LEADER 04125nam  2201033z- 450 
001 9910557443403321
005 20231214133553.0
035   $a(CKB)5400000000043288
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69369
035   $a(EXLCZ)995400000000043288
100   $a20202105d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aProgress in Metal Additive Manufacturing and Metallurgy
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (224 p.)
311   $a3-03943-663-5 
311   $a3-03943-664-3 
330   $aThe advent of additive manufacturing (AM) processes applied to the fabrication of structural components creates the need for design methodologies supporting structural optimization approaches that take into account the specific characteristics of the process. While AM processes enable unprecedented geometrical design freedom, which can result in significant reductions of component weight, on the other hand they have implications in the fatigue and fracture strength due to residual stresses and microstructural features. This is linked to stress concentration effects and anisotropy that still warrant further research. This Special Issue of Applied Sciences brings together papers investigating the features of AM processes relevant to the mechanical behavior of AM structural components, particularly, but not exclusively, from the viewpoints of fatigue and fracture behavior. Although the focus of the issue is on AM problems related to fatigue and fracture, articles dealing with other manufacturing processes with related problems are also be included.
606   $aHistory of engineering & technology$2bicssc
610   $aresidual stress/strain
610   $aelectron beam melting
610   $adiffraction
610   $aTi-6Al-4V
610   $aelectron backscattered diffraction
610   $aX-ray diffraction
610   $aSelective Laser Melting
610   $aTi6Al4V
610   $aresidual stress
610   $adeformation
610   $apreheating
610   $arelative density
610   $apowder degradation
610   $awire and arc additive manufacturing
610   $aadditive manufacturing
610   $amicrostructure
610   $amechanical properties
610   $aapplications
610   $aFe-based amorphous coating
610   $alaser cladding
610   $aproperty
610   $atitanium
610   $amicrostructural modeling
610   $ametal deposition
610   $afinite element method
610   $adislocation density
610   $avacancy concentration
610   $adirected energy deposition
610   $adefects
610   $ahardness
610   $aalloy 718
610   $ahot isostatic pressing
610   $apost-treatment
610   $aAlloy 718
610   $asurface defects
610   $aencapsulation
610   $acoating
610   $afatigue crack growth (FCG)
610   $aelectron beam melting (EBM)
610   $ahydrogen embrittlement (HE)
610   $awire arc additive manufacturing
610   $aprecipitation hardening
610   $aAl?Zn?Mg?Cu alloys
610   $amicrostructure characterisation
610   $atitanium alloy
610   $aTi55511
610   $asynchrotron
610   $aXRD
610   $amicroscopy
610   $aSLM
610   $aEBM
610   $aEBSD
610   $aRietveld analysis
610   $aWAAM
610   $aGMAW
610   $aenergy input per unit length
610   $aprocessing strategy
610   $acontact tip to work piece distance
610   $aelectrical stickout
615  7$aHistory of engineering & technology
700   $aPederson$b Robert$4edt$01323410
702   $aPederson$b Robert$4oth
906   $aBOOK
912   $a9910557443403321
996   $aProgress in Metal Additive Manufacturing and Metallurgy$93035518
997   $aUNINA