RU77046U1 - INTERFERENCE GAS ANALYZER - Google Patents

Abstract

An interference gas analyzer belongs to the field of measurement technology and can be used to quantify the concentration of individual components in a multicomponent gas mixture. The objective of the utility model is to expand the technical characteristics and increase the accuracy of determining the concentration of harmful impurities in a multicomponent gas mixture by studying signals of only one nature of origin. The technical result that can be obtained using the utility model is to reduce the susceptibility of the gas analyzer to acoustic and vibrational noise, as well as to reduce the noise immunity of the device. The problem is achieved in that the interference gas analyzer contains a source of broadband optical radiation, an optical filter, two cuvettes with identical characteristics: a comparative one with a "zero" gas and a measuring one with an analyzed gas, a recording device. At the same time, a micrometer screw is added to the measuring cell with the gas mixture under study, and the optical filter is a biconvex collecting lens with a diaphragm with one slit at the input and two slots at the output, while the recording device is a biconvex collecting lens installed at the exit of the cuvette and eyepiece. The difference in the refractive indices of the analyzed gas is determined relative to the reference with a known refractive index. Moreover, the nature of the arrangement of interference fringes allows one to determine the gas itself, and the shift of the fringes between the upper and lower interference fringes - its concentration. The use of one nature of the studied signals helps to reduce the susceptibility of the gas analyzer to acoustic and vibrational noise. The absence of dependence on the influence of external factors makes the research and registration process noise-immune. An interference gas analyzer can find application in systems for monitoring microconcentrations of hazardous and toxic impurities in the air. 1 ill.

Description

The utility model relates to the field of measurement technology and can be used to quantify the concentration of individual components in a multicomponent gas mixture.

Known gas analyzers built on the method of absorption spectroscopy in the field of infrared radiation, incorporating broadband sources of infrared radiation and located on their optical axes measuring and comparative gas cuvettes, a compensation cuvette and optical-pneumatic optical radiation detectors using the effect of changing the pressure concluded in gas during the absorption of optical radiation incident on it (J. Ash et al. Sensors of measuring systems. Book 2. chap. 19, p. 403. M .: Mir, 1992.).

The well-known optical-acoustic gas analyzer GIAM built according to this scheme is known (D.L. Bronstein, NN Aleksandrov. Modern means of measuring atmospheric pollution. L .: Gidrometeoizdat, 1989, chap. 3, p. 147).

The gas analyzer is built according to a two-channel scheme and has identical broadband optical radiation sources in each of the channels, on the optical axis of each of which measuring (comparative) cuvettes and optical-pneumatic optical radiation receivers are installed, and in one of the channels a controlled pump is forcedly pumped through the measuring cuvette a gas mixture, and in the other, a comparative cuvette is filled with "zero" gas (nitrogen or clean air), while filtration cuvettes of both canals s filled pure "interfering" gas, whose influence on the measurement results controlled the gas component to be excluded. The outputs of the optical-pneumatic receivers through the matching devices are connected to a computing device in which, based on the relative value of the pneumatic signals caused by the absorption of optical radiation in the optical-pneumatic receivers of the first and second channels, the concentration of the desired gas component in the gas mixture pumped through the measuring cell is determined.

The main disadvantage of the known gas analyzer is its low protection against the influence of acoustic and vibrational noise, due to the use of optical-pneumatic receivers of an acoustic microphone as a sensitive element. This circumstance leads to the fact that, despite the fact that the calculated sensitivity of this type of gas analyzers for many gases falling into the region of its measurement is quite high (up to background concentrations), in practice, the use of these types of gas analyzers is significantly limited. The high degree of susceptibility of this type of gas analyzers to acoustic and vibrational noise significantly worsens the threshold sensitivity of the analysis and makes it unsuitable for use in widespread practice in real production conditions.

The closest in technical essence and the achieved technical effect to the proposed technical solution is "Photothermoacoustic gas analyzer" (RF Patent for the invention No. 2207546, G01N 21/61, publ. 06/27/2003).

To reduce the susceptibility of the gas analyzer to acoustic and vibrational noise, the photothermal-acoustic gas analyzer contains two optical channels with identical sources of broadband optical radiation and a computing device. Three cuvettes are installed in each channel on the optical axis of the sources: in the first - filtration, measuring and recording, in the second - filtration, comparative and recording. The test gas mixture is pumped through the measuring cuvette, the comparative gas is filled with “zero” gas, and both of them are filled with gas, the concentration of which should be determined as part of the gas mixture under study. New in the device are the additionally introduced electric pulse generator, a time interval meter and two pairs of acoustically coordinated emitters and receivers of ultrasonic vibrations. The latter are located in pairs inside the recording ditches. The technical result is an increase in the sensitivity and noise immunity of the device.

In this gas analyzer, information on the concentration of the desired gas component is contained in the magnitude of the difference in the velocity of propagation of ultrasonic vibrations in the recording cells of the first and second channels, which

It does not depend on the influence of external factors and makes the registration process extremely noise-resistant.

A significant drawback of this gas analyzer is the need for strict identity of the sources of broadband emitters and filter cuvettes located immediately after them to ensure high accuracy of coincidence of characteristics. In addition, the accuracy of measuring the concentration of explosives in the air depends on the nature of the heating of the gas medium in the cells, as well as on the identity of the acoustic receivers. On the other hand, the multiple transformation of the nature of the signal under study: optical, ultrasonic, thermal and, finally, time intervals, also affect the measurement accuracy. In addition, the gas analyzer is designed to determine only one harmful substance in the air, because recording cuvettes are filled with the same gas, the concentration of which should be determined.

This drawback can be eliminated by using coherent waves, in which the phase difference of the oscillations does not change with time. In this case, a more appropriate way to determine the concentration is interference, rather than photothermoacoustic. In this case, the studied signals are coherent waves.

In the theory of interference, they operate not on the phase difference of the superimposed waves, but on the path difference of their rays.

The objective of the utility model is to expand the technical characteristics and increase the accuracy of determining the concentration of harmful impurities in a multicomponent gas mixture by studying signals of only one nature of origin.

The technical result that can be obtained using the utility model is to reduce the susceptibility of the gas analyzer to acoustic and vibrational noise, as well as to reduce the noise immunity of the device.

The problem is achieved in that the interference gas analyzer contains a source of broadband optical radiation, an optical filter, two cuvettes with identical characteristics: comparative with "zero"

gas and measuring with the analyzed gas, a recording device. At the same time, a micrometer screw is added to the measuring cell with the gas mixture under study, and the optical filter is a biconvex collecting lens with a diaphragm with one slit at the input and two slots at the output, while the recording device is a biconvex collecting lens installed at the exit of the cuvette and eyepiece.

A schematic diagram of an interference gas analyzer is shown in figure 1, and figure 2 is a system of interference fringes observed in a gas analyzer,

where: 1 - broadband emitter;

2 - diaphragm with one slit;

3 - biconvex collecting lens;

4 - diaphragm with two slits;

5 - comparative cuvette with a "zero" gas;

6 - measuring cell with the analyzed gas;

7 - micrometer screw;

8 - biconvex collecting lens;

9 - eyepiece.

Wave interference can only be observed if the folding waves are coherent. Coherent waves are waves in which the phase difference of the oscillations does not change with time.

The interference measurement method is based on obtaining an interference pattern from two coherent light beams passing through two parallel slits.

The light source of the interference gas analyzer is a broadband emitter, which creates a brightly lit slit S, from which the light wave falls on two equally spaced slits S ₁ and S ₂ parallel to the slit S (Fig. 1). Thus, the gaps S ₁ and S ₂ play the role of coherent sources.

In the theory of interference, they operate not on the phase difference of the superimposed waves, but on the path difference of the rays. The difference in the path of the rays and the difference in the phases of the oscillations are proportional.

We introduce the concept of optical path length as a product of geometric

the path of the beam to the absolute refractive index of the medium in which the given beam propagates (i.e. the distance that light would travel in a vacuum during the time during which light travels in a given substance)

where l is the geometric path length (the distance between the light source and the point at which the interference pattern is calculated);

n is the absolute refractive index of the medium. It shows how many times the speed of light in a given medium is less than the speed of light in a vacuum:

The principle of operation of the interference gas analyzer.

A beam of rays from a continuous spectrum light source (incandescent lamp) 1, passing through aperture 2 with one slit S, collecting lens 3 and aperture 4 with two slits S ₁ and S ₂ , is divided into two channels.

The rays exit the lens 4 in parallel rays and are surrounded on both sides by the same medium.

On the path of the beams against the slits S ₁ and S ₂ are installed two cuvettes with identical characteristics: comparative 5 with a "zero" gas and measuring 6 with the analyzed gas.

There are two spectral interference fringes located one above the other, with the upper picture moving, the lower one fixed (figure 2).

In the case when the cuvettes are filled with the same air medium, i.e. the path difference between the rays from both slits S ₁ and S ₂ is equal to zero, then the upper system of bands coincides with the lower (Fig. 2, a).

If you leave the reference air medium with a refractive index n ₀ in one cuvette and place the test air medium with a refractive index n ₁ in another, then an additional travel difference

as a result, the upper system of strips will move relative to the lower (figure 2, b). This displacement will depend on the difference in the refractive indices of the compared air media (n ₁ -n ₀ ).

If in the path of one beam to put a micrometer screw 7, made in the form of a compensation wedge of variable thickness 7 (figure 1), introducing an additional difference in stroke, then moving the wedge, it is possible to achieve that the difference in stroke given by the wedge is equal to zero and interference the strip will return to its original position (figure 2, a).

The micrometer screw 7 is calibrated so that a turn by one division changes the stroke difference by (1/30) λ. If the displacement of the strips is achieved by turning the screw by N divisions, then the stroke difference introduced by the wedge

Equating Equations and after small transformations we get

The micrometer screw of the interference gas analyzer has two scales: fixed with 30 divisions and movable with 100 divisions. Therefore, the entire compensation scale has 3,000 divisions.

The optical path difference arising between the interfering rays Δ = (n ₁ -n ₀ ) · l. Changing the stroke difference will result in a shift in the interference fringes. This shift can be characterized by

which shows how much of the width of the interference strip the interference pattern has shifted. By measuring the value of m with known λ, n ₀ and l, one can calculate either a change in n _x or a change in n _x -n ₀ .

In the focal plane of the lens 8 (F) creates a system of interference fringes, which is observed using the eyepiece 9 (figure 1).

The operating procedure of the interference gas analyzer.

1. Turn on the broadband emitter (light lamp) 1. In the absence of ditches 5, 6, make sure that the upper and lower interference fringes match. In this case, the micrometer screw 7 should occupy a position corresponding to zero divisions on both scales.

2. Place the ditches 5, 6 in the gas analyzer. In this case, both cuvettes must be filled with "zero" gas (nitrogen or clean air). The gas analyzer should show a “zero” instrument. If the lower and upper stripes are offset (figure 2),

it is necessary to return them to their original position by rotating the micrometer screw 7 and fix the count N ₀ . This will be the “zero” device.

3. Replace one of the cuvettes with cuvette 6 through which the controlled gas mixture is passed (in Fig. 1 this cuvette is located on the right).

4. Using a micrometer screw, achieve alignment of the upper and lower interference bands.

5. Calculate the refractive indices of the investigated air medium according to the formula

6. According to the graph n = f (C), determine the unknown concentration of C _x . If there is no such graph, then it is necessary to construct the graph n = f (C), repeating steps 1-5 several times and putting n on the ordinate, and C on the abscissa.

An interference gas analyzer allows you to measure the refractive index of the analyzed gas at very low concentrations with very high accuracy (up to 1/1000000).

Thus, the difference in the refractive indices of the analyzed gas is determined relative to the reference with a known refractive index. Moreover, the nature of the arrangement of interference fringes allows one to determine the gas itself, and the shift of the fringes between the upper and lower interference fringes - its concentration.

The use of one nature of the studied signals helps to reduce the susceptibility of the gas analyzer to acoustic and vibrational noise. The absence of dependence on the influence of external factors makes the research and registration process noise-immune.

An interference gas analyzer can find application in systems for monitoring microconcentrations of hazardous and toxic impurities in the air.

Claims (1)

An interference gas analyzer containing a source of broadband optical radiation, an optical filter, two cuvettes with identical characteristics: a comparative one with a "zero" gas and a measuring one with an analyzed gas, a recording device, characterized in that a micrometer screw is added to the measuring cell with the studied gas mixture, and the optical the filter is a biconvex collecting lens, at the entrance of which there is a diaphragm with one slit, and at the exit with two slits, while recording the device is a biconvex collecting lens mounted at the exit of the cuvette and eyepiece.