SU868584A1 - Impurity concentrator for gas chromatograph - Google Patents

Description

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The invention relates to chromatography and will find application in gas processing and chemical industries to determine the amount of impurities in gas-like substances.

Impurity concentrators for gas chromatographs are known for the purpose of accumulating impurities, concentrating them, and introducing them to a progressive chromatographic analysis.

These concentrators contain a cumulative column filled with an adsorbent installed in a thermostat with column heating and cooling devices, the cumulative column inlet is connected to the source of the analyzed gas and the carrier gas line, and the outlet is connected to the chromatographic analyzer and the discharge line. A sample of the gas to be analyzed is introduced into a cumulative column located in the chamber with a refrigerant, where some impurities accumulate in the gas being analyzed and are adsorbed on the cooled adsorbent of the cumulative column better than the main component. At the end of the sample introduction, the cumulative column is smoothly transferred from the cold zone to the thermal,

stat in the warm. Under the action of the thermal floor, thrust on the column from the input end, the impurities are desorbed and concentrated in the carrier gas stream,. squeezing into a narrow strip at the exit of the cumulative column, and then entered into a fl chromatographic analyzer

and 1: 2.

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However, such reactive concentrators, due to the presence of only one storage column filled with a specific type of adsorbent, allow only a narrow circle to be concentrated.

15 substances, and due to the presence of two temperature zones and moving storage columns that are irrational in shape and size, have a complex structure, low reliability and

20 accuracy.

The closest in technical essence to the present invention is a concentrator containing accumulative pegs filled with an adsorbent.

25 ki, made in the form of sections and installed in a thermostat equipped with a heat-insulated casing and devices for heating and cooling the storage columns / one 30 input from the columns, is connected through valves

the line of the gas to be analyzed and the ini-carrier gas connected via a valve to the inlet of the second inflation column, the output of which is connected through valves to the cast line and a chromatographic analyzer connected through the valve to the output of the first storage column C3}.

In this concentrator, accumulator columns made in the form of an arc. Circles, when accumulated, are placed in a tank with refrigerant, and when concentrated by means of a drive mechanism, they are transferred to the heated zone, moving in the heater air gap.

The disadvantages of such a concentrator are complex and unreliable construction, which is explained by the presence of rotating accumulator columns equipped with a moving mechanism, wear-and-rubbing parts and unreliable seals in the moving parts of the gas lines of the accumulation columns. temperature zones with a large temperature difference (from -19-6 to + 300 ° Сj and considerable power of the heater necessary for fast warming up of the storage columns moving in the air gap of the heater, as well as low accuracy due to incomplete desorption of impurity components during column heating and smearing of impurity bands in accumulation columns during concentration, which is caused by slow heating of the moving columns in the heater air gap and inconsistency between the carrier gas speed, column rotation speed and heating rate of the sections entering the heater cumulative columns.

The purpose of the invention is to simplify the design, increase the reliability and accuracy of the concentrator.

This relay is achieved by the fact that in a known concentrator for a gas chromator, containing accumulation columns filled with adsorbents, made in sections and installed in a thermostat fitted with heat-insulated housing and heating and cooling devices of the accumulation columns, the input of one of the columns is connected through valves to the gas of the analyzed gas and a carrier gas line connected through a valve to the inlet of the second cumulative column, the output of which is connected via a valve to the discharge line and the chromatographic The thermostat is also made of several, placed in a single heat-insulated casing, independent chambers, in which fixedly connected sections of accumulative columns are installed so that each chamber is arranged in pairs of one section of each column, the last section of one of the cumulative columns is installed in the independent chamber of the thermostat, and the output section of the first cumulative column with It is connected through valves with the first section of the second cumulative column and with the discharge line, and also with the fact that the thermostat chambers are connected by flow switches to the refrigerant line and the discharge line and are made in the form of cylindrical vessels fixed tightly with upper open ends on a single flange connected hermetically with thermostat housing.

The proposed design of the concentrator has no moving parts, the storage columns, broken into small sections, are in close contact with the heater, are quickly heated, the thermal gradient along the length of the columns when concentrated is achieved by successive heating of the column sections placed in independent chambers.

The drawing shows an impurity concentrator for a gas chromatograph.

The proposed device contains a thermostat 1, made in the form of several independent chambers 2, 3 and 4, which are connected via flow switches 5, 6 and 7 to the refrigerant line and the discharge line, and are in the form of cylindrical vessels 8 sealed to the flange 9 which is also hermetically connected to the housing 10 of the thermostat 1. The space between the walls of the vessels 8, the flange 9 and the inner surface of the housing 10 is filled with insulating material or evacuated. Chambers 2, 3 and 4 are closed with a heat insulating lid 11, on which heaters 12, 13 and 14 are fixed, placed in chambers 2, 3 and 4 of the thermostat 1. Thermostat has accumulator columns 15 and 16 filled with various adsorbents, made in the form of sections 15-1, 15-2, 15-3, 16-1 and 16-2, which are fixedly mounted on heaters 12, 13 and 14. Sections 15-1 and 16-1, 15-2 and 16-2 are installed in pairs in chambers 2 and 3, and the output section 15-3 of the cumulative column 15 is installed in a separate chamber 4. The sections of each column are connected in series.

The inputs of the first cumulative column 15 are connected via valves 17 and 18, respectively, to the line of the analyzed gas and the carrier gas line to which the input of the second cumulative column 16 is also connected via valve 19. The outputs of cumulative columns 15 and 16 are connected via valves 20 and 21 22, and through valves 23 and 24 with a discharge line. In addition, the last section 15-3 of the first cumulative column 15 is connected via valve 25 to the first sections 16-1 of the second cumulative column 17. The hub operates as follows. In the accumulation mode shown in the drawing, chambers 2, 3, and 4 are filled with a refrigerant, for example, liquid nitrogen, columns 15 and 16 are cooled to -196 ° C. valves 17, 24 and 25 are open; the remaining valves are closed. The gas to be analyzed through valve 17 enters accumulation columns 15 and 16, which are connected during accumulation in series through valve 25, and then through valve 24 to the discharge line. On the cooled adsorbents, the accumulative columns are bordered, the absorption of impurities that are sorbed better than the main component, and the main component (the analyzed gas), together with the non-sorbent di-impurities, is discharged. The adsorbents of accumulative columns 15 and 16 are selected in such a way that the weakly sorbed components pass unhindered through the column 15 and the adsorbent 16 is retained, the heavier components are completely absorbed by the adsorbent column 15. Thus, impurities that are concentrated for chromatographic analysis due to different sorption capacity cumulative columns into two groups. When the necessary, previously known, dosed amount of the gas being analyzed is passed through the storage columns, the adsorbent will be saturated with impurities over the entire length of the storage columns, close valve 17 and 25 and switch flow switch 5 to the reset position. The refrigerant from chamber 2 is discharged. The heater 12 in the chamber 2 is turned on and the valves 18, 19 and 23 are opened, while the accumulation columns 15 and 16 are connected in parallel, their inlet sections 15-1 and 16-1 are connected to the carrier gas line, the outlet sections 15-3 and 16-2 - to the line of discharge. The temperature in chamber 2 is increased, sections 15-1 and 16-1 of the cumulative columns, tightly attached to heater 12, are actively heated together with the heater to a predetermined value + (200 +, at which impurities absorbed by the adsorbent in sections 15-1 and 16-1 is desorbed and transported to the flow of carrier gas flowing through columns 15 and 16 to section 15-2, 16-2 and 15-3. When desorbing impurities from the heated sections of the storage columns, the concentration of impurities in the carrier gas increases and with increasing concentration the absorption capacity of the adsorb increases therefore, the desorbed impurities carried by the carrier gas flow in section 15-2, 16-2, and 15-3 are absorbed by the cooled adsorbents at a shorter length, i.e. the compression of impurity bands in the accumulation columns occurs. present in the accumulation columns after accumulation, and the carrier gas is discharged from the columns through valves 23 and 24. After the impurities are displaced from sections 15-1 and 16-1, the flow switch 6 is reset, the refrigerant from chamber 3 flows out, the heater 13, closing The valve 24 is opened and the valve 21 is opened. The temperature rises to a predetermined value in chamber 3 and sections 15-2 and 16-2 of the storage columns are heated. Impurities absorbed by the adsorbents of these sections are desorbed, their concentration in the carrier gas is still increasing. The impurity carrier gas is transferred by the flow of section 15-2 to the cooled section 15-3 installed in chamber 4, and from section 16-2 is passed through valve 21 to the chromatographic analyzer 22 for intensive analysis. Next, the flow switch 7 is switched to the reset position, the refrigerant flows out of the chamber 4. The heater 14 is turned on, the valve is closed 2-3 and the valve 20 is opened. The temperature in the chamber 4 rises to a predetermined value, the impurities are desorbed in section 15-3 and concentrated the narrow band enters through valve 20 into the chromatographic analyzer for an extensive analysis. After displacing the impurities from section 15-3 into chromatographic analyzer 22, close valves 18, 19, 20, 21, and 23, turn on heaters 12, 13, and 14, switch flow switches 5, 6, and 7 to their original positions, chambers 2, 3 and 4 is filled with refrigerant, after which valves 17 and 25 are opened and the next cycle of operation begins. I: In the case when, for example, more steps are needed to concentrate the group of impurities accumulated in column 16, in a separate chamber of the thermostat (4 the output section of this accumulative column (16) is placed, then a heavier group of impurities from column 1.5, and then lighter impurities from column 16. Non-simultaneous input of concentrated impurities

The analyzer allows chromatographic analysis and measurement on a single measurement channel, which simplifies the instrumentation.

Thus, the proposed design of the concentrator is simple, eliminates the loss of weakly sorbing components of impurities and ensures complete desorption of the most strongly retained adsorbents of the components of impurities during concentration, as with stationary storage columns placed in non-i dependent thermostat chambers, the sizes of the columns are optimally selected and the sections are heated columns for the desired progrstsime. This allows you to accumulate impurities without losses, concentrate them into narrow strips and optimally introduce a progressive analysis into the chromatographic analyzer. improve the reliability and accuracy of the concentrator, and hence the accuracy of chromatographic analyzes.

Claims (3)

1. An impurity concentrator for a gas chromatograph containing accumulator columns filled with adsorbents, made in sections and installed in a thermostat equipped with a heat-insulated casing and heating and cooling devices for the accumulating columns, the input of one of the columns is connected via valves to the line of the analyzed gas and the gas line media connected through a valve to the input of the second cumulative column, the output of which is connected through the valve to the discharge line and a chromatographic analyzer also connected through the valve with the output of the first cumulative column, characterized in that, in order to simplify the design, increase the reliability and accuracy of the concentrator, the thermostat is made of several independent chambers placed in a heat-insulated housing, in which fixedly connected sections of cumulative columns are installed that each chamber is placed in pairs in one section of each accumulation column, n & and this last section of one of the accumulation columns is installed in a separate a thermostat, and output ce); the qi of the first cumulative column is connected through valves to the first section of the second cumulative column and to the reset line. 2. The concentrator according to claim 1, wherein the thermostat chamber is connected to the flow switch with the refrigerant line and the discharge line and is made in the form of cylindrical vessels tightly fixed with upper open ends on a single flange connected tightly to the thermostat housing. Sources of information taken into account in the examination 1. USSR author's certificate No. 257848, cl. G 01 N 31/08, 1965. 2. USSR author's certificate №241094, cl. G 01 N 31/08, 1964. 3. USSR author's certificate No. 503174, cl. G 01 N 31/08, 1974 (prototype).