RU2372152C1 - Method of dry preparation of geological or technological samples of gold ore and placers to analysis and instalaltion for its implementation - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to field of mineral dressing and can be used at preparation of samples of poor impregnated, impregnated-stringed and particularly containing high-impregnated gold of ores and placers to analysis. In method of dry preparation of geological or technological samples of gold ores and placers to analysis dry assay, containing large gold and gold in aggregates^ are grinded and directed into middle part of classifier in the form of downcomer towards to ascending air, which is transformed by means of installation by its way of vertical row of hollow truncated cones, located by big basis upwards, forming main area of classification, located inside each hollow truncated cone at level of its less basis with similar in all hollow truncated cones rates of ascending air, additional classification area, located in annular gap, restricted by inner surface of pipe and large basis of each hollow truncated cone, and convective zone, located between two neighbouring cones. In the first and the last by way of airflow, and also in directly joined to area of feeding of initial material in additional classification areas, there are created similar rates of ascending air, maximal for whole classifier, and in the rest additional classification areas rate of ascending air successively increased top-down. Received floating fraction of dry sample is directed to sedimentation into successively installed centrifugal devices, and received sinking fraction - gold-containing concentrate - regrinded and directed to treatment, similar to treatment of initial sample. After what final gold-containing concentrate is totally, and floating fraction after blending and reduction, are directed to analysis. Method is implemented at installation, containing mill, bin with shaking feeder, classifier in the form of vertical pipe, with devices for air feeding into bottom part of pipe, devices for withdrawal of floating and sinking fractions, located correspondingly in top and bottom parts of pipe, successively installed centrifugal devices, communicated to device for withdrawal of floating fractions, devices for mixing and reduction of received floating fraction. Inside the vertical pipe of classifier it is rigidly installed vertical row of hollow truncated cones, located by large basis upwards and allowing similar height and similar less basis. The first and the last in height hollow truncated cones, and also hollow truncated cones, placed directly above and under outlet port of shaking feeder, are implemented with similar geometry and maximal large basis, and large basis of the rest hollow truncated cones are implemented as increasing top-down.

EFFECT: reduction of duration of preparation of geological or technological samples of gold ores and placers to analysis, and also increasing of trustworthiness of sampling.

8 cl, 1 dwg

Description

The invention relates to the field of mineral processing and can be used in the preparation of samples of poor disseminated, disseminated-vein and especially containing coarse gold ores and placers for analysis.

A known method of preparing geological or technological samples of gold-bearing ores and placers for analysis, including their sequential grinding and reduction with the selection of two samples of 50 g per assay. In this case, the assumption of uniform grinding of ore and barren components of the sample is assumed. However, this initial position is not observed due to the difference in the physicomechanical properties of gold and the rest of the sample. Gold is a very malleable metal. Its grinding in comparison with quartz, carbonates and other minerals is much behind, and when it reaches a particle size of 0.10-0.15 mm it practically stops.

Gold in ores is in the form of scattered grains with sizes ranging from microns to tenths of a millimeter. Together with small grains in ores of many deposits there are larger ones (up to 1 and more mm). The number of such grains is small (1-3%), but a significant (40-60%) part of gold is concentrated in them. Experiments show that with such a distribution, only 5-15 medium and large gold grains fall into a sample weighing 6-8 kg. A hinge will be representative only if such a small number of gold grains is evenly distributed over all quartered portions of the sample. However, due to the randomness factor, the metal grains are distributed equally among the parts of the sample, which leads to randomness of the test results. Moreover, due to the asymmetric distribution of gold grains by size, prerequisites arise for a systematic underestimation of grade estimates.

Since the currently available technical means of sample processing do not allow the grinding of gold to such an extent that would ensure a uniform distribution of the metal over the weighed portions of 50-100 g, errors can be eliminated only by extracting the gold released during grinding from the sample, i.e. by preliminary extraction of gold.

Work according to the known method is as follows. All the crushed material of the sample is soaked with water, stirred and washed with a stream of water evenly into the hopper-feeder, where water is supplied through the water distributor and sprinklers. The resulting pulp at the outlet is disintegrated by pressure jets and flows uniformly into a separator, where a heavy sample fraction is separated. The concentrate accumulates in the arrays of the rubber lining, and the tails are unloaded through the outlet and fed to the control separator, and then sent to the contractor. When processing the material, a large dilution of the pulp is required, i.e. high water consumption - see Temporary guidelines for the processing of geological samples of gold deposits with preliminary metal extraction, see - Moscow, USSR Ministry of Geology. Central Research Geological Exploration Institute of non-ferrous and noble metals "TsNIGRI", 1975

The disadvantage of this method is its high cost and duration, due to the need to first pulp the sample, and then dry the finished products, as well as the incomplete reliability of testing. Correct, technologically simple, affordable and low-cost in time methods of preparing geological and technological samples and, accordingly, installations for their implementation are not yet available.

Alternative methods, with the exception of pyro- and hydrometallurgical methods, are not known.

The claimed invention is a fundamentally new way and, accordingly, a new installation that has no analogues, since it is based on a fundamentally new approach to the solution of sample preparation for analysis.

The objective of the invention is to reduce the cost of preparing geological or technological samples of gold-bearing ores and placers for analysis.

The technical result of the claimed invention is to reduce the duration of the preparation of geological or technological samples of gold-bearing ores and placers for analysis, as well as increasing the reliability of testing.

The technical result is achieved by the fact that in the method of dry preparation of geological or technological samples of gold-bearing ores and placers for analysis, a dry sample containing large gold and gold in splices is crushed and sent to the middle part of the classifier in the form of a vertical pipe towards the upward air flow, which is transformed by installation along its course of a vertical row of hollow truncated cones located with large bases up, forming the main classification zone located inside each of a hollow truncated cone at the level of its smaller base with upward air flow velocities identical in all hollow truncated cones, an additional classification zone located in the annular gap bounded by the inner surface of the pipe and the large base of each hollow truncated cone, and a mixing zone located between two adjacent cones, while in the first and last along the air stream, as well as in additional areas directly adjacent to the feed zone of the source material Assignments create the same ascending air flow velocities, maximum for the entire classifier, and in the remaining additional classification zones, the ascending air flow velocity is successively increased from top to bottom, while the obtained light fraction of dry sample is sent for precipitation to sequentially installed centrifugal apparatuses, and the obtained heavy fraction is gold-containing concentrate - grinded and sent for processing similar to the processing of the initial sample, after which the final ash osoderzhaschy concentrate completely, and the light fraction and, after stirring for direct reduction assays.

The section of the classifier pipe located above the feed zone of the source material can be expanded up to reduce the concentration of particles in the classification zones, while air is additionally supplied to the feed zone of the source material.

Air may be additionally supplied to the first of the centrifugal apparatuses to improve the conditions of centrifugal deposition of light particles.

The technical result is also achieved by the fact that the installation for dry preparation of geological or technological samples of gold-bearing ores and placers for analysis contains a mill, a hopper with a vibratory feeder, a classifier in the form of a vertical pipe, with devices for supplying air to the bottom of the pipe, devices for outputting light and heavy fractions located respectively in the upper and lower parts of the pipe, sequentially installed centrifugal apparatus, communicated with a device for outputting a light fraction, tools for mixing and reducing the light fraction obtained, while inside the vertical tube of the classifier a vertical row of hollow truncated cones is arranged rigidly, with large bases up and of equal height, identical smaller bases, the first and last hollow truncated cones and hollow truncated the cones located directly above and below the outlet of the vibrator are made with the same geometry and maximum large bases, and large bases others are made hollow truncated cones increases downwards.

The section of the classifier pipe located above the outlet of the vibratory feeder can be made with the expansion up.

The installation can be equipped with an additional device for supplying air communicated with the classifier tube at the level of the outlet of the vibratory feeder.

The installation may be equipped with an additional device for supplying air in communication with the device for outputting the light fraction from the classifier pipe.

In a vertical classifier tube, by installing a series of hollow truncated cones and organizing a series of successive classification zones, in essence, a typical enrichment scheme is assembled, while the main separation (classification) operation is carried out in the classification zone of hollow truncated cones located above and below the feed zone of the source material in classifier. In this zone, all the source material is divided into two fractions - concentrate and tailings - according to the required boundary separation grain, which is determined by the speed of the upward air flow in the classification zones, which depends on the geometry of the hollow truncated cones and the total air flow. The final classification operations are carried out according to the same separation grain - the last purification of the concentrate in the classification zone of the first upstream hollow truncated cone and the last control operation of the tails in the classification zone of the last hollow truncated cone, therefore, the velocities of the upward air flow in these zones therefore, the geometry of hollow truncated cones should be the same.

Material mixing zones organized between hollow truncated cones are necessary for uniform distribution of the material, i.e. in order to reduce the gradient of particle concentration in the volume of the mixing zones and in horizontal sections of the classifier tube, which provides unrestricted separation conditions, and therefore, the minimum mutual influence of the particles during their separation is ensured and conditions are created for a more accurate separation of the material. In order to improve the separation conditions in the mixing zones, directed turbulent flows are organized from the center of the classifier pipe to its walls, where the velocities of the ascending air flow are reduced. This also allows for increased particle circulation between separation stages. A sequential increase in the velocity of the upward air flow in the annular gaps limited by the inner surface of the pipe and the large base of the hollow truncated cone from top to bottom due to the installation of hollow truncated cones with increasing upper bases of the cones, reaching the maximum size in the last separation operations, where the final cleaning of the separation products also increases separation accuracy. In this case, the velocity of the ascending air flow inside the hollow truncated cones at the level of their smaller base, i.e. in the central part of the classifier pipe, one and the same.

Such an organization of the ascending air flow ensures accurate separation of all particles, taking into account their density and size, reduces the duration of the preparation of geological and technological samples of gold-bearing ores and placers for analysis, and also increases the reliability of testing.

The claimed method is carried out in the installation shown in the drawing.

The installation for dry preparation of geological or technological samples of gold-bearing ores and placers for analysis contains a mill 1, a sealed hopper 2 with a vibratory feeder 3, a classifier 4 in the form of a vertical pipe (Zhukravlev multicascade air separator), with devices 5 for supplying air to the lower part of the pipe, with a device for controlling the air flow (not shown in the drawing) and devices 6 and 7 for outputting heavy and light fractions located respectively in the lower and upper parts of the pipe. Serially installed centrifugal apparatuses 8 and 9 are in communication with the device 7 for outputting the light fraction. The installation contains devices 10 and 11 for, respectively, mixing and reducing the resulting light fraction. Inside the vertical pipe of the classifier 4, a vertical row of hollow truncated cones 12 is arranged rigidly, which are arranged upward by large bases 13 and have the same height and the same smaller bases. The first and last in height hollow truncated cones, as well as hollow truncated cones located directly above and below the outlet of the vibrator 3, are made with the same geometry and maximum large bases. The large bases of the remaining hollow truncated cones 12 are made increasing from top to bottom, not reaching the size of the base of the first hollow truncated cone.

The pipe section of the classifier 4, located above the outlet of the vibratory feeder 3, can be made with the expansion up (not shown).

The installation may be equipped with an additional device for supplying air communicated with the classifier tube at the level of the outlet of the vibratory feeder (not shown in the drawing).

The installation may be equipped with an additional device 14 for supplying air, communicated with the device 7 for outputting light fractions from the pipe of classifier 4.

Hollow truncated cones 12 form classification zones: the main 15 — inside hollow truncated cones at the level of their smaller base (shown by the example of one hollow truncated cone) and an additional 16 — formed in an annular gap bounded by the inner surface of the pipe and the large base of the hollow truncated cone. Mixing zones 17 are located between two adjacent hollow truncated cones 12.

The claimed method is as follows. A dry geological or technological sample of gold-bearing ores and placers is crushed in a mill 1 and fed to a hopper 2, from where a vibrating feeder 3 is fed into the classifier 4 towards the upward air flow coming from the devices 5 for supplying air to the lower part of the classifier pipe 4. The air flow is set so to separate the sample for a given size and density. In classifier 4, the initial sample, passing through a vertical row of hollow truncated cones 12, is divided into heavy and light fractions, which are removed from the classifier with devices 6 and 7. The light fraction is separated from the air in sequentially installed centrifugal devices 8 and 9 and sent to devices 10 and 11 for mixing and contraction, respectively. The heavy fraction - the gold-containing concentrate - is crushed and sent for processing similar to the processing of the initial sample, after which the final gold-containing concentrate is completely, and the light fraction after mixing and reduction is sent for analysis.

Based on the claimed invention, a sample of the PVS-60 multicascade air separator was created, when used in a concentrate containing large gold, large intergrowths of any boundary separation size are allocated. In contrast to the known methods of sample processing, where the separation occurs under very constrained conditions, the claimed method and installation implement a fundamentally new approach to the separation of particles - separation in slightly constrained conditions - in air. In this case, the yield of particles is determined by the density and size of the particles, in contrast to enrichment in highly constrained conditions, where the allocation to the concentrate is determined by the density of the particles, and it is impossible to isolate large intergrowths into the concentrate. The sprouts fall into the tails and the sample becomes unreliable. The use of the claimed invention allows to increase the representativeness and reliability of the analysis, since all undisclosed growths are separated into concentrate, regrind and reclassified. The sample is subjected to verification classification according to any required class size.

Using the inventive method instead of a wet process allows to extract not only free gold, but also unopened gold splices into the concentrate, which is very significant when processing samples of gold deposits with uneven impregnation.

The cost of obtaining reliable information about the gold content in ore when using the claimed invention is reduced by 5-12 times, the time of preparation of samples for analysis - by 5-20 times.

Claims (8)

1. The method of dry preparation of geological or technological samples of gold-bearing ores and placers for analysis, characterized in that the dry sample containing large gold and gold in splices is crushed and sent to the middle part of the classifier in the form of a vertical pipe towards the upward air flow, which is transformed by the installation along its course of a vertical row of hollow truncated cones located with large bases up, forming the main classification zone located inside each hollow truncated a cone at the level of its smaller base with the same upward air velocities in all hollow truncated cones, an additional classification zone located in the annular gap bounded by the inner surface of the pipe and the large base of each hollow truncated cone, and a mixing zone located between two adjacent cones, at the same time in the first and last along the air flow, as well as in additional classification zones directly adjacent to the feed zone of the source material, give the same ascending air flow velocities, maximum for the entire classifier, and in the remaining additional classification zones, the ascending air flow velocity is successively increased from top to bottom, while the obtained light fraction of dry sample is sent for precipitation to sequentially installed centrifugal apparatuses, and the obtained heavy fraction is gold-containing concentrate - grind and sent to processing similar to the processing of the original sample, after which the final gold-containing con the centrate is completely, and the light fraction, after mixing and contraction, is sent for analysis. 2. The method according to claim 1, characterized in that the section of the classifier pipe located above the feed zone of the source material is expanded upward to reduce the concentration of particles in the classification zones. 3. The method according to claim 2. characterized in that air is additionally supplied to the feed zone of the source material. 4. The method according to claim 1, characterized in that the first of the centrifugal apparatuses is additionally supplied with air to improve the conditions of centrifugal deposition of light particles. 5. Installation for dry preparation of geological or technological samples of gold-bearing ores and placers for analysis, characterized in that it contains a mill, a hopper with a vibratory feeder, a classifier in the form of a vertical pipe, with devices for supplying air to the bottom of the pipe, devices for outputting light and heavy fractions located respectively in the upper and lower parts of the pipe, sequentially installed centrifugal devices in communication with a device for outputting a light fraction, a device for mixing and reducing the light fraction obtained, while inside the vertical tube of the classifier a vertical row of hollow truncated cones is arranged rigidly, with large bases up and having the same height and the same smaller bases, the first and last hollow truncated cones, as well as hollow truncated cones, located directly above and below the outlet of the vibratory feeder are made with the same geometry and maximum large bases, and large bases of the remaining floors x truncated cones formed increases downwards. 6. Installation according to claim 5, characterized in that the section of the classifier pipe located above the outlet of the vibratory feeder is made with the expansion up. 7. Installation according to claim 6, characterized in that it is equipped with an additional device for supplying air communicated with the classifier tube at the level of the outlet of the vibrator. 8. The installation according to claim 5, characterized in that it is equipped with an additional device for supplying air in communication with the device for outputting the light fraction from the classifier pipe.

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