Hot-wire arc additive manufacturing of aluminum alloy with reduced porosity and high deposition rate

Hot-wire arc additive manufacturing of aluminum alloy with reduced porosity and high deposition rate

Wire arc additive manufacturing (WAAM) technology has attracted considerable interest in large-scale metallic components, but porosity and low deposition rate are the two dominating technical challenges in WAAM of aluminum alloy. In order to effectively solve these problems, a novel method of hot-wi...

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Bibliographic Details
Published in:Materials & design Vol. 199; p. 109370
Main Authors: Fu, Rui, Tang, Shuiyuan, Lu, Jiping, Cui, Yinan, Li, Zixiang, Zhang, Haorui, Xu, Tianqiu, Chen, Zhuo, Liu, Changmeng
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2021
Elsevier
Subjects:
2024 alloy
Deposition rate
Hot-wire arc additive manufacturing
Macro/microstructures
Mechanical properties
Pores
Mechanical properties
Pores
Deposition rate
2024 alloy
Macro/microstructures
Hot-wire arc additive manufacturing
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Summary:Wire arc additive manufacturing (WAAM) technology has attracted considerable interest in large-scale metallic components, but porosity and low deposition rate are the two dominating technical challenges in WAAM of aluminum alloy. In order to effectively solve these problems, a novel method of hot-wire arc additive manufacturing is used to fabricate aluminum alloy. Systematic studies are carried out to investigate the formation mechanism of the pores, the macro/microstructures, as well as the mechanical properties of the parts. It is found that the pores were mainly clustered at the inter-layer. With the increase of the hot-wire current, the porosity firstly decreases, then reaches a minimum at 100 A, and afterwards increases progressively. The corresponding density changes from 96.8% at the hot-wire current of 0 A to 99.6% at 100 A. Increasing the current from 0 A to 120 A also leads to the increase of the deposition rate by about 3.5 times, and the gradual increase of the size of equiaxed grain by 1.6 times. The mechanical properties are considerably improved with the decrease of the porosity. [Display omitted] •A novel hot-wire arc additive manufacturing was used to manufacture aluminum alloy.•The effect of hot-wire current on porosity was studied.•The deposition efficiency of aluminum alloy was greatly improved.•Parts with excellent mechanical properties were obtained.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2020.109370