RU64107U1 - CONCENTRATOR FOR SEPARATION OF PARTICLES OF SOLID BULK MATERIAL BY THEIR DENSITY - Google Patents

Abstract

The invention relates to devices for separation (concentration) of particles of bulk materials by their density. The hub contains a pipeline (1) for transporting particles of bulk material in a gas stream, having a straight section (2) connected to a gas flow inducer (3) and a hopper (4) for introducing material particles into the gas stream, a radially curved section (5) for creating centrifugal forces in the particle stream and a distribution section (6) equipped with dividing walls (7) separating the particle stream emerging from the curved section into particle flows of different densities. A separator (9) of particles of the starting bulk material is introduced into the concentrator by their size, and one of the exits (10) of the separator, through which the fraction of particles of a certain size is output, is connected to the hopper (4) for introducing the separated particles into the gas stream in the pipeline. The bent section (5) of the pipeline is made in the form of several spirally arranged turns and in its cross section has an oval shape. The technical result consists in increasing the degree of separation of particles by density by reducing the influence of particle size dispersion. 4 s.p. f-ly, 4 ill.

Description

The invention relates to devices for concentrating particles with increased density from the total mass of particles of bulk materials. Such devices are called “hubs” in the literature. The utility model may find application for mineral processing from pre-ground ores, slags, dumps of metallurgical industries, etc.

Concentrators are known for separating particles of bulk material according to their density using centrifugal forces generated in a radially bent pipe for transporting particles of material in a gas stream (see, for example, GB 544397, B07B 7/08, 1942).

A disadvantage of the known hub is the complexity of the design, which leads to low reliability of its operation.

The closest in technical essence and the achieved result to the proposed hub is a hub for separating particles of bulk material by their density, containing a pipeline for transporting the separated particles of material in a gas stream, having a straight section connected to a gas flow inducer and a hopper for supplying the source bulk material to gas flow, radially bent section for creating centrifugal forces in the particle stream and distribution section provided with dividing wall and separating effluent from the curved pipe section to the particle flow streams of different density particles cyclones installed in different density particles flows (see. the patent GB 1,455,579, V07V 7/02, 1976).

A disadvantage of the known concentrator is that it does not provide a sufficiently high degree of separation of particles by density. This is due to the fact that the degree of separation of particles of solid bulk materials in the field of centrifugal forces depends not only on density, but also on particle size.

The objective of the utility model was to increase the degree of separation of particles by density by reducing the effect of differences in particle sizes.

This problem is solved by the fact that the proposed hub for separating particles of bulk material according to their density, containing a pipeline for transporting separated particles of material in a gas stream, having a straight section connected to a gas flow inducer and a hopper for supplying the source bulk material into a gas stream, radially curved a section for creating centrifugal forces in the particle stream, and a distribution section provided with dividing walls,

separating a stream of particles emerging from a bent section of the pipeline into flows of particles of different densities, cyclones installed in flows of particles of different densities, into which, according to a utility model, a particle separator of the initial bulk material is introduced, and one of the separator exits through which the particle fraction is withdrawn material of a certain size, connected to a hopper for supplying bulk material, installed in a straight section of the pipeline for transporting the separated particles in a gas stream.

The use of particles of a certain size for concentration of particles according to their density can dramatically reduce the effect of differences in particle sizes on the degree of their separation by density. This provides an increase in the degree of separation of particles by density.

Another difference of the concentrator is that the gas outlets of the cyclones are connected to the inlet of the gas flow inducer and are equipped with devices for regulating the gas flow. This ensures the economical use of energy, for example, air in the proposed hub.

Another difference of the concentrator is that the pipeline for transporting particles in a gas stream in its radially curved section has an oval cross-section in which the major axis is parallel to the horizontal plane.

Among the differences, it should be noted that the radially curved section of the pipeline is made in the form of several spirally arranged turns.

Another difference of the concentrator is that it is equipped with a gas flow heater installed at the outlet of the flow inducer. This makes it possible to simultaneously dry the particles of bulk material.

The technical result of the utility model is that the effect of the difference in particle sizes of the granular material on the degree of density separation in the field of centrifugal forces is reduced. This provides an increase in the degree of separation of particles of bulk material by density.

The invention is illustrated by drawings.

Figure 1 shows a schematic diagram of the proposed hub.

Figure 2 presents a top view of a centrifugal separator of particles by their density.

Figure 3 shows a cross-sectional view of a curved section of a pipeline for transporting particles of bulk material in a gas stream.

Figure 4 shows an embodiment of a concentrator with a device for heating a gas stream.

The hub contains a pipeline 1 for transporting particles of a shared bulk material in a gas stream, having a straight section 2 connected to a flow inducer 3 and a hopper 4 for supplying the source

bulk material into the gas stream, a radially bent section 5 for creating centrifugal forces in the particle stream, and a distribution section 6 provided with dividing walls 7 installed inside it and dividing the particle stream leaving the bent section 5 of the pipeline 1 into particle flows of different densities. At the outlet of the pipeline 1, cyclones 8 are installed in the flows of particles of different densities to separate particles of bulk material from the gas stream transporting them.

The concentrator also contains a separator 9 for separating the particles of the starting bulk material into fractions of particles of a certain size, one of the outlets 10 of which is connected via a conveyor 11 to the hopper 4 for supplying particles of the bulk material into the gas stream in the pipeline 1. Gas outlets 12 of the cyclones 8 can be connected to the input 13 of the inducer 3 of the gas flow using gas channels 14, in which devices 15 are installed to control the gas flow.

In a preferred embodiment, the curved section 5 of the pipe 1 has an oval cross-section (see FIG. 3).

The hub works as follows.

A pre-ground solid material (for example, slag) containing particles from 5 to 100 microns in size is fed to a separator 9, for example, a vibrating sieve separator, where it is divided into separate fractions of a certain size. One of the outputs 10 of the separator 9, through which a fraction of particles of a certain size (for example, 10-20 microns) is output, is connected via a conveyor 11 with a hopper 4 for introducing particles of bulk material into the gas stream passing through a straight section 2 of pipeline 1. When this, the other outputs of the separator 9 (not shown in FIG.), through which the output of fractions of particles of a different size is carried out, can be connected to hoppers for loading other concentrators of a similar type (not shown in FIG.).

The particles of bulk material received in the gas stream in the pipeline 1 are accelerated in this stream to speeds of 50-300 m / min. At these flow velocities in the bent section 5 of the pipeline 1, particles in the gas stream are affected by centrifugal forces, under the influence of which heavier particles (particles of higher density material) move to the wall of the radially bent section 5 of the pipeline with a smaller radius of curvature, displacing the less heavy (light) to a wall having a larger radius of curvature. Thus, after 2-3 turns of the spiral of a radially bent section 5 of the pipeline 1 inside it, under the action of centrifugal forces, the particles are stratified in the horizontal plane according to their density along the major axis of the oval cross section. At the exit from the radially bent section 5 of the pipeline 1, the particle stream is divided by means of partitions 7 vertically mounted at the inlet of the distribution section 6 of the pipeline 1 into flows of particles of different densities, which enter separate cyclones 8, where particles are separated from the gas. For example, high-density metal inclusions contained in ground slag

metallurgical production, while going to the leftmost in the direction of flow of the cyclone 8 (see figure 2), metal inclusions of lower density will settle in the middle cyclone 8, and inclusions of silicate type (the bulk of the composition of the slag) will settle in the far right in the direction of travel flow cyclone 8.

The embodiment of the concentrator shown in FIG. 4 differs from that described above (FIG. 1 and FIG. 2) in that a gas flow heater 16 is inserted into it, which is installed at the outlet of the gas flow inducer 3 in front of the hopper 4 for introducing particles of bulk material into the gas flow . In this embodiment, the hub gas outlets 12 of the cyclones 8 are not connected to the input of the flow inducer 3. These outputs can be connected to condensers of moisture vapor (not shown in Fig.), Which simultaneously act as dust collectors.

A feature of the work of this embodiment of the concentrator is that in it, along with the process of separating particles of bulk material by their density, the process of drying particles of bulk material is carried out. It also helps to increase the degree of separation of particles by density by eliminating agglomeration (adhesion of wet particles) of particles of the separated bulk material.

Thus, the proposed concentrator provides the ability to concentrate the useful constituents of bulk materials in a "dry" way, in contrast to the currently used "wet" methods of concentration, for example, by flotation. This significantly reduces energy costs for the concentration process and improves the quality of the products recovered (the products emitted are not contaminated with reagents used in the flotation process).

Claims (5)

1. A hub for separating particles of bulk material according to their density, comprising a pipeline for transporting the separated particles of material in a gas stream, having a straight section connected to a gas flow inducer and a hopper for supplying the initial bulk material into the gas stream, a radially curved section for creating in the stream particles of centrifugal forces, and a distribution section equipped with dividing walls installed inside it and separating the particle flow n from the bent section of the pipeline flows of particles of different densities, cyclones installed at the outlet of the pipeline in flows of particles of different densities, characterized in that a separator of particles of bulk material is introduced into it, and one of the exits of the separator through which a fraction of particles of material of a certain size is output is connected to a hopper for supplying bulk material, installed in a straight section of the pipeline for transporting particles to be separated in a gas stream. 2. The concentrator according to claim 1, characterized in that the gas outlets of the cyclones are connected to the inlet of the gas flow inducer and are equipped with devices for regulating the gas flow. 3. The concentrator according to claim 1 or 2, characterized in that the pipeline for transporting particles in a gas stream in its radially curved section has an oval cross-section in which the major axis is parallel to the horizontal plane. 4. The concentrator according to claim 3, characterized in that the radially curved section of the pipeline is made in the form of several spirally arranged turns. 5. The concentrator according to claim 1, characterized in that it is equipped with a gas flow heater installed at the outlet of the gas flow inducer.