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Metallurgist

Erschienen in:

12.05.2021

Study of the Influence of the Granulation Modes of Cu₂S Melt on the Granulometric and Structural Characteristics of Particles

verfasst von: O. V. Nechvoglod, S. V. Sergeeva, S. N. Agafonov

Erschienen in: Metallurgist | Ausgabe 1-2/2021

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Abstract

This study presents the results of experiments conducted on the granulation of copper sulfide (Cu₂S) melt. The granulometric characteristics of the samples are calculated as a function of the melt temperature. An increase in the melt temperature to 1,350°C promotes the formation of particles with a particle size of –10.0 +5.0 mm, and a decrease in the melt temperature to 1,250°C promotes the formation of particles with smaller size grades (i.e., –1.6 +1.0, –1.0 +0.63, and –0.63 +0.063 mm). With an increase in temperature, the mean squared deviation of particle size from the average value and the degree of polydispersity decreases to some extent. This study also estimates the influence of the melt temperature on the shape of the granules. The cooling and spheroidization times of particles during granulation at the melt temperatures of 1,250°C, 1,300°C, and 1,350°C were calculated. In the temperature range under consideration for all of the investigated size grades of particles, the cooling time exceeded the spheroidization time, which contributed to the formation of spherical particles. The melt temperature did not significantly affect the chemical composition of Cu₂S granules. The main phase component of the granules was chalcosine (Cu₂S) with a monoclinic lattice of more than 80%. Chalcosine (Cu₂S) with a hexagonal lattice of 8% to 9% and digenite (Cu_1.78S) with 4% to 12% were also identified. Dispersed inclusions of metallic copper were also detected.

Vorheriger Artikel Development and Application Prospects of Aluminum–Lithium Alloys in Aircraft and Space Technology

Nächster Artikel Dependence of the Grain Size in the Microstructure of Copper on the Rate of Deformation by “Helical Rolling–Pressing”

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R. B. Gordon, “Production residues in copper technological cycles,” Resources, Conservation and Recycling, 36, 2, 87–106 (2002).CrossRef

S. S. Naboychenko, N. G. Ageev, A. P. Doroshkevich, et al., Processes and Devices of Non-Ferrous Metallurgy: Textbook for Universities [in Russian], GOU VPO UGTU–UPI, Yekaterinburg (2005).

M. Wang and W. Li X. Chen, “Substance flow analysis of copper in production stage in the U.S. from 1974 to 2012,” Resources, Conservation and Recycling, 105, 36–48 (2015).CrossRef

R. Moskalyk and A. Alfantazi, “Review of copper pyrometallurgical practice: today and tomorrow,” Minerals Engineering, 16(10), 893–919 (2003).CrossRef

D. Dreisinger, “Copper leaching from primary sulfides: Options for biological and chemical extraction of copper,” Hydrometallurgy, 83, 10–20 (2006).CrossRef

F. Letowski, B. Kolodziej, M. Czernecki, et al., “A new hydrometallurgical method for the processing of copper concentrates using ferric sulphate,” Hydrometallurgy, 4(2), 169–184 (1979).CrossRef

B. Xu, H. Zhong, and T. Jiang, “Recovery of valuable metals from Gacun complex copper concentrate by two-stage countercurrent oxygen pressure acid leaching process,” Miner. Eng., 24(10), 1082–1083 (2011).CrossRef

D. M. Chizhikov, L. V. Pliginskaya, Z. F. Gulyanitskaya, et al., Patent USSR No. 280858, Electrochemical Method for Processing Copper-Nickel Matte, submitted 05/08/1968, published 09/03/1970, Bul. No. 28.

D. M. Chizhikov, Z. F. Gulyanitskaya, N. A. Gurovich, and I. N. Kitler, Hydrometallurgy of Sulfide Alloys and Mattes [in Russian], Izdatelstvo AN SSSR, Moscow (1962).

10.

V. V. Mikhailov, V. P. Schastlivy, and G. R. Pevzner, “Aspects of the use of electrolysis of nickel sulfide anodes at foreign plants,” Bul. CIIN. Tsvetn. Metallurg., No. 20, p. 33 (1971).

11.

E. N. Selivanov, O. V. Nechvoglod, L. Yu. Udoeva, et al., Patent RF No. 2434065, Method of Processing Sulfide Copper-Nickel Alloys, submitted 08/18/2010; published. 11/20/2011, Bul. No. 32.

12.

R. Maharjan and S. H. Jeong, “High shear seeded granulation: Its preparation mechanism, formulation, process, evaluation, and mathematical simulation,” Powder Technol., 366, 667–688 (2020).CrossRef

13.

S. S. Naboichenko, Non-Ferrous Metal Powders [in Russian], Metallurgiya, Moscow (1997).

14.

E. N. Selivanov, O. V. Nechvoglod, and V. G. Lobanov, “The effect of the nickel sulphide alloys structure on their electrochemical oxidation parameters,” IFAC Proceedings Volumes, 46(16), 259–262 (2013).CrossRef

15.

L. Yu. Udoeva, E. N. Selivanov, S. E. Klein, and N. I. Selmenskikh, “Granulation of copper-nickel matte: dispersion, microstructure, and reactivity,” Tsvetn. Metall., No. 12, 20–35 (2013).

16.

S. E. Vaysburd, Physicochemical Properties and Structural Aspects of Sulfide Melts [in Russian], Metallurgiya, Moscow (1996).

17.

A. V. Vanyukov and V. Ya. Zaitsev, The Theory of Metallurgical Processes [in Russian], Metallurgiya, Moscow (1993).

Titel: Study of the Influence of the Granulation Modes of Cu2S Melt on the Granulometric and Structural Characteristics of Particles
verfasst von: O. V. Nechvoglod
S. V. Sergeeva
S. N. Agafonov
Publikationsdatum: 12.05.2021
Verlag: Springer US
Erschienen in: Metallurgist / Ausgabe 1-2/2021
Print ISSN: 0026-0894
Elektronische ISSN: 1573-8892
DOI: https://doi.org/10.1007/s11015-021-01135-8

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