Additive manufacturing: A machine learning model of process-structure-property linkages for machining behavior of Ti-6Al-4V

Materials Science in Additive Manufacturing Pub Date : 2022-03-30 DOI:10.18063/msam.v1i1.6

Xi Gong, Dongrui Zeng, Willem Groeneveld-Meijer, G. Manogharan

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引用次数: 28

Abstract

Prior studies in metal additive manufacturing (AM) of parts have shown that various AM methods and post-AM heat treatment result in distinctly different microstructure and machining behavior when compared with conventionally manufactured parts. There is a crucial knowledge gap in understanding this process-structure-property (PSP) linkage and its relationship to material behavior. In this study, the machinability of metallic Ti-6Al-4V AM parts was investigated to better understand this unique PSP linkage through a novel data science-based approach, specifically by developing and validating a new machine learning (ML) model for material characterization and material property, that is, machining behavior. Heterogeneous material structures of Ti-6Al-4V AM samples fabricated through laser powder bed fusion and electron beam powder bed fusion in two different build orientations and post-AM heat treatments were quantitatively characterized using scanning electron microscopy, electron backscattered diffraction, and residual stress measured through X-ray diffraction. The reduced dimensional representation of material characterization data through chord length distribution (CLD) functions, 2-point correlation functions, and principal component analysis was found to be accurate in quantifying the complexities of Ti-6Al-4V AM structures. Specific cutting energy was the response variable for the Taguchi-based experimentation using force dynamometer. A low-dimensional S-P linkage model was established to correlate material structures of metallic AM and machining properties through this novel ML model. It was found that the prediction accuracy of this new PSP linkage is extremely high (>99%, statistically significant at 95% confidence interval). Findings from this study can be seamlessly integrated with P-S models to identify AM processing conditions that will lead to desired material behaviors, such as machining behavior (this study), fatigue behavior, and corrosion resistance.

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增材制造:Ti-6Al-4V加工行为过程-结构-性能联系的机器学习模型

金属增材制造(AM)的研究表明，与传统制造的零件相比，各种增材制造方法和增材制造后的热处理导致了明显不同的微观结构和加工行为。在理解这种工艺-结构-性能(PSP)联系及其与材料行为的关系方面，存在一个关键的知识缺口。在本研究中，通过一种新颖的基于数据科学的方法，研究了金属Ti-6Al-4V AM零件的可加工性，以更好地理解这种独特的PSP联系，特别是通过开发和验证一种新的机器学习(ML)模型，用于材料表征和材料性能，即加工行为。采用扫描电镜、电子背散射衍射和x射线衍射测量残余应力，定量表征了激光粉末床熔合和电子束粉末床熔合两种不同构建取向和AM后热处理制备的Ti-6Al-4V AM样品的非均质材料结构。通过弦长分布(CLD)函数、两点相关函数和主成分分析对材料表征数据进行降维表示，可以准确地量化Ti-6Al-4V AM结构的复杂性。比切削能是基于田口的力测功仪实验的响应变量。通过该模型建立了金属增材制造材料结构与加工性能之间的低维S-P联动模型。结果表明，该新的PSP连锁预测精度极高(>99%，在95%置信区间具有统计学意义)。本研究的结果可以与P-S模型无缝集成，以确定AM加工条件，这些条件将导致所需的材料行为，如加工行为(本研究)、疲劳行为和耐腐蚀性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Materials Science in Additive Manufacturing

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