| Description |
1 online resource |
| Series |
Additive manufacturing materials and technologies |
| Contents |
Front Cover -- Advances in Additive Manufacturing: Artificial Intelligence, Nature-Inspired, and Biomanufacturing -- Copyright Page -- Contents -- List of contributors -- About the editors -- I. Introduction -- 1 Introduction to additive manufacturing technologies -- 1.1 Introduction -- 1.2 Brief history of additive manufacturing -- 1.3 Classes of additive manufacturing -- 1.3.1 Vat photopolymerization -- 1.3.2 Material jetting -- 1.3.3 Binder jetting process -- 1.3.4 Material extrusion -- 1.3.5 Sheet lamination -- 1.3.6 Powder bed fusion -- 1.3.7 Directed energy deposition (DED) -- 1.4 Areas of application of additive manufacturing -- 1.4.1 Foods and housing -- 1.4.2 Healthcare -- 1.4.3 Automobiles and aerospace -- 1.4.4 Electronics -- 1.4.5 Consumers product and jewelry -- 1.5 Summary -- References -- Further reading -- 2 Trends in additive manufacturing: an exploratory study -- 2.1 Introduction -- 2.2 Research objectives of the chapter -- 2.3 Comparison of additive manufacturing with traditional manufacturing processes -- 2.4 Additive manufacturing -- 2.5 What and why of additive manufacturing -- 2.6 Development trends in additive manufacturing -- 2.7 Classification of additive manufacturing methods based on material characteristics -- 2.7.1 Powder-based additive manufacturing -- 2.7.1.1 Electron beam melting -- 2.7.1.2 Selective laser melting -- 2.7.1.3 Selective laser sintering -- 2.7.1.4 Laser metal deposition -- 2.7.1.5 Three-dimensional printing -- 2.7.2 Liquid-based additive manufacturing -- 2.7.2.1 Multijet modeling -- 2.7.2.2 Rapid freeze prototyping -- 2.7.2.3 Stereolithography -- 2.7.3 Solid-/filament-based additive manufacturing -- 2.7.3.1 Fused deposition Modeling -- 2.7.3.2 Laminated object manufacturing -- 2.7.3.3 Freeze form extrusion fabrication -- 2.8 Extensive capabilities of additive manufacturing in the current scenario |
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2.9 Application areas of additive manufacturing -- 2.9.1 Medical manufacturing -- 2.9.2 Aerospace and automotive manufacturing -- 2.9.3 Architectural and jewelry manufacturing -- 2.10 Challenges being taken up by additive manufacturing -- 2.11 Future applications and technologies of additive manufacturing -- 2.12 Conclusion -- References -- Further reading -- 3 Addictive manufacturing in the Health 4.0 era: a systematic review -- 3.1 Background and introduction -- 3.2 Additive manufacturing process and technologies -- 3.3 Application in the health-care industry -- 3.4 Materials and methods -- 3.4.1 Information sources -- 3.4.2 Search strategy and study selection -- 3.4.3 Data collection process -- 3.5 Results -- 3.6 Discussion -- 3.6.1 Global additive manufacturing market -- 3.6.2 Advantages of additive manufacturing processes -- 3.6.3 Challenges of additive manufacturing processes -- 3.6.4 Role of additive manufacturing during pandemic COVID-19 -- 3.7 Conclusion -- References -- 4 Integration of reverse engineering with additive manufacturing -- 4.1 Introduction -- 4.2 Concept of RE -- 4.3 Product development by RE and AM -- 4.4 Integrating RE with AM -- 4.4.1 Integration of RE and AM by constructing a 3D CAD model from the point cloud and obtaining an STL model for the AM system -- 4.4.1.1 Data acquisition -- 4.4.1.2 Processing of acquired data -- 4.4.1.2.1 Edge-based segmentation -- 4.4.1.2.2 Region-based segmentation -- 4.4.1.2.3 Attributes-based segmentation -- 4.4.1.2.4 Model-based segmentation -- 4.4.1.3 Surface fitting and CAD model construction -- 4.4.2 Integrating RE and AM by direct generation of STL model file from point cloud -- 4.4.3 Integration of RE and AM by Direct Conversion of Data Points to Sliced File -- 4.5 Data digitization techniques in RE -- 4.5.1 Noncontact data acquisition RE techniques |
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4.5.1.1 Active data acquisition techniques -- 4.5.1.2 Passive data acquisition techniques -- 4.5.1.3 Medical imaging RE techniques -- 4.5.1.4 Contact-based RE techniques -- 4.6 Summary -- References -- II. Additive manufacturing technologies -- 5 Recent innovative developments on additive manufacturing technologies using polymers -- 5.1 A brief introduction to AM technologies -- 5.2 AM market and innovation opportunities -- 5.3 Innovative AM technologies -- 5.3.1 AM based on FDM or fused filament fabrication -- 5.3.1.1 Delta, polar, and selective compliance assembly robot arm (SCARA) FDM -- 5.3.1.2 Koala 3D printer -- 5.3.1.3 Continuous 3D printing -- 5.3.1.4 Melt electrospinning/FDM printing -- 5.3.1.5 Multiaxis 3D printing -- 5.3.1.5.1 Rotational axis 3D printing -- 5.3.1.5.2 Multitool 3D printers -- 5.3.1.5.3 3D microwave printing -- 5.3.1.6 Continuous carbon fiber printing -- 5.3.1.7 AddJoining process -- 5.3.1.8 Metal parts extrusion via FDM -- 5.3.1.9 FDM and sintering -- 5.3.2 AM based on VAT photopolymerization: SLA or digital light processing (DLP) -- 5.3.2.1 Micro-SLA and direct laser writing (DLW) -- 5.3.2.2 Computed axial lithography -- 5.3.2.3 Continuous Liquid Interface Production -- 5.3.2.4 Continuous single droplet 3DP -- 5.3.2.5 Freeze-drying DLP -- 5.3.2.6 High area rapid printing -- 5.3.3 AM based on powder bed fusion (PBF) or SLS -- 5.3.3.1 Continuous 3D printing-SLS -- 5.4 Conclusions and future perspective -- Acknowledgments -- References -- 6 Printing file formats for additive manufacturing technologies -- 6.1 Introduction -- 6.2 3D model representation data formats in additive manufacturing techniques -- 6.2.1 Standard tessellation language format -- 6.2.2 Additive manufacturing format -- 6.2.3 3D manufacturing format -- 6.2.4 OBJ format -- 6.2.5 Virtual reality modeling language format -- 6.2.6 Jupiter Tessellation format |
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6.2.7 Extensible 3D format -- 6.2.8 Cubital Facet List format -- 6.2.9 Solid interchange format -- 6.2.10 Surface triangle hinted format -- 6.3 Comparison of 3D model representation data formats -- 6.4 Sliced model representation data formats in additive manufacturing -- 6.4.1 Common layer interface format -- 6.4.2 Layer exchange ASCII format -- 6.4.3 Stereolithography contour format -- 6.4.4 Hewlett Packard Graphics Language format -- 6.4.5 Comparison of sliced model representation data formats in additive manufacturing -- 6.5 Other additive manufacturing interfaces -- 6.5.1 Layered manufacturing interface -- 6.5.2 Rapid prototyping interface -- 6.5.3 Voxel-based modeling method -- 6.6 Data exchange standards utilization in additive manufacturing -- 6.6.1 Standard for the Exchange of Product Model standard -- 6.6.2 Initial graphics exchange specification standard -- 6.7 Discussion -- 6.8 Summary -- References -- 7 Additive manufacturing techniques used for preparation of scaffolds in bone repair and regeneration -- 7.1 Introduction -- 7.2 Scaffold design -- 7.2.1 Computer-aided design-based methods -- 7.2.2 Optimization of topology -- 7.2.3 Reverse modeling -- 7.2.4 Mathematical modeling -- 7.3 Additive manufacturing techniques -- 7.3.1 Selective laser sintering -- 7.3.2 Selective laser melting -- 7.3.3 Extrusion-based printing -- 7.3.4 Fused deposition modeling -- 7.3.5 Electron beam melting -- 7.3.6 Stereolithography -- 7.3.7 Powder inkjet printing -- 7.3.8 Electrospinning -- 7.4 Posttreatments -- 7.4.1 Heat treatment -- 7.4.2 Surface treatment -- 7.4.2.1 Chemical methods of surface modification -- 7.4.2.2 Acid etching -- 7.4.2.3 Electrochemical anodization -- 7.4.3 Coatings -- 7.4.3.1 Inorganic coatings -- 7.4.3.2 Organic biomolecule coatings -- 7.5 Challenges and conclusions -- References |
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8 Cold spray technology: a perspective of nature-inspired feature processing and biomanufacturing by a heatless additive me... -- 8.1 Introduction: a heatless additive method for nature-inspired, bio- and nanofeatures -- 8.2 Cold spraying principle and processing conditions for nanopowders -- 8.3 Development of superhydrophobic properties using the cold spray additive method -- 8.4 Cold spray additive biomanufacturing of biocompatible coating for surgical implant -- 8.5 Concluding remarks on the use of CS as nature-inspired and/or biomanufacturing -- References -- 9 Preprocessing and postprocessing in additive manufacturing -- 9.1 Introduction -- 9.2 Preprocessing in additive manufacturing -- 9.2.1 Preparation of CAD model -- 9.2.2 Conversion to STL file -- 9.2.2.1 Facet orientation rule -- 9.2.2.2 Adjacency rule or vertex-to-vertex rule -- 9.2.3 Diagnosis of STL file error -- 9.2.4 Part orientation -- 9.2.5 Generation/design of support -- 9.2.6 Types of support structure -- 9.2.7 Slicing -- 9.2.8 Generation of tool path pattern and internal hatching pattern -- 9.3 Postprocessing in additive manufacturing -- 9.3.1 Removal of support material -- 9.3.2 Improvement in surface finish -- 9.3.3 Improvement in accuracy -- 9.3.4 Esthetic improvement of additive manufacturing products -- 9.3.5 Modifying property of additive manufacturing products -- 9.4 Summary -- References -- 10 Computer vision based online monitoring technique: part quality enhancement in the selective laser melting process -- 10.1 Introduction -- 10.2 Experimental methods -- 10.2.1 Design of experiment -- 10.2.2 Methods and algorithms of analysis -- 10.2.2.1 Edge detection and analysis -- 10.2.2.2 Greyscale pixel value calculation and analysis -- 10.2.2.3 Clustering classification and analysis -- 10.3 Results and discussion -- 10.3.1 Edge detection analysis |
| Notes |
Description based on online resource; title from digital title page (viewed on February 16, 2023) |
| Subject |
Additive manufacturing.
|
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Manufacturing processes -- Data processing
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Additive manufacturing
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Manufacturing processes -- Data processing
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| Form |
Electronic book
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| Author |
Kumar, Ajay, editor
|
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Mittal, Ravi Kant, editor
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Haleem, Abid, editor
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| ISBN |
9780323918350 |
|
0323918352 |
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