RU2117530C1 - Method of estimating contents of precious and rare-earth metals - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: method is applicable, for example, when estimating placer gold in rejects of gold-mining industry. Sample is treated to produce placer complex and slag. Fraction 2 mm is separated from the former and is combined with treatment sludge to form pulp that is subjected to gravity concentration in centrifugal field with intensity 30 to 600 g. Loosening degree of pulp is maintained at the level 0.3-0.5, which is found from mathematical expression. According to invention, pulp in centrifugal field is additionally turbulized. EFFECT: enabled correct determination of gold content in particular test sites and reliable detection of circles with elevated concentrations of metal in examined pits. 6 cl, 2 dwg

Description

 The invention relates to the mining industry, in particular, to a method for assessing the content of noble and rare-earth metals, for example alluvial gold, in deposits and dumps of the gold mining industry.

 The urgent problem of the gold mining industry is the problem of correctly assessing the gold content at specific sampling points and the reliable detection of halos of increased metal concentration in the studied sections.

 Difficulties in solving the issue of assessing the gold content of rocks are primarily due to the properties and distribution features of gold itself, namely: nativeness, ductility and malleability, high specific gravity, low concentrations in the crust, heterogeneity of sizes and shapes of gold and uneven distribution of gold, which to some extent affect the determination of the true content of the element in the sample and object and cause both systematic and random errors during testing.

 Currently, there are many methods for assessing the content of gold and related noble and rare earth elements in deposits of various origin. All these techniques, perfect from the point of view of laboratory quantitative determination and mathematical processing of the analysis results, nevertheless do not allow to obtain the real content of the studied elements, since they are based on the main parameters: the initial mass of the sample and its representativeness, which were obviously distorted at the initial stage, namely in the process of sampling and preparing samples for determination. The use of the generally accepted system of errors in calculating the content of elements (an artificial way of approaching reality) does not guarantee objective indicators. This is especially true for placer and man-made gold deposits due to the great diversity of their mineralogical and structural nature.

 One of the tasks of preparing alluvial material for enrichment is the most complete separation of the gold-containing class - ephels from gali, sludge.

In connection with this, the following requirements are imposed on an average laboratory sample:
- according to the number and distribution of the components contained in it, it should correspond to the average composition of the material being tested;
- the mass of this sample should provide the necessary quantity and accuracy of subsequent analyzes.

 Consider the practice of sampling and sample preparation, adopted in Eastern Siberia. In the exploration of ore and placer gold deposits, sampling by pits or drilling is widely used.

 When drilling, several tens of liters of water are poured into the well, which facilitates the drilling and gelation process. The chopped rock with water rises upwards and merges into the receiver mounted on the surface. When a well is drilled from each drilling interval (“voyage” equal to 0.2 - 0.5; 1.0 m), the sinking material is desiccated and processed to obtain a concentrate for further laboratory testing. To clean the well of drilling material, depending on the “voyage” (0.2 - 0.5, or 1 m), 4–7 gelation operations are required with elevations and pouring of crushed rock into the receiver. After gelation is completed, the liquid penetration product is released from the receiver through the drain valve into a measuring vessel in which it is disintegrated, as a result, a schlich complex of sands and pulp (water + fine-grained sands, silt, clay) is released. The schlich complex is sent to flushing and refining the concentrate, then to analysis.

 Thus, according to the current scheme, the initial preparation, processing and reduction of the sample is carried out directly at the well. Moreover, in the preparation of placers according to existing schemes, after disintegration, washing and screening, large material and clay-mud mud were dumped, and only washed material was used for gravity enrichment. And since the bulk of gold in placers is represented by “thin” and finely dispersed gold, in fact, gold went to the dump with clay slurry.

 This practice of sampling and preparation of samples showed that the concentrate is the final product sent for testing, mainly gold-bearing rock with a grain size of at least 0.2 mm, and pulp, including a fraction of 0.2 mm, goes into the "tailings" and thin gold is not being tested. In addition, a gold-bearing rock fraction of 0.2-0.3 mm is captured in the concentrate only 82 - 92%, and with a second control wash 90 - 95%. That is, the sample (concentrate) received for testing cannot be considered representative.

 The initial mass of the extracted rock and its volume are previously measured by the aforementioned measuring vessel. After disintegration, the samples are also weighed for the remaining rock, that is, after removal of the pulp, which leaves both fine gold and fine-grained sands, silt, clay. And, if we take into account that up to 45% of clay rocks are contained in alluvial gold-bearing rocks, we can conclude that the initial mass of the sample, determined according to this scheme, is approximate and cannot be used later for mathematical processing of the analysis results. Therefore, they use the theoretical mass, determined by the diameter of the well and the length of the "voyage" of sinking and which is also approximate.

Taking into account the foregoing, we will evaluate the existing sampling and sample preparation scheme in practice in Eastern Siberia:
- this scheme does not allow to determine the actual weight and volume of the rock extracted from the well. The volume of the rock, measured in this sampling scheme, is a control and its measurement is carried out only with the aim of eliminating gross excesses of the actual volume of the rock over the theoretical. In case of excess in the calculation of the gold content, the practically extinct volume is used, which distorts the indicators of the gold content;
- This scheme is focused on the extraction of gold on traditional gravity devices, such as a mechanical tray, a concentration table, etc. Fine, thin and especially dispersed gold goes into the “tails” when the sludge is drained from the receiver, in the process of disintegration in a measuring vessel, in the process of washing and fine-tuning the concentrate;
- the method of sample reduction introduces a negative error, since, as a rule, fine gold is lost.

The problem of an objective assessment of the gold content of deposits is primarily associated with the problem of extracting fine, fine and dispersed gold, which is lost under the existing schemes for preparing samples for analysis and in the process of conducting assay analysis, and the loss of such gold occurs for two main reasons:
- Gravity enrichment devices currently used in sample preparation schemes do not provide complete capture of relatively small (less than 0.2 mm) free gold particles;
- gold coated with films associated with sulfides, quartz, and oxidized iron minerals (“refractory” gold) cannot be determined by amalgamation, atomic absorption, and assay methods without preliminary preparation (crushing, calcining, etc.).

 Recent studies have shown that the introduction of a centrifugal field apparatus into the sample preparation scheme for assessing the gold content of deposits can provide the extraction of fine gold and gold from its aggregates with other heavy minerals into concentrate (VN Shokhin, AG Lopatin. Gravity enrichment methods .- M .: Nedra, 1980).

 Known developed TsNIGRI sampling installation for mechanized processing of samples on dredges and operational instruments (Sampling and analysis of precious metals. Ed. By I.F. Baryshnikov.- M .: 1968). The sample processing scheme for this installation is shown in FIG. 1 and is closest in technical essence and the achieved result to the proposed technical solution. This technological scheme is adopted as a prototype.

 This decision provides for the preliminary allocation of large gold, which introduces the greatest error in the assessment of gold content in the traditional reduction scheme, and the subsequent separation of gold from small fractions of the sample (usually less than 8 mm) in the most rational way.

 In the prototype sample processing scheme, the selected rock sample falls on a receiving screen for removal of a +32 mm fraction into a pebble dump. The -32 mm fraction is sent to the drum disintegrator with a roar, where it is divided into three fractions: -32 + 8 mm (to the heap after viewing), -8 + 2.5 mm (to the sluice with the release of large gold), -2.5 mm (to a centrifugal separator with the release of grains of native gold and the heaviest concentrate minerals).

 The separation concentrate is measured and processed in a hydraulic trap to obtain an enriched product. Gold is taken from it under the binocular, and the remaining concentrate is attached to the tails of the trap and amalgamated.

 In this scheme, a class of -2.5 mm enters a centrifugal vertical separator, the bowl of which rotates at a speed of 300 rpm. The pulp entering the separator, under the action of centrifugal force, rises up along the walls of the bowl, which have annular arches. Grains of native gold and the heaviest schlich minerals are delayed in arithmetic, and lighter rock (separation tails), together with water, are removed through the sides of the bowl to the collecting casing and then to the dump. Separation tails will be tested with periodic pulp cutoff.

It is known that in cup-type centrifugal separators with a vertical axis of rotation, the enrichment of materials in an aqueous medium takes place at a low separation factor (Ф _р = 30-50).

где
W - угловая скорость;
R_t - радиус кривизны траектории зерна;
q - ускорение свободного падения;
Из формулы видно, что чем выше угловая скорость, тем выше извлечение мелкого золота. В вертикальных центробежных аппаратах чашечного типа достигнуть высокой степени разделения практически невозможно.The separation factor is determined by the formula:

Where
W is the angular velocity;
R _t is the radius of curvature of the grain path;
q is the acceleration of gravity;
It can be seen from the formula that the higher the angular velocity, the higher the extraction of fine gold. In a vertical cup-type centrifugal apparatus, it is practically impossible to achieve a high degree of separation.

As noted earlier, a significant amount of water is required for gelation of a rock from a borehole, specifically from the practice of Siberia - 17 - 20 m ³ per 1 m ^{3 of} rock, which necessitates a reduction in sample.

Thus, the technology of enrichment of the prototype does not solve the main problems of assessing the gold content of deposits, namely:
- the problem of representativeness of the samples is not solved, since traditional methods of their selection and preparation are used (that is, pre-reduced samples are enriched according to the prototype scheme);
- on a centrifugal separator with a rotation speed of 300 rpm it is not possible to extract gold of the entire size range;
- This sample processing scheme provides for amalgamation of the separation tails, since during the processing of fine gold it is not separated from the association of the host rocks.

 The aim of the invention is to eliminate the above disadvantages of the sampling and sample processing scheme, namely, increasing the objectivity of assessing the gold content of deposits, including industrial deposits.

 This technology provides an assessment of the gold content of deposits, virtually eliminating the loss of gold and other noble and rare earth elements (heavy elements) regardless of the nature of the deposits (their mineralogical, particle size, and other compositions) and also allowing for the extraction of fine gold for research and practical purposes its classification by fractions (up to a fraction of 0.02 mm), since for the development of the most rational industrial schemes of the primary enrichment process and vodka requires data on the ratio of the different fractions of gold (gold particle size distribution), the contents of related minerals, and especially forms of gold grains.

 The proposed method is a new approach to assessing gold content, which allows to determine gold in large samples with a high degree of reliability.

где
Q - степень разрыхления;
W - общий объем взвешенного слоя, м³;
W_тв - объем твердого во взвешенном слоем, м³;
W_ж - объем жидкой фазы во взвешенном слое, м³,
при этом в центробежном поле создают дополнительную турбулентность, причем пульпу подвергают гравитационному обогащению в центробежном поле, по крайней мере, однократно и золото в пульпе отделяют от ассоциации вмещающих пород, при этом гравитационное обогащение пульпы осуществляют до получения "хвостов" и концентрата, обладающих скоростью седиментации, близкой или равной нулю, а массообмен в концентрате гравитационного обогащения пульпы обеспечивают непрерывным удалением "хвостов", интервал бурения при таком отборе проб поддерживают не менее одного метра.This goal is achieved by the fact that in the method for assessing the content of noble and rare-earth metals, for example alluvial gold, in deposits and dumps of the gold mining industry, including sampling, processing it to obtain a sludge complex and sludge, preparing the sludge complex for gravity concentration, gravity concentration to obtain concentrate and "tails" and the quantitative analysis of the sample itself, a fraction of -2 mm is isolated from the schlich complex, combined with a sample processing slurry to obtain Ulpia pulp and subjected to gravity separation 30 in the centrifugal field intensity - 600 g, and the degree of disintegration of the pulp was maintained at 0.3 - 0.5, and is determined by the formula:

Where
Q is the degree of loosening;
W is the total volume of the suspended layer, m ³ ;
W _TV - the volume of solid in a suspended layer, m ³ ;
W _g - volume of liquid phase in fluidized bed, ^m3,
while in the centrifugal field create additional turbulence, and the pulp is subjected to gravitational enrichment in a centrifugal field, at least once, and the gold in the pulp is separated from the association of the host rocks, while the gravitational enrichment of the pulp is carried out to obtain "tails" and a concentrate having a sedimentation rate close to or equal to zero, and the mass transfer in the concentrate of gravitational enrichment of the pulp is provided by the continuous removal of the "tails", the drilling interval with this sampling is supported not less than one meter.

 In this method, the following points can be distinguished that ensure the objectivity and reliability of the gold rating.

1. So far, they have worked on the problem of representativeness of samples, improving traditional methods for their selection and preparation, that is, enrichment of previously reduced samples. In the proposed method, sample reduction is carried out in the process of initial enrichment (processing of the sample) with extraction of almost all the gold of the initial sample into the sludge and sludge, moreover, when the sample is processed, all the drain from the receiver (sludge) is sent for processing to the CCG according to the proposed scheme shown in FIG. . 2, since by increasing the driving distances to 1 m or more, water consumption for gelation is significantly reduced from 17 - 20 m ³ according to the traditional technology to 6 - 7 m ³ according to the proposed one.

 Thus, almost all of the gold in the original sample is sent for quantitative analysis, either from a schlich complex or from sludge.

 2. Currently existing methods of gravitational enrichment of gold used in sample preparation schemes are focused on the extraction of gold particles larger than 70 microns. Gold of this size during grinding is freed from bonding with other minerals and, being in a free state, is easily captured in the future by gravitational enrichment.

 The proposed method allows to capture gold of the entire size range due to the creation of a centrifugal field of high intensity (up to 600 g) and the imposition of additional turbulence, which ensures the release of “resistant” gold and its extraction with fine gold.

 The degree of extraction of fine gold depends primarily on the separation factor, the value of which is determined by the intensity of the centrifugal field. In the proposed method, its value varies between 30 - 600 g, which allows you to vary the separation factor in a wide range depending on the task without compromising the reliability of the final analysis result.

 Already at 30 g fine gold will be precipitated during gravitational enrichment in a centrifugal field, but at the same time a significant amount of fine and finely dispersed gold will go into the “tails”. This will hardly affect the final result of the analysis, since the “tails” are subjected to quantitative analysis separately.

 When the field intensity is less than 30 g, the “tails” go away and most of the fine gold and the centrifugal enrichment process becomes ineffective.

 With a field intensity of more than 600 g by centrifugal enrichment, not only gold of the entire size range is extracted, but also the most dense particles of the host rocks, so it is not possible to obtain a concentrate with a high gold content.

Practice has shown that when using the proposed method, high gold contents of 1 - 5 g / m ³ for a mass with a thickness of 5 - 30 m are established, which is 5 to 10 times higher than the contents obtained in the usual way, and up to 0.5 are found in overburden dumps of deposits - 1 g / cm ³ gold.

 3. Thin gold is partially, and finely divided in the bulk is in the grains of other minerals and is not enriched with gravity.

 In currently known centrifugal enrichment methods, the issue of additional purification of the concentrate is urgent, since a lot of waste rock is planted. In the proposed method, where the material is subjected to grinding at the level specified for the extraction of gold particles and the effects of hydrodynamic flows with a high turbulence index, this problem is not.

 The process of releasing “stubborn” gold most effectively proceeds in the pulp with a degree of loosening of 0.3 - 0.5, that is, with a small degree of thinning. This fact is explained by the fact that in a dense pulp, the factor of self-grinding becomes more important. When the degree of loosening is less than 0.3, the process of gravitational enrichment is practically impossible, since with an insufficient amount of liquid mass transfer in the pulp slows down. With a high degree of loosening (more than 0.5), the self-grinding factor decreases and the grinding process is less complete.

 4. For research purposes and when developing an industrial scheme for the initial enrichment of samples, data on the fractional composition of gold are required, the proposed method for assessing gold content allows to obtain data on the quantitative content of gold of each size separately from the grain composition of any set in the range of 2 - 0.02 mm. For gold with a fineness of less than 0.02 mm, a quantitative determination of the metal is carried out as a whole, without fractionation.

 Based on data on the fractional composition of gold, it is possible not only to choose the optimal technological scheme for sample preparation, but also to quickly change the enrichment parameters of gold-bearing rocks, depending on the situation.

 5. Practice has shown that when using the proposed centrifugal concentration method, the presence of platinum group metals is clearly fixed, both in some ore and alluvial gold deposits. The content of platinum metals in some concentrate dumps of placers in concentrates is higher than the gold content, and platinum metals are almost completely confined to the size class of 0.2 mm.

 6. The intralaboratory control showed a high degree of reproducibility of the analysis results with a 95% confidence probability of parallel samples prepared by the proposed method.

 7. The centrifugal beneficiation method used in the present methodology for assessing gold content can work as a highly efficient purification complex at a concentrator or a group of sites.

 The method improves the quality of the gold concentrate (up to 80% gold) and increases the complexity of the use of raw materials due to the possibility of simultaneous extraction of other noble metals, for example, the platinum group, as well as rare earth metals.

 The proposed centrifugal enrichment method is easily integrated into existing technological schemes of enrichment production as an additional redistribution, which provides an increase in gold recovery due to the capture of "thin" gold and allows in some cases to exclude environmentally hazardous flotation and cyanidation processes. The high homogeneity of the concentrate and the release of gold from schlich minerals allows you to apply assay directly after centrifugal enrichment, and the usual receiving melting of fine gold on the ingot after an additional stage of refining on a centrifugal separator.

 8. Objective data on the gold content obtained using this assessment method can increase the increase in gold production due to the expansion of the raw material base, namely the involvement of millions of cubic meters of processing waste and upper layers of the earth during overburden operations that have not been previously processed, how there was an erroneous opinion of many authors (S.I. Polkin et al. Enrichment of non-ferrous metal ores. - M .: Nedra, 1983, p. 253; A.A. Kulikov. Testing of gold-bearing conglomerates.-M .: Nauka, 1981, p. 22), that on the greater gold content in the placer is located in the lower part of the sands, on the border between the sands and bedrock (“raft”), and in the upper part of the placer there is practically no gold and it does not have a noticeable effect on the metal reserves in the deposit, therefore it is impractical to create concentration complexes for collecting fine and dispersed gold from the scatter.

 Practice has shown that using the proposed centrifugal beneficiation method, gold can be extracted even from such objects where it was not taken into account (associated mining during processing of raw materials at sand and gravel plants, associated mining during bottom-dredging operations, processing of dumps of factories and placer deposits , processing of nonmetallic dumps and evils of thermal power plants).

 9. The time required to prepare the sample material is reduced by eliminating a number of redistributions, namely, drying the sample material, crushing, grinding and reducing.

 The above nine paragraphs disclose the technical nature of the proposed method, they also contain the novelty of the proposed technical solution.

 Briefly, the technical essence of the invention consists in the fact that the proposed method for evaluating gold content provides for special enrichment of samples at a centrifugal gravity concentrator with subsequent assay analysis for gold.

 The gravitational enrichment mechanism in an intense centrifugal field is presented by the authors as follows.

 A centrifugal field is superimposed on the pulp stream supplied to the concentrator by twisting the wall of the rotating apparatus, and additional turbulence is created by turbulators rotating inside it.

 The process taking place in a pulp stream moving between turbulators reduces to the fact that particles of high-density minerals, under the action of hydrodynamic and centrifugal forces, tend to penetrate into the near-wall layers of the flow and settle in the space between the walls of the apparatus and the radially fixed turbulators.

 Maintaining high turbulence in the active zone of the apparatus promotes better segregation of particles as they move into the concentration zone. High turbulence enhances the mixing of settled particles of the concentrate and intensifies the leaching of lighter particles. Light particles are displaced, and heavy particles take their place.

 A necessary condition for centrifugal enrichment of materials in an aqueous medium is the presence of a transport (flush) flow in a direction that does not coincide with the centrifugal field force vector. In the proposed method, light particles are removed by means of a cutter (as a particular, by a screw).

The optimal excess of the apparatus rotation speed (V1) over the turbulizer rotation speed (V2) is 100 rpm, as in the case if:
- the speed V1 will significantly exceed the V2 process, goes into a very active turbulization mode with the release of fine gold into the tail product,
- at V2 approximately equal to V1, the process goes into the deposition mode and enrichment of the material by density stops.

где
E - извлечение металла,%;
K - поправочный коэффициент;
V1 - скорость вращения аппарата, об/мин;
V2 - скорость вращения турбулизаторов, об/мин;
M_max - максимальный размер золота в пульпе, мм.Obviously, by varying the values of centrifugal and hydraulic forces, it is possible to set the average density of particles deposited on the apparatus wall, and, therefore, a certain size of the recovered gold. This fact can be expressed by the formula:

Where
E - metal recovery,%;
K is the correction factor;
V1 - apparatus rotation speed, rpm;
V2 is the speed of rotation of the turbulators, rpm;
M _max - the maximum gold size in the pulp, mm.

 Practice has shown that the sludge has high sedimentation stability for a long time, for example, for two months, the separation of the obtained pulp was not visually observed, that is, the particle deposition rate determined by the Stokes formula was approximately equal to zero. The high sedimentation stability of the pulp is a confirmation of the high degree of sludge liberation from gold and other noble elements that have a higher specific gravity than the main rock containing them, that is, sludge, if it contains particles of noble and rare earth metals, is so thin that their weight It is commensurate with the weight of waste rock particles, so gravity gold is practically absent in the sludge volume.

This is possible, firstly, provided that the hard part of the pulp is finely pulverized in a centrifugal apparatus, and secondly, with a certain ratio W: T:
- practice has shown that for the proposed method of testing the most optimal ratio W: T = 1 - 0.5;
- the optimum degree of grinding is not less than 44 microns. The processing time on the apparatus should be sufficient to grind the solid phase of the pulp to this size, and fine gold less than 10 microns in gravitational enrichment in a centrifugal field mainly goes into the “tails”, where it is determined by the assay method of analysis.

 The grinding process in the apparatus is primarily aimed at extracting gold-bearing particles of rock, as heavier and not longer leaving the process of gravitational enrichment in a centrifugal field. Waste and larger sizes are removed from the apparatus.

 The analysis of existing methods for assessing the gold content of deposits showed that the fundamental difference of the proposed method is the presence of gravitational enrichment in a centrifugal field of high intensity with turbulization of the pulp.

Centrifugal enrichment is handled by a number of leading companies in this field. Currently, the most perfect are the devices of the company "Knelson gold concenrators" (Canada). But these devices do not allow to extract fine gold with the same completeness as in the proposed method, for two main reasons:
- low centrifugal field intensity - 60 g in a vertically located apparatus;
- lack of additional turbulization.

The proposed method for assessing gold content was subjected to practical testing for two years on placers in Eastern Siberia, and parallel work was carried out to assess the gold content using the traditional method for drilling, processing and preparing samples for quantitative analysis (see page 2 of the description) and according to the proposed method (Fig. 2), according to which, when sampling, the driving distance increases to 1 mm and higher, which reduces the water consumption for gelation to 6 - 7 m ³ .

 All crushed rock with water (the product of gelation) enters the receiver, from which the liquid product is sent to the primary disintegration to obtain a sludge complex and sludge (sample processing).

 Next, the concentrate complex is sent to the final disintegration (washing and refinement of the concentrate) and then to classification according to scheme 2.

 At the same time, the entire sample processing slurry is combined with a fraction of 2 mm of the schlich complex and sent to the treatment at the Central Testing Facility (in an intensive centrifugal field with additional turbulation).

 The test results are given in table. 12.

 From the above data it can be seen that the proposed method for assessing gold content allows us to identify 4.63 times more gold than the traditional for Eastern Siberia.

 As for the prototype, it is possible that this figure (4.63) will be slightly lower due to the presence of centrifugal enrichment in the redistribution scheme, but nevertheless, the gold content in the proposed scheme will be higher than that of the prototype, due to the use in centrifugal enrichment apparatuses of the original design (developed by the authors) that allow creating a centrifugal field with an intensity of up to 1000 g (as a result of which fine gold is extracted) and allowing creating significant turbulence in the pulp, as a result of which it opens extracted "stubborn" gold.

 Given in the table. 2 data necessitated the revaluation of previously explored alluvial deposits and the creation of new concentration complexes for collecting fine and dispersed gold.

 The proposed method does not require complex special equipment and can be used in the field of exploration sites, parties, in small laboratories.

 Currently, a program has been developed for the revaluation of the Lena placers using the proposed method for assessing gold content.

 The expected technical and economic effect only in the Lensky gold-bearing region due to the application of the method for revaluing bulk gold reserves will amount to hundreds of billions of rubles until 2000, and when it is distributed to other famous gold-mining regions of Russia (Yakutia, Amur, Transbaikalia, North-East, etc. ) it will have a value that can hardly be overestimated, because it will allow in a short time to significantly increase the production of alluvial gold in Russia due to fine and thin gold.

Claims (6)

1. A method for assessing the content of noble and rare-earth metals, for example alluvial gold, in the deposits and dumps of the gold mining industry, including sampling, processing it to produce a sludge complex and sludge, preparing the sludge complex for gravity concentration, gravity concentration to produce concentrate and tailings and proper quantitative analysis of the sample, characterized in that a fraction of 2 mm is isolated from the schlich complex, combined with a slurry of sample processing to obtain pulp and subjected the pulp is gravitational enrichment in a centrifugal field with an intensity of 30 - 600 g, where g = 9.8 m / cm ² is the acceleration of gravity, and the degree of pulp loosening is maintained equal to 0.3 - 0.5 and determined by the formula

where Q is the degree of loosening;
W is the total volume of the suspended layer, m ³ ;
W _TV - the volume of solid in a suspended layer, m ³ ;
W _W - the volume of the liquid phase in the suspended layer, m ³ ,
in the process of enrichment in a centrifugal field, the pulp is subjected to additional turbulization.  2. The method according to claim 1, characterized in that the pulp is subjected to gravitational enrichment in a centrifugal field at least once.  3. The method according to claim 1, characterized in that the pulp is separated from the association of the host rocks.  4. The method according to claim 1, characterized in that the gravitational enrichment of the pulp is carried out to obtain "tails" having a sedimentation rate close to or equal to zero.  5. The method according to p. 1, characterized in that the mass transfer in the concentrate during gravitational enrichment of the pulp provide continuous removal of the "tailings".  6. The method according to claim 1, characterized in that during sampling, the drilling interval is maintained at least 1 m

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