Depletion of converter slags to waste in the Vanyukov furnace during pyrometallurgical copper production at JSC Almalyk MMC
DOI:
https://doi.org/10.31643/2024/6445.39Keywords:
copper, slag, converter slag, depletion, magnetite, extraction, clinker, concentrate.Abstract
The article shows the possibility of involving man-made formations in the pyrometallurgical production of copper in the form of slag and clinker-zinc production for the purpose of comprehensive extraction of non-ferrous and precious metals from them at Almalyk MMC JSC. Clinker, a technogenic waste from zinc production, contains a significant amount of reducing elements in the form of metallic iron and carbon, as well as gold in the amount of 2.3 g/t and silver 250 g/t. In research, clinker works as a reducer of magnetite contained in the converter slag during its depletion and in the process of depletion (reduction) of the converter slag, noble metals are extracted into matte, and then into blister copper up to 95-98%. Converter slags from copper production of Almalyk MMC JSC contain 2.0-3.5% copper, and they, as a circulating product, are depleted in a reverberatory furnace with copper extraction of 75%. To increase the yield of copper from converter slag in Vanyukov furnaces, it is necessary to first deplete the converter slag in reduction processes and then transfer it for processing. It was found that using clinker, a technogenic waste from zinc production with a particle size of +5 - -10 mm, the recovery of converter slag in a converter from magnetite to wustite using the developed technology in 10-15 minutes exceeded more than 50.0% (the amount of magnetite decreased from 21.9 % to 9.8%). As a result of processing recovered converter slags in the Vanyukov furnace, it was possible to reduce the copper content in converter slags of copper production from 2.2-3.5% to 0.58-0.72% in waste slag. To increase the yield of copper from converter slag in the reverberatory and Vanyukov furnaces, it is necessary to first deplete the converter slag in reduction processes and then transfer it for processing.
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References
Tsemekhman LSh, Paretsky V. M. Modern methods of processing sulfide copper-nickel concentrates. Non-ferrous metals. 2020; 1:24-31.
Marchuk RA, KrupnovLV, Morgoslep VI, Rumyantsev DV. Practice of operation of flash smelting furnaces in the Norilsk Nickel company in the conditions of processing finely dispersed raw materials with reduced energy potential. Non-ferrous metals. 2020; 6:47-54.
Bellemans I,De Wilde E,Moelans N,Verbeken K. Metal losses in pyrometallurgical operations. A review. Adv. Colloid Interface Sci. 2018; 255:47-63.
Tlotlo Solomon Gabasiane, Gwiranai Danha, Tirivaviri A Mamvura, Tebogo Mashifana,and Godfrey Dzinomwa. Environmental andSocioeconomic Impact of Copper Slag. A Review. Crystals. 2021; 11:1504. https://doi.org/10.3390/cryst11121504
Busolic D, Parada F, Parra R, Sanchez M, Palacios J, and Hino M. Recovery of Iron from Copper Flash Smelting Slags. Mineral Processing and Extractive Metallurgy. 2011; 120(1):32-6. https://doi.org/10.1179/037195510X12772935654945
SanakulovKS, Kadyrov AA. Strategy for long-term innovative development of the Kyzylkum region. ISBN 978-3-943974-15-7.Publishing house Artem Cologne, Germany. 2021, 408.
GabasianeaTS, DanhaaG, MamvuraaTA, MashifanabT, DzinomwacG.Characterization of copper slag for beneficiation of iron and copper. Heliyon. 2021; 7(4). https://doi.org/10.1016/j.heliyon.2021.e06757
Khursanov AKh. History and development prospects, problems of processing technogenicdeposits of the Almalyk MMC. Materials of the international research and development conference. Almalyk.2019, 3-15
Sanakulov KS. Scientific and technical principles of processing waste from miningand metallurgical production. Tashkent: Fan. 2009, 404.
Mirzanova ZA, Khasanov AU, Isroilov AT, Tashaliev FU, Rakhimjonov ZhB. Technology for processing technogenic waste containing non-ferrous metals. Journal Coposition Materials. 2021; 2:176-180.
Vanyukov AV. Melting in a liquid bath. Moscow. Ed. Metallry. 1988, 208.
Kupryakov YuP. Copper smelting slags and their processing. M.: Metallurgy. 1987, 201.
Dosmukhamedov NK, Fedorov AN. Distribution of Cu, Pb, Zn and As between the products of two-stage reductive depletion of high-copper slags. Non-ferrous metals. 2019; 7:30-35.
Vanyukov AV, Zaitsev VYa. Theory of pyrometallurgical processes. M.: Metallurgy.1993, 384.
YakubovMM, Abdukadyrov AA,Mukhametdzhanova ShA,Yokubov OM. Involvement in the production of man-made formations at the enterprise JSC Almalyk MMC.Magazine Non-ferrous metals. 2022; 5:36-41.
Yokubov OM, Khasanov AS, Yakubov MM, Mukhametdzhanova ShA. Improving the depletion of converter slags from copper production. Uzbek Chemical Journal. 2022; 1:30-34.
Kupryakov YuP. Reflective smelting of copper concentrates. M.: Metallurgy. 1976, 350.
KenzhaliyevB, KvyatkovskiyS, Dyussebekova М, SemenovaA, NurhadiyantoD. Analysis of Existing Technologies for Depletion of Dump Slags of Autogenous Melting.Kompleksnoe Ispolzovanie Mineralnogo Syra = Complex Use of Mineral Resources. 2022; 323(4):23-29. https://doi.org/10.31643/2022/6445.36
KezhouSong&AriJokilaakso.Transport Phenomena in Copper Bath Smelting and Converting Processes –A Review of Experimental and Modeling Studies,Mineral Processing and Extractive Metallurgy Review. 2022; 43(1):107-121. https://doi.org/10.1080/08827508.2020.1806835
MoskalykRR,AlfantaziAM.Nickel sulphide smelting and electrorefining practice: A review.Mineral Processing and Extractive MetallurgyReview. 2002; 23(3-4):141-180. https://doi.org/10.1080/08827500306893
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