RU2709256C1 - Method for recovery of metalliferous sands - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to enrichment of minerals, in particular, to extraction of heavy minerals from sands containing magnetic particles. Method of beneficiation of gold-containing sands includes their disintegration and screening, extraction of magnetic fraction, gravity concentration, intermediate sieving, additional extraction of fine fractions of valuable component into concentrate. Concentration of gravity recovery concentrates and add-extracted fine fractions of valuable component are combined into one product, which is directed for further cleaning at sluice attachment by means of magnetisation and demagnetisation of product by constant field of high intensity and gradient, created by installation of magnetizing and demagnetizing rows of permanent magnets, located from below attachment chute across transported flow. Concentrate separated after cleaning is separated into a rich product and a non-productive fraction of tails. Latter is directed to further successive separation of magnetic and electroconductive fractions by separation. Separated magnetic fraction is returned for reuse in the process of additional extraction of fine classes of the valuable component. Electroconductive fraction containing clusters of bound gold with quartz and sulphide minerals is directed for grinding, subsequent classification with extraction of sink and sands. Draining is returned to circulation, and sands are directed for cyanidation of gold with their intensive mixing. Cyanination tails are sent for decontamination, and working solutions – for subsequent sorption recovery of gold. Attachment magnetic field is created by arrangement of permanent magnets with alternating polarity with number of magnetizing rows of at least two. Demagnetisation of the product is carried out at the outlet of the sluice attachment at concentrate ripening.

EFFECT: higher efficiency of sands dressing.

3 cl, 4 dwg, 1 tbl

Description

There is a known method of enrichment of metal-bearing sands, including the extraction of magnetic particles, the creation of a trapping bed from previously extracted magnetic particles at the bottom of the sluice, the extraction of valuable mineral by supplying sands in the form of pulp to the sluice while simultaneously applying a magnetic field to it from below, removing and finishing the concentrate (see RF patent No. 2168366, B03C 1/08, B03B 5/70, publ. 10.06.2001). In this case, the previously extracted magnetic particles are gradually added to the pulp over a period of time until the concentrate is removed, and the sands are screened (classified) according to the size class of at least 1 mm before being fed to the gateway.

A disadvantage of the known method of sand enrichment is low efficiency, and the extraction of magnetic particles after screening (classification) of sands by particle size class of at least 1 mm is among the costly processes that are difficult to carry out in an industrial environment. In addition, ore particles in intergrowths with gold and sulfide minerals are not extracted, but are delivered with tailings to the dump, which leads to additional losses of the valuable component.

The closest in technical essence to the claimed is a method of sand enrichment, including their disintegration and screening, extraction of the magnetic fraction simultaneously with disintegration and screening, gravity enrichment, retrieval of small classes of a valuable component by feeding tails of gravity enrichment in the form of pulp to the gateway while acting on it a magnetic field from below, creating a trap bed at the bottom of the airlock, picking up and fine-tuning the concentrate. At the same time, a catching bed at the bottom of the gateway is created in the process of retrieval of small classes of valuable mineral by feeding to the gateway simultaneously with the supply of tails of gravitational enrichment of the previously extracted magnetic fraction (see Kazimirov MP, Solodenko AB, Technology and equipment for concentrate dressing washing device ПГШОК-50-2 // III Congress of Concentrators of the CIS Countries March 20-23, 2001, Abstracts of reports. M: MISIS, 2001, p. 222).

The disadvantage of this method of sand enrichment, as in the previous analogue, is also low efficiency, since the extraction of the magnetic fraction is achieved by magnetic separation of the enriched sand, carried out simultaneously with their disintegration and screening, which does not allow to implement this technical solution in industrial conditions, in addition it refers to a very costly process and is not always economically feasible in practice. Moreover, the tails of gravitational enrichment come to retrieve small classes of a valuable component without intermediate screening, which does not allow to ensure, due to the difference in the size of the mineral particles, the optimal technological conditions of the process of recovering metal-bearing sands.

The technical result of the proposed method is to increase the efficiency of sand enrichment due to the recovery of free alluvial and bound gold in intergrowths with quartz and sulfide minerals.

The result is achieved in that the method of enrichment of gold-containing sands, including their disintegration and screening, extraction of the magnetic fraction, gravity enrichment, intermediate screening, retrieval of fine fractions of a valuable component into a concentrate, is characterized in that the combination of gravity concentration concentrates and retrieved small fractions of a valuable component into one product that is sent for further cleaning at the gateway console by magnetizing and demagnetizing the product with a constant a field of high tension and gradient created by the installation of magnetizing and demagnetizing rows of permanent magnets placed at the bottom of the prefix groove across the transported stream, and the concentrate separated after purification is divided into a rich product and an unproductive tail fraction, the latter being sent for further sequential separation by separation of the magnetic and electrically conductive fractions, the separated magnetic fraction is returned for reuse in the process of retrieval of small classes of valuable component, and the electrically conductive fraction containing intergrowths of bound gold with quartz and sulfide minerals is sent for grinding, the subsequent classification with the release of plum and sand, the plum is returned to circulation, and the sands are sent for cyanide gold with vigorous stirring, the cyanide tails are sent for decontamination, and working solutions for subsequent sorption extraction of gold.

The method of sand enrichment is also characterized in that the prefix magnetic field is created by placing permanent magnets with alternating polarity with a number of magnetizing rows of at least two.

The method of sand enrichment is also characterized in that the demagnetization of the product is carried out at the outlet of the lock prefix when rinsing the concentrate.

The invention is illustrated by drawings.

In FIG. 1 presents a flow chart that implements a method of enrichment of gold sands.

In FIG. 2 shows a diagram of the installation of permanent magnets with an indication of the dimensions when placing them under the conveying groove of the lock box.

- view A — parallel arrangement of magnets in the magnetizing row at a distance between them of 20 mm;

- view B is the angular arrangement of the magnets in the demagnetizing row when installing them on the edge.

In FIG. Figure 3 shows the dependence of the change in the magnetic field strength and the calculated magnetic force on the distance between the placed magnets.

The essence of the claimed invention lies in the fact that in the proposed method of enrichment of metal-bearing sands, including their disintegration and screening, extraction of the magnetic fraction, gravity enrichment, retrieval of small classes of a valuable component, concentrates are combined into one rich product with its subsequent purification on a magnetic flocculation lock prefix with simultaneous exposure from below to the catching bed of the airlock with a constant field with a high value of tension and gradient created by by displacing from the bottom of the gutter rows of alternating polarity magnets mounted across the transporting stream of a slurry of mineral particles.

In this case, the optimal value of the field strength and gradient is selected empirically, depending on the parallel and angular arrangement of magnets of alternating polarity (placement on the edge) in the magnetizing and demagnetizing rows.

The tails of the combined rich concentrate are subsequently subjected to magnetic and electrical separation for reuse of the magnetic fraction in the process of recovering small classes of the valuable component, and the conductive fraction containing gold in minerals intergrown with quartz and sulfide minerals is sent for grinding to a ball mill, and then , after the classification of products, the sands are subjected to further intensive cyanide leaching of gold with stirring with the release of working solutions, ravlyaetsya for sorption of gold.

An example of a specific implementation of the method.

The proposed method of sand enrichment is implemented on technological samples taken at different points in the dredging ground of the Jarmagatai deposit. Moreover, for conducting experimental experiments, an average representative technological sample was initially formed from several private samples of mineral raw materials. The prevailing grain size class of free gold was represented by grains of a valuable component of -0.315 mm, and the private yield of ore particles containing bound gold in intergrowths with quartz and sulfide minerals was 17%. The sludge complex of heavy minerals in metal-bearing sands was represented by mineral grains - 4 mm. The main magnetic minerals of concentrates were magnetite, titanomagnetite, and pyrrhotite, which are easily recoverable on separators with a weak magnetic field.

Experimental experiments were carried out on a lock prefix. As a trapping bed, magnetic particles were used (the main containing mineral is magnetite), with a particle size of -2 + 0.15 mm.

Permanent magnets made of a neodymium-iron-boron alloy were used as magnetizing and demagnetizing magnets placed under the chute of the lock prefix. The main dimensional parameters of the magnets used and the change in the dependence of the magnetic field strength and the calculated value of the magnetic interaction force over the magnets with parallel and angular arrangement between them are presented in FIG. 2, 3.

The methodology for conducting experiments on the enrichment of sand in a laboratory setup.

The preliminarily isolated average sample from metal-bearing sands was disintegrated and screened according to size classes of -8 + 16 mm, further screened and gravitationally enriched to isolate the gravity concentrate and to recover small classes of the valuable component (DMK), the concentrates were combined into one product and sent to a further magnetic flocculation cleaning on a lock prefix. Structurally, the gateway prefixing was performed with two magnetizing and one demagnetizing rows of magnets. Moreover, the rows formed of permanent magnets of alternating polarity were installed across the transported stream with a liquid to solid ratio in the pulp of 16: 1. The distance between the parallel-mounted magnets in the rows was 20 mm in the magnetizing rows, and with the angular placement of the demagnetizing magnets at the outlet of the lock prefix, it was 40 mm between the magnets at the top of the poles and 15 mm at the bottom. The angle of inclination of magnets of alternating polarity to the horizontal plane was 14 °. (The adopted parameters for the distance between the magnets and the angle of their inclination to the horizontal plane are determined on the basis of experimental measurements of the optimal magnetic field strength and the calculated value of the magnetic forces).

The combined product was fed into the head of the gateway set-top box with magnetizing and demagnetizing rows of magnets placed below the gateway. The captured rich concentrate was removed and the tailings with a high content of magnetic and conductive fractions were subjected to alternating magnetic and electrical separation. The magnetic fraction was sent for re-extraction of small classes of DMC. An electrically conductive fraction containing bound gold in intergrowths with quartz and sulfide minerals was sent for grinding to a ball mill in order to open up the intergrowths. After the classification of products in a hydrocyclone, plums and sands were isolated. The discharge was sent to a ball mill, and the isolated sands were subjected to cyanide leaching with vigorous stirring of products in order to separate gold into the working solution. The duration of the cyanide leaching of gold in the mixers was 12 hours at a concentration in%: NaCN 0.05-0.1, CaO 0.01-0.3 at a pH of 9-11. After collecting the working solution, it was sent for sorption separation of gold, and the tailings formed for further neutralization.

Comparative indicators of the extraction of free fine gold and sand bound in aggregates with ore particles (quartz and sulfide minerals) are presented in the table (Fig. 4).

Thus, by comparatively evaluating the obtained experimental data — a well-known prototype and proposed by application (table), an increase in the degree of extraction of free gold by 6–7%, and associated gold — by 4.3% was established.

Claims (3)

1. A method of enrichment of gold-containing sands, including their disintegration and screening, extraction of the magnetic fraction, gravity enrichment, intermediate screening, retrieval of fine fractions of a valuable component into a concentrate, characterized in that the combination of gravity concentration concentrates and recovered small fractions of a valuable component into one product, which is sent for further cleaning at the gateway console by magnetizing and demagnetizing the product with a constant field of high tension and the gradient created by the installation of magnetizing and demagnetizing rows of permanent magnets placed at the bottom of the prefix trough across the transported stream, and the concentrate separated after purification is divided into a rich product and an unproductive tail fraction, the latter being sent to further sequential separation by separation of the magnetic and electrically conductive fractions, with the selected magnetic the fraction is returned for reuse in the process of retrieval of small classes of a valuable component, and electric wires the bottom fraction containing intergrowths of bound gold with quartz and sulfide minerals is sent for grinding, the subsequent classification with the release of plum and sand, the plum is returned to circulation, and the sands are sent for cyanidation of gold with vigorous stirring, the cyanidation tails are sent for neutralization, and working solutions - for subsequent sorption extraction of gold. 2. The method of enrichment of sands according to claim 1, characterized in that the prefix magnetic field is created by placing permanent magnets with alternating polarity with a number of magnetizing rows of at least two. 3. The method of sand enrichment under item 1, characterized in that the demagnetization of the product is carried out at the outlet of the airlock prefix when rinsing the concentrate.

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