Alumina production: Historical development, issues, and solutions. Part 1

iPolytech Journal Pub Date : 2023-10-03 DOI:10.21285/1814-3520-2023-3-583-597

V. N. Brichkin, V. V. Vasiliev, R. I. Maksimova

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Abstract

This study focuses on documenting the historical stages of aluminium and alumina production prior to the transition to a modern industry structure, involving the Hall-Héroult electrometallurgical process, and their technical signiﬁcance for the contemporary metallurgical complex. It highlights the signiﬁcance of these stages in the development of scientiﬁc knowledge related to alumina, aluminium, and their production technology when using chemical methods for obtaining metallic aluminium. The analysis includes aspects, such as classiﬁcation, technical evaluation of the processes, and the raw material base. It is shown that the formation of scientiﬁc knowledge regarding alumina and aluminium is mainly associated with the practical need for using alum and, to some extent, clay minerals. Since the commencement of deliberate research into methods for aluminium production in its elemental state and virtually until the 1890s, aluminium was primarily produced using the metallothermal methods pioneered by Henri St. Clair Deville and his colleagues due to the high thermodynamic stability of aluminium compounds and the absence of affordable energy sources. It was found that from 1854 to 1890, the production of aluminium by chemical method was associated with the use of sodium aluminium chloride (NaCl·AlCl3), natural cryolite, or synthesised ﬂuoride salts. Available technical reagents (aluminium sulphate, ammonia alum, and aluminium hydroxide), along with natural raw materials (cryolite, bauxite, and clay), were used as source materials in this period. The extraction and processing of bauxite were primarily associated with the production of alum and aluminium sulphate consumed by light industry. Although the demand for pure aluminium oxide was limited during the metallothermic production of aluminium, the driving force behind the advancement of modern technologies for alumina production was the demand for chemical products. This demand led to the development of technology for processing bauxite, which forms the foundation of the metallurgical complex in aluminium production using the Hall-Héroult electrometallurgical method.

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氧化铝生产:历史发展、问题和解决方案。第1部分

本研究的重点是记录铝和氧化铝生产在过渡到现代工业结构之前的历史阶段，包括霍尔-海姆斯特电冶金过程，以及它们对当代冶金综合体的技术意义。它强调了在使用化学方法获得金属铝时，与氧化铝、铝及其生产技术有关的科学知识发展的这些阶段的重要性。分析包括分类、工艺技术评价、原料基础等方面。研究表明，关于氧化铝和铝的科学知识的形成主要与使用明矾的实际需要有关，在一定程度上也与使用粘土矿物有关。自19世纪90年代开始对铝的生产方法进行有意识的研究以来，由于铝化合物的高热力学稳定性和缺乏负担得起的能源，铝主要是使用Henri St. Clair Deville和他的同事开创的金属热方法生产的。研究发现，从1854年到1890年，用化学方法生产铝与使用氯化铝钠(NaCl·AlCl3)、天然冰晶石或合成氟化物盐有关。在这一时期，可用的技术试剂(硫酸铝、氨明矾和氢氧化铝)以及天然原料(冰晶石、铝土矿和粘土)被用作原料。铝土矿的提取和加工主要与轻工业消耗的明矾和硫酸铝的生产有关。虽然在铝的金属热生产过程中，对纯氧化铝的需求是有限的，但现代氧化铝生产技术进步背后的驱动力是对化学产品的需求。这一需求导致了铝土矿加工技术的发展，这构成了使用hall - hsamort电冶金法生产铝的冶金综合体的基础。

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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iPolytech Journal

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