RU2151646C1 - Pneumatic flotation machine - Google Patents

Abstract

FIELD: concentration of minerals by flotation method; coarse-grained flotation of ore and non- valuable raw materials. SUBSTANCE: flotation machine includes flotation chamber, slotted sifting surface, device for supply of coarse- grained feed to foam layer made in form of hollow ring with inlet branch pipes located tangentially over diameter of ring and slotted outlet from inner cavity in its lower portion. Outer wall of hollow ring is cone- shaped in its lower portion. Machine is provided with device for loading fine-grained pulp located along axis of chamber and made in form of vertical cylinder; this device is provided with intake ring-shaped shaped fitted with inlet branch pipes and having circular outlet to cylinder interior. Pipe-shaped mixer mounted along axis of flotation chamber is made in form of ejector whose upper portion is connected to lower end of cylinder. Machine is also fitted with branch pipe for discharge of chamber product, foam receiving chute, pneumohydraulic aerator unit, parabolic reflector coaxially secured under pipe-shaped mixer with circular clearance relative to its lower end. Inner cavity of coarse-grained feed supply device is tightly separated from inner cavity of ring-shaped intake chamber by means of cone-shaped wall; distributing disk is fitted inside hollow ring below level of inlet branch pipes at spaced relation to outer wall of ring. EFFECT: improved quality of flotation process due to improved aerodynamic mode of operation. 2 dwg

Description

 The invention relates to the field of mineral processing by flotation, in particular to devices for the separation of minerals, and can be used for coarse flotation of ore and non-metallic materials, and can also be used in flotation treatment of industrial and wastewater.

 Known pneumatic flotation machine containing a flotation chamber, made in the form of a cone-shaped vessel expanding upward with a bell in the upper part, a slit-like screening surface with a slit cross section increasing from the axis of the flotation chamber located at the top edge of the flotation chamber, a device for supplying coarse-grained food to the foam layer made in the form of a hollow ring with inlet pipes tangentially spaced along the diameter of the ring communicated with its inner polo a thaw, and with a slit-like exit from the inner cavity in its lower part directly onto the slit-like screening surface, a device for loading fine-grained pulp, a tube-shaped mixer mounted along the axis of the flotation chamber, a nozzle for unloading the chamber product, a foam-shaped chute located at the upper edge of the flotation chamber, pneumohydraulic aerator, parabolic reflector, open with its part facing in the direction opposite to the pneumohydraulic aerator / 1 /.

 The disadvantage of this machine is the lack of structural elements in it, which ensure optimization of the aerohydrodynamic mode of its operation and optimization of pulp aeration in the chamber of the machine, which reduces the quality of the flotation process realized in it. In particular, in this machine, the aerated liquid is fed into the volume of the chamber for aeration of the flotation pulp by pneumohydraulic aerators when high-speed jets of aerated liquid are introduced from the nozzles of these aerators directly into the flotation zone. As a result of this, a highly turbulent regime is created at the places of introduction of these jets, which impedes the effective flotation of particles of a useful component, especially large ones.

 The closest in technical essence and the achieved result is a pneumatic flotation machine containing a flotation chamber, made in the form of a cone-shaped vessel expanding upwards with a bell in the upper part, a slit-like sieving surface with a slit cross section increasing from the axis of the flotation chamber located at the level of the upper edge of the flotation chamber, device for supplying coarse-grained nutrition to the foam layer, made in the form of a hollow ring with tangentially arranged dia meter of the ring with inlet pipes and with a slit-like exit in its lower part directly to the slit-like screening surface, while the outer wall of the hollow ring in its lower part is conical, placed along the camera axis and made in the form of a vertically arranged cylinder, a device for loading fine-grained pulp, equipped with above the device for supplying coarse-grained food with an annular receiving chamber with inlet pipes and with an exit to the inner cavity of the cylinder, a tube-shaped mixer mounted along the axis of the flotation chamber, made in the form of an ejector, an upper part attached to the lower end of the cylinder, a nozzle for unloading the chamber product, a foam collecting chute located at the upper edge of the flotation chamber, a block of pneumohydraulic aerators, coaxially placed directly above the device for loading fine-grained pulp , parabolic reflector, open with its part facing in the direction opposite to the pneumohydraulic aerators, coaxially fixed along tubular mixer with an annular gap relative to its lower end, the diameter of the end portion of the parabolic reflector is greater than the diameter of the tubular end of the mixer / 2 /.

 The known machine / 2 / largely eliminated the disadvantages noted in the machine / 1 /, leading to a decrease in the quality of the flotation process. However, here, there is a slight decrease in the quality of the flotation process, since it lacks structural elements that provide optimization of the aero-hydrodynamic mode of its operation. In particular, in the machine / 2 /, the internal cavities of the device for supplying coarse-grained food and the annular receiving chamber of the device for loading fine-grained pulp are interconnected by means of annular passages. As a result of this, excessive flooding of coarse-grained nutrition entering the foam layer occurs. As a consequence of this, the aerohydrodynamic mode of the machine’s operation is deteriorating, especially during foam separation of the coarse-grained part of the feed, which leads to a decrease in the quality of the flotation process. The latter also occurs with a decrease in the total water consumption in the machine in order to exclude the water cut of coarse-grained food. Moreover, due to the lack of necessary structural elements in the machine, in particular in its feeding device, the distribution of coarse-grained particles over the area of the foam layer and the dispersal of mineral grains among themselves deteriorate, which also leads to a decrease in the quality of the flotation process and especially the foam separation process.

 The aim of the invention is to improve the quality of the flotation process by improving the aerohydrodynamic mode of operation.

 According to the invention, this goal is achieved in that in a pneumatic flotation machine containing a flotation chamber, made in the form of a cone-shaped vessel expanding upward with a bell in the upper part, a slit-like screening surface located at the level of the upper edge of the flotation chamber with a cross section of slots increasing from the axis of the flotation chamber, a device for supplying coarse-grained food to the foam layer, made in the form of a hollow ring with input parallels located tangentially along the diameter of the ring cuttings and with a slit-like exit in its lower part directly onto the slit-like screening surface, while the outer wall of the hollow ring in its lower part is conical, arranged along the chamber axis and made in the form of a vertically arranged cylinder, a device for loading fine-grained pulp, equipped with a device located above the device for supply of coarse-grained power with an annular receiving chamber with inlet nozzles and with an exit to the internal cavity of the cylinder mounted along the axis of the flo a tube-shaped mixer made in the form of an ejector with the upper part of the cylinder attached to the lower end, a nozzle for unloading the chamber product, a foam collection chute located at the upper edge of the flotation chamber, a block of pneumohydraulic aerators coaxially located directly above the device for loading fine-grained pulp, a parabolic reflector, open part facing towards the pneumohydraulic aerators, coaxially mounted under the pipe-shaped mixer m with an annular gap with respect to its lower end, and the diameter of the end part of the parabolic reflector exceeds the end diameter of the tube-shaped mixer, the inner cavity of the device for supplying coarse-grained food is tightly separated by a conical wall from the inner cavity of the annular receiving chamber, and inside the hollow ring below the level of its inlet nozzles installed with a gap in relation to the outer wall of the ring distribution disk.

 When creating the invention, the authors proceeded from the following.

 To optimize any separation process, it is necessary to provide the conditions for the maximum possible reduction in the turbulence of the pulp flows inside the separation apparatus. As for pneumatic flotation machines, their aerohydrodynamic operation can be significantly improved if the mixing zones of the pulp are separated from each other when it is saturated with air bubbles by means of pneumohydraulic aerators and the zone of direct flotation separation of the components of this pulp. In the flotation enrichment of a material with a wide range of particle sizes, it is necessary to provide a differentiated approach to food fractions of various sizes. For machines with a large unit capacity, where the input power flow is very large, the dispersion of the input power, as well as the method of introducing it into the device depending on the size of the enriched material, is essential to reduce pulp turbulence inside the apparatus, namely in its separation zones.

 As for the largest and heaviest part of the feed, it should be fed to the flotation apparatus according to the principle of foam separation on the surface of the foam layer with the maximum dispersal of the mineral grains among themselves and with a minimum amount of pulp liquid phase. In this case, the velocity vector of the supplied power should be directed along the surface of the foam layer in the direction of the foam gutter. This complies with the requirements of the mechanism of the foam separation process.

 Coarse-grained material of a smaller size should be fed into the flotation apparatus along the chamber axis from the bottom up in the form of a thoroughly mixed aerated pulp, so that the velocity vector of this aerated pulp stream coincides with the vector of Archimedean forces. This corresponds to the flotation conditions of larger mineral grains of the useful component from the volume of aerated pulp.

 These requirements are most fully satisfied by the design of the proposed pneumatic flotation machine. Details of the technical solutions adopted are set forth below in its description.

 In FIG. 1 shows a sectional view of a pneumatic flotation machine; in FIG. 2 is a top view of the machine.

 Pneumatic flotation machine consists of a flotation chamber 1 with a pipe 2 for the output of the tails, made in the form of a cone-shaped vessel expanding upwards with a bell in the upper part. On the periphery of the upper part of the flotation chamber 1, a foam collecting chute 3 is fixed with a pipe 4 for outputting the foam product. At the level of the upper edge, the flotation chamber 1 has a disk-shaped coaxially located slit-like screening surface 5 with a section of slots 6 increasing from the axis of the flotation chamber, above which is coaxially arranged a device 7 for supplying coarse-grained food to the foam layer, made in the form of a hollow ring 8 with tangentially arranged along the diameter of the ring by the inlet 9. The hollow ring 8 in the lower part of the outer wall 10 has a slit-like outlet 11 from its internal cavity directly to the slit-like gap ivayuschuyu surface 5. The outer wall 10 on the lower part directly above the exit slit 11 is tapered.

 A device 12 for loading a fine-grained pulp made in the form of a vertically arranged cylinder 13 is placed along the axis of the chamber 1, to the lower end of which there is attached a tube-shaped mixer 14, which is supported by the walls of the chamber 1 by means of radial ribs 15 and 16. Above the loading device 12 a block of fine-grained pulp is coaxially fixed with a block of pneumohydraulic aerators 17. Under the tube-shaped mixer 14, a parabolic reflector 19 is coaxially placed with an annular gap 18, its open part facing in the direction opposite to the pneumohydraulic aerators 17 and resting through the radial ribs 20 on the walls of the chamber 1. The parabolic reflector 19 for maintaining its configuration during operation of the machine is made of wear-resistant material, for example, siliconized graphite, cermet or polyurethane. The diameter of the end part of the parabolic reflector 19 exceeds the end diameter of the tube-shaped mixer 14.

 The device 12 for loading fine-grained pulp is provided with an annular receiving chamber 20 located above the device 7 with inlet pipes 21 and with an annular outlet 22 into the internal cavity of the cylinder 13. To prevent water-cut of the coarse-grained food supplied to the foam layer, the internal cavity of the device 7 is tightly separated by a conical wall 23 from the inner cavity of the annular receiving chamber 20. Inside the hollow ring 8 below the level of its inlet pipes 9 is installed with a gap 24 with respect to Shnei ring wall 8 distributing disc 25, intended for dispersal coarse power supplied to the foam layer. The block of pneumohydraulic aerators 17 is equipped with a water supply pipe 26 and an air supply fitting 27.

 Pneumatic flotation machine operates as follows.

 The flotation chamber 1 is filled with water with a foaming agent. At the same time, water and air are supplied to the block of pneumohydraulic aerators 17 under pressure through a water supply pipe 26 and an air supply fitting 27. In the supply pipe 9 and the inlet pipe 21 serves flotation pulp, pre-treated with flotation reagents. From the nozzles 9, the coarse-grained pulp is tangentially introduced into the hollow ring 8 of the device 7 for supplying coarse-grained food to the foam layer. Under the action of a pair of forces of two flows, since the nozzles 9 are located tangentially along the diameter of the ring 8, the pulp acquires a rotational movement inside the ring. After unwinding the pulp, its coarse fraction, moving under the action of centrifugal forces along the conical surface of the outer wall 10 of the ring 8, is discharged in a condensed form from the ring through a slit-like outlet 11 located in its lower part, directly onto the slit-like screening surface 5 with a section of slots 6 increasing from the axis of the flotation chamber 1, where the dispersion of particles over the area and between themselves. This is facilitated by the fact that the coarse-grained material emerging from the nozzles 9 partially enters the distribution disk 25, where it is preliminary dispersed, and then enters through the gap 24 onto the conical surface of the outer wall 10 of the ring 8.

 The fine-grained pulp introduced into the machine through the inlet pipes 21 first enters the annular receiving chamber 20, then through the annular outlet 22 it enters the device 12, where it is mixed with aerated liquid exiting the nozzles of the pneumohydraulic aerators 17, and then through a tube-shaped aerator the mixer 14 enters the volume of the chamber 1. In the flotation chamber 1, an aero-hydromix is formed with finely dispersed air, and a foam layer forms on its surface, which overflows into the foam collection chute 3.

 In the cylinder 13 of the device 12, the flows of pulp and aerated liquid are mixed and their velocities are equalized, after which the combined stream is directed to the diffuser of the tube-shaped mixer 14, where its kinetic energy is converted into the potential energy of the compressed stream, which strikes the parabolic reflector 19. The latter changes the trajectory the incoming flow of aerated pulp to the reverse with the formation of a more dispersed annular configuration thereof when entering through the annular gap 18 into the flotation chamber 1. In this case, the velocity vector of this aerated pulp stream coincides with the vector of Archimedean forces, which corresponds to the flotation conditions of larger mineral grains of the useful component from the volume of aerated pulp. In the tube-shaped mixer 14, along with intensive aeration of the introduced pulp, its very intensive mixing with finely dispersed air bubbles also takes place. After entering the aerated pulp into flotation chamber 1, optimal internal aerohydrodynamics of fluid flows is formed in it, as well as the directional movement of the foam layer from the place of loading onto it through slots 6 of the slit-like screening surface 5 of the coarse-grained feed fraction to the foam gutter 3. Large particles of power are distributed in dispersed form to the surface of the foam on top. The hydrophobic and hydrophobized particles of the useful component are retained by the foam layer and are carried out together with it and with the particles flotted from the volume of the pulp into the foam collecting trough 3, from where they are discharged through the pipe 4 to withdraw the foam product. Hydrophilic waste rock particles pass through the foam into the volume of the flotation chamber 1, fall onto the inclined walls of the chamber 1, slide down them and fall into the zone of upward flow of aerated pulp leaving the annular gap 18. This flow captures the pulp from the chamber, forming its intracameral circulation , which provides the possibility of re-extraction of particles of a useful component that accidentally fell out of the foam layer without reaching the foam collecting trough 3. The configuration of the flotation chamber itself plays an important role in this s 1, configured as a cone expanding upward from the funnels of the vessel in its upper part. Particles of the useful component are floated in the stream of aerated pulp and enter the 3 foam layer moving towards the foam collecting chute. Particles of waste rock settle on the wall of the flotation chamber 1 and are discharged from the machine through the pipe 2.

 Thus, the proposed technical solution in comparison with the prototype will allow to improve the quality of the flotation process by improving the aero-hydrodynamic mode of operation.

Sources of information taken into account when preparing the application
1. RF patent N 2011413 dated 04.29.91, cl. B 03 D 1/24, publ. 04/30/94, Bull. 1994, N 8.

 2. RF patent N 2113910 dated 12/15/96, cl. B 03 D 1/24, publ. 06/27/98, Bull. 1998, N 18 (prototype).

Claims (1)

 A pneumatic flotation machine containing a flotation chamber made in the form of a cone-shaped vessel expanding upward with a bell in the upper part, a slit-like screening surface with a slit cross section increasing from the axis of the flotation chamber at the top edge of the flotation chamber, a device for supplying coarse-grained food to the foam layer, made in the form of a hollow ring with inlet pipes tangentially located along the diameter of the ring and with a slit-like outlet in its lower part directly on the slit-like screening surface, while the outer wall of the hollow ring in its lower part is conical, arranged along the axis of the chamber and made in the form of a vertically arranged cylinder, a device for loading fine-grained pulp, equipped with an annular receiving chamber located above the device for supplying coarse-grained food with inlet nozzles and with the exit to the internal cavity of the cylinder mounted on the axis of the flotation chamber, a tube-shaped mixer is made th in the form of an ejector, the upper part of the cylinder attached to the lower end, a pipe for unloading the chamber product, a foam chute located at the upper edge of the flotation chamber, a block of pneumohydraulic aerators, coaxially placed directly above the device for loading fine-grained pulp, a parabolic reflector, open with its part facing in the direction opposite to the pneumohydraulic aerators, coaxially fixed under the pipe-shaped mixer with an annular gap with respect to its lower torus y, and the diameter of the end part of the parabolic reflector exceeds the end diameter of the tube-shaped mixer, characterized in that the inner cavity of the device for supplying coarse-grained food is tightly separated by a conical wall from the inner cavity of the annular receiving chamber, and is installed inside the hollow ring below the level of its inlet pipes with a gap with respect to to the outer wall of the ring distribution disk.

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