RU189684U1 - GAS CHROMATOGRAPH - Google Patents

Abstract

The invention relates to an analytical technique, namely, to chromatographic analyzers for the composition of gaseous and liquid media. The gas chromatograph contains a carrier gas flow stabilizer equipped with an outlet fitting, a serial connection of a dispenser equipped with an inlet fitting, an evaporator of liquid media, a chromatographic column and a gas detector with an evaporator outlet and chromatographic column inlet, and the outlet of this column and gas detector inlet capillary tubes, a variable choke with inlet and outlet fittings and a tee, the variable choke through the inlet fitting connected to the capillary tube, connecting The evaporator is equipped with an inlet of a chromatographic column, and the outlet of this choke is connected via a tee to a capillary tube connecting the chromatographic outlet to the gas detector inlet, the chromatograph also contains two additional chokes and an additional tee, while the additional tee inlet carrier, and its two outputs are connected to the inputs of additional variable chokes, the output of one of which is connected to the tee, and the output of the other - to the input fitting dispenser. The technical result is an increase in the accuracy of gas chromatographic analysis of the composition of gaseous and liquid multicomponent media. 2 Il.

Description

The invention relates to an analytical technique, namely, to chromatographic analyzers for the composition of gaseous and liquid media.

Known gas chromatograph (Stolyarov B.V., Savinov I.M., Vitenberg A.G. Guide to practical work on gas chromatography. - M .: Chemistry, 1978 - P. 12), containing a carrier gas flow stabilizer, the output fitting of which sequentially downstream of the latter is connected to the dispenser, the evaporator of the sample of the liquid analyzed medium, the chromatographic column and the gas detector, the evaporator and the inlet of the chromatographic column, as well as the outlet of this column and the detector inlet are connected by capillary lines.

During the analysis, a sample of the analyzed medium, constant in volume, is introduced by a dosing unit into the chromatographic column. Moreover, the sample of liquid analyzed medium is preliminarily evaporated. The multicomponent analyte medium, which has entered the chromatographic column in the gas phase, is transported through it by the carrier gas and is divided into separate components, which, entering the gas detector, cause its signal. This signal is used to obtain information about the composition of the analyzed gaseous or liquid medium.

The disadvantage of this gas chromatograph is the low accuracy of obtaining measurement information on the concentration of components in the analysis of the composition of liquid media, determined by the fact that when the composition of the analyzed medium changes, the volume of this medium vapor after evaporation changes, which significantly complicates the analysis and requires for the correct calculations to obtain a complete chromatogram of the analyzed environment, but even in this case allows you to get information about the concentrations of components only in the gas phase. In cases where it is not possible to obtain a complete chromatogram, the determination of the concentration of components can be performed only approximately even after an absolute calibration of the gas chromatograph.

The closest to the technical essence of the solution is a gas chromatograph (RF patent 84123 U1, 06/27/2009) containing a carrier gas flow stabilizer, equipped with an outlet fitting, a serial connection of a dispenser equipped with an inlet fitting, an evaporator of liquid media, a chromatographic column and a gas detector, the evaporator outlet and the chromatographic column inlet, as well as the outlet of this column and the gas detector inlet are connected by capillary tubes, a variable choke with inlet and outlet fittings and a tee, , The variable throttle via the inlet fitting connected to the capillary tube, connecting the evaporator with the chromatographic column inlet, and the outlet nipple of the tee is connected via a throttle to the capillary tube, connecting the outlet of the chromatographic column with the inlet of the gas detector.

In the process of analysis, a sample of the analyzed medium is introduced into the carrier gas stream with a dosing unit, and the sample of the liquid medium is preliminarily evaporated before entering the chromatographic column. A gas sample or vapor of a liquid sample is transported by a carrier gas stream to the chromatographic column and to a variable choke, the Opening degree of which is selected when adjusting the chromatograph. One part of the sample, which is in the gaseous state, after passing through the throttle enters the tee, is picked up by the carrier gas flow coming from the additional flow stabilizer, and is transported to the gas detector, causing the first pulse signal, whose area is proportional to the mass of the sample analyzed. The second part of the sample is divided into separate components on the chromatographic column, and the pulse signals of the gas detector that arise in this case carry information about the masses of the individual components of the medium being analyzed. The received signals are used to calculate the mass concentrations of the individual components.

The disadvantage of such a gas chromatograph is the possibility of changing the sensitivity (conversion factor) of its detector, associated with the error in maintaining the flow rates of the carrier gas coming from the flow stabilizers, which ultimately leads to an increase in the error in obtaining measurement information on the concentrations of components during chromatographic analysis.

The task of the utility model is to create a gas chromatograph, in which the conversion coefficient of the detector is invariant to changes in the flow rate of the carrier gas.

The technical result is an increase in the accuracy of gas chromatographic analysis of the composition of gaseous and liquid multicomponent media.

The technical result is achieved by the fact that a gas chromatograph containing a carrier gas flow stabilizer, equipped with an outlet fitting, a serial connection of a dispenser equipped with an inlet fitting, an evaporator of liquid media, a chromatographic column and a gas detector, which has an evaporator outlet and an inlet of the chromatographic column, as well as This column and the gas detector inlet are connected by capillary tubes, a variable choke with an inlet and an outlet choke and a tee, moreover, a variable choke through the input piece The cer is connected to a capillary tube connecting the evaporator to the inlet of the chromatographic column, and the outlet of this choke is connected via a tee to the capillary tube connecting the outlet of the chromatographic column to the inlet of the gas detector, according to the utility model also contains two additional chokes and an additional tee; the tee is connected to the output fitting of the carrier gas flow stabilizer, and its two outputs are connected to the inputs of additional variable chokes, the output of one of which is connected to the tee, and the output of the other - to the inlet fitting of the dispenser.

This design allows gas flows to the chromatographic column and a tee connected to a variable choke from one flow regulator through an additional tee and two additional variable chokes. This virtually eliminates the change in sensitivity (conversion factor) of the gas chromatograph detector, since possible errors in maintaining the flow rate with one stabilizer equally affect the error in maintaining carrier gas flow rates through the chromatographic column and through the tee, and this makes it possible to increase the accuracy of gas chromatographic analysis of the composition of gaseous and liquid media.

FIG. 1 shows a gas chromatograph scheme; in fig. 2 - chromatogram.

The gas chromatograph contains a stabilizer of the flow rate of the carrier gas 1, equipped with an outlet nozzle 2, a serial connection of the dispenser 3, equipped with an inlet nozzle 4, an evaporator of liquid media 5, a chromatographic column 6 and a gas detector 7, which has an evaporator outlet 8 and an inlet 9 of the chromatographic column Also, the output of this column 10 and the inlet 11 of the gas detector 7 are connected to capillary tubes 12 and 13, a variable choke 14 with an input 15 and an output 16 chokes and a tee 17, and the variable choke 14 is connected via an input choke 15 a capillary tube 12 connecting the evaporator 5 to the inlet 9 of the chromatographic column 6, and the outlet 16 of this choke is connected via a tee 17 to the capillary tube 13 connecting the outlet 10 of the chromatographic column to the inlet 11 of the gas detector 7. The gas chromatograph also contains two additional chokes 18, 19 and an additional tee 20, while the input 21 of an additional tee 20 is connected to the output fitting 2 of the carrier gas flow regulator 1, and its two outputs are connected to the inputs 22 and 23 of additional variable chokes 18 and 19 The output 24 of the variable choke 19 is connected to the tee 17, and the output 25 of the variable choke 18 is connected to the inlet 4 of the dispenser 3. All elements of the gas chromatograph are located in the thermostat 26. As a gas detector in the chromatograph are used: flame ionization detector (Farzane N.G. . and others. "Automatic detectors of gases and liquids" - M .: Energoatomizdat, 1983, p. 70-72) or a multi-thermistor thermochemical detector (L. Ilyasov. Utility Model Patent of the Russian Federation No. 184021 Thermochemical Gas Detector, Bull. 29, 2018). These detectors are sensitive to molecular weight, and, consequently, to the density in the gas phase and the mass of detected substances. The signal areas of these detectors can be described by the expression:

where: K - conversion factor;

m _i is the mass of the i-th component.

The work of the gas chromatograph is as follows

Using the dispenser 3 in the flow of carrier gas generated by the flow rate stabilizer 1, is introduced a sample of the analyzed medium. A sample of the liquid analyzed medium when entering the evaporator 5 turns into steam. The gas sample or vapors of the liquid sample are transported by the carrier gas stream to the chromatographic column 6 and variable choke 14, the opening degree of which is selected when the chromatograph is adjusted. One part of the sample, which is in the gaseous state, after passing through the throttle 14 enters the tee 17, is picked up by a flow of carrier gas leaving the additional throttle 19, and is transported to the gas detector 7, which produces the first pulse signal (see Fig. 2). The area of this signal S _{a is} described by the expression:

where: K _d - the division ratio of the flow divider, composed of chromatographic column 6 and variable choke 14;

m is the mass of the sample of the analyzed medium.

The second part of the sample, which is in the gaseous state, enters the chromatographic column 6, where due to the repeated repetition of sorption and desorption events occurring on the sorbent filling the column 6, they are gradually divided into separate components.

Upon receipt of the individual components in the gas detector 7, pulsed signals appear (see Fig. 2), the areas of which are described by expression (1).

After completion of the analysis, the mass concentration of any component is determined as follows. Using expressions (1) and (2), we can write:

where: α _i is the mass concentration of the i-th component from the analyzed medium.

From the expression (3) we find:

To determine the value of the coefficient for the adopted scheme and the operating mode of the gas chromatograph, an analysis of the reference gaseous or liquid substance is carried out, and then from the relation:

where: S _e - the signal area of the reference substance generated by its mass entering the detector from chromatographic column 6;

S _EA - the signal area of the reference substance generated by its mass entering the detector from a variable choke 14.

The coefficient K _d when this is determined from the expression:

Using expressions (4) and (6), we find:

As follows from the expression (7), the proposed gas chromatograph allows to determine the mass concentrations of the components of gaseous and liquid media, both with full and incomplete chromatograms, since expression (7) is valid for all types of chromatograms.

The advantage of the proposed technical solutions are:

- the possibility of obtaining measurement information on the mass concentrations of the components of the gaseous and liquid media being analyzed for any types of chromatograms;

- no need for laborious and complex absolute component-wise calibration of the gas chromatograph;

- eliminating the need for accurate dosing of samples of the analyzed medium.

The proposed gas chromatograph can be implemented on the basis of any standard laboratory or industrial gas chromatograph and a small number of additional elements widely used in chromatographic practice.

The proposed gas chromatograph can be widely used in the practice of laboratory and industrial analysis of the composition of multicomponent gaseous and liquid media.

Claims (1)

A gas chromatograph containing a carrier gas flow stabilizer, equipped with an outlet fitting, a serial connection of a dispenser equipped with an inlet fitting, an evaporator of liquid media, a chromatographic column and a gas detector with an evaporator outlet and chromatographic column inlet, as well as an outlet of this column and a gas detector input connected by capillary tubes, a variable choke with an inlet and an outlet choke and a tee, the variable choke being connected through an inlet choke to the capillary tube, connecting an evaporator with an inlet of the chromatographic column, and the outlet of this choke is connected via a tee to a capillary tube connecting the chromatographic outlet to the gas detector inlet, wherein the chromatograph also contains two additional chokes and an additional tee, while the additional tee input is connected to the output to the fitting of the carrier gas flow stabilizer, and its two outputs are connected to the inputs of additional variable chokes, the output of one of which is connected to the tee, and in The output of the other - to the input fitting dispenser.

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