UID:
almahu_9949983484502882
Format:
1 online resource (328 pages)
ISBN:
0-323-85723-X
Series Statement:
Woodhead Publishing Reviews: Mechanical Engineering
Content:
Innovative Processes and Materials in Additive Manufacturing explains game-changing interdisciplinary applications of recent research breakthroughs in additive manufacturing technology. The number of research publications addressing additive manufacturing has soared in recent years as a range of disciplines explore the possibilities that this technology can provide. This book acts as a bridge between this high-level research and the large number of academics and practitioners looking to additive manufacturing for innovative solutions, providing them with practical and approachable information. Applications in aerospace, automotive, medical, construction, and food industries are addressed, featuring technical details that will help successful implementation. This unique book also provides broad coverage of the theory behind this emerging technology, including material development, as well as the technical details required for readers to investigate the novel applications of the involved methods for themselves.
Note:
Front cover -- Half title -- Title -- Copyright -- Contents -- Contributors -- Preface -- Chapter 1 On quality characteristics of additively manufactured polypropylene (PP) -- 1.1 Introduction -- 1.2 Materials and methods -- 1.3 Result & -- discussion -- 1.3.1 Effect of shrinkage on length -- 1.3.2 Effect of shrinkage on thickness -- 1.3.3 Effect of shrinkage on width -- 1.3.4 Effect of orientation -- 1.3.5 Effect of layer thickness -- 1.3.6 Effect of head scan speed -- 1.3.7 Effect of infill patterns -- 1.3.8 Effect of infill density -- 1.3.9 Effect of shell wall thickness -- 1.4 Conclusion -- References -- Chapter 2 Effect of post-heat treatment on the properties of additive manufacturing parts -- 2.1 Introduction -- 2.2 Methodology -- 2.3 Literature review -- 2.4 Heat treatments -- 2.5 Residual stresses -- 2.6 Conclusions and remarks -- References -- Chapter 3 Parametric design and stress analysis of 3D printed prosthetic finger -- 3.1 Introduction -- 3.2 Research background -- 3.3 Research methods -- 3.3.1 Finger and hand anthropometry data -- 3.4 Finite element analysis -- 3.4.1 Pre-processing stage involves -- 3.4.2 Plan arrange includes -- 3.4.3 Postprocessing stage involves -- 3.5 Regression models of carbon fiber, nylon polyamide, and PLA materials used in 3D printer -- 3.5.1 Analysis of the regression model for fiber (F-1-F-3) -- 3.5.2 Implications and future directions -- 3.6 Conclusion -- Declaration of conflicting interests -- Funding -- References -- Chapter 4 3D printing with biomaterials: A prospective view for biomedical applications -- 4.1 Introduction -- 4.1.1 Evolution of 3D printing -- 4.1.2 Biomaterials -- 4.2 Overview of 3D printing technologies -- 4.2.1 Extrusion-based methods -- 4.2.2 Optical-based (photopolymerization) methods -- 4.2.3 Particle fusion-based 3D printing methods -- 4.2.4 Inkjet printing.
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4.3 Material selection and its advantages -- 4.4 Conclusion -- References -- Chapter 5 Hydrogels for additive manufacturing in scaffolding applications: A review -- 5.1 Background -- 5.2 Hydrogels in additive manufacturing -- 5.3 Natural, synthetic, and hybrid hydrogels -- 5.3.1 Natural hydrogels -- 5.3.2 Synthetic hydrogels -- 5.3.3 Hybrid hydrogels -- 5.4 Stimulus responsive hydrogels -- 5.4.1 Biological stimuli-responsive hydrogels -- 5.4.2 Physical stimuli-responsive hydrogels -- 5.4.3 Chemical stimuli-responsive hydrogels -- 5.5 Cross-linked hydrogels -- 5.5.1 Physical/temporary hydrogels -- 5.5.2 Chemical/permanent hydrogels -- 5.6 Conventional versus smart hydrogels -- 5.6.1 Conventional hydrogels -- 5.6.2 Smart hydrogels -- 5.7 Co-polymeric, homopolymeric, and interpenetrating hydrogels -- 5.7.1 Homopolymeric hydrogels -- 5.7.2 Co-polymeric hydrogels -- 5.7.3 Interpenetrating hydrogels -- 5.8 Cationic, anionic, and non-ionic hydrogels -- 5.8.1 Cationic hydrogels -- 5.8.2 Anionic hydrogels -- 5.8.3 Non-ionic hydrogels -- 5.9 Processing methodology of innovative biological hydrogels for additive manufacturing of scaffolds -- 5.10 Summary -- Acknowledgment -- References -- Chapter 6 From Drosophila material to functional structures: Biomimetic through additive manufacturing technology -- 6.1 Biomimetics in additive manufacturing -- 6.2 Background -- 6.3 Additive manufacturing of functional structures -- 6.4 Functional biomaterials in additive manufacturing -- 6.5 Insects in biomimetics -- 6.6 Drosophila as a biomaterial in additive manufacturing -- 6.7 Future aspects of Drosophila biomaterials for additive manufacturing -- 6.8 Summary -- Acknowledgment -- References -- Chapter 7 Three-dimensional printing against COVID-19: Addressing supply shortages -- 7.1 Introduction -- 7.2 3D printing: supplies medical gears against COVID-19.
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7.2.1 Personal protective equipment -- 7.2.2 Ventilators and respiratory -- 7.2.3 Medicine -- 7.2.4 Supply chain -- 7.2.5 3D printing of test swabs -- 7.3 Conclusions -- References -- Chapter 8 Improving the communication of 4D printing between engineers and designers -- 8.1 Introduction -- 8.2 Communicating 4D printing -- 8.3 Using standardized symbols for 4D printing -- Conclusions -- References -- Chapter 9 Comparative analysis of concrete 3D printing and conventional construction technique for housing -- 9.1 Introduction -- 9.2 Factors affecting the cost of concrete 3D printing -- 9.2.1 Material -- 9.2.2 Machine -- 9.2.3 Manpower -- 9.3 Review of literature -- 9.4 Methods and materials -- 9.4.1 Cost of material for concrete 3D printing (C3DP) -- 9.4.2 Cost of machinery for concrete 3D printing -- 9.4.3 Cost of manpower for concrete 3D printing -- 9.4.4 Cost of civil structure for conventional construction technique -- 9.4.5 Project duration of C3DP -- 9.5 Results and future scope -- References -- Chapter 10 Wire arc additive manufacturing: A comprehensive review on methodologies and processes to overcome challenges with metallic alloys -- 10.1 Introduction -- 10.2 Challenges associated with WAAM material processing -- 10.3 Types of primary processes associated with WAAM -- 10.4 Additional processes involved in WAAM -- 10.4.1 Processes dependent on oscillations -- 10.4.2 Oscillations caused due to different wire feeder-based mechanisms -- 10.4.3 Workpiece-based oscillations -- 10.4.4 Processes based on movement of heat transfer -- 10.4.5 Processes based upon cold-work -- 10.4.6 Processes based on removing material -- 10.5 Metals used in WAAM process -- 10.5.1 Titanium -- 10.5.2 Aluminum and steel alloys -- 10.5.3 Nickel superalloys -- 10.5.4 Other metals -- 10.6 Defects observed in WAAM processes -- 10.6.1 Deformation and residual stresses.
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10.6.2 Porosity -- 10.6.3 Delamination and cracking -- 10.7 Improving quality of WAAM process -- 10.7.1 Heat treatment involved during post-processing -- 10.7.2 Cold rolling inter-pass process -- 10.7.3 Colling with inter-pass -- 10.7.4 Ultrasonic impact and penning treatment methods -- 10.8 Scope of improvement and conclusion -- References -- Chapter 11 Insights of extrusion-based polymer additive manufacturing technology -- 11.1 Introduction -- 11.2 Types of additive manufacturing processes -- 11.3 Fused deposition modeling process -- 11.4 Components of FDM -- 11.4.1 Extrusion head -- 11.4.2 Build platform -- 11.4.3 Printing materials -- 11.4.4 Microprocessor and software -- 11.5 Applications of FDM -- 11.6 Conclusions -- Acknowledgment -- References -- Chapter 12 Orthopaedic application of biomaterials: A study -- 12.1 Introduction -- 12.2 History of orthopaedic application of biomaterials -- 12.2.1 First-generation biomaterials -- 12.2.2 Second-generation biomaterials -- 12.3 Bioceramic biomaterials -- 12.4 Biomaterials with antibacterial and osteogenic properties -- 12.5 Conclusion -- 12.6 Future scope -- References -- Chapter 13 On 3D printing assisted fabrication of dental crowns for veterinary patients -- 13.1 Introduction -- 13.2 Material selection and crown design -- 13.3 Manufacturing methods -- 13.3.1 CAD assisted IC -- 13.4 Case study for preparation of dental crown of veterinary patient -- 13.5 Conclusions -- 13.6 Scope for future work -- Acknowledgment -- References -- Chapter 14 4D printing for product development: State of the art and future scope -- 14.1 Introduction -- 14.2 Shape changes -- 14.3 Shape transformations -- 14.4 Applications -- 14.5 Discussion -- References -- Index -- Back cover.
Additional Edition:
Print version: Singh, Sunpreet Innovative Processes and Materials in Additive Manufacturing San Diego : Elsevier Science & Technology,c2022 ISBN 9780323860116
Language:
English
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