KR101359940B1 - Stack exhaust gas online monitoring system - Google Patents

Abstract

The present invention relates to an online monitoring system for exhaust gas from a chimney, and more specifically, to an online monitoring system for exhaust gas from a chimney, wherein the system allows the measurement of low concentration of ions by sampling exhaust gas from a chimney through a wet sampling method, separating ionic substances in a sample collected by an ion chromatography method into individual components, and measuring the concentration of the ionic substances. [Reference numerals] (AA) Absorbing solution

Description

Stack exhaust gas online monitoring system

The present invention relates to a chimney flue gas on-line monitoring system, and more specifically, a sample of the flue flue gas is sampled by a wet sampling method, and an ionic component is obtained by separating ionic substances in a sample collected by an ion chromatography method into individual components. By measuring the concentration of the present invention relates to a chimney flue gas online monitoring system that can be measured reliably to low concentrations.

Emissions from general industrial sites, such as chemical plants, incineration plants, and various manufacturing facilities, not only have a serious impact on the human body, but also have a serious adverse effect on national image along with environmental pollution such as acid rain, smog, and plant death.

For this reason, not only domestic but also globally, it regulates the kinds of harmful substances in the flue gas and regulates and manages the concentration of the discharge tongue by substance.

For the management and regulation of flue-gases, a measuring system for measuring the concentration of pollutants is essential.

In Korea, the concentration of pollutants emitted from the chimneys of each business site is measured using the Chimney Flue Gas Automatic Monitoring System (TMS) and transmitted to the control center for real-time integrated management. .

Based on these data, management departments are using it to establish environmental policies, such as regulating the total amount of emissions and imposing emission charges.

In the flue gas measurement system there are systems for measuring HF, HCl, SOx and the like in the exhaust gas. As one example, HCl has been described.

The analysis of hydrogen chloride (Hcl) in the exhaust gas is generally the use of non-dispersive infrared (NDIR) and ion electrode methods.

As a related technology, Korean Registered Patent No. 1030931 (Registration Date: 2011.04.18, Name: Hydrogen Chloride Meter and Measurement Method of Exhaust Gas Using the Flue Gas Continuous Automatic Measurement System) has an exhaust gas measurement system using ion electrode method. It has been disclosed.

The legal requirements for the current flue-gas monitoring system are set at a relatively high concentration of less than 1 ppm, with the lowest limit of 2 ppm for melting and melting facilities in glass and glassware manufacturing facilities. Since the lowest emission limit is 5ppm or less, it can be judged that it can be sufficiently applied by measuring devices such as NDIR or ion electrode method with a measurement limit of about 1ppm.

However, in the case of the chimney emission gas, discharge charges and excess charges are imposed not only on the emission limit but also on the total amount restriction. Emission charges are calculated according to the emissions of pollutants, which are calculated by multiplying the emissions concentration by the emission data, which is the measurement data from the automatic flue gas measurement system.

In particular, most of the installations to which the flue gas automatic measuring system is attached are very large, with the amount of exhaust gas per outlet being more than 10,000 standard cubic meters (m ³ ) per hour. It can make a big difference.

Therefore, the automatic flue-gas measurement system must not only meet the emission limit, but also need reliable measurements at low concentrations at the ppb level.

In addition, the installations to which the chimney flue gas measuring system is attached are subject to legislation that may limit the installation of more than 10 tonnes of a single substance or more than 25 tonnes of two or more substances per year. This makes measuring performance at the ppb level more important.

For example, assuming that a chimney flue gas measurement system with a measurement limit of 0.1 ppm is used, the emissions are calculated arithmetically at 10,000 m ³ / hr because the emission is recognized as 0.1 ppm even in a chimney where 0.1 ppm or less is continuously detected. Annual emissions from chimneys are 8.76 tonnes. In addition, for equipment with a lower measuring limit of 0.1 ppm, the data can fluctuate up to 0.3 ppm because the measurement quantitative reliability is generally more than three times higher, and if measured at 0.2 ppm, the emissions will be 17.52 tons, resulting in excessive collection of discharge charges. In addition, installation of discharge facilities may be limited, which may cause direct damage to industry.

In recent years, due to such emission regulations, the performance of the decontamination technology of the exhaust gas is continuously improved, so that the emission level is generally maintained at a low concentration. However, due to the limitation of measurement, the conventional flue gas automatic measurement system is economical, such as excessive investment and overlapping investment for reducing the emission gas, because the concentration of the exhaust gas is expressed with higher concentration or incorrect data. Waste is occurring.

Korean Registered Patent No. 1030931 (Registration Date: 2011.04.18, Name: Hydrogen Chloride Meter in the Continuous Automatic Measurement System of Exhaust Gas of Chimney and Measurement Method of Exhaust Gas Using the Same)

The present invention has been made to solve the above problems, an object of the present invention is to sample the sample of the flue gas by the wet sampling method, and to separate the ionic substances in the sample collected by the ion chromatography method into individual components Then, by measuring the concentration of the ionic component, to provide a flue gas online monitoring system that can be measured reliably to low concentrations.

The chimney flue gas online monitoring system according to an embodiment of the present invention includes a discharge gas inlet 110 through which the discharge gas is introduced, a sample collecting part 200 in which the absorbent liquid and the discharge gas are collected through a physical or chemical reaction, and the It characterized in that it comprises an ion analyzer 400 for separating the ionic substances in the sample collected by the sample collection unit 200 by the ion chromatography method to measure the concentration of the ionic component.

In addition, the chimney exhaust gas online monitoring system 1 includes a first sample selection valve 510 connected to the exhaust gas inlet 110; A second sample selection valve 520 connected to a span calibration gas inlet 120; A third sample selection valve 530 connected to a zero calibration gas inlet 130; The gas selected from the discharge gas, the span calibration gas and the zero calibration gas is introduced to one side through the opening and closing control of the first to third sample selection valves 530, and the absorbent liquid introduced through the operation of the absorbent liquid injection pump 140 and A sample collecting part 200 contacting gas and collecting the gas and separating the gas-liquid; A controller 600 for controlling an online monitoring operation of the chimney exhaust gas and a calibration operation in advance; It may be formed to include.

In addition, the sample collecting unit 200 is a gas-liquid mixing unit 210 is mixed with the absorbed liquid and gas introduced through the operation of the absorbent liquid injection pump 140; And the sample introduced from the gas-liquid mixing unit 210 through the sample inlet 310 is gas-liquid separated, and the separated liquid sample is discharged to the sample outlet 320, and the sample outlet 320 and the ion analyzer ( And a gas-liquid separator 220 to which 400 is connected.

In addition, the ion analyzer 400 includes an eluent storage unit 410 for storing an eluent; An eluent supply pump 420 connected to the eluent storage 410 to pump and move the eluent; The eluent introduced through the operation of the eluent supply pump 420 and the liquid sample separated from the sample collection unit 200 are injected into the sample loop 431, and the eluent and the liquid sample are analyzed into the analysis column 440. Sample injection unit 430 to transfer; A suppressor 450 in which electrolysis of the eluent is performed; A detector 460 for detecting ionic substances in the liquid sample separated from the analysis column 440; It may be formed to include.

In addition, the chimney exhaust gas online monitoring system 1 is formed by connecting the transport pump 170 on the gas pipe formed by branching the gas pipe between the exhaust gas inlet 110 and the first sample selection valve 510. Can be.

In addition, the ion analyzer 400 may be formed to include a thermostat for maintaining a constant temperature.

In addition, the sample collection unit 200 collects the water-soluble contaminants in the flue gas by using the absorbent liquid, and may be any one selected from a spiral coil sampler, a diffusion scrubber, a denuder, and an impinger.

In addition, the chimney exhaust gas online monitoring system 1 is connected to the sample outlet 320 for discharging the sample after gas-liquid separation in the sample collector 200, the liquid sample discharged from the sample collector 200 And a standard solution may be mixed and mixed with the standard solution supply part 700 to be injected into the ion analyzer 400.

In addition, the chimney flue gas online monitoring system (1) performs a calibration using a standard gas or a standard solution, but to create a multi-point calibration curve over several concentration ranges as a standard solution for low concentration measurement of ppb level, Measure the concentration in the measurable range, and prepare a calibration curve using the standard gas by using a correlation formula comparing the concentration measurement result of the standard gas and the concentration measurement result of the standard solution previously built in the program of the controller 600. Can be.

In addition, the chimney flue gas online monitoring system 1 may analyze the ion component detected by comparing the detection time with the standard solution when the ion analyzer 400 detects the ion.

In addition, the chimney exhaust gas online monitoring system (1) is a gas pipe between the span correction gas inlet 120 and the second sample selection valve 520 branched to the gas in order to relieve pressure when the standard gas injection, the gas to the outside It may be formed to include a bypass unit 150 discharged.

In addition, the absorbent liquid may be an ultrapure water or an aqueous solution in which at least one substance is mixed.

In addition, the absorbent liquid may be mixed with Br ⁻ as a standard material.

In addition, the chimney exhaust gas online monitoring system 1 may measure at least one of HF, Hcl, HNO2, SO2.

In addition, the chimney exhaust gas online monitoring system (1) includes a flow control system 330 is connected to the gas outlet for discharging the gas separated from the gas-liquid separator 300; A trap 340 provided between the gas discharge port and the flow control system 330 to collect a water reducing unit or water to reduce the amount of water; And a vacuum pump 350 connected to the flow controller 330; It may be formed to include.

In addition, the control unit 600 is such that the flow rate of the absorbent liquid and gas flowing into the sample collection unit 200 is automatically changed according to the mode in which the chimney exhaust gas online monitoring system 1 operates normally and the mode to be cleaned. Can be controlled.

The chimney flue gas online monitoring system of the present invention samples a sample of the flue flue gas by a wet sampling method, and separates the ionic substances in the sample collected by the ion chromatography method into individual components and then measures the concentration of the ion component. It has the advantage of being able to measure reliably up to low concentrations.

In other words, in the calibration operation of the flue gas on-line monitoring system, the present invention creates a multi-point calibration curve over several concentration ranges with standard solutions for low concentrations of ppb levels, and then measures the ranges that can be measured with standard gases. By measuring the concentration and comparing the concentration measurement result of the standard gas and the concentration measurement result of the standard solution previously built in the program of the controller, a calibration curve is prepared by using the standard gas. In addition to being able to achieve measurement reliability at, it also meets the statutory criteria for monitoring flue-gas emissions.

In addition, the present invention by separating the various substances in the ionic state using an analytical column, by measuring the properties of the ionic components using the ion conductivity, it is possible to simultaneously quantitative and qualitative analysis of the contaminants in the flue gas emissions economical effect Can be greatly improved.

In addition, the chimney flue gas online monitoring system of the present invention can measure the pollutants of the exhaust gas to a low concentration, thereby preventing the economic waste due to excessive collection of discharge charges and over-investment and redundant investment of the emission reduction facility There is an advantage that can improve the competitiveness of the industries used.

1 is a block diagram showing an embodiment of the chimney exhaust gas online monitoring system according to the present invention.
Figure 2 is a block diagram showing another embodiment of the chimney exhaust gas online monitoring system according to the present invention.
Figure 3 is a schematic view showing another embodiment of the chimney exhaust gas online monitoring system according to the present invention.
Figure 4 is a schematic view showing another embodiment of the chimney exhaust gas online monitoring system according to the present invention.
5 is a chromatogram analysis of HCl gas using the chimney exhaust gas online monitoring system according to the present invention.
Figure 6 is a graph comparing the theoretical concentration and the concentration actually measured by the chimney exhaust gas online monitoring system of the present invention.

Hereinafter, the chimney exhaust gas online monitoring system according to the present invention as described above will be described in detail with reference to the accompanying drawings.

The chimney flue gas on-line monitoring system 1 of the present invention improves the problem that the conventional chimney automatic measurement system was able to measure only the high concentration of ppm level, and has the measurement performance, and can measure the low concentration of ppb level reliably. It is formed to.

That is short, the chimney exhaust water-soluble material, such as HF, Hcl, HNO2, SO2 of various contaminants present in the gas when collecting the liquid sampling method using the absorbing solution in the absorption liquid is F ^- ions, such as ^-, Cl ^-, SO2 The contaminant is present, and the present invention separates various materials in an ionic state using an analytical column used in an ion chromatography method, and then measures characteristics of ionic components using ion conductivity.

In other words, in the case of the ion electrode method used in the conventional chimney flue gas measurement system (TMS), the present invention is different from the selective measurement of a specific component by using an ion selective membrane in the various ion components in the collected collection liquid Various ion components are separated using the analysis column 440, and the characteristics of each ion component are simultaneously measured using ion conductivity.

Accordingly, the chimney flue gas online monitoring system 1 of the present invention can quantitatively and qualitatively analyze contaminants in the flue gas at the same time, thereby greatly improving the economic effect.

Hereinafter, the chimney exhaust gas on-line monitoring system 1 of the present invention having the features as described above will be described in more detail.

First, the chimney exhaust gas online monitoring system 1 of the present invention includes a discharge gas inlet 110 through which exhaust gas is introduced, a sample collecting part 200 in which absorbent liquid and exhaust gas are collected through a physical or chemical reaction, and It is formed including an ion analyzer 400 for separating the ionic substances in the sample collected by the sample collector 200 by an ion chromatography method to measure the concentration of the ionic component.

Referring to the embodiment shown in Figure 1, the chimney exhaust gas online monitoring system 1 of the present invention is large, the exhaust gas inlet 110, the first sample selection valve 510, the second sample selection valve 520, the third sample selection valve 530, the sample collection unit 200, the ion analyzer 400, and the control unit 600 are formed.

The exhaust gas inlet 110 is connected to the chimney so that the exhaust gas is introduced, and is also connected to the first sample selection valve 510.

The second sample selection valve 520 is connected to the span calibration gas inlet 120, and the third sample selection valve 530 is connected to the zero calibration gas inlet 130 and calibrated (calibration). Work), and may be closed when measuring the concentration of pollutants introduced from the exhaust gas inlet 110 to perform actual monitoring.

As the zero calibration gas, N2 or clean air, which has been decontaminated, may be supplied and used, and as shown in FIG. 4, the air filter unit 160 is provided on the zero calibration gas inlet 130 to remove the contamination. Inlet and filtered air can be used.

In the chimney exhaust gas online monitoring system 1 of the present invention, a gas pipe is branched between the span calibration gas inlet 120 and the second sample selection valve 520 to relieve pressure during injection of a standard gas used as a span calibration gas. And further include a bypass unit 150 through which gas is discharged to the outside.

At this time, the bypass unit 150 may be formed by branching the gas pipe between the zero calibration gas inlet 130 and the third sample selection valve.

The sample collection unit 200 is a gas selected from the discharge gas, span calibration gas and zero calibration gas flows into one side through the opening and closing control of the first to third sample selection valve 530, the absorbing liquid injection pump 140 The absorbed liquid and gas introduced through the operation of the contact is collected, and then it is a gas-liquid separation.

At this time, in the sampling method, the absorbent liquid and the gas may be directly contacted using the absorbent liquid injection pump 140, and the gas is collected in the absorbent liquid through the membrane membrane while the absorbent liquid and the gas move to a flow path separated by the membrane membrane. The chemical method may be coated on the inner wall surface of the sample collecting unit 200, and then the polluting gas may be collected to extract contaminants adsorbed on the wall surface with ultrapure water.

In addition, the direct contact between the absorbent liquid and the gas may be caused by a pump injection, and the absorbent liquid may be injected into the aerosol by using ultrasonic waves or an injection device, and then contacted with the gas.

The absorbent liquid may be ultrapure water or an aqueous solution in which at least one substance is mixed.

The sample collection unit 200 may be the collection and gas-liquid separation at the same time in one device, as shown in Figure 2, the gas-liquid mixing unit 210 is mixed with the absorbed liquid and gas introduced through the operation of the absorbing liquid injection pump 140 ), And the sample introduced from the gas-liquid mixing unit 210 through the sample inlet 310 is gas-liquid separated, the separated liquid sample is discharged to the sample outlet 320, the sample outlet 320 and the ion analyzer It may be made of a gas-liquid separator 220 to which 400 is connected.

The sample collecting unit 200 collects the water-soluble contaminants in the flue gas by using an absorbent liquid, and may be any one selected from a spiral coil sampler, a diffusion scrubber, a denuder, and an impinger.

At this time, the diffusion scrubber is a gas-liquid separation through the membrane at the same time without a separate gas-liquid separation portion proceeds.

The gas-liquid separator 220 is where the sample introduced through the sample inlet connected to the gas-liquid mixing unit 210 is separated by gas-liquid separation, and the separated liquid sample is discharged through the sample outlet connected to the ion analyzer 400. The separated gas is discharged through the gas outlet.

At this time, the chimney exhaust gas online monitoring system 1 of the present invention is a flow controller 330 connected to the gas outlet, a vacuum pump 350 connected to the flow controller 330, the gas-liquid separator ( After passing through 300, the water flow controller 330 and the vacuum pump 350 may further include a water reducing unit 340 for preventing water from being generated.

Similar to the span calibration gas inlet 120 and the zero calibration gas inlet 130, a bypass portion through which the gas pipe is branched may be further formed between the flow controller 330 and the vacuum pump 350.

The water reducing unit 340 is to suppress the condensation of water in the chimney exhaust gas online monitoring system 1, or to generate water to suppress damage of the flow controller 330 or the pump, and collects water, or Nafion Water may be removed using a dryer or a moisture adsorption filter, or a device may be used to control the temperature to prevent condensation.

The ion analyzer 400 includes an eluent storage unit 410 for storing an eluent; An eluent supply pump 420 connected to the eluent storage 410 to pump and move the eluent; Eluent introduced through the operation of the supply pump and the liquid sample separated from the sample collection unit 200 is injected into the sample loop 431, the sample injection to transfer the eluent and the liquid sample to the analysis column 440 Part 430; A suppressor 450 in which electrolysis of the eluent is performed; A detector 460 for detecting ionic substances in the liquid sample separated from the analysis column 440; It may be formed to include.

That is, the chimney exhaust gas online monitoring system 1 of the present invention separates the ionic substances in the sample collected by the sample collection unit 200 by using the analysis column 440 of the ion analyzer 400. The concentration of the ionic component may be measured by the detector 460 by using the conductivity characteristics of the ionic materials electrolyzed by the suppressor 450.

At this time, the chimney exhaust gas online monitoring system 1 of the present invention is a gas pipe between the exhaust gas inlet 110 and the first sample selection valve 510 to prevent the exhaust gas is adsorbed or stagnant in the sampling tube. The transport pump 170 may be formed on the branched gas pipe.

In general, the chimney flue gas automatic measuring system (TMS) should be installed around the chimney, because it is installed outdoors, due to the climate characteristics of our country is exposed to large temperature changes.

However, the chimney flue gas online monitoring system 1 of the present invention is not only a change in temperature of the absorbent liquid may lower the gas collection efficiency, but also an ion detection time depending on the temperature in the case of an analytical column that separates various ions in the sample. Since the sensitivity changes with temperature and the ion conductivity for measuring the concentration of ions is also changed, it is preferable to be kept close to the constant temperature.

Accordingly, the ion analyzer 400 may further include a thermostat to maintain a constant temperature to improve the accuracy of the analysis result.

The thermostat may be a device for locally controlling the temperature of the analysis column 440, or a cell insulator for preventing a temperature change of the conductivity cell.

On the other hand, in order to use the chimney flue gas online monitoring system (1) of the present invention as a chimney flue gas automatic measuring system (TMS), at least the measurement range must meet the legal emission standard, the legal emission limit is the production of glass and glass products Since the melting / melting facility is less than 2 ppm and most of the facilities are more than 5 ppm, in addition to being able to measure low concentrations at the ppb level, it should be possible to measure high concentrations above 5 ppm.

Calibration of TMS must use standard gas to satisfy legal standards, but there is a problem that low concentration measurement is not possible because the standard gas supplied from the standard gas supplier is not supplied below 1 ppm.

In order to solve this problem, the chimney exhaust gas online monitoring system 1 of the present invention performs calibration using standard gas or standard solution.

The chimney flue gas online monitoring system 1 of the present invention performs calibration using a standard gas or a standard solution, and prepares a multi-point calibration curve over various concentration ranges as a standard solution for low concentration measurement of ppb level, Measure the concentration in the measurable range, and prepare a calibration curve using the standard gas by using a correlation formula comparing the concentration measurement result of the standard gas and the concentration measurement result of the standard solution in the program of the controller 600 in advance. To compensate.

That is, the chimney exhaust gas online monitoring system 1 of the present invention quantifies the concentration by using a standard gas or a standard solution complex, and after creating a multi-point calibration curve with a standard solution for calibration, a section in which the linearity of the measurement result is formed. The calibration curve is automatically applied to each other, and a system for automatically compensating for the difference between the measured concentration of the standard gas and the measured concentration of the standard solution may be included in the controller 600.

Accordingly, the chimney flue gas online monitoring system 1 of the present invention can not only have measurement reliability in all sections from low concentration to high concentration, but also satisfy legal standards for flue gas emission monitoring.

In addition, the chimney exhaust gas online monitoring system 1 of the present invention measures the concentration of the entire section with a standard solution for calibration, and then creates a calibration curve, and compares the sensitivity using only one standard gas to prepare a calibration curve with the standard solution. You can also use the method to calibrate.

HCl gas is a toxic gas, but the standard solution is not only possible to low concentration, but also has the advantage of easy handling in a stable aqueous state, it can be easily used for calibration.

To this end, as shown in FIG. 3, the chimney exhaust gas online monitoring system 1 of the present invention is connected to a sample outlet 320 in which a sample is discharged after gas-liquid separation in the sample collecting unit 200. The liquid sample and the standard solution discharged from the sample collection unit 200 may be mixed with the standard solution supply unit 700 to be injected into the ion analyzer 400.

The chimney flue gas online monitoring system 1 of the present invention may analyze the ion component detected by comparing the retention time with a standard solution when the ion analyzer 400 detects ions.

In addition, the chimney exhaust gas online monitoring system 1 of the present invention periodically checks the detection time and sensitivity using a standard solution to automatically increase the measurement accuracy, and automatically corrects the detection time and sensitivity. Such a program may be embedded in the 600 and automatically executed, or may be manually executed at the administrator's discretion.

Meanwhile, the chimney exhaust gas online monitoring system 1 of the present invention controls the injection amount and the injection interval at which the sample introduced into the gas-liquid separator 300 is injected into the sample injection unit 430 of the ion analyzer 400. It may be formed to be possible.

For example, the chimney-emission gas online monitoring system 1 of the present invention is injected into the sample injection unit 430 at a specific time after a predetermined amount of the sample collected by meeting the gas and absorbent liquid is accumulated in the analysis column 440 As soon as the sample is transported, or as soon as the gas and absorbent liquid are collected, the sample may be continuously transferred to the sample injection unit 430 and the sample may be transferred to the analysis column 440 at a specific time.

In order to use the measurement results by the conventional TMS equipment as legal data, type approval or preliminary type approval is required, which requires a response time of less than 10 minutes.

Therefore, in the conventional TMS, data is measured in real time as a sample is injected by FIA (Flow Injection Analysis), thereby securing a response time within 10 minutes.

On the contrary, in the chimney exhaust gas online monitoring system 1 of the present invention, after accumulating the collected liquid in the gas-liquid separator 300 for a predetermined time, the sample accumulated by using the sample injection unit 430 is flow and stop. A rapid response time was secured by injecting a sample into the sample or injecting a sample collected by the sample collecting unit 200 into the sample injection unit 430 to inject a sample into the analysis column 440 at a specific time. .

5 is a chromatogram of the analysis of HCl gas using the chimney flue gas online monitoring system of the present invention, Figure 6 is a graph comparing the theoretical concentration and the actual concentration measured by the chimney flue gas online monitoring system of the present invention. .

Through this, in the chimney flue gas online monitoring system of the present invention, it can be seen that the theoretical concentration calculated by the calibration through calibration and the actual measured concentration very well match.

The chimney flue gas online monitoring system 1 of the present invention may be mixed with Br ^- as a standard material in the absorbent liquid used for sample collection.

This is to automatically correct the evaporation amount of absorbent liquid by relative humidity and temperature by using Br ^- which is a standard substance whose properties are known correctly and its amount does not change in the absorbent liquid and measured. It helps you to accurately measure the concentration of ions you are going to.

In addition, the chimney exhaust gas online monitoring system 1 of the present invention is the controller 600 and the flow rate of the absorbent liquid and gas flowing into the sample collection unit 200 according to the mode in which the chimney exhaust gas is monitored and the cleaning mode. Can be controlled to be automatically variable.

That is, the chimney flue gas online monitoring system 1 of the present invention is cleaned in addition to the mode in which the chimney flue gas is monitored in order to improve the sample collection performance in the sample collecting part 200 and to achieve a quick response time through memory removal. In the mode, the gas suction flow rate and the absorption liquid suction flow rate are automatically changed by the controller 600, or a separate flow rate controller 330 may be installed to change the flow rate.

Accordingly, the present invention separates the various substances in the ionic state using the analysis column 440, and then measure the characteristics of the ionic components using ion conductivity, thereby simultaneously quantitatively and qualitatively analyzing contaminants in the flue gas. Economic effects can be greatly improved.

In addition, the chimney flue gas online monitoring system (1) of the present invention can measure the pollutants of the exhaust gas to a low concentration, thereby reducing the economic waste due to excessive collection of discharge charges and over-investment and redundant investment in the emission reduction facility. There is an advantage that can improve the competitiveness of the industry using it.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1: flue gas online monitoring system
110: exhaust gas inlet 120: span calibration gas inlet
130: zero calibration gas inlet 140: absorbent liquid injection pump
150: bypass unit 160: gas filter unit
200: sample collection unit
210: gas-liquid mixing unit 220: gas-liquid separation unit
310: sample inlet 320: sample outlet
321 gas outlet
330: flow controller 340: moisture reduction
350: vacuum pump
400: ion analysis unit
410: eluent storage unit 420: eluent supply pump
430: sample injection unit 431: sample loop
440: analysis column 450: suppressor
460: detection unit
510: first sample selection valve 520: second sample selection valve
530: third sample selection valve
600:
700: standard solution supply unit

Claims (16)

An exhaust gas inlet 110 through which the exhaust gas is introduced;
A sample collecting unit 200 in which absorbent liquid and exhaust gas are collected through a physical or chemical reaction;
An ion analyzer 400 for separating the ionic substances in the sample collected by the sample collector 200 by an ion chromatography method to measure concentrations of ionic components;
A controller 600 for controlling an online monitoring operation of the chimney exhaust gas and a calibration operation in advance; Formed to include,
After creating a multi-point calibration curve over several concentration ranges with standard solutions, measure and store the concentrations within the ranges that can be measured with standard gases, and compare the results of the measurement of the concentrations of standard gas and the concentration of standard solutions stored in the program of the controller. A chimney flue gas online monitoring system, characterized in that calibration is performed by creating a calibration curve based on a standard gas based on the correlation formula created.
The method of claim 1,
The flue gas online monitoring system (1)
A first sample selection valve 510 connected to the exhaust gas inlet 110;
A second sample selection valve 520 connected to a span calibration gas inlet 120;
A third sample selection valve 530 connected to a zero calibration gas inlet 130;
The gas selected from the discharge gas, the span calibration gas and the zero calibration gas is introduced to one side through the opening and closing control of the first to third sample selection valves 530, and the absorbent liquid introduced through the operation of the absorbent liquid injection pump 140 and A sample collecting part 200 contacting gas and collecting the gas and separating the gas-liquid; Chimney emissions online monitoring system, characterized in that it is formed, including.
3. The method of claim 2,
The sample collection unit 200
A gas-liquid mixing unit 210 in which the absorbent liquid and the gas introduced through the operation of the absorbent liquid injection pump 140 are mixed; And
The sample introduced from the gas-liquid mixing unit 210 through the sample inlet 310 is gas-liquid separated, the separated liquid sample is discharged to the sample outlet 320, the sample outlet 320 and the ion analyzer 400 ) Is connected to the gas-liquid separator 220; chimney exhaust gas online monitoring system, characterized in that it comprises a.
3. The method of claim 2,
The ion analyzer 400
Eluent storage unit 410 in which the eluent is stored;
An eluent supply pump 420 connected to the eluent storage 410 to pump and move the eluent;
The eluent introduced through the operation of the eluent supply pump 420 and the liquid sample separated from the sample collection unit 200 are injected into the sample loop 431, and the eluent and the liquid sample are analyzed into the analysis column 440. Sample injection unit 430 to transfer;
A suppressor 450 in which electrolysis of the eluent is performed;
A detector 460 for detecting ionic substances in the liquid sample separated from the analysis column 440; Chimney emissions online monitoring system, characterized in that it is formed, including.
3. The method of claim 2,
The flue gas online monitoring system (1)
The flue gas online monitoring system, characterized in that the transport pump 170 is connected to the gas pipe formed by branching the gas pipe between the discharge gas inlet 110 and the first sample selection valve (510).
5. The method of claim 4,
The ion analyzer 400
Chimney emissions online monitoring system, characterized in that it comprises a thermostat to maintain a constant temperature.
3. The method of claim 2,
The sample collection unit 200
By using the absorbent liquid to collect the water-soluble contaminants in the flue gas,
Chimney emissions online monitoring system, characterized in that any one selected from spiral coil sampler, diffusion scrubber, denuder, impinger.
3. The method of claim 2,
The flue gas online monitoring system (1)
After the gas-liquid separation in the sample collecting unit 200 is connected to the sample outlet 320 for discharging the sample, the liquid sample and the standard solution discharged from the sample collecting unit 200 is mixed with the ion analyzer 400 Chimney exhaust gas online monitoring system, characterized in that it further comprises a standard solution supply unit 700 to be injected into.
The method of claim 8,
The flue gas online monitoring system (1)
Perform calibration using standard gas or standard solution,
In order to measure the low concentration of ppb level, a multipoint calibration curve is drawn over several concentration ranges with standard solution, and then the concentration is measured over the range that can be measured with standard gas.
Chimney flue gas online monitoring comprising: preparing a calibration curve based on a standard gas by using a correlation between the concentration measurement result of the standard gas and the concentration measurement result of the standard solution, which are built in the program of the controller 600 in advance; system.
The method of claim 8,
The flue gas online monitoring system (1)
When the ion analyzer 400 detects ions, the chimney exhaust gas on-line monitoring system characterized in that to analyze the detected ion component by comparing the detection time with the standard solution.
3. The method of claim 2,
The flue gas online monitoring system (1)
In order to relieve pressure when the standard gas is injected, the gas pipe between the span calibration gas inlet 120 and the second sample selection valve 520 is branched to include a bypass unit 150 through which gas is discharged to the outside. Chimney emissions online monitoring system, characterized in that.
The method of claim 1,
The absorbent liquid
Chimney flue gas online monitoring system, characterized in that the ultrapure water or an aqueous solution in which at least one substance is mixed.
The method of claim 1,
The absorbent liquid
Chimney emissions online monitoring system characterized in that the standard material Br ^- is mixed.
The method of claim 1,
The chimney emissions online monitoring system (1)
A chimney flue gas online monitoring system comprising measuring at least one of HF, Hcl, HNO 2 and SO 2.
The method of claim 3, wherein
The chimney emissions online monitoring system (1)
A flow controller 330 connected to a gas outlet 321 through which the gas separated from the gas-liquid separator 220 is discharged;
A water reduction unit 340 provided between the gas discharge port and the flow control system 330 to reduce the amount of water; And
A vacuum pump 350 connected to the flow controller 330; Chimney emissions online monitoring system, characterized in that it is formed, including.
3. The method of claim 2,
The control unit 600
On-line monitoring, characterized in that for controlling the flow rate of the absorbent liquid and gas flowing into the sample collection unit 200 according to the mode in which the chimney exhaust gas online monitoring system 1 operates normally and the mode to be cleaned. system.

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