RU2201981C2 - Method of extraction of gold and silver in solution by hydrochlorination and cavitation dispersion - Google Patents

Abstract

FIELD: hydrometallurgy of noble metals; technology of extraction of gold and silver from mining mass, ore concentrates and semi-finished products, tailings of concentrating plants; alternative technological cyanidation process. SUBSTANCE: method consists in grinding ore in cavitation dispensers to required consistency at simultaneous hydrochlorination in solution of sodium chloride and hydrochloric lime making use of cavitation effects: heating the pulp, forming hydrogen peroxide and shock waves breaking hardly soluble oxide films on surfaces of metals being extracted. Solid fraction is separated from gold- and silver-containing solutions by settling on watertight platform of primary settler. After primary settling, solution is drained to secondary settler for clarification and solid fraction is subjected to vacuum drying. After drying and dehydration, sand-and-sludge mixture of solid fraction goes to waste. EFFECT: reduction of time required for extraction; enhanced profitableness. 3 cl, 3 dwg

Description

 The invention relates to the field of hydrometallurgy of precious metals and can be used in the technology of extracting gold and silver from the ore mass, ore concentrates and semi-finished products, tailings of dressing plants, as well as an alternative cyanidation process in order to reduce the time of metal extraction and cost-effective ore processing with small balance reserves.

 Most methods for extracting gold and silver from ores include the step of converting the noble metals into solution. The main method for the extraction of gold and silver is cyanidation, a method based on the selectivity of dissolving metals with a weak concentration of a solution (0.03-0.3%) of cyanide.

 The theory of cyanidation processes is based on the laws of kinetics of dissolution on an inhomogeneous surface (with cathodic depolarization with oxygen) and diffuse dissolution of metals (with simultaneous diffusion of cyanide and oxygen), taking into account the laws of interaction of reagents with minerals.

 However, gold and silver can dissolve under the influence of atmospheric oxygen not only in aqueous solutions of cyanides, but also in aqueous solutions of chloroids, bromides, and odides: unfavorable kinetics hinder the use of these processes in practice. However, the dissolution rate substantially depends on the nature of the oxidizing agent. Favorable kinetics has the process of dissolving gold and silver under the action of chlorine in aqueous solutions of chlorides.

 The dissolution rate of gold and silver in chlorine solutions is much higher than in cyanides, and the addition of halide ions further increase it.

A known method of extracting compounds of platinum metals, gold and silver in a solution of Russian patent RU 2154684, according to which the feedstock is kept in an inert gas atmosphere (nitrogen or argon) at a temperature of 650-1000C ^o for 5-20 minutes Then the feedstock is cooled in an inert atmosphere, with the dissociation of the platinum group metal oxides contained in the feed to metals (platinum, palladium, radium, iridium). Hydrochlorination is carried out with hydrochloric acid and chlorine in the presence of a nitrate ion in an amount (0.01-3.0%) of the solution volume.

The disadvantages of the known method of extracting gold and silver are:
- the inability to expedite the processing of gold- and silver-containing ores cost-effectively in field conditions without causing damage to the environment;
high chlorine toxicity, requiring complex hardware design of the process and safe operation, as well as an expensive safety system for maintenance personnel.

 The above method of extracting gold and silver into a solution by hydrochlorination is the closest to the claimed method of hydrochlorination and cavitation dispersion, however, the traditional process, which is easily carried out under refining at the factory, is unsuitable for extracting gold and silver under expeditionary conditions.

 The technical problem to which the invention is directed is to create a method for extracting gold and silver into a solution from ore, the technical result of which would be to accelerate the hydrochlorination process without high-temperature heating and exposure to inert gases, to exclude toxic precious metals from the technological process.

 The technical result is achieved by a method of extracting gold and silver from ore into a solution, including hydrochlorination, separation of the solid fraction from gold and silver-containing solutions, clarification of solutions, reduction of gold and silver from solutions, according to the invention, hydrochlorination is carried out by cavitation dispersion of ore, and separation of the solid fraction from the solution carry out sludge in a waterproof area. In this case, cavitation dispersion is carried out during grinding of ore to the required sand-clay fraction while hydrochlorinating in a solution of sodium chloride and bleach, as well as the fact that after settling and draining the solution, the sand-clay mixture is subjected to vacuum drying.

 a) This method includes hydrochlorination in a cycle of ore grinding by cavitation dispersants, which allow fine dispersion up to (5-10 μm) grinding in a stream of hydrochloride solutions, and also use other cavitation effects.

b) The use of cheap and affordable oxidizing agents in a chloride-chloride medium, where chlorine is not only an oxidizing agent, but also a complexing agent (for example, NaCl> 2.0 mol (L), as well as a chlorinating agent (for example, Ca (OSl) ₂ bleaching lime) ), which has significant technological advantages: the reagent is cheaper than chlorine, less toxic and safe to use, less aggressive, which simplifies the hardware design of the process.

 c) Drainage sites of the primary settler, designed to separate the pulp into gold and silver solutions and the sand-mud fraction, are equipped with installations for vacuum removal of liquid and drainage of the sand-mud fraction.

The essence of the invention lies in the fact that the entire volume of pulp, impregnated with chlorine ions of NaCl and reagent (bleaching lime) Ca (OSl) ₂ , is sent to a closed cycle of cavitation dispersion to grind, heat the pulp and continue hydrochlorination, followed by discharge to a waterproof drainage site. On the drainage site, the formation of complex compounds of gold and silver is completed.

 It is known that cavitation in a liquid occurs the earlier, the more the liquid is contaminated with solid particles. This is due to the fact that a thin layer of air is adsorbed on the surface of solid particles, the particles of which, when they enter the zone of reduced pressure, serve as foci that contribute to the occurrence of cavitation. Cavitation bubbles arising on the surfaces of dispersible materials are deformed when the treated pulp moves. With the condensation of deformed cavitation bubbles, cumulative streams appear, providing intensive dispersion of the pulp.

 The pressures arising at the points of disappearance of cavitation bubbles generate shock waves in the pulp. In the cavitation zone, a huge number of bubbles appear and collapse. Therefore, the same surface or particle of a solid body experiences repeatedly repeated pulses of mechanical stress, which lead to fatigue and subsequent destruction of these particles or films from sparingly soluble compounds (for example, AgCl) formed on the surfaces of recoverable metals.

 It is known that during cavitation exposure to water, hydrogen peroxide is formed in it.

In systems containing chlorine ions, it is possible to oxidize (for example) gold and transfer it into solution in the form of AuCl ₂ ^- and AuCl ₄ complexes ^- not only with the help of such strong oxidizing agents as active chlorine or Н ₂ О ₂ , but also atomic or molecular oxygen.

 The advantages of hydrochlorination of gold and silver include the high chemical activity of chlorine, its much greater solubility in water compared to oxygen. This provides higher speeds of the chlorination process compared to cyanidation rates.

So, for example, if at 25 ^o C and a concentration of chlorine in the solution of 0.02 mol / l, the gold dissolution rate is 73 mg / ms ² • h, when cyanidation it does not exceed 1.7-5.7 mg / cm ² • h

Although, when using bleaching lime Ca (OC) ₂ as a chlorinating reagent, the dissolution rate decreases by 2.5–4.0 times due to the formation of surface films containing calcium compounds. However, as a result of the complex effect of oxidizing agents of chlorine ions, hydrogen peroxide, shock waves from cavitation, destroying ore particles and films of insoluble compounds, abrasive action of the sand fraction on the surface of recoverable metals, contributing to an increase in the dissolution rate of metals to (90-95%) in 1 min

For the simultaneous extraction of gold and silver, it is necessary to carry out hydrochlorination in the presence of thiourea CS (NH ₂ ) ₂ .

 The pulp leaving the cavitation dispersants and having a high temperature is sent to the drainage platform for sludge on the thickened sediment and clarified solution. After settling, the solution is discharged into a secondary sump or tank for final clarification, and the thickened precipitate, consisting of a sand-silt mixture, is subjected to vacuum drainage. In the process of evacuation, the gold- and silver-containing solution through the suction mat is sent to the liquid ring vacuum pump, and then to the secondary sump.

 Dried sandy-mud mass with the remains of the solution and insoluble compounds after neutralization is sent to the dump.

The clarified solution is directed to the recovery of gold and silver contained in chloride solutions. The standard oxidation potentials Е ^o at 25 ^o С of gold and silver in chloride solutions are quite high (from 0.8 to 1.0 V), therefore, from chloride solutions, gold and silver are easily reduced by many reducing agents: oxalic acid, formic acid, tin chloride, carbon monoxide, sulfur dioxide, and the like.

For instance:
2 [AuCl4] ^- + 3H ₂ C ₂ O ₄ = 2Au + 6CO ₂ + 8Cl ^- + 6H ⁺ ;
4 [AuCl ₄ ] ^- + 3C + 6H ₂ O = 4Au + 3CO ₂ + 16Cl ^- + 12H ⁺ ;
2 [AuCl ₄ ] ^- + 3SO ₂ + 6H ₂ O = 2Au + 3SO4 ^2- + 8Cl ^- + 12H ⁺ ;
etc.

Therefore, the recovery of gold and silver from the resulting solutions from hydrochlorination can be obtained by such simple reactions. After the separation of gold and silver, the solution with the components contained in it after a slight adjustment of the concentrations of NaCl and Ca (OCl) _{2 is} sent for recycling.

In fact, the Cl ^- and H ⁺ elements obtained as a result of the reduction reactions of gold and silver are dissociated atoms of hydrochloric acid Hcl, which, by acidifying the solution, increases the positive effect of the dissolution of gold and silver. The second positive effect of the acidification of the HCl solution is the translation of the sparingly soluble silver compound AgCl formed in the initial stage of AgCl ₂ , which is readily soluble in water.

The proposed method of hydrochlorination includes the following known features:
- hydrochlorination occurs in a closed cycle of cavitation dispersion with fine grinding and heating of the pulp, hydrochlorination on the drainage site is completed during cooling and delamination of the pulp;
- separation of the sand-silt fraction from the gold and silver-containing solutions by sedimentation and evacuation;
- clarification of solutions with secondary sludge;
- extraction of gold and silver from clarified solutions with reducing agents: oxalic acid, formic acid, tin chloride, carbon monoxide, sulfur dioxide, etc. followed by separation of the reduced metals;
- the direction of the solid fraction remaining after drainage from the gold and silver solutions to the dump after neutralization;
- the direction of desalted and silver-free chloride solutions for adjustment and recycling.

The disadvantages of this method are:
the need for separation of the solid fraction from the gold and silver-containing solutions of two settlers;
the presence of a sufficiently labor-intensive evacuation process for more complete drainage of the solid fraction from gold and silver-containing solutions.

 The mentioned disadvantages are compensated by the speed of the hydrochlorination process, more complete extraction of gold and silver from the ore, faster draining of the solid fraction, evacuation from solution residues, ease of recovery of gold and silver, and the ability to recover precious metals economically and environmentally safely even at low ambient temperatures.

 Figure 1 shows the process of the hydrochlorination method, in which mixing and cavitation dispersant plants are used for fine grinding, pulp heating and cavitation hydrochlorination, as well as a set of equipment for vacuum dehydration of the sand-clay fraction, a loading and transport complex for the export of sand-clay fraction to the dump.

 In FIG. 2 and 3, a factory plan and section with a set of devices necessary for implementing this hydrochlorination process. The set of devices outside the walls of the factory building is planned in the form of two mirror-mounted halves with solid waterproof bases both inside the building and the settling tanks 3 and 4, drainage pits 29, separated by a partition 30.

 The bases of each part of the complex are made with the necessary slopes, pits, overflow 31 and drainage 20 pipelines, drainage pumps 11 and pumps for pumping the solution 19.

 For periodic dehydration of the sand-mud fraction 26 in the primary sump 3, an evacuation unit is intended, including: a liquid ring vacuum pump 23, a suction mat 25, a suction sleeve 24, a pressure sleeve 22 and a compressor 32.

 An excavator 27, equipped with a clamshell loader, is designed for periodic unloading and neutralization of the drained sand-mud fraction.

 The neutralization of the sand-mud fraction 26 is carried out in the process of loading into vehicles 28.

 The process of the hydrochlorination process is as follows.

The rock mass, ore, concentrate or tailings of the processing plants after grinding in the crushing module to a fraction (5-10 mm) enter the loading device 1, connected by an inclined gallery to the building of the hydrochlorination factory 2. The inclined conveyor 7 with the trolley transfers the crushed ore to the bunkers 8 and then into mortar mixers 9 into which a solution of [NaCl + Ca (Ocl) ₂ ] is supplied from a supply tank 15. A mixture of ore mass and solution (sodium chloride and bleach) is sent after mixing in mixers 9 to rotary cavitation 10 dispersive dispersers, in which the ore mass is ground and pulp is heated, which is returned to the mixers through looped pipelines, then to dispersants, and so on to fine grinding.

 After the necessary dispersion and warming up, the hydrochlorinated pulp is sent through slurry pipe 13 to one of the compartments of the primary settler 3. As one compartment is filled, the pulp discharge switches to the second compartment, and in the first compartment, the pulp settles and stratifies into a gold and silver-containing solution and sandy-silty fraction. After delamination, the solution is piped into a secondary settling tank 31 for final clarification.

 Sand-mud mixture 26 after evacuation is unloaded into the vehicle 28 and sent to the dump.

 The clarified solution from the secondary settler 4 is pumped through a pipe 14 to a storage tank 16, then to a precipitation plant 17. After loading the necessary reducing agents, gold and silver are precipitated from the solution, separated and washed, and the solution, after adjusting the concentrations of sodium chloride and bleach, is sent into the supply tank 15.

 The solution leaked from the primary settler 3 to the drainage pit 5, and the solution fed through the drainage channel 21 to the drainage pit 6, is returned by pumps 19 through the pipe 12 to the primary settler 3.

The H ⁺ and Cl atoms released as a result of the reduction reactions ^, which are actually dissociated hydrochloric acid atoms of HCl, acidify the solution, which is sent for reuse. Acidification has a positive effect on the conversion of insoluble compounds (e.g., AgCl to the complex compound AgCl ₂ ) into soluble ones.

 All parameters of the hydrochlorination process depend on the dispersion of metals in the raw material and are determined by research, laboratory control at all stages of the process, technological and technical and economic calculations.

Sources of information
1. Patent of Russia RU 2154684, LLC Scientific-production company "Himmet". "A method of extracting compounds of platinum metals, gold and silver into a solution."

 2. Russian patent RU 2154118. Institute for Integrated Development Problems of the Russian Academy of Sciences "Cyanidation Method".

 3. B.V. Nekrasov. Fundamentals of General Chemistry. Ed. the third. - M .: Chemistry, 1973, T. I, p.118-122, 147-152; T. II, p. 244-279, 414-462.

 4. I. A. Zubovich. Inorganic chemistry. - M .: Higher school. 1989, p. 171-175, 194-195, 206-218, 411-419.

 5. S.V. Masimov, B.C. Ivkin, E.G. Demenev, V.V. Burnetov. Compaction of concrete with flexible vacuum shields. - UDC 693.546.002.5.

 6. T. M. Bashta. Engineering hydraulics. - M.: Mechanical Engineering, 1971, p. 44-49.

 7. I. Pirsol. Cavitation. Per. from English - M .: Mir, 1975, pp. 11-14, 69-72.

 8. USSR patent, SU 1586759. Sverdlovsk city center of scientific and technical creativity of youth. "Rotary apparatus of hydropercussion."

 9. I. Nentwig, M. Kneider, K. Morgenstern. Chemical simulator, part II. - M .: World. - 1986, p. 130-165.

Claims (3)

 1. The method of extracting gold and silver from ore into a solution, including hydrochlorination, separation of the solid fraction from gold and silver solutions, clarification of solutions, recovery of gold and silver from solutions, characterized in that the hydrochlorination is carried out by cavitation dispersion of the ore, and the separation of the solid fraction from the solution carry out sludge in a waterproof area.  2. The method according to claim 1, characterized in that the cavitation dispersion is carried out when grinding ore to the desired sand-clay fraction while hydrochlorinating in a solution of sodium chloride and bleach.  3. The method according to claim 1, characterized in that after settling and draining the solution, the resulting sand-mud mixture is subjected to vacuum drainage.

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