INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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Advances and Prospects in Thermal Energy Storage:a Critical Review Based on CiteSpace |
CHEN Liping1, CAI Liang1, LI Guanghua1, ZHOU Qiang2
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1 School of Energy and Environment, Southeast University, Nanjing 210096 2 State Grid Jiangsu Integrated Energy Service Co., Ltd., Nanjing 210019 |
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Abstract Thermal energy storage, using the heat storage material to keep the energy and release it when required, is the technology utilized for adjusting the instability and time discrepancy between supply and demand of energy. It has wide ranges of applications in various fields, like solar thermal power generation, industrial waste heat recovery, thermal management of electronics, building energy conservation, etc. In order to make a systematical analysis of the developing tendency of this technology, the literatures on subject of “Thermal energy storage” (included in Web of Science, 2007—2017) have been taken as data resource and been analyzed with the visualization software CiteSpace. With the help of the software, a graph of country, institution and researcher cooperation in the technology of thermal energy storage has been made to indicate the distribution of its research power and the cooperating situations of the scientific research. By using the software co-occurrence analysis, the co-occurrence graphs of research fields and keywords have been made to indicate the prevailing fields of the research and its researching hotspots respectively. Meanwhile, by analyzing the co-citation of the literatures and making its network graph, the frontiers and developing tendency of this research have been concluded, which shows that the new multi-scale thermal storage composite materials as well as the hybrid thermal energy storage systems will be the focal points of the future research.
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Published: 08 May 2019
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Fund:This work was financially supported by the National Key Research and Development Program of China (2018YFC0705306) and the National Natural Science Foundation of China (6503000103). |
About author:: Liping Chen received her B.E. degree in Building Environment and Energy Application Engineering from Xinjiang University in 2014. She is currently pursuing her Ph.D. at the School of Energy and Environment, Southeast University under the supervision of Prof. Liang Cai. Her research has focused on thermal energy storage of molten salt. Liang Cai received his B.E. and Ph.D. degrees in thermal engineering from Southeast University in 1995 and 2002, respectively. He performed collaborative research in 2009 at University of Florida, USA. He is currently a full professor and doctoral supervisor in Southeast University. His research interests include optimal operation of gas heat pump, heat and mass transfer in porous media, heat transfer enhancement and thermal energy storage of molten salt and so on. He has published more than 30 journal papers. In addition, he was acquired the second-class award “National Technical Invention Award of China”. |
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