1 has the following disadvantages. First, because of the use of the expensive GC (65), the economic burden of increasing the price of the entire analysis system was large. In addition, due to the large number of accessories such as the desiccant dry gas storage tank 10, the carrier gas storage tank 60, the hydrogen tank, the air tank, and the like, the space occupation is large and the operating cost of the entire system is greatly increased.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an exhaust gas analyzing apparatus having a thermal desorption unit and an NDIR unit capable of maintaining a compact structure of the exhaust gas analysis system, And to provide an analysis method thereof.

A second object of the present invention is to provide an exhaust gas purifying apparatus which is capable of analyzing all the components of the exhaust gas by replacing only GC with a typical harmful substance component (benzene (B), toluene (T), ethylbenzene (E) , And xylene (X), hereinafter referred to as " BTEX "), and an NDIR unit, and an analysis method thereof.

According to an aspect of the present invention, there is provided an air conditioner comprising: an outside air inlet port through which exhaust gas flows; Flow means for flowing the exhaust gas; A thermal detachment portion connected to the flow means and collecting the exhaust gas; And an NDIR unit 400 connected to the thermal detachment unit 330 and analyzing the component concentration of the NDIR unit 400. The NDIR unit 400 for analyzing one component of the exhaust gas is connected to the thermal detachment unit 330 And a plurality of NDIR units are connected in parallel to each other, and each of the NDIR units 100 is configured to analyze different components. An exhaust gas analyzer having the thermal detachable unit and the NDIR unit is provided.

Further, the flow means includes a pump 320 connected to the outside air inlet 25; And a flow control valve 310 connected to the pump 320.

Further, a sample dryer 300 for removing moisture of the exhaust gas may be further provided between the outside air inlet 25 and the heat-dissipating unit 330.

The heat-dissipating unit 330 includes a low-temperature adsorption unit 340 for adsorbing at -40 ° C. to -20 ° C. and collecting and desorbing in a vacuum to transfer the exhaust gas to the NDIR unit 400.

The NDIR unit 400 further includes an NDIR 100a for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas; An NDIR (100b) for toluene (T) analyzing the concentration of toluene (T) in the exhaust gas; An NDIR (100c) for ethylbenzene (E) for analyzing the concentration of ethylbenzene (E) in the exhaust gas; And NDIR (100d) for xylene (X) for analyzing the concentration of xylene (X) in the exhaust gas.

According to another aspect of the present invention, there is provided a method of analyzing the above-described analytical apparatus, comprising: a step (S100) in which an exhaust gas is introduced through an outside air inlet (25) ; A step (S200) in which the thermal detachment section (330) collects the exhaust gas and thermal desorption in vacuum; And a step (S300) of analyzing one specified component of the exhaust gas by each NDIR (100) of the NDIR unit (400) by an analysis method of an exhaust gas analyzer having a thermal detachable unit and an NDIR unit Can be achieved.

The inflow step S100 includes: a step S110 in which the pump 320 sucks the exhaust gas through the outside air intake port 25; And the flow rate control valve 310 controlling the flow rate of the exhaust gas (S130) may be performed sequentially or in reverse order.

The method may further include a step S120 of removing moisture of the exhaust gas between the outside air intake port 25 and the thermal desorption unit 330 during the inflow step S100.

Further, the collecting step (S200) of the thermal detachable part 330 is adsorbed at -40 ° C to -20 ° C and collected.

The NDIR unit 400 further includes an NDIR 100a for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas; An NDIR (100b) for toluene (T) analyzing the concentration of toluene (T) in the exhaust gas; An NDIR (100c) for ethylbenzene (E) for analyzing the concentration of ethylbenzene (E) in the exhaust gas; And NDIR (100d) for xylene (X) for analyzing the concentration of xylene (X) in the exhaust gas.

As another embodiment of the present invention, there is provided an air conditioner comprising: an outside air inlet (25) through which exhaust gas flows; Flow means for flowing the exhaust gas; A thermal detachment portion connected to the flow means and collecting the exhaust gas; And a NDIR unit 400 connected to the thermal desiccation unit 330 to analyze the concentration of the components. In the NDIR unit 400, one composite gas NDIR 600 for analyzing the component concentration of the exhaust gas is heat- (330), and the composite gas NDIR (600) includes a multiplex filter (500) in which optical filters (510) corresponding to the respective components are combined; And a detector 540 provided on one side of the multiplex filter 500 and corresponding to each of the optical filters 510. The exhaust gas analyzing apparatus has a thermal detachable portion and an NDIR portion.

In addition, the multi-filter 500 may be composed of four individual optical filters 510, which are equally spaced and combined, and each detector 540 may be integrally formed on the rear surface of each individual optical filter 510.

The multi-filter 500 also includes an optical filter for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas; An optical filter for toluene (T) for analyzing the concentration of toluene (T) in the exhaust gas; An optical filter for ethylbenzene (E) to analyze the concentration of ethylbenzene (E) in the exhaust gas; And an optical filter for xylene (X) for analyzing the concentration of xylene (X) in the exhaust gas.

According to one embodiment of the present invention, the structure of the exhaust gas analysis system can be simplified and kept compact. Therefore, it is possible to install and operate in a narrow place with less restrictions on the system installation.

It is also possible to quickly analyze only typical harmful substances (benzene (B), toluene (T), ethylbenzene (E), xylene (X), hereinafter referred to as "BTEX") among the exhaust gases. Therefore, there is a convenience that it is possible to easily analyze only the concentrations of representative harmful substances by easily installing them in all factories, facilities, and chimneys where exhaust gas is discharged.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description of the invention given below, serve to further understand the technical idea of the invention. And should not be construed as interpreted.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a conventional vacuum thermal desorption system;
2 is a block diagram of an exhaust gas analyzer having a thermal detachable portion and an NDIR portion according to the first embodiment of the present invention;
3 is an exploded perspective view schematically showing a first embodiment of the NDIR 100 among the NDIR unit 400 of FIG. 2,
4 is a block diagram of an emission gas analyzer having a thermal desorption unit and an NDIR unit according to a second embodiment of the present invention;
5 is an exploded perspective view schematically showing an embodiment of the composite gas NDIR 600 in the NDIR unit 400 of FIG. 4,
6 is a flowchart of an analysis method using an emission gas analyzer having a thermal detach portion and an NDIR portion.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings. While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and are herein described in detail.

It is noted that the terms "comprises" or "having" in this application are intended to specify the presence of stated features, integers, steps, operations, elements, parts, or combinations thereof, , Steps, operations, components, parts, or combinations thereof, as a matter of principle.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Configuration of the first embodiment

FIG. 2 is a block diagram of an exhaust gas analyzer having a thermal detachable unit and an NDIR unit according to an embodiment of the present invention. FIG. 3 is a schematic exploded perspective view of the NDIR unit 100 of the NDIR unit 400 in FIG. 2, the analyzing apparatus of the present invention includes a series of sample driers 300, a flow control valve 310, a pump 320, a thermal desorption unit 330, and a configuration in which a NDIR unit 400 is connected to be.

The sample dryer 300 is connected to the outside air intake port 25 to one side to allow the exhaust gas to flow in and the flow control valve 310 is connected to the other side. The outside air inlet 25 is an inlet through which the exhaust gas for analysis is introduced. The sample dryer 300 is a device for removing moisture contained in the introduced exhaust gas for more accurate component analysis. The sample drier 300 includes a Peltier element therein to maintain the temperature of about -30 ° C. so that moisture or moisture in the exhaust gas is crystallized and removed. The sample dryer 300 is a well-known structure and a detailed description thereof will be omitted.

The flow rate control valve 310 is provided between the sample dryer 300 and the pump 320 and controls an inflow amount or a flow amount of the exhaust gas according to a control command of a microcomputer (not shown) or the like. One or a plurality of such flow control valves 310 may be installed at any position in the flow path of the exhaust gas.

The pump 320 is a representative example of a suction pump or a vacuum pump and serves as a power source for introducing exhaust gas. One or a plurality of such pumps 320 may be installed at any position in the flow path of the exhaust gas.

The heat-dissipating unit 330 is connected to the pump 320 at one side and the NDIR unit 400 at the other side. The thermal desorption unit 330 is a member for concentrating and adsorbing a dried sample (exhaust gas) transferred from the sample dryer 300 at a low temperature (for example, -30 ° C), and then desorbing the heated sample. To this end, the thermal desorption unit 330 is provided with a low temperature adsorption unit 340 containing an adsorbent, and a cooling pipe 350 for realizing a low temperature around the low temperature adsorption unit 340, (Not shown). Examples of adsorbents include carbotrap, silicagel, tenax, or carbopack. A temperature sensor (not shown) and an adjusting unit (not shown) for controlling the cooling and heating of the low temperature adsorption unit 340 may be included.

The mixing chamber 370 is connected to the low temperature adsorption portion 340, and a vacuum pump 372 and a first valve 374 are formed therebetween. The mixing chamber 370 is also called a syringe pump, and temporarily stores the desorbed sample (exhaust gas) to a predetermined concentration. The piston (or syringe) in the mixing chamber 370 drives the sample to the NDIR unit 400.

The NDIR unit 400 is a configuration for continuously measuring gas components and concentrations using a non-dispersive infrared absorption (NDIR) analysis method. FIG. 3 is a schematic exploded perspective view of the NDIR 100 of the NDIR unit 400 in FIG. 3, in the NDIR 100, a wide wavelength IR radiation emitted from an infrared (IR) light source unit 120 is passed through an optical filter (Bandpass filter) 240 and only a specific IR wavelength is passed . At this time, the detector 250 detects a change in the IR wavelength, converts the IR wavelength into an electrical signal, and amplifies the electrical signal. In addition, it is possible to compensate for concentration interference effects between gases by mounting a GFC (Gas Fourier Correlation, hereinafter referred to as "GFC") as needed.

That is, the NDIR 100 is a method of obtaining the gas concentration by measuring the light absorption rate with respect to the concentration by using the characteristic that gas molecules absorb light (infrared light) of a specific wavelength. That is, since specific gas molecules have a characteristic of absorbing only light of a specific wavelength band, it is necessary to measure light by irradiating gas molecules with light of various wavelengths and filtering only the light of the wavelength band absorbed by the gas molecules. The NDIR 100 may be attached to the optical detector 240 with an optical filter 240 transmitting only the wavelength.

In one embodiment of the present invention, an NDIR (100a) for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas; NDIR (100b) for toluene (T) analyzing the concentration of toluene (T); NDIR (100c) for ethylbenzene (E) for analyzing the concentration of ethylbenzene (E); And NDIR (100d) for xylene (X) for analyzing the concentration of xylene (X) are arranged in parallel.

Configuration of the second embodiment

FIG. 4 is a block diagram of an emission gas analyzer having a thermal detachable unit and an NDIR unit according to a second embodiment of the present invention, and FIG. 5 is a block diagram of an embodiment of the composite gas NDIR 600 of the NDIR unit 400 of FIG. Fig. The configuration of FIG. 4 is similar to that of the first embodiment and the configuration of FIG. 2, so a detailed description thereof will be omitted to avoid redundancy.

As shown in FIG. 5, the multiplex filter 500 is composed of a combination of four pieces of individual optical filters 510. These four optical filters 510 include an optical filter for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas; An optical filter for toluene (T) to analyze the concentration of toluene (T); An optical filter for ethylbenzene (E) to analyze the concentration of ethylbenzene (E); And an optical filter for xylene (X) that analyzes the concentration of xylene (X).

The individual transmitted light beams 530 having passed through the multiple filter 500 have different wavelengths? 1,? 2,? 3 and? 4, respectively. Each detector 540 is integrally assembled to the rear surface of the individual optical filter 510, and the detected electrical signal is outputted through the detector signal line 550.

The operation of the first embodiment

Hereinafter, the operation of the present invention having the above-described configuration will be described with reference to the accompanying drawings. 6 is a flowchart of an analysis method using an emission gas analyzer having a thermal detach portion and an NDIR portion. As shown in Fig. 6, first, a process of flowing the exhaust gas by the flow means is performed. That is, the pump 320, which is one example of the flow means, operates, and the exhaust gas to be measured flows through the outside air intake port 25 (S100).

The inflow step S100 includes: a step S110 in which the pump 320 sucks the exhaust gas through the outside air intake port 25; A step (S120) of the sample dryer (300) to remove moisture of the exhaust gas between the outside air inlet (25) and the thermal desorption unit (330); And the flow rate control valve 310 controlling the flow rate of the exhaust gas (S130) may be performed sequentially or in reverse order. The suction step (S110), the removing step (S120), and the controlling step (S130) may be performed in any order besides the sequential or reverse order.

Then, the thermal detachable portion 330 collects the exhaust gas (S200). Specifically, the cooling pipe 350 is cooled to a temperature of -40 ° C to -20 ° C (for example, -30 ° C) by a material such as liquid nitrogen or an electronic cooler (Peltier). At a temperature lower than -40 ° C, much power is consumed to maintain the cryogenic temperature, and there is a limit in that the concentration and adsorption can not be efficiently performed at temperatures exceeding -20 ° C. In this state, the sample dried by the sample dryer 300 is conveyed by the pump 320 and passes through the low temperature adsorption section 340, and is concentrated and adsorbed to the above-mentioned adsorbent (not shown). When a sufficient amount of the sample is adsorbed to the low temperature adsorption unit 340, power is applied to the heating wire 360 surrounding the low temperature adsorption unit 340 while maintaining the operation of the cooling pipe 350, The sample is adsorbed to the adsorbent (not shown) by heating to a temperature of 200 ° C to 300 ° C with a small amount of desorbed gas flowing in a period of 1-2 minutes.

Thereafter or simultaneously, the first valve 374 is opened and the second valve 376 is closed, the vacuum pump 372 operates to condense the sample (exhaust gas) that has been deteriorated into the mixing chamber 370 . After the predetermined concentration or a predetermined time has elapsed, the first valve 374 is closed, the second valve 376 is opened, and the piston (not numbered) is pushed to push the sample to the NDIR unit 400. Due to this operation, the mixing chamber 370 is also referred to as a syringe pump.

Next, each NDIR 100 of the NDIR unit 400 analyzes one specified component of the exhaust gas (S300). That is, the NDIR 100a for benzene (B) in the NDIR unit 400 analyzes the concentration of benzene (B) in the exhaust gas and the NDIR 100b for toluene (T) analyzes the concentration of toluene , NDIR (100c) for ethylbenzene (E) analyzes the concentration of ethylbenzene (E) in the exhaust gas and NDIR (100d) for xylene is analyzed for the concentration of xylene .

The NDIR 100 for analyzing only the concentration of the specific gas can be added in parallel in accordance with the desired gas. By controlling the opening and closing of the valve 170 provided at the inlet 140 of the NDIR 100, it is possible to control the ON / OFF of concentration analysis of the gas, and the analyzed gas is discharged through the outlet 150.

The operation of the second embodiment shown in FIGS. 4 and 5 is similar to that of the first embodiment, so a detailed description thereof will be omitted.

Although the present invention has been described in connection with the preferred embodiments set forth above, it will be readily appreciated by those skilled in the art that various other modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that all modifications are within the scope of the appended claims.

10: desorption / drying gas storage tank,
11: first flow control valve,
12: Vacuum gauge,
13: low temperature adsorption tube,
14: adsorbent,
15: Cooling tube,
17: Thermal line,
20: first control valve,
21: Sample dryer,
23: Vacuum pump,
24: Flow regulator,
25: outside air inlet,
30: sample storage and supply unit,
31: second flow control valve,
40: second control valve,
50, 51: loop,
60: Carrier gas storage tank,
61: third flow control valve,
62: fourth flow control valve,
65: gas chromatography (GC)
70: heat sink tube,
71: Thermal line,
74: fifth flow control valve,
80: third control valve,
100: NDIR,
100a: NDIR for benzene (B)
100b: NDIR for toluene (T)
100c: NDIR for ethylbenzene (E)
100d: NDIR for xylene (X)
120: light source part,
130: Infrared,
140: entrance,
150: exit,
160: gas cell,
170: valve,
200: glass,
240: Optical filter,
250:
300: sample dryer,
310: Flow control valve,
320: pump,
330: thermal detachment portion,
340: low temperature adsorption portion,
350: cooling pipe,
360: Thermal line,
370: mixing chamber,
372: Vacuum pump,
374: a first valve,
376: second valve,
400: NDIR unit,
500: multiple filters,
510: Individual optical filter,
530: individual transmitted light,
540: detector,
550: detector signal line,
600: Combined gas NDIR.

Claims (2)

An outside air inlet 25 through which exhaust gas flows;
Flow means for flowing said exhaust gas;
A thermal detachment unit connected to the flow unit and collecting the exhaust gas; And
And an NDIR unit 400 connected to the thermal detachable unit 330 to analyze the component concentration,
In the NDIR unit 400, a plurality of NDIR units 100 for analyzing one component of the exhaust gas are connected in parallel to the thermal detacher unit 330, and each NDIR unit 100 analyzes different components Lt; / RTI >
Wherein said flow means comprises:
A pump 320 connected to the outside air inlet 25; And
And a flow control valve 310 connected to the pump 320,
A sample dryer 300 for removing moisture of the exhaust gas is further provided between the outside air inlet 25 and the thermal detacher 330,
The heat-dissipating unit 330 includes:
A low-temperature adsorption unit 340 for adsorbing at -40 ° C to -20 ° C, collecting and transferring the exhaust gas to the NDIR unit 400 by vacuum desorption;
A mixing chamber (370) connected to the low temperature adsorption unit (340) for temporarily storing the exhaust gas to a predetermined concentration;
A vacuum pump 372 and a first valve 374 formed between the low temperature adsorption unit 340 and the mixing chamber 370; And
And a second valve (376) configured between the mixing chamber (370) and the NDIR unit (400)
The NDIR unit 400,
An NDIR (100a) for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas;
An NDIR (100b) for toluene (T) for analyzing the concentration of toluene (T) in the exhaust gas;
An NDIR (100c) for ethylbenzene (E) for analyzing the concentration of ethylbenzene (E) in the exhaust gas;
An NDIR (100d) for xylene (X) for analyzing the concentration of xylene (X) in the exhaust gas; And
(100a) for the benzene (B), the NDIR (100b) for the toluene (T), the NDIR (100c) for the ethylbenzene (E), and the NDIR And a valve (170) that is opened and closed to control the flow rate of the exhaust gas. The analysis method of the analyzing apparatus according to claim 1,
In the course of flow of the exhaust gas by the flow means,
A step (S100) in which the exhaust gas flows through the outside air inlet (25);
A step (S200) of the thermal desorption unit (330) collecting the exhaust gas and thermal desorption in vacuum; And
(S300) each NDIR (100) of the NDIR unit (400) analyzes one specified component of the exhaust gas,
The inflow step (SlOO)
(S110) the pump 320 sucks the exhaust gas through the outside air intake port 25; And
(S130) in which the flow rate control valve 310 controls the flow rate of the exhaust gas, is performed sequentially or in reverse order,
(S120) of removing moisture of the exhaust gas between the outside air inlet (25) and the thermal detacher (330) during the inflow step (S100)
In the collecting step S200 of the thermal detachable unit 330,
The low-temperature adsorption unit 340 adsorbs and collects the exhaust gas at -40 ° C to -20 ° C, heat-desorbs it by heating at 200 ° C to 300 ° C,
The vacuum pump 372 is operated by opening the first valve 374 and closing the second valve 376 to concentrate the exhaust gas in the mixing chamber 370,
The first valve 374 is closed and the second valve 376 is opened to transfer the exhaust gas to the NDIR unit 400,
The NDIR unit 400,
An NDIR (100a) for benzene (B) for analyzing the concentration of benzene (B) in the exhaust gas;
An NDIR (100b) for toluene (T) for analyzing the concentration of toluene (T) in the exhaust gas;
An NDIR (100c) for ethylbenzene (E) for analyzing the concentration of ethylbenzene (E) in the exhaust gas;
An NDIR (100d) for xylene (X) for analyzing the concentration of xylene (X) in the exhaust gas; And
(100a) for the benzene (B), the NDIR (100b) for the toluene (T), the NDIR (100c) for the ethylbenzene (E), and the NDIR And the valve 170 is opened and closed to control ON / OFF of concentration analysis of the gas by controlling the opening and closing of the valve 170. The exhaust gas analyzing apparatus having the thermal desorption unit and the NDIR unit .

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