RU2758915C2 - Method for extracting gold from gold-containing raw materials - Google Patents

Abstract

FIELD: hydrometallurgy.

SUBSTANCE: invention relates to hydrometallurgy and can be used in the extraction of gold from gold-containing raw materials. The extraction of gold from gold-containing raw materials includes the treatment of raw materials with a leaching solution containing acid, sodium chloride and a chlorine-containing oxidizer, which is used as chloroisocyanurates. The leaching solution has a pH of 4-6. During the processing of raw materials, the oxidative potential of the leaching solution is controlled and maintained in the range of + 0.7-1.3 V by introducing hydrogen peroxide into the leaching solution.

EFFECT: method makes it possible to improve environmental performance in the processing of gold-containing raw materials while reducing the consumption of chlorine-containing reagents by 1.5-2 times.

1 cl, 1 dwg, 1 ex

Description

The invention relates to hydrometallurgy and can be used in the leaching of precious metals from ores, concentrates and tailings.

Precious metals are extremely resistant to chemical attack; they dissolve only if the solution contains an oxidizing agent and a ligand that binds gold into a strong complex. None of the ingredients are effective on their own. The combination of a ligand and an oxidizing agent that dissolves the valuable components is called a leach system.

The choice of a particular leach system depends on various factors, including the cost of the components, manufacturability and environmental friendliness. For hydrometallurgical processes, the main factor of choice is often environmental friendliness and safety of use in relation to personnel.

In practical metallurgy, for the extraction of gold from ores and concentrates, the most widely used system is the combination of sodium (potassium) cyanide as a ligand with air (oxygen) as an oxidizing agent. The thermodynamic basis for the preferred use of cyanides is the exceptional strength of the complexes formed. Even a relatively low oxidation potential of oxygen in aqueous solutions (+0.4 V) at atmospheric pressure is sufficient for oxidation and conversion of gold into a cyanide complex / 1 . Maslenitskiy I.N., Chugaev L.G. and others, Metallurgy of noble metals. - M .: Metallurgy, 1987 366 p. /.

The selectivity of the action of cyanide solutions with respect to gold, the possibility of using conventional iron equipment for cyanidation, the technological stability of cyanides and the possibility of using this reagent in circulation made cyanidation uncompetitive in the processing of most types of base ores and concentrates. The main disadvantages of cyanide leaching are the high toxicity of the reagent and the low rate of the process.

For the leaching of gold and silver from mineral and secondary raw materials, many alternative ligand / oxidant systems are known and tested to varying degrees: thiourea, sulfuric acid / 2 . AS .. USSR No. 1319661 / and thiocyanate / 3. RF No. 2275436 / with ferric ions; sulfite, sodium thiosulfate, copper (II) sulfate and ammonia in combination with oxygen; bromate, sodium bromide and bromine, iodide and iodine, / 4. Mineev GG, Panchenko AF Solvents of gold and silver in hydrometallurgy. - M .: Metallurgy, 1994 .-- 241 p.); sulfur solution in milk of lime ( 5. RF No. 1788768), thiocyanate solution and permanganate / 6 . RF No. 32275436 /, dithiooxamide or substituted dithiooxamide / 7 . RF No. 2575278 / etc.

Before the invention of the cyanide method, acidic and alkaline solutions containing chlorine ion as a complexing agent and active chlorine capable of oxidizing gold were widely used for processing ores and concentrates. Chlorine gas, hypochlorites and perchlorates of alkali metals / 1 / were used as the oxidizing agent.

Known methods and compositions for leaching gold, including preliminary acidification of ore with a solution of hydrochloric acid and leaching of ore with hydrochloric acid solutions, including halite and molecular chlorine / 8. Neberi VP. Cherpey E.I. Babichev N.I. Krasilnikova R.G. On the extraction of gold from the subsoil by in-situ leaching. Hydrometallurgy of gold. M. Nedra, 1980, p. 63-67 /, surfactant and hypochlorite / 9. RF No. 2476610 /, hydrochloric acid, sodium, potassium or calcium hypochlorites / 10. RF No. 2094605, 11 . RF No. 2093672 /, aqueous solution of hypochlorous acid / 12 . RF №2137855 /. The disadvantages of the known solutions include: high cost of reagents, increased aggressiveness of acid solutions in relation to technological equipment.

There is a known method of extracting gold from ore and other raw materials, including the treatment of ore or concentrate with a solution containing chlorides and a carrier of active chlorine, which is used as chlorisocyanurates / 13 . CN No. 1047346A /.

This solution is the closest to the proposed one in terms of the number of common features and is chosen as a prototype. Chloroisocyanurates are chlorine-containing derivatives of cyanuric acid (C ₃ H ₃ N ₃ O ₃ ), which belongs to the category of organic acids. In fact, cyanuric acid (abbreviated as CYA) is a stabilizer for active chlorine. Preparations based on dichloro - and trichloroisocyanuric acid are widely used for sanitizing pool water and as disinfecting washing liquids. When chlorisocyanurates are dissolved in water, active chlorine is released, which provides the oxidizing function of the reagent. The preparations are poorly soluble in water, and this feature of chlorisocyanurates causes prolongation of the oxidizing properties of the reagent, ensures confident regulation and maintenance of the required redox potential of the leaching system in a wide pH range at the required level.

The most important feature of chlorisocyanurates is their environmental safety, reagents of this type belong to the III hazard class of chemicals, which is an indicator of the extremely low toxicological hazard of the reagent. For comparison, hypochlorite used as an oxidizing agent for gold in known methods is classified as a hazardous reagent in accordance with industrial safety requirements.

When chlorisocyanurates are used as an oxidizing agent for leaching gold from mineral raw materials, the activity of the reagent initially introduced into the system is noticeably reduced, the completeness of using the reagent for the target process also decreases, and the specific consumption increases accordingly. The initial introduction of an excess of oxidant is accompanied by unproductive decomposition and release of chlorine gas into the atmosphere.

The technical problem to be solved by the proposed method lies in the high specific costs of reagents, typical for the extraction of gold from ores and concentrates using known methods, including the prototype and insufficient environmental friendliness of the application.

The technical result is achieved by controlling the oxidation potential of the leach solution and using an additional oxidizing agent, which ensures the reactivation of chloroisocyanurates.

The technical result is achieved when using a method that includes processing raw materials with a leaching solution containing hydrochloric or sulfuric acid, sodium chloride and a chlorine-containing oxidant, which is used as chlorine isocyanurates. Unlike the prototype, in the proposed method, the leach solution has a pH of 4-6, while during the processing of raw materials, the oxidation potential is monitored and maintained in the range of + 0.7 ÷ 1.3 V by introducing hydrogen peroxide into the leaching solution.

The essence of the invention is illustrated by figure 1 (table), which shows the results of experiments carried out in comparable conditions.

Studies have shown that gold goes into an acidic solution containing chlorisocyanurates at a rate acceptable for practical purposes. The optimal composition of the leaching solution includes hydrochloric or sulfuric acid in an amount providing pH = 4-6 and sodium chloride providing the required amount of a complexing agent. The optimal consumption of chlorisocyanurates depends on the properties of the feedstock, temperature and other conditions of use. The above pH range corresponds to the conditions for the rational consumption of chlorisocyanurates. In a more acidic environment, the unproductive decomposition of the oxidant is intensified; in a neutral and slightly alkaline medium, oxidized gold compounds are hydrolyzed.

In accordance with the theoretical foundations of the process under study, the factor that determines the rate of gold leaching is the oxidation potential (OP) of the system. The higher the specific consumption of the reagent, the higher the OD and the higher the leaching rate. At the same time, with an excessive specific consumption of chlorisocyanurates, the degree of productive consumption for the target process decreases, the active chlorine formed in excess is released into the atmosphere. In this regard, the criterion for the optimal consumption of chlorine isocyanurates, regardless of the types of this reagent, is the OP, at which gold leaches, but unproductive chlorine release into the atmosphere is not observed. On the other hand, particles of poorly water-soluble chlorisocyanurates during leaching in water-mineral systems are covered with films of secondary insoluble compounds, the activity of the oxidizing agent decreases, and a significant part of the initially introduced reagent in neutral and weakly acidic solutions remains unused for its intended purpose. The results of targeted experiments show that the activation of the oxidizing properties of chlorisocyanurates and an increase in the completeness of use is achieved by the introduction of an additional environmentally friendly oxidant. It is proposed to use hydrogen peroxide as such an initiator of the activity of chlorisocyanurates. The condition for the rational use of the main and additional oxidizing agent is the maintenance of the oxidizing potential of the leach solution in the range of + 0.7 ÷ 1.3 V.

An example of the implementation of the proposed method are the results of the following experiments.

As an object of research, we used dry, crushed to a particle size of 0.1 mm, gold-bearing quartz ore with a gold content of 2.7 g / t. Samples of ore weighing 100 g were mixed with water, the required amount of sulfuric acid was added, and in other experiments - hydrochloric acid at W: T = 3: 1 until the required pH value was reached. The resulting mixture was variably added with dichloroisocyanuric (DCCA) acid or trichloroisocyanuric (TCA) acid in amounts providing a predetermined initial value of the oxidative potential. Leaching was carried out at room temperature in a beaker, the pulp was stirred with a mechanical stirrer; leaching duration - 10 hours. During leaching, the oxidation potential of the system was monitored using a Milwaukee ORP57 ORP meter. With a decrease in OD less than + 0.7 V, the required amount of hydrogen peroxide (35%) was added to the pulp. After the end of leaching, the solutions were analyzed for gold content by atomic adsorption, and the degree of recovery was estimated from the results of the analysis. To assess the environmental performance, the reactor was sealed and the release of gaseous chlorine from the pulp was monitored using a hydraulic seal.

For comparison, experiments were carried out on the conditions of the prototype method.

The results are shown in tables (Fig. 1).

Comparative analysis of technical solutions, incl. the method, presented as a prototype, and the proposed invention, allows us to conclude that it is the combination of the claimed features that ensures the achievement of the required technical result. The implementation of the proposed method makes it possible to improve environmental performance in the processing of gold-containing raw materials and reduce the consumption of chlorine-containing reagents by 1.5-2 times.

Claims (1)

A method for extracting gold from gold-containing raw materials, including processing the raw material with a leaching solution containing acid, sodium chloride and a chlorine-containing oxidant, which is used as chlorine isocyanurates, characterized in that the leaching solution has a pH of 4-6, while during the processing of the raw material, the oxidative potential of the leaching solution in the range of + 0.7-1.3 V by introducing hydrogen peroxide into the leaching solution.

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