SU766644A1 - Cyclone and separator - Google Patents

Description

one

The invention relates to mineral Hijra in heavy environments, and more specifically to hydrocyclones for separating bulk materials by density in a heavy medium, and can be used to enrich coal and other materials in the coal, mining, metallurgical and chemical and other industries. x industrial conditions.

Cylindrical cyclones with feed of the source material directly into the cyclone {.

Also known cyclone, including the upper and lower cylindrical sections, equipped with tangential and axial nozzles, and. intermediate section 2.

The source material in a known cyclone is fed through the upper axial nozzle into the interior of the cyclone, where it is picked up by a vortex suspension flow pumped through the lower tangential nozzle. In the vortex flow, the source material under the action of centrifugal forces is divided into a heavy fraction thrown into the apparatus wall and displaced a light fraction to the air column. T wish

the fraction is withdrawn from the cyclone through the upper tangential nozzle, and lightly through the lower axial.

5 The disadvantage of the apparatus is that a part of the material, directed at loading along the axis of the cyclone, slips, by inertia, through the air column into the discharge tube of the light

10 Fractions not falling into a vortex suspension flow, i.e. mine separation process.

Thus, a light fraction of clogging of BTS by impurities is easy. Moreover, the source material fed into the cycle. It is perpendicular to the direction of rotation of the vortex flow of the suspension, slowing down this flow, while decreasing the centrifugal

20 forces, and thus separation of products worsens.

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

The goal is achieved by

25 that the intermediate section is made in the form of a sector of the torus. In this case, the axial loading nozzle of the upper section is equipped with a vortex chamber coaxial with it with a tangential nozzle for.

30 water supply systems.

In such a cyclone, the axis of the vortex suspension flow together with the air column repeats the curvature of the guide channel surface. The curvature of the vortex flow contributes to the capture of the entire material, since the trajectory of movement of the particles of the material continuing to move inertia. along the axis of the loading nozzle, it intersects with a curved vortex flow encompassing this axis. Moving the slurry elementary jets relative to each other while turning the vortex flow at the bending of the cyclone helps to improve the redistribution of the material particles in their fractions, and thus improve the quality of the enrichment products.

The drawing shows a cyclone separator, a longitudinal section.

The cyclone separator contains upper and lower cylindrical sections 1 and 2 and an intermediate section 3. Lower section 2 is equipped with a tangential nozzle 4 and an axial nozzle 5, upper section 1 - a tangential 6 and an axial 7. Axial nozzle 7 of the upper section 1 has a vortex chamber 8 s tangential pipe 9 a. A hopper 10 of the starting material is installed above chamber 8. The intermediate section 3 is made in the form of a cyclic channel surface with a curved guide.

The cyclone separator works as follows.

Through the tangential nozzle 4 of the lower section 2 is injected under the pressure of the suspension, from which a separating vortex flow is formed in the cyclone. The source material from the hopper 10 enters the cyclone through the axial, pipe 7 of the upper section 1. Passing through the loading pipe 7, the material is unwound by a vortex flow formed in the vortex chamber 8 from the suspension pumped through the pipe 9, and under the action of centrifugal forces from the pipe 7 is thrown into cyclone in the form of the flow rate of the con- strua. In a cyclone, the source prepared material is picked up by a vortex flow, in which, under the action of centrifugal forces, it is divided into products: its heavy fraction is thrown to the wall of the cyclone and through the tangential nozzle 6 of the upper section 1 is removed with a part of the suspension from the cyclone, and light

the fraction is forced into the vortex flow into the air column and, with the rest of the suspension, leaves the cyclone through the axial nozzle 5 of the lower section 2.

Since the source material enters the cyclone previously unwound, and in the direction coinciding with the direction of rotation of the separating vortex flow, when it enters the flow, it almost does not hinder its movement. This source material, as it exits the nozzle under the action of centrifugal forces, tends toward the periphery, being introduced into the separation flow. Those particles of material

5, which do not have time to receive rotational movement in the axial nozzle 7, and along a straight line moving parallel to the axis along the air column, necessarily fall into the curved flow. Particles of light fraction,

0 pressed against the wall of the cyclone by the heavy fraction and carried along with it, on the turn they turn out of the heavy fraction and rush to the air column, and the particles of the same fraction, carried away by the layer of the light fraction, on the turn fall through the layer holding them and leave to the heavy fraction.

The proposed cyclone separator design provides high enrichment efficiency with the so-called free-flow material loading.

Claims (2)

1. Cyclone separator, including upper and lower cylindrical sections, equipped with tangent and axial nozzles and an intermediate section, characterized in that, in order to improve the quality of separation products, the intermediate section is made in the form of a torus sector. 2. A cyclone separator according to claim 1 / characterized in that the axial loading nozzle of the upper section is provided with a vortex chamber coaxial with it with a tangential nozzle for supplying a heavy medium. Sources of information taken into account in the examination 1. Patent 2917173, cl. 209-172.5, 15.12.59. 2. Patent number 3219186, cl. 209-172.5, 11/23/65. ffucemq fvda 9f Kt4ug