增材制造、铸造和轧制镁锂合金微观结构和机械性能差异的综合研究

Dengke Liu, Xuewen Zong, Pengsheng Xue, Yan Zhang, Hongzhi Zhou, Zhongtang Gao, Rui Wang, Bingheng Lu
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引用次数: 0

摘要

为了探索高锂含量镁锂合金线材直接能量沉积的成型机制,本研究介绍了一种利用冷金属转移线材电弧增材制造(CMT-WAAM)成功制造出 LA103Z 镁锂合金薄壁结构的新方法。除了铸造和轧制样品外,还对 CMT-WAAM 样品不同区域的微观结构和机械性能进行了综合比较评估。CMT-WAAM 样品的微观结构主要由 β-Li 相和细小针状的 α-Mg 相组成,与铸造和轧制样品的微观结构有明显差异。值得注意的是,在 CMT-WAAM 样品中,沿沉积方向的机械性能表现出显著的变化,但沿沉积和扫描方向的机械性能没有发现明显的各向异性。不同区域的机械性能差异主要归因于晶粒大小、α-镁相和次生相的大小和比例的变化,这与 CMT-WAAM 工艺的低热输入和高冷却速率有关。CMT-WAAM 样品的平均拉伸强度为 159.5 兆帕,与铸造和轧制样品相比分别提高了 30.7% 和 13.9%。这些研究结果表明,与传统成型样品相比,CMT-WAAM 样品具有出色的强度。这项研究为大规模复杂结构的双相镁锂合金增材制造提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Comprehensive study on the differences in microstructure and mechanical properties of Mg-Li alloy fabricated by additive manufacturing, casting, and rolling
In order to explore the forming mechanism of direct energy deposition of magnesium-lithium alloy wire with high lithium content, this study introduces a novel approach utilizing Cold Metal Transfer Wire Arc Additive Manufacturing (CMT-WAAM) to successfully fabricate thin-walled structures of LA103Z Mg-Li alloy. A comprehensive comparison was conducted to evaluate the microstructure and mechanical properties of different regions on CMT-WAAM samples, in addition to cast and rolled samples. The microstructure of CMT-WAAM samples is mainly composed of β-Li phase and fine needle shaped α-Mg phase, exhibiting a notable divergence from the microstructure observed in cast and rolled samples. It is noteworthy that the mechanical properties along the deposition direction exhibited significant variability in CMT-WAAM samples, but no significant anisotropy is discerned in the mechanical properties along the deposition and scanning directions. The discrepancies in mechanical properties across different regions are predominantly attributed to variations in grain size, and the size and proportion of the α-Mg phase and secondary phases, which are related to the low heat input and high cooling rate of the CMT-WAAM process. The mean tensile strength of CMT-WAAM samples is 159.5 MPa, marking a respective increase of 30.7% and 13.9% compared to cast and rolled samples. These findings underscore the outstanding strength of CMT-WAAM samples compared to conventionally formed samples. This study provides novel insights into additive manufacturing of dual-phase Mg-Li alloys for large-scale complex structures.
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