RU2023038C1 - Method of conversion of copper-nickel mattes - Google Patents

Abstract

FIELD: non-ferrous metallurgy. SUBSTANCE: method comprises steps of blowing a sulfide melt by oxygen-containing gaseous mixture; charging flux and cold additives; periodically draining the slag with making up of sulfide mass, had been produced, to a converter matte; at a period of making up the sulfide mass to the converter matte introducing a carbon-containing fuel to oxygen-containing blowing with a coefficient of oxygen consumption 6.5-9.0. EFFECT: enhanced quantity of copper-nickel converter mattes. 1 cl, 2 dwg

Description

 The invention relates to ferrous metallurgy and can be used to improve the quality of copper-Nickel matte, the composition of which depends on the performance of subsequent processing of Feinstein to anode nickel and blister copper.

 A known method of converting polymetallic cobalt-containing mattes, in which, in order to increase the extraction of non-ferrous metals in Feinstein, that is, increase their contents in the latter, especially cobalt, the melt is purged to obtain a slag: matte ratio of 0.7-2.0, and then the oxygen-containing blast is fed with carbon-containing fuel at an oxygen flow rate of 0.6-0.7 for 8-15 minutes before the slag is drained.

 There is also a known method for converting copper-nickel mattes, the purpose of which is to increase the output of conditioned matte, i.e. Feinstein, which meets the quality requirements of technological instructions. The quality of the Feinstein is determined by its composition (the ratio of nickel to copper, the content of cobalt, iron and sulfur), on which the technological parameters of the subsequent redistribution of the separation of Feinstein into nickel and copper concentrates and the efficiency of further processing of the latter in the nickel and copper branches of metallurgical production depend.

 The most significant (and difficult to reach) parameters are high sulfur, cobalt and nickel: copper ratios in Feinstein. The higher the values of these parameters, the better is the separation of copper and nickel (with cobalt) during the matte flotation. Reducing Feinstein's iron content to 3% or less at domestic plants is not difficult, however, at the end of the Feinstein sulphide finishing operation, metallization of the latter increases (due to either the high iron content in the sulphide mass before lapping or low iron content due to the release of metallic copper at a certain stage of purging), which drastically worsens the matte flotation performance.

 The sulfur content in Feinstein is determined by the ratio of the rates of development of two opposing processes in the converter bath - oxidizing, occurring in the zone of interaction of air blast with sulfide melt, where sulfur is burned out, and reducing, occurring in the volume of the bath, remote from the tuyeres, as a result of which the metal oxidizes iron without sulfur oxidation. The higher the sulfur content in Feinstein, the less its metallization. When the sulfur content in Feinstein is 22-23%, its metallization reaches 6-8%.

 In these conversion methods, the sulfur content is not high enough and is 23.2%.

 In other methods of converting copper-nickel mattes, the sulfur content in Feinstein is almost the same, but with a low cobalt content of 0.43-0.53% and a low ratio of nickel: copper (β) in the range of 1.07-1.12 or slightly higher (up to 23.8% sulfur and 0.81-0.98% cobalt), but with the same low value β = 1.06-1.12, and where the calculated value of β reaches 1.29 in Feinstein , very low cobalt content of 0.35%.

 In a method for converting copper-nickel mattes to increase the content of cobalt (and sulfur) and reduce metallization in the Feinstein, gypsum that sulfides the non-ferrous metals of Feinstein is specially loaded onto the Feinstein. In this case, the cobalt content rises to 1.22%, but judging by the composition of the initial sulfide mass with a nickel content of 24.6 and copper 38.0%, the value β in Feinstein, i.e. nickel: copper ratio should be less than one.

 Thus, from the consideration of the listed analogues, the difficulty of simultaneous achievement of high sulfur, cobalt and nickel: copper ratios when converting in Feinstein is seen.

 To increase the sulfur content in the method of processing Feinstein into the already obtained Feinstein with a sulfur content of 21.3-22.5%, liquid sulfur is supplied under the melt layer to a depth of 1.0-1.5 m. The liquid matte treated with liquid sulfur contains from 23.3-24.0 to 25.8-28.6% sulfur, with almost no metallic phase.

 The disadvantage of this method is the bulkiness of the scheme, requiring the organization of a special section for the preparation of liquid sulfur at the converter stage and additional equipment for supplying sulfur to the matte after the operation to refine the sulfide mass to matte.

 The closest in technical essence and purpose is a method for converting copper-nickel mattes, in which cold additives are loaded 70-90 minutes before the end of the matte production process in the ratio of 0.3-0.4 tons per 1 ton of melt, then the purging is continued for 40-60 minutes, the slag is drained and the resulting mass is brought up to Feinstein.

 In the examples of the implementation of this method were obtained matteyns of the following composition, wt.%: Sulfur 22.0-22.5; cobalt 0.75-0.78; metal phase 4.5-4.9; the ratio of Nickel: copper in the range of 1.03-1.04.

 The disadvantage of the prototype, despite the simultaneous achievement in it of sulfur, cobalt and β values that exceed those in the individual analogues discussed above, is the fact that the content of the listed components in Feinstein is still significantly inferior to the highest sulfur, cobalt and β values achieved in separate analogues.

 The aim of the invention is to improve the quality of the Feinstein by increasing the content of sulfur and cobalt, as well as the ratio of nickel: copper.

 This goal is achieved by the fact that in the method for converting copper-nickel mattes, which includes blowing a sulfide melt with an oxygen-containing gas mixture, loading fluxes and solid additives, as well as periodically draining the slag with finishing the obtained sulfide mass to a matte, while introducing it into the oxygen-containing blast carbon-containing fuel with an oxygen consumption coefficient of 6.5-9.0.

 The invention consists in the following.

 When the oxidizer consumption coefficient (α) is less than 6.5, an excess amount of carbon-containing fuel appears, which did not have time to react with the slag melt and burns over the bath, which increases the process temperature, because of which nickel and especially cobalt begin to intensively transfer to slag, reducing their content , and therefore sulfur, in sulfide mass, i.e. Feinstein, in this case, the nickel: copper ratio also decreases.

 If α is more than 9.0, the carbon-containing fuel in the slag bath becomes insufficient for the complete recovery of non-ferrous metals and their transition to a sulfide mass, which is why the contents of nickel and especially cobalt, as well as sulfur in Feinstein are reduced.

 And only in the range of values α = 6.5–9.0 is a normal process temperature observed with sufficient reducing ability of the gas mixture, which ensures the minimum transition of non-ferrous metals to lapping slags and thereby contributes to the production of a better matte with a high content of cobalt and sulfur.

 Further processing of such Feinsteins improves technological performance at subsequent stages of Feinstein separation, roasting of nickel concentrate, anode smelting of nickel cinder and nickel electrolysis, as well as at stages of processing copper concentrate CRF and cement copper.

 An example implementation of the method.

 In the second half of 1990, in the smelting shop No. 2 of the Nadezhda Metallurgical Plant, tests were carried out for various modes of adjusting the sulfide mass to Feinstein, the so-called “brewing” of Feinstein when converting copper-nickel mattes using natural gas (carbon-containing fuel) in air blasting.

At the end of ordinary and idle purges, the matte steaming operation was performed using air blasting with natural gas at an oxidizer flow coefficient in the range of 4.5-10.0. In various modes temperature "cooking" matte varied from 1170 to 1230 C and ^the gas flow rate from 400 to 1300 Nm ³ / h.

 Selected test results are given in table. 1. As follows from the data table. 1, the most optimal “brewing” modes of Feinstein are modes 4–6 with values α = 6.5–9.0, in which there is an increased content of cobalt and sulfur in the Feinstein, as well as an increased ratio of nickel: copper.

 In the table. Figure 2 shows the weighted average content of elements in Feinstein for the entire period of testing on air blast with natural gas (month) and on conventional air blast according to traditional technology (for the previous 3 months). From the data table. 2 it follows that the use of natural gas in the blast for cooking Feinstein can significantly improve its quality (sulfur content in Feinstein increased by 1.19% (abs.), Cobalt content - by 0.12% (abs.), And the ratio copper: Nickel has grown from 1.37 to 1.56.

Claims (1)

 METHOD FOR CONVERTING COPPER-NICKEL STEINS, including blowing a sulfide melt with an oxygen-containing gas mixture, loading fluxes and cold additives, periodically draining slag with finishing the resulting sulfide mass to a matte matte, characterized in that, in order to improve the quality of the matte matte sinter matte, carbon-containing fuel is introduced into the oxygen-containing gas mixture at an oxygen flow rate of 6.5 to 9.0.

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