Machine Learning Assisted Composition Effective Design for Precipitation Strengthened Copper Alloys

Hongtao Zhang, Huadong Fu, Shuaicheng Zhu, Wei Yong, Jian-Xin Xie
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引用次数: 54

Abstract

Abstract Optimizing the composition and improving the conflicting mechanical and electrical properties of multiple complex alloys has always been difficult by traditional trial-and-error methods. Here we propose a machine learning strategy to design alloys with remarkable properties by screening key alloy factors through correlation screening, recursive elimination and exhaustive screening, and then designing composition iteratively through Bayesian optimization. Taking the precipitation strengthened copper alloys as an example, 5 kinds of key alloy factors affecting hardness (HV) and 6 kinds of key alloy factors affecting electrical conductivity (EC) were obtained by screening alloy factors. “HV - key alloy factors” model with error less than 7% and the “EC - key alloy factors” model with error less than 9% were established, respectively. Then, new copper alloys were effectively designed utilizing Bayesian optimization and iterative optimization experiments. Designed Cu-1.3Ni-1.4Co-0.56Si-0.03Mg alloy has excellent combined mechanical and electrical properties with the measured ultimate tensile strength (UTS) of 858 MPa and EC of 47.6%IACS. The property results are superior to the reported precipitation strengthened copper alloys, which realize the simultaneous improvement of the conflicting mechanical and electrical properties.
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机器学习辅助沉淀强化铜合金成分有效设计
摘要通过传统的试错方法来优化复合合金的成分和改善其相互冲突的力学和电学性能一直是一个难题。本文提出了一种机器学习策略,通过相关筛选、递归淘汰和穷举筛选筛选关键合金因素,然后通过贝叶斯优化迭代设计成分,从而设计出性能显著的合金。以沉淀强化铜合金为例,通过对合金因素的筛选,得到了影响硬度(HV)的5种关键合金因素和影响电导率(EC)的6种关键合金因素。分别建立了误差小于7%的“HV -关键合金因素”模型和误差小于9%的“EC -关键合金因素”模型。然后,利用贝叶斯优化和迭代优化实验,有效地设计了新型铜合金。所设计的Cu-1.3Ni-1.4Co-0.56Si-0.03Mg合金具有优异的综合力学性能和电性能,实测抗拉强度(UTS)为858 MPa,电导率(EC)为47.6%IACS。性能结果优于已有报道的沉淀强化铜合金,实现了相互矛盾的力学性能和电性能的同时改善。
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