SU1764666A1 - Separator for system liquid-liquid - Google Patents

Abstract

The invention relates to chemical engineering and can be used in the chemical, food and other industries. The purpose of the invention is to increase the degree of separation of the phases. The separator contains a vertically installed cylindrical housing, in the upper part of which a tangential medium inlet is installed, branch pipes for the discharge of the hard and light phase, respectively. located in the bottom of the case. Collecting channels are installed on the side walls of the casing from the outside. The channels are connected to a collector to which a branch pipe is attached to the heavy phase. The collecting channels are connected to the housing by holes. A central channel is installed on the housing axis, which is connected with holes to the separation channel, inside which separating partitions are installed, alternately attached along the housing axis to the wall of the separation channel, then to the wall of the central channel, which is connected to the outlet pipe pipes: a pipe forming the central channel and a pipe forming the outer wall of the separation channel, with the separating partitions having the shape truncated to cones set large bases downwards. Attached to the outer wall of the pipe are ejection channels with open ends, which are a quarter of a ring attached at one end to a pipe in which holes are made, combined with ejection channels. The holes are located above the separating partitions attached to the pipe, and the holes 10 are located below the separating partitions attached to the central channel. A guide cylinder is attached to the upper part of the housing. The manifold is connected by holes to the separation channel. 1 hp f-ly. 2 Il. ate with 2 i lON

Description

The invention relates to the field of chemical engineering and can be used in the chemical, food and other industries.

The purpose of the invention is to increase the degree of separation of the phases.

Fig, 1 shows a longitudinal section of a general view of the separator; figure 2 - section aa in figure 1.

The separator contains a vertically installed cylindrical housing 1, in the upper part of which there is a tangential nozzle 2 for supplying the medium, nozzles 3, 4 for diverting the hard and light phase, respectively, are located in the lower part of the case, collecting channels 5 are installed outside the side walls of the case co-partitioning walls 6 are installed, which are partitions covering 60-70% of the living section of channels 5, and alternately attached downwards to the side wall of the housing, then to the side station The channel 5. The channels 5 are connected to the collector 7, to which the branch pipe of the heavy phase 3 is attached. The collecting channels 5 are connected to the body 1 by holes 8. On the axis of the body 1 there is a central channel 9 which is connected by holes 10 to the separation chamber 11 , inside which are installed separating partitions

12, alternately attached along the axis of the housing, either to the wall of the separation channel 11, or to the wall of the central channel 9, which is connected to the branch pipe 4 for discharging the light phase. The separation chamber 11 is formed by two coaxial pipes: a pipe forming the central channel 9 and a pipe

13, forming the outer wall of the separation channel 11, while the separating partitions have the shape of truncated cones, installed with large bases downwards.

To the outer wall of the pipe 13 attached to the ejection with open ends of the camera

14, representing a quarter of a ring attached at one end to a pipe 13, in which holes 15 are made, aligned with ejection ducts. The holes 14 are located above the separating partitions 12 attached to the pipe 13, and the openings 10 are located below the separating partitions attached to the central channel 9. The guide cylinder 16 is attached to the upper part of the body, the collector 7 is connected by openings 17c of the separation chamber 11,

The separator works as follows. The emulsion through the tangential nozzle 2 enters the housing 1, while the emulsion acquires a rotational motion and is directed downward by the guide cylinder 16. Under the action of centrifugal force, the phase phase is pressed against the walls of the housing 1 and through the holes 8 enters the collecting channels 5, passes between the coalescing partitions 6. Due to the presence of coalescing partitions, the slipped light phase collects under the partitions and merges into large drops of light liquid . Further, the hard phase together with large drops of light liquid moves into the reservoir.

7, and from it through pipe 3 is removed from the separator. The light phase presses to the axis, rises up the separator and through the open upper end of the separator.

the chamber 11 enters the separating chamber 11. Next, the fluid bends around the separating partitions 12 successively, while the light phase is collected under the partitions and discharged through the openings 10

0, the central channel 9, and from there, through pipe 4, is withdrawn from the separator. The tela phase collects over the partitions 12 and through the holes 15 enters the interior of the ejection chambers 14, and from there, due to the ejection

5 swirling flow inside the housing 1 to the flow, i.e. essentially, the stream sucks the heavy phase from the separation channel. The ejection chambers are installed so that the open end of the channel is

0 is directed downstream (along the azimuthal component of the stream), the accumulating light in the collector 7 is discharged through the openings 17 into the separation chamber 11, and from there through the openings 10 to the central

5 channel 9 and nozzle 4 are removed from the separator. The collecting phase in the separation chamber 11 tons of yellow phase is discharged through the openings 17 to the collector 7.

It is advisable to use the separator together with the gravitational capacity separator, in this case, the light phase output connection pipe is connected to the pipeline, which is inserted into the separator and ends above the phase separation level, and

The 5th outlet of the heavy phase is connected to the pipeline introduced into the gravity separator and ends below the phase separation level.

Using the device allows

0 40% reduction in the content of light or heavy phases in the discharge phases.

Claims (2)

Claim 1. Splitter for liquid-liquid systems, comprising a vertical housing with 5 tangential medium inlet, light and heavy phase nozzles, heavy phase collecting channels with coalescing partitions, communicating through the holes with the housing, and a collector connected to the heavy phase outlet channels, characterized in that increase the degree of separation of phases, it is equipped with a central channel with a blind bottom edge connected to the Pat5 by retraction of the light phase, a separation chamber installed coaxially with the central channel, separation walls, placed E inside the separation chamber mounted in the upper housing guide cylinder, ejection chambers with open ends arranged in the separation chamber and communicating with the separation chamber by means located above the separating wall openings, and a central passage communicates with the separation chamber holes, made under the separation baffles 2. A separator according to claim 1, characterized in that the collector is connected to the separating chamber by openings. i FIG. R