A review on metal additive manufacturing:modeling and application of numerical simulation for heat and mass transfer and microstructure evolution 被引量：3

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摘要 Metal additive manufacturing technology has been widely used in prototyping,parts manufacturing and repairing.Metal additive manufacturing is a multi-scale and multi-physical coupling process with complex physical phenomena of heat and mass transfer and microstructure evolution.It is hard to directly observe the dynamic behavior and microstructure evolution of molten pool during additive manufacturing.Therefore,numerical simulation of additive manufacturing process is significant since it can efficiently and pertinently predict and analyze the physical phenomena in the process of metal additive manufacturing,and provide a reference for technological parameters selection.In this review,the research progress of numerical simulation of metal additive manufacturing is discussed.Various aspects of numerical simulation models are reviewed,including:(1)Introduction of basic control method and physical description of numerical simulation models;(2)Comparison of various heat and mass transfer models based on different physical assumptions(heat conduction model;heat flux coupling model;discrete powder particle heat flux coupling model);(3)Applications of various microstructure evolution models[phase field(PF),cellular automata(CA),and Monte Carlo(MC)].Finally,the development trend of numerical simulation of metal additive manufacturing,including the thermal-flow-solid coupling model and deep learning for numerical model,is analyzed.

作者 Chuan-ming Liu Hua-bing Gao Li-yu Li Jian-dong Wang Chun-huan Guo Feng-chun Jiang

机构地区 Key Laboratory of Superlight Materials&Surface Technology

出处《China Foundry》 SCIE CAS 2021年第4期317-334,共18页 中国铸造（英文版）

基金 the National Key R&D Program of China(No.2017YFE0123500 and No.2017YFB1103701)。

关键词 additive manufacturing numerical simulation heat and mass transfer microstructure evolution

分类号 TP391.9 [自动化与计算机技术—计算机应用技术]

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