RU63254U1 - SCREW SEPARATOR - Google Patents

Abstract

The utility model relates to devices for separating bulk solid materials according to their density and can find application in mining and processing, metallurgical, coal and other industries. A screw separator is proposed in which the upper turns (5) of the screw trough (1), along which the separated loose material moves, are equipped with a device (4) for heating the material and evaporating the moisture contained in it and several vibrators (6) interacting with the bottom of these turns gutters. The technical result of the utility model is that under the influence of heating and vibration, the process of adhesion of small particles of gangue into agglomerates decreases and, as a result, the degree of enrichment of useful heavy minerals and metals in the dry method of enrichment increases. 2 s.p. f-ly, 3 ill.

Description

The utility model relates to devices for separating bulk solid materials by their density and can be used in the mining and processing industry for the extraction of heavy valuable minerals, as well as in the disposal of slag from metallurgical industries, the separation of coal particles from mineral components, etc.

Known screw separator, which is a fixed helical trough with a vertical axis, equipped with a device for receiving the initial power, flush water and cut-offs of the beneficiation products (see, for example, the Guide to ore dressing. Main processes. / Ed. By O.S. Bogdanov, M. Nedra, 1983, pp. 120-127 /. Such screw separators are used to enrich fine-grained sand and crushed ores containing diamond, magnetite, hematite, zircon, ilmenite, ruby, cassiterite, tantalite, columbite, tungsten, gold, platinum and others. heavier s metals and minerals.

A disadvantage of the known screw separators is the need to use wash water in them. This requires subsequent drying of the products of enrichment and disposal of wash water.

The closest to the proposed separator by technical essence is a screw separator containing a vertically mounted helical groove, a hopper for loading the source material installed under the helical groove, and enrichment product cutters installed in the lower part of the helical groove (see RF patent No. 2169047, B03B 5 / 52, 2001).

A disadvantage of the known screw separator, adopted for the prototype, is that it uses washing water to enrich dispersed solid materials.

Previously, attempts were made to use screw separators for the enrichment of particulate bulk materials in a dry way, i.e. without the use of wash water, however, as far as the authors know, these attempts did not achieve the desired result. This, apparently, is due to the fact that any dispersed bulk material has a certain moisture content (2-4% or more). Such material, when moving along the trough, tends to aggregate particles. In a screw separator, in which centrifugal forces are used to separate particles, the degree of separation of particles depends not only on the density of the material of the particles, but also on their particle size. Adhesive small particles of the material to be separated, which are, as a rule, particles of gangue, move similarly to small particles of higher density, which are

particles of an enriched mineral or metal, and fall into the composition of the allocated concentrate, drastically reducing the degree of enrichment.

The objective of the utility model was to increase the degree of enrichment of useful heavy minerals and metals by separating them from gangue particles in a dry way by reducing the stickiness of small gangue particles.

This problem is solved by the fact that a screw separator is proposed comprising a vertically mounted chute, a hopper for loading the starting material, mounted under the helical chute, and enrichment product cutters installed in the lower part of the helical chute, in which, according to a useful model, the upper turns of the helical chute are equipped with a device for heating the original bulk material moving along the gutter, and evaporating the moisture contained therein, and several vibrators interacting with the bottom of these turns of the gutter.

In a particular embodiment of the separator, a helical chute can be placed between two cylindrical central and external bodies, the inner edges of the chute being rigidly connected to the surface of the central cylindrical body, which serves as a support for the helical chute, a hopper for loading the initial bulk material and cut-offs of enrichment products, and the outer edges the gutters are in close contact with the inner surface of the outer cylindrical body, the outer surface of which is provided with an electrical heater, the central cylindrical body in the upper part has openings located above the edges of the trough connected to it, and in the lower part of the central body there is a gas burner equipped with channels for supplying gas fuel and air, and the inner channel of the central cylindrical body serves as a channel for exhausting flue gases burners and vapors evaporated from the original bulk material, moisture.

Another difference of the proposed separator is that the pitch of the turns of the spiral groove in its upper part, where the heating devices and vibrators are installed, is made smaller with respect to the pitch of the turns of the spiral groove in its lower part.

Due to the heating of the source material in the upper part of the helical trough, accompanied by the evaporation of the moisture contained in it, as well as the vibration of the particles of the material on the upper turns of the trough due to the vibration of its bottom, the possibility of sticking together of small particles and the formation of their agglomerates is almost completely eliminated, which ensures an increase in the degree of enrichment of heavy particles of valuable minerals and metals in the dry enrichment method.

This is the technical result of the utility model.

Thus, in the proposed separator, the spiral chute has two parts for various functional purposes: the upper part, which serves primarily for drying the particles of dispersed material and destroying them

agglomerates, and the lower part, which serves to separate particles according to their density under the action of centrifugal forces.

The essence of the utility model is illustrated by drawings.

Figure 1 shows the proposed screw separator.

Figure 2 presents a view in plan of the separator in section along aa of figure 1.

The separator comprises a vertically mounted helical groove 1, a hopper 2 for loading the starting material, mounted above the helical groove 1, and cut-offs 3 of the enrichment products installed in the lower part of the helical groove 1. The upper turns of the helical groove are equipped with a device 4 for heating the initial bulk material 5 moving along the groove 1, and several vibrators 6, interacting with the bottom of these turns of the groove 1. The vibrators can be made in the form of electromagnetic vibrators.

In a particular embodiment of the separator, a helical groove 1 is placed between two cylindrical central and external housings 7 and 8, respectively. The inner edges of the groove 1 are rigidly connected to the surface of the central cylindrical body 7, which is mounted on the base 9 and serves as a support for the screw groove 1, hopper 2 for loading the source material and cut-offs 3 of the enrichment products. The outer edges of the screw groove 1 are in close contact with the inner surface of the outer cylindrical body 8, which is also installed on the base 9. The device 4 for heating the initial bulk material can be made in the form of electric heaters (TENOV), evenly placed on the outer surface of the outer case 8 (see Fig. 3). In this case, the heaters 4 are isolated from the external environment by a thermal insulation layer 10. The central cylindrical body 7 in its upper part has openings 11 located above the inner edges of the trough 1 connected to it and used to remove moisture vapor from the source material from the space between the bodies 7 and 8 under the influence of heating. In the lower part of the central building 7, a gas burner 12 is installed, equipped with channels 13 and 14 for supplying gas fuel and air, respectively. The inner channel 15 of the Central cylindrical body 7 passes into the outlet pipe 16 and serves to remove flue gases and moisture vapor that evaporates from the source material. Thus, the heating of the source material 5 moving along the helical groove 1 is carried out both from the heaters 4 and with the help of the flue gases of the burner 12 passing through the internal channel 15 of the central cylindrical body 7. Air enters the combustion zone of gas fuel in the burner 12 through the inlet pipe 14 due to natural traction developed in the channel of the Central cylindrical body 7.

The separator works as follows.

Before starting work include the supply of gas fuel to the burner 12 and its ignition. At the same time, heaters 4 are turned on. The source bulk material (crushed ore, slag from metallurgical industries, etc.) with

using a conveyor (not shown in Fig.) through the hopper 2 it enters the surface of the screw groove 1, the bottom of which vibrates under the action of vibrators 6. Under the influence of gravity and vibration, the bulk feed material slowly flows down the upper turns of the groove 1, where it heats up, giving off steam moisture into the space between the cylindrical bodies 7 and 8. Through holes 11, moisture pairs pass from the space between the bodies 7 and 8 into the channel 15 of the central body 7, where they are picked up by flue gases from the burner 12 and through the outlet pipe 16 are in the atmosphere. The length of the upper turns of the helical groove and the speed of movement of the source material along them are selected so that the initial bulk material, when it enters the lower turns of the helical groove 1, having a larger step in comparison with the upper turns, is practically free of moisture. When moving particles of bulk material from the upper turns of the gutter 1 to the lower turns, the speed of their movement along the gutter 1 increases sharply due to an increase in the angle of inclination of the gutter 1. At the same time, the centrifugal forces acting on the particles of the bulk material moving along the gutter also increase. of centrifugal forces, particles of higher density, for example, metal particles, are pressed to the inner edge of the groove 1, pushing light particles (gangue particles) to the outer edge of the groove 1. In this case, the particles are redistributed by their density along the cross section of the gutter 1. When particles of bulk material come off the bottom turn of the screw gutter 1 using enrichment products 3 cutters 3 vertically mounted on the edge of the gutter 1, the total particle flow is divided into several separate particle flows of different densities (see Fig. 2), which arrive in separate receivers (not shown in FIG.). It should be noted that the process of redistribution of particles of bulk material over the cross section of the groove 1, depending on their density, occurs already on the upper turns of the helical groove. However, this process is carried out more intensively on the lower turns, which have a larger pitch and, therefore, a greater angle of inclination to the horizon. The main purpose of the upper turns of the helical groove 1 is to dry the particles of the starting bulk material and to free them from moisture to prevent them from sticking together and agglomerating when moving along the groove 1. The most intensive process of separation of particles occurs on the lower turns of the helical groove, where the movement of dry particles through the groove is accelerated , and increase, the centrifugal forces acting on them.

Claims (3)

1. A screw separator containing a vertically mounted screw chute, a hopper for loading the source material mounted above the screw chute, and cut-offs of enrichment products installed in the lower part of the screw chute, characterized in that the upper turns of the screw chute are equipped with a device for heating the source bulk material, moving along the gutter, and the evaporation of the moisture contained in it, and several vibrators interacting with the bottom of these turns of the gutter. 2. The separator according to claim 1, characterized in that the helical groove is located between two cylindrical central and external bodies, the inner edges of the groove being rigidly connected to the surface of the central cylindrical body, which serves as a support for the helical groove, a hopper for loading the starting material and cut-offs of enrichment products and the outer edges of the gutter are in close contact with the inner surface of the outer cylindrical body, the outer surface of which is provided with an electric heater in the upper part, central The first cylindrical body in the upper part has openings located above the inner edges of the trough connected to it, and in the lower part of the central body there is a gas burner equipped with channels for supplying gas fuel and air, and the inner channel of the central cylindrical body serves as a channel for exhausting the flue gases of the burner and vapors of moisture evaporated from the starting bulk material. 3. The separator according to claim 1 or 2, characterized in that the pitch of the turns of the spiral groove in its upper part, where the heating devices and vibrators are installed, is made smaller with respect to the pitch of the turns of the spiral groove in its lower part.