Litcius/Paper detail

Progress and prospects in magnesium alloy scrap recycling

Lipeng Wang, Dong Liang, Rong Yu, Meng Wang, Yang Tian, Tingzhuang Ma, Bin Yang, Baoqiang Xu, Wenlong Jiang

2024Journal of Magnesium and Alloys30 citationsDOIOpen Access PDF

Abstract

• Reviewed the complete process flows of magnesium alloy scrap recycling process, including scrap classification, sorting, pre-treatment and recycling. • Comprehensively summarized and evaluated the existing variants of Mg alloy scrap recycling methods for their suitability from commercial and environmental. • Emphatically focuses on the recycling of magnesium alloy old scraps with potential increasing complex chemical composition. • Emphasized the strategies and methods for the removal of major hazardous metal impurities such as Fe, Cu, Co, Ni and Si. Magnesium (Mg) alloy is widely used in aerospace and automotive industries as an excellent lightweight metal material to reduce carbon emissions. The expansion of Mg alloy applications and the increasing demands for these materials have significantly facilitated the generation of Mg alloy scrap. The recycling of Mg resources is crucial for promoting both environmental sustainability and economic viability. However, current recycling effect is unsatisfactory. Therefore, this paper provides a comprehensive review of the entire recycling process, including scrap classification, separation and sorting, pre-treatment, and recycling. This paper explores the generation of Mg alloy scrap and its reincorporation into industrial products. This review outlines various Mg scrap recycling technologies based on different phase states. These include liquid-state recycling (such as flux refining, impurity removal additives, fluxless refining, compound treatment, and direct remelting), solid-state recycling (involving hot extrusion, equal-channel angular pressing (ECAP), friction stir extrusion (FSE), and spark plasma sintering (SPS)), vapor-state recycling (comprising vacuum distillation and sublimation), electrochemical recycling (solid oxide membrane (SOM) electrolysis, RE-12™ electrorefining, and non-aqueous solution electrorefining), and Mg secondary alloy development. The advantages and existing challenges associated with each method are compared and discussed, and the current obstacles to the future recycling of complex scrap are examined.

Topics & Concepts

ScrapMaterials scienceMagnesiumMagnesium alloyAlloyMetallurgyWaste managementEngineeringMagnesium Alloys: Properties and ApplicationsBauxite Residue and UtilizationMetallurgy and Material Science