Energy Systems Integration for Multi-Energy Systems

This book offers a comprehensive approach to energy systems integration (ESI) that optimizes the design and operation of energy systems, maximizing the benefits of all components while minimizing potential negative impacts. By coordinating the production, distribution, and utilization of energy from diverse sources, ESI ensures the most efficient and cost-effective fulfillment of end-users' needs.

The true value of ESI lies in its ability to harmonize interconnected systems, enabling the production and supply of energy in its various forms to achieve reliability, environmental sustainability, and economic viability at appropriate scales. Through the analysis and design of integrated energy systems, often referred to as multi-energy systems (MES), decision-makers and industry professionals gain valuable insights into the optimal strategies required to fulfill these objectives while considering contextual conditions and operational constraints.

The book explores the design, modeling, supervising, and controlling of energy systems but also examines how these approaches can be seamlessly integrated into future MES through innovative and ESI processes.

Through its comprehensive analysis and forward-thinking approach, this book serves as a vital resource for researchers, practitioners, and policymakers seeking to navigate the complexities of energy systems integration and leverage the potential of renewable energy for a sustainable future.

Is a reference for control-oriented engineers/researchers on multi-energy systems (MES) Highlights green energy, energy integration, and MES Includes examples from a wider range of energy projects in a variety of environments

Auteur

Professor Carlos Ocampo-Martinez has been actively involved in research and development activities pertaining to the management and control of energy systems. His research focuses on model predictive control strategies, distributed optimization approaches for large-scale network management, evolutionary game theory and the management and control of water and energy systems. Prof. Ocampo-Martinez has written more than 100 articles on a variety of issues, including non-centralized control for network systems, model predictive control of complex networks involved in the urban water cycle, and smart manufacturing systems. His research contributions highlight the significance of this book in integration of energy systems since it offers insights into sophisticated control strategies, optimization methods, and the administration of complex energy networks.

Professor Nicanor Quijano is an expert in hierarchical and distributed network optimization methods for control using learning, bio inspired, and game-theoretical techniques for dynamic resource allocation problems, especially those in the fields of energy, water, agriculture, and transportation. His research has mostly concentrated on topics such as real-time management of urban drainage and irrigation systems, dynamic population games for microgrids employing population dynamics, and applications in open-channels irrigation systems. His knowledge in these areas provides relevant insights into the issues and solutions connected with integrating energy vectors as well as the water-energy-food nexus, which is paramount in this sort of research problem. His work has been published in more than a 100 articles in peer-reviewed journals, conferences, and book chapters.

Contenu

Part 1: Introduction to Energy Systems Integration.- Part 2: Demand Response.- Part 3: Water-Energy-Food Nexus.- Part 4: Storage and Hydrogen.- Part 5: Energy Communities.- Part 6: Offshore and Wind Farms.- Part 7: Electric Vehicles and Transportation.- Part 8: Applications.