RU2811860C1 - Centrifugal concentrator - Google Patents

Abstract

FIELD: mineral processing.

SUBSTANCE: proposed invention is related to devices designed for mineral processing, and can be used to separate solid particles by density, in particular, to process gold ores and fine sands. The centrifugal concentrator comprises a hollow rotor connected to a bowl placed in its cavity, which has a cylindrical wall with recesses on the inner surface between the annular protrusions and with holes for injecting liquid into the recesses from the liquid supply device through the hollow rotor shaft and the cavity between the walls of the rotor and the bowl. In the recesses between the annular protrusions, annular cavities are formed with edges converging towards the outer surface of the bowl, on which corrugations are made, and in the upper expanded part of the recesses, permeable plugs covering the annular cavities are installed, consisting of a mesh, traps connected to it and polymer veins. The corrugation on the edges of the annular cavities is formed by protrusions that form a curvilinear spiral located around the axis of the bowl, pine with a rotor, and one end of the spiral is close to the inner surface of the bowl in the wide part of the recess, and the second end is distant from the axis of the bowl and is located in the narrow part of the recess, whereas the spirals on opposite faces of the annular cavity are shifted relative to each other by half the base of the section of the spiral protrusion.

EFFECT: increased efficiency of segregation of separated particles.

6 cl, 2 dwg

Description

The invention relates to devices intended for the beneficiation of minerals, and can be used to separate solid particles by density, in particular for the processing of gold ores and fine sands.

A centrifugal concentrator is known, which is a device containing a monolithic cone-shaped concentration bowl with grooves on the inner surface formed by annular protrusions, installed in a hollow rotor with the possibility of rotation and periodic alternating changes in the speed of rotation of the bowl in such a way that a shift occurs in the pulp layer adjacent to the wall relative to the upper its layers and the displacement of the pulp relative to the grooves of the bowl. The side wall of the frame contains a number of metal annular frame ribs. The working surface of the concentration bowl is formed by the inner surface of the concentration bowl and contains a number of annular protrusions formed by the annular ribs of the frame, and annular cavities located between them [RU 2579160 C1, publ. 04/10/2016].

The disadvantages of the device are the design features of a cone-shaped bowl with an internal working surface formed by annular protrusions with grooves between them, as well as the complexity of the concentrator design due to the possibility of changing the parameters of the drive with interacting magnets when selecting the separation mode.

A centrifugal concentrator is known, containing a rotatably installed hollow rotor connected to a centrifuging bowl placed in its cavity, including annular grooves-recesses with holes for injection of wash water entering through the hollow rotor shaft and the cavity between the walls of the rotor and the centrifuging bowl, a loading device enriched material into a centrifuging bowl, a device for supplying wash water and a device for removing the heavy fraction. The said centrifuging bowl is made as a composite and includes a base and a cylindrical side wall. There is a series of slots at the base of the centrifuging bowl, and a series of through holes at the upper edge of the rotor wall. Rotation of the rotor is ensured by an electric motor installed with the ability to change the speed of rotation of the rotor due to movement along the height of the V-belt rotation transmission from the electric motor pulley to one of the two working diameters of the pulley [RU 2763488, publ. 12/29/2021].

The disadvantage of this centrifugal concentrator is the difficulty in selecting the separation mode.

A known bowl of a centrifugal concentrator contains a removable elastic conical liner, which has annular grooves on the inner surface, one of which exceeds the height of the others. This higher riffle is located in the upper area of the bowl. The wall of this riffle and/or the wall of the bowl in the place where this riffle adjoins it is provided with holes. The height of the specified riffle can exceed the height of the other riffles by 1.5-3 times. Thus, in all inter-rib grooves, the same conditions are created for the enrichment of the material, which contributes to the effective concentration of heavy particles and their extraction by removing the liner and turning it outward [RU 2151642, publ. 06/27/2000].

This design increases the extraction of the useful component into the concentrate. The disadvantage of the device is the complexity of the design, since it is necessary to provide shaking movements to accelerate the concentration of heavy particles.

A common disadvantage of the centrifugal concentrators described above, which limits their practical use, is that under the influence of centrifugal force, solid particles from the wash water settle inside these concentrators, accompanied by compaction of the sediment, which gradually leads to the filling of the rotor cavities with solid (silty-clayey) particles . The consequence of this is the limitation of the supply of washing water to the centrifuging bowl, up to the complete cessation of material separation in it.

As a prototype, a centrifugal concentrator is adopted, containing a hollow rotor connected to a bowl placed in its cavity, having an internal surface with recesses between the annular protrusions and holes for injecting liquid into the recesses from the device for its supply through the hollow rotor shaft and a cavity between the walls of the rotor and the bowl, wherein the bowl is made with a cylindrical wall, in the recesses of which, between the annular protrusions, annular cavities are formed with edges converging towards the outer surface of the bowl, on which partitions of a triangular shape in the longitudinal section are concentrically located, offset relative to the partitions on the opposite side by half the length of the base of the triangle and directed towards the axes of the holes for liquid injection, and in the upper part of the recesses forming the annular cavities, a permeable plug is installed, consisting of traps, mesh and polymer veins [RU 2778769, publ. 08/24/2022, prototype].

The disadvantage of the prototype is that in such separators it is possible to enrich gold ores having a relatively wide range of particle sizes, for example, -5(3)+0 mm. However, when enriching materials with an increased amount of large minerals with low and medium (sulfides, magnetite, etc.) specific gravity, enrichment indicators, namely the degree of gold concentration, the completeness of its extraction and the productivity of separators, are reduced due to the inevitable accumulation of large particles of waste rock , and especially poorly rounded and unrounded (angular) shapes, in the corners between the annular partitions of the inner part of the recesses and reducing the loosening effect. In addition, to effectively remove them from the recesses by slipping the annular partitions towards the axis of rotation of the rotor, either a pulsed supply of loosening water or a change in the rotor rotation speed is necessary, which will inevitably lead to disruption of the structure of the formed bed.

The technical problem solved by the invention is to increase the efficiency and productivity of the ore enrichment process by enhancing the segregation effect of separated particles.

The technical result of the invention is to enhance the segregation of separated particles in the recesses of the bowl by making protrusions on the edges of the annular cavities, forming a curvilinear spiral located around the axis of the bowl approaching the inner surface of the wall and moving away from it, which helps to change the dynamics of particle movement in the near-wall zones of the recess .

To solve a technical problem and achieve a technical result, a centrifugal concentrator is proposed, containing a hollow rotor connected to a bowl placed in its cavity, having a cylindrical wall with recesses on the inner surface between the annular protrusions and with holes for injecting liquid into the recesses from a liquid supply device through a hollow shaft rotor and the cavity between the walls of the rotor and the bowl. In this case, in the recesses between the annular protrusions, annular cavities are formed with edges converging towards the outer surface of the bowl, on which corrugations are made, and in the upper expanded part of the recesses, permeable plugs are installed that cover the annular cavities, consisting of a mesh, traps connected to it and polymer veins. What is new is that the corrugation on the edges of the annular cavities is formed by protrusions that form a curvilinear spiral located around the axis of the bowl, pine with a rotor, and one end of the spiral is close to the inner surface of the bowl in the wide part of the recess, and the second end is distant from the axis of the bowl and is located in narrow part of the recess, while the spirals on opposite sides of the annular cavity are shifted relative to each other by half the base of the section of the spiral protrusion.

According to the invention, for its implementation, special cases of spiral design are possible, reflected in the dependent claims of the invention.

According to the invention, the spirals are formed by protrusions of a triangular cross-section.

According to the invention, the spirals are formed by protrusions of rectangular cross-section.

According to the invention, the spirals are formed by protrusions of a semicircular cross-section.

According to the invention, the spirals are formed by protrusions of arbitrary shape with their height decreasing as they move away from the axis of the bowl.

According to the invention, the spirals are formed by protrusions of arbitrary shape with their height increasing as they move away from the axis of the bowl.

The arrangement of the spirals on both sides of the annular cavity, offset with respect to the opposite side by half, for example, the length of the base of the triangle, allows for alternating direction of the flow of separated particles into zones of flows circulating at different speeds and accelerations, which contributes to a change in their dynamics.

With the help of these spirals, when the rotor rotates, large particles of waste rock, moving with a delay in relation to the inner surface of the bowl, are forcibly removed from the recesses towards the axis of the bowl, by analogy with the operation of a spiral elevator, and then into the tailings. At the same time, due to the rolling and mechanical lifting of particles in a spiral, the loosening of the compacted wall layer is enhanced, as well as the segregation of small heavy grains.

Figure 1 schematically shows a centrifugal concentrator, in particular a longitudinal section of the concentrator bowl; in fig. 2 shows a cross section A-A in FIG. 1, where:

1 - holes for liquid injection,

2 - spirals,

3 - semi-cylindrical traps,

4 - polymer intertwined veins,

5 - mesh,

6 - ring fastening of traps with mesh,

7 - supply pipe,

8 - recesses representing annular cavities,

9 - ring protrusions,

10 - concentrator bowl.

The centrifugal concentrator works as follows.

The enriched material, containing particles of heavy and light fractions and subject to enrichment, is fed through a stationary supply pipe 7 into the rotating bowl 10 of the concentrator located in the rotor cavity (not shown in the figure). Under the influence of centrifugal forces, the particles move to a permeable plug consisting of intertwined polymer veins 4, a mesh 5 connected to semi-cylindrical traps 3 using a ring mount 6, and are subjected to a counter uniformly distributed slow flow of liquid injected through holes 1. The plug prevents entry large particles into recess 8, and a uniform upward flow of loosening water is created, as well as a zone of preliminary concentration of heavy particles. Particles, moving continuously along the surface of the plugs, form a fluidized layer, turbulence and suction of water flows occur, while capturing and retaining predominantly small heavy particles and continuously cleaning them (washing off large light ones). Most of the light particles in the fluidized bed are washed into the tailings as a result of segregation and the action of an upward slow flow of liquid. Passing through the mesh 5, heavy and relatively large light particles under the action of centrifugal forces fall into the zones of action of traps 3. Further, the particles, moving towards the walls of the recesses 8, along them and the walls of the spirals 2, are captured in larger vortices of water accelerating closer to the fluid injection holes 1. In this case, the spirals 2, formed by protrusions, for example, of a triangular cross-sectional shape, which is the most optimal, with their vertices directed towards the axes of the holes for the injected liquid, due to the displacement relative to the spirals on the opposite side by half the length of the base of the triangle, make it possible to create a cascade, continuously changing during Each revolution of the bowl, the nature of the movement of particles from circulation zones with smaller ones to circulation zones with high speeds of water flows under the influence of centrifugal accelerations, as well as in the opposite direction when their concentration is critical (overflow), which allows to prevent the retention of relatively large particles of waste rock and fill more evenly the volume of recesses with 8 heavy particles of a valuable component.

In this case, in addition to the triangular cross-sectional shape of the spiral protrusions, a rectangular cross-sectional shape of the protrusions or a semi-cylindrical cross-sectional shape can also be used. At the same time, it is possible to make a spiral with a varying height of the protrusions, increasing or decreasing with distance from the axis of the bowl, which also helps to change the dynamics of the particle flow.

The light fraction is removed by gravity through the upper overflow side of the bowl 10 and then through the drain pipe (not shown).

After the completion of the accumulation cycle of the heavy fraction (concentrate), the supply of the enriched material stops, the rotation of the bowl 10 slows down, and the consumption of injected water increases to wash the recesses 8 from concentrated particles and remove the concentrate.

Thus, the inventive centrifugal concentrator, in the presence of design changes in the annular cavity of the bowl, makes it possible to enhance the effect of loosening the enriched material during fluid injection due to the dynamics of the flow of the wall region, as well as the segregation of separated particles in the recesses of the bowl, and, consequently, increase the efficiency and productivity of the ore enrichment process .

Claims (6)

1. A centrifugal concentrator containing a hollow rotor connected to a bowl placed in its cavity, having a cylindrical wall with recesses on the inner surface between the annular protrusions and with holes for injecting liquid into the recesses from the device for its supply through the hollow rotor shaft and the cavity between the walls of the rotor and bowls, while in the recesses between the annular protrusions, annular cavities are formed with edges converging towards the outer surface of the bowl, on which corrugations are made, and in the upper expanded part of the recesses, permeable plugs are installed that cover the annular cavities, consisting of a mesh, traps connected to it and polymer veins , characterized in that the corrugation on the edges of the annular cavities is formed by protrusions that form a curvilinear spiral located around the axis of the bowl, a pine with a rotor, and one end of the spiral is close to the inner surface of the bowl in the wide part of the recess, and the second end is distant from the axis of the bowl and is located in narrow part of the recess, while the spirals on opposite sides of the annular cavity are shifted relative to each other by half the base of the section of the spiral protrusion. 2. Centrifugal concentrator according to claim 1, characterized in that the spirals are formed by protrusions of a triangular cross-section. 3. Centrifugal concentrator according to claim 1, characterized in that the spirals are formed by protrusions of a rectangular cross-section. 4. Centrifugal concentrator according to claim 1, characterized in that the spirals are formed by protrusions of a semicircular cross-section. 5. Centrifugal concentrator according to claim 1, characterized in that the spirals are formed by protrusions with a decrease in their height as they move away from the axis of the bowl. 6. Centrifugal concentrator according to claim 1, characterized in that the spirals are formed by protrusions with their height increasing as they move away from the axis of the bowl.

Images