通过平滑粒子流体力学模拟添加剂摩擦搅拌沉积过程预测微观结构

N. I. Palya, K. Fraser, N. Zhu, J. B. Hoarston, K. Doherty, P. G. Allison, J. B. Jordon
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引用次数: 0

摘要

添加式摩擦搅拌沉积(AFSD)是一种固态添加式制造方法,它利用摩擦生热和严重的塑性变形,在逐层沉积过程中实现冶金结合。由于亚固态加工温度比基于熔融的替代方法更有优势,因此 AFSD 可用于增材制造散件或修复铝合金。由于 AFSD 加工过程中会发生动态再结晶,微观结构会发生显著变化,从而导致晶粒和金属间颗粒尺寸出现巨大梯度。在本研究中,我们提出了一个与历史相关的建模框架,通过无网格数值模拟来预测 AFSD 加工过程中的微观结构演变。在这项工作中,我们将实验量化的晶粒和金属间颗粒尺寸以及温度和应变率之间的关系纳入光滑颗粒流体动力学模拟框架,以预测 AFSD 加工后的微观结构。SPH 模拟方法表明,AFSD 加工后晶粒和金属间颗粒尺寸分布的模型预测与实验结果之间存在合理的一致性。
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Microstructure Prediction from Smooth Particle Hydrodynamics Process Simulations of Additive Friction Stir Deposition

Additive friction stir deposition (AFSD) is a solid-state additive manufacturing method that exploits frictional heat generation and severe plastic deformation to achieve metallurgical bonding during layer-by-layer deposition. AFSD can be used for additive manufacturing of bulk components or repair of aluminum alloys as the sub-solidus processing temperatures can be beneficial over fusion-based alternatives. Due to dynamic recrystallization during AFSD processing, significant evolution of the microstructure can occur which can lead to substantial gradients in grain and intermetallic particle size. In this study, we present a history dependent modeling framework to predict the microstructure evolution in the AFSD process through mesh-free numerical simulations. In this work, experimentally quantified relationships between grain and intermetallic particle size as well as temperatures and strain rates were incorporated into a smooth particle hydrodynamic simulation framework to predict the microstructure after AFSD processing. The SPH simulation approach showed reasonable agreement between the model predictions and experimental results of grain and intermetallic particle size distribution after AFSD processing.

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