01310nam0 22003131i 450 UON0031912420231205104132.74128-7106-405-920090113d2006 |0itac50 bafreBE|||| 1||||Henri Michauxdossier dirigé par Véronique Jago-Antoine & Jacques CarionBruxellesLe Cric2006136 p.24 cm.Dono Comunità francese del BelgioIT-UONSI FranceseXI BCAR001UON002387622001 Textylesrevue des lettres belges de langue française210 BruxellesPierre Halen29MICHAUX HENRIUONC042858FIBEBruxellesUONL000128B840.09Letteratura belga. Storia, descrizione, studio critico21CARIONJacquesUONV120948JAGO-ANTOINEVéroniqueUONV125343Le CriUONV267444650ITSOL20240220RICASIBA - SISTEMA BIBLIOTECARIO DI ATENEOUONSIUON00319124SIBA - SISTEMA BIBLIOTECARIO DI ATENEOSI Francese XI B CAR SI DC 959 5 Dono Comunità francese del BelgioHenri Michaux309674UNIOR08573nam 2202401z- 450 9910404089103321202102113-03928-415-0(CKB)4100000011302247(oapen)https://directory.doabooks.org/handle/20.500.12854/40124(oapen)doab40124(EXLCZ)99410000001130224720202102d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierAdditive Manufacturing: Alloy Design and Process InnovationsMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (352 p.)3-03928-414-2 Additive manufacturing (AM) is one of the manufacturing processes that warrants the attention of industrialists, researchers and scientists, because of its ability to produce materials with a complex shape without theoretical restrictions and with added functionalities. There are several advantages to employing additive manufacturing as the primary additive manufacturing process. However, there exist several challenges that need to be addressed systematically. A couple such issues are alloy design and process development. Traditionally alloys designed for conventional cast/powder metallurgical processes were fabricated using advanced AM processes. This is the wrong approach considering that the alloys should be coined based on the process characteristics and meta-stable nature of the process. Hence, we must focus on alloy design and development for AM that suits the AM processes. The AM processes, however, improve almost every day, either in terms of processing capabilities or processing conditions. Hence, the processing part warrants a section that is devoted to these advancements and innovations. Accordingly, the present Special Issue (book) focuses on two aspects of alloy development and process innovations. Here, 45 articles are presented covering different AM processes including selective laser melting, electron beam melting, laser cladding, direct metal laser sintering, ultrasonic consolidation, wire arc additive manufacturing, and hybrid manufacturing. I believe that this Special Issue bears is vital to the field of AM and will be a valuable addition.Additive ManufacturingHistory of engineering and technologybicssc12CrNi2 alloy steel powder2219 aluminum alloy3D metal printing3D printingablationABSadditive manufacturingAdditive manufacturingadditive surface structuringAl-5Si alloyAl-Mg alloyAl-Mg-Si alloyAl-SiAl6061AlSi10MgAlSi10Mg alloyaluminumaluminum alloysamorphous alloyanalytical modelingarc additive manufacturearc additive manufacturingarc currentball millingbulk metallic glassescementcircular economycomposite materialscompositionconcreteconstitutive modelcontinuous carbon fibercontinuous dynamic recrystallizationcrystallographic textureCu50Zr43Al7CuAl2 phasedefectsdeformationdesigndirect metal laser sinteringdisc brakedivisional scanningdynamic characteristicsdynamic propertieselastic abrasiveElectron Beam Meltingelement segregationepitaxial growthepoxy solderequivalent processing modelfatiguefemtosecondfinite element analysisflowabilityfused filament fabricationGH4169grain refinementgraphene nano-sheets (GNSs)gray cast ironH13 tool steelHastelloy X alloyheat treatmenthigh computational efficiencyhot deformationHot Isostatic Pressurehot stamping steel blankshydrophobicityimpactin-process temperature in MPBAMInconel 718inoculationinterfacesintermediate thermo-mechanical treatmentintermetallic compound (IMC)laser claddinglaser cladding depositionlaser energy densitylaser powder bed fusionlaser powder bed fusion (LPBF)laser power absorptionlatent heatlaves phaselocalized inductive heatingM300 mold steelmacro defectsmagnetizermartensitic transformationmechanical propertiesmechanical propertymelt pool sizemetal powdersmetallic glassesMg contentmicrohardness measurementmicrostructural evolutionmicrostructuremicrostructure and propertiesmicrostructuresmillingmodelmolten pool dynamic behaviormolten pool evolutionmulti-laser manufacturingn/anickel alloysnickel-based superalloynumerical analysisnumerical simulationpaint bake-hardeningparameter optimizationparts designperformance characteristicsporosityporosity reductionPowder bedpowder bed fusionpowder flowabilitypowder packingpowder propertiesprecipitatesprocess parametersprocess-dampingpropertiesPSO-BP neural network algorithmpulse frequencyquality of the as-built partsquenching rateradial groovesrapid solidificationrefractory high-entropy alloyregular mixingresidual stressscanningscanning electron microscopy (SEM)scanning strategyselective laser meltingselective laser melting (SLM)side spatterssimulationslagSLM process parametersstability lobe diagramstorage energysubgranular dendritessubstrate preheatingsupport strategyTaguchitailored propertiestemperature and stress fieldstensile strengthtexture evolutionthermal behaviourthermal capillary effectsthermal conductivitythermal stress analysisthermosetting epoxy resinthin-walled weak rigidity partsTi-6Al-4VTi6Al4V alloytitanium alloyultrafast laserultrasonic bondingvalorizationvanadiumvolumetric heat sourcewater absorptionwearwire feeding additive manufacturingwire lateral feedingworkpiece scaleWxNbMoTaHistory of engineering and technologyWang Zhiauth696383Konda Gokuldoss PrashanthauthBOOK9910404089103321Additive Manufacturing: Alloy Design and Process Innovations3024330UNINA