ALGORITHM FOR AUTOMATIC COMPENSATION OF VOLTAGE DIPS IN POWER SUPPLY OF INDUSTRIAL FACILITIES
Keywords:
Voltage dip, automatic control system, quality of electro supply, dynamic compensator of voltage distortion
Abstract
The factors of failures and their impact on the equipment of large enterprises is discussined in this article. The optimal method for compensating voltage dips was selected and the principle of operation of the developed compensator operation algorithm is described. According to the algorithm, a model was developed at the MatLab Simulink environment. The graphs of the model are presented.
References
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[2] Abramovich, Boris & Ustinov, D.A. & Sychev, Yuriy & Shkljarskiy, A.Y.A.. (2014). The methods of voltage dips and distortion compensation in electrical networks of oil production enterprises. 110-112.
[3] Castro, karla maria & Alev, Üllar & Aparicio, Xabier & Arumägi, Endrik & Ascione, Fabrizio & Babin, Mihajlo & Bianco, Nicola & Burman, Esfandiar & Roset, Jaime & Corgnati, Stefano & Cotana, F. & D'Oca, Simona & De Masi, Rosa & De Stasio, Claudio & Portillo, Luis & Erić, Miloš & Erkoreka, A. & Fabrizio, Enrico & Ferrara, Maria & Xamán, Jesús. (2017). Cost-Effective Energy-Efficient Building Retrofitting - Materials, Technologies, Optimization and Case Studies.
[4] Testimony 2019611491 Russian Federation. Certificate of official registration of the computer program. simulation model of automatic control system for the installation of dynamic compensation of voltage dips / B.N. Abramovich, I.A. Bogdanov, V.I. Malarev; Applicant and copyright holder Federal State Budgetary Educational Institution of Higher Education "St. Petersburg Mining University" (RU) - No. 20169610240; declared 01/10/2019; publ. 01/28/2019.
[5] Abramovich, B & Bogdanov, I & Kopteva, Alexandra & Malarev, Vadim. (2019). The system of trigeneration with binary cycle for use as an energy source for gas fuel. IOP Conference Series: Materials Science and Engineering. 643. 012092. 10.1088/1757-899X/643/1/012092.
[6] Belsky, Aleksey & Dobush, Vasiliy & Malarev, V. (2020). Electro Steam Thermal Complex Powered by Wind-Driven Generator for the Treatment of the Oil Formation’s Bottomhole Area. Journal of Physics: Conference Series. 1441. 012020. 10.1088/1742-6596/1441/1/012020
[7] Bogdanov I.A., Veprikov A.A., Kasyanova A.N., Morenov V.A. Increase of energy efficiency of electrotechnical complexes of cogeneration plants for power supply of objects of oil and gas enterprises / International Research Journal. №: 12-5 (66) year: 2017. p. 59-63.
[8] Yemelyanov, V., Nedelkin, A., & Yemelyanova, N. (2020). Expert system software for assessing the technical condition of critical lined equipment doi:10.1007/978-3-030-37916-2_92
[9] Kuzmin, P. A., Bukharina, I. L., & Kuzmina, A. M. (2020). An investigation of the biochemical composition of norway maple (acer platanoides l.) in the conditions of technogenic stress. [Investigação da composição bioquímica do bordo da noruega (acer platanoides l.) nas condições de estresse tecnogênico] Periodico Tche Quimica, 17(34), 905-914.
[10] Yemelyanov, V. A., Yemelyanova, N. Y., Nedelkin, A. A., Glebov, N. B., & Tyapkin, D. A. (2019). Information system to determine the transported liquid iron weight. Paper presented at the Proceedings of the 2019 IEEE Conference of Russian Young Researchers in Electrical and Electronic Engineering, ElConRus 2019, 377-380. doi:10.1109/EIConRus.2019.8656693
[11] Yemelyanov, V. A., Nedelkin, A. A., & Olenev, L. A. (2019). An object-oriented design of expert system software for evaluating the maintenance of lined equipment. Paper presented at the 2019 International Multi-Conference on Industrial Engineering and Modern Technologies, FarEastCon 2019, doi:10.1109/FarEastCon.2019.8934414
