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Energy Storage in Transportation and Buildings

Detalles Bibliográficos
Autor principal: Robyns, Benoît
Otros Autores: Saudemont, Christophe, Hissel, Daniel, Roboam, Xavier, Sareni, Bruno, Pouget, Julien, François, Bruno
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Somerset : John Wiley & Sons, Incorporated, 2019.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Half-Title Page; Title Page; Copyright Page; Contents; Foreword; Introduction; 1. Storing Electrical Energy in Habitat: Toward "Smart Buildings" and "Smart Cities"; 1.1. Toward smarter electrical grids; 1.1.1. The move to decentralize electrical grids; 1.1.2. Smart grids; 1.2. Storage requirements in buildings; 1.3. Difficulties in storing electrical energy; 1.4. Electricity supply in buildings; 1.4.1. Building supply and consumption; 1.4.2. Self-production and self-consumption; 1.4.3. Micro-grids; 1.5. Smart buildings; 1.6. Smart cities; 1.7. Socio-economic questions
  • 1.7.1. Toward new economic models1.7.2. Social acceptability; 1.8. Storage management; 1.9. Methodologies used in developing energy management for storage systems; 2. Energy Storage in a Commercial Building; 2.1. Introduction; 2.2. Managing energy storage in a supermarket; 2.2.1. Introduction; 2.2.2. System characteristics; 2.2.3. Electricity billing; 2.2.4. Objectives of the energy management strategy; 2.2.5. Fuzzy logic supervisor; 2.2.6. Simulation; 2.2.7. Performance analysis using indicators; 2.3. Conclusion; 2.4. Acknowledgments
  • 3. Energy Storage in a Tertiary Building, Combining Photovoltaic Panels and LED Lighting3.1. Introduction; 3.2. DC network architecture; 3.3. Energy management; 3.3.1. Specification; 3.3.2. System inputs/outputs; 3.3.3. Functional graph; 3.3.4. Determination of membership functions; 3.3.5. Operational graph; 3.3.6. Fuzzy rules; 3.4. Simulation results; 3.4.1. Case 1: favorable grid access conditions (GAC); 3.4.2. Case 2: unfavorable GACs; 3.4.3. Case 3: variable GAC; 3.4.4. Comparison of results; 3.5. Conclusion; 3.6. Acknowledgments
  • 4. Hybrid Storage Associated with Photovoltaic Technology for Buildings in Non-interconnected Zones4.1. Introduction; 4.2. Photovoltaic systems in buildings and integration into the grid; 4.2.1. Context and economic issues; 4.2.2. Examples of projects; 4.3. Importance of storage in photovoltaic systems; 4.3.1. Photovoltaic systems for isolated sites; 4.3.2. Photovoltaic systems connected to the grid; 4.3.3. Hybrid storage; 4.3.4. Electronic conversion structures for hybrid storage; 4.4. Photovoltaic generator with hybrid storage system; 4.4.1. Case study
  • 4.4.2. Principles and standards for frequency support4.4.3. Calculating battery wear; 4.5. Energy management; 4.5.1. Methodology; 4.5.2. Operating specifications; 4.5.3. Supervisor structure and determination of input/output; 4.5.4. Functional graphs; 4.5.5. Membership functions; 4.5.6. Operating graphs; 4.5.7. Fuzzy rules; 4.5.8. Evaluation indicators; 4.6. Simulation results; 4.6.1. Supervisor validation; 4.6.2. Life expectancy of storage elements; 4.6.3. Efficiency; 4.6.4. Levelized cost of energy; 4.7. Experimental validation of energy management; 4.7.1. Definition of tests