摘要
Metal additive manufacturing provides remarkable flexibility in geometry and component design,but localized heating/cooling heterogeneity leads to spatial variations of as-built mechanical properties,significantly complicating the materials design process.To this end,we develop a mechanistic data-driven framework integrating wavelet transforms and convolutional neural networks to predict location-dependent mechanical properties over fabricated parts based on process-induced temperature sequences,i.e.,thermal histories.The framework enables multiresolution analysis and importance analysis to reveal dominant mechanistic features underlying the additive manufacturing process,such as critical temperature ranges and fundamental thermal frequencies.We systematically compare the developed approach with other machine learning methods.The results demonstrate that the developed approach achieves reasonably good predictive capability using a small amount of noisy experimental data.It provides a concrete foundation for a revolutionary methodology that predicts spatial and temporal evolution of mechanical properties leveraging domain-specific knowledge and cutting-edge machine and deep learning technologies.
基金
This study was supported by the National Science Foundation(NSF)through grants CMMI-1934367
We thank Jennifer Glerum for performing the SEM imaging and Mark Fleming for his detailed review and helpful suggestions.J.Bennett and J.Cao would like to acknowledge the support from the Army Research Laboratory(ARL W911NF-18-2-0275)
J.Bennet acknowledeg the ARL Oak Ridge Associated Universities(ORAU)Journeyman Fellowship.