Advances in Thermal Energy Storage Systems
Methods and Applications
- 2nd Edition - October 27, 2020
- Imprint: Woodhead Publishing
- Editor: Luisa F. Cabeza
- Language: English
- Hardback ISBN:9 7 8 - 0 - 1 2 - 8 1 9 8 8 5 - 8
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 1 9 8 8 8 - 9
Advances in Thermal Energy Storage Systems, 2nd edition, presents a fully updated comprehensive analysis of thermal energy storage systems (TES) including all major advances and d… Read more
Purchase options
Institutional subscription on ScienceDirect
Request a sales quoteAdvances in Thermal Energy Storage Systems, 2nd edition, presents a fully updated comprehensive analysis of thermal energy storage systems (TES) including all major advances and developments since the first edition published. This very successful publication provides readers with all the information related to TES in one resource, along with a variety of applications across the energy/power and construction sectors, as well as, new to this edition, the transport industry. After an introduction to TES systems, editor Dr. Prof. Luisa Cabeza and her team of expert authors consider the source, design and operation of the use of water, molten salts, concrete, aquifers, boreholes and a variety of phase-change materials for TES systems, before analyzing and simulating underground TES systems.
This edition benefits from 5 new chapters covering the most advanced technologies including sorption systems, thermodynamic and dynamic modelling as well as applications to the transport industry and the environmental and economic aspects of TES. It will benefit researchers and academics of energy systems and thermal energy storage, construction engineering academics, engineers and practitioners in the energy and power industry, as well as architects of plants and storage systems and R&D managers.
- Includes 5 brand new chapters covering Sorption systems, Thermodynamic and dynamic models, applications to the transport sector, environmental aspects of TES and economic aspects of TES
- All existing chapters are updated and revised to reflect the most recent advances in the research and technologies of the field
- Reviews heat storage technologies, including the use of water, molten salts, concrete and boreholes in one comprehensive resource
- Describes latent heat storage systems and thermochemical heat storage
- Includes information on the monitoring and control of thermal energy storage systems, and considers their applications in residential buildings, power plants and industry
Academia: Researchers and academics of energy systems and thermal energy storage, as well as construction engineering. Industry: Engineers and practitioners in energy, power and construction, as well as architects of plants and storage facilities. R&D managers with an interest in thermal energy storage solutions, civil engineers with an interest in passive houses.
- Cover image
- Title page
- Table of Contents
- Copyright
- List of Contributors
- 1. Introduction to thermal energy storage systems
- Abstract
- 1.1 Introduction
- 1.2 Basic thermodynamics of energy storage
- 1.3 Overview of system types
- 1.4 Environmental impact and energy savings produced
- 1.5 Conclusions
- Acknowledgments
- References
- Part One: Sensible heat storage systems
- 2. Advances in thermal energy storage systems: methods and applications
- Abstract
- 2.1 Introduction
- References
- 3. Advances in molten salt storage systems using other liquid sensible storage media for heat storage
- Abstract
- 3.1 Introduction
- 3.2 Principles of heat storage systems using molten salts and other liquid sensible storage media
- 3.3 Advances in molten salt storage
- 3.4 Advanced concepts for other liquid-media based systems
- 3.5 Molten salts for advanced solar thermal energy power
- 3.6 Additional future trends
- References
- Sources of further information and advice
- 4. Using concrete and other solid storage media in thermal energy storage systems
- Abstract
- 4.1 Introduction
- 4.2 Principles of heat storage in solid media
- 4.3 State-of-the-art regenerator-type storage
- 4.4 Advances in the use of solid storage media for heat storage
- References
- 5. The use of aquifers as thermal energy storage systems
- Abstract
- 5.1 Introduction
- 5.2 Thermal sources
- 5.3 Aquifer thermal energy storage
- 5.4 Thermal and geophysical aspects
- 5.5 Aquifer thermal energy storage design
- 5.6 Aquifer thermal energy storage cooling only case study: Richard Stockton College of New Jersey (currently Stockton University)
- 5.7 Aquifer thermal energy storage district heating and cooling with heat pumps case study: Eindhoven University of Technology
- 5.8 Aquifer thermal energy storage heating and cooling with deicing case study: aquifer thermal energy storage plant at Stockholm Arlanda Airport
- 5.9 Conclusion
- Acknowledgment
- References
- Further reading
- 6. The use of borehole thermal energy storage systems
- Abstract
- 6.1 Introduction
- 6.2 System integration of borehole thermal energy storage
- 6.3 Investigation and design of borehole thermal energy storage construction sites
- 6.4 Construction of borehole heat exchangers and borehole thermal energy storage
- 6.5 Examples of borehole thermal energy storage
- 6.6 Conclusion and future trends
- References
- 7. Analysis, modeling, and simulation of underground thermal energy storage systems
- Abstract
- 7.1 Introduction
- 7.2 Aquifer thermal energy storage system
- 7.3 Borehole thermal energy storage system
- 7.4 FEFLOW as a tool for simulating underground thermal energy storage
- 7.5 Applications
- References
- Part Two: Latent heat stoage systems
- 8. Using ice and snow in thermal energy storage systems
- Abstract
- 8.1 Introduction
- 8.2 Principles of thermal energy storage systems using snow and ice
- 8.3 Design and implementation of thermal energy storage using snow
- 8.4 Full-scale applications
- 8.5 Future trends
- References
- 9. Solid-liquid phase change materials for thermal energy storage
- Abstract
- 9.1 Introduction
- 9.2 Principles of solid-liquid phase change materials
- 9.3 Methods to determine physical and technical properties of phase change materials
- 9.4 Comparison of physical and technical properties of key phase change materials
- 9.5 Future trends
- References
- 10. Microencapsulation of phase change materials for thermal energy storage systems
- Abstract
- 10.1 Introduction
- 10.2 Microencapsulation of organic phase change materials
- 10.3 Microencapsulation of inorganic salt hydrate phase change materials
- 10.4 Shape-stabilized phase change materials
- 10.5 Conclusions and perspectives
- References
- 11. Design of latent heat energy storage systems using phase change materials
- Abstract
- 11.1 Introduction
- 11.2 Phase change material requirements and considerations
- 11.3 Heat exchange systems
- 11.4 Design methodologies
- 11.5 Future trends
- References
- 12. Modeling of heat transfer in phase change materials for thermal energy storage systems
- Abstract
- 12.1 Introduction
- 12.2 Inherent physical phenomena in phase change materials
- 12.3 Modeling methods and approaches for the simulation of heat transfer in phase change materials for thermal energy storage
- 12.4 Examples of modeling applications
- 12.5 Future trends
- References
- Sources of further information and advice
- 13. Integrating phase change materials in thermal energy storage systems for buildings
- Abstract
- 13.1 Introduction
- 13.2 Integration of phase change materials into the building envelope: physical considerations and heuristic arguments
- 13.3 Organic and inorganic phase change materials used in building walls
- 13.4 Phase change material containment
- 13.5 Measurement of the thermal properties of PCM and PCM integrated in building walls
- 13.6 Experimental studies
- 13.7 Numerical studies
- 13.8 Conclusion
- References
- Part Three: Thermochemical heat storage systems
- 14. Sorption systems for thermal energy storage
- Abstract
- 14.1 Introduction
- 14.2 Principles of sorption reactions
- 14.3 Main characterization techniques of sorbent materials
- 14.4 Sorption storage prototypes
- 14.5 Conclusion and future perspectives
- References
- 15. Modeling of sorption systems for thermal energy storage
- Abstract
- 15.1 Introduction
- 15.2 Reactor level (continuum approach)
- 15.3 Reactor level (noncontinuum lumped parameter approach)
- 15.4 System level (black-box models)
- 15.5 Applications
- 15.6 Conclusion
- References
- 16. Using thermochemical reactions in thermal energy storage systems
- Abstract
- 16.1 Introduction
- 16.2 Applications of reversible gas-gas reactions
- 16.3 Applications of reversible gas-solid reactions
- 16.4 Conclusion
- References
- 17. Modeling thermochemical reactions in thermal energy storage systems
- Abstract
- 17.1 Introduction
- 17.2 Grain model technique (Mampel’s approach)
- 17.3 Reactor model technique (continuum approach)
- 17.4 Molecular simulation methods: quantum chemical simulations (DFT)
- 17.5 Molecular simulation methods: statistical mechanics
- 17.6 Molecular simulation methods: molecular dynamics
- 17.7 Properties estimation from molecular dynamics simulation
- 17.8 Examples
- 17.9 Conclusion and future trends
- Acknowledgments
- References
- Part Four: Systems operation and applications
- 18. Monitoring and control of thermal energy storage systems
- Abstract
- 18.1 Introduction
- 18.2 Overview of state-of-the-art monitoring and control of thermal energy storage systems
- 18.3 Stand-alone control and monitoring of heating devices
- 18.4 Data logging and heat metering of heating devices
- 18.5 Future trends in the monitoring and control of thermal storage systems
- 18.6 Sources of further information and advice
- References
- 19. Thermal energy storage for space heating and domestic hot water in individual residential buildings
- Abstract
- 19.1 Introduction
- 19.2 Requirements for thermal energy storage in individual residential buildings
- 19.3 Thermal energy storage for space heating in individual residential buildings
- 19.4 Conclusion and outlook
- References
- 20. Thermal energy storage systems for cooling in residential buildings
- Abstract
- 20.1 Introduction
- 20.2 Sustainable cooling through passive systems in building envelopes
- 20.3 Sustainable cooling through phase change material in active systems
- 20.4 Sustainable cooling through sorption systems
- 20.5 Sustainable cooling through seasonal storage
- 20.6 Other options of sustainable cooling with thermal energy storage
- 20.7 Conclusion
- Acknowledgment
- References
- 21. Thermal energy storage systems for district heating and cooling
- Abstract
- 21.1 Introduction
- 21.2 District heating and cooling overview
- 21.3 Advances in applications
- 21.4 Investment costs
- 21.5 Future trends
- 21.6 Information sources
- References
- 22. Waste heat recovery using thermal energy storage
- Abstract
- 22.1 Introduction
- 22.2 Generation of waste process heat in different industries
- 22.3 Application of thermal energy storage for valorization of waste process heat
- 22.4 Conclusion
- References
- 23. Thermal energy storage systems for cogeneration and trigeneration systems
- Abstract
- 23.1 Introduction
- 23.2 Overview of cogeneration and trigeneration systems
- 23.3 Design of thermal energy storage for cogeneration and trigeneration systems
- 23.4 Implementation of thermal energy storage in cogeneration and trigeneration systems
- 23.5 Future trends
- 23.6 Conclusion
- References
- Sources of further information and advice Books and handbooks
- 24. Thermal storage for concentrating solar power plants
- Abstract
- 24.1 Thermal energy storage and concentrating solar power
- 24.2 Basic storage concept for concentrating solar power
- 24.3 Thermal energy storage in commercial solar thermal power plants
- 24.4 Conclusion and future trends
- References
- 25. Thermal energy storage systems for greenhouse technology
- Abstract
- 25.1 Introduction
- 25.2 Greenhouse heating and cooling
- 25.3 Thermal energy storage technologies for greenhouse systems
- 25.4 Case studies for thermal energy storage in greenhouses
- 25.5 Conclusion and future trends
- References
- 26. Thermal energy storage in the transport sector
- Abstract
- 26.1 Introduction
- 26.2 Applications of thermal energy storage in the transport sector
- References
- 27. Thermal energy storage for temperature management of electronics
- Abstract
- 27.1 Introduction
- 27.2 Thermal storage for thermal management: concept
- 27.3 Hybrid heat sink
- 27.4 Portable electronics
- 27.5 Pulsed power electronics
- 27.6 Batteries
- 27.7 Photovoltaic panels
- 27.8 Future trends
- References
- Index
- Edition: 2
- Published: October 27, 2020
- Imprint: Woodhead Publishing
- No. of pages: 796
- Language: English
- Hardback ISBN: 9780128198858
- eBook ISBN: 9780128198889
LC
Luisa F. Cabeza
Luisa F. Cabeza is Professor at the University of Lleida (Spain) where she leads the GREA research group. She has co-authored over 100 journal papers and several book chapters. Luisa F. Cabeza received her PhD in Industrial Engineering in 1996 from the University Ramon Llull, Barcelona, Spain. She also holds degrees in Chemical Engineering (1992) and in Industrial Engineering (1993), as well as an MBA (1995) from the same University. Her interests include the different TES technologies (sensible, latent and thermochemical), applications (buildings, industry, refrigeration, CSP, etc.), and social aspects. She also acts as subject editor of the journals Renewable Energy, and Solar Energy.
Affiliations and expertise
Professor, University of Lleida, SpainRead Advances in Thermal Energy Storage Systems on ScienceDirect