RU2401311C2 - Method of extracting gold from concentrate - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: proposed method comprises leaching and oxidising concentrated by alkaline solutions of sodium or potassium ferrocyanide in heating. Note here that oxidising and leaching are performed simultaneously in single step at 80-90°C with the help of alkaline solutions of sodium or potassium ferrocyanide that contain oxidisers represented by lime chloride or alkaline metal or ammonia persulphate. In leaching, solutions pH is kept in the range of 12.5 to 13.5.

EFFECT: invention allows said processes to occur at lower temperatures and atmospheric pressure, high selectivity of gold extraction.

6 cl, 1 tbl, 13 ex

Description

The invention relates to hydrometallurgy of precious metals and can be used to extract gold from concentrates obtained from industrial placers, which are characterized by a high content of metal impurities, such as copper, mercury, arsenic.

Modern gold hydrometallurgy is based on the use of a cyanide process by which more than 70% of the metal in the world is extracted from ores (V. Lodeishchikov. Technology for the extraction of gold and silver from refractory ores. Irkutsk. 1999. OAO Irgiredmet. 2 vol. 786 s.). For all its merits, this process is characterized by significant disadvantages, namely the use of a highly toxic solvent - sodium cyanide, as well as the indiscriminate nature of the cyanide process. Along with precious metals, impurity metals such as copper, arsenic, and mercury are also extracted into the leach solution.

This, on the one hand, leads to an increased consumption of sodium cyanide, and on the other hand, pollutes leaching solutions with impurity metals, as a result of which it is necessary to resort to a number of additional operations to remove base metals either in the head or at the end of the process. In particular, in the known method according to US Pat. RF №1716800 (publ. 1994.10.30) the deposition of mercury in the form of sulfide from gold-containing cyanide alkaline solutions is carried out at the end of the process. In another method of processing gold-containing raw materials (RF application No. 94015041, publ. 1994.04.22) leaching of non-ferrous metal impurities is carried out before cyanidation.

There is also known a method of extracting gold from gold-bearing ores, including leaching the feedstock with an alkaline solution of sodium cyanide at the rate of 400 g of sodium cyanide per 1 ton of concentrate. Leaching is carried out for 48 hours in five agitators installed in series. Gold recovery is 96% (Meretukov MA, Orlov A.M. Metallurgy of precious metals. Foreign experience. M.: Metallurgy. 1991. 416 p.).

Common disadvantages of the known methods for extracting gold from concentrates by leaching with sodium cyanide solutions are the high toxicity of the solutions used and the rather high duration of the gold dissolution process. In addition, the presence of free CN ions in leaching solutions leads to the simultaneous extraction of impurity metals present in the feed into the solution.

Closest to the claimed invention is a method for extracting gold from concentrates by leaching with solutions of sodium or potassium ferrocyanides (US Pat. RF No. 2027785, publ. 1995.01.27). The method involves the processing of gold-containing raw materials with alkaline solutions of sodium or potassium ferrocyanides in an autoclave at a temperature of 100-180 ° C and a compressed air pressure of 5-20 ati for 5 hours. According to the example given in the description of the invention, leaching of the concentrate with ferrocyanide solutions is preceded by its oxidation.

The disadvantages of the method include the implementation of the process at elevated temperature and pressure, which necessitates the use of special equipment and increases the cost of the method.

The objective of the invention is to optimize the method of extracting gold from concentrates due to the process at lower temperatures and at atmospheric pressure (which, accordingly, simplifies the hardware design of the method) while ensuring a sufficiently high selectivity for the extraction of gold from concentrates.

The problem is solved by the proposed method for extracting gold from concentrates, including oxidation and leaching of concentrates with alkaline solutions of sodium or potassium ferrocyanides, when heated, in which, in contrast to the known method, the oxidation and leaching of concentrates is carried out simultaneously in one stage by processing them at a temperature of 80-90 ° C alkaline solutions of ferrocyanides containing oxidizing agents, which are used as bleach or alkali metal or ammonium persulfate, while the pH of the solution leaching oroes are kept in the range 12.5–13.5.

The method is as follows.

The gold-containing concentrate is treated with an alkaline solution containing 5-20 g / l of sodium or potassium ferrocyanide and an oxidizing agent in an amount of 10-20 g / l. As oxidizing agents, for example, bleach or sodium persulfate, or potassium, or ammonium can be used.

The specified amount of bleach added to the ferrocyanide solution is sufficient to achieve a solution pH of 12.5-13.5. In the case of using sodium or potassium or ammonium persulfate as an oxidizing agent, alkali metal hydroxide (sodium or potassium) is additionally added to the leaching solutions in an amount of 5-10 g / l of a solution that provides the required pH value.

The process of oxidation and simultaneous leaching of a gold-containing concentrate is carried out with stirring for 5 hours at a temperature of 80-90 ° C and a mass ratio of the concentrate to the leach solution (T: G) equal to 1: 3. During the processing of the concentrate, metallic gold goes into an ionic state, and gold selectively replaces iron in the ferrocyanide complex and goes into solution, while iron in the alkaline environment precipitates in the form of hydroxide. A leach solution containing an excess of sodium or potassium ferrocyanide, after extraction of gold from it and corresponding adjustment, can be used in circulation in the following leaching stages.

It has been experimentally established that the proposed amounts of sodium or potassium ferrocyanide, as well as an oxidizing agent in the leach solution at a solution pH of 12.5–13.5, together provide maximum gold recovery in the leach solution with minimal extraction of impurity metals into the solution.

Thus, in an optimal embodiment of the method, the extraction of gold into the leach solution is 98.7%, while the metal impurities practically do not pass into the solution.

Gold from leaching solutions after filtration and washing the cake with water can be recovered by known methods, for example, by carburization or electrolysis.

Thus, the inventive method of extracting gold provides a sufficiently high and selective extraction of gold from concentrates at lower temperatures and atmospheric pressure, in contrast to the prototype, as a result of which the inventive method does not require complex equipment for its implementation, which is the technical result of the invention. In addition, the listed advantages of the proposed method can reduce energy costs for the implementation of the method.

The possibility of carrying out the invention is confirmed by examples. In all examples, the extraction of gold was carried out from a concentrate obtained from man-made placers of the Fadeevsky deposit of the Primorsky Territory.

The gold content in the leach solution was determined by the method of neutron activation analysis, and the macronutrients of metals (copper, arsenic) were determined by the method of atomic absorption analysis.

Example 1. A concentrate with a gold content of 760 g / t, copper - 0.5%, arsenic - 0.3%, treated with a solution containing 20 g / l potassium ferrocyanide, 20 g / l sodium persulfate and 10 g / l sodium hydroxide for 5 hours at a temperature of 90 ° C and a ratio of solid to liquid (T: G), equal to 1: 3, with constant stirring. After completion of the leaching process, the pulp is filtered, the cake is washed and the washings are combined with the leach solution. The recovery of gold into the solution at the leaching stage was 98.7%. Extraction of copper - 0.07%, arsenic - 0.01%. From a leach solution combined with washings, gold is recovered by cementation.

Example 2. A concentrate with a gold content of 220 g / t, copper - 0.47%, arsenic 0.19% leached with a solution containing 20 g / l of potassium ferrocyanide and 10 g / l of bleach under the same conditions as in the example 1. The recovery of gold in the leach solution was 95.5%. Extraction of copper - 0.8%, arsenic - 0.02%.

Example 3. Carried out according to the conditions of example 2, except that as ferrocyanide take ferrocyanide sodium in an amount of 5 g / L. The recovery of gold in the leach solution is 90.2%. Copper recovery - 0.6%, arsenic - 0.03%.

Example 4. Carried out according to the conditions of example 2, except that as ferrocyanide take ferrocyanide sodium in an amount of 15 g / l and bleach in an amount of 15 g / l. The recovery of gold in the leach solution is 93.2%. Extraction of copper - 0.7%, arsenic - 0.04%.

Example 5. Carried out according to the conditions of example 2 except that bleach is taken in an amount of 20 g / l. The recovery of gold in the leach solution is 96.0%. Extraction of copper - 0.4%, arsenic - 0.05%.

Example 6. Carried out under the conditions of example 2 except that potassium ferrocyanide is taken in an amount of 3 g / l, and bleach - in an amount of 5 g / l. The recovery of gold into the leach solution is low, amounting to only 56.2%.

Example 7. Carried out according to the conditions of example 2 except that potassium ferrocyanide and bleach are taken in an amount of 25 g / L. Extraction of gold into the leach solution is 96.1%, copper - 0.6%, arsenic - 0.08%, which implies that an increase in the content of potassium ferrocyanide and bleach in the leach solution of more than 20 g / l is impractical.

Example 8. Carried out under the conditions of example 1 except that the concentrate is treated with a solution containing 5 g / l of sodium ferrocyanide, 10 g / l of potassium persulfate and 5 g / l of sodium hydroxide. The recovery of gold in the leach solution is 82.3%. Extraction of copper - 0.12%, arsenic - 0.09%.

Example 9. Carried out according to the conditions of example 1 except that the concentrate is treated with a solution containing 15 g / l of potassium ferrocyanide, 15 g / l of potassium persulfate and 5 g / l of potassium hydroxide. The processing of the concentrate is carried out at 80 ° C. The recovery of gold in the leach solution is 95.6%. Copper extraction - 0.10%, arsenic - 0.05%.

Example 10. Carried out according to the conditions of example 1 except that the concentrate is treated with a solution containing 15 g / l of potassium ferrocyanide, 15 g / l of ammonium persulfate and 10 g / l of sodium hydroxide. The recovery of gold in the leach solution is 95.8%. Copper recovery - 0.09%, arsenic - 0.02%.

Example 11. Carried out according to the conditions of example 1 except that the concentrate is treated with a solution containing 25 g / l of potassium ferrocyanide, 25 g / l of potassium persulfate and 10 g / l of sodium hydroxide. The recovery of gold in the leach solution is 94.7%, which implies that an increase in the content of potassium ferrocyanide and potassium persulfate in the leach solution of more than 20 g / l is not economically feasible. Extraction of copper - 0.08%, arsenic - 0.04%.

Example 12. Carried out according to the conditions of example 1 except that the concentrate is treated with a solution containing 10 g / l of potassium ferrocyanide, 5 g / l of potassium persulfate and 3 g / l of sodium hydroxide. The recovery of gold in the leach solution is low, amounting to only 42.1%.

Example 13. (According to the prototype.) A concentrate with a gold content of 220 g / t, copper - 0.47%, arsenic 0.19% is first subjected to oxidation in an alkaline environment in an autoclave, the liquid and solid phases are separated. The solid phase is subjected to cyanidation with potassium ferrocyanide in an autoclave at a temperature of 140 ° C, a pressure of 14 atm, and at T: W = 1: 2 for 5 hours. Gold recovery into the leaching solution was 81%, copper - 2%, arsenic - 6% .

The table below shows the basic conditions for the implementation of examples 1-12 and indicators of gold recovery in the leach solution.

Example Number MFe (CN) ₆ , g / l Ca (ClO) ₂ , g / l M ₂ S ₂ O ₈ , g / l NaOH, g / l Extraction of Au in a leach solution one twenty - twenty 10 98.7 2 twenty 10 - - 95.5 3 5 10 - - 90.2 four fifteen fifteen - - 93.2 5 twenty twenty - - 96.0 6 3 5 - - 56.2 7 25 25 - - 96.1 8 5 - 10 5 82.3 9 fifteen - fifteen 5 95.6 10 fifteen - fifteen 10 95.8 eleven 25 - 25 10 94.7 12 10 - 5 3 42.1

Claims (6)

1. The method of extracting gold from concentrates, including the oxidation and leaching of concentrates with alkaline solutions of sodium or potassium ferrocyanides, when heated, the oxidation and leaching of concentrates is carried out simultaneously in one stage by processing them at a temperature of 80-90 ° C with alkaline solutions of ferrocyanides containing oxidizing agents, which use bleach or an alkali metal or ammonium persulfate, while the pH of the leach solutions is kept in the range 12.5-13.5. 2. The method according to claim 1, characterized in that the leach solutions contain 5-20 g / l of sodium or potassium ferrocyanides. 3. The method according to claim 1, characterized in that the leach solutions contain bleach or sodium or potassium or ammonium persulfate in an amount of 10-20 g / l of solution. 4. The method according to claim 1 or 2, characterized in that when using alkali metal or ammonium persulfate as an oxidizing agent, the leach solutions contain sodium or potassium hydroxide in an amount of 5-10 g / l of solution. 5. The method according to claim 1, characterized in that the mass ratio of the concentrate to the leach solution is 1: 3. 6. The method according to claim 1, characterized in that the leaching of concentrates is carried out for 5 hours