Hydrometallurgical treatment of zinc ash from hot-dip galvanizing process

Q2 Materials Science

Minerals & Metallurgical Processing Pub Date : 2018-05-01 DOI:10.19150/MMP.8288

E. Rudnik, G. Włoch, L. Szatan

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引用次数: 6

Abstract

The oxide fraction of industrial zinc ash was characterized in terms of chemical and phase composition, leaching behavior in sulfuric acid solutions, and leaching thermal effect. The waste product contained about 68 percent zinc (Zn), 7 percent chlorine (Cl), 2 percent aluminum (Al) and less than 1 percent other metals, such as iron (Fe), manganese (Mn), calcium (Ca) and silicon (Si). It consisted mainly of zinc oxide contaminated with metallic zinc and zinc hydroxide chloride. The dissolution of metals from the zinc ash was determined for solid-to-liquid ratios ranging from 100 to 500 kg/m3, acid concentrations of 10 and 20 percent, and temperatures of 20 and 40 °C. The best result — 130 g/dm3 Zn(II) at 95 percent zinc recovery — was obtained at a solid-to-liquid ratio of 200 kg/m3, sulfuric acid concentration of 20 percent and initial temperature of 40 °C. The final solutions were contaminated mainly by Mn(II) and Fe(III) ions, but the presence of cadmium (Cd(II)) and lead (Pb(II)) ions enabled electrowinning of zinc of about 99 percent purity at high current efficiency of 85 to 99 percent. Leaching of the material was an exothermic process with reaction heat of about 520 kJ/kg.

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热镀锌锌灰的湿法冶金处理

从化学成分和相组成、在硫酸溶液中的浸出行为以及浸出热效应等方面对工业锌灰的氧化物部分进行了表征。废物含有约68%的锌（Zn）、7%的氯（Cl）、2%的铝（Al）和不到1%的其他金属，如铁（Fe）、锰（Mn）、钙（Ca）和硅（Si）。它主要由被金属锌污染的氧化锌和氯化氢氧化锌组成。在固液比为100至500 kg/m3、酸浓度为10%和20%以及温度为20和40°C的情况下，测定了锌灰中金属的溶解情况。在固液比为200kg/m3、硫酸浓度为20%和初始温度为40°C的条件下，获得了最佳结果——锌回收率为95%时为130g/dm3-Zn（II）。最终溶液主要被Mn（II）和Fe（III）离子污染，但镉（Cd（II））和铅（Pb（II）离子的存在使得能够在85%至99%的高电流效率下电积纯度约99%的锌。材料的浸出是一个放热过程，反应热约为520kJ/kg。

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来源期刊

Minerals & Metallurgical Processing 工程技术-矿业与矿物加工

CiteScore

0.84

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： For over twenty-five years, M&MP has been your source for the newest thinking in the processing of minerals and metals. We cover the latest developments in a wide range of applicable disciplines, from metallurgy to computer science to environmental engineering. Our authors, experts from industry, academia and the government, present state-of-the-art research from around the globe.