极限抗拉强度
合金
材料科学
延展性(地球科学)
人工神经网络
延伸率
熔点
可塑性
冶金
复合材料
机器学习
计算机科学
蠕动
作者
Jeong Mok Oh,P.L. Narayana,Jae‐Keun Hong,Jong‐Taek Yeom,N.S. Reddy,Namhyun Kang,Chan Hee Park
标识
DOI:10.1016/j.jallcom.2021.161029
摘要
Transformation-induced plasticity (TRIP) Ti alloys are promising structural materials that offer high strength and ductility. However, these alloys often include heavy, expensive, and high-melting-point β-stabilizing elements such as V, Nb, Mo, and W. Herein, an artificial neural network (ANN) was used to develop a Ti–Al–Fe–Mn-based TRIP alloy comprising lighter and/or cheaper elements. The ANN model was trained with 30 experimental tensile datasets for heat-treated (830–920 °C) Ti–4Al–2Fe–xMn (x = 0–4 wt%) alloys, and used to generate 400 tensile datasets with more finely tuned composition and temperature intervals. Based on the predicted data, an 883 °C-heat-treated Ti–4Al–2Fe–1.4Mn alloy was produced (conditions not used in the training datasets), which exhibited ultra-high specific strength (289 MPa·cm3/g) and high elongation (34%). Thus, the ANN approach successfully led to the development of a new alloy while minimizing the number of labor-intensive and time-consuming experiments.
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