Ahmed M. Faizan Mohamed , Francesco Careri , Raja H.U. Khan , Moataz M. Attallah , Leonardo Stella
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引用次数: 0
摘要
机器学习(ML)能够通过数据预测复杂的模式和行为,因此在增材制造(AM)领域引起了极大的兴趣。这方面的例子包括设计优化、过程控制和成本最小化。在本文中,我们开发了一种基于强化学习(RL)的新型框架,用于金属激光粉末床融合(L-PBF)中的孔隙率预测。这种方法有两方面的新颖性:它是第一种将强化学习集成到 L-PBF 中进行孔隙率预测的方法,其中状态空间由三个参数(激光功率、扫描速度和舱口间距)的排列组合组成,以获得最佳参数组合;此外,通过适当制定的奖励函数,我们嵌入了基于 Eagar-Tsai 热模型的物理信息原则进行训练。所提出的框架已在 L-PBF 高强度 A205 Al 合金上进行了实验验证。实验结果表明,尽管存在少数异常值,但与预测的最佳参数的保真度很高,证明了这种方法的潜力。
A novel porosity prediction framework based on reinforcement learning for process parameter optimization in additive manufacturing
Machine learning (ML) has generated great interest in additive manufacturing (AM) thanks to its ability to predict complex patterns and behaviors through data. Examples include design optimization, process control, and cost minimization. In this paper, we develop a novel framework based on reinforcement learning (RL) for porosity prediction in metal laser-powder bed fusion (L-PBF). The novelty of this approach is twofold: it is the first approach that integrates RL in L-PBF for porosity prediction where the state space consists of permutations of three parameters (laser power, scan speed, and hatch spacing) for optimal parameter combinations; furthermore, through an appropriately formulated reward function, we embed physics-informed principles based on the Eagar-Tsai thermal model for training. The proposed framework has been experimentally validated on L-PBF high-strength A205 Al alloy. The experimental results demonstrated high fidelity with the predicted optimal parameters, despite few outliers, demonstrating the potential of this approach.
期刊介绍:
Scripta Materialia is a LETTERS journal of Acta Materialia, providing a forum for the rapid publication of short communications on the relationship between the structure and the properties of inorganic materials. The emphasis is on originality rather than incremental research. Short reports on the development of materials with novel or substantially improved properties are also welcomed. Emphasis is on either the functional or mechanical behavior of metals, ceramics and semiconductors at all length scales.
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