Sulfidization-Free Potassium Amyl Xanthate for Tenorite Recovery in Flotation of Copper-Quartz Systems
##plugins.themes.bootstrap3.article.main##
摘要
Copper oxide (Cu(II)O) and quartz are critical minerals in industrial applications, and their efficient separation is essential for optimizing resource recovery and waste management. This study investigates the use of Potassium Amyl Xanthate (PAX) as a collector for tenorite (CuO) flotation without prior sulfidization, a traditional but complex and costly process. Microflotation experiments demonstrated that CuO recovery reached approximately 80% at pH 10 with a PAX dosage of 600 g/ton, while quartz recovery remained negligible under the same conditions. Binary microflotation tests revealed the intricate dynamics between quartz and CuO. At a 25:75 Quartz to CuO ratio, quartz recovery in the concentrate was around 60%, while CuO recovery reached approximately 75%. When the proportion of quartz increased to 33:67, quartz recovery dropped slightly to 55%, while CuO recovery remained high at 80%. Remarkably, at a 5:95 ratio, quartz recovery significantly decreased to 35%, and CuO recovery was maximized at nearly 85%. These results demonstrate the selective effectiveness of PAX for CuO flotation, especially at higher CuO concentrations. Sodium silicate effectively suppressed quartz recovery, reducing it to as low as 20% at lower quartz-to-CuO ratios, particularly at pH 7 with a dosage of 400 g/ton. X-ray diffraction (XRD) analysis confirmed the effectiveness of separation and identified mineral transformations in concentrates and tailings. The results underscore the potential of PAX as an efficient and cost-effective collector for CuO flotation, offering a simplified and robust approach for improving mineral recovery in complex systems.
##plugins.themes.bootstrap3.article.details##
##submission.howToCite##
参考
CEWEP - The Confederation of European Waste-to-Energy Plants 2024. https://www.cewep.eu/bottom-ash-factsheet/.
Holm O, Simon FG. Innovative treatment trains of bottom ash (BA) from municipal solid waste incineration (MSWI) in Germany. Waste Management 2017;59:229–36. https://doi.org/10.1016/J.WASMAN.2016.09.004.
Berkhout SPM, Oudenhoven BPM, Rem PC, Berkhout SPM, Oudenhoven BPM, Rem PC. Optimizing Non-Ferrous Metal Value from MSWI Bottom Ashes. J Environ Prot (Irvine, Calif) 2011;2:564–70. https://doi.org/10.4236/JEP.2011.25065.
Arickx S, Van Gerven T, Boydens E, L’hoëst P, Blanpain B, Vandecasteele C. Speciation of Cu in MSWI bottom ash and its relation to Cu leaching. Applied Geochemistry 2008;23:3642–50. https://doi.org/10.1016/J.APGEOCHEM.2008.09.006.
Keber S, Müller M, Elwert T, Goldmann D. Investigations on Single Minerals and Synthetic Ash Components for the Enrichment of Copper from Waste Incineration Bottom Ashes by Flotation. Minerals 2023, Vol 13, Page 358 2023;13:358. https://doi.org/10.3390/MIN13030358.
Piantone P, Bodénan F, Chatelet-Snidaro L. Mineralogical study of secondary mineral phases from weathered MSWI bottom ash: implications for the modelling and trapping of heavy metals. Applied Geochemistry 2004;19:1891–904. https://doi.org/10.1016/J.APGEOCHEM.2004.05.006.
Rissler J, Klementiev K, Dahl J, Steenari BM, Edo M. Identification and Quantification of Chemical Forms of Cu and Zn in MSWI Ashes Using XANES. Energy and Fuels 2020;34:14505–14. https://doi.org/10.1021/ACS.ENERGYFUELS.0C02226/ASSET/IMAGES/LARGE/EF0C02226_0004.JPEG.
Breitenstein B, Elwert T, Goldmann D, Haas A, Schirmer T, Vogt V. Froth Flotation of Copper and Copper Compounds from Fine Fractions of Waste Incineration Bottom Ashes. Chemie Ingenieur Technik 2017;89:97–107. https://doi.org/10.1002/CITE.201600017.
Ndoro TO, Witika L. A Review of the Flotation of Copper Minerals. Ndoro, International Journal of Sciences: Basis and Applied Research 2017;34:145–65.
Saquet J, Apraxine V, Lakaye J. Kolwezi mining and metallurgical operations of Union MInière du Haut-Katanga. Mining Engineering, 14(12), S 70-74 - Google Search 1962;14:70–4.
Castro S, Soto H, Goldfarb J, Laskowski J. Sulphidizing reactions in the flotation of oxidized copper minerals, II. Role of the adsorption and oxidation of sodium sulphide in the flotation of chrysocolla and malachite. Int J Miner Process 1974;1:151–61. https://doi.org/10.1016/0301-7516(74)90011-8.
Emirhan Kiraz. Recovery of copper from oxide copper ore by flotation and leaching. Graduate school of natural and applied sciences of Middle East technical university, 2014.