RU2350394C2 - Method of ore pretreatment of oxidated and mixed copper ores for leaching - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method of ore pretreatment of oxidized and mixed ores for leaching consists in consecutive size reduction by ore crushing by means of dry method. Reduction is implemented in 4 stages: till fineness minus 300-350 mm, till fineness minus 50-75 mm, till fineness minus 10-20 mm and till fineness, providing surface opening of oxidized minerals of copper no less than 50%. Screening is implemented after each of the first three crushing stages with screening and direction of finished fineness fraction of the following stage into corresponding crushing stage or final crushing product, with implementation of closing stage of crushing by impact centrifugal method.

EFFECT: effectiveness increase of copper extraction, more full and selective surface opening of oxidised minerals, reduction of equipment quantity for crushing and power consumption.

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Description

The invention relates to the metallurgy of copper, as well as the metallurgy of other non-ferrous metals, in particular to a method for ore preparation of oxidized and sulfide-oxidized copper ores for leaching.

Extraction of metals from ores containing oxidized copper compounds is often carried out using the leaching process, for which the size of the material is previously reduced by crushing and grinding.

A known method of dry concentration of wollastonite ore (RU 2142348, B07B 13/00, publ. 10.12.99), including dry crushing of ore, grinding in a cone inertial crusher (KID) or self-grinding mill "AEROFOL" with air classification by particle size, while Before ore is crushed to a grade of ore, it is screened with separation into size classes, after which the +50 mm class is sent for refinement, the -10 mm class is fed to the KID, and the +10, -20 and +20, -50 mm classes are sent to an X-ray luminescent separator low wollastonite pieces you put in tails, after which the pre-ore and the fineness class -10 mm are subjected to grinding by KID to a fineness of -3 mm, from which, using the air classification, the fineness class -0.1 mm representing the first wollastonite concentrate, the fineness class +0.1 -3 mm is passed through a magnetic separator.

The advantage of this method is the implementation of dry ore preparation for the separation of concentrates. The disadvantage of this method is the limitation of the purpose of ore preparation for the implementation of dry beneficiation methods - lumpy x-ray luminescent preconcentration and deslaminated magnetic rather than wet beneficiation methods, in particular leaching, the use of an inertial cone crusher at all stages of crushing.

A known method of impact crushing of ores and rocks (RU 2178589, C22B 3/00, publ. 10.12.01), including the division of the source material into two streams and the destruction of the material.

The method defines a method of impact crushing, which can be used for dry crushing, but there is no crushing size and ore preparation scheme for leaching copper ores.

A known method of processing oxidized copper and mixed ores (RU 2179589, C22B 3/00, publ. 02.20.2002), including dry ore preparation for leaching, carried out by crushing and grinding of the initial product to the required size of fractions exceeding the flotation fraction for subsequent leaching.

The disadvantages of the method are the lack of ore preparation schemes and crushing methods to obtain materials of the desired fraction and quality, the indefinite final size of the ore for leaching.

The closest analogue is the method of ore preparation of oxidized and mixed copper ores for leaching, including reducing the ore by dry grinding to obtain a finished fraction of 2-6 mm, sufficient to selectively reveal the surface of the oxidized minerals for leaching (SU 45572 B03B 07/00, publ. 01/31/1936 )

The disadvantages of the method are the lack of ore crushing scheme, which determines the energy consumption for ore preparation, crushing methods that affect the efficiency of subsequent leaching, methods for determining the final ore size, in which oxidized copper minerals are selectively revealed for leaching.

The technical result of the claimed method is to increase the extraction of copper from crushed ore during leaching, reducing the cost of electricity for ore preparation, as well as the volume of circulating flows during ore preparation, the volume of equipment for crushing ore.

The specified technical result is achieved as follows. The method of ore preparation of oxidized and mixed copper ores for leaching, which consists in sequentially reducing the fineness by crushing the ore by dry method in 4 stages: to fineness minus 300-350 mm, to fineness minus 50-75 mm, to fineness minus 10-20 mm and to fineness, providing a surface opening of oxidized copper minerals of at least 50%, screening after each of the first three stages of crushing with screening and sending fractions of the finished size of the subsequent stage to the corresponding stage of crushing or the final crushing product, with wasp By the final stage of crushing by centrifugal-shock method.

In addition, the fineness of the final finished fraction, sufficient to reveal the surface of the oxidized copper minerals for leaching, is minus 1-4 mm.

The achievement of the above technical result using the above characteristics is provided as follows.

Dry ore crushing can reduce the consumption of water and electricity for ore preparation, the size of the tailings and save sulfuric acid for subsequent leaching.

The sequential step-by-step reduction of the initial ore size (minus 1200 mm) with screening and screening of fractions of the finished size of the subsequent stages after the first three stages of crushing allows the ore to be crushed faster, with less energy and equipment, by reducing circulating flows, reducing the load on the crushers.

The size of the finished ore fractions in the first three stages of crushing (minus 300-350 mm, minus 50-75 mm, minus 10-20 mm) is determined by the physico-chemical properties of the ore, the characteristics of the crushers used.

The fractions of finished size for the first stage of crushing are minus 300-350 mm, for the second stage of crushing minus 50-75 mm, for the third stage of crushing minus 10-20 mm, for the fourth stage of crushing, depending on the opening of oxidized copper minerals minus 1-4 mm

After the first crushing stage by screening, the finished fraction of the second crushing stage of fineness minus 50-75 mm is separated, which is sent immediately to the third crushing stage. After the second crushing stage by screening, the finished fraction of the third crushing stage of fineness minus 10-20 mm is separated, which is sent immediately to the fourth crushing stage.

After the third crushing stage by screening, the final finished crushing fraction of fineness minus 1-4 mm is released, which is sent immediately to the warehouse or hopper of the final crushing product, which is leached.

As a result, part of the ore is not crushed in separate stages of crushing, but immediately passes through the stage to a lower stage.

The first three stages of dry crushing are performed with the repeated return of large fractions to crushing to prevent the passage of large fractions to smaller crushing and the operation of crushers in the established mode - a certain slot width.

Oxidized and mixed copper ores have a number of favorable conditions for the leaching of ore components, such as mineral composition, increased duty cycle (porosity) of copper and iron minerals, good solubility of oxidized copper and iron minerals in weak acids, which affects the crushing method and final fineness crushing for effective leaching.

Leaching of ore minerals of various oxidized phases of copper is characterized primarily by the fraction of discovered ore minerals and the conductivity of the solution into the ore particles, determined by the mineral composition and porosity of ore minerals and aggregates.

The bulk of ore minerals in oxidized and mixed copper ores is present in intergrowths. Primary and secondary sulfides of copper and magnetite are everywhere found in intergrowths with minerals of the oxidation zone - malachite, brocanthite, and iron hydroxides. In connection with the developed oxidation processes, the surface of ore minerals is covered with iron hydroxides, malachite, and other secondary minerals.

A characteristic feature of oxidized copper ores is an increased degree of duty cycle (porosity) of intergrowths of ore minerals. For example, in the copper ore of the Udokan deposit, the average duty cycle of the splices of oxidized copper minerals is 7%, copper sulfides have a duty cycle of 8% on average, magnetite and iron hydroxides have a higher duty cycle of 14 to 16%.

Ore size minus 1.0-4.0 with a degree of disclosure of the surface of ore minerals in crushed ore about 50%, with minerals covering them mostly with secondary copper sulfides or oxidized copper and iron minerals and to a lesser extent with rock-forming minerals, duty cycle 5 -7% is sufficient for the penetration of an acid solution to leach oxidized copper minerals. The minerality of ore minerals is their physical characteristic.

The disclosure of copper minerals during crushing is determined by microscopic examination of fractions of crushed material.

Large, medium and small crushing can be carried out in crushers of various designs, providing dry crushing - jaw, cone and centrifugal-impact, etc. Finishing ore (fine crushing) to a particle size of minus 1-4 mm can provide cone-inertial crushers (for example, KID ) or centrifugal shock (for example, DC), which have the required slot width.

The use of the centrifugal-impact crushing method at the last stage of ore preparation is determined primarily by the increase in the disclosure of minerals in the crushing product and the advantages in specific capital and operational characteristics compared to cone-inertial crushing, including:

- increased selectivity of the disclosure of minerals due to the destruction of part of the raw material along the weakened bonds - along the boundaries of the fusion of minerals, cracks, dislocations;

- intensive crushing method - a short residence time of the source material in the crushing chamber;

- the output of fractions of the required size is smoothly controlled by changing the peripheral speed of the rotor accelerator;

- high maintainability and ease of maintenance: the replacement time of wearing parts is less than 1 hour; operating costs for quickly wearing parts are low and do not exceed 0.8-1.0 rubles per ton of finished products (cone-inertia crushers have a very low degree of maintainability);

- the specific installation power of the drive is 1-1.5 kW / h per tonne of capacity (according to KID from 2.8 to 4.2 kW / h);

- lack of an oil station in the design of the crusher (KID and Vachtas are equipped with an oil station with a volume of 1.8 tons and a resource of 600 hours);

- wide possibilities for the source ore used, ore is crushed with a moisture content of up to 8-15% (for KID - no more than 2%) and without limitation on the clay content in it (for KID - no more than 2%).

Studies have shown that after crushing mixed and oxidized copper ore by centrifugal impact method, sulfuric acid leaching proceeds more intensively, with greater copper recovery, than after crushing in a jaw crusher under otherwise identical conditions.

Examples of the method.

Example 1

Ore preparation of a sample of oxidized copper ore from the Udokan deposit (72% copper in oxidized minerals) for subsequent sulfuric acid leaching.

An analysis of the textural and structural properties and composition of the ore determined the high conductivity of the solutions in the samples: rock fracture, vein mineralization, the development of oxidized forms of copper along cracks, increased duty cycle of iron hydroxides, the presence of hydromica layers, which are water channels. The size of the opening of more than 53% of the surface of copper minerals, taking into account the average duty cycle of oxidized copper minerals of 7%, and iron minerals of 14% is minus 4.0 + 0 mm.

Ore preparation included sequential stepwise reduction of ore size in the first three stages using a jaw crusher and in the 4th stage using a centrifugal impact crusher. Crushing was carried out in 4 stages: to fineness minus 350 mm, to fineness minus 75 mm, to fineness minus 20 mm, to fineness minus 4 mm, screening after the first stage of crushing with screening of fraction of fineness minus 75 mm and the direction of this fraction to the third stage of crushing screening after the second stage of crushing with a sieving fraction of coarseness minus 20 mm and directing this fraction to the fourth stage of crushing, screening after the third stage of crushing with a sieving fraction of coarseness minus 4 mm and directing this fraction to a finely divided ore bin for I subsequent leaching.

Copper extraction during leaching of ore crushed according to this scheme with a particle size of minus 4 mm sulfuric acid at a concentration of 20 g / dm ³ per 1 hour is 10.2% higher than according to the scheme with crushing at the last stage in a jaw crusher.

Example 2

Ore preparation of a mixed copper ore sample from the Udokan deposit (45.2% copper in oxidized minerals) for subsequent sulfuric acid leaching.

Mineralogical analysis showed that the size of the disclosure of more than 50% of the surface of copper minerals is minus 1.0 mm.

Ore preparation included sequential stepwise reduction of ore size in the first three stages using a jaw crusher and in the 4th stage using a centrifugal impact crusher. Crushing was carried out in 4 stages: to fineness minus 300 mm, to fineness minus 50 mm, to fineness minus 10 mm, to fineness minus 1 mm, screening after the first crushing stage with screening of fineness fraction minus 50 mm and the direction of this fraction to the third crushing stage screening after the second stage of crushing with a screening fraction of coarseness minus 10 mm and directing this fraction to the fourth stage of crushing, screening after the third stage of crushing with a screening of coarse fraction minus 1 mm and directing this fraction to a fine ore bin for I subsequent leaching.

Copper extraction during leaching of ore crushed according to this scheme with a particle size of minus 1 mm sulfuric acid at a concentration of 24 g / dm ³ per 1 hour is 5.2% higher than according to the scheme with crushing at the last stage in a jaw crusher.

Claims (2)

1. The method of ore preparation of oxidized and mixed copper ores for leaching, which consists in sequentially reducing the fineness by crushing the ore by dry method in 4 stages: to fineness minus 300-350 mm, to fineness minus 50-75 mm, to fineness minus 10-20 mm and up to size, providing the disclosure of the surface of oxidized copper minerals of at least 50%, screening after each of the first three stages of crushing with screening and sending fractions of the finished size of the subsequent stage to the corresponding stage of crushing or the final product of crushing with os By the implementation of the final stage of crushing by centrifugal-shock method. 2. The method according to claim 1, which consists in the fact that the size of the fractions, sufficient to open the surface of oxidized copper minerals for leaching, is 1-4 mm