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Full Description
Microgrids are essential components of next-generation energy grids. A microgrid is a local, integrated energy system comprising interconnected loads and distributed energy resources; they can represent urban or rural districts, islands or local communities. Microgrids can operate in parallel with the main grid or independently in an intentional island mode. When on-site generation is included, intelligent buildings can also function as microgrids. Efficient optimization and control algorithms are crucial for ensuring optimal microgrid performance, making them a continuous focus of research and development in the field of power systems.
The next-generation energy grid and urban environment need to be smart and sustainable to deal with the growing energy demand and achieve environmental goals. In this context, the role of local energy systems at the distribution level, which can represent urban or rural districts, islands or local communities, is crucial.
System Level Control and Optimisation of Microgrids offers a comprehensive and systematic review of developments in this field. The chapters cover topics such as modelling of integrated energy systems and district heating systems, dynamics and control of grid-connected microgrids, frequency regulation, distributed optimization for energy grids, integration of distributed energy resources, transactive energy management for multi-energy microgrids, and laboratory validation. Real-world examples are provided through case studies based on the EUREF Energy Workshop and fog computing-based decentralized energy management.
This book presents a wide range of perspectives from academia and industry on the challenges and solutions in microgrid optimization and control. It serves as a thorough resource for engineers and academics in the control and power systems fields, as well as for graduate students in related disciplines. Advanced control and optimization techniques for microgrids are discussed in depth, with examples and case studies demonstrating their practical application in shaping the future of energy systems.
Contents
Introduction and overview
Part I: Dynamics and modelling
Chapter 1: Modeling of integrated energy systems
Chapter 2: Energy-based modeling and dissipativity analysis of district heating systems
Part II: Frequency control
Chapter 3: Dynamics and control of grid-connected microgrids
Chapter 4: Fully distributed and economic frequency regulation solutions for autonomous microgrids
Part III: Electric energy management
Chapter 5: Distributed optimization for energy grids: a tutorial on ADMM and ALADIN
Chapter 6: Integrating distributed energy resources in real-world sector-coupled microgrids: challenges, strategies, and experimental insights
Part IV: Multi-Energy Management
Chapter 7: Risk-averse transactive energy management for a multi-energy microgrid
Chapter 8: Operation of multi-energy microgrids with laboratory validation
Part V: Case studies
Chapter 9: Electricity market-oriented control of the EUREF Energy Workshop
Chapter 10: A fog computing-based architecture for the decentralized energy management of microgrids
