RU56633U1 - ANALYZER OF HYDROGEN CONCENTRATION IN GAS MEDIA - Google Patents

Abstract

The utility model relates to the field of analytical technology, namely, to measuring instruments, the concentration of hydrogen of multicomponent hydrogen-containing gas environments. The analyzer of hydrogen concentration in gaseous media contains a measuring diffusion cell, consisting of auxiliary and analyzed gas chambers, separated from each other by a membrane selectively permeable to hydrogen, and equipped with inlet and outlet fittings, while the input fitting of the auxiliary gas chamber is connected via an alternating choke to the output of the auxiliary gas flow stabilizer, and the output fitting of this chamber - with a measuring chamber of a thermoconductometric detector, a column made in the form a metal tube, the input of which is connected to the output of the dispenser, and the output to the input fitting of the analyzed gas chamber, the output fitting of which is connected to the atmosphere, and a unit for measuring and recording the signal of the thermoconductometric detector. The analyzer further comprises a hydrogen flow stabilizer and a comparative diffusion cell, wherein the input nozzle of the auxiliary gas chamber of the comparative diffusion cell is connected through an alternating orifice to the outlet nozzle of the auxiliary gas flow stabilizer, and the inlet of the analyzed gas chamber through an alternating orifice is connected to the outlet of the hydrogen flow stabilizer, to to which the metering input is also connected, while the output fitting of the auxiliary gas chamber of the comparative diff the ionization cell is connected to the comparative chamber of the thermoconductometric detector, and the outlet fitting of the analyzed gas chamber is connected to the atmosphere.

Description

The utility model relates to the field of analytical technology, namely, to measuring instruments, the concentration of hydrogen of multicomponent hydrogen-containing gas environments.

A known analyzer of the concentration of hydrogen in gaseous media (Farzan N.G., Ilyasov L.V., Azim zade A.Yu. Technological measurements and instruments. M: Higher school, 1989, S.301-302), containing a diffusion cell, consisting of auxiliary and analyzed gas chambers separated by a palladium-silver alloy membrane selectively permeable to hydrogen and provided with inlet and outlet fittings, as well as an additional flow chamber connected to the inlet of the auxiliary gas chamber., thermoconductometric detector OR, the comparative thermistor of which is located in the additional chamber, and the measuring thermistor is in the auxiliary gas chamber of the diffusion cell, and the unit for measuring and recording the detector signal.

During operation of the analyzer, only hydrogen diffuses through the membrane from the chamber of the analyzed gas, which is added to the auxiliary gas stream washing the measuring thermistor. This causes a change in the resistance of the thermistor, which is measured and recorded by the measuring and recording unit. It serves as a measure of the concentration of hydrogen in the analyzed gas medium.

The disadvantage of this analyzer is the need to use brittle and expensive membranes made of an alloy of palladium with silver and the lack of the ability to control the drift of the initial signal level of a thermoconductometric detector, which causes a noticeable additive error.

The closest in technical essence is the analyzer of hydrogen concentration in gaseous media (Ilyasov L.V., Sulman E.M., Sulman M.G. et al. Utility Model Patent No. 38945, Bull. No. 19, 2004 “Selective Analyzer volume concentration of hydrogen in gases ”), containing a measuring diffusion cell, consisting of auxiliary and analyzed gas chambers, separated from each other by a membrane selectively permeable to hydrogen, and equipped with input and output fittings, while the input fitting of the auxiliary chamber g is connected through an alternating throttle to the output of the auxiliary gas flow stabilizer, and the output fitting of this chamber to the measuring chamber of the thermoconductometric detector, a column made in the form of a metal tube, the input of which is connected to the output of the dispenser, and the output to the input fitting of the analyzed gas chamber, the output the nozzle of which is connected to the atmosphere, and the unit for measuring and recording the signal of the thermoconductometric detector.

This analyzer uses a polymer membrane with selective hydrogen permeability.

During the operation of such an analyzer, auxiliary gas flows (nitrogen or air) flow at constant rates through the chambers of the diffusion cell, as well as the measuring and comparative chambers of the thermoconductometric detector. Using a dispenser, a sample constant in volume is introduced into the gas stream flowing through the chamber of the analyzed gas with a syringe

analyzed hydrogen-containing gas. This sample is transported by a stream of auxiliary gas to the membrane. The hydrogen contained in the sample diffuses through the membrane into the auxiliary gas chamber of the diffusion cell. In this case, the diffusion flow of hydrogen through the membrane is proportional to the concentration of hydrogen in the sample of the analyzed gas medium. The diffused hydrogen molecules are picked up by the auxiliary gas stream flowing through the auxiliary gas chamber and transported by this stream to the measuring chamber of the thermoconductometric detector. The appearance of hydrogen in the measuring chamber causes a signal from a thermoconductometric detector, which has a peak shape, and the amplitude of this signal is proportional to the concentration of hydrogen in the analyzed gas medium.

The disadvantage of this analyzer is the significant error in measuring the hydrogen concentration at large (80-95% vol.) Its values in the analyzed gas environment, which complicates the use of the analyzer in systems for monitoring the concentration of hydrogen in hydrogen-containing gas environments of technological processes associated with the production of high-octane gasolines.

The objective of the utility model is to improve the design of the analyzer of the concentration of hydrogen in gaseous media, aimed at increasing its accuracy.

The technical result is the creation of a high-precision analyzer of the concentration of hydrogen in gaseous media.

The technical result is achieved by the fact that the analyzer of the concentration of hydrogen in gaseous media, containing a measuring diffusion cell, consisting of auxiliary and analyzed gas chambers, separated from each other by a membrane selectively permeable to hydrogen, and equipped with input and output

nipples, while the input nozzle of the auxiliary gas chamber is connected through an alternating throttle to the output of the auxiliary gas flow stabilizer, and the output nozzle of this chamber is connected to the measuring chamber of the thermoconductometric detector, a column made in the form of a metal tube, the input of which is connected to the output of the dispenser, and the output is to the input fitting of the analyzed gas chamber, the output fitting of which is connected to the atmosphere, and the unit for measuring and recording the signal of the thermoconductometric detector, according to the useful meter Delhi additionally contains a hydrogen flow stabilizer and a comparative diffusion cell, wherein the input nozzle of the auxiliary gas chamber of the comparative diffusion cell is connected through an alternating orifice to the outlet nozzle of the auxiliary gas flow stabilizer, and the inlet of the analyzed gas chamber through an alternating orifice is connected to the outlet of the hydrogen flow stabilizer, to which the metering input is also connected, while the output fitting of the auxiliary gas chamber is comparatively diffusion th cell is connected to the reference chamber thermal conductivity detector and the output of the sample gas chamber fitting - with the atmosphere, the comparative diffusion cell identical in construction diffusion measuring cell.

This design allows you to increase the accuracy of measuring the concentration of hydrogen due to the fact that it provides its determination by the difference between 100% vol. and the total volumetric concentration of impurities in a hydrogen-containing gas. This is ensured by the presence of a comparative diffusion cell and its differential inclusion together with the measuring diffusion cell in the measuring circuit of the analyzer.

Compared with the prototype of the claimed design has a distinctive feature in the combination of elements and their relative position.

A diagram of an analyzer of the concentration of hydrogen in gaseous media is shown in FIG.

The analyzer contains a measuring diffusion cell 1, consisting of an auxiliary gas chamber 2 and an analyte gas chamber 3, separated from each other by a membrane 4 selectively permeable to hydrogen. Chambers 2 and 3 are equipped with input 5 and 6 and output 7 and 8 fittings. The inlet nozzle 5 of the auxiliary gas chamber through an alternating inductor 9 is connected to the output 10 of the auxiliary gas flow stabilizer 11, and the outlet nozzle 7 of this chamber is connected to the measuring chamber 12 of the thermoconductivity detector 13. The analyzer also contains a column 14 made in the form of a metal tube, the input 15 of which connected to the output 16 of the dispenser 17, and the output 18 to the input fitting 6 of the chamber 3 of the analyzed gas. The outlet fitting 8 of this chamber is connected to the atmosphere. The thermoconductivity detector 13 is connected to the measuring and recording unit 19. In addition, the analyzers of the concentration of hydrogen in gaseous media include a flow rate stabilizer 20 and a comparative diffusion cell 21, similar in design and characteristics to the measuring diffusion cell. The comparative cell contains chambers 22 and 23, separated by a membrane 24 and equipped with input 25 and 26 and output 27 and 28 fittings. The inlet fitting 25 is connected through an alternating orifice 29 to the output 10 of the auxiliary gas flow rate stabilizer 11, the inlet 26 through an alternating orifice 30 is connected to the outlet 31 of a hydrogen flow stabilizer 20, to which the inlet 32 of the dispenser 17 is also connected. Outlet 27

connected to the comparative chamber 33 of the thermoconductivity detector 13, and the output fitting 28 to the atmosphere.

The work of the analyzer of the concentration of hydrogen in gaseous media is as follows.

The analyzer has two operating modes “Preparation” and “Analysis”. In the “Preparation” mode, from flow stabilizers 11 and 20 to the chambers 5 and 23, as well as 3 and 22, flows of auxiliary gas (nitrogen, air) and hydrogen are supplied with constant flow rates. Moreover, in measuring 1 and comparative 21 diffusion cells, diffusion occurs through hydrogen membranes 4 and 24 from chamber 3 to chamber 2 and from chamber 22 to chamber 23. Since the characteristics of membranes 4 and 24 are the same, the diffusion flows of hydrogen from chambers 3 and 22 cameras 2 and 23 are also the same. These flows in the chambers in chambers 2 and 23 are mixed with the auxiliary gas flows entering these chambers. In this case, the concentrations of hydrogen in the gas flows entering the measuring 12 and comparative 33 chambers of the thermoconductivity detector 13 are almost the same. Therefore, the value of its sigal is close to zero. This signal is recorded by block 19 and is taken as the initial signal level of the analyzer. The “Preparation” mode lasts 10-20 s.

In the “Analysis” mode, into which the analyzer is transferred manually or using a command device, with a dispenser 17, a constant volume sample of the analyzed hydrogen-containing gas medium is introduced into the stream of hydrogen flowing through the tube 14 (sample volume 1.5-5 ml.). This sample is transported through the tube 14 and through a fixed time interval necessary to complete the transient processes caused by the switching of the dispenser channels, enters the chamber 3. Since the concentration of hydrogen in the sample is less than in the hydrogen stream, the diffusion flow of hydrogen from chamber 3 to chamber 2 will decrease. Moreover, its decrease is proportional to the total concentration

impurities contained in the analyzed in a hydrogen-containing medium. This leads to a decrease in the hydrogen concentration in the flow entering the measuring chamber 12 of the thermoconductivity detector 13. Since a gas flow with a constant hydrogen concentration enters the comparative chamber 33 of this detector, this causes a signal of the thermoconductometric detector having a peak shape whose amplitude is proportional to the volume concentration of impurities With _P in a hydrogen-containing gas medium. The hydrogen concentration is defined as the difference of 100% vol. - With _P % vol. The information display device of block 19 is calibrated directly in the values of volumetric hydrogen concentration.

During automatic operation of the analyzer in each analysis cycle, the “Preparation” and “Analysis” modes are repeated.

In the implemented analyzer layout, the following values of the operational parameters were adopted:

- volumetric flow rate of hydrogen - 3 l / h;

- volumetric flow of nitrogen - 3 l / h;

- sample volume - 1.5-5.0 ml. (selected depending on the concentration of the impurity);

- temperature - 45 ° C;

- consumption of the analyzed gas - 15 l / h;

- the time of one analysis cycle is 2-3 minutes.

In this case, the error in measuring the concentration of hydrogen was 0.2-0.5% vol. (against 1-2% vol. for the prototype), that is, decreased by 4-5 times.

The advantage of the proposed technical solution is:

- simplicity of design and operation;

- high accuracy;

- expressness of analysis.

The proposed analyzer can be created on the basis of serial laboratory and industrial chromatographs.

The analyzer can be used to control gas flows of hydrogen-containing gas media at the enterprises of the oil refining and petrochemical industries.

Claims (2)

1. An analyzer of the concentration of hydrogen in gaseous media, comprising a measuring diffusion cell, consisting of auxiliary and analytic gas chambers, separated from each other by a membrane selectively permeable to hydrogen, and equipped with inlet and outlet fittings, while the input fitting of the auxiliary gas chamber is connected through an alternating a throttle with the output of the auxiliary gas flow stabilizer, and the output fitting of this chamber with the measuring chamber of the thermoconductometric detector, a column made in ide metal tube, the input of which is connected to the output of the dispenser, and the output to the input fitting of the analyzed gas chamber, the output fitting of which is connected to the atmosphere, and a unit for measuring and recording the signal of the thermoconductometric detector, characterized in that the analyzer further comprises a hydrogen flow stabilizer and a comparative diffusion cell, and the inlet chamber of the auxiliary gas chamber of the comparative diffusion cell is connected through an alternating choke to the outlet nozzle of the flow stabilizer gas, and the inlet chamber of the analyzed gas through a variable choke is connected to the outlet of the hydrogen flow stabilizer, to which the dispenser inlet is also connected, while the outlet nozzle of the auxiliary gas chamber of the comparative diffusion cell is connected to the comparative chamber of the thermoconductometric detector, and the outlet nozzle of the chamber of the analyzed gas - with the atmosphere. 2. The analyzer of the concentration of hydrogen in gaseous media according to claim 1, characterized in that the comparative diffusion cell is identical in design to the measuring diffusion cell.