By Luisa F. Cabeza
Thermal strength garage (TES) applied sciences shop thermal power (both warmth and chilly) for later use as required, instead of on the time of creation. they're as a result vital opposite numbers to numerous intermittent renewable strength new release tools and likewise supply a manner of valorising waste technique warmth and lowering the strength call for of constructions. This publication presents an authoritative evaluation of this key zone. half one studies brilliant warmth garage applied sciences. half covers latent and thermochemical warmth garage respectively. the ultimate part addresses functions in heating and effort systems.
- Reviews brilliant warmth garage applied sciences, together with using water, molten salts, concrete and boreholes
- Describes latent warmth garage structures and thermochemical warmth storage
- Includes details at the tracking and regulate of thermal power garage structures, and considers their purposes in residential constructions, energy crops and industry
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155–176. Dordrecht: Springer. 18. Nagano, K. (2007) Energy pile system in new building of Sapporo City University. O. ) NATO Sciences Series, II. Mathematics, Physics and Chemistry, Vol. 234: Thermal Energy Storage for Sustainable Energy Consumption: Fundamentals, Case Studies and Design, pp. 245–253. Dordrecht: Springer. 19. A. J. (2013) ‘Charge and discharge strategies for a multi-tank thermal energy storage’, Applied Energy, 109, 366–373. 20. A. J. (2009) ‘Characterization of a thermosyphon heat exchanger for solar domestic hot water systems’, Journal of Solar Energy Engineering, Transactions of the ASME, 131, 0245021–0245024.
M. F. (2012) ‘Modeling and control of a solar thermal power plant with thermal energy storage’, Chemical Engineering Science, 71, 138–145. 28. F. et al. (2013) Final report Annex 25: Surplus Heat Management using Advanced TES for CO2 mitigation. 3. 28 Advances in Thermal Energy Storage Systems 29. Martin, V. and Vadiee, A. (2013) ‘Technoeconomical feasibility study of the integration of PCM-base thermal energy transportation in district energy systems’. 30. , Pérez, G. F. (2010) ‘Experimental study of using PCM in brick constructive solutions for passive cooling’, Energy and Buildings, 42, 534–540.
US Patent, US7588694B1. W. (2010) ‘Viscosity of multicomponent molten nitrate salt-liquidus to 200°C’, Sandia report. W. E. (1990) ‘High-temperature stability of ternary nitrate molten salts for solar thermal energy systems’, Solar Energy Materials, 21(1), 51–60. W. and Segel, N. (2008) ‘Molten nitrate salt development for thermal energy storage in parabolic trough solar power system’, Proceedings of Energy Sustainability, 2, 631–637. F. J. (2004) ‘Testing thermocline filler materials and moltensalt heat transfer fluids for thermal energy storage systems used in parabolic trough solar power plants’, SAND2004–3207.
Advances in thermal energy storage systems : methods and applications by Luisa F. Cabeza