RU2322580C1 - Method for complex enrichment and additional recovery of metals in dump - Google Patents

Abstract

FIELD: complex chemical and electrochemical additional metal recovery from tails, mud and depleted ore directly in bank facilities, namely in tailing dumps, in mud accumulation structures and rock dumps.

SUBSTANCE: method involves forming layer of tails, mud or depleted ore (mud) on water-impermeable base; drilling at least one well to supply chemical reagents, at least one well to receive coal anode, which generates oxygen inside mud layer; arranging at least three cementing pairs C anode - Al cathode, wherein two pairs are arranged inside mud body and the third one is located in drain well along with at least one coal or aluminum cathode. The chemical reagents are aqueous sulfuric acid solution or mixture including sulfuric acid and ferric sulfate(+3), preferably mixture with concentration 0.15M H₂SO₄+0.15M Fe₂(SO₄)₃.

EFFECT: increased efficiency of metal concentration on movable geochemical barrier, increased degree of additional metal recovery from drain water and increased environmental safety.

2 cl, 1 dwg

Description

The invention relates to the field of development of technology for complex chemical and electrochemical extraction of metals (zinc, lead, copper, cadmium, nickel, cobalt and noble metals), mainly from tailings, sludges and depleted ores directly in the places of their storage: in tailings, sludge collectors, mining dumps .

A fairly large number of patents are known for methods for intra-mine dressing of rocks, for example (RU 2002951 C1, 11/15/1993), metal-containing rocks, for example (RU 2013551 C1, 05/30/1994), substandard ores, for example (RU 2060391 C1, 05/20/1996) .

For all methods, common signs are the formation of a drainage, enrichable, leachable layer, the presence of perforated pipelines, the treatment of the leachable layer with chemical reagents, while the enrichment solutions are removed through the drainage layer. A common disadvantage of such methods is the low metal recovery efficiency.

A known method of intra-mine dressing and processing of substandard ores, mainly containing Nickel (RU 2058483 C1, 04/20/1996).

The method consists in the following: initially, a drainage layer is formed, then an enriched (adsorption) layer is made of substandard metal-containing (for example, nickel) ores based on minerals - nickel precipitators, mainly minerals with uncompensated layer charges, after which a leachable layer is formed from nickel-containing sulfide rocks; during the storage period of the rock during hypergenesis, nickel is leached from the leached layer and nickel-containing solutions migrate to the enriched layer, where nickel is deposited on the geochemical barrier, and then man-made ores are processed by electrodialysis.

The known invention allows to increase the efficiency of redistribution in the dump mass of Nickel, however, its subsequent extraction has a fairly low coefficient.

There is a method of leaching metals by alternating electric current, including opening the ore deposits by boreholes, placing casing strings, filters, heads and electrodes in them, supplying technological solutions and electricity, while leaching of metals from ores is carried out when the frequency of the supplied alternating electric current coincides with the frequency of their own optical oscillations of the lattice of leached minerals at a frequency of supplied alternating electric current equal to 10 ¹³ Hz, as a result, leaching occurs metals from ores and the migration of metal-bearing solutions to the pumping well, through which they are extracted to the surface and sent to the hydrometallurgical plant (RU 2105877 C1, 02.27.1998).

The method is sufficiently effective for the extraction of metals from ore deposits, but ineffective for depleted ores, sludges and dumps containing metals at a level below 0.1%. In addition, the method requires additional extraction of metals from enriched solutions outside the place of development.

Patent studies have shown that there are currently no effective methods for intra-mine dressing and recovery of metals from tailings, sludge and depleted ores that could be used directly in the places of their storage.

The technical task of the invention is the creation of a fundamentally new method of integrated intra-mine dressing and additional extraction of metals from tailings, sludges and depleted ores as effective, economical and environmentally friendly methods of forming technogenic deposits directly in the places of their storage and processing of raw materials near mining and processing and mining and metallurgical (MMC) plants.

The technical result of the method is to increase the efficiency of concentration of metals on a moving geochemical barrier, increase the degree of additional extraction of metals from drainage water and increase the environmental safety of the environment.

The technical result is achieved by the fact that the method of complex intra-mine dressing and additional extraction of metals from sludge, tailings or depleted ores is characterized by the fact that they form a layer of tailings, sludge or depleted ores (hereinafter sludge) on a water-resistant base, at least one discharge is placed inside the sludge layer perforated well for supplying chemicals, at least one well for placement of a carbon anode generating oxygen, placement of at least three cementitious pairs C anode - A l a cathode, two of which are placed in the body of the sludge, and a third in the drainage well together with at least one carbon or aluminum cathode, designed to extract metal from the drainage water, while an aqueous solution of sulfuric acid or a mixture of sulfuric acid are used as chemical reagents acid with iron sulfate (+3), mainly a mixture of a concentration of 0.15M H ₂ SO ₄ + 0.15M Fe ₂ (SO ₄ ) ₃ . As chemical reagents, sulfuric acid solutions of waste from mining and processing or mining and metallurgical plants can also be used.

The development of the method has a dual purpose and is aimed at:

1) the formation of complex technogenic deposits as a means of renewing mineral resources;

2) reduction of the environmental load on the environment (natural waters and the atmosphere) in places of storage and processing of tailings, sludge and depleted ores;

3) cheaper processes of sulfide oxidation and metal deposition in the secondary enrichment zone using available reagents of large-tonnage chemical technologies used in the practice of specific GOKs and MMCs.

The drawing shows a variant of the scheme of integrated intra-mine enrichment and recovery of metals using sludge as an example, where 1 is sludge, 2 is a water-resistant base, 3 is a perforated injection well for supplying a chemical reagent, 4 is a well in which a carbon anode is located, 5, three cement couples 6, 7 — drainage well in which cathode 8 is placed. Arrows indicate the direction of solution filtration.

The sludge from the Sadon group of deposits containing quartz, feldspars, carbonates, pyrite and ore minerals: galena, sphalerite, chalcopyrite was used as sludge. The number of anodes, cathodes of cementing pairs depends on the volume of the sludge storage and can reach up to several tens units.

The essence of the method is as follows.

Within the framework of the experiment, the intensification of the oxidation process is carried out comprehensively, i.e. by the reagent method, by introducing a solution of sulfuric acid as a oxidizing agent into the injection well, or a mixture of a solution of sulfuric acid and iron sulfate (0.15M H ₂ SO ₄ + 0.15M Fe ₂ (SO ₄ ) ₃ )) and electrochemically by generating oxygen on coal anodes. The main concentration process is the secondary deposition of sulfides of ore elements during the interaction of their sulfate solutions with usually dominant pyrite or arsenopyrite and dispersed initial sulfides of ore elements. An additional process that facilitates the concentration and accumulation of ore elements is the hydrolytic formation of iron hydroxide on a moving barrier during the interaction and neutralization of sulfate solutions with feldspars and carbonates of rocks and tailings. At the moving front of the formation of Fe (III) hydroxide, with a change in pH from 1-2 to 5-6, adsorption and co-depositional accumulation of heavy metals occurs. Partial interception and their concentration, as well as monitoring the speed of movement of the geochemical barrier, is carried out by cathodes of cementation and loaded pairs of electrodes introduced into the solution downstream (for example, into a drainage well or directly into the body of a sludge collector).

With this complex treatment of sludge, the chromatographic movement of metals in the form of sulfate solutions occurs in the direction of filtration and the secondary adsorption-precipitation concentration of ore sulfides in the mobile layer towards the drainage system, where cathodic extraction of metals from drainage water solutions is carried out for their purification.

With regard to storage conditions in pond tailings, this is as follows. A system of wells is drilled to the base of the tailing dump, into which anodes generating oxygen are placed. Sulfuric acid solution is supplied, but the main filtration of the flow is lateral, towards the drainage system. The oxidation of sulfides and the transfer of heavy metals to a mobile state. During the filtration process, the solution interacts with carbonates and sulphides of the sludge and is neutralized. The filtrate (pH 5-7) with metals dissolved in it comes into the drainage system. A cathode of a loaded pair (or cathodes of pairs) is placed in the drainage well, which intercepts and concentrates heavy metals on its surface, thereby removing them from the solution. Partial interception and concentration of metals is carried out by cementation and loaded vapors introduced directly into the body of the sludge dump (tailings).

The reagent oxidation of sludge sulfides by a solution of sulfuric acid and ferric sulfate is described by the following reactions:

(1) 2FeS ₂ + 4H ₂ SO ₄ = 5S + Fe ₂ (SO ₄ ) ₃ + 4H ₂ O

(2) FeS ₂ + Fe ₂ (SO ₄ ) ₃ + 4H ₂ O = 3Fe (OH) ₂ + 2S + 3H ₂ SO ₄ and

for all sulfides: (3) MeS + 2O ₂ = MeSO ₄ .

In this case, the ferric sulfate solution begins to hydrolyze with the formation of iron (III) hydroxide and new portions of sulfuric acid: Fe ₂ (SO ₄ ) ₃ + 6Н ₂ О = 2Fe (ОН) ₃ + 3H ₂ SO ₄ . Thus, 75% of sulfuric acid is generated by hydrolysis of Fe ₂ (SO ₄ ) ₃ .

The generation of oxygen on graphite anodes accelerates the oxidation process due to the electrolytic decomposition of water: O ₂ + 4H ⁺ + 4е ^- → 2Н ₂ О

In the anode space, the solution is acidified, i.e. additional sulfuric acid generation occurs electrochemically.

Experimental data showed that when filtering a chemical reagent through sludge and due to the oxygen of the anode, the ore elements are intensively extracted into the solution, but the concentration decreases along the route of the solution in the direction of filtration due to the formation of new sulfides. A mobile geochemical barrier forms in the sludge, which slowly moves in the direction of the solution filtration; at the beginning of the filtration, the content of elements at the outlet of the solution to the drainage well is low due to the intensive neutralization of sulfuric acid by the sludge. As the barrier advances in the direction of filtration, the content of elements in it and in the drainage well increases, and when their concentration exceeds the maximum permissible norm in the well, metals are recovered at the cathode, after which the drainage waters become environmentally friendly.

The concentration coefficient of metals on a moving geochemical barrier varies from 10 to 100 depending on the nature of metals and sludge.

In the cathode space, the solution is electrochemically alkalized.

The experiments showed that the additional extraction of metals from sludge is from 10 to 50%, depending on the nature of the metal and the exposure time. So for lead and zinc, the initial concentration was 0.5% and 2%, respectively. After complex exposure for 30 days in the upper zone of the sludge collector, it decreased to 0.1%. The process of complete intra-dump retrieval and enrichment is lengthy, but is industrially profitable.

The main process of reagent and electrochemical additional extraction of ore components from the entire tailings (sludge and depleted ores), followed by extraction at the cathodes, is organized during the injection of aggressive solutions so that an adsorption-precipitation geochemical barrier is formed in the body of the accumulated tailings, the concentration of ore elements on which is slow but continuously increases as it moves to the drainage system. The combination of chemically contrasting processes: oxidation and acidification in the anode zone, reduction and alkalization in the cathode zone, was done for the first time for sludge collectors. The first processes mobilize ore components with the dissolution of sulfides in the rear of the barrier and secondary deposition at its front. The cathodic processes immobilize, immobilize the ore substance, additionally extracting from the solution also increasing concentrations of useful components.

The proposed method can be used to create complex technogenic deposits as a means of renewing mineral resources and reducing the environmental burden on the environment in the places of storage and processing of ores. The use of available reagents of large-tonnage chemical technologies used or produced during the operation of most GOKs and MMCs reduces the cost of the process.

Thus, a new promising, environmentally friendly method has been developed for the integrated enrichment and additional extraction of metals from tailings, sludges and depleted ores.

Claims (2)

1. The method of integrated intra-waste enrichment and recovery of metals from tailings sludge or depleted ores, characterized in that the sludge layer is formed on a water-resistant base, at least one injection well is placed inside the body of sludge for supplying chemicals, at least one well at least three cementing pairs C anode - Al cathode are placed to place a carbon anode generating oxygen, two of which are placed in the body of the sludge, and the third - in the drainage well together, at least e, with one carbon or aluminum cathode, designed to monitor the extraction of metal, including from drainage waters, while an aqueous solution of sulfuric acid or a mixture of sulfuric acid with iron sulfate (+3) is used as chemical reagents, mainly a mixture of concentration 0, 15M H ₂ SO ₄ + 0.15M Fe ₂ (SO ₄ ) ₃ . 2. The method according to claim 1, characterized in that sulfuric acid solutions of waste from mining and processing or mining and metallurgical plants are used as chemical reagents.