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Оглавление1 1 Tang, Y., Zhong, J., and Liu, J. (2016). A Generation adjustment methodology considering fluctuations of loads and renewable energy sources. IEEE Transactions on Power Systems 31 (1): 125–132.
2 2 Malinowski, M., Milczarek, A., Kot, R. et al. (2015). Optimized energy‐conversion systems for small wind turbines: renewable energy sources in modern distributed power generation systems. IEEE Power Electronics Magazine 2 (3): 16–30.
3 3 Berseneff, B., Perrin, M., Quoc, T.T. et al. (2014). The significance of energy storage for renewable energy generation and the role of instrumentation and measurement. IEEE Instrumentation & Measurement Magazine 17 (2): 34–40.
4 4 Díaz, N.L., Luna, A.C., Vasquez, J.C., and Guerrero, J.M. (2017). Centralized control architecture for coordination of distributed renewable generation and energy storage in islanded AC microgrids. IEEE Transactions on Power Electronics 32 (7): 5202–5213.
5 5 Wei, W., Liu, F., Mei, S., and Hou, Y. (2015). Robust energy and reserve dispatch under variable renewable generation. IEEE Transactions on Smart Grid 6 (1): 369–380.
6 6 Wang, Z., Chen, Y., Mei, S. et al. (2017). Optimal expansion planning of isolated microgrid with renewable energy resources and controllable loads. IET Renewable Power Generation 11 (7): 931–940.
7 7 Mohan, V., Suresh, R., Singh, J.G. et al. (2017). Microgrid energy management combining sensitivities, interval and probabilistic uncertainties of renewable generation and loads. IEEE Journal on Emerging and Selected Topics in Circuits and Systems 7 (2): 262–270.
8 8 Yang, P. and Nehorai, A. (2014). Joint optimization of hybrid energy storage and generation capacity with renewable energy. IEEE Transactions on Smart Grid 5 (4): 1566–1574.
9 9 Li, N. and Hedman, K.W. (2015). Economic assessment of energy storage in systems with high levels of renewable resources. IEEE Transactions on Sustainable Energy 6 (3): 1103–1111.
10 10 Wong, S. and Pinard, J.P. (2017). Opportunities for smart electric thermal storage on electric grids with renewable energy. IEEE Transactions on Smart Grid 8 (2): 1014–1022.
11 11 Baker, K., Guo, J., Hug, G., and Li, X. (2016). Distributed MPC for efficient coordination of storage and renewable energy sources across control areas. IEEE Transactions on Smart Grid 7 (2): 992–1001.
12 12 Hill, C.A., Such, M.C., Chen, D. et al. (2012). Battery energy storage for enabling integration of distributed solar power generation. IEEE Transactions on Smart Grid 3 (2): 850–857.
13 13 Djairam, D., Morshuis, P.H.F., and Smit, J.J. (2014). A novel method of wind energy generation‐the electrostatic wind energy converter. IEEE Electrical Insulation Magazine 30 (4): 8–20.
14 14 Abdelsamad, S.F., Morsi, W.G., and Sidhu, T.S. (2015). Impact of wind‐based distributed generation on electric energy in distribution systems embedded with electric vehicles. IEEE Transactions on Sustainable Energy 6 (1): 79–87.
15 15 Wang, H. and Huang, J. (2016). Cooperative planning of renewable generations for interconnected microgrids. IEEE Transactions on Smart Grid 7 (5): 2486–2496.
16 16 Betie, A., Rao, U.M., Fofana, I. et al. (Dec. 2019). Influence of cellulose paper on gassing tendency of transformer oil under electrical discharge. IEEE Transactions on Dielectrics and Electrical Insulation 26 (6): 1729–1737.
17 17 Leila, S., Zafour, H., Rao, U.M., and Fofana, I. (2019). Regeneration of transformer insulating fluids using membrane separation technology. Energies 12 (3): 368.
18 18 Theraja, B.L. and Theraja, A.K. (2014). Electrical Technology, vol. II. New Delhi, India: S. Chand Publishers.
19 19 Kulkarni, S.V. and Khaparde, S.A. (2004). Transformer Engineering: Design and Practice. CRC Press.
20 20 ASTM (2018). D117‐18, Standard Guide for Sampling, Test Methods, and Specifications for Electrical Insulating Liquids. West Conshohocken, PA: ASTM International.
21 21 Chakravorti, S., Dey, D., and Chatterjee, B. (2013). Recent Trends in the Condition Monitoring of Transformers, 1ste. London: Springer‐Verlag.
22 22 Kassi, K.S., Fofana, I., Meghnefi, F., and Yeo, Z. (2015). Impact of local overheating on conventional and hybrid insulations for power transformers. IEEE Transactions on Dielectrics and Electrical Insulation 22 (5): 2543–2553.
23 23 Rao, U.M., Sood, Y.R., and Jarial, R.K. (2016). Physiometric and Fourier transform infrared spectroscopy analysis of cellulose insulation in blend of mineral and synthetic ester oils for transformers. IET Science, Measurement & Technology 11 (3): 297–304.
24 24 Rao, U.M., Fofana, I., Betie, A. et al. (Nov.‐Dec. 2019). Condition monitoring of in‐service oil‐filled transformers: case studies and experience. IEEE Electrical Insulation Magazine 35 (6): 33–42.
25 25 Martin, D., Saha, T., Gray, T., and Wyper, K. (2015). Determining water in transformer paper insulation: effect of measuring oil water activity at two different locations. IEEE Electrical Insulation Magazine 31 (3): 18–25.
26 26 Martin, D., Saha, T., Dee, R. et al. (2015). Determining water in transformer paper insulation: analyzing ageing transformers. IEEE Electrical Insulation Magazine 31 (5): 23–32.
27 27 Claiborne, C.C. and Pearce, H.A. (1989). Transformer fluids. IEEE Electrical Insulation Magazine 5 (4): 16–19.
28 28 Plessner, K.W. and Reynolds, E.H. (1976). New pure or blended liquids for high voltage application. CIGRE Report No. 15‐07.
29 29 Bartnikas, R. (1994). Electrical insulating liquids. In: Engineering Dielectrics, vol. 3. American Society for Testing and Materials.
30 30 Fofana, I. (2013). 50 Years in the development of insulating liquids. IEEE Electrical Insulation Magazine 29 (5): 13–25.
31 31 Rao, U.M., Fofana, I., Jaya, T. et al. (2019). Alternative dielectric fluids for transformer insulation system: research progress, challenges, and future prospects. IEEE Access 7 (1): 1–20.
32 32 Rao, U.M., Sood, Y.R., and Jarial, R.K. (2015). Review on ester based dielectric liquids for transformer insulation technology. In 2015 International Conference on Condition Assessment Techniques in Electrical Systems (CATCON).