激光粉末床熔融制造铝硅铜镍合金微结构的凝固机理及力学性能效应

Metals Pub Date : 2024-05-17 DOI:10.3390/met14050586
Zhichao Shi, Pengfei Yan, Biao Yan
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摘要

在前人利用激光粉末床熔融(PBF-LB/M)技术成功制造出 Al-Si-Cu-Ni 合金的基础上,本研究进一步观察了合金的微观结构,分析了凝固过程中微观结构的形成机理,并讨论了其对力学性能的影响。研究结果表明,合金的微观结构由多层次的蜂窝状异质结构组成,蜂窝状结构内部为α-Al基体,边界处富含铜相和镍相,并与硅网络交织在一起。在凝固过程中,α-Al 首先凝固并占据晶胞的核心,而硅相和富铜及镍相则在表面张力的影响下沿晶胞边界沉积。在晶胞边界的凝固过程中,受旋光性分解和晶格间距的影响,硅相和富铜、富镍相相互连接并交叉分布,共同形成多层次的晶胞结构。PBF-LB/M Al-Si-Cu-Ni合金细化的蜂窝状微结构提高了合金的机械性能。该合金的抗弯强度为 766 ± 30 兆帕,抗拉强度和屈服强度分别为 437 ± 6 兆帕和 344 ± 4 兆帕,断裂伸长率相对较低,约为 1.51 ± 0.07%。通过适当的热处理工艺,可实现后续改进。
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Solidification Mechanism of Microstructure of Al-Si-Cu-Ni Alloy Manufactured by Laser Powder Bed Fusion and Mechanical Properties Effect
Based on previous work, where Al-Si-Cu-Ni alloy was successfully manufactured by laser powder bed fusion (PBF-LB/M) technology, in this study, we further observe the microstructure of the alloy, analyze the formation mechanism of the microstructure during solidification, and discuss their implications for the mechanical properties. The results indicate that the microstructure comprises multi-level cellular heterogeneous structures, with an α-Al matrix in the interior of the cellular structure and Cu- and Ni-rich phases clustered at the boundaries, intertwined with the silicon network. During solidification, α-Al solidifies first and occupies the core of the cells, while Si phases and Cu- and Ni-rich phases deposit along the cellular boundaries under the influence of surface tension. During the solidification process of cellular boundaries, influenced by spinodal decomposition and lattice spacing, Si phases and Cu- and Ni-rich phases interconnect and distribute crosswise, collectively forming multi-level cellular structures. The refined cellular microstructure of the PBF-LB/M Al-Si-Cu-Ni alloy enhances the mechanical properties of the alloy. The alloy exhibits a bending strength of 766 ± 30 MPa, a tensile strength and yield strength of 437 ± 6 MPa and 344 ± 4 MPa, respectively, with a relatively low fracture elongation of approximately 1.51 ± 0.07%. Subsequent improvement can be achieved through appropriate heat treatment processes.
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