Metal Plasticity and Fatigue at High Temperature

In several industrial fields (such as automotive, steelmaking, aerospace, and fire protection systems) metals need to withstand a combination of cyclic loadings and high temperatures. In this condition, they usually exhibit an amount—more or less pronounced—of plastic deformation, often accompanied...

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Hoofdauteurs: Srnec Novak, Jelena, Moro, Luciano, Benasciutti, Denis
Formaat: Online
Taal:Engels
Gepubliceerd in: MDPI - Multidisciplinary Digital Publishing Institute 2021
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Online toegang:46090
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author Srnec Novak, Jelena
Moro, Luciano
Benasciutti, Denis
author_browse Benasciutti, Denis
Moro, Luciano
Srnec Novak, Jelena
author_facet Srnec Novak, Jelena
Moro, Luciano
Benasciutti, Denis
author_sort Srnec Novak, Jelena
collection Directory of Open Access Books
description In several industrial fields (such as automotive, steelmaking, aerospace, and fire protection systems) metals need to withstand a combination of cyclic loadings and high temperatures. In this condition, they usually exhibit an amount—more or less pronounced—of plastic deformation, often accompanied by creep or stress-relaxation phenomena. Plastic deformation under the action of cyclic loadings may cause fatigue cracks to appear, eventually leading to failures after a few cycles. In estimating the material strength under such loading conditions, the high-temperature material behavior needs to be considered against cyclic loading and creep, the experimental strength to isothermal/non-isothermal cyclic loadings and, not least of all, the choice and experimental calibration of numerical material models and the selection of the most comprehensive design approach. This book is a series of recent scientific contributions addressing several topics in the field of experimental characterization and physical-based modeling of material behavior and design methods against high-temperature loadings, with emphasis on the correlation between microstructure and strength. Several material types are considered, from stainless steel, aluminum alloys, Ni-based superalloys, spheroidal graphite iron, and copper alloys. The quality of scientific contributions in this book can assist scholars and scientists with their research in the field of metal plasticity, creep, and low-cycle fatigue.
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spelling doab-20.500.12854ir-532502024-04-11T15:10:38Z Metal Plasticity and Fatigue at High Temperature Srnec Novak, Jelena Moro, Luciano Benasciutti, Denis TA1-2040 T1-995 aluminum cast partial constraint n/a fatigue criterion thermo-mechanical fatigue stress relaxation aging behavior stainless steel constitutive models environmentally-assisted cracking initial stress levels slip system-based shear stresses thermomechanical fatigue activation volume engineering design pore distribution experimental set-ups tensile tests elevated temperature creep economy LCF fatigue strength hardening/softening hardness pore accumulation defects kinematic model Sanicro 25 probabilistic design AA7150-T7751 strain rate crack growth models bcc probabilistic Schmid factors isotropic model crack-tip cyclic plasticity anisotropy creep fatigue X-ray micro computer tomography temperature transient effects aluminum-silicon cylinder head spheroidal cast iron Probabilistic modeling pre-strain crack-tip blunting and sharpening high temperature steels lost foam thermal–mechanical fatigue cyclic plasticity flow stress Ni-base superalloy pure fatigue René80 polycrystalline FEA constitutive modelling thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology In several industrial fields (such as automotive, steelmaking, aerospace, and fire protection systems) metals need to withstand a combination of cyclic loadings and high temperatures. In this condition, they usually exhibit an amount—more or less pronounced—of plastic deformation, often accompanied by creep or stress-relaxation phenomena. Plastic deformation under the action of cyclic loadings may cause fatigue cracks to appear, eventually leading to failures after a few cycles. In estimating the material strength under such loading conditions, the high-temperature material behavior needs to be considered against cyclic loading and creep, the experimental strength to isothermal/non-isothermal cyclic loadings and, not least of all, the choice and experimental calibration of numerical material models and the selection of the most comprehensive design approach. This book is a series of recent scientific contributions addressing several topics in the field of experimental characterization and physical-based modeling of material behavior and design methods against high-temperature loadings, with emphasis on the correlation between microstructure and strength. Several material types are considered, from stainless steel, aluminum alloys, Ni-based superalloys, spheroidal graphite iron, and copper alloys. The quality of scientific contributions in this book can assist scholars and scientists with their research in the field of metal plasticity, creep, and low-cycle fatigue. 2021-02-11T19:22:37Z 2021-02-11T19:22:37Z 2020-06-09 16:38:57 2020 book 46090 9783039287703 9783039287710 https://directory.doabooks.org/handle/20.500.12854/53250 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/2284 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03928-771-0 10.3390/books978-3-03928-771-0 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783039287703 9783039287710 220 open access
spellingShingle TA1-2040
T1-995
aluminum cast
partial constraint
n/a
fatigue criterion
thermo-mechanical fatigue
stress relaxation aging behavior
stainless steel
constitutive models
environmentally-assisted cracking
initial stress levels
slip system-based shear stresses
thermomechanical fatigue
activation volume
engineering design
pore distribution
experimental set-ups
tensile tests
elevated temperature
creep
economy
LCF
fatigue strength
hardening/softening
hardness
pore accumulation
defects
kinematic model
Sanicro 25
probabilistic design
AA7150-T7751
strain rate
crack growth models
bcc
probabilistic Schmid factors
isotropic model
crack-tip cyclic plasticity
anisotropy
creep fatigue
X-ray micro computer tomography
temperature
transient effects
aluminum-silicon cylinder head
spheroidal cast iron
Probabilistic modeling
pre-strain
crack-tip blunting and sharpening
high temperature steels
lost foam
thermal–mechanical fatigue
cyclic plasticity
flow stress
Ni-base superalloy
pure fatigue
René80
polycrystalline FEA
constitutive modelling
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
Srnec Novak, Jelena
Moro, Luciano
Benasciutti, Denis
Metal Plasticity and Fatigue at High Temperature
title Metal Plasticity and Fatigue at High Temperature
title_full Metal Plasticity and Fatigue at High Temperature
title_fullStr Metal Plasticity and Fatigue at High Temperature
title_full_unstemmed Metal Plasticity and Fatigue at High Temperature
title_short Metal Plasticity and Fatigue at High Temperature
title_sort metal plasticity and fatigue at high temperature
topic TA1-2040
T1-995
aluminum cast
partial constraint
n/a
fatigue criterion
thermo-mechanical fatigue
stress relaxation aging behavior
stainless steel
constitutive models
environmentally-assisted cracking
initial stress levels
slip system-based shear stresses
thermomechanical fatigue
activation volume
engineering design
pore distribution
experimental set-ups
tensile tests
elevated temperature
creep
economy
LCF
fatigue strength
hardening/softening
hardness
pore accumulation
defects
kinematic model
Sanicro 25
probabilistic design
AA7150-T7751
strain rate
crack growth models
bcc
probabilistic Schmid factors
isotropic model
crack-tip cyclic plasticity
anisotropy
creep fatigue
X-ray micro computer tomography
temperature
transient effects
aluminum-silicon cylinder head
spheroidal cast iron
Probabilistic modeling
pre-strain
crack-tip blunting and sharpening
high temperature steels
lost foam
thermal–mechanical fatigue
cyclic plasticity
flow stress
Ni-base superalloy
pure fatigue
René80
polycrystalline FEA
constitutive modelling
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
topic_facet TA1-2040
T1-995
aluminum cast
partial constraint
n/a
fatigue criterion
thermo-mechanical fatigue
stress relaxation aging behavior
stainless steel
constitutive models
environmentally-assisted cracking
initial stress levels
slip system-based shear stresses
thermomechanical fatigue
activation volume
engineering design
pore distribution
experimental set-ups
tensile tests
elevated temperature
creep
economy
LCF
fatigue strength
hardening/softening
hardness
pore accumulation
defects
kinematic model
Sanicro 25
probabilistic design
AA7150-T7751
strain rate
crack growth models
bcc
probabilistic Schmid factors
isotropic model
crack-tip cyclic plasticity
anisotropy
creep fatigue
X-ray micro computer tomography
temperature
transient effects
aluminum-silicon cylinder head
spheroidal cast iron
Probabilistic modeling
pre-strain
crack-tip blunting and sharpening
high temperature steels
lost foam
thermal–mechanical fatigue
cyclic plasticity
flow stress
Ni-base superalloy
pure fatigue
René80
polycrystalline FEA
constitutive modelling
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
url 46090
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AT moroluciano metalplasticityandfatigueathightemperature
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