Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature

A single-crystal plasticity model as well as a gradient crystal plasticity model are used to describe the creep behavior of directionally solidi?ed NiAl based eutectic alloys. To consider the transition from theoretical to bulk strength, a hardening model was introduced to describe the strength of t...

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Egile nagusia: Albiez, Jürgen
Formatua: Online
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Argitaratua: KIT Scientific Publishing 2021
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author Albiez, Jürgen
author_browse Albiez, Jürgen
author_facet Albiez, Jürgen
author_sort Albiez, Jürgen
collection Directory of Open Access Books
description A single-crystal plasticity model as well as a gradient crystal plasticity model are used to describe the creep behavior of directionally solidi?ed NiAl based eutectic alloys. To consider the transition from theoretical to bulk strength, a hardening model was introduced to describe the strength of the reinforcing phases. Moreover, to account for microstructural changes due to material ?ux, a coupled diffusional-mechanical simulation model was introduced.
format Online
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institution Directory of Open Access Books
language eng
publishDate 2021
publishDateRange 2021
publishDateSort 2021
publisher KIT Scientific Publishing
publisherStr KIT Scientific Publishing
record_format ojs
spelling doab-20.500.12854ir-476892024-04-09T23:16:44Z Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature Albiez, Jürgen T1-995 Crystal plasticity Creep Directional solidification Gradient plasticity Finite element simulation Kriechen Gerichtete Erstarrung Finite Elemente Methode Kristallplastizität Gradientenplastizität thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues A single-crystal plasticity model as well as a gradient crystal plasticity model are used to describe the creep behavior of directionally solidi?ed NiAl based eutectic alloys. To consider the transition from theoretical to bulk strength, a hardening model was introduced to describe the strength of the reinforcing phases. Moreover, to account for microstructural changes due to material ?ux, a coupled diffusional-mechanical simulation model was introduced. 2021-02-11T13:43:28Z 2021-02-11T13:43:28Z 2019-07-30 20:02:01 2019 book 35295 2192693X 9783731509189 https://directory.doabooks.org/handle/20.500.12854/47689 eng Schriftenreihe Kontinuumsmechanik im Maschinenbau / Karlsruher Institut für Technologie, Institut für Technische Mechanik - Bereich Kontinuumsmechanik image/jpeg Attribution-ShareAlike 4.0 International https://www.ksp.kit.edu/9783731509189 KIT Scientific Publishing 10.5445/KSP/1000092297 10.5445/KSP/1000092297 68fffc18-8f7b-44fa-ac7e-0b7d7d979bd2 9783731509189 X, 197 p. open access
spellingShingle T1-995
Crystal plasticity
Creep
Directional solidification
Gradient plasticity
Finite element simulation
Kriechen
Gerichtete Erstarrung
Finite Elemente Methode
Kristallplastizität
Gradientenplastizität
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
Albiez, Jürgen
Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title_full Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title_fullStr Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title_full_unstemmed Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title_short Finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
title_sort finite element simulation of dislocation based plasticity and diffusion in multiphase materials at high temperature
topic T1-995
Crystal plasticity
Creep
Directional solidification
Gradient plasticity
Finite element simulation
Kriechen
Gerichtete Erstarrung
Finite Elemente Methode
Kristallplastizität
Gradientenplastizität
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
topic_facet T1-995
Crystal plasticity
Creep
Directional solidification
Gradient plasticity
Finite element simulation
Kriechen
Gerichtete Erstarrung
Finite Elemente Methode
Kristallplastizität
Gradientenplastizität
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
url 35295
work_keys_str_mv AT albiezjurgen finiteelementsimulationofdislocationbasedplasticityanddiffusioninmultiphasematerialsathightemperature