Development of a Model Wind and Solar Power Installation Comprising High-Temperature Superconductors

L. I. Chubraeva, V. F. Shyshlakov, M. A. Turubanov, S. S. Tymofeyev, D. A. Volkov

Abstract


Abstract
The investigation of main performance properties of the hybrid wind and solar power installation with application superconductive elements was carried out. In the frames of the study, both mathematical simulations and experimental testing were performed. The study shows some difficulties to be solved during mutual operation of the various high-temperature superconductivity (HTSC) devices, especially if they operate with semi-conductive systems.


Keywords


Hybrid wind; Solar power installation; High-temperature superconductivity (HTSC); Renewable energy; Simulation; SMES; Fault current limiter; Physical modeling

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References


A66hmed, N. A., & Miyatake, M. (2006). A stand-alone hybrid generation system combining solar photovoltaic and wind turbine with simple maximum power point tracking control. Proceedings of CES/IEEE 5th International Conference on Power Electronics and Motion Control, 1, 1-7.

Andreev, E. N., Chubraeva, L. I., Korotkov, D. A., Manzuk, M. V., Timofeyev, S. S., Vandyuk, N. Y.,…, Volynkin, I. V. (2007). Results of development and investigation of HTSC electric power installation. Proceedings of JAPMED’5 Fifth Japanese-Mediterranean Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting and Nano Materials, 2, 156-157.

Chubraeva, L., Sokolovsky, V., & Meerovich V. (2010). Investigation of inductive FCL with a split winding and SMES with magnetic core intended for operation in superconducting complexes. Superconductivity, 1.

Chubraeva, L., Sokolovsky, V., & Meerovich, V. (2010). An improved design of an inductive fault current limiter based on a superconductive cylinder. Superconductor science and technology. USA: IOP Publishing.

De S. Ribeiro, L. A., Saavedra, O. R., De Matos, J. G., Bonan, G., & Martins, A. S. (2009). Small renewable hybrid systems for standalone applications. Proceedings of IEEE Power Electronics and Machines in Wind Applications, 1, 1-7.

Jahdi, S., Lai, L. L., & Nankoo, D. (2011). Grid integration of wind-solar hybrid renewables using AC/DC converters as DG power sources. Proceedings of World Congress on Sustainable Technologies, 171-177.

Weiss, H., & Xiao, J. (2003). Fuzzy system control for combined wind and solar power distributed generation unit. Proceedings of IEEE International Conference on Industrial Technology, 2, 1160- 1165.

Yi, L., Agelidis, V. G., & Shrivastava, Y. (2009). Wind-solar resource complementarity and its combined correlation with electricity load demand. Proceedings of 4th IEEE Conference on Industrial Electronics and Applications, 2, 3623-3628.




DOI: http://dx.doi.org/10.3968/j.est.1923847920130602.2374

DOI (PDF): http://dx.doi.org/10.3968/g5285

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