Tribology of Additively Manufactured Materials: Fundamentals, Modeling, and Applications starts with a look at the history, methods and mechanics of additive manufacturing (AM), focusing on power bed fusion-based and direct energy deposition-based additive manufacturing. Following sections of the book provide a foundational background in the fundamentals of tribology, covering the basics of surface engineering, friction and wear, corrosion and tribocorrosion, and the tribological considerations of a variety of AM materials, such as friction and wear in non-metallic and metallic AM materials, degradation in non-metallic AM components, and corrosion and tribocorrosion in AM components.
The book then concludes with a section covering modeling and simulation scenarios and challenges related to the tribology of AM materials, providing readers with the processing conditions needed to extend and strengthen the lifetime and durability of AM materials and components.
- Provides theoretical, experimental and computational data for a better understanding of the complex tribological behaviors in additively manufactured components
- Discusses applications of additively manufactured components, considering their tribological properties
- Studies how unique surface roughness and texture develop in additively manufactured components and how these unique characteristics affect their tribological function
- Outlines variables, additive manufacturing methods and performance of additively manufactured components
- Equips readers with a better understanding of degradation effects due to tribology and corrosion
1. Powder Bed Fusion Based Additive Manufacturing: SLS, SLM, SHS, DMLS
2. Fundamentals of Additive Manufacturing of Metallic Components By Cold Spray Technology
3. Fundamentals of Stereolithography: Techniques, Properties And Applica
4. Additively Manufactured Functionally Graded Metallic Materials: Production, Properties and Applicati
5. Fusion Deposition Modeling: Processes, Properties, and Applications
6. Additive Manufacturing: Process and Microstructure
7. Development of Surface Roughness from Additive Manufacturing Processing Parameters and Post-Processing Surface Modification Techniques
8. Tribology of Additively Manufactured Materials: Fundamentals Modeling, and Applications.
9. Tribology of Additively Manufactured metallic components: Titanium Alloy for Medical Implants
10. Corrosion in Additively Manufactured Cold Sprayed Metallic Deposits
Dr. Pradeep L. Menezes is an Associate Professor in the Department of Mechanical Engineering at the University of Nevada, USA. Before joining this university, he worked as an Adjunct Assistant Professor at the University of WisconsinMilwaukee (UWM), and as a Research Assistant Professor at the University of Pittsburgh. Dr. Menezess productive research career has produced more than several peer-reviewed journal publications book chapters, books related to tribology and a patent. He teaches Introduction to Tribology, Advanced Tribology, Surface Engineering, Introduction to Manufacturing Processes, Mechanical Design, and Engineering Composites. He participated in many national and international conferences in roles such as conference paper reviewer, conference review committee member, conference technical committee member, session chairman, Paper Solicitation Chair and technical session organizer. Manoranjan Misra is a Foundation Professor at the University of Nevada Reno, USA. He has published over 200 journal articles. His research interests are metallurgy, and chemical and material processing. Dr. Pankaj Kumar is an Assistant Professor in the Mechanical Engineering Department at the University of New Mexico, USA. He obtained his doctoral degree in Metallurgical Engineering from the University of Utah, USA. He has published over 30 articles in peer-reviewed journals and served as the journal reviewer for more than 25 journals. He has also served as the guest journal editor, session chair in conferences, book chapter reviewer, grant reviewer, and M.S. and Ph.D. theses committee member. Dr. Kumars research is in the broader areas of advanced manufacturing and materials design for novel structural and functional applications. His research includes material concepts with specific emphasis on advanced manufacturing, materials processing, and physical and mechanical metallurgy. He teaches mechanical engineering design and advanced manufacturing courses to undergraduate and graduate students at the University of New Mexico.
