Advances in Thermal Energy Storage Systems: Methods and Applications: Woodhead Publishing Series in Energy
Editat de Luisa F. Cabezaen Limba Engleză Hardback – 15 oct 2014
- Reviews sensible heat storage technologies, including the use of water, molten salts, concrete and boreholes
- 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
Din seria Woodhead Publishing Series in Energy
- Preț: 942.59 lei
- 23% Preț: 1503.95 lei
- 23% Preț: 1083.90 lei
- 26% Preț: 951.97 lei
- 26% Preț: 797.33 lei
- 33% Preț: 842.38 lei
- 26% Preț: 975.79 lei
- 9% Preț: 858.83 lei
- 9% Preț: 864.44 lei
- 9% Preț: 1102.31 lei
- 9% Preț: 1220.86 lei
- 9% Preț: 1057.92 lei
- 9% Preț: 862.88 lei
- 9% Preț: 865.06 lei
- 9% Preț: 918.46 lei
- 9% Preț: 975.05 lei
- 9% Preț: 915.31 lei
- 9% Preț: 863.49 lei
- 9% Preț: 861.93 lei
- 9% Preț: 788.58 lei
- 9% Preț: 969.57 lei
- 9% Preț: 859.03 lei
- 31% Preț: 1101.77 lei
- 26% Preț: 1097.87 lei
- 40% Preț: 1166.93 lei
- 9% Preț: 1268.53 lei
- 40% Preț: 1268.75 lei
- 9% Preț: 1188.77 lei
- 9% Preț: 1374.59 lei
- 9% Preț: 926.38 lei
- 9% Preț: 1098.09 lei
- 9% Preț: 1120.22 lei
- 40% Preț: 799.84 lei
- 40% Preț: 951.28 lei
- 40% Preț: 1113.08 lei
- 9% Preț: 817.49 lei
- 40% Preț: 986.06 lei
- 26% Preț: 1187.51 lei
- 26% Preț: 978.69 lei
- 26% Preț: 1187.51 lei
- 26% Preț: 1379.05 lei
- 26% Preț: 976.31 lei
- 26% Preț: 1259.19 lei
- 31% Preț: 1320.25 lei
- 31% Preț: 890.99 lei
- 31% Preț: 972.57 lei
- 26% Preț: 1533.01 lei
- 26% Preț: 1467.03 lei
- 31% Preț: 974.21 lei
Preț: 1037.86 lei
Preț vechi: 1166.14 lei
-11%
Puncte Express: 1557
Preț estimativ în valută:
198.83€ • 215.87$ • 170.52£
198.83€ • 215.87$ • 170.52£
Cartea nu se mai tipărește
Doresc să fiu notificat când acest titlu va fi disponibil:
Se trimite...
Preluare comenzi: 021 569.72.76
Specificații
ISBN-13: 9781782420880
ISBN-10: 1782420886
Pagini: 612
Dimensiuni: 152 x 229 x 39 mm
Greutate: 1.03 kg
Editura: ELSEVIER SCIENCE
Seria Woodhead Publishing Series in Energy
ISBN-10: 1782420886
Pagini: 612
Dimensiuni: 152 x 229 x 39 mm
Greutate: 1.03 kg
Editura: ELSEVIER SCIENCE
Seria Woodhead Publishing Series in Energy
Public țintă
R&D managers with an interest in thermal energy storage solutions, civil engineers with an interest in passive houses, and postgraduate students and researchers working on thermal energy storage or civil engineering.Cuprins
- List of contributors
- Woodhead Publishing Series in Energy
- Preface
- 1: Introduction to thermal energy storage (TES) 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
- Acknowledgements
- Part One: Sensible heat storage systems
- 2: Using water for heat storage in thermal energy storage (TES) systems
- Abstract
- 2.1 Introduction
- 2.2 Principles of sensible heat storage systems involving water
- 2.3 Advances in the use of water for heat storage
- 2.4 Future trends
- 3: Using molten salts and other liquid sensible storage media in thermal energy storage (TES) systems
- 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 Advances in other liquid sensible storage media
- 3.5 Future trends
- Acknowledgements
- 4: Using concrete and other solid storage media in thermal energy storage (TES) 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
- 5: The use of aquifers as thermal energy storage (TES) systems
- Abstract
- 5.1 Introduction
- 5.2 Thermal sources
- 5.3 Aquifier thermal energy storage (ATES)
- 5.4 Thermal and geophysical aspects
- 5.5 ATES design
- 5.6 ATES cooling only case study: Richard Stockton College of New Jersey
- 5.7 ATES district heating and cooling with heat pumps case study: Eindhoven University of Technology
- 5.8 ATES heating and cooling with de-icing case study: ATES plant at Stockholm Arlanda Airport
- 5.9 Conclusion
- Acknowledgements
- 6: The use of borehole thermal energy storage (BTES) systems
- Abstract
- 6.1 Introduction
- 6.2 System integration of borehole thermal energy storage (BTES)
- 6.3 Investigation and design of BTES construction sites
- 6.4 Construction of borehole heat exchangers (BHEs) and BTES
- 6.5 Examples of BTES
- 6.6 Conclusion and future trends
- 7: Analysis, modeling and simulation of underground thermal energy storage (UTES) systems
- Abstract
- 7.1 Introduction
- 7.2 Aquifer thermal energy storage (ATES) system
- 7.3 Borehole thermal energy storage (BTES) system
- 7.4 FEFLOW as a tool for simulating underground thermal energy storage (UTES)
- 7.5 Applications
- Appendix: Nomenclature
- 2: Using water for heat storage in thermal energy storage (TES) systems
- Part Two: Latent heat storage 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
- 9: Using solid-liquid phase change materials (PCMs) in thermal energy storage systems
- Abstract
- 9.1 Introduction
- 9.2 Principles of solid-liquid phase change materials (PCMs)
- 9.3 Shortcomings of PCMs in thermal energy storage systems
- 9.4 Methods to determine the latent heat capacity of PCMs
- 9.5 Methods to determine other physical and technical properties of PCMs
- 9.6 Comparison of physical and technical properties of key PCMs
- 9.7 Future trends
- 10: Microencapsulation of phase change materials (PCMs) for thermal energy storage systems
- Abstract
- 10.1 Introduction
- 10.2 Microencapsulation of phase change materials (PCMs)
- 10.3 Shape-stabilized PCMs
- 11: Design of latent heat storage systems using phase change materials (PCMs)
- Abstract
- 11.1 Introduction
- 11.2 Requirements and considerations for the design
- 11.3 Design methodologies
- 11.4 Applications of latent heat storage systems incorporating PCMs
- 11.5 Future trends
- 12: Modelling of heat transfer in phase change materials (PCMs) for thermal energy storage systems
- Abstract
- 12.1 Introduction
- 12.2 Inherent physical phenomena in phase change materials (PCMs)
- 12.3 Modelling methods and approaches for the simulation of heat transfer in PCMs for thermal energy storage
- 12.4 Examples of modelling applications
- 12.5 Future trends
- 13: Integrating phase change materials (PCMs) in thermal energy storage systems for buildings
- Abstract
- 13.1 Introduction
- 13.2 Integration of phase change materials (PCMs) into the building envelope: physical considerations and heuristic arguments
- 13.3 Organic and inorganic PCMs used in building walls
- 13.4 PCM 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 Conclusions
- 8: Using ice and snow in thermal energy storage systems
- Part Three: Thermochemical heat storage systems
- 14: Using thermochemical reactions in thermal energy storage systems
- Abstract
- 14.1 Introduction
- 14.2 Applications of reversible gas–gas reactions
- 14.3 Applications of reversible gas–solid reactions
- 14.4 Conclusion
- 15: Modeling thermochemical reactions in thermal energy storage systems
- Abstract
- 15.1 Introduction
- 15.2 Grain model technique (Mampel’s approach)
- 15.3 Reactor model technique (continuum approach)
- 15.4 Molecular simulation methods: quantum chemical simulations (DFT)
- 15.5 Molecular simulation methods: statistical mechanics
- 15.6 Molecular simulation methods: molecular dynamics (MD)
- 15.7 Properties estimation from molecular dynamics simulation
- 15.8 Examples
- 15.9 Conclusion and future trends
- Acknowledgements
- 14: Using thermochemical reactions in thermal energy storage systems
- Part Four: Systems operation and applications
- 16: Monitoring and control of thermal energy storage systems
- Abstract
- 16.1 Introduction
- 16.2 Overview of state-of-the-art monitoring and control of thermal energy storage systems
- 16.3 Stand-alone control and monitoring of heating devices
- 16.4 Data logging and heat metering of heating devices
- 16.5 Future trends in the monitoring and control of thermal storage systems
- 17: Thermal energy storage systems for heating and hot water in residential buildings
- Abstract
- 17.1 Introduction
- 17.2 Requirements for thermal energy storage in individual residential buildings
- 17.3 Sensible heat storage for space heating in individual residential buildings
- 17.4 Latent and sorption heat storage for space heating in individual residential buildings
- 17.5 Thermal energy storage for domestic hot water and combined systems in individual residential buildings
- 17.6 Conclusions and future trends
- 18: Thermal energy storage systems for district heating and cooling
- Abstract
- 18.1 Introduction
- 18.2 District heating and cooling overview
- 18.3 Advances in applications of thermal energy storage systems
- 18.4 Future trends
- 19: Thermal energy storage (TES) systems using heat from waste
- Abstract
- 19.1 Introduction
- 19.2 Generation of waste process heat in different industries
- 19.3 Application of thermal energy storage (TES) for valorization of waste process heat
- 19.4 Conclusions
- 20: Thermal energy storage (TES) systems for cogeneration and trigeneration systems
- Abstract
- 20.1 Introduction
- 20.2 Overview of cogeneration and trigeneration systems
- 20.3 Design of thermal energy storage for cogeneration and trigeneration systems
- 20.4 Implementation of thermal energy storage in cogeneration and trigeneration systems
- 20.5 Future trends
- 20.6 Conclusion
- 21: Thermal energy storage systems for concentrating solar power (CSP) technology
- Abstract
- 21.1 Introduction
- 21.2 Commercial concentrating solar power (CSP) plants with integrated storage capacity
- 21.3 Research and development in CSP storage systems
- 21.4 Conclusion
- 22: Thermal energy storage (TES) systems for greenhouse technology
- Abstract
- 22.1 Introduction
- 22.2 Greenhouse heating and cooling
- 22.3 Thermal energy storage (TES) technologies for greenhouse systems
- 22.4 Case studies for TES in greenhouses
- 22.5 Conclusions and future trends
- 23: Thermal energy storage (TES) systems for cooling in residential buildings
- Abstract
- 23.1 Introduction
- 23.2 Sustainable cooling through passive systems in building envelopes
- 23.3 Sustainable cooling through phase change material (PCM) in active systems
- 23.4 Sustainable cooling through sorption systems
- 23.5 Sustainable cooling through seasonal storage
- 23.6 Conclusions
- Acknowledgements
- 16: Monitoring and control of thermal energy storage systems
- Index