RU2522873C1 - Plant for gold extraction from ores and concentrates - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: proposed plant comprises tank with processed material loading and unloading pipes, cyanide solution feed pump and circulation pump. It differs from designs in that it is equipped with at least one two-beam hydroacoustic radiator with fixed direction of acoustic field fitted inside said tank on its vertical axle and communicated with circulation pump inlet. Besides it has air feed pipe combined with cyanide solution feed pipe into common manifold. Outlets of said radiator are located at radiator rarefaction zone.

EFFECT: accelerated dissolution of gold and etching and higher yield.

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Description

The invention relates to hydrometallurgy of precious metals, in particular for the extraction of gold from ores and concentrates by leaching in cyanide solutions.

A known installation for conducting the process of cyanide gold in an ultrasonic field. The installation consists of a bath, a mechanical stirrer, an ultrasonic transducer and an unloading device. The installation has several disadvantages: low productivity and high energy costs./ Agranat B.A., Kirillov O.D. and others. Ultrasound in hydrometallurgy. Publishing house "Metallurgy", 1969, S. 61-63 /.

Also known installation for gold extraction processes such as patchouk, cone, percolator, consisting of a housing, nozzles for input and output of the solution, nozzles for loading and releasing the processed material (patent RU No. 206806 from 04.20.94 g). The disadvantages of the device include significant energy costs that go to the acidification of the solution and the low degree of gold recovery during cyanidation in the atmosphere.

Known ultrasonic installation, the main part of which is a device mounted from four cylindrical magnetostrictive transducers in the form of a column in which the suspension is leached in cavitation mode in a closed circle using a pump / Fridman V.M. and others. Ultrasonic chemical-technological equipment. CINTIAM Publishing House, 1964). The disadvantages include high energy costs, low productivity and short life of the converters.

A known installation for cyanidation of rich gold-bearing concentrates (Russian Patent No. 2168555, MPK7 C22B 11/00, 3/02 publ. 01/22/1999), where the device is equipped with an additional pipe for supplying wear to the working parts of the pressure pump, oxygen directly to the impeller pump. The disadvantages include a low degree of dispersion of oxygen, as well as a gap in the continuity of the treated pulp, leading to rapid wear of the working parts of the injection pump.

The installation consisting of an autoclave, a separator, a filter is described. The main device of the installation is a cascade of sonar emitters / Medvedev A.S.

Leaching and methods of intensification. M .: MISiS, 2005 .-- 240 p. /. The disadvantages of this device include the low processing capacity of the pulp and the difficult method of introducing air or oxygen to disperse it in the treated medium.

A device is known that is described in the method for gold extraction (WO No. 15856 Al, 03/23/2000), where the authors at the Acacia installation supply compressed oxygen to the reaction zone through a ceramic dispersant located in the pipe behind the cyanide solution feed pump. It should be noted that the ceramic dispersant does not crush oxygen bubbles, but only passes oxygen bubbles of a certain size through its pores. In addition, such a dispersant quickly clogs and its performance drops, which increases the time of leaching of gold.

The closest in technical essence and the achieved result is the installation for leaching gold-containing concentrates, containing a buffer tank, a circulation pump, a housing, nozzles for input and output of the solution, nozzles for loading and unloading the processed material, an oxygen source with a reducer, an oxygen flow meter and an oxygen supply pipe ( Russian Patent No. 2168555, published on June 10, 2001).

An important factor in the operation of the installation is the dispersion of the supplied oxygen into the solution, where the authors use the oxygen supply to the pipe located in front of the circulation pump in the pulp circulation mode. According to the authors, under certain conditions, oxygen disperses and dissolves, which leads to an increase in the efficiency of gold recovery.

However, such a facility for the extraction of gold from ores and concentrates is inefficient, expensive and energy intensive, since an expensive gas is used to extract gold - oxygen.

An object of the present invention is to provide a highly efficient gold leaching plant from ores and concentrates containing a device that can increase air dispersion, shorten leaching time and increase gold recovery.

The problem is solved in the installation for leaching gold from ores and concentrates, containing a tank with nozzles for loading and unloading the processed material and a nozzle for introducing a cyanide solution and a circulation pump. The installation is equipped with at least one two-beam hydroacoustic emitter with a fixed directivity of the acoustic field installed in the tank on its vertical axis and connected to the inlet of the circulation pump, and an air supply pipe combined with a pipe for supplying a cyanide solution to a common collector, the outlet openings of which located in the rarefaction zone of a two-beam sonar emitter.

Hydroacoustic (hydrodynamic) emitters of acoustic vibrations according to their design features are divided into three groups: plate, vortex and rotor. Vortex emitters, in turn, are divided into gas and liquid transducers with one and three beam nozzles (AS No. 1494317 dated March 15, 1989).

The proposed installation used a vortex double-beam liquid hydroacoustic emitter, the operation of which is based on the excitation of a wide range of frequencies in a hydrogen medium. The medium being processed at a pressure of about 3-5 atm through the inlet nozzle is tangentially fed into the resonator chamber, which has two-beam outlet nozzles, preferably located opposite. As a result of the expiration of the rotating jet from the round output nozzles of the emitter, the vortex intensity in the medium being processed sharply increases, and due to this, the pressure of the outflowing fluid along the axes of the output nozzles becomes much lower than atmospheric. As a result, powerful opposed funnels are formed with a rarefaction zone, where all the ingredients of the processed medium are actively supplied. As a result, the medium being processed acquires planetary (rotational-translational) fluid motion in the entire volume of the tank, which ensures the intensification of the gold leaching process.

A variant of the opposite arrangement of nozzles in a sonar emitter mounted on the vertical axis of the tank is optimal from the point of view of the distribution of acoustic vibrations in the medium being treated, having a fixed directivity. Depending on the shape of the used container, the nozzles of the two-beam hydroacoustic emitter can be directed at a different angle (relative to the indicated opposite arrangement) with respect to each other and, accordingly, with respect to the vertical axis of the container, while the selection of the optimal angle is carried out experimentally.

The installation preferably contains at least one two-beam hydroacoustic emitter, and the pipeline for supplying air from the atmosphere and a solution of sodium hydroxide and sodium cyanide has a common pipe with a collector.

The use of the invention in the scope of the above set of features makes it possible to substantially intensify the process of leaching gold from ores and concentrates due to the excitation in the whole volume of a wide frequency range created by a two-beam hydroacoustic emitter and secondary effects (cavitation, pulsation, micro and macro streams) that arise in the processed medium.

Figure 1 presents one of the possible installation options. The installation consists of a vertical tank 1 with a volume of at least 2 m ³ , at the bottom of a conical shape there is an outlet pipe 2 with a crane for draining the processed material. The source pulp through the inlet pipe 3 enters the inlet device of the circulation pulp pump 4 and then, under a pressure of 4 atm, the pulp enters the two-beam acoustic emitter 5 located on the vertical axis of the tank 1. The air supply pipe from the atmosphere 6 and the solution supply pipe 7 are combined into a common collector 8, the outlet openings of which are in the rarefaction zone 9 created by the two-beam sonar emitter 5. When the tank is filled with pulp to a certain level, it passes through the suction rd line 10 and fed through pulp pump 4 sonar emitter 5 and extends 3-5-fold treatment, circulating in the container 1.

The installation also allows you to change the scheme of the supply of ingredients and first fill the tank with water through the water supply pipe 11 to the level of the suction pipe 10, and after switching on the pulp pump, simultaneously supply dry material through the pipe 12, air from the atmosphere and the solution through the pipes 6 and 7, coming through a common the collector 8 into the rarefaction zone of the two-beam hydroacoustic emitter 5, exciting a wide frequency range. The leaching process is considered complete, as in the first case, after 3-5 times the pulp passes through the acoustic device. The pulp feed pressure is controlled by a pressure gauge, and the air flow rate is controlled by a ratameter. The oxygen content of the processed material is controlled by an oximeter.

Figure 2 shows the movement of the treated pulp when passing through a two-beam sonar emitter. Due to the secondary effects created by the emitter and the resulting rarefaction zone, the pulp stream acquires the translational-rotational direction of movement in the entire volume of the tank. (Translational flow direction 1, rotational flow direction 2). In this case, cavitation, pulsation, alternating pressure, collision and friction of the particles lead to a high degree of dispersion and homogenization of not only the pulp, but also air oxygen, which facilitates the penetration of the cyanide solution into the pores of the treated mass and increases the dissolution rate and the degree of grinding of gold.

An example of the installation.

The process of leaching of gold is as follows. The prepared feedstock in the form of pulp, in which more than 80% are particles with a dispersion of 75 μm, the ratio T: W is 1: 2.5, the gold content is 20 g / t, in the amount of 0.7 m ^{3 it} enters the inlet pipe 3 pulp pump 4 with a capacity of 5 m ³ / h and at a pressure of 4 atm and through a pipe enters a two-beam hydroacoustic emitter 5 and then to tank 1, where under the influence of vacuum created by the acoustic emitter, into tank 1 through a common collector 8, the outlet which is located in the zone of vzrezheniya, at the same time atmospheric air and 0.01-0.02% cyanide solution with a pH of 10-11. When the tank 1 is filled with pulp to the level of the suction pipe 10, the inlet pipe 3 of the pulp pump is blocked, and the pulp is circulated in a circle until the gold is completely leached from the pulp into the solution. Since a wide range of acoustic frequencies is generated in the entire volume, alternating pressure, translational-rotational flow, a cyanide solution and air oxygen penetrate into the pores of each pulp particle due to the capillary effect, accelerating the process of gold leaching by more than 4-5 times. The recovery of gold in solution is 97-98%. In addition, it should be noted that the sonar emitter located in the tank allows, after leaching, to clean its inner surface from contamination.

Claims (1)

A device for leaching gold from ores and concentrates, containing a tank with nozzles for loading and unloading the processed material and a nozzle for introducing a cyanide solution and a circulation pump, characterized in that it is equipped with at least one two-beam hydroacoustic emitter with a fixed directivity of the acoustic field installed in the tank on its vertical axis and connected to the inlet of the circulation pump, and the air supply pipe, combined with a pipe for supplying a solution of cyanide in conductive collector outlet openings which are arranged in the dilution zone of a two-beam sonar emitter.

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