RU77444U1 - SORPTION TUBE AND DEVICES FOR ITS USE - Google Patents

Abstract

The utility model relates to sorption tubes used in gas chromatographic determination of the mass concentration of impurities in natural gas. The sorption tube contains a housing, in the middle of the inner part of the housing there is a sorbent of activated KSK silica gel, at the ends of the housing there are two valves. The natural gas sampling device, comprising a housing with a container for accommodating the sorption tube and at opposite ends of the lid body, is equipped with needles with internal channels installed in the lids and providing opening of the sorption tube valves when sampling natural gas. A thermal desorber containing a housing with a capacity for accommodating the sorption tube, a platinum resistance thermometer and at opposite ends of the lid body, is equipped with two needles with internal channels installed in the lids and providing opening of the sorption tube valves during analysis. 3 n.a.s. 4 s.p. f-ly, 3 ill.

Description

The utility model relates to sorption tubes used in gas chromatographic determination of the mass concentration of impurities in natural gas.

Known sorption tubes containing a housing with a sorbent in the inner part of the housing (see for example. Sorption tube ST 223, http: //pribors.narod.m/p/pribs894.htm, http://www.atmosfera-npk.ru, sorption tube in patent application US 2006/0039827 A1, IPC G01N 30/60, publication date 02/23/2006).

The disadvantages of the known sorption tubes is the failure to quickly seal the internal volume of the tube and the deposition of methanol on the inner walls of the tube.

The closest analogue of the claimed sorption tube is a sorption tube containing a housing with a sorbent in the inner part of the housing (see, for example, Sorption tube ST 223, http://pribors.narod.ru/p/pribs894.htm, http: // www .atmosfera-npk.ru).

The disadvantages of the sorption tube is the lack of rapid sealing of the internal volume and the deposition of methanol on the inner walls of the tube.

The closest analogue of the claimed sampling device is a sampling device for analyzing gas containing a housing with a container for accommodating the sorption tube and at opposite ends of the lid housing (see, for example, the invention according to patent RU No. 22210073, class G01N 30/08, B01D 15 / 08, application No. 2002116995/28 of 06.25.2002, publication date 10.08.2003, bull. No. 22).

The disadvantage of the sampling device is the inability to open the valves of the sorption tube after placing it

into the sampling device and closing the valves of the sorption tube after pumping the required dose of natural gas through the sorption tube.

The closest analogue of the claimed thermal desorber is a thermal desorber containing a housing with a container for accommodating the sorption tube, a platinum resistance thermometer at the opposite ends of the lid housing and which is part of the Chromatek chromatographic complex (see, for example, http://www.chromatec.ru).

The disadvantage of the thermal desorber is the inability to open the valves of the sorption tube after placing it in the tank body of the thermal desorber.

The sorption tube contains a housing, in the middle of the inner part of the housing there is a sorbent of activated KSK silica gel, at the ends of the housing there are two valves.

The natural gas sampling device comprises a housing with a container for accommodating the sorption tube and at opposite ends of the lid body, provided with needles with internal channels installed in the lids and providing opening of the sorption tube valves when sampling natural gas.

The thermal desorber contains a housing with a capacity for accommodating the sorption tube, a platinum resistance thermometer and at opposite ends of the lid body, is equipped with two needles with internal channels installed in the lids and providing opening of the sorption tube valves during analysis.

The essence of the sorption tube and devices for its use is illustrated by drawings, where:

figure 1 sorption tube in cross section;

in Fig.2 a sampling device in cross section;

figure 3 thermal desorber in cross section.

The sorption tube contains a housing 1, in the middle of the inner part of the housing 1 there is a sorbent that is made of activated KSK 2 silica gel, two valves 3 and 4 are located at the ends of the housing 1 (Fig. 1).

This design allows you to maintain the tightness of the sorption tube inside the sampling device before and after sampling, as well as after removing the sorption tube from the sampling device before starting the analysis of the sample.

The valves 3 and 4 of the sorption tube can be made in the form of ball valves, each of which contains a ball 26 or 27, one or two sealing rings 5 of elastic material, located between the ledge in the inner part of the housing 1 of the sorption tube and the ball 26 or 27, which pressed by springs 6 to the nearest sealing ring 5. The sealing rings 5 are fixed inside the housing 1 by sleeves 7 and threaded bushings 8 installed at the ends of the housing 1.

Additionally, the sorption tubes can be sealed with plugs, which can maintain tightness during transportation from the sampling point to the place of analysis and vice versa (for example, from a gas field to the laboratory). This, in turn, gives a number of advantages, expressed in the exclusion of moisture on the sorbent from the air, in the exclusion of the loss of concentrated impurities during transportation, which allows you to determine the concentration of the analyzed components at the level of 1 ppm.

The housing 1 of the sorption tube can be equipped with a protrusion 9, which is made in the form of a ring or part thereof and eliminates the incorrect location of the sorption tube in the sampling device (figure 2) and thermal desorber (figure 3).

The sorption tube is placed in a sampling device and then in a thermal desorber in a specific position. This is due to the following. When passing the analyzed gas through the sorption tube, impurities of the sample are usually adsorbed at the beginning of the inner part of the housing of the sorption tube filled with sorbent (in the claimed sorption tube with activated KSK 2 silica gel). The desorption of impurities from the sorbent is carried out in the opposite direction to reduce the blurring of the chromatographic zone and obtain narrow symmetric peaks of the analyzed components. In known similar tubes, a graphic image is applied at one end, which in no way excludes errors in the placement of the sorption tube in the thermal desorber when it is inserted from the wrong end, which should be introduced first into the thermal desorber. The presence of the protrusion 9, for example, in the form of a ring or part thereof, at one end of the housing 1 of the sorption tube automatically ensures the fulfillment of the specified condition (figure 3).

To use the claimed sorption tube, a natural gas sampling device (Fig. 2) and a thermal desorber (Fig. 3) were developed. A feature of the natural gas sampling device and thermal desorber is the presence of needles 10, 11 (FIG. 2) and 19, 20 (FIG. 3), which open valves 3 and 4 in the sorption tube during sampling and analysis.

The natural gas sampling device comprises a housing 12 with a container for accommodating the sorption tube and lid 13, 14 at opposite ends of the housing 12. The natural gas sampling device is provided with needles 10 and 11 with internal channels installed in the lids 13, 14 and providing opening of valves 3 , 4 sorption tubes when sampling natural gas. In the middle of the housing 12 of the sampling device attached to the line 15 of the discharge of natural gas before sampling (figure 2).

In one embodiment of the sampling device at the ends of the needles 10, 11 with internal channels, grooves are made with a direction from the internal channel to the outside of each needle 10 and 11.

The thermal desorber contains a housing 16 with a container for accommodating the sorption tube, a platinum resistance thermometer 17 and caps 18 and 19 at opposite ends of the housing 16. The thermal desorber is equipped with two needles 20 and 21 with internal channels installed in the covers 18, 19 and allowing valves 3, 4 to open sorption tube in the analysis (figure 3). The thermal desorber is located on the chromatograph 22 and is connected to a 10-port switch crane (conditionally not shown in the drawing as not included in the thermal desorber).

In one embodiment, a thermal desorber at the ends of the needles 20, 21 with internal channels, grooves are made with a direction from the internal channel to the outer side of each needle 20 or 21.

Sampling of the analyzed natural gas is carried out on a sorption tube filled with activated KSK 2 silica gel. To do this, unscrew the cover 13 from the sampling device. The sorption tube, previously conditioned and cooled, is placed in the sampling device. Install cover 13 on the body of the sampling device. One end of the sampling device is connected to an aspirator 23, the second end of the sampling device to a closed valve 24 for purging with natural or other analyzed gas, and a gas discharge line 15 is connected to the middle part of the housing 12 of the sampling device. When screwing the cover 13 of the sampling device to a certain position, the sampling device is sealed, but the valves 3, 4 of the sorption tube still remain closed. Open valve 24 and purge the natural gas sampling device with gas discharged to line 15 for approximately several minutes

(two minutes is enough). This also removes air that was previously in the sampling device. Excess gas is released into the atmosphere. After purging, the cover 13 of the sampling device is screwed to the stop. Needles 10, 11 with internal channels enter the sorption tube, press the valves 3, 4 of the sorption tube and open them. The grooves on the ends of the needles 10, 11 with a direction from the inner channel to the outer side of the needles 10 and 11 provide guaranteed gas flow around the surface of the valves 3, 4 after they are opened. The gas flows through activated KSK silica gel 2 sorption tube. With the aspirator 23, for example, bellows or the like, through activated silica gel XK 2 sorption tube is pumped necessary volume of natural gas in the range of 100-600 cm ³ (e.g., to determine the methanol concentration greater than 0.2 g / m ³ to 100 cm is sufficient to pump ³ natural gas). After gas sampling, the sorption tube valves 3, 4 are closed by unscrewing the cover 13 of the sampling device after closing the valve 24. The sorption tube is removed from the sampling device and, if necessary, additionally sealed with plugs.

Then, after moving to the chromatograph 22 and after removing the plugs (if they were used, if necessary, the sorption tube is placed in a thermal desorber heated to a certain temperature (for example, up to 180 ° C). When tightening the cover 18 of the thermal desorber, the needles 20, 21 with internal channels located on the covers 18, 19 of the thermal desorber open the valves 3, 4 of the sorption tube. The sorption tube is heated for about 1 minute. After switching the 10-port switch crane to the analysis mode, a carrier gas, for example, helium, begins to flow through the thermal desorber and the sorption tube. The impurities are desorbed from the heated KSK 2 silica gel and the desorbed impurities are eluted into the chromatographic column of chromatograph 22. The grooves on the ends of the needles 20, 21 with a direction from

the inner channel to the outer side of the needles 20 and 21 provide a guaranteed flow of gas around the surface of the valves 3, 4 after they open.

The claimed sorption tube for gas chromatographic determination of the mass concentration of impurities in natural gas and devices for its use can be used for analysis of other impurities in a gas or air environment.

Claims (7)

1. A sorption tube containing a housing, a sorbent, characterized in that the sorbent in the middle of the inner part of the housing is made of activated KSK silica gel, two valves are located at the ends of the housing. 2. The sorption tube according to claim 1, characterized in that the two valves are made in the form of ball valves. 3. The sorption tube according to claim 1, characterized in that on the outer side of one of the ends of the housing is made a protrusion in the form of a ring or part thereof. 4. A device for sampling natural gas, comprising a housing with a container for accommodating the sorption tube and at opposite ends of the lid body, characterized in that it is equipped with needles with internal channels installed in the lids and providing opening of the sorption tube valves when sampling natural gas. 5. The device for sampling natural gas according to claim 4, characterized in that at the ends of the needles with internal channels grooves are made with a direction from the internal channel to the outside of the needle. 6. A thermal desorber comprising a body with a container for accommodating the sorption tube, a platinum resistance thermometer and at opposite ends of the lid body, characterized in that it is equipped with two needles with internal channels installed in the lids and providing opening of the sorption tube valves during analysis. 7. The thermal desorber according to claim 6, characterized in that at the ends of the needles with internal channels grooves are made with a direction from the internal channel to the outside of the needle.