Description
Power System Flexibility provides a consolidated foundation in the design, planning, and operation of intermittent highly renewable power systems—integrating core theory, mathematical analysis, and modern international applications in an unusually multidisciplinary approach. Opening with an expansive theoretical grounding in the definition, analysis, and modeling of power systems, the book demonstrates how to apply flexibility theory to critical problems involving intermittency and variability in power system planning and operation. The guide concludes with an international complement of case studies, demonstrating how flexibility theory has been applied to real-world projects of increasing complexity.- Integrates underlying scientific foundations with modern methods in the planning and operation of flexible power systems- Demonstrates how to design, plan, operationalize, and optimize flexible solutions across the full range of power generation, electrical grids, energy demand, and energy storage applications- Includes an international complement of real-world case studies focusing on delivering flexibility in highly renewable electricity systems
Table of Contents
Part 1: Concepts and Mathematics about Flexibility 1. Introduction to power system flexibility2. Mathematical basis for flexibility modeling3. Concepts and characteristics of power system flexibility4. Flexibility Balancing Principle and Indices5. Flexibility Assessment based on operational simulation6. Flexibility Assessment Tool and Case StudiesPart 2: Incorporating Flexibility into Power System Analysis 7. Active Power Balance Control based on Flexibility Theory8. Reactive Power Balance Control based on Flexibility Theory9. Modeling Flexibility in Electric Power MarketPart 3: The optimal planning of power system flexibility resources 10. Introduction to power system flexibility planning11. Coordinating planning of generation-grid-load-storage flexibility resources12. Integrated planning of collection and delivery system for large scale new energy base13. Collection and transmission flexibility planning for large offshore wind power base14. Deployment and allocation of storage based on flexibility theoryPart 4: The optimal operation of power system flexibility resources 15. Introduction to power system flexibility operation16. Virtual power generator based hierarchical schedule of wind power cluster17. Multi-sources complementary operation considering grid constraints18. Multi-temporal-spatial-scale flexibility to improve renewable accommodation 19. Flexible resource coordination on demand sidePart 5: Planning applications of flexibility theory 20. Planning projects of power system flexibility21. Operation application of flexibility theory22. The sector coupled flexibility resources
