材料科学
金属间化合物
共晶体系
合金
微观结构
粒度
等轴晶
冶金
铸造
晶界
体积分数
脆性
撕裂
复合材料
作者
Shifeng Luo,Guangyu Yang,Zhen You Zou,Shuxia Ouyang,Lei Xiao,Wanqi Jie
标识
DOI:10.1002/adem.201800139
摘要
The hot tearing susceptibility (HTS) of binary Mg–Gd alloys is tested from 1.0 to 8.0 wt% using a constrained rod casting (CRC) mold. It is found that the curve of the HTS versus Gd content follows a typical “Λ” curve: HTS increases firstly, reaches a maximum at 1.5% Gd, and then decreases, which is in good agreement with the results predicted by Clyne‐Davies model. Microstructure observations and thermodynamic calculations show that grain structure (size and morphology), the susceptible freezing range, the volume fraction of eutectic liquid, and the amount of intermetallics (Mg 5 Gd) are the main factors influencing the HTS of Mg–Gd experimental alloys. The highest HTS observed in Mg–1.5Gd alloy is attributed to its coarse columnar grains, the high freezing range, and the thin and continuous liquid film as well as the hard and brittle intermetallics precipitated along the grain boundaries. In contrast, the lowest HTS observed in Mg–8Gd alloy is mainly related to the fine equiaxed grains, which can effectively accommodate the strain during solidification, and the tear healing by eutectic liquid. Furthermore, the effect of grain refinement by Zr addition on the HTS is also studied, and the results show that grain refinement can significantly reduce the HTS.
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