TY - GEN
T1 - Material Fracture Life Prediction Under High Temperature Creep Conditions Using Support Vector Machines And Artificial Neural Networks Techniques
AU - Martinez, Roberto Fernandez
AU - Jimbert, Pello
AU - Callejo, Lorena M.
AU - Barbero, Jose Ignacio
N1 - Publisher Copyright:
© 2021 IEEE.
PY - 2021
Y1 - 2021
N2 - One of the most applied materials to manufacture critical components in power plants are martensitic steels due to their high creep and oxidation resistance. In this work, the fracture life of martensitic steels that are designed based on the P92 standard is modeled in order to better understand the relation between its service life and its composition and its thermal treatment. This feature is usually studied by performing creep tests, although carrying out tests of this type are really cost and time consuming. To solve this problem, a multivariate analysis and a training-testing model methodology were performed using a dataset formed by 344 creep tests with the final goal of obtaining a model to predict the fracture life of the material based on several nonlinear techniques like support vector machines and artificial neural networks. Once the models were defined based on predicting with the better generalization capability to cover the whole scenario of the problem, those were compared to determine which one was the most accurate among them. Finally, it was concluded that the model's performance using the proposed methodology based on artificial neural networks got the most accurate results, achieving low errors of approximately 6.14% when predicting creep behavior under long service times.
AB - One of the most applied materials to manufacture critical components in power plants are martensitic steels due to their high creep and oxidation resistance. In this work, the fracture life of martensitic steels that are designed based on the P92 standard is modeled in order to better understand the relation between its service life and its composition and its thermal treatment. This feature is usually studied by performing creep tests, although carrying out tests of this type are really cost and time consuming. To solve this problem, a multivariate analysis and a training-testing model methodology were performed using a dataset formed by 344 creep tests with the final goal of obtaining a model to predict the fracture life of the material based on several nonlinear techniques like support vector machines and artificial neural networks. Once the models were defined based on predicting with the better generalization capability to cover the whole scenario of the problem, those were compared to determine which one was the most accurate among them. Finally, it was concluded that the model's performance using the proposed methodology based on artificial neural networks got the most accurate results, achieving low errors of approximately 6.14% when predicting creep behavior under long service times.
KW - artificial neural networks
KW - nonlinear regression
KW - support vector machines
KW - validation methodology
KW - Nonlinear regression
KW - Artificial neural networks
KW - Support vector machines
KW - Validation methodology
UR - http://www.scopus.com/inward/record.url?scp=85141355588&partnerID=8YFLogxK
U2 - 10.1109/ICCTA54562.2021.9916603
DO - 10.1109/ICCTA54562.2021.9916603
M3 - Conference contribution
AN - SCOPUS:85141355588
SN - 978-1-6654-7855-7
T3 - 31st International Conference on Computer Theory and Applications, ICCTA 2021 - Proceedings
SP - 127
EP - 132
BT - 31st International Conference on Computer Theory and Applications, ICCTA 2021 - Proceedings
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 31st International Conference on Computer Theory and Applications, ICCTA 2021
Y2 - 11 December 2021 through 13 December 2021
ER -