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Solar Thermal Energy Storage

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Applications of Solar Energy

Part of the book series: Energy, Environment, and Sustainability ((ENENSU))

Abstract

Over the past few decades, considerable research efforts have been devoted to improve the usage of renewable energy resources. Till date, major energy demands have been addressed by fossil fuels, and the limited resource of these precious fuels is continuously depleting at an alarming rate. Increase in the energy demands, deficiency of fossil fuels, and influence of pollution on the environment have forced us to opt for renewable energy resources. Solar energy is a natural source of energy that is not depleted by its use. It is a promising option for replacing conventional energy resources partially or totally, but it is transient, intermittent, and unpredictable in nature. Because of this sporadic nature of solar energy across a given interval of hours, days, and season, various practical problems arise. Variable DNI causes power plants to shut down for few hours of the day or to run at part load most of the time. This creates a demand for an effective subsystem which is capable of storing energy when available solar energy overshoots the demand during the interval of radiant sunshine, and to make it accessible during night or season. A similar problem arises for waste heat recovery systems where accessibility of waste heat and usage period are not the same, and thus creates a need for thermal energy storage (TES) for energy conservation. TES has tempted a lot of researchers to improve its high energy storage capacity and efficiency. If solar energy system is not run with TES, a considerable section of energy demand has to depend on conventional resources which in result reduce the annual solar fraction. TES helps to reduce dependency over conventional resource by minimizing energy waste. TES is mainly described by the parameters like capacity, power, efficiency, storage period, charge and discharge time, and cost. There are different storage mechanisms by which energy can be stored: sensible, latent, and chemical reactions. In sensible-type storage, energy is stored by increasing the temperature of solid or liquid storage media (e.g., sand-rock minerals, concrete, oils, and liquid sodium). These materials have excellent thermal conductivity and are cheaper, but due to low heat capacity, it increases system size. In latent-type storage, energy is stored/released during phase change; thus, it has higher storage capacity than sensible, but suffers from the issue of low thermal conductivity. As the solid–liquid phase change process of pure or eutectic substances is isothermal in nature, it is beneficial for the application having limitations with working temperature. In chemical-type TES, heat is absorbed/released due to breakdown or formation of chemical bonds. The technology is not much developed and has limited application due to possibility of degradation over time and chemical instability. TES can also be classified as active and passive depending upon the solid or liquid energy storage medium. Active TES is further classified as direct active and indirect active depending on whether the storage fluid and the heat transfer fluid (HTF) are same or some other HTF is required to extract heat from solar field. The discussion in this chapter includes basic heat transfer models, along with experimental studies by different research groups on various TES. Finally, methods and design criteria that can improve the system performance are discussed.

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References

  1. Barr KP (1982) Buffer thermal energy storage for a solar Brayton engine. Mirror

    Google Scholar 

  2. Somasundaram S, Brown DR, Kevin Drost M (1997) Diurnal thermal energy storage for cogeneration applications. Cogener Compet Power J 12(2):51–78

    Google Scholar 

  3. Givoni B (1977) Underground longterm storage of solar energy—an overview. Sol Energy 19(6):617–623

    Article  Google Scholar 

  4. Pardo P et al (2014) A review on high temperature thermochemical heat energy storage. Renew Sustain Energy Rev 32(2014):591–610

    Google Scholar 

  5. Sukhatme K, Sukhatme SP (1996) Solar energy: principles of thermal collection and storage. Tata McGraw-Hill Education

    Google Scholar 

  6. Shelton J (1975) Underground storage of heat in solar heating systems. Sol Energy 17(2):137–143

    Article  Google Scholar 

  7. imnh.isu.edu/digitalatlas/hydr/concepts/gwater/aquifer.htm. Accessed 3 July 2017

  8. Caljé RJ (2009) Future use of Aquifer thermal energy storage below the historic centre of Amsterdam. Master Study Hydrology Department of Water-Management, Delft University of Technology, December 16th 2009 (5/7/2017)

    Google Scholar 

  9. Paksoy H, Snijders A, Stiles L (2009) State-of-the-art review of aquifer thermal energy storage systems for heating and cooling buildings. In: Proceedings of the EFFSTOCK conference, Stockholm, Sweden

    Google Scholar 

  10. Ercan Ataer O (2006) Storage of thermal energy, in energy storage systems. In: Gogus YA (ed) Encyclopedia of life support systems (EOLSS). Developed under the Auspices of the UNESCO. Eolss Publishers, Oxford, UK. http://www.eolss.net

  11. Ushak S, FernĂ¡ndez AG, Grageda M (2014) Using molten salts and other liquid sensible storage media in thermal energy storage (TES) systems. In: Advances in thermal energy storage systems: methods and applications, 1st ed. Cabeza, LF, Ed, pp 49–63

    Google Scholar 

  12. Ortega JI, Ignacio Burgaleta J, TĂƒÅ llez FM (2008) Central receiver system solar power plant using molten salt as heat transfer fluid. J Sol Energy Eng 130(2):024501

    Google Scholar 

  13. Jorgenson J, Gilman P, Dobos A (2011) Technical manual for the SAM biomass power generation model. No. NREL/TP-6A20-52688. National Renewable Energy Laboratory (NREL), Golden, CO

    Google Scholar 

  14. Solar Millennium (2008) The parabolic trough power plants Andasol 1 to 3. Tech. Solar Millennium AG

    Google Scholar 

  15. https://www.nrel.gov/csp/solarpaces/project_detail.cfm/projectID=3. Accessed 5 July 2017

  16. Tesfay M, Venkatesan M (2013) Simulation of thermocline thermal energy storage system using C. Int J Innov Appl Stud 3(2):354–364

    Google Scholar 

  17. Chang ZS et al (2015) The design and numerical study of a 2 mwh molten salt thermocline tank. Energy Procedia 69:779–789

    Article  Google Scholar 

  18. Flueckiger SM, Yang Z, Garimella SV (2013) Review of molten-salt thermocline tank modeling for solar thermal energy storage. Heat Transf Eng 34(10):787–800

    Article  Google Scholar 

  19. (2010) Solar thermal storage systems: preliminary design study. EPRI report 1019581

    Google Scholar 

  20. Li P et al (2011) Generalized charts of energy storage effectiveness for thermocline heat storage tank design and calibration. Sol Energy 85(9):2130–2143

    Google Scholar 

  21. Haller MY et al (2009) Methods to determine stratification efficiency of thermal energy storage processes—review and theoretical comparison. Sol Energy 83(10):1847–1860

    Google Scholar 

  22. Davidson JH, Adams DA, Miller JA (1994) A coefficient to characterize mixing in solar water storage tanks. Guide to the records of the Solar Energy Applications Laboratory and Solar Village. http://lib.colostate.edu/archives/findingaids/university/ucsv.html

  23. Andersen E, Furbo S, Fan J (2007) Multilayer fabric stratification pipes for solar tanks. Sol Energy 81(10):1219–1226

    Article  Google Scholar 

  24. Zavattoni SA et al (2015) Evaluation of thermal stratification of an air-based thermocline TES with low-cost filler material. Energy Procedia 73:289–296

    Google Scholar 

  25. Tian Y, Zhao C-Y (2013) A review of solar collectors and thermal energy storage in solar thermal applications. Appl Energy 104:538–553

    Article  Google Scholar 

  26. Canbazoğlu S et al (2005) Enhancement of solar thermal energy storage performance using sodium thiosulfate pentahydrate of a conventional solar water-heating system. Energy Build 37(3):235–242

    Google Scholar 

  27. Morrison DJ, Abdel-Khalik SI (1978) Effects of phase-change energy storage on the performance of air-based and liquid-based solar heating systems. Sol Energy 20(1):57–67

    Article  Google Scholar 

  28. Jurinak JJ, Abdel-Khalik SI (1979) On the performance of air-based solar heating systems utilizing phase-change energy storage. Energy 4(4):503–522

    Article  Google Scholar 

  29. Enibe SO (2002) Performance of a natural circulation solar air heating system with phase change material energy storage. Renew Energy 27(1):69–86

    Article  Google Scholar 

  30. Zhang J (1999) Energy saving technology of refrigeration devices

    Google Scholar 

  31. Gu Z, Liu H, Li Y (2004) Thermal energy recovery of air conditioning system—heat recovery system calculation and phase change materials development. Appl Therm Eng 24(17):2511–2526

    Article  Google Scholar 

  32. Buddhi D (1997) Thermal performance of a shell and tube PCM storage heat exchanger for industrial waste heat recovery. In: Proceedings of the ISES 1997 solar world congress, Taejon, Korea

    Google Scholar 

  33. Lovegrove K, Luzzi A, Kreetz H (1999) A solar-driven ammonia-based thermochemical energy storage system. Sol Energy 67(4):309–316

    Article  Google Scholar 

  34. Steinfeld A, Sanders S, Palumbo R (1999) Design aspects of solar thermochemical engineering—a case study: two-step water-splitting cycle using the Fe3O4/FeO redox system. Sol Energy 65(1):43–53

    Google Scholar 

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Authors and Affiliations

  1. Department of Mechanical Engineering, Indian Institute of Technology Jodhpur, Jodhpur, India

    Aniket D. Monde, Amit Shrivastava & Prodyut R. Chakraborty

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  1. Aniket D. Monde
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  2. Amit Shrivastava
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  3. Prodyut R. Chakraborty
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Correspondence to Prodyut R. Chakraborty .

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Editors and Affiliations

  1. Department of Mechanical Engineering, Indian Institute of Technology Ropar, Rupnagar, Punjab, India

    Himanshu Tyagi

  2. Department of Mechanical Engineering, Indian Institute of Technology Kanpur, Kanpur, Uttar Pradesh, India

    Avinash Kumar Agarwal

  3. Department of Mechanical Engineering, Indian Institute of Technology Jodhpur, Jodhpur, Rajasthan, India

    Prodyut R. Chakraborty

  4. School of Engineering, Indian Institute of Technology Mandi, Mandi, Himachal Pradesh, India

    Satvasheel Powar

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Monde, A.D., Shrivastava, A., Chakraborty, P.R. (2018). Solar Thermal Energy Storage. In: Tyagi, H., Agarwal, A., Chakraborty, P., Powar, S. (eds) Applications of Solar Energy. Energy, Environment, and Sustainability. Springer, Singapore. https://doi.org/10.1007/978-981-10-7206-2_8

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  • DOI: https://doi.org/10.1007/978-981-10-7206-2_8

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  • Online ISBN: 978-981-10-7206-2

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