Treatment of copper-containing leaching residue by sulfation roasting followed by acid/water leaching

Q4 Chemistry

Mongolian Journal of Chemistry Pub Date : 2023-06-19 DOI:10.5564/mjc.v24i50.1310

Nyamdelger Shirchinnamjil, Narangarav Tumen-Ulzii, Nemekhbayar Davaadorj, Khulan Byambasuren, Sarantsetseg Purevsuren, Ulziibadrakh Erdenebat, Enkhtuul Surenjav

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Abstract

This research investigates the extraction of copper from copper-containing leaching residue, which includes 33.45% of copper, 14.14% of iron, 23.87% of sulfur and trace amounts of silver and other elements. Roasting the copper-containing residue under air and oxygen flow convert sulfides into sulfate, followed by water and acid leaching to extract copper. The process parameters, including leaching temperature, sulfuric acid concentration, leaching time, solid-to liquid ratio, and agitation speed, were optimized for both water and acid leaching methods. Results showed that the maximum copper dissolution efficiency was 93.12% with water leaching, and 97.16% with acid leaching. Chemical analysis revealed that the water and acid leaching residue contained 48.13% and 31.64% of iron, respectively. This study provides valuable insights into the process optimization for copper extraction from copper-containing leaching residue, which can inform the development of more efficient and sustainable methods for metal recovery.

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硫酸焙烧-酸/水浸出处理含铜浸出渣

研究了从含铜浸出渣中提取铜的方法，该浸出渣中铜含量为33.45%，铁含量为14.14%，硫含量为23.87%，银含量为微量。在空气和氧气流下焙烧含铜残留物，将硫化物转化为硫酸盐，然后用水和酸浸提取铜。对水浸法和酸浸法的工艺参数，包括浸出温度、硫酸浓度、浸出时间、固液比和搅拌速度进行了优化。结果表明，水浸和酸浸对铜的最大溶出率分别为93.12%和97.16%。化学分析表明，水浸渣和酸浸渣中铁含量分别为48.13%和31.64%。这项研究为从含铜浸出渣中提取铜的工艺优化提供了有价值的见解，可以为开发更有效和可持续的金属回收方法提供信息。

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来源期刊

Mongolian Journal of Chemistry Materials Science-Materials Chemistry

CiteScore

1.10

自引率

0.00%

发文量

审稿时长

20 weeks