Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model

Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model

A Transformation-Induced Plasticity (TRIP) steel matrix reinforced with magnesium-partially stabilized zirconia (Mg-PSZ) particles depicts a superior energy absorbing capacity during deformation. In this research, the TRIP/TWIP material model already developed in the framework of the Düssel...

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Main Authors: Faisal Qayyum, Sergey Guk, Matthias Schmidtchen, Rudolf Kawalla, Ulrich Prahl
Format: Article
Language:English
Published: MDPI AG 2020-03-01
Series:Crystals
Subjects:
trip steel
zirconia composite
numerical simulation
crystal plasticity
local deformation behavior
Online Access:https://www.mdpi.com/2073-4352/10/3/221
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spelling doaj-cb8042b2475145ec871a02743e19f34d2020-11-25T03:29:29ZengMDPI AGCrystals2073-43522020-03-0110322110.3390/cryst10030221cryst10030221Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity ModelFaisal Qayyum0Sergey Guk1Matthias Schmidtchen2Rudolf Kawalla3Ulrich Prahl4Institute of Metal Forming, Technische Universität Bergakademie Freiberg 09599, GermanyInstitute of Metal Forming, Technische Universität Bergakademie Freiberg 09599, GermanyInstitute of Metal Forming, Technische Universität Bergakademie Freiberg 09599, GermanyInstitute of Metal Forming, Technische Universität Bergakademie Freiberg 09599, GermanyInstitute of Metal Forming, Technische Universität Bergakademie Freiberg 09599, GermanyA Transformation-Induced Plasticity (TRIP) steel matrix reinforced with magnesium-partially stabilized zirconia (Mg-PSZ) particles depicts a superior energy absorbing capacity during deformation. In this research, the TRIP/TWIP material model already developed in the framework of the Düsseldorf Advanced Material Simulation Kit (DAMASK) is tuned for X8CrMnNi16-6-6 TRIP steel and 10% Mg-PSZ composite. A new method is explained to more accurately tune this material model by comparing the stress/strain, transformation, twinning, and dislocation glide obtained from simulations with respective experimental acoustic emission measurements. The optimized model with slight modification is assigned to the steel matrix in 10% Mg-PSZ composite material. In the simulation model, zirconia particles are assigned elastic properties with a perfect ceramic/matrix interface. Local deformation, transformation, and the twinning behavior of the steel matrix due to quasi-static tensile load were analyzed. The comparison of the simulation results with acoustic emission data shows good correlation and helps correlate acoustic events with physical attributes. The tuned material models are used to run full phase simulations using 2D Electron Backscatter Diffraction (EBSD) data from steel and 10% Mg-PSZ zirconia composites. Form these simulations, dislocation glide, martensitic transformation, stress evolution, and dislocation pinning in different stages of deformation are qualitatively discussed for the steel matrix and ceramic inclusions.https://www.mdpi.com/2073-4352/10/3/221trip steelzirconia compositenumerical simulationcrystal plasticitylocal deformation behavior
collection DOAJ
language English
format Article
sources DOAJ
author Faisal Qayyum
Sergey Guk
Matthias Schmidtchen
Rudolf Kawalla
Ulrich Prahl
spellingShingle Faisal Qayyum
Sergey Guk
Matthias Schmidtchen
Rudolf Kawalla
Ulrich Prahl
Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
Crystals
trip steel
zirconia composite
numerical simulation
crystal plasticity
local deformation behavior
author_facet Faisal Qayyum
Sergey Guk
Matthias Schmidtchen
Rudolf Kawalla
Ulrich Prahl
author_sort Faisal Qayyum
title Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
title_short Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
title_full Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
title_fullStr Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
title_full_unstemmed Modeling the Local Deformation and Transformation Behavior of Cast X8CrMnNi16-6-6 TRIP Steel and 10% Mg-PSZ Composite Using a Continuum Mechanics-Based Crystal Plasticity Model
title_sort modeling the local deformation and transformation behavior of cast x8crmnni16-6-6 trip steel and 10% mg-psz composite using a continuum mechanics-based crystal plasticity model
publisher MDPI AG
series Crystals
issn 2073-4352
publishDate 2020-03-01
description A Transformation-Induced Plasticity (TRIP) steel matrix reinforced with magnesium-partially stabilized zirconia (Mg-PSZ) particles depicts a superior energy absorbing capacity during deformation. In this research, the TRIP/TWIP material model already developed in the framework of the Düsseldorf Advanced Material Simulation Kit (DAMASK) is tuned for X8CrMnNi16-6-6 TRIP steel and 10% Mg-PSZ composite. A new method is explained to more accurately tune this material model by comparing the stress/strain, transformation, twinning, and dislocation glide obtained from simulations with respective experimental acoustic emission measurements. The optimized model with slight modification is assigned to the steel matrix in 10% Mg-PSZ composite material. In the simulation model, zirconia particles are assigned elastic properties with a perfect ceramic/matrix interface. Local deformation, transformation, and the twinning behavior of the steel matrix due to quasi-static tensile load were analyzed. The comparison of the simulation results with acoustic emission data shows good correlation and helps correlate acoustic events with physical attributes. The tuned material models are used to run full phase simulations using 2D Electron Backscatter Diffraction (EBSD) data from steel and 10% Mg-PSZ zirconia composites. Form these simulations, dislocation glide, martensitic transformation, stress evolution, and dislocation pinning in different stages of deformation are qualitatively discussed for the steel matrix and ceramic inclusions.
topic trip steel
zirconia composite
numerical simulation
crystal plasticity
local deformation behavior
url https://www.mdpi.com/2073-4352/10/3/221
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AT sergeyguk modelingthelocaldeformationandtransformationbehaviorofcastx8crmnni1666tripsteeland10mgpszcompositeusingacontinuummechanicsbasedcrystalplasticitymodel
AT matthiasschmidtchen modelingthelocaldeformationandtransformationbehaviorofcastx8crmnni1666tripsteeland10mgpszcompositeusingacontinuummechanicsbasedcrystalplasticitymodel
AT rudolfkawalla modelingthelocaldeformationandtransformationbehaviorofcastx8crmnni1666tripsteeland10mgpszcompositeusingacontinuummechanicsbasedcrystalplasticitymodel
AT ulrichprahl modelingthelocaldeformationandtransformationbehaviorofcastx8crmnni1666tripsteeland10mgpszcompositeusingacontinuummechanicsbasedcrystalplasticitymodel
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