Application of Machine Learning to predict the mechanical properties of high strength steel at elevated temperatures based on the chemical composition
Application of Machine Learning to predict the mechanical properties of high strength steel at elevated temperatures based on the chemical composition
This paper presents the results obtained using Machine Learning (ML) algorithms to predict the mechanical properties, including ultimate tensile strength, yield strength, 0.2% proof strength and elastic modulus, of high strength steel plate material at elevated temperatures. High strength steels are increasingly used in several areas of construction offering efficient structural solutions with a high strength-to-weight ratio. Safe fire design of these structures relies heavily on accurate prediction of mechanical properties of the material with temperature. The data on elevated temperature mechanical properties collected from the literature experimental tests show a high degree of scatter, implying that they are influenced significantly by various factors, most notably the testing method, manufacturing process and chemical composition. However, the current methods for predicting the mechanical properties of high strength steels at elevated temperatures by using ‘reduction factors’ as adopted by the structural design codes do not consider these effects and may lead to inaccurate predictions. To overcome these deficiencies, a ML-based prediction method that uses temperature and chemical composition as input parameters is developed in this paper. Deep Neural Networks are trained and validated on the basis of elevated temperature material data collated from the literature test programmes. The analysis of the results show that the trained algorithm gives an excellent correlation coefficient with very small error value in predicting the strength and stiffness reduction factors of HSS.
Chemical Composition, Constitutive model, Deep Learning, Elevated temperature, High strength steel, Machine Learning
17-29
Shaheen, Mohamed A.
e4b3a715-84b2-4b42-b428-89123485c796
Presswood, Rebecca Sophie
d432390b-beb2-4f14-801f-5a21e404f96b
Afshan, Sheida
68dcdcac-c2aa-4c09-951c-da4992e72086
June 2023
Shaheen, Mohamed A.
e4b3a715-84b2-4b42-b428-89123485c796
Presswood, Rebecca Sophie
d432390b-beb2-4f14-801f-5a21e404f96b
Afshan, Sheida
68dcdcac-c2aa-4c09-951c-da4992e72086
Shaheen, Mohamed A., Presswood, Rebecca Sophie and Afshan, Sheida
(2023)
Application of Machine Learning to predict the mechanical properties of high strength steel at elevated temperatures based on the chemical composition.
Structures, 52 (6), .
(doi:10.1016/j.istruc.2023.03.085).
Abstract
This paper presents the results obtained using Machine Learning (ML) algorithms to predict the mechanical properties, including ultimate tensile strength, yield strength, 0.2% proof strength and elastic modulus, of high strength steel plate material at elevated temperatures. High strength steels are increasingly used in several areas of construction offering efficient structural solutions with a high strength-to-weight ratio. Safe fire design of these structures relies heavily on accurate prediction of mechanical properties of the material with temperature. The data on elevated temperature mechanical properties collected from the literature experimental tests show a high degree of scatter, implying that they are influenced significantly by various factors, most notably the testing method, manufacturing process and chemical composition. However, the current methods for predicting the mechanical properties of high strength steels at elevated temperatures by using ‘reduction factors’ as adopted by the structural design codes do not consider these effects and may lead to inaccurate predictions. To overcome these deficiencies, a ML-based prediction method that uses temperature and chemical composition as input parameters is developed in this paper. Deep Neural Networks are trained and validated on the basis of elevated temperature material data collated from the literature test programmes. The analysis of the results show that the trained algorithm gives an excellent correlation coefficient with very small error value in predicting the strength and stiffness reduction factors of HSS.
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Submitted date: 1 July 2022
Accepted/In Press date: 15 March 2023
e-pub ahead of print date: 3 April 2023
Published date: June 2023
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Publisher Copyright:
© 2023 The Author(s)
Keywords:
Chemical Composition, Constitutive model, Deep Learning, Elevated temperature, High strength steel, Machine Learning
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Local EPrints ID: 477683
URI: http://eprints.soton.ac.uk/id/eprint/477683
ISSN: 2352-0124
PURE UUID: d8b3b47c-9da6-490f-a57d-d02e6ec40bac
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Date deposited: 13 Jun 2023 16:50
Last modified: 17 Mar 2024 04:08
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Author:
Mohamed A. Shaheen
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