计算机科学
过程(计算)
计算模型
系统工程
忠诚
钥匙(锁)
工业工程
计算模拟
航程(航空)
灵活性(工程)
仿真建模
高保真
风险分析(工程)
生产(经济)
数据科学
过程建模
建模与仿真
管理科学
制造工程
新兴技术
多尺度建模
财产(哲学)
分布式计算
超级计算机
材料加工
商业化
公共记录
先进制造业
专区
多样性(政治)
软件
作者
Alex Plotkowski,Matt Rolchigo,Gregory J. Wagner,Samuel Temple Reeve,John Coleman,Gerry Knapp,Lyle E. Levine,Albert C. To,Stephen DeWitt,Florian Dugast,Sankaran Mahadevan,Christopher K. Newman,Benjamin Stump,Matt Bement,John Turner
标识
DOI:10.1177/09506608251394155
摘要
Metal additive manufacturing (AM) offers a unique opportunity for production of advanced materials and complex geometries. However, variability in microstructure and properties challenges conventional approaches to design, process optimization, qualification, and materials selection. Modeling and simulation can improve understanding of AM processing and materials, but also poses major challenges for existing computational methods. Simultaneously, modern scientific computing hardware has become increasingly complex, most notably with the adoption of hybrid architectures such as Graphical Processing Units (GPUs). If appropriately utilized, emerging computational capabilities provide an opportunity to reveal new insight into AM processing and the resulting material structure and properties. In this review we describe the computational AM landscape, identify critical gaps, and highlight opportunities to impact the development and application of AM. First, the requirements and challenges of representative AM problem statements will be defined. These problems range from scientific studies to industrial applications and are designed to capture the breadth of challenges facing the AM community. Next, the current state of AM modeling and simulation is evaluated, broken down by enabling hardware and software, process simulation, microstructure simulation, and property simulation. Each section describes the diversity of simulation approaches and associated trade-offs in physical fidelity and computational expense. Each area is then assessed based on their suitability and readiness for current and developing computational architectures. Lastly, the greatest opportunities for future research and application are highlighted, including gaps in modeling capabilities, opportunities for near-term application, and key scientific challenges.
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