Hydrogen Reduction of Hazardous Bauxite Residue for Green Steel and Sustainable Alumina Production.

IF 2.5 3区材料科学 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY

Journal of Sustainable Metallurgy Pub Date : 2025-01-01 Epub Date: 2025-03-11 DOI:10.1007/s40831-025-01046-x

Manish Kumar Kar, Mengyi Zhu, Jafar Safarian

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Abstract

This study introduces a novel approach in sustainable metallurgy for the efficient utilization and valorization of bauxite residue, aimed at producing sustainable alumina and green steel. The integrated process combines hydrogen reduction, alkaline leaching, and smelting of the leaching residue. Initially, the bauxite residue was pelletized with calcite and quicklime to create self-hardened pellets, leveraging the cementing effect of quicklime with water. These pellets underwent hydrogen reduction, achieving over 95% reduction, resulting in the formation of metallic iron and a leachable calcium aluminate phase for alumina recovery. The reduced pellets were then subjected to alkaline leaching, extracting 62% alumina. Subsequently, smelting at 1550 °C facilitated the near-complete separation of iron and calcium-rich slag. The process was analyzed using various analytical techniques, including X-ray diffraction, electron probe microanalysis, and inductively coupled plasma mass spectroscopy, complemented by thermodynamic calculations using FactSage 8.1 software. Iron oxide reduction to metallic iron was achieved at 1000 °C for 120 min, while sodium carbonate leaching effectively extracted alumina from the calcium aluminate slag. However, residual alumina was attributed to the formation of indissoluble gehlenite and a dense calcium carbonate layer that impeded leaching kinetics. Successful iron separation during smelting required temperatures above 1500 °C, though this process was challenged by the high viscosity of the oxide matrix and the purity of the iron.

Graphical abstract:

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氢还原有害铝土矿渣用于绿色钢铁和可持续氧化铝生产。

本文介绍了一种新的可持续冶金方法，用于铝土矿渣的高效利用和增值，旨在生产可持续氧化铝和绿色钢。该工艺集氢还原、碱浸、浸渣熔炼为一体。最初，铝土矿渣与方解石和生石灰制成球团，以制造自硬化球团，利用生石灰与水的胶结作用。这些颗粒经过氢还原，达到95%以上的还原，形成金属铁和可浸出的铝酸钙相，用于氧化铝回收。然后对还原球团进行碱性浸出，提取62%的氧化铝。随后，在1550℃熔炼有利于富铁渣和富钙渣的几乎完全分离。该过程使用各种分析技术进行分析，包括x射线衍射、电子探针微分析和电感耦合等离子体质谱，并辅以FactSage 8.1软件的热力学计算。在1000℃下浸出120 min，实现了氧化铁还原为金属铁，碳酸钠浸出可有效地从铝酸钙渣中提取氧化铝。然而，残留的氧化铝是由于形成了不溶的辉长石和致密的碳酸钙层，阻碍了浸出动力学。在冶炼过程中，成功的铁分离需要1500°C以上的温度，尽管这一过程受到氧化物基体高粘度和铁纯度的挑战。图形化的简介:

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

Journal of Sustainable Metallurgy Materials Science-Metals and Alloys

CiteScore

4.00

自引率

12.50%

发文量

151

期刊介绍： Journal of Sustainable Metallurgy is dedicated to presenting metallurgical processes and related research aimed at improving the sustainability of metal-producing industries, with a particular emphasis on materials recovery, reuse, and recycling. Its editorial scope encompasses new techniques, as well as optimization of existing processes, including utilization, treatment, and management of metallurgically generated residues. Articles on non-technical barriers and drivers that can affect sustainability will also be considered.