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Advances in Concentrating Solar Thermal Research and Technology
1st Edition - November 10, 2016
Editor: Manuel Blanco
Language: English
Paperback ISBN:9780081005163
9 7 8 - 0 - 0 8 - 1 0 0 5 1 6 - 3
eBook ISBN:9780081005170
9 7 8 - 0 - 0 8 - 1 0 0 5 1 7 - 0
After decades of research and development, concentrating solar thermal (CST) power plants (also known as concentrating solar power (CSP) and as Solar Thermal Electricity or STE sy…Read more
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After decades of research and development, concentrating solar thermal (CST) power plants (also known as concentrating solar power (CSP) and as Solar Thermal Electricity or STE systems) are now starting to be widely commercialized. Indeed, the IEA predicts that by 2050, with sufficient support over ten percent of global electricity could be produced by concentrating solar thermal power plants. However, CSP plants are just but one of the many possible applications of CST systems. Advances in Concentrating Solar Thermal Research and Technology provides detailed information on the latest advances in CST systems research and technology. It promotes a deep understanding of the challenges the different CST technologies are confronted with, of the research that is taking place worldwide to address those challenges, and of the impact that the innovation that this research is fostering could have on the emergence of new CST components and concepts. It is anticipated that these developments will substantially increase the cost-competiveness of commercial CST solutions and reshape the technological landscape of both CST technologies and the CST industry. After an introductory chapter, the next three parts of the book focus on key CST plant components, from mirrors and receivers to thermal storage. The final two parts of the book address operation and control and innovative CST system concepts.
Contains authoritative reviews of CST research taking place around the world
Discusses the impact this research is fostering on the emergence of new CST components and concepts that will substantially increase the cost-competitiveness of CST power
Covers both major CST plant components and system-wide issues
R&D professionals in the CST industry as well as postgraduate researchers in academia working on CST
Related titles
List of contributors
Editors’ biographies
Acknowledgment
Part One. Introduction
1. Introduction to concentrating solar thermal (CST) technologies
1.1. The sun as an energy source
1.2. Defining characteristics of CST technologies
1.3. Thermal efficiency and the need for concentration
1.4. Limits of concentration
1.5. Optimum operating temperature to maximize light-to-work conversion efficiency
1.6. Main commercially available solar concentrating technologies
1.7. Industry and market trends
1.8. Research priorities, strategies, and trends
Part Two. Advances in the collection and concentration of sunlight
2. Advanced mirror concepts for concentrating solar thermal systems
Nomenclature
2.1. Introduction
2.2. Anti-soiling coatings
2.3. High-reflective mirror materials
2.4. High-temperature mirrors for secondary concentrators
2.5. Low-cost mirrors based on stainless steel
2.6. Conclusions
3. Improved design for linear Fresnel reflector systems
3.1. Introduction (motivation)
3.2. Advanced linear Fresnel reflector concentrators
3.3. Conclusion
Part Three. Advances in the thermal conversion of concentrated sunlight
4. A new generation of absorber tubes for concentrating solar thermal (CST) systems
4.1. Introduction
4.2. Glass cover
4.3. Steel tube
4.4. Vacuum maintenance
4.5. Bellows
4.6. Conclusion
5. Innovative working fluids for parabolic trough collectors
5.1. Introduction
5.2. Direct steam generation
5.3. Molten salts
5.4. Compressed gases
5.5. Conclusions
6. A new generation of solid particle and other high-performance receiver designs for concentrating solar thermal (CST) central tower systems
6.1. Introduction
6.2. Particle receivers
6.3. Other high-performance receiver designs
6.4. Summary and conclusions
7. Next generation of liquid metal and other high-performance receiver designs for concentrating solar thermal (CST) central tower systems
7.1. Introduction
7.2. Thermophysical properties of liquid metals
7.3. Liquid metals in central receiver systems
7.4. Innovative power conversion cycles with liquid metals as heat transfer fluid
7.5. Conclusions and outlook
Part Four. Advances in the power block and thermal storage systems
8. Supercritical CO2 and other advanced power cycles for concentrating solar thermal (CST) systems
8.1. Introduction
8.2. Stand-alone cycles
8.3. Combined cycles
8.4. Summary and conclusions
9. Advances in dry cooling for concentrating solar thermal (CST) power plants
9.1. Introduction
9.2. Current cooling technologies for concentrating solar thermal power plants
9.3. Air-cooled heat exchanger and cooling tower sizing
9.4. Advances in dry cooling technologies for concentrating solar thermal power plants
9.5. Conclusions
10. High-temperature latent heat storage for concentrating solar thermal (CST) systems
10.1. General introduction
10.2. Introduction to latent heat storage
10.3. General challenges for concentrating solar thermal latent heat storage systems
10.4. Latent heat storage configurations for concentrating solar thermal applications
10.5. Summary
11. Thermochemical energy storage for concentrating solar thermal (CST) systems
11.1. Introduction to thermochemical energy storage
11.2. General challenges for CST thermochemical storage systems
11.3. Power plant and chemical plant
11.4. Le Châtelier's principle and thermochemical energy storage
11.5. Conclusions
12. Thermal energy storage concepts for direct steam generation (DSG) solar plants
Nomenclature
12.1. Introduction
12.2. Overview on direct steam generation solar plants
12.3. Basic considerations on thermal energy storage
12.4. Integration of thermal energy storage systems in direct steam generation solar plants
12.5. Conclusions
Part Five. Advances in the control an operation of CPS plants
13. Forecasting and nowcasting of DNI for concentrating solar thermal systems
13.1. Introduction
13.2. Main forecasting techniques
13.3. Forecasting systems for CST power plants
13.4. Solar radiation forecasting baseline
13.5. DNI and CST power plants forecasting: main challenges
13.6. Conclusions
14. Advanced control strategies to maximize ROI and the value of the concentrating solar thermal (CST) plant to the grid
14.1. Introduction
14.2. Optimal operation in solar trough plants
14.3. Optimization of flux distribution in solar tower plants
14.4. Conclusions and future works
Part Six. Cost competitive CST plants concepts
15. Linear Fresnel reflector (LFR) plants using superheated steam, molten salts, and other heat transfer fluids
15.1. Introduction (motivation)
15.2. Heat transfer fluids
15.3. Higher temperatures: molten salts as HTF and thermal energy storage medium
15.4. Advanced LFR and molten salts: a new concept plant
15.5. Yearly performance
15.6. Discussion
15.7. Conclusions
16. Central tower systems using the Brayton cycle
16.1. Introduction and history
16.2. Solarization of gas turbines
16.3. Solar gas turbine cycle concepts
16.4. System components
16.5. System studies
16.6. Conclusions
Abbreviations
17. Solar power towers using supercritical CO2 and supercritical steam cycles, and decoupled combined cycles
17.1. Introduction
17.2. Solar power towers with supercritical cycles
17.3. Decoupled solar combined cycles
17.4. Summary and conclusions
18. Solar thermal processing
18.1. Introduction
18.2. H2/CO production
18.3. Material processing and chemical commodity production
18.4. Other thermal processes
18.5. Other solar processes
18.6. Conclusions and future trends
Index
No. of pages: 494
Language: English
Edition: 1
Published: November 10, 2016
Imprint: Woodhead Publishing
Paperback ISBN: 9780081005163
eBook ISBN: 9780081005170
MB
Manuel Blanco
Prof. Manuel Blanco has more than 30 years of experience as a solar researcher and engineer and has contributed to advancing the state-of the-art of Concentrating Solar Thermal (CST) technologies. He is an expert on Thermodynamics, Heat Transfer, Optics, and Modelling of Energy Systems. He is a Full Professor and holder of the European Research Area (ERA) Chair in Solar Thermal Energy of the Cyprus Institute’s Energy, Environment and Water Research Center (EEWRC). He is also the Chair of the Executive Committee of SolarPACES, the Technology Collaboration Program of the International Energy Agency responsible for promoting the development and deployment of solar thermal power technologies and the solar-assisted manufacturing of fuels and chemicals. Until August, 2016, he has been Science Leader of the Solar Energy Systems Research Group of CSIRO -Australia’s National Research Agency, as well as the Director of the Australian Solar Thermal Research Initiative (ASTRI). He is the former Director of the Solar Thermal Energy Department of the National Renewable Energy Centre of Spain (CENER), Chair and Full Professor of the Engineering Department of the University of Texas at Brownsville, and Director of the Plataforma Solar de Almería of CIEMAT, which is the largest European solar research infrastructure.
Affiliations and expertise
Cyprus Institute’s Energy, Environment and Water Research Center, Nicosia, Cyprus
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