KR20230030284A - Nitrogen oxide meter with improved reaction part - Google Patents

Abstract

The present invention aims to provide a means for better measuring light generated by chemiluminescence by improving a conventional structure for collecting light generated by chemiluminescence. To this end, the present invention provides a nitrogen oxides measurement device with an improved reaction unit, which is a nitrogen oxides measurement device that measures the concentration of nitrogen monoxide by reacting nitrogen monoxide with ozone (O3) in a chemiluminescent method, includes a nitrogen oxides (NO) reaction unit where nitrogen monoxide and O3 react, wherein the NO reaction unit is composed of an NO gas supply unit, an O3 gas supply unit, a gas supply nozzle, a reaction cell, a gas outlet, and a red filter provided at a front end of the reaction cell. The reaction cell is equipped with a reaction cell reflector sleeve, which is a reflector sleeve having a semicircular cross-section, and reflects the light of chemiluminescence generated by the NO and O3 gases forward so that the light can be measured by a PMT sensor provided in the front, thereby improving measurement precision. With the above configuration, the present invention has the advantage of measuring lower concentrations of nitrogen oxides by collecting and measuring the light generated by chemiluminescence.

Description

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The present technology relates to a nitrogen oxide meter. More specifically, it relates to a measurement technique using a chemiluminescence method generated by the reaction of NO and O3.

Prior art prior to this application has disclosed a portable nitrogen oxide measuring device. In this technology, the present invention is to remove unnecessary devices from the nitrogen oxide measuring device or to provide a portable atmospheric nitrogen monoxide measuring device by reducing its size.

In order to achieve the above object, the present invention provides an atmospheric gas inlet pipe for introducing atmospheric gas; and an ozone gas generator for generating ozone gas for measurement; and a reaction chamber for reacting the air introduced from the atmospheric gas inlet pipe with ozone generated in the ozone gas generator; and a gas outlet for reacting the introduced atmospheric gas with the ozone and then discharging the reaction chamber. It is provided, the atmospheric gas inlet and the ozone inlet are provided on the lower side facing each other, and the atmospheric gas inlet and the ozone inlet and the upper side are provided with two facing the gas outlet on the side perpendicular to the ozone inlet, A connection part connected to the two outlets is provided in the middle of the gas outlet, and an ozone (O3) concentration sensor is provided at the rear end of the connection part to measure the concentration of ozone discharged, thereby measuring whether the ozone supply amount is high or low, and the ozone A technique of including a pump for sucking in the ozone and atmospheric gas at a negative pressure at the rear end of a discharge pipe in which a concentration sensor is installed is disclosed.

Another prior art is a technology related to a chemiluminescent NOx concentration measuring device that measures NOx concentration by detecting the emission intensity generated when ozone generated by a silent discharge ozone generator and NO in a sample gas react in a reaction tank with a detector. This is disclosed. In this technology, a replaceable filter was applied to the pipe connecting the silent discharge ozone generator and the reaction tank.

Registered Patent Publication 10-2074700 Japanese Laid-open Patent Publication 2021-073474

The present invention is intended to more accurately measure chemiluminescence generated by the reaction by improving the shape of a reactor in which nitrogen monoxide (NO) and ozone (O3) react.

Existing reaction cells are provided in the form of cylindrical pillars, have a wide space for reaction, and have a configuration in which light emission is measured by a PMT sensor provided in front of the reaction cell without a means for collecting chemiluminescence light generated by the reaction. (See Figure 1)

The present invention is intended to provide a means for better measuring light generated by chemiluminescence by improving a structure that collects light generated by chemiluminescence in the past. On the other hand, by limiting the space where the chemiluminescence occurs, a chemical reaction occurs only within a certain space to cause chemiluminescence, thereby providing a means for measuring the optical density by increasing it.

In order to solve the above problem, the present invention provides the following problem solving means.

In the nitrogen oxide measuring device for measuring the concentration of nitrogen monoxide by the chemiluminescence method by reacting nitrogen monoxide with ozone,

The nitrogen oxide reaction unit in which the nitrogen monoxide reacts with ozone

NO gas supply unit; and

O3 gas supply unit; and

gas supply nozzle; and

reaction cell; and

gas outlet; and

remind It consists of a red filter provided at the front end of the reaction cell,

The reaction cell is provided with a reaction cell reflector sleeve, which is a reflector sleeve having a semicircular cross section, so that the chemiluminescent light generated by the NO gas and the O3 gas is reflected forward to be measurable to the PMT sensor provided in the front, thereby improving measurement accuracy. The reaction part, characterized in that the height, provides an improved nitrogen oxide measuring device.

In addition, an ozone sensor is further provided at the gas outlet so that the PMT sensor measures chemiluminescence generated by the reaction of NO gas and ozone gas in the nitrogen oxide reaction unit and the amount of ozone discharged through the gas outlet. By measuring the sensor and analyzing their correlation, it is possible to determine whether the result measured by the PMT sensor is due to noise or chemiluminescence. On the other hand, when the amount of ozone emitted is small, sufficient ozone is Provided is an improved nitrogen oxide measuring device in which the reaction unit determines that ozone is not supplied and increases the supply of ozone.

As another embodiment,

The reaction unit provides an improved nitrogen oxide measuring device, characterized in that it further comprises a transparent cylindrical diffusion prevention ring between the front of the gas supply nozzle of the reaction cell and the red filter.

In addition, the gas supply nozzle is made of transparent glass to measure chemiluminescence generated at the inlet of the gas supply nozzle.

By the configuration as described above, the present application has an effect of measuring nitrogen oxide at a lower concentration by collecting and measuring light generated by chemiluminescence.

In addition, by collecting the non-reactive gas discharged from the gas outlet in a specific area within the reaction cell, it reacts in a narrow area and measures it, thereby increasing the density of measurement light and measuring a signal resistant to noise.

1 shows the configuration of a conventional PMT sensor 50 and a conventional nitrogen oxide reaction unit 90.
Figure 2 shows the internal configuration of the conventional nitrogen oxide reaction zone 90 in a perspective cross-section.
Figure 3 shows the internal configuration of the existing nitrogen oxide reaction ring 90 in cross-sectional view.
Figure 4 shows the configuration of the nitrogen oxide reaction unit of the present invention as a conventional nitrogen oxide reaction unit and a new reaction cell reflector sleeve.
5 shows a cross-sectional view of the improved nitrogen oxide reaction unit of the present invention.
6 shows an improved nitrogen oxide reaction unit of the present invention in a perspective cross-sectional view.
Figure 7 shows an improved nitrogen oxide reaction unit further provided with a diffusion preventing ring as another embodiment of the present invention.
Figure 8 shows a perspective view of another embodiment of the anti-diffusion ring of the present invention.
Figure 9 shows the action of another embodiment of the anti-diffusion ring of the present invention.

The operation and effect of the invention of the present application will be described using drawings as follows.

Methods for measuring nitrogen oxides among air pollution measurement technologies include a water analysis method, an automatic Salzman measurement method, and a chemiluminescence method. Among them, as a method for continuously and automatically measuring nitrogen oxides, the chemiluminescence method has been put into practical use and is widely used.

Chemiluminescence refers to a phenomenon in which a reactant is excited during a chemiluminescence process and emits light when it returns to a ground state. At this time, it is known that when the concentration of the reacting substance is low, the luminous intensity is proportional to the concentration of the substance. Therefore, the concentration of the reactant can be known by measuring the emission intensity. Therefore, when measuring nitrogen oxides using chemiluminescence, it can be said that minimizing the loss of light emitted by chemiluminescence is an important element of the analytical instrument.

Nitrogen oxide concentration measurement using the chemiluminescence method is based on the principle that the intensity of chemiluminescence generated when nitrogen monoxide (NO) and ozone (O3) in a sample gas react to produce nitrogen dioxide (NO2) is proportional to the concentration of nitrogen monoxide. It is to continuously measure the concentration of nitrogen monoxide contained in the sample air by using

Looking at the reaction relationship between nitrogen monoxide and ozone, nitrogen dioxide (NO2) is formed when nitrogen monoxide is oxidized in a low-pressure state with ozone as shown in the equation below, and as activated (excited) molecules transition to the ground state, chemiluminescence Among the wavelengths by , 620 nm light is selectively passed through.

(화학식 1 )

(Formula 1)

That is, by maintaining an excess of ozone in the reaction chamber, the concentration of NO in the sample is determined by measuring the amount of emitted light.

1 shows the configuration of a conventional PMT sensor 50 and a conventional nitrogen oxide reaction unit 90. In order to measure chemiluminescence of a conventional nitrogen oxide reaction unit, a perspective view is shown in which PMT sensors face each other. That is, chemiluminescence generated by the reaction of nitrogen monoxide and ozone in the existing nitrogen oxide reaction unit is measured by the PMT sensor.

2 and 3 show the internal structure of the conventional nitrogen oxide reaction zone 90 in perspective and cross-sectional views. As can be seen from the figure, when NO gas and O3 gas are respectively introduced into the inlet, the gas from the gas supply nozzle 95 formed of a double pipe chemically reacts in the reaction cell straight sleeve inside the reaction cell to emit light. However, the direction of light generated during emission may be directed in all directions.

As confirmed in FIG. 3, light emitted in the lateral direction is not transferred to the PMT sensor, and effective measurement is not possible toward the side or rear.

The present invention solves this problem and provides the reaction cell reflector sleeve described in FIG. 4 in order to further equip the reaction cell with a configuration for transmitting light emitted toward the side or rear toward the front PMT sensor.

Figure 3 shows the internal configuration of the existing nitrogen oxide reaction ring 90 in cross-sectional view.

Figure 4 shows the configuration of the nitrogen oxide reaction unit of the present invention as a conventional nitrogen oxide reaction unit and a new reaction cell reflector sleeve. It is shown in FIG. 4 that the conventional straight sleeve of the nitrogen oxide reaction unit is removed and an improved reaction cell reflector sleeve is applied.

5 and 6 show the improved nitrogen oxide reactor of the present invention in cross-sectional and perspective cross-sectional views. The operation is the same as that of the conventional nitrogen oxide reaction unit, but by applying the reaction cell reflector sleeve, more light generated by the chemical reaction is transmitted to the front, thereby improving measurement accuracy. Meanwhile, comparing FIG. 3 and FIG. 5 , it can be seen that the reaction space of NO and O3 is reduced by about 1/2. Therefore, it is another advantage of the present application that less ozone can be used for nitrogen oxide measurement.

In addition, an ozone sensor may be further provided at an outlet connected to the gas outlet 90c. The ozone sensor reacts and measures the remaining amount of ozone, so that it can be used to check whether the measurement result is accurate or not affected by noise. That is, if it appears that a large amount of nitrogen oxide is measured even though the amount of ozone measured by the ozone sensor is high, the measured value of the signal of the PMT sensor is high due to the influence of noise and the like. If the amount of ozone measured by the ozone sensor is small, there may be NO gas that does not react with ozone. Therefore, information on the measurement process of these devices is obtained by using the amount of ozone emitted from the central control unit and the result of measuring nitrogen oxides. can be monitored.

For this purpose, a separate electrochemical sensor may be used, or a photosensor equipped with an LED emitting 253.65 nm light integrally using an NDIR method and a filter of 253.65 nm Gas discharged through the gas outlet The amount of ozone can be measured in By doing this, of course, the ozone concentration in the gas discharged through the gas outlet can be measured using the absorbance measured by the photosensor equipped with the 253.65 nm filter.

Figure 7 shows an improved nitrogen oxide reaction unit further provided with a diffusion preventing ring as another embodiment of the present invention. This has a problem in that nitrogen monoxide and ozone from the double tube do not mix well in the process of being ejected forward, and are diffused and released to the gas outlet. To improve this, a diffusion prevention ring is provided in front of the gas supply nozzle 95 Thus, the gas supplied from the gas supply nozzle does not spread in the lateral direction, but is supplied forward and is easily converted into NO2 and O2 by being combined with each other while being bounced off the red filter provided in the front. In addition, the same result was obtained by chambering the anti-expansion ring and the red filter at a distance of 2 to 5 mm so that the gas after the reaction could be discharged.

Figure 8 shows a perspective view of another embodiment of the anti-diffusion ring of the present invention. An anti-expansion ring made of a transparent material was formed at regular intervals from the red filter, and was installed at intervals so that nitrogen dioxide, etc., having reduced kinetic energy, could be discharged to the lower portion after the reaction was completed. In addition, ozone that did not participate in the reaction is discharged through the above interval.

Figure 9 shows the action of another embodiment of the anti-diffusion ring of the present invention. Here, a process in which the reaction gas from the double-tube gas supply nozzle collides with the anti-diffusion ring and the red filter provided on the front side and is mixed is shown. The anti-diffusion ring is provided transparently so that light reflected from the reaction cell reflector sleeve can be transmitted to the front PMT sensor.

The configuration of the invention for exhibiting the above functional effects is as follows.

In the nitrogen oxide measuring device for measuring the concentration of nitrogen monoxide by the chemiluminescence method by reacting nitrogen monoxide with ozone,

The nitrogen oxide reaction unit in which the nitrogen monoxide reacts with ozone

NO gas supply unit; and

O3 gas supply unit; and

gas supply nozzle; and

reaction cell; and

gas outlet; and

It consists of a red filter provided at the front end of the reaction cell,

The reaction cell is provided with a reaction cell reflector sleeve, which is a reflector sleeve having a semicircular cross section, so that the chemiluminescent light generated by the NO gas and the O3 gas is reflected forward to be measurable to the PMT sensor provided in the front, thereby improving measurement accuracy. The reaction part, characterized in that the height, provides an improved nitrogen oxide measuring device.

In addition, an ozone sensor is further provided at the gas outlet so that the PMT sensor measures chemiluminescence generated by the reaction of NO gas and ozone gas in the nitrogen oxide reaction unit and the amount of ozone discharged through the gas outlet. By measuring the sensor and analyzing their correlation, it is possible to determine whether the result measured by the PMT sensor is due to noise or chemiluminescence. On the other hand, when the amount of ozone emitted is small, sufficient ozone is Provided is an improved nitrogen oxide measuring device in which the reaction unit determines that ozone is not supplied and increases the supply of ozone.

As another embodiment,

The reaction unit provides an improved nitrogen oxide measuring device, characterized in that it further comprises a transparent cylindrical diffusion prevention ring between the front of the gas supply nozzle of the reaction cell and the red filter.

In addition, the gas supply nozzle is made of transparent glass to measure chemiluminescence generated at the inlet of the gas supply nozzle.

90: Existing nitrogen oxide reaction unit
90a: NO gas supply unit
90b: O3 gas supply unit
90c: gas outlet
95: gas supply nozzle
100: nitrogen oxide reaction unit
110: reaction cell
110a; Reaction cell straight sleeve
110b: red filter
120: reaction cell reflector sleeve
150: diffusion prevention ring
200: PMT sensor (Photo Multiplier Tube)
210: signal line

Claims (4)

In the nitrogen oxide measuring device for measuring the concentration of nitrogen monoxide by the chemiluminescence method by reacting nitrogen monoxide with ozone,
The nitrogen oxide reaction unit in which the nitrogen monoxide reacts with ozone
NO gas supply unit; and
O3 gas supply unit; and
gas supply nozzle; and
reaction cell; and
gas outlet; and
It consists of a red filter provided at the front end of the reaction cell,
The reaction cell is provided with a reaction cell reflector sleeve, which is a reflector sleeve having a semicircular cross section, so that the chemiluminescent light generated by the NO gas and the O3 gas is reflected forward to be measurable to the PMT sensor provided in the front, thereby improving measurement accuracy. Nitrogen oxide measuring device with an improved reaction part, characterized in that the height. According to claim 1,
An ozone sensor is further provided at the gas outlet so that the degree of chemiluminescence generated by the reaction of NO gas and ozone gas in the nitrogen oxide reaction unit is measured by the PMT sensor and the amount of ozone discharged through the gas outlet is measured by the ozone sensor. By measuring and analyzing their correlation, it is possible to confirm whether the result measured by the PMT sensor is due to noise or chemiluminescence. On the other hand, if the amount of ozone emitted is small, sufficient ozone is not supplied for the reaction. Nitrogen oxide measuring device with an improved reaction unit, characterized in that the supply of ozone is increased by determining that it is not. According to claim 1,
The nitrogen oxide measuring device with an improved reaction part, characterized in that it further comprises a transparent cylindrical diffusion prevention ring between the front of the gas supply nozzle of the reaction cell and the red filter. According to claim 1,
The gas supply nozzle is made of transparent glass to measure chemiluminescence generated at the inlet of the gas supply nozzle.

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