General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters

General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters

In this study, a promising model is presented to describe the flow stress curves with acceptable accuracy as well as generality. In this model, peak strain, peak stress, steady-state stress and hardening and softening constants are uncoupled and expressed as either bi-linearly interpolated or closed...

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Main Authors: Mohd Kaswandee Razali, Missam Irani, ManSoo Joun
Format: Article
Language:English
Published: Elsevier 2019-05-01
Series:Journal of Materials Research and Technology
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785418310391
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spelling doaj-af05d6e5eed3413882b416c01f00e9e92020-11-25T02:47:09ZengElsevierJournal of Materials Research and Technology2238-78542019-05-018327102720General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parametersMohd Kaswandee Razali0Missam Irani1ManSoo Joun2Gyeongsang National University, Gyeongsangnam-do, Jinju-si, Gajwa-do, Republic of KoreaGyeongsang National University, Gyeongsangnam-do, Jinju-si, Gajwa-do, Republic of KoreaCorresponding author.; Gyeongsang National University, Gyeongsangnam-do, Jinju-si, Gajwa-do, Republic of KoreaIn this study, a promising model is presented to describe the flow stress curves with acceptable accuracy as well as generality. In this model, peak strain, peak stress, steady-state stress and hardening and softening constants are uncoupled and expressed as either bi-linearly interpolated or closed-form functions of temperature and strain rate. A practical method to obtain material constants is developed to render the model applicable in practice, which is based on optimization scheme. The flow stress curves of four materials are obtained using the new model and compared with experiments or the other models at some specific temperatures and strain rates. The comparison has revealed that the new model is feasible and general to describe the flow stress curves of various metals and alloys at different temperatures and strain rates with acceptable accuracy. Keywords: Flow stress model, Closed-form function, Bi-linear interpolation, Softening, Hardeninghttp://www.sciencedirect.com/science/article/pii/S2238785418310391
collection DOAJ
language English
format Article
sources DOAJ
author Mohd Kaswandee Razali
Missam Irani
ManSoo Joun
spellingShingle Mohd Kaswandee Razali
Missam Irani
ManSoo Joun
General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
Journal of Materials Research and Technology
author_facet Mohd Kaswandee Razali
Missam Irani
ManSoo Joun
author_sort Mohd Kaswandee Razali
title General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
title_short General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
title_full General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
title_fullStr General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
title_full_unstemmed General modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
title_sort general modeling of flow stress curves of alloys at elevated temperatures using bi-linearly interpolated or closed-form functions for material parameters
publisher Elsevier
series Journal of Materials Research and Technology
issn 2238-7854
publishDate 2019-05-01
description In this study, a promising model is presented to describe the flow stress curves with acceptable accuracy as well as generality. In this model, peak strain, peak stress, steady-state stress and hardening and softening constants are uncoupled and expressed as either bi-linearly interpolated or closed-form functions of temperature and strain rate. A practical method to obtain material constants is developed to render the model applicable in practice, which is based on optimization scheme. The flow stress curves of four materials are obtained using the new model and compared with experiments or the other models at some specific temperatures and strain rates. The comparison has revealed that the new model is feasible and general to describe the flow stress curves of various metals and alloys at different temperatures and strain rates with acceptable accuracy. Keywords: Flow stress model, Closed-form function, Bi-linear interpolation, Softening, Hardening
url http://www.sciencedirect.com/science/article/pii/S2238785418310391
work_keys_str_mv AT mohdkaswandeerazali generalmodelingofflowstresscurvesofalloysatelevatedtemperaturesusingbilinearlyinterpolatedorclosedformfunctionsformaterialparameters
AT missamirani generalmodelingofflowstresscurvesofalloysatelevatedtemperaturesusingbilinearlyinterpolatedorclosedformfunctionsformaterialparameters
AT mansoojoun generalmodelingofflowstresscurvesofalloysatelevatedtemperaturesusingbilinearlyinterpolatedorclosedformfunctionsformaterialparameters
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