SU832469A1 - Chromatograph column - Google Patents

Description

(54) CHROMATOGRAPHIC COLUMN

;one. .

The invention relates to gas chromatography and can be used in the preparative isolation of various substances from mixtures. :

Chromatographic columns are known, made in the form of a cylindrical tube with a round, oval, or petal cross section filled with sorbent particles ij.

Closest to the proposed invention is the design of a chromatographic column, inside of the case of which, filled with sorbent particles, radial partitions of annular shape are located adjacent to the inner surface of the wall of case 2.

A disadvantage of the known constructions of chromatographic columns with different cross-sectional shapes is the low separation efficiency of quantities due to the different gas flow profiles over the column section. This is due to the uneven packing of the sorbent particles over the column section, which are now packed tightly, rarely, and in some. there are voids like arches. When the columns are filled with a sorbent, size fractionation also occurs. Larger ones are located near the walls or on the center (depending on the backfilling method). The flow of the sorbing substance 5 goes mainly along the path of least hydraulic resistance,

which leads to a blur of the chromatographic strip. When using annular radial partitions 0, a portion of the peripheral space between the partitions may be unfilled. Sorbent, located in. these areas, forms dead stagnant zones that do not work, moreover, to replace congestion. They need to be removed to change the distance between them. At the same time, it is also necessary to extract the sorbent asbestos. In addition, partitions interfere with the backfilling of sorbent particles and its further installation. Thus, when using annular partitions, contradictions arise: at the time of preparation, the chromatographic 5. There should be no columns for the work of partitions inside the column, but they should be located in the interior of the column. In addition, to measure the size of the partitions and the distance between them, they must be

are movable in the radial direction and are capable of mixing in the axial direction, and in the process of work they must be rigid and prevent gas from passing along the inner surface of the walls.

The purpose of the invention is to improve the efficiency of the column operation, which is achieved due to the possibility of adjusting the height of the partitions and the distance between them using the invention, as well as simplifying the process of filling the column with sorbent particles. The goal is achieved by the fact that in a chromatographic column containing a tubular body filled with a sorbent and annular radial partitions, the body walls and annular radial partitions are made in the form of flexible elements, and the shape of the outer surface of the elements repeats the shape of their inner surface, for example corrugated In addition, the internal volume of the corrugation is filled with smaller particles of the sorbent with respect to the particles of the sorbent that fill the entire remaining volume of the column.

The drawing shows the structure of a chromatographic column, a general view.

The chromatographic column contains a housing 1 filled with sorbent particles 2, the ends are made in a smooth transition to cyclic distributors 3 mounted along the axis of the column. The walls of the casing are made in the form of flexible elements 4, for example in the form of corrugations.

The column operates as follows.

The carrier gas with the breakdown of the substance to be separated enters through the inlet cylindrical distributor 3 and moves to the outlet distribution through the particles of sorbent 2. When the gas mixture passes through the column, the mixture cannot flow at high speed along the wall, resulting in no blur stripes.

In addition, since the inner surface of the flexible elements 3 is not perpendicular to the direction of movement of the gas flow in the sorption process, sorbent particles located in the depressions participate, and the dimensions of the annular partition formed by the inner surface of the flexible elements 3 can be changed during operation, and distance between adjacent partitions.

The use of the proposed chromatographic column design makes it possible to increase the efficiency of separation of substances due to the more uniform velocity profile, the gas flow. In addition, the process of filling the column with a sorbent is significantly improved, since in the compaction process it is possible to perform laying by vibrating compression or expansion of the body along the longitudinal axis. By selecting the vibration frequency, controlled fractionation of sorbent particles is carried out, and the vibration frequency is selected so that the peripheral area of the column is filled

5 smaller particles. If it is necessary to change the parameters of the annular partitions in the course of work, it is sufficient to do this by compressing or stretching the body along the longitudinal

0 axis, with the simultaneous addition or filling of the sorbent. In addition, it should be noted that during the operation of the chromatographic column, the sorbent particles are crushed,

5 which leads to poor performance. In the proposed design, it is possible to compress the flexible walls of the casing, thereby restoring operability.

Claims (3)

1. A chromatographic column comprising a tubular body filled with sorbent particles and annular radial partitions attached to the inner surface of the body wall, characterized in that, in order to increase work efficiency, the body walls and partitions are made in the form of flexible elements, and the shape of the outer the surfaces of the elements follow the shape of their inner surface. 5 2. The column under item 1, from l and h y and with that, that elements are executed in the form of a corrugation. 3. Column on PP. 1 and 2, is incriminating in that Q bump volume is filled with smaller ones sorbent particles with respect to sorbent particles filling the rest of the column volume. Sources of information taken into account in the examination 1. Preparative gas chromatography. M ,, Mir, 1974, p. 127-130. 2. Sakodinsky K. I. and others. Preparative gas chromatography M., Himi, 1972, p. 195.