RU2288468C1 - All-purpose detection sorption piezo cell - Google Patents

Abstract

FIELD: chemical engineering.

SUBSTANCE: device has cylindrical casing having two tubes arranged in perpendicular to each other, cover for fastening holders arranged in circle for supporting a number of sensors provided with film-coated sorbents, units for exciting oscillations and recording piezosensor signals. Holders for fixing nine piezosensors provided with sorbents having various film coatings. The cylindrical casing part has additional tube. All cylindrical casing part tubes are arranged in diametrically opposite directions, one being placed near casing base and another one at the piezosensor level. The cover having units for exciting oscillations and recording piezosensor signals is covered with soft protection envelope.

EFFECT: increased information amount in recognizing visual imprints; enhanced effectiveness in analyzing multi-component gas and liquid media mixtures in dynamic and static modes.

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Description

The invention relates to analytical chemistry and is used to analyze gaseous media containing organic compounds.

The closest in technical essence and the achieved effect is a matrix piezosorption detection cell, consisting of a housing with nozzles, inside which there are a number of sensors with various film coatings for fixing the main components of the gas mixture, devices for exciting oscillations and recording sensor signals. The cell body is made in the form of a cylinder with a cover on which holders for six sensors are arranged in a circle, a nozzle for introducing a liquid mixture is perpendicular to the nozzle for introducing a gaseous mixture, a removable substrate is located in the lower part of the cylindrical body, and the nozzles are equipped with polyurethane gaskets and the cover is connected to the cylindrical body by means of a thread, while the removable substrate used for the analysis of liquid mixtures is made of glass or other inert material in the form of convex disk with a diameter corresponding to the diameter of the cylindrical cell body [Pat. RU 2212657, Matrix piezosorption detection cell [Text] / Kuchmenko TA, Shlyk Yu.K., Korenman Ya.I. 2003. - No. 26 (Part III). - S.629].

The disadvantages of the known detection cell are:

- analysis of the gas phase of multicomponent mixtures only in static mode;

- the presence of only six measuring elements does not give sufficiently informative results, which increases the likelihood of making an erroneous decision;

- fixing responses in a certain sequence requires the development of a specific algorithm for polling sensors

The technical task of the invention is to increase the number of measuring elements; the ability to analyze the gas phase of complex multicomponent mixtures of gaseous and liquid samples; the ability to conduct analysis in both dynamic and static modes.

The technical task of the invention is achieved in that in a universal piezosorption detection cell, consisting of a cylindrical body with two nozzles arranged perpendicular to each other, a lid on which holders for a number of sensors with various film coatings of sorbents, devices for exciting oscillations and fixing signals are attached in a circle of piezosensors, new is that on the lid in a circle there are holders for nine piezosensors with various film coatings of sorb ents; the cylindrical part of the housing is equipped with an additional nozzle, and the nozzles of the cylindrical part are located in diametrically opposite directions - one at the base of the cell, the other at the level of the piezosensors; the cover with devices for exciting oscillations and fixing the signals of the piezosensors is closed with a protective cover.

The technical result consists in increasing the number of measuring elements; the possibility of analyzing the gas phase of complex multicomponent mixtures of gaseous and liquid samples; analysis capabilities in both dynamic and static modes.

The universal piezosorption detection cell (FIGS. 1, 2) is a hollow cylinder (1) with two nozzles (2) and (3) located perpendicular to each other, a cover (4) and a removable base (5), which simplifies preparation (removal traces of organic compounds) of the reaction vessel for the following measurements, in the center of which a pipe (3) is located. On the cover (4) there are panels (6) for mounting nine sensors (7). To ensure the tightness of the connection of the cover and the base with the cylinder, there are two rubber rings (8). The outer cylindrical part of the housing is equipped with an additional pipe (9). Pipes (2) and (9) are directed in diametrically opposite directions. The pipe (9) is located at the base of the cell, and the pipe (2) at the level of the piezosensors. This arrangement of the nozzles provides a more efficient ventilation of the reaction vessel after measurements. The nozzles are closed with clamping plugs (10 - with a puncture hole, 11 and 12 - blind) and polyurethane gaskets (13) - 3 pieces by means of a threaded connection, creating the necessary tightness of the system.

A universal piezosorption detection cell operates as follows.

To analyze the gas phase of liquid samples (whey) in static mode, crystal generators (14) - 9 pieces are connected to the cover (4) of the detection cell to excite oscillations of nine piezosensors and closed with a protective cover (15) (Fig. 3). The pipe (3) is used to enter the sample. A syringe piercing a polyurethane gasket (13) through a hole in the pressure plug (10) introduces a certain volume of the equilibrium gas phase of the multicomponent liquid mixture. In this case, the nozzles (2) and (9) are hermetically closed (Fig. 4). To analyze the gas phase of volatile liquids: gasolines, aromatic (benzene, toluene, ethylbenzene) and normal saturated hydrocarbons (C ₅ -C ₁₀ ), a certain volume of sample is taken with a syringe in liquid form and injected through a pipe (9). In this case, the nozzles (2) and (3) are hermetically closed. Getting on a removable base (5), the liquid sample evaporates and passes into the gas phase, ensuring uniform distribution of the analyzed sample throughout the volume of the reaction vessel, as well as reproduction of the sorption front with each subsequent measurement (figure 5).

To analyze the gas phase of liquid samples (whey, liquid hydrocarbon fuels, aromatic and saturated hydrocarbons of normal structure) in dynamic mode, air saturated with the pairs of the analyzed sample passes continuously through the detector. A crystal oscillator (14) is attached to the cover (4) of the detection cell — 9 pieces to excite the oscillations of nine piezosensors and close with a protective cover (15) (Fig. 3). The nozzles (2) and (9) are open, the nozzle (3) is closed (Fig.6). At the inlet and outlet of the reaction vessel, flow meters of the PC type (not shown in FIG.) Are installed to vary the flow rate of the supplied air into the cell (at the inlet) and to control the tightness of the gas transmission system as a whole (at the outlet). With stable operation of the installation, the readings of both rotameters are the same. Saturation of air with the vapors of the analyzed sample is carried out using finely porous spraying (bubbling). The flow direction of the carrier gas from the bottom up ensures a uniform supply of the analyte vapor to the surface of the piezosensor electrodes. Sensor responses are recorded automatically.

After the measurements, the sorption coating is regenerated with dried laboratory air and the reaction vessel is vented.

Sensor responses are recorded simultaneously from all sensors and transmitted for further processing to a computer. The “visual imprint” of the analyzed sample is formed as a result of a survey of nine piezosensors with various sorbent films. Each type of sample corresponds to a characteristic geometric image of a “visual imprint”. Recognition and identification of the analyzed sample, qualitative and quantitative analysis of the sample are carried out by comparing the "visual fingerprints" of the smell of the test sample and the standard sample using the methodology of artificial neural networks.

A comparison of some characteristics of the proposed technical solution and the analogue is presented in the table.

Table
Comparative parameters of the proposed cell and prototype Comparison options Technical solution Analogue Dynamic gas phase analysis of samples Available Impossible Sensor Response Logging Does not require a specific individual algorithm According to a specific individual algorithm Number of sensors 9 6

The proposed universal piezosorption detection cell by increasing the number of measuring elements with various film coatings allows you to obtain more complete information necessary for the recognition of "visual imprint"; analyze the gas phases of complex multicomponent mixtures of gaseous and liquid samples; conduct analysis in both dynamic and static modes.

Claims (1)

A universal piezosorption detection cell, consisting of a cylindrical body with two nozzles perpendicular to each other, a lid on which holders for a number of sensors with various film coatings of sorbents, devices for exciting oscillations and fixing signals of piezosensors are mounted in a circle, characterized in that on the lid in a circle there are holders for nine piezosensors with various film coatings of sorbents, the cylindrical part of the housing is equipped with lnym nozzle, wherein the nozzles of the cylindrical portion are located in diametrically opposite directions - one at the bottom of the cell, another level pezosensorov lid with means for the excitation of oscillations and fixing pezosensorov signal closes the protective cover.

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