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Comprehensive reference on multi energy hub (MEH) modeling, management, protection, and trading across energy exchange markets with supporting case studies Energy Management Strategies for Multi-Vectored Energy Hubs to Achieve Low Carbon Societies discusses the complex exchange process across different sources within an evolving set of technologies, presenting multi-vectored energy hub (MV-EH) modeling techniques and associated energy management strategies for their network architecture. This includes in-depth assessments of advanced energy conversion technologies, market mechanisms, and transactive energy management to ensure robust and flexible energy-sharing mechanisms. The book focuses on renewable energy integration in MV-EHs, advanced energy storage, and advance energy conversion technologies. Later chapters cover detailed analyses of Power-to-X (P2X) technologies, bioenergy integration, and emerging challenges in high-renewable penetration in energy hubs. Case studies of MV-EHs explore the latest advancements such as the carbon tax mechanism, carbon trading strategies, the role of hydrogen generation, and carbon storage to enhance MV-EH performance. Readers will find insights into the integration of carbon reduction techniques (CDR) and emission trading mechanisms, along with the role of bioenergy in building the low emission energy systems. Mathematical models of various new energy conversion systems such as power to gas (P2X), hydrogen storage, and hydrogen usage are also explored. Edited by a team of highly qualified authors, this book covers additional topics such as:
- Types of frameworks to manage network energy hubs, cooperative and non-cooperative strategies, and centralized, decentralized, and distributed system architectures
- Advanced energy conversion units such as electric heat pumps, combined heat and power units, gas boilers, absorption chillers, electric chillers, and energy storage units
- The role of bioenergy, power-to-X, hydrogen, carbon reduction techniques (CDR), carbon taxes, carbon market, and trading strategies in achieving low energy systems
- Technologies to enhance flexibility in MEHs such as electrical, heating, cooling, and community demand response programs
- The impact of high or full share of renewables and load-side uncertainties on MV-EH operations
Delivering a thorough understanding of networked multi-vectored energy systems, and their role in sustainable energy transitions,
Energy Management Strategies for Multi-Vectored Energy Hubs to Achieve Low Carbon Societies is an essential reference for engineers, researchers, and graduate students developing energy systems, smart grids, and decarbonization strategies.
List of contents
About the Editors
List of Contributors
Preface
Chapter 1: Evaluation of Power/Energy System to the Modern Multi-Vectored Energy Hubs (MV-EHs)
Ankit Garg, K.R. Niazi, S. S. Sahoo, and Shubham Tiwari
Chapter 2: Introduction of Transactive Energy Management in a Multi-Energy Networked System
Ankit Garg, K. R. Niazi, S. S. Sahoo, and Shubham Tiwari
Chapter 3: Energy Management Strategies for Optimal Scheduling of Multi-Energy Network Hubs
Divya Sharma and Naran M. Pindoriya
Chapter 4: Impact of Hydrogen and Power to Gas technology on MV-EHs
S. S. Sahoo, Ankit Garg, K. R. Niazi, and Shubham Tiwari
Chapter 5: Modelling and Analysis of MV-EHs with Advanced Energy Storage Units
R. Shenbagalakshmi, J. Subramaniyan, G. Ramprakash, and V. Vengatesan
Chapter 6: Market and Energy Trading Mechanism in MV-EHs
R. Rajasree, D. Lakshmi, R. Karthickmanoj, K. Stalin, P. Sivaraman, and Sharmeela
Chapter 7: Impact of High or Full Share of RESs and Load Side Uncertainty on Multi Vectored Energy Hubs.
Stephen Oko Gyan Torto, Rupendra Kumar Pachauri, Jai Govind Singh, Nilay Kumar Sarker, and Prasad Kaparaju
Chapter 8: Green Energy, Greener Future: Bioenergy's Role in Carbon Reduction
Nilay Kumar Sarker and Prasad Kaparaju
Chapter 9: Perspectives of Integrating Bioenergy into Energy Mix in Developing Nations: A SWOT Analysis
Toyese Oyegoke
Chapter 10: Integration of Carbon Reduction Techniques (CDR) and Emission Trading Mechanisms among MV-EHs
Mohammad Parhamfar and Saeed Khorrami
About the Editors
About the author
Shubham Tiwari is a Research Scholar at the International Institute of Applied Systems Analysis (IIASA), Austria.
Jai Govind Singh, PhD, is an Associate Professor in Sustainable Energy Transition at the Asian Institute of Technology, Pathum Thani, Thailand.
Sivaraman Palanisamy is an industry professional and also a Research Scholar with the Department of Electrical and Electronics Engineering at CEG Campus, Anna University, Chennai.
Sharmeela Chenniappan, PhD, holds the post of Professor in the Department of Electrical and Electronics Engineering. She is also Adjunct Professor at the Centre of E-Vehicle Technologies, and the Centre for Energy Storage Technologies, CEG Campus, at Anna University, Chennai, India.
Rupendra Kumar Pachauri, PhD, is an Associate Professor in the Electrical Cluster, School of Advanced Engineering, UPES, Dehradun, India.
Sanjeevikumar Padmanaban, PhD, is a faculty member with the Department of Electrical Engineering, IT and Cybernetics at the University of South-Eastern Norway, Porsgrunn, Norway.
