Chapter 1: Introduction.- Chapter 2: Mathematical modeling of manufacturing processes.- Chapter 3: Numerical modeling and experimentation.- Chapter 4: Manufacturing processes with phase change.- Chapter 5: Continuous materials processing.- Chapter 6: Polymer processing.- Chapter 7: Thin film deposition: micro/nanoscale fabrication.- Chapter 8: Manufacture of optical fibers: drawing and coating processes.- Chapter 9: Other manufacturing processes.- Chapter 10: Simulation, design and optimization of manufacturing systems.
Dr. Yogesh Jaluria is Board of Governors Professor and Distinguished Professor at Rutgers University, New Jersey. He is the author/co-author of eight books and editor/coeditor of thirteen conference proceedings, eight books, and seven special issues of archival journals. He has contributed over 500 technical articles, including over 210 in archival journals and 20 book chapters. He has received the prestigious 2007 Kern Award from AIChE, the 2003 Robert Henry Thurston Lecture Award from ASME, and the 2002 Max Jakob Memorial Award, the highest international recognition in heat transfer, from ASME and the AIChE. He received the 2000 Freeman Scholar Award, the 1999 Worcester Reed Warner Medal and the 1995 Heat Transfer Memorial Award all from ASME. He was the Editor of the Journal of Heat Transfer (2005-2010), and Computational Mechanics (2003-2005). He is an Honorary Member of ASME, a Fellow of AAAS and APS, and an Associate Fellow of AIAA. He is currently the President of the American Society of Thermal and Fluids Engineers.
This book focuses on advanced processing of new and emerging materials, and advanced manufacturing systems based on thermal transport and fluid flow. It examines recent areas of considerable growth in new and emerging manufacturing techniques and materials, such as fiber optics, manufacture of electronic components, polymeric and composite materials, alloys, microscale components, and new devices and applications. The book includes analysis, mathematical modeling, numerical simulation and experimental study of processes for prediction, design and optimization. It discusses the link between the characteristics of the final product and the basic transport mechanisms and provides a foundation for the study of a wide range of manufacturing processes.
Focuses on new and advanced methods of manufacturing and materials processing with traditional methods described in light of the new approaches;
Maximizes reader understanding of the fundamentals of how materials change, what transport processes are involved, and how these can be simulated and optimized - concepts not covered elsewhere;
Introduces new materials and applications in manufacturing and summarizes traditional processing methods, such as heat treatment, extrusion, casting, injection molding, and bonding, to show how they have evolved and how they could be used for meeting the challenges that we face today.