RU167120U1 - CENTRIFUGAL EXTRACTOR - Google Patents

Abstract

1. A centrifugal extractor comprising a housing, on a removable flange of which a drive with a bearing support and a drive shaft is mounted, on which the rotor with a cover and a ring is rigidly fixed, the inner walls of the rotor with a ring and longitudinal blades form a separation chamber partitioned along the azimuthal angle, in which the sides of the shaft are the output tubes from the rotor of the light phase, and the lid with the ring and the shell located between them, rigidly mounted on the housing, form a water seal to withdraw the heavy phase from the rotor with sediment , overflow and transfer openings of the tubes and the hydraulic lock communicate with the pockets of the housing for collecting the separated phases with the outlet pipes, while the lower part of the housing under the rotor serves as a mixing chamber, which is connected via a blade transport mechanism to the separation chamber, has a paddle mixer and inlet pipes, characterized in that in each section of the separation chamber on the longitudinal blades at different levels fixed transverse plates mounted on adjacent longitudinal blades alternately with a gap m and without it with them, and with a gap between themselves and with the rotor. 2. A centrifugal extractor according to claim 1, characterized in that the transverse plates are made in the form of an annular sector, the inner diameter of which is less than the diameter of the overflow of the light phase. Centrifugal extractor according to paragraphs. 1 and 2, characterized in that the gap of the transverse plate with the adjacent blade has the shape of an annular sector, the area of which is greater than the area of the annular gap of the plate with the rotor.

Description

The utility model relates to liquid extraction, namely, to designs of centrifugal extractors for a liquid-liquid system, including the processing of liquids containing or forming precipitates upon contact, and can be used in hydrometallurgical, chemical, pharmaceutical, and other industries.

A centrifugal extractor is known from the prior art (see USSR author's certificate 1608903 A2, B01D 11/04, publication date 05/23/1993, Bull. 19), comprising a housing, on a removable flange of which a drive with a bearing support and a drive shaft is mounted on which it is rigidly a rotor with a cover is fixed, the inner walls of the rotor with longitudinal blades form a separation chamber partitioned along the azimuthal angle, in which the output tubes from the rotor of the light phase are placed on the shaft side, and a water seal with a transfer hole is placed on the side of the cover I withdrawal from the rotor of the heavy phase with sediment, overflow and transfer openings of the tubes and the hydraulic lock communicate with the pockets of the housing for collecting the separated phases with the outlet pipes, while the lower part of the housing under the rotor serves as a mixing chamber, which is connected to the separation chamber through the blade transport mechanism paddle mixer and inlet nozzles.

The disadvantage of this centrifugal extractor is low productivity, due to the fact that the emulsion is subjected to additional forced acceleration of delamination from contact with the longitudinal blades only in a small volume near them. In this zone, the average longitudinal emulsion velocity along the shaft is minimal, but the velocity gradient is maximum, which contributes to additional deformation of the emulsion and coalescence of droplets. In addition, the implementation of the hydraulic lock in the form of two tubes placed with a gap in one another contributes to the clogging of the overflow hole of the hydraulic lock with sediment, both during operation and when the drive starts, which violates the separation of the emulsion and stops the process for cleaning the rotor from accumulated sediment .

The closest technical combination and technical result achieved to the applicant’s proposal is a centrifugal extractor (see USSR author's certificate 1546096 A1, B01D 11/04, publication date 02/28/1990, Bull. 8), containing a housing on which a drive is mounted on a removable flange with a bearing support and a drive shaft on which the rotor with the cap and the ring is rigidly fixed, the inner walls of the rotor with the ring and longitudinal blades form a separation chamber partitioned along the azimuthal angle, in which The output tubes from the rotor of the light phase are placed on the shaft, and the lid with the ring and the shell placed between them, rigidly mounted on the body, form a water seal for withdrawing the heavy phase from the rotor with sediment, overflow and transfer openings of the tubes and the water seal communicate with the pockets of the case to collect the separated phases with outlet nozzles, while the lower part of the housing under the rotor serves as a mixing chamber, which is connected via a blade transporting mechanism to the separation chamber, has a paddle mixer and inlet nozzle and.

The disadvantage of this centrifugal extractor is its low productivity, which is caused similarly to the previous small contact area of the emulsion with the longitudinal blades, which reduces their additional effect on the acceleration of delamination of the emulsion in the rotor separation chamber.

The problem to which the claimed utility model is directed is to increase the performance of a centrifugal extractor and the quality of the target product.

The technical result achieved by the claimed utility model is to increase the performance of a centrifugal extractor by attaching additional elements — transverse plates — in each section of the separation chamber to longitudinal blades at different levels along the shaft to increase the forced deforming effect on the emulsion in order to accelerate the coalescence of droplets of the dispersed phase.

The proposed arrangement of transverse plates blocks each section of the separation chamber into a sequence of volumes communicating along the shaft and, thus, forcibly changes the transport path in the rotor of most of the flow of the separated emulsion from straight to zigzag. This provides an additional deforming effect on the interfacial surface of the emulsion due to azimuthal mixing of the emulsion when flowing around the edges of the plates and the occurrence of an alternating Coriolis force acting on the emulsion layer in the radial direction. At the same time, the interfacial surface of the emulsion is additionally deformed, both when moving between adjacent plates, including due to an increase in the contact area with them, and when the transportation direction changes to the opposite along the azimuthal angle. As a result, the coalescence rate of the droplets of the dispersed phase and the separation of the emulsion increases, compared with the prototype, which increases the productivity of the extractor and improves the quality of the target product by reducing the mutual phase entrainment.

The technical result is achieved by the fact that a centrifugal extractor is declared, comprising a housing, on a removable flange of which a drive with a bearing support and a drive shaft is mounted, on which a rotor with a cover and a ring is rigidly fixed, the inner walls of the rotor with a ring and longitudinal blades form a partition along the azimuthal angle a chamber in which the output tubes from the rotor of the light phase are placed on the shaft side, and the cover with a ring and a shell placed between them, rigidly mounted on the housing, form a hyd a shutter for withdrawing a heavy phase from the rotor with sediment, overflow and transfer openings of the tubes and the hydraulic lock communicate with the pockets of the housing for collecting the separated phases with the outlet pipes, while the lower part of the housing under the rotor serves as a mixing chamber, which is connected through the blade conveyor mechanism to the separation chamber, has a paddle mixer and inlet nozzles, and in each section of the separation chamber on the longitudinal blades, transverse plates mounted on adjacent lane blades alternately with and without a gap with them, and with a gap between themselves and with the rotor.

Thus, the claimed utility model of a centrifugal extractor, in which in each section of the separation chamber on the longitudinal blades at different levels along the shaft are fixed transverse plates arranged alternately with and without a gap with adjacent longitudinal blades and with a gap between themselves and with the rotor, allows increase the productivity of the extractor and the quality of the target product.

In the presented FIG. 1 schematically shows the proposed centrifugal extractor in section, in FIG. 2 schematically shows section AA of FIG. 1, in FIG. 3 schematically shows a view along arrow B of FIG. 1 to longitudinal blades and transverse plates placed in the rotor.

The claimed centrifugal extractor (Fig. 1, Fig. 2) contains a housing 1, on a removable flange 2 of which a drive 3 is mounted with a bearing support 4 and a shaft 5 fixed therein, articulated with the drive 3 through the coupling 6. The rotor 7 is rigidly fixed to the shaft 5 conical shape with longitudinal blades 5 along the shaft 5, transverse plates 9 and a ring 10 with a transfer hole 11, forming a separation chamber 12 sectioned along the azimuthal angle, and a cover 13 with an overflow hole 14, forming a water seal 15 with the ring 10. Ring 10 is made in the form hubs rigidly mounted on the shaft 5, on which the rotor 7 and the cover 13 are fixed. In the chamber 12 there are tubes 16 with an overflow hole 17 of the output of the light phase placed at a radius of R ₁ , and a shell 18 is placed in the hydraulic lock 15 of the output of the heavy phase and sediment, rigidly mounted on the flange 2. The shell 18 can be made in the form of a ring or plate. The overflow openings of the tubes 16 and the cover 13 communicate with the chambers 19 and 20 for collecting the separated phases with the outlet pipes 21, while the lower part of the housing 1 under the rotor 7 serves as a mixing chamber 22, which through the blade transporting mechanism 23, made with the possibility of feeding the mixture from the mixing chamber 22, and connected with the separation chamber 12, has a paddle mixer 24 mounted on the rotor 7, and inlet pipes 25. In each section of the separation chamber 12, the transverse plates 9 are mounted alternately on adjacent longitudinal blades 8 26 with a gap and without them, with a gap 27 between themselves in different levels along the shaft 5, and a gap 28 with the rotor 7. The transverse plate 9 may have a form of an annular sector with an inner radius R ₂ <R _1, thus, the clearances 26 will have a similar shape.

Centrifugal extractor works as follows. After starting drive 3, the initial solutions through the inlet pipes 25 are fed into the mixing chamber 22, where they are mixed with a mixer 24 for mass transfer of the distributed component, and the resulting emulsion is fed by a transporting mechanism 23 to the rotating rotor 7. In the process of transporting the emulsion from bottom to top in the rotor 7 and its delamination in each section of the separation chamber 12 between the longitudinal blades 8 and the transverse plates 9, it takes the form of an annular emulsion layer of densely packed drops of dispersion meat phase different shape and volume, separated by a thin layer of the continuous phase. With a decrease in the thickness of this layer due to centrifugal force, the coalescence of the droplets accelerates and a second continuous layer of fully coalesced droplets of the initially dispersed phase forms. Thus, in the rotor 7, under the ring 10, three radially adjoining annular layers are formed - two clean separated phases separated from each other in the axial and peripheral zones of the rotor and the emulsion layer between them.

The light phase through the overflow hole 17 is discharged from the rotor 7 into the chamber for collecting the light phase, and through the outlet pipes 21 to the outside of the extractor. The heavy phase through the overflow hole 11 enters the hydraulic lock 15, is transported to the axis of rotation of the shaft 5 to the overflow hole 14 and is discharged from the rotor 7 towards the periphery into the heavy phase collection chamber 20 and through the outlet pipes 21 to the outside of the extractor. Sediment due to centrifugal force is transported along the conical surface of the rotor 7 to the overflow hole 11, is wound with a stationary shell 18 and is then removed with the flow of the heavy phase through the overflow hole 14 from the rotor 7.

When the condition R ₂ <R _{1 is} fulfilled, one part of the flow of the shared emulsion in the gaps 27 successively connected along the shaft 5 when flowing around the lateral edge of the transverse plate 9 in the sector gap 26 changes the direction of the relative velocity in the opposite direction. When the emulsion moves in a circle relative to the rotor 7, in addition to the others, the Coriolis force acting along the radius acts on it. When the direction of the relative velocity vector is reversed, the vector of this force also changes sign, which helps to accelerate the coalescence of droplets of the dispersed phase in the emulsion layer. The other part of the flow of the shared emulsion in the gaps 27, communicating inextricably with the first, when flowing around the outer edge of the transverse plate 9 in the annular gap 28 is transported without changing the direction of the relative speed and therefore is not subjected to additional separating effect of the plates 9. In this case, the sediment does not accumulate on the transverse plates 9 as well as on the longitudinal blades 8 due to their radial fastening across and along the shaft 5, which contributes to the withdrawal of sediment from the rotor 7. To increase part of the flow shared mulsii directed in a serpentine path along the shaft 5, it is necessary to increase the area of sector gap 26 in comparison with the area of the annular gap 28. However, to reduce the area of the annular gap 28 to zero is impossible, as it is required for transportation through the conical surface of the rotor 7 precipitate.

The utility model is industrially applicable, since it has now passed bench tests that have confirmed its reliability, ease of manufacture and the achievement of a new technical result — increased productivity for both possible types of emulsion — in solid or heavy or light phases, as well as the quality of the target product. Specific design features of the claimed extractor are feasible and do not contradict the application in an industrial environment.

Thus, the claimed technical solution to the above problem, the totality of the features of which is unknown from the present prior art, is novel in comparison with the selected prototype, technically feasible and industrially applicable, which meets the criteria characterizing the utility model.

Claims (3)

1. A centrifugal extractor comprising a housing, on a removable flange of which a drive with a bearing support and a drive shaft is mounted, on which the rotor with a cover and a ring is rigidly fixed, the inner walls of the rotor with a ring and longitudinal blades form a separation chamber partitioned along the azimuthal angle, in which the sides of the shaft are the output tubes from the rotor of the light phase, and the lid with the ring and the shell located between them, rigidly mounted on the housing, form a water seal to withdraw the heavy phase from the rotor with sediment , overflow and transfer openings of the tubes and the hydraulic lock communicate with the pockets of the housing for collecting the separated phases with the outlet pipes, while the lower part of the housing under the rotor serves as a mixing chamber, which is connected via a blade transport mechanism to the separation chamber, has a paddle mixer and inlet pipes, characterized in that in each section of the separation chamber on the longitudinal blades at different levels fixed transverse plates mounted on adjacent longitudinal blades alternately with a gap m and without it with them, and with a gap between themselves and with the rotor. 2. The centrifugal extractor according to claim 1, characterized in that the transverse plates are made in the form of an annular sector, the inner diameter of which is less than the diameter of the overflow of the light phase. 3. Centrifugal extractor according to paragraphs. 1 and 2, characterized in that the gap of the transverse plate with the adjacent blade has the shape of an annular sector, the area of which is greater than the area of the annular gap of the plate with the rotor.

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