Kooperativer Bibliotheksverbund

UID:

Format: 1 Online-Ressource : , Illustrationen.

ISBN: 978-0-12-812327-0 , 0-12-812327-3

Note: Includes bibliographical references and index

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-0-12-812155-9

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 0-12-812155-6

Language: English

Subjects: Engineering

Keywords: Rapid Prototyping

DOI: 10.1016/C2016-0-01595-4

URL: Volltext  (URL des Erstveröffentlichers)

URL: Volltext  (URL des Erstveröffentlichers)

URL: Volltext  (URL des Erstveröffentlichers)

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 1 online resource (252 pages)

ISBN: 0-12-822559-9

Content: Multiscale Modeling of Additively Manufactured Metals: Application to Laser Powder Bed Fusion Process provides comprehensive coverage on the latest methodology in additive manufacturing (AM) modeling and simulation. Although there are extensive advances within the AM field, challenges to predictive theoretical and computational approaches still hinder the widespread adoption of AM. The book reviews metal additive materials and processes and discusses multiscale/multiphysics modeling strategies. In addition, coverage of modeling and simulation of AM process in order to understand the process-structure-property relationship is reviewed, along with the modeling of morphology evolution, phase transformation, and defect formation in AM parts. Residual stress, distortion, plasticity/damage in AM parts are also considered, with scales associated with the spatial, temporal and/or material domains reviewed. This book is useful for graduate students, engineers and professionals working on AM materials, equipment, process, development and modeling.

Additional Edition: ISBN 0-12-819600-9

Language: English

UID:

Format: 1 online resource (364 pages)

ISBN: 0-12-812327-3 , 0-12-812155-6

Note: Cover -- Title Page -- Copyright Page -- Contents -- Contributors -- 1 - Overview of additive manufacturing process -- 1 - Additive manufacturing technology -- 2 - The birth of AM and vat photopolymerization -- 3 - New 3D printing technologies -- 3.1 - Fused deposition modeling -- 3.2 - Sheet lamination -- 3.3 - Selective laser sintering -- 3.4 - Material jetting -- 3.5 - Binder jetting -- 4 - Metal 3D printing -- 4.1 - Directed energy deposition -- 4.2 - Powder bed fusion -- 5 - Next-generation 3D printing -- 5.1 - Low-cost plastic -- 5.2 - FDM and sheet lamination with composites -- 5.3 - Vat photopolymerization -- 5.4 - Multi Jet fusion -- 5.5 - New metals -- 5.6 - Hybrid 3D printing -- 5.7 - 3D printing electronics -- 5.8 - Bioprinting -- 5.9 - Additive construction -- 5.10 - 3D printing food -- 5.11 - 3D printing in space -- 6 - Applications -- 6.1 - Visual and functional prototypes -- 6.2 - Tooling -- 6.3 - Example -- 6.3.1 - Patterns, molds, and cores for casting -- 6.3.2 - End parts -- 7 - Future applications -- 7.1 - Bigger -- 7.2 - Faster -- 7.3 - Better -- 7.4 - Easier -- 7.5 - Cheaper -- 7.6 - More complex -- 7.7 - The future -- 8 - Homework: what AM is right for a given project? -- References -- Further Readings -- 2 - Additive manufacturing processes and equipment -- 1 - Introduction -- 2 - Additive manufacturing processes and equipment for polymers -- 2.1 - Stereolithography -- 2.2 - Ink jetting -- 3 - Additive manufacturing processes and equipment for metals -- 3.1 - Powder bed fusion -- 3.2 - Directed energy deposition -- 3.3 - Binder jetting -- 3.4 - Sheet lamination -- 4 - Additive manufacturing processes and equipment for ceramics -- 4.1 - Binder jetting -- 4.2 - Ink jetting -- 4.3 - Stereolithography -- 5 - Other advanced additive manufacturing processes and equipment -- References. , 3 - Additive manufacturing of metallic materials -- 1 - Introduction -- 2 2D printing of metallic materials -- 2.1 Introduction -- 2.2 Metallic particle ink -- 2.3 Thermodynamics and kinetics of nanoparticles -- 2.4 Metallization with nanoparticle inks -- 2.5 Laser sintering -- 2.6 Laser transfer -- 3. 3D printing of metallic materials -- 3.1 Metallic powder -- 3.1.1 Powder bed fusion -- 3.1.2 Powder re-use in powder bed fusion -- 3.1.3 Directed energy deposition -- 3.1.4 Binder jetting and microextrusion of nanoparticles -- 3.1.4.1 - Binder jetting -- 3.1.4.2 - Nanoparticle jetting -- 3.2 - Metal microdroplet -- 3.2.1 Introduction -- 3.2.2 - The nozzle-based method -- 3.2.3 Laser-based printing -- Reference -- 4 - Additive manufacturing of ceramic components -- 1 - Introduction -- 2 - State of additive manufacturing in ceramic manufacturing -- 2.1 - Tape casting -- 2.2 - Slip casting (pressure slip casting) -- 2.3 - Extrusion -- 2.4 - Ceramic injection molding -- Q: Why AM technologies can be seen as an "add-on" to conventional shaping techniques? -- What are the weaknesses and the strengths of AM in comparison to CIM? -- What are the specialties of ceramic AM in comparison to metals or polymers? -- Why AM of ceramic components is still in a very early state of development? -- 3 - Market survey -- Q: Describe the market structure for AM of ceramic components -- What are the market perspectives of ceramic AM when taking into account the state of the art of this technological route? -- 4 - Classification of additive manufacturing methods for ceramics -- 4.1 - Direct versus indirect methods -- Q: What are the advantages and disadvantages of direct and indirect AM for ceramics? -- 4.2 - Direct 3D additive manufacturing of ceramics -- 4.2.1 - Powder-based processes -- 4.2.1.1 - Powder bed binder jet/inkjet 3D printing. , Q: Name three major strategies for binding of ceramic powders in powder bed inkjet 3D printing process -- 4.2.1.2 - Selective Laser Sintering -- Q: Name two inorganic or organic binders that can be used with SLS process for fabrication of ceramics -- 4.2.1.3 - Selective Laser Melting -- Q: Elaborate three reasons that make SLM process a very challenging process for direct fabrication of ceramic materials -- 4.2.1.4 - Pressure assisted 3D printing -- 4.2.2 - Suspension-based processes -- 4.2.2.1 - Stereolithography (laser and digital light projection based) -- Q: Name three advantages and two disadvantages of SLA process for fabrication of high-quality ceramics? -- 4.2.2.2 Laminated Object Manufacturing -- 4.2.2.2 - Robocasting -- 4.2.2.3 - Direct printing -- 4.2.2.4 - Fused deposition modeling -- Q: Elaborate on the differences and similarities in fabrication of ceramics using direct inkjet method, direct filament dep... -- 4.2.2.5 - Layer-wise slurry deposition -- Q: What are the critical aspects that must be taken into consideration for applying LSD technology? -- 4.2.2.6 - 3D screen and stencil printing -- Q: What are the limitations of the above-mentioned AM method? -- Q: What makes 3D screen printing attractive in comparison to other AM techniques? -- 4.2.2.8 Thermoplastic 3D-printing -- Q: Why T3DP has the potential of becoming a breakthrough technology among the suspension-based AM methods? -- 4.2.3 - Precursor-based processes -- Q: What is the difference between SLA and precursor-derived 3D fabrication of ceramics? -- 4.2.4 - Direct melting and deposition -- Q: What 3D method can directly print glass material? Elaborate on the process? -- 4.3 - Indirect 3DAM of ceramics -- 4.3.1 - Benefits of using indirect methods -- 4.3.2 - Methods and materials for 3D additive manufacturing of mold (permanent and sacrificial molds). , Q: What are infiltration methods that are usually used for indirect fabrication of ceramics? -- 5 - Future development trends -- 5.1 - Hybridization of processes and materials -- Q: Which requirements must be met for combining different materials by ceramic AM processes (e.g. material properties, proc... -- 6 - Summary -- Acknowledgements -- References -- 5 - Characterization of fused deposition modeling polymeric structures using embedded fiber Bragg grating sensors -- 1 - Introduction -- 1.1 - The method -- 1.2 - Method drawbacks: the concept of the mesostructure -- 1.3 - Characterizing the FDM-built structures: challenges -- 1.4 - Fiber Bragg grating sensors: working principles -- 2 - Experimental study -- 2.1 - Fiber embedment during printing and process monitoring -- 2.2 - Measurement of fabrication-induced residual strains -- 2.3 - Calculation of the coefficient of the thermal expansion -- 2.4 - Mechanical characterization -- 2.4.1 - Flexural tests -- 2.4.2 - Tensile tests -- 3 - Conclusion -- Acknowledgments -- References -- 6 - Quantification and certification of additive manufacturing materials and processes -- 1 - Introduction -- 1.1 - Barriers to QC of additive manufactured parts -- 1.2 - Strategies for overcoming QC barriers -- 2 - Standards harmonization: an approach to the QC pathway -- 2.1 - Harmonization: one approach to standardization -- 2.2 - Modification of existing standards for AM -- 2.3 - Currently approved standards for AM technologies -- 2.3.1 - Standards addressing terminology -- 2.3.1.1 - ASTM ISO/ASTM52900-15 standard terminology for AM-general principles-terminology -- 2.3.2 - Standards addressing design -- 2.3.2.1 - ISO/ASTM 52915-16 standard specification for additive manufacturing file format (AMF) Version 1.2 -- 2.3.2.2 - ISO/ASTM 52910-17 standard guidelines for design for AM. , 2.3.3 - Standards addressing materials and processes -- 2.3.3.1 - ASTM F2924-14 standard specification for AM titanium-6 aluminum-4 vanadium ((Ti-6Al-4V)) with powder bed fusion -- 2.3.3.2 - ASTM F3001-14 standard specification for AM titanium-6 aluminum-4 vanadium extra low interstitial with powder bed... -- 2.3.3.3 - ASTM F3049-14 standard guide for characterizing the properties of metal powders used for AM processes -- 2.3.3.4 - ASTM F3055-14a standard specification for AM nickel alloy (UNS N07718) with powder bed fusion -- 2.3.3.5 - ASTM F3056-14e1 standard specification for AM nickel alloy (UNS N06625) with powder bed fusion -- 2.3.3.6 - ASTM F3091/F3091M-14 standard specification for the powder bed fusion of plastic materials -- 2.3.3.7 - ASTM F3184-16 standard specification for AM stainless steel alloy (UNS S31603) with powder bed fusion -- 2.3.3.8 - ASTM F3187-16 standard guide for DED of metals -- 2.3.3.9 - ASTM ISO/ASTM52901-16 standard guide for AM-general principles-requirements for purchased AM parts -- 2.3.4 - Standards addressing test methods -- 2.3.4.1 - F2971-13 standard practice for reporting data for test specimens prepared by AM -- 2.3.4.2 - F3122-14 standard guide for evaluating the mechanical properties of metal materials made via AM processes -- 2.3.4.3 - ISO/ASTM 52921-13 standard terminology for AM-coordinate systems and test methodologies -- 3 - Roadmap action plans: approaches to the QC pathway -- 3.1 - Standard guidelines and methods for QC -- 3.2 - Closed-loop process control -- 3.3 - Standards and protocols for round-robin testing -- 3.4 - Shared, standardized third-party data repositories -- 4 - Research and development efforts to support QC of AM: materials & processes -- 4.1 - AM for polymer material systems -- 4.1.1 - AM for thermoplastic polymers -- 4.1.2 - AM for UV-curable polymers -- 4.1.3 - AM for soft polymers. , 4.2 - AM for metal material systems.

Language: English

UID:

Format: 1 Online-Ressource (XII, 286 p. 156 illus., 101 illus. in color)

ISBN: 9783319599069

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-3-319-59905-2

Language: English

Subjects: Engineering

DOI: 10.1007/978-3-319-59906-9

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 1 Online-Ressource (142 p.)

ISBN: 9783036503189 , 9783036503196

Content: TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials

Note: English

Language: English

URL: kostenfrei

UID:

Format: 1 Online-Ressource : , Illustrationen.

ISBN: 978-0-12-812327-0 , 0-12-812327-3

Note: Includes bibliographical references and index

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-0-12-812155-9

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 0-12-812155-6

Language: English

Subjects: Engineering

Keywords: Rapid Prototyping

DOI: 10.1016/C2016-0-01595-4

URL: Volltext  (URL des Erstveröffentlichers)

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 1 electronic resource (142 p.)

Content: TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.

Note: English

Additional Edition: ISBN 3-0365-0318-8

Additional Edition: ISBN 3-0365-0319-6

Language: English

UID:

Format: 1 electronic resource (142 p.)

Content: TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.

Note: English

Additional Edition: ISBN 3-0365-0318-8

Additional Edition: ISBN 3-0365-0319-6

Language: English

UID:

Format: 1 electronic resource (142 p.)

Content: TBC materials in the hot components of a gas turbine are exposed to extremely harsh environments. Therefore, the evaluation of various environmental factors in applying new TBCs is essential. Understanding the mechanisms for degradation which occur in comprehensive environments plays an important role in preventing it and improving the lifetime performance. The development of novel coating techniques can also have a significant impact on lifetime performance as they can alter the microstructure of the coating and alter the various properties resulting from it. This Special Issue presents an original research paper that reports the development of novel TBCs, particularly the application of advanced deposition techniques and novel materials.

Note: English

Additional Edition: ISBN 3-0365-0318-8

Additional Edition: ISBN 3-0365-0319-6

Language: English

UID:

Format: 1 online resource (252 pages)

ISBN: 0-12-822559-9

Content: Multiscale Modeling of Additively Manufactured Metals: Application to Laser Powder Bed Fusion Process provides comprehensive coverage on the latest methodology in additive manufacturing (AM) modeling and simulation. Although there are extensive advances within the AM field, challenges to predictive theoretical and computational approaches still hinder the widespread adoption of AM. The book reviews metal additive materials and processes and discusses multiscale/multiphysics modeling strategies. In addition, coverage of modeling and simulation of AM process in order to understand the process-structure-property relationship is reviewed, along with the modeling of morphology evolution, phase transformation, and defect formation in AM parts. Residual stress, distortion, plasticity/damage in AM parts are also considered, with scales associated with the spatial, temporal and/or material domains reviewed. This book is useful for graduate students, engineers and professionals working on AM materials, equipment, process, development and modeling.

Additional Edition: ISBN 0-12-819600-9

Language: English