LEADER 04519nam  2201021z- 450 
001 9910404081603321
005 20210211
010   $a3-03928-771-0
035   $a(CKB)4100000011302322
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/53250
035   $a(oapen)doab53250
035   $a(EXLCZ)994100000011302322
100   $a20202102d2020      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aMetal Plasticity and Fatigue at High Temperature
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 online resource (220 p.)
311 08$a3-03928-770-2 
330   $aIn 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.
606   $aHistory of engineering and technology$2bicssc
610   $aAA7150-T7751
610   $aactivation volume
610   $aaluminum cast
610   $aaluminum-silicon cylinder head
610   $aanisotropy
610   $abcc
610   $aconstitutive modelling
610   $aconstitutive models
610   $acrack growth models
610   $acrack-tip blunting and sharpening
610   $acrack-tip cyclic plasticity
610   $acreep
610   $acreep fatigue
610   $acyclic plasticity
610   $adefects
610   $aeconomy
610   $aelevated temperature
610   $aengineering design
610   $aenvironmentally-assisted cracking
610   $aexperimental set-ups
610   $afatigue criterion
610   $afatigue strength
610   $aflow stress
610   $ahardening/softening
610   $ahardness
610   $ahigh temperature steels
610   $ainitial stress levels
610   $aisotropic model
610   $akinematic model
610   $aLCF
610   $alost foam
610   $an/a
610   $aNi-base superalloy
610   $apartial constraint
610   $apolycrystalline FEA
610   $apore accumulation
610   $apore distribution
610   $apre-strain
610   $aprobabilistic design
610   $aProbabilistic modeling
610   $aprobabilistic Schmid factors
610   $apure fatigue
610   $aRene?80
610   $aSanicro 25
610   $aslip system-based shear stresses
610   $aspheroidal cast iron
610   $astainless steel
610   $astrain rate
610   $astress relaxation aging behavior
610   $atemperature
610   $atensile tests
610   $athermal-mechanical fatigue
610   $athermo-mechanical fatigue
610   $athermomechanical fatigue
610   $atransient effects
610   $aX-ray micro computer tomography
615  7$aHistory of engineering and technology
700   $aSrnec Novak$b Jelena$4auth$01331941
702   $aMoro$b Luciano$4auth
702   $aBenasciutti$b Denis$4auth
906   $aBOOK
912   $a9910404081603321
996   $aMetal Plasticity and Fatigue at High Temperature$93040681
997   $aUNINA