SU1512666A1 - Dehydrator of suspensions - Google Patents

Abstract

The invention relates to hydrocyclones and can be used in agriculture for the dehydration of potato mash. The purpose of the invention is to improve the quality of the separation of suspensions. Pipe 4 drainage of the filtrate is made of conical rings 5 with a gap between them, to the inner surface of which is attached multiturn tape helix. During operation, the initial suspension through the tangential nozzle 2 is fed under pressure to the housing 1, where it acquires a rotational motion, hits the turns of the screw 7, in which the direction of twisting is opposite to the orientation of the spiral trajectory of the heavy fraction in the housing 1. The screw device presses and unloads the heavy the fraction in the nozzle 3, and the resulting filtrate penetrates through the gaps of the conical rings 5 into the cavity of the pipe 4, is sucked into the ascending flow and, together with the liquid fraction, is brought up through the drain pipe 4. 1 ° C f-ly. 3 il.

Description

AT

(L

ello

O5 O5 05

The invention relates to devices for the continuous separation of suspensions under the action of centrifugal field forces, namely hydrocyclones, and can be used in agriculture, for example, in dewatering potato mash.

The purpose of the invention is to improve the quality of the separation of suspensions.

FIG. 1 shows a slurry dehydrator, obndium view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows the node I in FIG. one.

The dehydrator consists of a cylindrical body 1 with a tangential inlet 2 and outlet 3 nozzles.

Along the axis of the cylindrical housing 1, along its entire height, a perforated drain pipe 4 is installed, consisting of a package of conical rings 5, placed with a clearance “relative to each other

friend

Inside the pipe 4, along its entire length, a multiple-branch spiral helix 6 is fixed. In the lower part of the perforated pipe 4, a screw 7 is fixed. The perforated pipe 4 performs a vrastive movement (drive not shown).

Dehydrator works in the following way.

The initial suspension through the tangential nozzle 2 is fed under pressure to the housing 1, where it acquires a rotational movement supported by the jet energy. Under the action of centrifugal forces, the most heavy fraction is thrown to the periphery and moves downwards along a spiral trajectory. Then it falls on the turns of the screw 7, in which the direction of twisting is opposite to the spiral trajectory of movement of the heavy fraction into the housing 1. As a result, a countercurrent occurs, the vector of which is directed in the direction opposite to the direction of axial movement of the heavy fraction. This ensures effective tedding of the thickened fraction in the boundary layer at the beginning of the auger, which contributes to a better determination of free moisture and an increase in productivity. The screw device 7 promotes and unloads the heavy fraction into the pipe 3, and the resulting filtrate penetrates through the gaps of the conical rings 5 into the cavity of the pipe 4, is sucked into the ascending flow and together with the liquid fraction is withdrawn up through the drain pipe 4.

The liquid fraction under the action of centrifugal forces is displaced to the center of the housing 1, filling the annular gaps of the conical rings 5 of the rotating tube 4. At the moment the liquid fraction enters the gaps of the conical rings, the angular velocity increases, resulting in the separation of small particles from the heavy fraction the height of the dewatering unit, which contributes to an increase in the quality of the separation of the suspension. Due to the coincidence of the directions of the spiral movement of the fluid and the angle of inclination of the conical rings of the rotating pipe, the annular gaps free fill, and a sharp change in the cross section of the moving stream in the boundary layer adjacent to the outer surface of the pipe 4 and in its cavity increases the speed of its movement. Once inside the pipe 4, the flow rate is increased due to the forced movement along the turns of the multiple spiral tape 6. As a result, an increased pressure is created in the placement area of the cylindrical part of the body, which facilitates lifting the filtrate from the dewatering zone upward, thereby accelerating the free moisture from the compression layer by counting the difference in circumferential flow rates of the liquid fraction moving along a spiral path, and the rotating pipe 4, annular gaps are prevented from blocking. As a result, the process of separating the suspensions into fractions is intensified, and the productivity of the dehydrator is increased.

Claims (2)

1. A slurry dehydrator containing a cylindrical housing with a tangential inlet and outlet nozzles, pups and a drain pipe placed along the axis of the housing, characterized in that, in order to improve the quality of separation of suspensions, it is equipped with a multiple-use ribbon helix installed inside the drain pipe of a liquid which is made of a set of conical rings set apart from each other. 2. A dewatering machine as claimed in Claim 1, characterized in that the liquid discharge pipe is made over the entire height of the body. FIG. five