Additive Manufacturing (AM) for Advanced Materials and Structures Green and Intelligent Development Trend

Additive manufacturing (AM), as an advanced manufacturing technology, has overturned the traditional concept of subtractive manufacturing. It has revolutionized advanced integrated structural design, high-performance material preparation, and the manufacturing of complex components. AM technology is...

Full description

Bibliographic Details
Main Author: Yi, Hao
Other Authors: Cao, Huajun, Liu, Menglin, Jia, Le
Format: eBook
Language:English
Published: Basel MDPI - Multidisciplinary Digital Publishing Institute 2023
Subjects:
N/a
Cfa
Online Access:
Collection: Directory of Open Access Books - Collection details see MPG.ReNa
LEADER 05908nma a2201465 u 4500
001 EB002157340
003 EBX01000000000000001295455
005 00000000000000.0
007 cr|||||||||||||||||||||
008 230515 ||| eng
020 |a books978-3-0365-6334-3 
020 |a 9783036563350 
020 |a 9783036563343 
100 1 |a Yi, Hao 
245 0 0 |a Additive Manufacturing (AM) for Advanced Materials and Structures  |h Elektronische Ressource  |b Green and Intelligent Development Trend 
260 |a Basel  |b MDPI - Multidisciplinary Digital Publishing Institute  |c 2023 
300 |a 1 electronic resource (304 p.) 
653 |a machine learning 
653 |a seawater environment 
653 |a accuracy 
653 |a aluminum matrix composites 
653 |a 3D printing 
653 |a lattice structures 
653 |a diamond coating 
653 |a formability 
653 |a microhardness 
653 |a laser powder bed fusion 
653 |a Taylor cone 
653 |a nano-Si3N4 
653 |a History of engineering & technology / bicssc 
653 |a compression 
653 |a non-metallic inclusions 
653 |a nanomechanical properties 
653 |a adaptive neuron-fuzzy methods 
653 |a Technology: general issues / bicssc 
653 |a generation 
653 |a additive manufacturing 
653 |a HVOF spraying 
653 |a joule thermal 
653 |a resin matrix composites 
653 |a artificial neural network 
653 |a fused deposition modeling (FDM) 
653 |a microstructure evolution 
653 |a multiple linear regression 
653 |a imitative full stress method 
653 |a peridynamic method 
653 |a micro-scale wax structure 
653 |a specific sensitivity analysis 
653 |a scaffolds structure 
653 |a laser powder bed fusion (LPBF) 
653 |a laser manufacturing 
653 |a specific energy absorption 
653 |a selective laser melting 
653 |a thin-wall cladding 
653 |a tensile strength 
653 |a femtosecond laser 
653 |a continuous carbon fiber reinforced 
653 |a Se doping silicon 
653 |a diamond structure 
653 |a microstructure 
653 |a spring steel 
653 |a AlSi10Mg 
653 |a ultrafast laser 
653 |a utilization 
653 |a lubricating film 
653 |a special material manufacturing 
653 |a heat treatment 
653 |a wear resistance 
653 |a multiple-crack propagation 
653 |a strain rate sensitivity 
653 |a near-infrared 
653 |a picosecond laser 
653 |a BCCZ 
653 |a functionally graded structure 
653 |a single layer linear grid structure 
653 |a refining slag 
653 |a SLM additive manufacturing 
653 |a 55SiCr steel 
653 |a n/a 
653 |a defects 
653 |a fused deposition modeling 
653 |a strain rate 
653 |a process parameters 
653 |a micro-droplet 
653 |a mathematical model 
653 |a indentation work 
653 |a simulation 
653 |a additive manufacture 
653 |a adhesive wear 
653 |a geometric accuracy 
653 |a cemented carbide 
653 |a high-voltage electric field-driven jet 
653 |a projection stereolithography 
653 |a LPBF 
653 |a laser cladding 
653 |a sensitivity analysis 
653 |a CFA 
653 |a viscous drag force 
653 |a corrosion resistance 
653 |a tribological performance 
653 |a Polycaprolactone (PCL) 
653 |a NiCoCrAlYCe coatings 
653 |a mechanical properties 
653 |a FeCrAl alloy 
653 |a powder bed fusion 
653 |a high temperature viscosity 
653 |a composite alloy powder 
700 1 |a Cao, Huajun 
700 1 |a Liu, Menglin 
700 1 |a Jia, Le 
041 0 7 |a eng  |2 ISO 639-2 
989 |b DOAB  |a Directory of Open Access Books 
500 |a Creative Commons (cc), https://creativecommons.org/licenses/by/4.0/ 
028 5 0 |a 10.3390/books978-3-0365-6334-3 
856 4 0 |u https://www.mdpi.com/books/pdfview/book/6584  |7 0  |x Verlag  |3 Volltext 
856 4 2 |u https://directory.doabooks.org/handle/20.500.12854/96639  |z DOAB: description of the publication 
082 0 |a 363 
082 0 |a 576 
082 0 |a 500 
082 0 |a 900 
082 0 |a 333 
082 0 |a 700 
082 0 |a 600 
082 0 |a 620 
520 |a Additive manufacturing (AM), as an advanced manufacturing technology, has overturned the traditional concept of subtractive manufacturing. It has revolutionized advanced integrated structural design, high-performance material preparation, and the manufacturing of complex components. AM technology is changing the way products are developed, produced, and commercialized, leading to disruptive changes in the economy and society. AM technology has received extensive attention and research from the research community since its inception, and it is leading manufacturing technology and continues to be used with great effectiveness in the aerospace industry, automotive industry, medical plant applications, and many other fields. However, the development of additive manufacturing still faces demanding technical challenges; for example, due to insufficient process planning and inadequate process control, many defects are often observed in the products of AM processes, reducing production efficiency and deteriorating product quality. To promote AM technology toward high efficiency, high precision, high performance, and low cost in a green and intelligent direction, many advanced design and manufacturing technologies are in urgent need of further breakthroughs, such as numerical and analytical models for structural design, experimental methods, performance prediction, and process optimization.