This book describes the behavior, underlying principles and design of self-healing materials, structures, machines, and systems.
This book describes the behavior, underlying principles and design of self-healing materials, structures, machines, and systems. Self-healing is a ubiquitous phenomenon that appears in many systems ranging from the molecular scale up through to large macroscale systems and in domains ranging from materials such as self-healing polymers, to self-sealing tires, water distribution networks, and information systems including control systems for damaged aircraft. Self-healing extends performance and endurance in ways that are just not possible otherwise. This book presents a unifying holistic approach to the operation and design of self-healing systems. It acts as a valuable reference for students, researchers, and engineers that are interested in understanding self-healing mechanisms and acquiring techniques to extend the performance and endurance of the structures, machines and systems that they build, design and study.
Key Features:
- Describes the design, operating principles, manufacture and performance assessment of self-healing materials, structures, machines, and systems.
- Presents a unique holistic approach to the engineering and inclusion of self-healing into structures, machines, and systems.
- Topics covered includes materials, machines, vessels, structures, networks, and systems, with detailed discussions of polymers, concrete, machinery, pressure vessels, fuel tanks, knives, clothing, lasers, biohybrids, networks, and information systems.
1. Introduction.
2. Molecular Scale Healing.
3. Micro and Nano Scale
Healing.
4. Meso and Macro Scale Healing.
5. Surfaces Healing, Sealing and
Cleaning.
6. Vessels and Containers.
7. Vascular Methods.
8. Multiscale and
Multifunctional Methods.
9. Coordinated Repair.
10. Electronics, Optics and
Functionalized Material Systems.
11. Systems and Networks.
12. Biologic
Hybrids.
13. Design, Performance and Manufacturing.
14. Future Directions.
Appendix A. Acronyms. Appendix B. Patents. Appendix C. Engineering Analysis.
Appendix D. Scaling. References.
Dryver Huston has been an engineering faculty member at the University of Vermont since 1987. His research interests include subsurface sensing, structural health monitoring and electromechanical systems design. Recent research applications include the use of ground penetrating radar, acoustic sensing, and augmented reality to map and assess urban subsurface infrastructure. Dr. Huston authored the book Structural Sensing, Health Monitoring and Performance Evaluation (2010) and has a PhD (1986) and MA (1982) from Princeton University and a BS (1980) from University of Pennsylvania.
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