A REVIEW OF THE USE OF THERMAL SOLAR ENERGY WITH CAES SYSTEMS
DOI:
https://doi.org/10.59627/cbens.2016.1967Palavras-chave:
Thermal solar energy, CAES, TESResumo
Considering the importance of studying energy production and its storage, this paper conducts a survey of the most relevant publications already realized about the use of thermal solar energy with compressed air energy storage (CAES). Once solar energy devices meet some needs of CAES, they allow its usage for electricity generation in a much more clean way, without the necessity of burning fossil fuels. Moreover, when coupled to another store system like the thermal energy storage (TES), they enable compressed air use even during moments of no sunlight. These possibilities are treated here by gathering some works which best represent them. Also motivated by the fact that such promising combination still has a lack for new research, the authors propose a different system to be studied in future. All this data and the best references can be found in this paper and used to proceed with new investigation in this area.
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McGrail, B. P., Cabe, J., Davidson, C., Knudsen, F. S., Bacon, D., Bearden, M., Chamness, M., Horner, J., Reidel, S., Schaef, T., Spane, F., Thorne, P., 2013. Compressed Air Energy Storage: Grid-Scale Technology for Renewables Integration in the Pacific Northwest. Pacific Northwest National Laboratory. U.S. Department of Energy. Richland, Washington, USA.
Xia, C., Zhou, Y., Zhou, S., Zhang, P., & Wang, F., 2015. A simplified and unified analytical solution for temperature and pressure variations in compressed air energy storage caverns. Renewable Energy, 74, 718-726.
Raju, M., Khaitan, S. K., 2012. Modeling and simulation of compressed air storage in caverns: a case study of the Huntorf plant. Applied Energy, v. 89, n. 2, p. 474-481.
Crotogino, F., Mohmeyer, K. U., Scharf, R., 2001. Huntorf CAES: More than 20 years of successful operation. Spring 2001 Meeting. Orlando, Florida, USA.
Safaei Mohamadabadi, H., 2015. Techno-Economic Assessment of the Need for Bulk Energy Storage in Low-Carbon Electricity Systems With a Focus on Compressed Air Storage (CAES). Doctoral dissertation, Harvard University, Graduate School of Arts & Sciences.
ANEEL - Agência Nacional de Energia Elétrica. Atlas de energia elétrica do Brasil. 2 ed., 243 p., Brasília, Brazil.
Zhang, J., Zhao, H., 2014. A novel compressed air solar energy photo-thermal generating electricity system. Computer Modelling & New Technologies, 18(3), 39-43.
Sperling, J. G., Hayden, H., Alva , J. K., Rey, E., Simmons, J., Thiella, J., 2009. SolarCAT - A Practical Path to Renewable Energy Independence.
Nakatani, H., Osada, T., Kobayashi, K., Watabe, M., Tagawa, M., 2012. Development of a Concentrated Solar Power Generation System with a Hot-Air Turbine. Mitsubishi Heavy Industries Technical Review, v. 49, n. 1.
Kalaiselvam, S., Parameshwaran, R., 2014. Thermal Energy Storage Technologies for Sustainability: Systems Design, Assessment and Applications. Elsevier.
Grazzini, G., Milazzo, A., 2008. Thermodynamic analysis of CAES/TES systems for renewable energy plants. Renewable Energy, v. 33, n. 9, p. 1998-2006.
Grazzini, G., Milazzo, A., 2008. Exergy analysis of a CAES with thermal energy storage. Università di Firenze, Italy.
Porto, M., Pedro, H., Machado, L., Koury, R., Coimbra, C., 2014. Compressed and liquefied air storage systems for reducing power output variability from PV solar farms. La Jolla, California, 92093, USA.
Garvey, S. D., 2012. The dynamics of integrated compressed air renewable energy systems. Renewable Energy, v. 39, n. 1, p. 271-292.
Garrison, J. B., Webber, M. E., 2011. An integrated energy storage scheme for a dispatchable solar and wind powered energy systema). Journal of Renewable and Sustainable Energy, 3(4), 043101.