RU2169202C1 - Method of continuous processing of copper concentrate into blister copper - Google Patents

Abstract

FIELD: metallurgy, particularly, methods of processing of copper sulfide concentrates, including nickel-containing ones into blister copper. SUBSTANCE: method includes charging of mixture into vessel, blowing of melt with oxygen-containing gas to form oxidized and metal phases; maintenance of required ratio of height of layers of oxidized and metal phases, and tapping of heat products. In this case, concentrate is melted with ratio of concentrate charging and supply of oxygen-containing gas within 0.3-1.3 of theoretically needed for oxidation of all sulfur and impurities (iron, nickel, etc) to oxides. Height of oxideslag layer is maintained within 0.3-0.8 of total height of melt bath by varying ratio of concentrated charging to supply of oxygen-containing gas. EFFECT: reduced energy and material inputs and decreased losses of nonferrous metals and effluents of sulfur to atmosphere. 3 cl, 1 tbl, 8 ex

Description

 The invention relates to the field of metallurgy, in particular to a method for processing copper sulfide (including nickel-containing) concentrates into blister copper.

 A known method of processing Nickel-containing copper concentrates on blister copper. In the known method (US patent N 3819362), the concentrate is melted in a separate unit on matte, and then it is blown in a horizontal batch converter on blister copper and dry converter slag.

 The disadvantages of this method include: low extraction of copper in blister copper and sulfur in gases rich in sulfur dioxide; high costs of processing copper-rich "dry" nickel slags; the impossibility of organizing a continuous melting process.

 A known method for the continuous melting of sulfide materials in a liquid bath (a. With. The USSR N 510842). According to this method, sulphide materials are melted in a slag bath to produce slag and matte at a height of their layers, respectively, of 0.6 - 0.7 and 0.3 - 0.4 of the total melt height. During the smelting process, the oxygen consumption necessary to oxidize only part of the iron and nickel sulfides is maintained. The main disadvantages of the method are the low extraction of sulfur into rich gases, the high cost of processing matte in horizontal converters.

 The closest technical solution is a method for continuous melting of sulfide copper-containing concentrates (RF patent N 1734389), which consists in continuous melting of sulfide copper-containing concentrates in a melt bath consisting of layers of slag, matte and crude copper (containing 1.0 - 2.5% sulfur and 4 - 6% nickel). According to the known method, the height of the matte layer (0.05 - 0.1 of the total height of the bath) is maintained by changing the ratio of the oxygen consumption and the loaded concentrate based on the oxidation of up to 95% sulfur and part of the nickel contained in the concentrate, and the height of the slag and crude copper layers (0 , 1 - 0.4 and 0.5 - 0.85 of the total height of the bath) are supported by the release of these products.

 The main disadvantages of this method are: the presence of a matte layer in the aggregate, which even with a slight slag peroxidation leads to foaming of the melt, which can lead to its ejection from the aggregate; the production of copper sulphide requires its processing in converters, which is associated with significant energy and material costs for the conversion and processing of dry nickel converter slag; insufficiently complete extraction of sulfur into gases rich in sulfur dioxide.

 The present invention is directed to reducing energy and material costs, reducing losses of non-ferrous metals and reducing sulfur emissions into the atmosphere.

 In our proposed method, the smelting of the concentrate is carried out at a ratio of the loading of the concentrate and the supply of oxygen-containing gas in the range of 0.3-1.3 from theoretically necessary for the oxidation of all sulfur and impurities (iron, nickel, etc.) to oxides, the height of the oxide-slag layer is maintained within 0.3 - 0.8 of the total height of the melt pool by changing the ratio of the concentrate loading and oxygen-containing gas supply.

 A decrease in the ratio of concentrate loading and supply of oxygen-containing gas below 0.3 leads to a strong increase in the overall bath level due to a sharp increase in the gas saturation of the oxide-slag layer as a result of the interaction of sulfides of the loaded concentrate with copper oxide contained in the oxide-slag melt, and, as a result , to foaming the bath, reducing the height of the oxide-slag layer below 0.3 of the total level of the bath, to increased wear of the lance and the high probability of burnout.

 An increase in the ratio of concentrate loading and supply of oxygen-containing gas above 1.3 leads to the accumulation of a significant amount of copper oxide in the oxide-slag melt and, as a result, to an increase in the level of the oxide-slag layer over 0.8 of the total bath height and to a decrease in the yield of blister copper. In addition, an increase in the height of the oxide-slag layer of more than 0.8 of the total height of the molten bath leads to difficulties in the production of blister copper.

 During the smelting of the concentrate, the ratio of the loading of the concentrate and the supply of oxygen-containing gas is maintained within 1.0-1.3 from theoretically necessary for the oxidation of all sulfur and impurities (iron, nickel, etc.) to oxides. An increase in the ratio of concentrate loading and oxygen-containing gas supply above 1.3 from theoretically necessary for the oxidation of all sulfur and impurities (iron, nickel, etc.) to oxides leads to the conversion of part of the concentrate copper to copper oxide and, as a result, to the growth of oxide-slag a layer above 0.8 of the total bath level, reducing the yield of finished blister copper, greatly increasing the duration of the preparation of slag for release. A decrease in the ratio of concentrate loading and supply of oxygen-containing gas to less than 1.0 from the theoretically necessary for the oxidation of all sulfur and impurities (iron, nickel, etc.) to oxides leads to a decrease in the height of the oxide-slag layer to less than 0.2, its thickening and foaming for reducing the content of copper oxide in it.

 Prior to slag production, the ratio of concentrate loading and oxygen-containing gas supply is maintained within the range of 0.3-1.0 from theoretically necessary for the oxidation of all sulfur and impurities (iron, nickel, etc.) to oxides. A decrease in the ratio below 0.3 leads to a strong increase in the overall level of the bath due to a sharp increase in the gas saturation of the oxide-slag layer as a result of the interaction of sulfides of the loaded concentrate with the nitrous oxide contained in the oxide-slag melt. When the ratio increases above 1.0, copper oxide contained in the oxide-slag melt does not recover with concentrate sulfides, and, as a result, the slag does not deplete in copper, and therefore, copper recovery into finished products decreases sharply.

Example. Melting of copper concentrate from the separation of copper-nickel matte was carried out in an industrial stationary unit with top blast. A concentrate containing 68.5 - 69% copper, 4.2 - 4.5% nickel, 4.0 - 4.5% iron, 0.2 - 0.25% cobalt and 20.5 - 21% was supplied to the smelting. sulfur. Humidity of the concentrate is 8%. Quartzite with a silica content of 69 - 72% was used as a flux. A mixture of 96% concentrate and 4% quartz flux in an amount of 23 t / h was continuously charged into the unit. Oxygen with a flow rate of 4400 nm ³ / h and liquid fuel (fuel oil) 250 kg / h were supplied to the melt through an oxygen-fuel lance. During the smelting period, the ratio of concentrate loading and oxygen-containing gas supply to the oxidation of the charge components (sulfur, nickel, cobalt and iron and an insignificant part of copper) was 1.1, i.e. 170 nm ³ oxygen was supplied per 1 ton of concentrate loaded into the aggregate. The mixture was melted at a melt temperature of 1300 - 1350 ^o C. The total height of the melt bath was 2000 mm, while the height of the oxide-slag layer was 1200 mm, i.e., 0.6 the total height of the melt bath. 30 minutes before slag discharge, the charge load was increased to 26 t / h and the oxygen consumption for oxidation of the charge components was reduced to 2500 nm ³ / h, i.e. the ratio of the loading of the concentrate and the supply of oxygen-containing gas to the oxidation of the charge components (sulfur, nickel, cobalt and iron) was 0.5. As a result of smelting, blister copper was obtained containing 98.5% copper, 0.43% nickel, 0.001% cobalt, 0.038% iron and 0.033% sulfur. The resulting slag contained 11.5% nickel, 1.5% cobalt, 22.2% copper, 34% iron and 21.5% silicon oxide. The waste gas contained 20 - 25% sulfur dioxide and was sent to the sulfuric acid production.

 Other examples of the proposed method are shown in the table.

Claims (3)

 1. A method for the continuous processing of copper concentrate into blister copper, including loading the charge, smelting, blowing the melt with an oxygen-containing gas to form oxidized and metallic phases, maintaining the ratio of the height of the layers of the oxidized and metal phases and the release of melting products, characterized in that the concentrate is melted at a ratio loading the concentrate and supplying oxygen-containing gas in the range of 0.3-1.3 from theoretically necessary for the oxidation of all sulfur and impurities to oxides, and the height of the oxide-slag layer is 0.3-0.8 alive within the overall height of the molten bath by changing the load ratio of the concentrate and the oxygen containing gas.  2. The method according to claim 1, characterized in that during the smelting process, the ratio of the concentrate loading to the oxygen-containing gas supply is maintained within 1.0-1.3 from the theoretically necessary for the oxidation of all sulfur and impurities to oxides.  3. The method according to claim 1, characterized in that before the release of slag, the ratio of the load of the concentrate and the supply of oxygen-containing gas is maintained in the range of 0.3-1.0 from theoretically necessary for the oxidation of all sulfur and impurities to oxides.

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