Metals | |
Machine Learning Based Methods for Obtaining Correlations between Microstructures and Thermal Stresses | |
Alankar Alankar1  Akshay Bhutada1  Sunni Kumar1  Dayalan Gunasegaram2  | |
[1] Department of Mechanical Engineering, Indian Institute of Technology Bombay, Mumbai 400076, India;The Commonwealth Scientific and Industrial Research Organisation (CSIRO), Research Way, Clayton, VIC 3168, Australia; | |
关键词: material design; data-enabled predictions; materials informatics; additive manufacturing; ICME; | |
DOI : 10.3390/met11081167 | |
来源: DOAJ |
【 摘 要 】
The microstructure–property relationship is critical for parts made using the emerging additive manufacturing process where highly localized cooling rates bestow spatially varying microstructures in the material. Typically, large temperature gradients during the build stage are known to result in significant thermally induced residual stresses in parts made using the process. Such stresses are influenced by the underlying local microstructures. Given the extensive range of variations in microstructures, it is useful to have an efficient method that can detect and quantify cause and effect. In this work, an efficient workflow within the machine learning (ML) framework for establishing microstructure–thermal stress correlations is presented. While synthetic microstructures and simulated properties were used for demonstration, the methodology may equally be applied to actual microstructures and associated measured properties. The dataset for ML consisted of images of synthetic microstructures along with thermal stress tensor fields simulated using a finite element (FE) model. The FE model considered various grain morphologies, crystallographic orientations, anisotropic elasticity and anisotropic thermal expansion. The overall workflow was divided into two parts. In the first part, image classification and clustering were performed for a sanity test of data. Accuracies of 97.33% and 99.83% were achieved using the ML based method of classification and clustering, respectively. In the second part of the work, convolution neural network model (CNN) was used to correlate the microstructures against various components and measures of stress. The target vectors of stresses consisted of individual components of stress tensor, principal stresses and hydrostatic stress. The model was able to show a consistent correlation between various morphologies and components of thermal stress. The overall predictions by the model for all the microstructures resulted into
【 授权许可】
Unknown