Process and mechanism of Zn and Co leaching from cobalt xanthate slag enhanced by oxidative roasting

IF 6.9 2区环境科学与生态学 Q1 ENGINEERING, CHEMICAL

Process Safety and Environmental Protection Pub Date : 2024-11-02 DOI:10.1016/j.psep.2024.10.117

Zhanhe Zhang , Yanjuan Zhang , Yadong Ning , Guangye Wei , Jingkui Qu , Zhihui Yu , Xiudong Liu

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引用次数: 0

Abstract

Cobalt xanthate slag is the waste slag produced by the use of xanthate cementation and decontamination before the wet refining and electrowinning of Zn, in which Zn, Co, Cd, etc., and butyl xanthate exist in the form of hydrophobic complexes, which are poorly soluble with water. In addition, most of the cobalt xanthate in the slag exists in the form of high-valent Co, which lowers the extraction rate when directly leaching the metal elements. In this study, the atmosphere of the roasting process is regulated to destroy the hydrophobic complexes and change the mineral phase structure of the cobalt xanthate slag. In the cobalt xanthate slag, the Co and Fe valence states change during the roasting and leaching steps; specifically, during the roasting process, the complexes first decompose into CS₂, reducing part of the Co³⁺. Following the disappearance of this sulfur-rich environment, the oxygen in the flowing air oxidises Fe²⁺ to Fe³⁺, but the valence state of Co remains unchanged. During the subsequent leaching process, Co³⁺ and Fe²⁺ further react to realise the benign transformation of Co³⁺ to Co²⁺ and Fe²⁺ to Fe³⁺ without an added redox agent. The rapid redox reaction between Co³⁺ and Fe²⁺ controls Co₃O₄ dissolution; thus, the reaction rate is controlled by the slower process of internal diffusion. Under the optimal roasting conditions, the Co³⁺ content in cobalt xanthate slag decreases to 21.10 % and that of Fe²⁺ to 48.78 %. Consequently, the optimum Zn and Co leaching rates reach 99.92 % and 99.57 %, respectively, and only 0.86 % of Fe in the final leaching solution exists in the form of Fe²⁺.

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氧化焙烧强化黄原酸钴渣中锌和钴的浸出过程和机制

黄原酸钴渣是在锌的湿法精炼和电积之前，利用黄原酸钴固结和去污而产生的废渣，其中的锌、钴、镉等元素与黄原酸丁酯以疏水络合物的形式存在，与水的溶解性很差。此外，矿渣中的黄原酸钴大部分以高价钴的形式存在，直接浸出金属元素时会降低萃取率。本研究通过调节焙烧过程的气氛来破坏疏水络合物，改变黄原酸钴渣的矿相结构。在黄原酸钴渣中，钴和铁的价态在焙烧和浸出过程中发生了变化；具体而言，在焙烧过程中，络合物首先分解成CS2，还原了部分Co3+。这种富硫环境消失后，流动空气中的氧气将 Fe2+ 氧化成 Fe3+，但 Co 的价态保持不变。在随后的浸出过程中，Co3+ 和 Fe2+ 进一步发生反应，在不添加氧化还原剂的情况下实现 Co3+ 向 Co2+ 和 Fe2+ 向 Fe3+ 的良性转化。Co3+ 和 Fe2+ 之间的快速氧化还原反应控制着 Co3O4 的溶解；因此，反应速度由较慢的内部扩散过程控制。在最佳焙烧条件下，黄原酸钴渣中的 Co3+ 含量降至 21.10%，Fe2+ 含量降至 48.78%。因此，锌和钴的最佳浸出率分别达到 99.92 % 和 99.57 %，最终浸出液中只有 0.86 % 的铁以 Fe2+ 的形式存在。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Process Safety and Environmental Protection 环境科学-工程：化工

CiteScore

11.40

自引率

15.40%

发文量

929

审稿时长

8.0 months

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