SU1226305A1 - Gas chromatograph - Google Patents

Abstract

The invention relates to gas analysis of trace contaminants in the air. The aim of the invention is to increase the efficiency of separation of microimpurities by reducing the smearing of the front of the substances to be separated and the reduction of dead volumes. The device contains a source of carrier gas, a faucet-switch, a vaporizer with two evaporation chambers, a separation column and a concentrator installed in one from the evaporation chambers, the tap-switch being installed between the outlets from both evaporation chambers and the entrance to the separation column so that it either connects the output of the first chamber with column-inflammatory or soedi- n g t-two chambers in series and the output of the second evaporation chamber with the separation column. 2 Il. C (L ND GcE 05 00

Description

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The invention relates to the field of gas chromatography, in particular, to chromatographic circuits for analyzing trace impurities of substances in air, and can be used to control the gas composition of air.

The purpose of the invention is to increase the efficiency of the separation of microimpurities by reducing the front erosion by splitting substances, reducing dead-fCI output volumes and stabilizing temperature regimes when switching flows,

On . 1 shows the gas chromatograph scheme; FIG. 2 - evaporator with two chambers.

The gas chromatograph contains an enrichment column 1, connected by means of a four-way gas valve 2 through an evaporator 3. having two evaporation chambers 4 and 5, to a chromatographic column 6 for separating microimpurities 5 located in the thermostat 7 of the chromatograph. The output of the chromatographic column 6 is connected to the detector 8, the direction of movement of the carrier gas in the diagram is shown by arrows.

A gas metering tap chromatograph of the Tsvet-100 series, in which two gas channels are closed, was used as a four-way gas crane. The diagram in solid lines shows the position of the gas valve Before analysis, the dotted position of the gas valve Analysis.

The proposed gas chromatograph in the course of performing analysis of trace substances in air works as follows.

In the position of the four-way gas valve. Prior to analysis, the carrier gas passes through the evaporation chamber 4, (the gas position: indicated

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The gas column KpaE-ia vaporization chamber 5 is free of carrier gas flow and contains a concentration column 1 containing concentrated microlumber, after which the vaporization chamber 5 is sealed

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lines), the evaporation chamber 5 with the concentration column 1, again through the gas valve 2 and the chromatographic column 6. In this position of the gas valve, the microimpurities, desorbed in the evaporation chamber 5, are transferred by a flow of carrier gas from the enrichment ( ; flax column 1 in chromatography column 6 for separation and subsequent detection on detector 8.

The positive effect of the image was confirmed by studies of the efficiency of chromatographic separation in the process of analysis of benzene and methylzethylketone trace impurities in the air using the proposed and known devices, as well as by the gas scheme with direct injection of the analyzed substances into the chromatograph evaporator. The efficiency of the chromatographic column on methyl ethyl ketone and the degree of separation of benzene and methyl ethyl ketone using the proposed gas chromatograph were 1270 tons. and 0.97, respectively, and for direct input of an equal amount of analyzable substances to the chromatograph evaporator, the indicated values turned out to be equal to 1250 tons. and 0.96, respectively. The efficiency of the column and the degree of separation of these substances using the known gas scheme are equal to 860 tons, and 0.71 correspondingly: o, which is significantly lower than the results obtained according to the invention. Thus, the use of the proposed gas scheme of the chromatograph for the analysis of trace impurities in air, as compared with the known, allows to significantly increase the efficiency of chromatographic separation in the process of analyzing trace impurities in air. The proposed gas scheme can be used as a variant of the gas scheme for the analysis of microimpurities in Tsvet-100 series gas chromatographs.

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Claims (1)

Invention Formula A gas chromatograph containing a successively installed source of carrier gas, a switch valve, a concentration column, a vaporizer with two evaporation chambers, a separation column and a detector, differing from the fact that, in order to increase the efficiency, it is closed (FIG. 2) 3 position of the gas tap Analysis of the carrier gas passes through the evaporation chamber .4, gas tap 2 (the position of the gas tap in Fig. 1 is indicated by dashed lines). Invention Formula A gas chromatograph containing a successively installed source of carrier gas, a switch valve, a concentration column, a vaporizer with two evaporation chambers, a separation column and a detector, differing from the fact that, in order to increase the efficiency of dividing the micronoids by reducing the smearing of the front of the separated substances and reducing the dead volumes and stabilizing temperature regimes when switching flows, the source of carrier gas is connected to the inlet of the first evaporator chamber; Carrier gas evaporation chambers and the entrance to the separation column in such a way that in one position the tap switch connects the output of the first evaporator chambers to the separation column, and in the second position during desorption, it connects both evaporator chambers in series, and the output of the second evaporator chamber connects with the separator column. 1 Carrier gas