SU1542564A1 - Attachment for pulsating and vibrating heat- and mass-exchange apparatus - Google Patents

Abstract

The invention relates to mass transfer devices, can be used for solvent extraction in the chemical industry, as well as in other areas of the industry where extraction processes are used, and allows to intensify the extraction process and reduce the centrifugal separation of the phases. A nozzle for pulsating and vibratory mass transfer devices is a set of horizontal discs with square or hexagonal holes, each of which is equipped with guide vanes, bent away from the disk plane in different directions so that screw surfaces are created at the corners of the junction of the adjacent openings. The holes in each adjacent pair of disks are placed so that the dots of the vertices of the polygons of the adjacent disk are located above the centers of the holes of each disk. 2 Il.

Description

The invention relates to mass transfer device designs and can be used for solvent extraction in the chemical industry, as well as in other industries where extraction processes are used.

The purpose of the invention is to intensify the extraction process and reduce centrifugal phase separation.

FIG. 1 shows a nozzle for the case of hex holes, top view; in fig. 2 shows section A-A in FIG. one.

The disk 1 of the nozzle has multi-faceted holes 2 with guide vanes 3.

The nozzle works as follows.

The fluid flow (one of the swirling zones is shown in Fig. 1), crossing the cross section of the disk 1, is deflected by a pair of guide vanes 4.5 at an angle to its plane. Similarly, pairs of blades 6.7 and 8.9 deflect the flow to the plane.

The plate sections At the same time, the horizontal components of these flows are directed at an angle of 120 ° to each other and form a vortex fluid movement in this zone. The nature of the location of the vortex zones at the vertices of the squares or hexagons ensures an even distribution of the vortex bundles in the cross section of the apparatus, with each pair of adjacent ones rotation is in the opposite direction.

This method of organizing the movement reduces the energy costs of creating rotational motion and contributes to an increase in the lifetime of the vortex, thereby increasing the height of the vortex zone above and below the plate.

This sequence of installation of the disks and the order of the arrangement of the holes in them ensure that the junction points of the vertices of the globules of the adjacent holes of each disk are located above the centers of the adjacent holes. Thus excluded

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Direct passage of the interacting phases through a pair of disks, preventing channelization. In addition, the centers of the vortex bundles created by each subsequent plate are located above the centers of the zones of the peripheral regions of the lower layer, with a uniform distribution of local movement in the cross section of the apparatus.

At the same time, the organization of flows by this packing eliminates the global rotational movement and phase separation caused by it, ensuring uniform mixing of flows in the cross section of the apparatus, reducing transverse discontinuities.

The use of the invention allows, in comparison with the prototype, to almost completely eliminate the rotational movement of the total flow in the apparatus, and hence the centrifugal separation of the phases. Intensive mixing and crushing of droplets of the dispersed phase as a result of the rotational motion of individual jet streams increases the intensity of extraction.

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Claims (1)

Invention Formula A nozzle for pulsating and vibratory mass transfer devices, comprising a set of horizontal disks with holes, each of which is equipped with guide vanes, bent in different directions to the plane of the disk, characterized in that, in order to intensify the extraction process and reduce centrifugal phase separation, the holes made in the form of hexagons or squares, the guide vanes are made in the form of triangles, formed by dividing the areas of the holes by diagonals, while the adjacent blades adjacent each other to each other, the holes are bent in opposite directions, and the blades of each hole are bent so that they form screw surfaces at the junction angles of adjacent holes, while the centers of the holes in each pair of adjacent disks are opposite the junction points of the hexagons or squares of adjacent holes of the adjacent disk Zo azayairu- 80N1 / I FIG L pua 2