Chapter 7. Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues

H. Gomes, M. Rogerson, R. Courtney, W. Mayes
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引用次数: 3

Abstract

With an estimated annual production of two billion tonnes globally, alkaline industrial wastes can be considered both major global waste streams, and materials that offer significant options for potential resource recovery. Alkaline wastes are usually derived from high temperature production (e.g. steel and alumina) or disposal (e.g. incineration) processes and are increasingly abundant given rising global demand for steel and alumina and the drive for waste incineration in some jurisdictions. Although relatively long-standing afteruses have been adopted for these materials providing opportunities for value recovery (e.g. steel slag use as an aggregate), they are not sufficient to consume all residues generated or completely limit potential environmental impacts. These impacts can include the generation of fugitive dusts, challenges associated with revegetation, and effects on the water environment. These wastes can produce highly alkaline leachates enriched with trace metals (e.g. As, Cr, Mo, V) and persist over decades after site closure. Vanadium, one of the most hazardous ecotoxins in leachates, is also a valuable commodity for renewable energy technologies, unifying the often divergent needs of resource recovery and remediation. Case studies are included to illustrate routes to resource recovery from wastes from two major industrial sectors: steel production and alumina production.
第七章。工业碱性废物的综合治理与资源化利用——以钢铁和氧化铝工业废渣为例
全球估计每年生产20亿吨碱性工业废物,可被视为全球主要的废物流,也是为潜在资源回收提供重要选择的材料。碱性废物通常来自高温生产(如钢铁和氧化铝)或处理(如焚烧)过程,由于全球对钢铁和氧化铝的需求不断上升以及一些司法管辖区对废物焚烧的推动,碱性废物越来越多。虽然这些材料采用了相对长期的后用方式,提供了价值回收的机会(例如钢渣作为骨料使用),但它们不足以消耗产生的所有残留物或完全限制潜在的环境影响。这些影响包括扬尘的产生、与植被恢复相关的挑战以及对水环境的影响。这些废物可产生富含微量金属(如砷、铬、钼、钒)的高碱性渗滤液,并在场地关闭后持续数十年。钒是渗滤液中最危险的生态毒素之一,也是可再生能源技术的宝贵商品,统一了资源回收和补救的不同需求。包括案例研究,以说明从两个主要工业部门:钢铁生产和氧化铝生产的废物中回收资源的途径。
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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