Effect of Cooling Rate on the Microstructure Evolution and Mechanical Properties of Iron-Rich Al-Si Alloy

The mechanical properties of iron-rich Al-Si alloy is limited by the existence of plenty of the iron-rich phase (β-Al FeSi), whose unfavorable morphology not only splits the matrix but also causes both stress concentration and interface mismatch with the Al matrix. The effect of the cooling rate on...

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Bibliographic Details
Published in:Materials 2022-01, Vol.15 (2), p.411
Main Authors: Shen, Xiao, Liu, Shuiqing, Wang, Xin, Cui, Chunxiang, Gong, Pan, Zhao, Lichen, Han, Xu, Li, Zirui
Format: Article
Language:English
Subjects:
Alloys
Aluminum base alloys
Cooling
Cooling effects
Cooling rate
Energy consumption
Iron
Mechanical properties
Melt spinning
Metallurgy
Morphology
Resource recovery
Silicon
Solidification
Spectrum analysis
Stress concentration
Tensile properties
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Summary:The mechanical properties of iron-rich Al-Si alloy is limited by the existence of plenty of the iron-rich phase (β-Al FeSi), whose unfavorable morphology not only splits the matrix but also causes both stress concentration and interface mismatch with the Al matrix. The effect of the cooling rate on the tensile properties of Fe-rich Al-Si alloy was studied by the melt spinning method at different rotating speeds. At the traditional casting cooling rate of ~10 K/s, the size of the needle-like β-Al FeSi phase is about 80 μm. In contrast, the size of the β-Al FeSi phase is reduced to 500 nm and the morphology changes to a granular morphology with the high cooling rate of ~10 K/s. With the increase of the cooling rate, the morphology of the β-Al FeSi phase is optimized, meanwhile the tensile properties of Fe-rich Al-Si alloy are greatly improved. The improved tensile properties of the Fe-rich Al-Si alloy is attributed to the combination of Fe-rich reinforced particles and the granular silicon phase provided by the high cooling rate of the melt spinning method.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma15020411