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关于使用L-抗坏血酸将直接炼泡铜闪速熔炼炉渣中的铅、铜和铁湿法冶金转移至溶液的研究。

Studies on the Hydrometallurgical Transfer of Lead, Copper, and Iron from Direct-to-Blister Copper Flash Smelting Slag to Solution Using L-Ascorbic Acid.

作者信息

Gargul Krzysztof, Pawlik Arkadiusz, Stępień Michał

机构信息

Faculty of Non-Ferrous Metals, AGH University of Krakow, Al. Mickiewicza 30, 30-059 Krakow, Poland.

Philip Morris Polska, 31-982 Krakow, Poland.

出版信息

Molecules. 2025 Mar 18;30(6):1365. doi: 10.3390/molecules30061365.

DOI:10.3390/molecules30061365
PMID:40142138
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11945397/
Abstract

This study explored the behavior of lead, copper, and iron during the leaching process of flash smelting slag from direct-to-blister copper flash smelting using l-ascorbic acid solutions. Flash smelting slag is generated in considerable quantities by various copper smelters worldwide. One drawback of the single-stage flash smelting technology for copper concentrates is the production of large quantities of metal-rich by-products. However, through appropriate management of postprocess waste, valuable components such as copper or lead can be recovered. In practice, the slag is typically subjected to decoppering processes involving electric and converter furnaces. The hydrometallurgical process proposed in this study is aimed at replacing high-temperature recovery methods. The primary objective of the experiments was to investigate the effects of variations in specific leaching parameters and the addition of auxiliary substances on the leaching efficiency of lead, copper, and iron. Four parameters were adjusted during the tests: concentration of l-ascorbic acid, liquid-to-solid phase ratio, temperature, and time. An oxidizing agent in the form of perhydrol and citric acid with an oxidant were used as additives. Optimal process conditions were determined to achieve maximum lead leaching efficiency while maintaining relatively low leaching of copper and iron. The experiments indicated that leaching in ascorbic acid solutions resulted in lead extraction efficiencies ranging from approximately 68% to more than 88%, depending on the conditions. Conversely, relatively low leaching efficiencies of iron (4-12%) and copper (0-29%) were observed.

摘要

本研究探讨了在使用L-抗坏血酸溶液对直接炼泡铜闪速熔炼产生的闪速熔炼炉渣进行浸出过程中铅、铜和铁的行为。全球各种铜冶炼厂都会产生大量的闪速熔炼炉渣。铜精矿单段闪速熔炼技术的一个缺点是会产生大量富含金属的副产品。然而,通过对后处理废物进行适当管理,可以回收铜或铅等有价值的成分。在实际操作中,炉渣通常要经过涉及电炉和转炉的脱铜过程。本研究提出的湿法冶金工艺旨在取代高温回收方法。实验的主要目的是研究特定浸出参数的变化以及添加辅助物质对铅、铜和铁浸出效率的影响。试验过程中调整了四个参数:L-抗坏血酸浓度、液固比、温度和时间。使用过氧化氢形式的氧化剂和含氧化剂的柠檬酸作为添加剂。确定了最佳工艺条件,以在保持铜和铁相对较低浸出率的同时实现最大的铅浸出效率。实验表明,在抗坏血酸溶液中浸出时,根据条件不同,铅的提取效率在约68%至超过88%之间。相反,观察到铁(4 - 12%)和铜(0 - 29%)的浸出效率相对较低。

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