High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach
Variations in the high cycle fatigue response of laser powder bed fusion materials can be caused by the choice of processing and post-processing strategies. The numerous influencing factors arising from the process demand an effective and unified approach to fatigue property assessment. This work ex...
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sg-ntu-dr.10356-1409272021-01-29T07:49:08Z High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach Zhang, Meng Sun, Chen-Nan Zhang, Xiang Goh, Phoi Chin Wei, Jun Hardacre, David Li, Hua School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing Engineering::Mechanical engineering Fatigue Additive Manufacturing Variations in the high cycle fatigue response of laser powder bed fusion materials can be caused by the choice of processing and post-processing strategies. The numerous influencing factors arising from the process demand an effective and unified approach to fatigue property assessment. This work examines the use of a neuro-fuzzy-based machine learning method for predicting the high cycle fatigue life of laser powder bed fusion stainless steel 316L. A dataset, consisting of fatigue life data for samples subjected to varying processing conditions (laser power, scan speed and layer thickness), post-processing treatments (annealing and hot isostatic pressing) and cyclic stresses, was constructed for simulating a complex nonlinear input-output environment. The associated fracture mechanisms, including the modes of crack initiation and deformation, were characterised. Two models, by employing the processing/post-processing parameters and the static tensile properties respectively as the inputs, were developed from the training data. Despite the diverse fatigue and fracture properties, the models demonstrated good prediction accuracy when checked against the test data, and the computationally-derived fuzzy rules agree well with understanding of the fracture mechanisms. Direct application of the model to literature results, however, yielded a range of prediction accuracies because of the variability in the reported data. Retraining the model by incorporating the literature results into the dataset led to improved modelling performance. Accepted version 2020-06-03T02:31:18Z 2020-06-03T02:31:18Z 2019 Journal Article Zhang, M., Sun, C.-N., Zhang, X., Goh, P. C., Wei, J., Hardacre, D., & Li, H. (2019). High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach. International Journal of Fatigue, 128, 105194-. doi:10.1016/j.ijfatigue.2019.105194 0142-1123 https://hdl.handle.net/10356/140927 10.1016/j.ijfatigue.2019.105194 128 105194 en International Journal of Fatigue © 2019 Elsevier. All rights reserved. This paper was published in International Journal of Fatigue and is made available with permission of Elsevier. application/pdf |
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Engineering::Mechanical engineering Fatigue Additive Manufacturing Zhang, Meng Sun, Chen-Nan Zhang, Xiang Goh, Phoi Chin Wei, Jun Hardacre, David Li, Hua High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| description |
Variations in the high cycle fatigue response of laser powder bed fusion materials can be caused by the choice of processing and post-processing strategies. The numerous influencing factors arising from the process demand an effective and unified approach to fatigue property assessment. This work examines the use of a neuro-fuzzy-based machine learning method for predicting the high cycle fatigue life of laser powder bed fusion stainless steel 316L. A dataset, consisting of fatigue life data for samples subjected to varying processing conditions (laser power, scan speed and layer thickness), post-processing treatments (annealing and hot isostatic pressing) and cyclic stresses, was constructed for simulating a complex nonlinear input-output environment. The associated fracture mechanisms, including the modes of crack initiation and deformation, were characterised. Two models, by employing the processing/post-processing parameters and the static tensile properties respectively as the inputs, were developed from the training data. Despite the diverse fatigue and fracture properties, the models demonstrated good prediction accuracy when checked against the test data, and the computationally-derived fuzzy rules agree well with understanding of the fracture mechanisms. Direct application of the model to literature results, however, yielded a range of prediction accuracies because of the variability in the reported data. Retraining the model by incorporating the literature results into the dataset led to improved modelling performance. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Zhang, Meng Sun, Chen-Nan Zhang, Xiang Goh, Phoi Chin Wei, Jun Hardacre, David Li, Hua |
| format |
Article |
| author |
Zhang, Meng Sun, Chen-Nan Zhang, Xiang Goh, Phoi Chin Wei, Jun Hardacre, David Li, Hua |
| author_sort |
Zhang, Meng |
| title |
High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| title_short |
High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| title_full |
High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| title_fullStr |
High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| title_full_unstemmed |
High cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| title_sort |
high cycle fatigue life prediction of laser additive manufactured stainless steel : a machine learning approach |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/140927 |
| _version_ |
1692012940992970752 |