Modeling and simulations of transformation and twinning induced plasticity in advanced high strength austenitic steels

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2 Citations (Scopus)

Abstract

The current work is focused on the development of a combined micromechanical model of transformation and twinning induced plasticity in austenite based steels. Both mechanisms are combined by incorporating transformation in twinning based crystal plasticity model. Initially, mechanical twinning is incorporated in slip based crystal plasticity model. Afterwards, austenite to martensite transformation is included in the developed slip and twin based model. Kinematics of the mechanisms is developed by defining elastic, plastic, and transformation deformation gradients. Energy balanced principle is used to develop thermodynamic framework where dissipated energy and driving potential equations are formed. A fully implicit integration scheme is developed to solve constitutive equations. Numerical integration algorithm is then implemented in ABAQUS as a user-defined subroutine. Three dimensional finite element model of single and polycrystal austenite are developed. The orientation of each grain is defined through Euler angles. The performance of the model is evaluated through finite element simulations to predict elastic-plastic and transformation behaviors of single and polycrystal austenite. The developed model is in good agreement with the published experimental and simulation results. A prominent difference in stress magnitude is found once twinning mode is incorporated in slip and transformation. This difference has significant magnitude in case of polycrystal austenite. This shows substantial advantage in terms of strength and formability of incorporating mechanical twinning along with slip and transformation.

Original languageEnglish
Pages (from-to)83-101
Number of pages19
JournalMechanics of Materials
Volume95
DOIs
Publication statusPublished - Apr 1 2016

Fingerprint

Austenitic steel
Twinning
twinning
high strength
High strength steel
plastic properties
Plasticity
austenite
steels
Austenite
Polycrystals
slip
polycrystals
mechanical twinning
simulation
Plastics
subroutines
Crystals
Steel
elastic deformation

Keywords

  • Constitutive modeling
  • Crystal plasticity
  • Finite element method
  • Martensitic transformation
  • Mechanical twinning
  • Volume fraction of martensite

ASJC Scopus subject areas

  • Instrumentation
  • Materials Science(all)
  • Mechanics of Materials

Cite this

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title = "Modeling and simulations of transformation and twinning induced plasticity in advanced high strength austenitic steels",
abstract = "The current work is focused on the development of a combined micromechanical model of transformation and twinning induced plasticity in austenite based steels. Both mechanisms are combined by incorporating transformation in twinning based crystal plasticity model. Initially, mechanical twinning is incorporated in slip based crystal plasticity model. Afterwards, austenite to martensite transformation is included in the developed slip and twin based model. Kinematics of the mechanisms is developed by defining elastic, plastic, and transformation deformation gradients. Energy balanced principle is used to develop thermodynamic framework where dissipated energy and driving potential equations are formed. A fully implicit integration scheme is developed to solve constitutive equations. Numerical integration algorithm is then implemented in ABAQUS as a user-defined subroutine. Three dimensional finite element model of single and polycrystal austenite are developed. The orientation of each grain is defined through Euler angles. The performance of the model is evaluated through finite element simulations to predict elastic-plastic and transformation behaviors of single and polycrystal austenite. The developed model is in good agreement with the published experimental and simulation results. A prominent difference in stress magnitude is found once twinning mode is incorporated in slip and transformation. This difference has significant magnitude in case of polycrystal austenite. This shows substantial advantage in terms of strength and formability of incorporating mechanical twinning along with slip and transformation.",
keywords = "Constitutive modeling, Crystal plasticity, Finite element method, Martensitic transformation, Mechanical twinning, Volume fraction of martensite",
author = "Rashid Khan and Tasneem Pervez and Qamar, {Sayyad Zahid}",
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AB - The current work is focused on the development of a combined micromechanical model of transformation and twinning induced plasticity in austenite based steels. Both mechanisms are combined by incorporating transformation in twinning based crystal plasticity model. Initially, mechanical twinning is incorporated in slip based crystal plasticity model. Afterwards, austenite to martensite transformation is included in the developed slip and twin based model. Kinematics of the mechanisms is developed by defining elastic, plastic, and transformation deformation gradients. Energy balanced principle is used to develop thermodynamic framework where dissipated energy and driving potential equations are formed. A fully implicit integration scheme is developed to solve constitutive equations. Numerical integration algorithm is then implemented in ABAQUS as a user-defined subroutine. Three dimensional finite element model of single and polycrystal austenite are developed. The orientation of each grain is defined through Euler angles. The performance of the model is evaluated through finite element simulations to predict elastic-plastic and transformation behaviors of single and polycrystal austenite. The developed model is in good agreement with the published experimental and simulation results. A prominent difference in stress magnitude is found once twinning mode is incorporated in slip and transformation. This difference has significant magnitude in case of polycrystal austenite. This shows substantial advantage in terms of strength and formability of incorporating mechanical twinning along with slip and transformation.

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