Autore: |
Wang Zhi
|
Titolo: |
Additive Manufacturing: Alloy Design and Process Innovations . Vol. 2
|
Pubblicazione: |
MDPI - Multidisciplinary Digital Publishing Institute, 2020 |
Descrizione fisica: |
1 electronic resource (352 p.) |
Soggetto non controllato: |
microstructure |
|
slag |
|
crystallographic texture |
|
epoxy solder |
|
additive manufacturing |
|
substrate preheating |
|
thermosetting epoxy resin |
|
AlSi10Mg alloy |
|
impact |
|
residual stress |
|
stability lobe diagram |
|
laves phase |
|
vanadium |
|
selective laser melting (SLM) |
|
molten pool dynamic behavior |
|
scanning strategy |
|
pulse frequency |
|
thin-walled weak rigidity parts |
|
scanning |
|
aluminum |
|
elastic abrasive |
|
2219 aluminum alloy |
|
Powder bed |
|
ABS |
|
laser energy density |
|
equivalent processing model |
|
composition |
|
numerical analysis |
|
scanning electron microscopy (SEM) |
|
Hastelloy X alloy |
|
regular mixing |
|
texture evolution |
|
graphene nano-sheets (GNSs) |
|
Electron Beam Melting |
|
powder bed fusion |
|
microstructural evolution |
|
Mg content |
|
cement |
|
bulk metallic glasses |
|
grain refinement |
|
Taguchi |
|
intermediate thermo-mechanical treatment |
|
valorization |
|
microstructure and properties |
|
arc current |
|
high computational efficiency |
|
powder properties |
|
dynamic characteristics |
|
composite materials |
|
CuAl2 phase |
|
rapid solidification |
|
magnetizer |
|
M300 mold steel |
|
circular economy |
|
titanium alloy |
|
Al-5Si alloy |
|
Al-Mg-Si alloy |
|
ultrasonic bonding |
|
water absorption |
|
disc brake |
|
support strategy |
|
inoculation |
|
arc additive manufacture |
|
3D metal printing |
|
ultrafast laser |
|
Hot Isostatic Pressure |
|
arc additive manufacturing |
|
continuous carbon fiber |
|
performance characteristics |
|
process-damping |
|
intermetallic compound (IMC) |
|
interfaces |
|
direct metal laser sintering |
|
porosity |
|
nickel-based superalloy |
|
element segregation |
|
hydrophobicity |
|
H13 tool steel |
|
Cu50Zr43Al7 |
|
metal powders |
|
parameter optimization |
|
side spatters |
|
powder packing |
|
3D printing |
|
precipitates |
|
simulation |
|
laser cladding deposition |
|
melt pool size |
|
quenching rate |
|
Al-Mg alloy |
|
tailored properties |
|
workpiece scale |
|
fatigue |
|
laser cladding |
|
Ti-6Al-4V |
|
deformation |
|
quality of the as-built parts |
|
model |
|
milling |
|
wire feeding additive manufacturing |
|
martensitic transformation |
|
ball milling |
|
Inconel 718 |
|
ablation |
|
in-process temperature in MPBAM |
|
subgranular dendrites |
|
porosity reduction |
|
femtosecond |
|
paint bake-hardening |
|
Al6061 |
|
defects |
|
continuous dynamic recrystallization |
|
wear |
|
Additive manufacturing |
|
volumetric heat source |
|
Ti6Al4V alloy |
|
AlSi10Mg |
|
radial grooves |
|
GH4169 |
|
temperature and stress fields |
|
laser powder bed fusion |
|
metallic glasses |
|
numerical simulation |
|
latent heat |
|
divisional scanning |
|
wire lateral feeding |
|
laser powder bed fusion (LPBF) |
|
heat treatment |
|
thermal behaviour |
|
fused filament fabrication |
|
microstructures |
|
thermal conductivity |
|
12CrNi2 alloy steel powder |
|
tensile strength |
|
hot stamping steel blanks |
|
multi-laser manufacturing |
|
aluminum alloys |
|
additive surface structuring |
|
parts design |
|
process parameters |
|
thermal stress analysis |
|
SLM process parameters |
|
nickel alloys |
|
Al-Si |
|
powder flowability |
|
laser power absorption |
|
refractory high-entropy alloy |
|
localized inductive heating |
|
mechanical properties |
|
selective laser melting |
|
storage energy |
|
concrete |
|
mechanical property |
|
gray cast iron |
|
constitutive model |
|
analytical modeling |
|
hot deformation |
|
epitaxial growth |
|
design |
|
flowability |
|
amorphous alloy |
|
PSO-BP neural network algorithm |
|
molten pool evolution |
|
microhardness measurement |
|
macro defects |
|
thermal capillary effects |
|
finite element analysis |
|
dynamic properties |
|
WxNbMoTa |
|
properties |
Persona (resp. second.): |
Konda GokuldossPrashanth |
Sommario/riassunto: |
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. |
Altri titoli varianti: |
Additive Manufacturing |
Titolo autorizzato: |
Additive Manufacturing: Alloy Design and Process Innovations |
ISBN: |
3-03928-415-0 |
Formato: |
Materiale a stampa |
Livello bibliografico |
Monografia |
Lingua di pubblicazione: |
Inglese |
Record Nr.: | 9910404089103321 |
Lo trovi qui: | Univ. Federico II |
Opac: |
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