火法冶金过程中的绿色反应物、可再生能源和环境影响缓解策略:综述。

IF 4.3
Jean-Philippe Harvey, William Courchesne, Minh Duc Vo, Kentaro Oishi, Christian Robelin, Ugo Mahue, Philippe Leclerc, Alexandre Al-Haiek
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引用次数: 6

摘要

摘要:金属和合金是我们工业化社会中最重要的技术材料之一。它们是汽车、飞机和建筑物中最常用的结构材料,也是大多数电子设备的技术核心。它们可以远距离运输能源,并在可再生能源技术的关键部分得到利用。尽管初级金属生产工业已经成熟,并运行优化的火法冶金工艺,但它们广泛依赖于廉价和丰富的碳质反应物(化石燃料,焦炭),需要高功率加热装置(通常也由化石燃料供电)来煅烧,烘烤,冶炼和精炼,并且它们产生的许多输出流具有高残余能量含量。除了大量的二氧化碳排放外,许多装置的操作还会产生有害的气体,这需要未来的气体洗涤和捕获策略。因此,仍然有很多机会来降低关键的火法冶金操作的环境足迹。本文探讨了在不同的火法冶炼装置中使用生物燃料、生物炭、氢和氨等绿色反应物的可能性。它还确定了所有可用的回收流(如钢和铝废料,电子废物和锂离子电池)以及与它们在初级金属工艺中整合相关的技术挑战。围绕氢、金属还原和惰性阳极电冶金的使用,对碳基还原的替代方案进行了完整的讨论。综述了在火法冶炼装置中使用可再生能源和余热增值的不同方法。最后,详细介绍了减轻火法冶金操作对环境影响的策略,如二氧化碳捕获、利用和储存以及气体洗涤技术。这篇原始的综述论文首次汇集了所有可能的战略和努力,可以在未来部署,以减少火法冶金工业的环境足迹。它的主要目的是促进协作工作,并在学术界、火法冶金工业、决策者和设备供应商之间建立协同作用。图形摘要:重点:使用更环保的反应物、绿色电力或碳捕获进行更可持续的金属生产是可能的,有时已经在进行中。加速变革需要更多的投资和压力。讨论:铝和钢铁行业是否有足够的压力来达到设定的气候目标?现有设施的温室气体排放通常可以通过使用绿色技术进行改造来部分缓解,我们是否应该过早关闭工厂,以使用更环保的技术建造新工厂?由于绿色或可再生资源目前的可用性有限,我们应该在哪个部门使用它们以最大化其效益?
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Greener reactants, renewable energies and environmental impact mitigation strategies in pyrometallurgical processes: A review.

Greener reactants, renewable energies and environmental impact mitigation strategies in pyrometallurgical processes: A review.

Greener reactants, renewable energies and environmental impact mitigation strategies in pyrometallurgical processes: A review.

Greener reactants, renewable energies and environmental impact mitigation strategies in pyrometallurgical processes: A review.

Abstract: Metals and alloys are among the most technologically important materials for our industrialized societies. They are the most common structural materials used in cars, airplanes and buildings, and constitute the technological core of most electronic devices. They allow the transportation of energy over great distances and are exploited in critical parts of renewable energy technologies. Even though primary metal production industries are mature and operate optimized pyrometallurgical processes, they extensively rely on cheap and abundant carbonaceous reactants (fossil fuels, coke), require high power heating units (which are also typically powered by fossil fuels) to calcine, roast, smelt and refine, and they generate many output streams with high residual energy content. Many unit operations also generate hazardous gaseous species on top of large CO2 emissions which require gas-scrubbing and capture strategies for the future. Therefore, there are still many opportunities to lower the environmental footprint of key pyrometallurgical operations. This paper explores the possibility to use greener reactants such as bio-fuels, bio-char, hydrogen and ammonia in different pyrometallurgical units. It also identifies all recycled streams that are available (such as steel and aluminum scraps, electronic waste and Li-ion batteries) as well as the technological challenges associated with their integration in primary metal processes. A complete discussion about the alternatives to carbon-based reduction is constructed around the use of hydrogen, metallo-reduction as well as inert anode electrometallurgy. The review work is completed with an overview of the different approaches to use renewable energies and valorize residual heat in pyrometallurgical units. Finally, strategies to mitigate environmental impacts of pyrometallurgical operations such as CO2 capture utilization and storage as well as gas scrubbing technologies are detailed. This original review paper brings together for the first time all potential strategies and efforts that could be deployed in the future to decrease the environmental footprint of the pyrometallurgical industry. It is primarily intended to favour collaborative work and establish synergies between academia, the pyrometallurgical industry, decision-makers and equipment providers.

Graphical abstract:

Highlights: A more sustainable production of metals using greener reactants, green electricity or carbon capture is possible and sometimes already underway. More investments and pressure are required to hasten change.

Discussion: Is there enough pressure on the aluminum and steel industries to meet the set climate targets?The greenhouse gas emissions of existing facilities can often be partly mitigated by retrofitting them with green technologies, should we close plants prematurely to build new plants using greener technologies?Since green or renewable resources presently have limited availability, in which sector should we use them to maximize their benefits?

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