RU2343983C2 - Separation method and device for its implementation - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention concerns mineral dressing and can be applied in ferrous metallurgy at concentration plants processing magnetite ores. Separation method involves sludge feed to a sloping chute, upper part of which is positioned in magnetic flocculator field for preliminary magnetisation of magnetic particles in the sludge flow, especially in upper layers; exposure of magnetic particles to traveling field of magnetic inductor at the chute bottom; exposure of separated mineral particles to transverse vibration by placing vibrating flat vertical plates into the flow in flow direction; flow height separation at the chute end into upper and lower products. Method is performed by separation device including nonmagnetic chute with flat bottom, mounted at variable angle ranging from 3 to 25 degrees, magnetic flocculator system positioned in the upper part and assembled of constant magnets without polarity alternation, inductor of traveling magnetic field, oscillator connected to vibration cartridge in the form of vertical plate set directed along sludge flow, and separator positioned at the chute end at flow outlet. Distance from lower plate edges of vibration cartridge connected to oscillator to the chute bottom is adjustable.

EFFECT: improved product separation efficiency and ore mineral extraction into heavy product, reduced ore mineral content in light product, enhanced efficiency of the whole technological chain by application of the invention in preliminary concentration.

20 cl, 1 dwg

Description

The invention relates to the field of mineral processing and can be used in ferrous metallurgy at concentration plants processing magnetite ores.

A known method of separation by gravity method, described in the device, in which the main element is a tapering gutter with a flat bottom, installed at an angle of 16-22 °, including the supply of pulp with a density of 40-65% solid in the upper part of the gutter and unloading of stratified mineral particles in the lower end of the gutter in the form of concentrate, intermediate and tails [1].

The disadvantage of this method and device for enrichment is limited productivity, as well as a decrease in the efficiency of the process with an increase in the length of the gutter more than 1 m, a sharp deterioration in performance when fluctuations in the supply volume. In addition, the known method and device is characterized by the fact that the upper layers of the stream, even at the end of the trench, are significantly clogged with small particles of high-density mineral, which is required to be obtained in a heavy product, i.e. into the lower layers of the stream [2]. The upper layers of the flow move with the greatest speed, so the residence time of the mineral particles in their thickness is very short. Thin particles of a heavy ore mineral do not have time to settle and remain suspended in the upper layers until they exit the gutter. The high content in the upper layers of the stream of fine particles of high-density mineral is associated with increased turbulence of the stream. The application of the known method is limited to the enrichment of non-ferrous and rare metals.

A known method of washing ore, implemented in vibration washers (vibration chutes) [3, 4, 5], based on the vibrational impact of their working bodies on the washed material.

The disadvantage of this method and devices is the limited scope, which consists in washing non-metallic building materials, disintegrating clay inclusions and removing the resulting clay suspension. The use of vibrations in these devices is due to the specifics of the problem being solved. The attached vibrations in these devices are designed to better wash clay particles, usually carried out by mechanical stirring in an aqueous medium. The circular vibrations used in these devices do not promote stratification by density, but intensify mixing. In addition, in known devices, vibrations are applied to the body, the outer walls of the trough, which is associated with the energy consumption for the vibration of the entire mass of the device, together with the material inside it.

A known method of separation in electromagnetic separators tray type [6]. A feature of such separators is a magnetic system consisting of longitudinal magnetic cores, in the grooves of which a winding is laid. The feed material is separated in a traveling magnetic field generated by alternating current passed through the windings of the coils.

The disadvantage of this method and devices is limited performance.

The objective of the proposed technical solution is to increase productivity and increase the efficiency of separation of products due to the intensification of the separation process by applying a magnetic field and transverse vibrations.

This is achieved by the fact that in the separation method, which includes feeding the pulp into the upper part of the inclined trough and unloading the mineral particles stratified by the height of the flow at the lower end of the trough in the form of products with different contents of the useful component, the material to be separated is subjected to a magnetic field along the flow path and transverse vibrations (linear vibrations), while the vibrations transmitted to the stratified flow are directed across the flow 1) in the horizontal plane or 2) in the vertical plane. In addition, the magnetic field is set with the ability to change the tension in the direction of flow. In addition, at the beginning of the movement, the flow of the material to be separated is subjected to preliminary magnetization by the action of a weak deep magnetic field. In a separation device containing an inclined trough and a vibration exciter, the latter is attached to a frame on which a series of flat or wedge-shaped rectangular plates are mounted vertically directed along the flow, and the vibrations transmitted to the stratified flow are directed across the flow 1) in a horizontal plane or 2) in the vertical plane. In addition, from the side of the bottom of the gutter made of non-magnetic material, there is an electromagnetic inductor, which is a magnetic system consisting of longitudinal magnetic cores, in the grooves of which a winding is laid, with the possibility of changing the distance to the bottom of the gutter from both sides in the direction of movement of the material. In addition, the trough is installed with the possibility of adjusting the angle of inclination from 3 to 24 ° C. In addition, a flocculator is located on top of the gutter at the power supply section - a permanent magnet magnet system made in monopolar (without alternating poles), with the possibility of changing the distance to the flow of the material to be separated. In addition, at the exit from the gutter there is a divider (cut-off) of products with the ability to change the positioning height in the gutter relative to its bottom. In addition, the trough can be made tapering.

This embodiment of the separation method and device for its implementation can significantly increase the separation efficiency and productivity of the process due to the intensification of the separation process by applying a magnetic field and transverse vibrations. Under the influence of vibrations, the fluidity of the pulp increases, and its speed along the gutter increases. Applying vibration in this way allows both to intensify the process of separation of mineral material in density, and to use small values of the slope to install the gutter. The latter circumstance contributes to a better separation of the material by density and expands the layout and interface of the gutter with subsequent processing equipment.

In addition, the presence of narrow channels between the vertical plates of the exciter reduces the turbulence of the flow, which improves separation. Using a traveling magnetic field prevents siltation of the bottom of the gutter. Particles with a high iron content that settle to the bottom will be transported along it, rolling under the action of a rotating magnetic field.

The use of preliminary magnetization in a weak field promotes a more complete movement (deposition) of magnetic particles from the upper layers of the stream to the lower due to selective flocculation.

The drawing shows a device for implementing the proposed separation method.

The separation method is as follows.

Pulp-shaped crushed material is fed into the upper part of the inclined trough. When moving along the gutter, the mineral particles exfoliate depending on the density. Heavy mineral particles are concentrated in the lower, slowly flowing pulp layer, and the lungs are carried to the upper layers. The power supply to the working area of the device in the initial section is carried out under conditions of reduced magnetic field strength, which causes selective attraction of magnetic particles to each other (flocculation), coarsening upon adhesion with increasing mass of these coarse particles, which contributes to better cleaning of the material of the upper layers of the flow from magnetic particles and moving them to the lower layers of the stream. Once in the range of the running magnetic field of the inductor located at the bottom of the trough, particles with a high metal content accelerate the downward movement. In this case, particles with a high metal content in the bottom region of the trough are rolled in the form of magnetic strands along the bottom towards discharge. Strengthening the process of separation of the mechanical mixture of mineral particles of various densities and increasing the throughput of the device is achieved by increasing the fluidity of the pulp - the effect of artificial liquefaction when applying vibrations.

The use of a unipolar (without alternating polarity) magnetic system of the flocculator allows you to create a deep weak magnetic field extending to a significant depth of flow, due to the low value of the gradient of tension (rate of decrease in tension with distance from the field source). The small magnitude of the magnetic field strength in the range from 4 to 15 kA / m with a low gradient of tension creates the conditions for controlled gradual magnetization, eliminates the possibility of an avalanche-like uncontrolled flocculation, which is characteristic of fields with a higher intensity and gradient. Moreover, the magnitude of the magnetic force directed upward to the source of the magnetic field is negligible. After preliminary magnetization, the probability of deposition of magnetic particles sharply increases due to the formation of magnetic flocs, especially in the zone of application of a traveling magnetic field from the bottom of the gutter. Pre-magnetization in a weak field allows not only to accelerate the further process, but also makes magnetic flocculi more clean, since flocculation is slower and more selective.

The separation device includes a trough 1 with a rectangular or trapezoidal (tapering) bottom installed with the possibility of adjusting the angle of inclination from 3 to 25 ° C, a vibrocassette 2 connected with a vibration exciter 3, a flocculator 4, a traveling magnetic field inductor 5.

From above, a vibro cassette 2 is lowered into the gutter, consisting of a set of flat (or wedge-shaped) rectangular plates arranged vertically, directed along the flow and attached at equal intervals to the frame on which the vibration exciter 3 is attached, and the vibrations transmitted to the stratified flow are directed across the flow. The vibration exciter has a mount on the frame of the vibrocassette with the ability to change the position so that the generated vibrations are directed perpendicular to the direction of flow 1) in the horizontal plane or 2) in the vertical plane. The vibrocassette and the vibration exciter are suspended on spring springs from the supporting truss (mounted above the gutter) with the possibility of adjusting the distance from the vibrocassette to the bottom of the gutter, for example, by means of a screw device.

The gutter is made of non-magnetic material (e.g. plastic).

A flocculator 4 is installed in the upper part of the chute from the loading side - a magnetic system made of permanent magnets without alternating polarity, while the magnetic field strength in the working area at the level of the flow surface has a value in the range from 4 to 15 kA / m.

On the side of the bottom of the gutter there is a magnetic inductor 5, which is a magnetic system consisting of longitudinal magnetic cores, in the grooves of which a winding is laid, with the possibility of changing the distance to the bottom of the gutter from both sides.

In the lower part of the chute from the unloading side a cutter (divider) of products is installed with the possibility of moving in a vertical plane depending on the height of the flow in the chute. By means of a draft system, the cutter is connected to a float that monitors the flow level in the upper part of the gutter. The traction system provides proportional dividing the flow at the outlet for any feed trough performance. The proportion ratio - the ratio between the height of the cut-off layer of the lower product and the total flow height - is set depending on the required quality of the lower product.

The device operates as follows.

In the upper part of the gutter 1 is pulp. Under the influence of gravity and vertical components of the flow velocity, the separation of mineral particles occurs depending on the density and size. Heavy mineral particles are concentrated in the lower, slowly flowing pulp layer, and the lungs are carried to the upper layers.

Under the influence of a magnetic field of low intensity (in the range from 4 to 15 kA / m) created by the flocculator 4, magnetization of magnetic particles occurs and the process of flocculation begins. The most strongly magnetic particles, that is, particles with the highest ore mineral content, become the centers of the flocculi. Due to the low value of the field strength, the process of flocculus formation is relatively slow and selective, which avoids mechanical entrapment of nonmetallic particles into magnetic locks (thus avoiding the avalanche-like production of flocculi). As a result, the flocs are cleaner. The mutual attraction of magnetized particles with the formation of flocs (magnetic strands) contributes to the rapid deposition of these enlarged particles. In this case, the upper layers of the stream are better cleaned from magnetic particles, which are rapidly precipitated in the lower layers of the stream. It is characteristic that the upper location of the magnetic system of the flocculator allows the most intense magnetization of particles in the upper fast-flowing layers, characterized by the greatest involvement of fine and fine particles of a heavy ore mineral. Due to the high speed of the upper layers, their residence time in the trench is significantly reduced. This explains the feasibility of additional intensification of the separation process in the upper layers of the stream. This function is performed by the flocculator and vibrocassette.

Bypassing the pre-magnetization zone in the initial zone of the trough, particles with a high metal content fall into the operating zone of the traveling magnetic field of the inductor 5 located below the trough 1 and accelerate the downward movement. In this case, particles with a high metal content in the bottom region of the groove 1 are rolled in the form of magnetic locks along the bottom towards the discharge side. The mechanical mixture of mineral particles of various densities undergoes stratification when transverse vibrations are transmitted by the exciter 3 through the vibrating plates of the vibrocassette 2. The stratified material at the end of the groove 1 is divided into two streams by a horizontal cutter. At the same time, the positioning of the cutter is provided automatically by a follow-up circuit consisting of a float and a system of rods (levers). When changing the volumetric flow rate, the established proportion (ratio) of the heights of the flow layers is kept constant. The separated streams received at the outlet are diverted to different troughs.

The separation method and device for its implementation can be used for pre-concentration to obtain intermediate products, each of which can be subjected to further processing, for example, heavy (lower) - subsequent concentration, and light (lower) - control scraping with the allocation of tailings.

Thus, the use of the proposed separation method and device for its implementation can reduce the content of ore material in a light (upper) product, thereby increasing the purity of the resulting light (upper) product and increase the extraction of ore mineral in a heavy (lower) product. In addition, the use of the proposed method and device for separation allows you to increase the productivity of the entire process chain when used for pre-concentration purposes.

Information sources

1. S.I.Polkin, E.V. Adamov. Enrichment of ores of non-ferrous and rare metals. - M .: Nedra, 1975, p.213.

2. A.D. Bogatov, Yu.L. Zubynin. Separation of minerals in suspended streams of small thickness. - M .: Nedra, 1973, p. 72.

3. Copyright certificate of the USSR No. 285848, cl. B03b 5/02, 1971

4. Copyright certificate of the USSR No. 310677, cl. B03b 5/02, 1971

5. USSR author's certificate No. 882605, cl. B 03 b 5/02, 1981

6. USSR author's certificate No. 80510, 1949

Claims (20)

1. The separation method, including feeding the pulp into the inclined trough and delaminating it in the direction of the lower discharge end, characterized in that, in order to intensify the deposition of ore mineral particles from the upper layers of the stream and increase the purity of the upper product, the exfoliated material is subjected to transverse vibrations by introducing into the stream vibrating flat plates arranged vertically and directed along the stream. 2. The separation method according to claim 1, characterized in that the plates in the plan have the shape of a wedge (triangle), so that the gap between the surfaces of the vibrating plates gradually decreases along the course of the pulp. 3. The separation method according to claim 1 or 2, characterized in that the vibrations are directed linearly perpendicular to the direction of flow in the horizontal plane. 4. The separation method according to claim 1 or 2, characterized in that the vibrations are directed linearly perpendicular to the direction of flow in the vertical plane. 5. The separation method according to claim 1 or 2, characterized in that, in order to intensify the deposition of particles of ore minerals with magnetic properties from the upper layers of the stream and increase the purity of the upper product, the stratified material is exposed to a magnetic field, while the magnetic field at the level of the flow surface is in the range of 4-15 kA / m. 6. The separation method according to claim 1 or 2, characterized in that, in order to intensify the deposition of particles of ore minerals with magnetic properties, and its transportation, the separation is carried out when exposed to a traveling magnetic field, while the current direction is selected so that the magnetic strands rotating material rolled in the direction of discharge in the lower part of the inclined trough. 7. The separation method according to claim 1 or 2, characterized in that, in order to stabilize the separation indicators when changing the volumetric flow rate, provide a constant ratio of the level of elevation of the flow divider above the bottom of the gutter to the surface level of the flow at the discharge end of the gutter. 8. A device for separation, containing installed with the possibility of changing the angle of inclination from 3 to 25 °, a gutter with a flat bottom and a vibration exciter, characterized in that the vibration exciter is connected with a vibrocassette, which is a block of flat plates located vertically and directed along the stream, while the vibrocassette associated with the vibration exciter, is installed with the ability to change the distance from the lower edges of the plates to the bottom of the gutter. 9. The separation device according to claim 8, characterized in that the plates in the plan have the shape of a wedge (triangle), so that the gap between the surfaces of the vibrating plates gradually decreases along the course of the pulp. 10. The separation device according to claim 8 or 9, characterized in that the bottom of the gutter is trapezoidal, tapering towards discharge. 11. The separation device according to claim 8, or 9, characterized in that the vibration exciter is mounted on the frame of the block of vertical plates with the possibility of changing the direction of vibration in a plane perpendicular to the direction of flow of the pulp. 12. The separation device according to claim 10, characterized in that the vibration exciter is mounted on the frame of the block of vertical plates with the possibility of changing the direction of vibration in a plane perpendicular to the direction of flow of the pulp. 13. The separation device according to claim 8 or 9, characterized in that the trough is made of non-magnetic material. 14. The separation device of claim 10, wherein the trough is made of non-magnetic material. 15. The separation device according to claim 13, characterized in that a flocculator is installed above the upper part of the chute — a magnetic system made of permanent magnets without alternating polarity, while the magnetic field strength in the working area at the level of the flow surface has a value in limits from 4 to 15 kA / m. 16. The separation device according to claim 14, characterized in that a flocculator is installed above the upper part of the chute — a magnetic system made of permanent magnets without alternating polarity, while the magnetic field strength in the working area at the level of the flow surface has a value in limits from 4 to 15 kA / m. 17. The separation device according to item 13, wherein the running magnetic field inductor is located on the bottom of the gutter, which is a magnetic system consisting of longitudinal magnetic cores, in the grooves of which a winding is laid, with the possibility of changing the distance to the bottom of the gutter from both its parties. 18. The separation device according to 14, characterized in that on the side of the bottom of the gutter there is a traveling magnetic field inductor, which is a magnetic system consisting of longitudinal magnetic cores, in the grooves of which a winding is laid, with the possibility of changing the distance to the bottom of the gutter from both its parties. 19. The separation device according to claim 8 or 9, characterized in that in the lower part of the chute from the discharge side there is a cutter (divider) of products with the ability to move in a vertical plane depending on the height of the flow in the chute, while the cutter is connected by a traction system with a float that monitors the flow level in the upper part of the gutter in such a way that a proportional division of the output flow is ensured for any gutter power supply. 20. The separation device according to claim 10, characterized in that in the lower part of the chute from the discharge side there is a cutter (divider) of products with the ability to move in a vertical plane depending on the height of the flow in the chute, while the cutter is connected by a rod system to the float, monitoring the flow level in the upper part of the gutter in such a way that a proportional division of the output flow is ensured for any gutter power supply.