Details
Solid-State Metal Additive Manufacturing
Physics, Processes, Mechanical Properties, and Applications1. Aufl.
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133,99 € |
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| Verlag: | Wiley-VCH |
| Format: | |
| Veröffentl.: | 16.04.2024 |
| ISBN/EAN: | 9783527839339 |
| Sprache: | englisch |
| Anzahl Seiten: | 416 |
DRM-geschütztes eBook, Sie benötigen z.B. Adobe Digital Editions und eine Adobe ID zum Lesen.
Beschreibungen
<b>Solid-State Metal Additive Manufacturing</b> <p> <b>Timely summary of state-of-the-art solid-state metal 3D printing technologies, focusing on fundamental processing science and industrial applications</b> <p><i>Solid-State Metal Additive Manufacturing: Physics, Processes, Mechanical Properties, and Applications </i>provides detailed and in-depth discussion on different solid-state metal additive manufacturing processes and applications, presenting associated methods, mechanisms and models, and unique benefits, as well as a detailed comparison to traditional fusion-based metal additive manufacturing. <p>The text begins with a high-level overview of solid-state metal additive manufacturing with an emphasis on its position within the metal additive manufacturing spectrum and its potential for meeting specific demands in the aerospace, automotive, and defense industries. Next, each of the four categories of solid-state additive technologies—cold spray additive manufacturing, additive friction stir deposition, ultrasonic additive manufacturing, and sintering-based processes—is discussed in depth, reviewing advances in processing science, metallurgical science, and innovative applications. Finally, the future directions of these solid-state processes, especially the material innovation and artificial intelligence aspects, are discussed. <p>Sample topics covered in <i>Solid-State Metal Additive Manufacturing </i>include: <ul><li>Physical processes and bonding mechanisms in impact-induced bonding and microstructures and microstructural evolution in cold sprayed materials</li><li>Process fundamentals, dynamic microstructure evolution, and potential industrial applications of additive friction stir deposition</li><li>Microstructural and mechanical characterization and industrial applications of ultrasonic additive manufacturing</li><li>Principles of solid-state sintering, binder jetting-based metal printing, and sintering-based metal additive manufacturing methods for magnetic materials</li><li>Critical issues inherent to melting and solidification, such as porosity, high residual stress, cast microstructure, anisotropic mechanical properties, and hot cracking</li></ul> <p><i>Solid-State Metal Additive Manufacturing </i>is an essential reference on the subject for academic researchers in materials science, mechanical, and biomedicine, as well as professional engineers in various manufacturing industries, especially those involved in building new additive technologies.
Chapter 1. Overview of State-of-the-art Solid-State Technologies for Metal Additive Manufacturing.<br> Category 1. Cold Spray Additive Manufacturing<br> Chapter 2. Physical processes and bonding mechanisms <br> Chapter 3. Microstructure evolution <br> Chapter 4. Mechanical properties<br> Chapter 5. Cold spray in practical applications<br> Category 2. Additive Friction Stir Deposition<br> Chapter 6. Process fundamentals <br> Chapter 7. Dynamic microstructure evolution <br> Chapter 8. Mechanical properties<br> Chapter 9. Niche applications<br> Category 3. Ultrasonic Additive Manufacturing<br> Chapter 10. Process fundamentals.<br> Chapter 11. Materials innovations.<br> Chapter 12. Industrial applications.<br> Category 4. Sintering-based processes<br> Chapter 13. Principle of solid-state sintering<br> Chapter 14. Extrusion-based metal printing<br> Chapter 15. Binder jetting-based metal printing<br> Chapter 16. Other sintering-based additive processes<br> Chapter 17. Applications of sintering-based metal additive manufacturing<br> Chapter 18. Future Directions<br>
<p><i><b>Hang Z. Yu, PhD, </b> is an Associate Professor in the Department of Materials Science and Engineering at Virginia Tech, USA. His research focuses on materials processing and manufacturing science, emphasizing the underlying process physics, mechanics, and kinetics. His work also aims to leverage the process fundamentals to drive material sustainability to new heights, e.g., via solid-state metal recycling, structural repair, and austere condition-resilient manufacturing.</i> <p><i><b>Nihan Tuncer, PhD, </b> is a Principal Scientist at Desktop Metal Inc. since 2016, where she has been developing solid-state 3D printing technologies and equipment. She holds several patents in addition to research papers and review articles. Her expertise includes powder metallurgy, processing-microstructure-property relationships in ferrous and non-ferrous alloys, porous metals, and shape memory alloys.</i> <p><i><b>Zhili Feng, PhD, </b> currently leads the Materials Joining Group and is a Distinguished R&D Staff Member of Oak Ridge National Laboratory, USA. His research covers various aspects of thermal-mechanical-metallurgical behaviors of materials in materials joining.</i>
<p> <b>Timely summary of state-of-the-art solid-state metal 3D printing technologies, focusing on fundamental processing science and industrial applications</b> <p><i>Solid-State Metal Additive Manufacturing: Physics, Processes, Mechanical Properties, and Applications </i>provides detailed and in-depth discussion on different solid-state metal additive manufacturing processes and applications, presenting associated methods, mechanisms and models, and unique benefits, as well as a detailed comparison to traditional fusion-based metal additive manufacturing. <p>The text begins with a high-level overview of solid-state metal additive manufacturing with an emphasis on its position within the metal additive manufacturing spectrum and its potential for meeting specific demands in the aerospace, automotive, and defense industries. Next, each of the four categories of solid-state additive technologies—cold spray additive manufacturing, additive friction stir deposition, ultrasonic additive manufacturing, and sintering-based processes—is discussed in depth, reviewing advances in processing science, metallurgical science, and innovative applications. Finally, the future directions of these solid-state processes, especially the material innovation and artificial intelligence aspects, are discussed. <p>Sample topics covered in <i>Solid-State Metal Additive Manufacturing </i>include: <ul><li>Physical processes and bonding mechanisms in impact-induced bonding and microstructures and microstructural evolution in cold sprayed materials</li><li>Process fundamentals, dynamic microstructure evolution, and potential industrial applications of additive friction stir deposition</li><li>Microstructural and mechanical characterization and industrial applications of ultrasonic additive manufacturing</li><li>Principles of solid-state sintering, binder jetting-based metal printing, and sintering-based metal additive manufacturing methods for magnetic materials</li><li>Critical issues inherent to melting and solidification, such as porosity, high residual stress, cast microstructure, anisotropic mechanical properties, and hot cracking</li></ul> <p><i>Solid-State Metal Additive Manufacturing </i>is an essential reference on the subject for academic researchers in materials science, mechanical, and biomedicine, as well as professional engineers in various manufacturing industries, especially those involved in building new additive technologies.
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