RU97651U1 - MASS EXCHANGE SEPARATION ELEMENT - Google Patents

Abstract

 1. Mass-exchange separation element, comprising a shell with a flow swirl and a dropper placed above the edge of the shell, made in the form of a U-shaped deflector with vertical side surfaces forming communicating annular channels with the outer and inner sides of the shell, characterized in that the part of the shell located above the outer edge of the dropper, made perforated, while the total cross section of the perforations of the shell does not exceed 2.0 section of the annular channel between the shell and the dropper, cr In addition, a droplet separator is installed on the dropper. ! 2. Mass-transfer separation element according to claim 1, characterized in that along the upper forming part of the scraper, holes are made, oriented in the direction of swirling the flow with a swirler.

Description

The utility model relates to devices for mass transfer between gas and liquid, as well as for gas purification from liquid impurities using centrifugal forces arising from swirling gas flow, and can be used both for mass transfer processes and gas-liquid separation processes in oil , gas, petrochemical and other industries.

A centrifugal separation element is known, including a shell, two successive swirlers with guide vanes and a thin-layer nozzle between them, a gas outlet pipe installed inside the shell, and a separated liquid trap, which is a ring with a vertical side adjacent to the gas outlet pipe, and the surface of the shell forms a flange and communicating annular channels with the outer surface of the gas outlet pipe (RF patent No. 2052272, IPC V01D 45/12, publ. 01.20.1996).

Common features of the known centrifugal separation element with the proposed are:

- shell;

- flow swirl;

- a trap of separated liquid located above the edge of the shell.

A disadvantage of the known device is the increased hydraulic resistance due to the presence of two swirls and insufficiently effective separation of the liquid from the gas, due to the secondary ablation of droplets deposited on the gas outlet in the form of a film.

The closest in technical essence and the achieved result to the proposed invention is a centrifugal separation element, comprising a casing with a trap of separated liquid and a swirl. Inside the shell, a hollow cylindrical body is placed coaxially with it, one end of which is sealed and protruding above the trap of the separated liquid, and the other end is made in the form of a nozzle and is located above the swirl; in addition, the protruding end part of the hollow body is equipped with gas supply pipes. The trap for trapping the separated liquid is a ring with vertical sides forming communicating annular channels with the outer and inner sides of the shell (patent No. 2140317, IPC ⁶ V01D 45/12, publ. 12.10.1999, OB No. 30).

Common features of the known and proposed devices are:

- shell;

- flow swirl;

- a dropper placed above the edge of the shell, made in the form of a U-shaped deflector with vertical side surfaces forming communicating annular channels with the outer and inner sides of the shell.

A disadvantage of the known device is the low efficiency of gas separation and mass transfer with a high content of droplet liquid due to secondary entrainment caused by the deposition of part of the droplets that bounced onto the outer surface of the hollow central body and the flow of part of the liquid from the inner cavity of the hollow central body onto it, and also not high enough performance of the separation element due to the organization of recycling of part of the stream.

The technical problem is to achieve high performance mass transfer separation element, as well as high separation efficiency by eliminating the entrainment of droplet liquid with gas with low hydraulic resistance.

This object is achieved by the fact that in the mass transfer separation element, including a shell with a flow swirl and a dropper placed above the shell edge, made in the form of a U-shaped deflector with vertical side surfaces forming communicating annular channels with the outer and inner sides of the shell, a part of the shell located above the outer edge of the dropper, made perforated, while the total section of the perforations of the shell does not exceed 2.0 section of the annular channel between the shell and a dropper, in addition, a droplet collector is installed on the dropper.

In addition, holes are formed along the upper forming part of the dropper, oriented toward the swirling direction of the flow with a swirl.

The perforated part of the shell located above the outer edge of the droplet remover allows most of the liquid film to be drained through the holes before it enters the annular channel between the inner side of the shell and the vertical side surfaces of the U-shaped deflector. This eliminates the stall of large drops and, therefore, reduces the secondary entrainment of the liquid with the main part of the gas stream. In addition, the throughput of the mass transfer centrifugal element in the trapped fluid is increased.

The execution of the part of the shell located above the outer edge of the dropper, perforated so that the total cross section of the perforations of the shell does not exceed 2.0 of the cross section of the annular channel between the shell and the dropper, allows a high mass transfer coefficient to be obtained without a significant change in the swirl angle of the gas stream.

The installation of a droplet eliminator on the dropper eliminates the secondary entrainment of liquid with part of the gas bursting into the annular channels formed by the outer and inner sides of the shell and the vertical side surfaces of the U-shaped deflector. This part of the gas leaves the outer annular channel and, moving upward along the outer surface of the dropper, it encounters a droplet separator in its path, on the outer surface of which the gas is separated from the droplet liquid.

Performing holes along the upper forming part of the scavenger oriented toward the swirling direction of the flow by the swirl excludes the formation of gas-liquid plugs in the annular channels, which impede the uniform removal of the liquid film by the scraper and lead to secondary liquid entrainment.

The device is presented in the figures, in which Fig. 1 shows a general view, Fig. 2 is a view A-A of the mass transfer separation element indicating the directions of twisting of the gas stream and the gas outlet from the openings.

The mass-exchange separation element consists of a shell 1 with a swirl 2 of a stream, a dropper 3 located above the edge of the shell 1, and a droplet 4 mounted on droplet 3 and made in the form of a confuser, or a polyhedral truncated pyramid or segment of the surface of a sphere. The dropper 3 is made in the form of a U-shaped deflector with vertical side surfaces 5, forming communicating annular channels 6 with the outer and inner sides of the shell 6. The part of the shell 1, located above the edge of the outer side surface 5 of the dropper 3, is perforated with holes 7. The total section of the holes 7 of the shell 1 does not exceed 2.0 of the cross section of the annular channel 6 between the shell 1 and the scraper 3. On the upper generatrix of the scraper 3 holes 8 are made, oriented in the direction of flow swirling swirl 2.

The device operates as follows. Gas with a droplet liquid passes through a swirl 2, where it takes a rotational-translational motion, and is sent to the inner cavity of the shell 1. The liquid under the action of centrifugal forces is concentrated at the inner surface of the shell 1, and the separated gas, having contacted the liquid film, through the central opening of the dropper 3 leaves the centrifugal element. The liquid in the film form along the inner surface rises to the upper edge of the shell 1, with most of the fluid flowing along the inner wall of the shell through the perforation 7 in the shell 1, and the remaining part of the fluid is removed from the stream through the annular channel 6 between the upper part of the shell 1 and droplet remover 3. Located horizontally and at an angle to the vertical plane - in a direction similar to the angle of twist of the blades in the swirl 3, - openings 8 serve for the exit of gas that burst with the liquid in the ring howling channel 6, contributing to the uniform removal of the liquid film droplet 3, which eliminates the secondary ablation of the liquid.

The droplet eliminator 4 is designed to prevent secondary entrainment of liquid with a part of the gas bursting into the annular channels 6 formed by the outer and inner sides of the shell 1 and the vertical side surfaces 5 of the U-shaped deflector. This part of the gas leaves the outer annular channel 6 and, moving up along the outer surface of the shell 1, encounters a droplet separator 4 in its path, on the outer surface of which the gas is separated from the droplet liquid.

Thus, at first separation of the droplet liquid from the gas and the formation of a liquid film on the inner surface of the shell 1 occur, after which a mass transfer occurs between the gas and the liquid in the film mode.

Figure 1 shows the implementation of the drop eliminator 4 in the form of a confuser.

Perforation on the shell 1 can be of any shape, and the total cross section of the holes 7 does not exceed 2.0 of the cross section of the annular channel 6 between the shell 1 and the drier 3. Figure 1 shows the perforation 7 on the shell 1 in the form of round holes.

Claims (2)

1. Mass-exchange separation element, comprising a shell with a flow swirl and a dropper placed above the edge of the shell, made in the form of a U-shaped deflector with vertical side surfaces forming communicating annular channels with the outer and inner sides of the shell, characterized in that the part of the shell located above the outer edge of the dropper, made perforated, while the total cross section of the perforations of the shell does not exceed 2.0 section of the annular channel between the shell and the dropper, cr In addition, a droplet separator is installed on the dropper. 2. The mass-exchange separation element according to claim 1, characterized in that along the upper forming part of the scraper, holes are made, oriented in the direction of swirling the flow with a swirl.