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Wire arc additive manufacturing (WAAM) of nanotreated aluminum alloy 6061

材料科学 压痕硬度 合金 极限抗拉强度 微观结构 复合材料 可制造性设计 冶金 扫描电子显微镜 机械工程 工程类
作者
Yitian Chi,Narayanan Murali,Jingke Liu,Maximillian Liese,Xiaochun Li
出处
期刊:Rapid Prototyping Journal [Emerald Publishing Limited]
卷期号:29 (7): 1341-1349 被引量:28
标识
DOI:10.1108/rpj-05-2022-0148
摘要

Purpose Additive manufacturing (AM) can achieve significant weight savings with only minor compromises in strength if high-performance wrought aluminum alloys are used as feedstock. Despite the advantages in strength that aluminum alloys (AA) 6061 offer, they cannot be manufactured via printing because of hot cracking and other solidification problems. The purpose of this study is to achieve high-quality printing of AA6061 with nanotreated wires. Design/methodology/approach Nanotreating was used to modify the AA6061 alloy composition by adding a small fraction of nanoparticles to enhance the alloy’s manufacturability and resultant properties. Wire arc additive manufacturing (WAAM) was used to print the nanotreated AA6061 wire feedstock. The microstructure of the printed AA6061 was characterized by X-ray crystallography, optical microscopy, scanning electron microscopy and energy dispersive spectroscopy mapping. The microhardness profile, tensile behavior and fracture surface were analyzed. Findings This work successfully used WAAM to print nanotreated AA 6061 components. The resulting AA6061 parts were crack-free, with exceptional grain morphology and superior mechanical properties. Owing to the excellent size control capabilities of nanoparticles, a homogeneous distribution of small grains was maintained in all deposited layers, even during repeated thermal cycles. Originality/value Previous studies have not successfully printed AA6061 using WAAM. Conventional WAAM products exhibit anisotropic mechanical properties. The nanotreated AA6061 was successfully printed to achieve homogeneous microhardness and isotropic tensile properties. The promising results of this study reflect the great potential of nanotech metallurgy as applied to the WAAM process.
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