Energy storage devices for electronic systems : rechargeable batteries and supercapacitors

Energy storage devices for electronic systems rechargeable batteries and supercapacitors

Energy storage devices are a crucial area of research and development across many engineering disciplines and industries. While batteries provide the significant advantage of high energy density, their limited life cycles, disposal challenges and charge and discharge management constraints undercut...

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Detalles Bibliográficos
Otros Autores: Kularatna, Nihal, author (author)
Formato: Libro electrónico
Idioma:Inglés
Publicado: London, England : Academic Press 2015.
Edición:First edition
Materias:
Energy storage.
Electronic systems.
Storage batteries.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009629466806719
Tabla de Contenidos:
  • Front Cover; Energy Storage Devices for Electronic Systems: Rechargeable Batteries and Supercapacitors; Copyright; Dedication; Contents; Preface; Acknowledgments; Chapter 1: Energy storage devices-a general overview; 1.1. Introduction; 1.2. Simple fundamentals; 1.2.1. Work, power, and energy; 1.2.2. Impact of the open circuit voltage and internal resistance of an energy source; 1.2.2.1. Maximum power transfer; 1.2.3. Energy wasted inside a source and its heating effect; 1.2.4. Time delays in delivering or transferring energy; 1.2.5. Complex models of ESDs
  • 1.3. Energy storage in electrical systems1.3.1. Basic electrical components as in-circuit energy storage; 1.3.2. Energy storage options for longer term and infrequent utilization; 1.3.3. Flywheel as an ESD in electrical systems; 1.3.4. Fuel cells; 1.4. Compressed air energy storage; 1.5. Superconductive magnetic energy storage; 1.6. Rapid energy transfer requirements and fundamental circuit issues; 1.7. Technical specifications of ESDs; 1.7.1. Energy and power density; 1.7.1.1. Energy density; 1.7.1.2. Power density; 1.7.1.3. Cycle life; 1.7.1.4. Cyclic energy density
  • 1.7.1.5. Self-discharge rate1.7.1.6. Charge acceptance or coulombic efficiency; 1.8. Ragone plot; References; Chapter 2: Rechargeable battery technologies: an electronic engineers view point; 2.1. Introduction; 2.2. Battery terminology and fundamentals; 2.2.1. Capacity; 2.2.1.1. Standard capacity; 2.2.1.2. Actual capacity; 2.2.1.3. Available capacity; 2.2.1.4. Rated capacity; 2.2.1.5. Retained capacity; 2.2.2. Peukerts law and the battery capacity; 2.2.3. C rate; 2.2.4. Energy density; 2.2.5. Power density of a battery; 2.2.6. Cycle life; 2.2.7. Cyclic energy density
  • 2.2.8. Self-discharge rate2.2.9. Charge acceptance; 2.2.10. Depth of discharge; 2.2.11. Battery discharge curves and related terminology; 2.2.11.1. Voltage plateau; 2.2.11.2. Midpoint voltage; 2.2.12. Overcharge; 2.2.13. State of charge (SoC); 2.2.14. State of health; 2.3. Battery technologies: an overview; 2.4. Lead-acid batteries; 2.4.1. Flooded lead-acid batteries; 2.4.2. Sealed lead-acid batteries; 2.4.2.1. Discharge performance of sealed lead-acid cells; 2.4.2.2. Capacity during battery life; 2.4.2.3. Effect of pulse discharge on capacity; 2.4.3. Charging; 2.5. Nickel-cadmium batteries
  • 2.5.1. Discharge characteristics2.5.2. Charge characteristics; 2.5.3. Voltage depression effect; 2.6. Nickel metal hydride batteries; 2.6.1. Construction; 2.6.2. A comparison between NiCd and NiMH batteries; 2.7. Lithium-based rechargeable batteries; 2.7.1. Construction; 2.7.2. Charge and discharge characteristics; 2.7.3. Li-ion micro batteries; 2.8. Reusable alkaline batteries; 2.8.1. Cumulative capacity; 2.9. Zn-air batteries; Chapter 3: Dynamics, models, and management of rechargeable batteries; 3.1. Introduction; 3.2. Simplest concept of a battery; 3.3. Battery dynamics
  • 3.3.1. Long-term effects

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