RU2065952C1 - Method for bacterial leaching of sulfide ores and concentrates - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: invention concerns bacterial leaching of iron and arsenic-containing finely divided floatation concentrates, in particular, gold-arsenic, tin-arsenic, and polymetal floatation concentrates, as well as finely divided sulfide ores and their wastes. Material is first subjected to granulation, for example, on a bowl granulator producing acid- resistant grains. Into the latter, bacteria, for example, autotroph acidophilic bacteria are entered to be accumulated in the material. Then bacteria-rich material is heaped on a waterproof basis and sprinkled with bacterial solution. EFFECT: enhanced efficiency of process.

Description

 The invention relates to the mining industry and can be used for bacterial leaching of iron-containing, arsenic-containing finely ground flotation concentrates: gold-arsenic, tin-arsenic, collective polymetallic and other flotation concentrates, as well as finely ground sulfide ores and their wastes.

 A known method of heap bacterial leaching.

However, it is not advisable to use this method for leaching concentrates, that is, during leaching during irrigation with bacterial solutions, natural siltation of the concentrate occurs [1]
A known method of vat bacterial leaching of sulfide ores and concentrates [2] Vat leaching is carried out in acid-resistant vats.

 The disadvantages of this method are the relatively low productivity, complexity and cumbersome hardware design of the technological scheme. In addition, the low pH of solutions in almost all operations of the technological process necessitates the manufacture of all equipment and pipelines from acid-resistant materials, mainly expensive alloy steels.

 The purpose of the invention is to increase the efficiency of the method with high leaching efficiency.

 The goal is achieved by the fact that finely ground material (concentrate or ore and its waste) is subjected to granulation to obtain acid-resistant granules, bacteria are introduced into it, a heap is formed and a bacterial solution is irrigated.

 The essence of the proposed method is as follows.

 The finely ground material is granulated, for example, on a bowl granulator to obtain acid-resistant granules, then bacteria, for example, autotrophic acidophilus bacteria [Thiobacillus ferrooxidans and Thiobacillus thiooxidans], are introduced into the granular material. In this case, the bacteria penetrate into the pores of the granules and remain in them. This operation serves to accumulate bacteria in the material before leaching.

 A heap is formed from a material enriched with bacteria on a waterproof base.

 The formed heap is irrigated from above with a reverse bacterial solution, which serves to leach various components (As, Sb, Cu, Zn, Ni, etc.). The bacterial solution flowing from under the heap is collected in a settling pond, from where it is again irrigated.

 With the accumulation of leached elements in a circulating bacterial solution, the latter enters into their selection by known methods. The purified solution is regenerated and returned to the settling pond for irrigation.

 Air supply to the heap and pond to create a process of continuous cultivation of introduced bacteria, which determines their high activity and abundance, is carried out through perforated pipes introduced into them.

 In the process of bacterial leaching, As, Sb, Cu, Zn, and others enter the solution. Gold and silver remain in the solid phase and are subsequently extracted by pyro or hydrometallurgical methods.

 PRI me R 1.

A flotation sulfide polymetallic concentrate was tested with a gold content of 31 g / t, silver 290 g / t and copper 2.5
The initial flotation sulfide concentrate with a particle size of 0.074 mm is subjected to granulation to obtain acid-resistant granules, the obtained granules are mixed with a bacterial solution at a concentration of at least 10 cells / g of material and sent to the formation of a heap. The heap formed is leached with bacterial solutions for several months. After precipitation, the leached solution containing copper was concentrated by condensation to obtain a solution which, after culturing the bacteria, is returned to the leaching process. The leached heap is cyaninated to produce gold and silver. Extraction of metals amounted, wt. copper 97
98; gold 93.0 93.5; silver 79 80.

 PRI me R 2.

 We tested a flotation sulfide polymetallic concentrate with a grain size of 0.074 mm with an arsenic content of 16 gold 36 g / t, silver 280 g / t, and the gold in the submicroscopic disseminated concentrate is associated mainly with arsenopyrite and pyrite. The experimental conditions are similar to the conditions in example 1, but instead of carburizing copper, arsenic is precipitated. Extraction of metals amounted, wt. gold 94.0 94.5; silver 80.2 - 82.1; arsenic 97.0 98.0.

 The results of experimental verification of the method confirm the high efficiency of heap bacterial leaching of finely ground sulfide materials. 2 At the same time, due to the proposed method, it becomes possible to use the heap method for bacterial leaching of finely ground ores and concentrates. The process compared to the tank is simpler, since it does not require significant capital and operating costs, it is simpler hardware (requires much less expensive equipment) and technological (eliminates a number of expensive technological operations: filtering, mixing) scheme. At the same time, the performance of the heap process is unlimited.

 Thus, the proposed method improves the efficiency of the process with high efficiency leaching of finely ground sulfide ores and concentrates.

Claims (1)

 A method for bacterial leaching of sulfide ores and concentrates by adding bacteria to them and irrigation with solutions, characterized in that before adding bacteria, sulfide ores and concentrates are granulated to obtain acid-resistant granules, after the bacteria are added, a heap is formed from the granules, and irrigation is carried out with bacterial solutions.