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Evolving Material Porosity on an Additive Manufacturing Simulation with the Generalized Method of Cells

机译：使用单元格广义方法在增材制造模拟中不断发展的材料孔隙率

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The effect of material porosity on final part distortion and residual stresses in a selective laser sintering manufacturing simulation is presented here. A time-dependent thermo-mechanical model is used with the open-source FEA software CalculiX. Effective homogenized material properties for Inconel 625 are precomputed using NASA's Micromechanics Analysis Code with the Generalized Method of Cells (MAC/GMC). The evolving porosity of the material is estimated with each pass of the laser beam during simulation runtime. A comparison with a homogenous model and the evolving model shows that the evolving porous model predicts larger distortions with greater residual stresses.

机译：这里给出了材料孔隙率对选择性激光烧结制造模拟中的最终部件失真和残余应力的影响。时间依赖的热机械模型与开源FEA软件计算使用。用于Inconel 625的有效均化材料特性使用NASA的微机械分析代码预先计算，具有通用的细胞（MAC / GMC）。通过激光束在仿真运行时间期间估计材料的发展孔隙率。与同质模型的比较和不断发展的模型表明，不断发展的多孔模型预测具有更大残余应力的更大扭曲。

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《AIAA SciTech Forum and Exposition》|2020年|296-309|共14页
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Luis F. Silva; Francisco Yapor; Evan J. Pineda; Peter A. Gustafson;
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1. Compressive fatigue properties of additive-manufactured Ti-6Al-4V cellular material with different porosities [J] . Ming-Wei Wu, Jhewn-Kuang Chen, BoHuan Lin, Materials Science and Engineering . 2020,第Jul14期

机译：添加剂制造的Ti-6AL-4V细胞材料具有不同孔隙的压缩疲劳性能
2. Failure mechanisms of additively manufactured porous biomaterials: Effects of porosity and type of unit cell [J] . Kadkhodapour J., Montazerian H., Darabi A. Ch., Journal of the mechanical behavior of biomedical materials . 2015,第Null期

机译：增材制造的多孔生物材料的失效机理：孔隙率和晶胞类型的影响
3. Failure mechanisms of additively manufactured porous biomaterials: Effects of porosity and type of unit cell [J] . Kadkhodapour J., Montazerian H., Darabi A. Ch., Journal of the mechanical behavior of biomedical materials . 2015,第Null期

机译：碱性制造多孔生物材料的失效机制：孔隙率和单位细胞类型的影响
4. The challenges in edge detection and porosity analysis for dissimilar materials additive manufactured components [C] . Ahmed Tawfik, Radu Racasan, Desi Bacheva, International Conference of the European Society for Precision Engineering and Nanotechnology . 2019

机译：不同材料添加剂制造部件边缘检测和孔隙度分析的挑战
5. Design and Manufacturing Guidelines for Additive Manufacturing of High Porosity Cellular structures [D] . Kabbur, Nikhil. 2017

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6. Artificial Neural Networks-Based Material Parameter Identification for Numerical Simulations of Additively Manufactured Parts by Material Extrusion [O] . Paul Meißner, Hagen Watschke, Jens Winter, 2020

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7. Finite element analysis to determine the role of porosity in dynamic localization and fragmentation: Application to porous microstructures obtained from additively manufactured materials [O] . M. Marvi-Mashhadi, A. Vaz-Romero, F. Sket, 2021

机译：有限元分析，以确定孔隙率在动态定位和碎片中的作用：应用于从加成制造的材料获得的多孔微观结构

Evolving Material Porosity on an Additive Manufacturing Simulation with the Generalized Method of Cells

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