Technologies for integrated energy systems and networks / / edited by Giorgio Graditi, Marialaura Di Somma
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| Titolo: |
Technologies for integrated energy systems and networks / / edited by Giorgio Graditi, Marialaura Di Somma
|
| Pubblicazione: | Weinheim, Germany : , : Wiley-VCH GmbH, , [2022] |
| ©2022 | |
| Descrizione fisica: | 1 online resource (329 pages) |
| Disciplina: | 621.042 |
| Soggetto topico: | Renewable resource integration |
| Soggetto genere / forma: | Electronic books. |
| Persona (resp. second.): | GraditiGiorgio |
| Di SommaMarialaura | |
| Nota di bibliografia: | Includes bibliographical references and index. |
| Nota di contenuto: | Cover -- Title Page -- Copyright -- Contents -- Chapter 1 Challenges and Opportunities of the Energy Transition and the Added Value of Energy Systems Integration -- 1.1 Energy Transformation Toward Decarbonization and the Added Value of Energy Systems Integration -- 1.2 European Union as the Global Leader in Energy Transition -- 1.3 Pillars for the Transition Toward Integrated Decentralized Energy Systems -- List of Abbreviations -- References -- Chapter 2 Integrated Energy Systems: The Engine for Energy Transition -- 2.1 Introduction: the Concept of Integrated Energy System -- 2.2 Key Enablers for Integrated Energy Systems -- 2.2.1 Storage and Conversion Technologies -- 2.2.2 End User Engagement and Empowerment -- 2.2.3 Digitalization Enabler -- 2.2.4 Emergence of an Integrated Energy Market -- 2.3 Integrated Energy Systems at the Local Level -- 2.3.1 Conceptualizing Local Integrated Energy Systems -- 2.3.2 Map of Enabling Technologies -- 2.3.3 Key Stakeholders and Related Benefits from Local Integrated Energy Systems Deployment -- 2.4 Main Barriers for Implementation -- 2.4.1 Techno‐economic Barriers -- 2.4.2 Socioeconomic Barriers -- 2.4.3 Policy and Regulatory Barriers -- 2.5 Conclusions -- List of Abbreviations -- References -- Chapter 3 Power Conversion Technologies: The Advent of Power‐to‐Gas, Power‐to‐Liquid, and Power‐to‐Heat -- 3.1 Introduction -- 3.1.1 Motivation for Power‐to‐X -- 3.1.2 Defining Power‐to‐X Categories -- 3.1.3 Goal of this Chapter -- 3.2 Power‐to‐X Technologies -- 3.2.1 Power‐to‐Gas -- 3.2.1.1 Natural Gas Market Demand -- 3.2.1.2 Technology Identification and Overview -- 3.2.1.3 Unique Integration Challenges and Opportunities -- 3.2.2 Power‐to‐Chemicals‐and‐Fuels -- 3.2.2.1 Market and Demand -- 3.2.2.2 Technology Identification and Overview -- 3.2.2.3 Unique Integration Challenges and Opportunities. |
| 3.2.2.4 Implications on Power Generation -- 3.2.3 Power‐to‐Heat -- 3.2.3.1 Market and Demand -- 3.2.3.2 Technology Identification and Overview -- 3.2.3.3 Unique Integration Challenges and Opportunities -- 3.2.3.4 Implications on Power Generation -- 3.3 Overarching Challenges, Opportunities, and Considerations -- 3.3.1 Feedstock and Energy Sourcing -- 3.3.1.1 Feedstocks (CO2, N2, H2O, and Biomass) -- 3.3.1.2 Operational Flexibility for Grid Integration and Revenue -- 3.3.2 Key Considerations from Life Cycle Analysis and Techno‐economic Analysis -- 3.3.2.1 Life Cycle Analysis -- 3.3.2.2 Techno‐Economic Analysis -- 3.3.3 Business Model and Business Innovation -- 3.4 Concluding Remarks -- Disclaimer -- List of Abbreviations -- References -- Chapter 4 Role of Hydrogen in Low‐Carbon Energy Future -- 4.1 Introduction -- 4.2 Main Drivers for Hydrogen Implementation -- 4.2.1 Increasing Penetration of Stochastic Renewable Energy -- 4.2.2 Opportunity of Hydrogen as a Sector Coupling Enabler -- 4.3 Hydrogen Economy and Policy in Europe and Worldwide -- 4.4 Main Renewable Hydrogen Production, Storage, and Transmission/Distribution Schemes -- 4.4.1 Hydrogen Production Pathways -- 4.4.2 Hydrogen Transmission and Distribution -- 4.4.2.1 Main Hydrogen Storage Technologies -- 4.4.2.2 Methods for Hydrogen Transmission and Distribution -- 4.5 Technological Applications in Integrated Energy Systems and Networks -- 4.5.1 Hydrogen as an Energy Storage System for Flexibility at Different Scales -- 4.5.2 Industrial Use as a Renewable Feedstock in Hard‐to‐Abate Sectors and for the Production of Derivates -- 4.5.3 Hydrogen Mobility: A Complementary Solution to Battery Electric Vehicles -- 4.5.4 Fuel Cells, Flexible Electrochemical Conversion Systems for High‐Efficiency Power, and/or CHP Applications -- 4.6 Conclusions -- List of Abbreviations -- References. | |
| Chapter 5 Review on the Energy Storage Technologies with the Focus on Multi‐Energy Systems -- 5.1 Introduction -- 5.2 Energy Storage -- 5.2.1 Main Concept of Energy Storage in the Power System -- 5.2.2 Different Types of Energy Storage Systems -- 5.2.2.1 Electromechanical Energy Storage Systems -- 5.2.2.2 Electromagnetic Energy Storage Systems -- 5.2.2.3 Electrochemical Energy Storage Systems -- 5.2.2.4 Thermal Energy Storage Systems -- 5.2.3 Advantages of Storage in the Energy System -- 5.3 Energy Storage Technology Application in the Multi‐Energy Systems -- 5.4 Conclusion -- List of Abbreviations -- References -- Chapter 6 Digitalization and Smart Energy Devices -- 6.1 Introduction -- 6.2 Our Vision of the Digital Networks -- 6.3 Enabling State‐of‐the‐Art Digital Technologies -- 6.4 Key Digital Use Cases and Associated Benefits -- 6.5 Integrated Digital Platform Across Stakeholders -- 6.6 Key Digital Recommendations -- 6.7 Conclusion -- List of Abbreviations -- References -- Further Reading -- Chapter 7 Smart and Sustainable Mobility Adaptation Toward the Energy Transition -- 7.1 Smart and Sustainable Mobility Definitions and Metrics -- 7.1.1 Sustainable Mobility KPI (Key Performance Indicators) -- 7.1.2 KPI of Urban Mobility in Two European Cities -- 7.2 Smart Mobility Applied to Bicycle Sharing in Urban Context and Impacts on Sustainability -- 7.3 Ground‐Level Ozone Indicator -- 7.4 Energy Transition -- 7.5 Resilience of the Mobility System -- 7.6 Conclusions -- Acknowledgments -- List of Abbreviations -- References -- Chapter 8 Evolution of Electrical Distribution Grids Toward the Smart Grid Concept -- 8.1 Smart Grid Concept -- 8.2 Advanced Metering Infrastructure (AMI) General Description -- 8.3 Communications and Impact on Remote Management -- 8.3.1 PLC PRIME Communication -- 8.3.2 Data Concentrator Unit (DCU) Description. | |
| 8.3.3 Smart Meter Description -- 8.3.4 Future Scenario: Evolution of Communications Toward Hybrid Systems -- 8.4 Central System for Data Reception and Analysis -- 8.4.1 Real‐Time Event Management -- 8.4.2 LV Network Monitoring -- 8.4.3 Automatic Diagnostic -- 8.5 DSO Challenge: AMI for LV Network Management -- 8.6 Digital Twin of the LV Network -- 8.7 Evolution of the Functionalities for LV Network Management -- 8.8 Conclusions -- List of Abbreviations -- References -- Chapter 9 Smart Grids for the Efficient Management of Distributed Energy Resources -- 9.1 Electrical System Toward the Smart Grid Concept -- 9.1.1 Technology Areas of Smart Grids -- 9.1.2 Services and Functionalities of the Smart Grids -- 9.1.2.1 Needs to Integrate New Emerging Technologies -- 9.1.2.2 Improve the Operation of the Network -- 9.1.2.3 New Investment Planning Criteria -- 9.1.2.4 Improve the Functionality of the Market and Services to End Users -- 9.1.2.5 Active Involvement of the End User -- 9.1.2.6 Increased Energy Efficiency and Reduced Environmental Impact -- 9.2 Need of a Multi‐Domain Optimization in Smart Grids -- 9.3 Advanced Control Mechanisms for Smart Grid -- 9.3.1 Architecture and Grid Model -- 9.3.2 Congestion Issues in the TSO Domain -- 9.3.3 Congestion Issues in the DSO Domain -- 9.3.4 Frequency Instability in the TSO Domain -- 9.4 Case Studies -- 9.4.1 Case Study 1: Congestion Events at the Transmission Level -- 9.4.2 Case Study 2: Congestion Events at the Distribution Level -- 9.4.3 Case Study 3: Frequency Instability Issues -- 9.5 Conclusions -- List of Abbreviations -- References -- Chapter 10 Nearly Zero‐Energy and Positive‐Energy Buildings: Status and Trends -- 10.1 Introduction -- 10.1.1 Concept of Nearly Zero‐ and Positive‐Energy Buildings -- 10.1.1.1 Definitions, Regulations, and Standards -- 10.1.2 Overview of Design Strategies. | |
| 10.1.2.1 Energy Conservation Strategies -- 10.1.2.2 Energy Generation Strategies -- 10.1.2.3 Smart Readiness -- 10.2 Status and Research Directions on High‐Performance Buildings for the Coming Decade -- 10.2.1 Overview of Case Studies and Research Projects -- 10.2.1.1 Challenges, Drivers, and Best Practices -- 10.2.2 Transition from Individual Nearly Zero‐Energy Buildings to Positive‐Energy Districts (PEDs) -- 10.3 Conclusions -- List of Abbreviations -- References -- Chapter 11 Transition Potential of Local Energy Communities -- 11.1 Introduction -- 11.1.1 "2030 Agenda for Sustainable Development" of United Nations -- 11.1.2 Clean Energy for All European Package: Renewable and Citizen "Energy Communities" -- 11.1.3 Human Capital for Local Energy Communities -- 11.1.4 Local Energy Communities: An Organizational Bottom‐Up Model to Empower Final Users -- 11.2 Local Energy Communities Making the Green Deal Going Local -- 11.2.1 Game Changer of the Green Deal -- 11.2.2 Green Deal Going Local -- 11.2.3 Neighborhood Approach and Local Energy Communities in the Green Deal -- 11.3 Local Energy Communities as Integrated Energy Systems at Local Level -- 11.3.1 Local Energy Communities as Promoters for Sector Coupling -- 11.3.2 Optimal Medium-Long‐Term Planning for Local Energy Communities -- 11.3.3 Key Technologies in the Context of Local Energy Communities -- 11.3.4 Digitalization to Enable Flexibility and Empower Final Users -- 11.4 Local Energy Communities and Energy Transition: A Vision for the Next Future -- 11.4.1 Some Reflections -- 11.5 Conclusions -- List of Abbreviations -- References -- Index -- EULA. | |
| Titolo autorizzato: | Technologies for Integrated Energy Systems and Networks |
| ISBN: | 3-527-83363-3 |
| 3-527-83361-7 | |
| Formato: | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione: | Inglese |
| Record Nr.: | 9910554825103321 |
| Lo trovi qui: | Univ. Federico II |
| Opac: | Controlla la disponibilità qui |