JPS6345536A - Chemiluminescence type nitrogen dioxide analyzing instrument - Google Patents

Abstract

PURPOSE:To permit measurement of gaseous NO of low concn. in measurement range of a small full scale by supplying the gaseous O3 of the concn. lower than the concn. of the gaseous NO to a gas which is to be measured and is passed through a converter and a gas which is not passed therethrough to oxide the NO. CONSTITUTION:A chemiluminescence chamber 1 and an introducing port 2 for the gas to be measured are piped by a flow line 3. The converter 4 for converting NO2 to NO, a pretreatment part 5 and a flow control part 6 are connected to the line 3. A selector cock 8 is provided to the inlet part 7 of the converter 4 and a selector line 3' is piped and connected thereto. On the other hand, a gaseous ozone supply line 11 for supplying gaseous O3 from an ozone generating part 10 is piped to the chamber 1. A gaseous ozone introducing line 12 is provided to the gaseous ozone generating part 10 so that the gaseous O3 of the concn. lower than the concn. of the gaseous NO which is the gas to be measured and is admitted through the introducing 2 is supplied.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a chemiluminescent nitrogen dioxide analyzer for measuring the concentration of nitrogen dioxide gas contained in 1M street exhaust gas.

[Conventional technology]

This is a chemical method that utilizes the method of measuring NO gas concentration, which is generally called the chemirumi method, and uses a photomultiplier tube to detect the intensity of light emitted when NO (-nitric oxide) gas reacts with 03 (ozone). The luminescent nitrogen dioxide analyzer converts NO2 into NO2 by sampling the gas to be measured from the gas inlet.
The NO gas concentration after passing through the converter is measured through the NO, -NO converter that converts it into NO, -NO.
The NO gas concentration is measured without passing through an O converter, and the NO2 gas concentration in the gas to be measured is determined from the difference between the two NO gas concentrations.

[Problem that the invention seeks to solve]

The chemiluminescent nitrogen dioxide analyzer described above exhibits excellent characteristics such as low interference effects and excellent sensitivity and stability. However, there is a problem in that the concentration of NO2 gas in the gas discharged from the flue is usually extremely low, and despite this, measurement must be performed in a large full-scale concentration measurement range. In other words, as mentioned above, the chemiluminescent nitrogen dioxide analyzer calculates the NO2 gas concentration by measuring the NO gas concentration, but the NO gas concentration in the measured gas is lower than the NO2 gas concentration. Since the NO□ gas concentration itself is extremely low, measurement must be carried out in a large full-scale concentration measurement range. For this reason, the ratio of the NO2 gas concentration to the full-scale concentration becomes extremely small, leading to problems such as deterioration of analysis accuracy1.For example, if the NO gas concentration in the gas to be measured is between 100 and 200 ppm, the analysis The measurement range of the device must be a full scale of about 250 ppm.

On the other hand, since the concentration of NO is usually only about 5 to 10 pprn, the value is only about 2 to 4% with respect to the full scale concentration of 250 ppm. For this reason, in conventional devices, the output value is electrically expanded to obtain an apparently small full-scale concentration measurement range, but this merely expands the output value and reduces the apparent reading accuracy. However, no substantial improvement in accuracy has been achieved.

The object of this invention is to essentially improve the measurement accuracy in a chemiluminescent nitrogen dioxide analyzer.

[Means for solving problems]

As described above, the present invention provides a chemiluminescent nitrogen dioxide analyzer using the chemiluminescence method, which analyzes gases to be measured such as NO and -N.
NO after passing through that converter through the O converter
We focused on the structure that measures the gas concentration and the NO gas concentration of the measured gas that does not pass through the NO2-NO converter, and calculates the NO2 gas concentration in the measured gas from the difference in NO gas concentration between the two. The chemiluminescent nitrogen dioxide analyzer was constructed as follows. In other words, NO2 gas and N
The measured gas in which O gas coexists is passed through an NO, -NO converter equipped with a reduction catalyst to change NO2 into NO, and the NO gas concentration in the gas after passing through the converter is determined by □-Detect the NO gas concentration in the gas that does not pass through the NO converter and the NO gas concentration in the gas that does not pass through the converter, and
A chemiluminescent analyzer that calculates NO and gas concentrations from the difference between O gas concentrations, characterized in that an ozone gas introduction path is communicated with any part of the gas flow path from the NO2-NO converter to the detector. The gist is a chemiluminescent nitrogen dioxide analyzer.

[For production]

In the chemiluminescent nitrogen dioxide analyzer according to the present invention configured as described above, the ozone gas introduction path communicates with any part of the gas flow path from the NO□-NO converter to the detector. , through this ozone gas introduction path, a concentration of 0. When gas is supplied, NO is oxidized in an amount corresponding to the gas concentration, becomes NO2, and does not react with the detector, and the remaining N
Only O gas is detected in each detector. In this case, the gas on the path side that has passed through the NO□-NO converter is more
The NO gas concentration increases by the amount that NO□ changes to NO, but from both of them, the above 0. Since the NO gas concentration corresponding to the gas concentration is subtracted, the difference between the rain detection values corresponds to the NO2 gas concentration that has changed to NO in the NO, -NO converter, and is expressed as the NO□ gas concentration. It will be measured. Therefore, the measurement range of the detector can be set to a small full-scale concentration corresponding to the remaining NO gas concentration.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows one embodiment of the present invention, and is a schematic diagram of a chemiluminescent nitrogen dioxide analyzer, and FIG. 2 shows the NO concentration versus full-scale concentration of the conventional device and the device according to the present invention.
FIG. 3 is a diagram showing the ratio of two density values.

In the illustrated chemiluminescent nitrogen dioxide analyzer, a flow line 3 is connected between a chemiluminescence chamber 1 as a detector and a gas inlet 2 through which a gas to be measured is introduced. This flow path line 3 includes a converter 4 that converts NO2 into NO,
A pre-processing section 5 and a distribution control section 6 are connected. Also,
A switching cock 8 is provided at the inlet 7 of the converter 4 without passing through the converter 4.

A switching line 3' is connected to the outlet 9 of the converter 4. On the other hand, the chemiluminium chamber 1 receives 0.0% from the ozone generator 10. An ozone gas supply line 11 for supplying gas is installed. In addition, the ozone gas generation section 10 is provided with an ozone gas introduction line 12 that is piped to the outlet section 8 of the converter 4 in the flow path line 3, in addition to the ozone gas supply line 11 to the chemiluminium chamber 1, and is connected to the ozone gas introduction line 12 from the gas introduction port 2. The 03 gas is supplied with a concentration lower than the NO gas concentration of the inflowing gas to be measured. Note that 13 is the N detected in the Chemiluminium chamber 1.
An indicator needle 14 indicates the O gas concentration, and 14 is an ozone gas decomposition unit.

In the chemiluminescent nitrogen dioxide analyzer having the above configuration, for example, 10 ppm of NO□ gas and 190 PPm of NO
First, the gas to be measured in which NO gas coexists is introduced into the converter 4 using the switching cock 8. This converter 4
At this point, NO2 in the gas to be measured is converted to NO, so that the NO gas concentration reaches the outlet section 9 at 200 ppm. At this outlet section 9, the ozone gas introduction line 12 is passed from the ozone gas generating section 10 to a concentration of 0.0000, which is lower than the NO gas concentration, for example, 150 ppm. Once gas is supplied.

The reaction of NO+O,=NO,+O, occurs, and 150PP
The NO gas has a concentration of 50 ppm and NO gas has a concentration of 50 ppm, and reaches the pretreatment section 5, where pretreatment such as dehumidification and dust removal is performed. This pretreated gas is supplied to the flow rate controller 6
is supplied to the chemiluminium chamber 1 via. In the chemiluminescence chamber 1, the 0° gas introduced from the ozone gas generation unit 10 through the ozone gas supply line 11 is
50ppm concentration of NO, does not react with gas, 50ppm
It reacts with NO gas at a concentration of 50 ppm to emit chemiluminescence, which is converted into an electrical signal by a photomultiplier tube, and a signal corresponding to a concentration of 50 ppm of NO gas is detected, and this detected value is held. Next, the switching cock 8 is switched to allow the gas to be measured to flow through the switching line 3' without passing through the converter 4, and is sent to the outlet section 7. Here, since gas with a concentration of 150 ppm is supplied from the ozone gas generation unit 10 through the ozone gas introduction line 12, a reaction similar to that in the case of passing through the converter 4 occurs, and NO2 gas with a concentration of 10 ppm and NO2 gas with a concentration of 190 PPm occur. The measured gas in which NO gas coexists becomes NO2 gas with a concentration of 160 ppm and NO gas with a concentration of 40 ppm, and reaches the chemirumi chamber 1 from the pretreatment section 5, and the remaining NO gas with a concentration of 40 ppm passes through the ozone gas generation section. It reacts with the ○ gas supplied from 10 to emit chemiluminescence, and is detected as NO gas concentration of 4 Qppm. The signal corresponding to the NO gas concentration of 50 ppm that is detected and held when passing through the converter 4 includes the NO gas concentration where NO□ changes to NO in the converter 4, so the converter 4 is N after subtracting the NO gas concentration of 40PPm detected in the case of no passage.
The O gas concentration is measured as the desired NO2 gas concentration.

Therefore, the measurement range of the detector in this example device can be set to a full scale concentration of, for example, 50 ppm in the above example. In this regard, FIG. 2 shows a comparison with a conventional case in which a measurement range with a full scale concentration of 250 ppm was used to set NO gas at a concentration of 2° OPPm.

That is, 250 ppm of NO2 gas with a concentration of 10 ppm
When measured in the m full scale range, it is only 4% of the full scale, but in the 50 ppm full scale range, it is 20% of the full scale. If the concentration of NO gas is kept below 50 ppm in this way,
It is now possible to set the full scale concentration to a small measurement range of 50 ppm, and there is no need to expand the gain of the calculation section.
Accuracy improvement in an essential sense is achieved.

In the above embodiment, the gas flow line is one series, and in the middle of the line, NO, -N, which changes NO2 to NO,
A case has been described in which the flow path passing through the O converter and the flow path not passing through the O converter are branched, and the flow paths are merged downstream of the NO and -NO converters, and the flow path is switched at the branch point. , each channel separately,
That is, it is possible to have two series, provide ozone introduction means in each flow path, and measure the NO2 gas concentration by detecting the NO gas concentration for each series.

〔effect〕

According to the chemiluminescent nitrogen dioxide analyzer of the present invention described above, each of the gas to be measured that has passed through the NO2-NO converter and the gas to be measured that has not passed through the NO, -NO converter has a concentration lower than the NO gas concentration. When O gas is supplied, NO is oxidized to NO gas by the concentration of the supplied O3 gas, and the N remaining in each gas is
Since the O gas concentration decreases by exactly the same concentration, those N
The difference in the detected value of O gas concentration.

This indicates the gas concentration of NO2 that has changed to NO. Therefore, low concentration NO gas can be measured in a small full-scale measurement range, thereby improving the analytical accuracy of the chemiluminescent nitrogen dioxide analyzer.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram showing one embodiment of the chemiluminescent nitrogen dioxide analyzer according to the present invention, and FIG. 2 is the ratio of the NO2 gas concentration value to each full-scale concentration in the conventional device and the device according to the present invention. FIG. 1...Chemilumi chamber. 2...Gas inlet, 3...Flow path line, 3'
...Switching line, 4...Converter. 5... Pretreatment section, 6... Flow rate control section, 7...
・Inlet section, 8...Switching cock. 9... Outlet part, 10... Ozone gas generation part, 11... Ozone gas supply line, 12... Ozone gas introduction line, 13... Indicator. Figure 1 Figure 2 Horai! A! Replacement βμ”

Claims (1)

[Claims] NO_2 gas and N introduced from the gas introduction part to be measured
The gas to be measured in which O gas coexists is passed through an NO_2-NO converter equipped with a reduction catalyst to change NO_2 into NO, and the N in the gas after passing through the converter is
A detector detects the O gas concentration and the NO gas concentration in the gas that does not pass through the NO_2-NO converter, and determines the NO_2 gas from the difference between these NO gas concentrations. A chemiluminescent nitrogen dioxide analyzer for calculating concentration, characterized in that an ozone gas introduction path is connected to any part of the gas flow path from the NO_2-NO converter to the detector.