Серия «Энергетика»

Для отбора мощности из полуволновой электропередачи предлагается использование устройства, которое стабилизирует напряжение у нагрузки при изменении её мощности от нуля до максимального значения. При отборе мощности из полуволновой электропередачи режим напряжения в промежуточной системе отбора мощности должен соответствовать допустимым пределам и не оказывать влияния на режим передачи натуральной мощности по линии. С целью регулирования напряжения в линии предлагается использовать линейный регулятор-стабилизатор напряжения – тиристорный стабилизатор параметров в месте отбора мощности из полуволновой электропередачи. При этом для регулирования используется способ встречного регулирования напряжения в функции тока нагрузки, которая позволяет следить за изменением тока нагрузки с помощью трансформаторов тока, включенных в магистральную линию и линию отбора мощности.

Hubert F.J., Gent M.R. Half-Wavelength Power Transmission Lines. IEEE Transactions on Power Appa-ratus and Systems, 1965, vol. 84, pp. 965–974. DOI: 10.1109/tpas.1965.4766125

Prabhakara F.S., Parthasarathy K., Rao H.N.R. Performance of Tuned Half-Wave-Length Power Trans-mission Lines. IEEE Transactions on Power Apparatus and Systems, 1969, vol. PAS-88, pp. 1795–1802. DOI: 10.1109/tpas.1969.292295

Wang G., Li Q., Zhang L. Research Status and Prospects of the Half-Wavelength Transmission Lines. Asia-Pacific Power and Energy Engineering Conference, 2000.

Santos M.L. Jardini J.A., Masuda M., Nicola G.L.С. A Study and Design of Half-Wavelength Lines as

an option for long distance power transmission. IEEE PES Trondheim PowerTech: The Power of Technology for

a Sustainable Society, 2011. DOI: 10.1109/ptc.2011.6019235

Song Y., Fan B., Bai Y., Qin X., Zhang Z. Reliability and Economic Analysis of UHV Half-Wave-Length AC Transmission. IEEE International Conference on Power System Technology, POWERCON, 2012. DOI: 10.1109/powercon.2012.6401413

Gu P., Wang P., Han B., Xiang Z., Ban L., Zhao H., Jiao C. Route Construction Analysis and Overvoltage Characteristics of True Type Half Wavelength AC Transmission Line Test. Dianli Jianshe/Electric Power Con-struction, 2018, vol. 39, pp. 101–107.

Tang L., Dong X., Wang B., Shi S. Study on the Current Differential Protection for Half-Wave-Length AC Transmission Lines. IEEE Power and Energy Society General Meeting, 2018. DOI: 10.1109/pesgm.2017.8273851

Tavares M.C., Portela C.M. Half-Wave Length Line Energization Case Test – Proposition of a Real Test. International Conference on High Voltage Engineering and Application, ICHVE, 2008. DOI: 10.1109/ichve.2008.4773923

Iliceto F., Cinieri E. Analysis of Half-Wave Length Transmission Lines with Simulation of Corona Losses. IEEE Transactions on Power Delivery, 1988, vol. 3, pp. 2081–2091. DOI: 10.1109/61.194020

Samorodov G.I. Optimizatsiya skhem i parametrov dal'nikh i sverkhdal'nikh elektroperedach peremen-nogo toka: avtoref. dokt. diss. [Optimization of Circuits and Parameters of Long-Distance and Ultra-Long Alter-nating Current Transmissions. Abstract of doct. diss]. Novosibirsk, 1990. 32 p.

Samorodov G.I. Sverkhdal'nie elektroperedachi poluvolnovogo tipa [Ultra-Long Power Transmission of

a Half-Wave Type]. Novosibirsk, Science Publ., 2003. 177 p.

Zil'berman S.M. Metodicheskie i prakticheskie voprosy poluvolnovoy tekhnologii peredachi elektro-energii: avtoref. dokt. diss. [Methodical and Practical Questions of Half-Wave Technology of Electric Power Transmission. Abstract of doct. diss.]. Krasnoyarsk, 2009. 39 p.

Khoyutanov A.M., Kobylin V.P., Davydov G.I., Nesterov A.S., Vasil'ev P.F. [Distribution of Parameters Along Half-Wave Electricity Transmission and Its Capacity as Part of Association “ENES of the East of Russia”]. Mezhdunarodnyy zhurnal prikladnykh i fundamental'nykh issledovaniy [International Magazine of Applied and Basic Researches], 2016, no. 4-5, pp. 872–875. (in Russ.)

Khoyutanov A.M., Kobylin V.P., Vasil'ev P.F., Davydov G.I., Nesterov A.S. [Application of Half-Wave Technologies to Increase Capacity of Inter-System and Inter-Regional Power Lines]. Trudy VII evraziyskogo sim-poziuma po problemam prochnosti materialov i mashin dlya regionov kholodnogo klimata [Proceedings of

the VII Eurasian Symposium on Strength Problems of Materials and Machines for Cold-Climate Regions].

St. Peterburg, 2014, pp. 467–471. (in Russ.)

Kobylin V.P., Sedalishchev V.A., Li-Fir-Su R.P., Khoyutanov A.M., et al. [Development of Scientific and Methodological Support for Implementation of Energy Strategy of the North Region Taking into Account Fuel and Energy Complex and Main Transmission Lines of the UNEG Development in the East of Russia]. Institute of Physical and Technical Problems of the North, Jakutsk, 2013, 96 p. (in Russ.)

Kobylin V.P. Povyshenie ekspluatatsionnoy nadezhnosti elektrosetevogo khozyaystva na Severe

[Improving the Reliability and Efficiency of Ultra-Long Interconnects]. Novosibirsk, Nauka Publ., 2006.

p.

Khoiutanov A.M., Vasilyev P.F., Kobylin V.P. Increasing of Reliability and Efficiency of Long-Distance Intersystems Communications. Bulletin of the South Ural State University. Ser. Power Engineering, 2017, vol. 17, no. 3, pp. 67–75. (in Russ.) DOI: 10.14529/power170308

Khoyutanov A.M., Li-Fir-Su R.P., Kobylin V.P., Kobylin A.V. Ustroystvo otbora moshchnosti iz linii el-ektroperedachi [Power Take-Off from Power Transmission Line]. Patent RF, no. 2559024, 2014.

Khoyutanov A.M., Li-Fir-Su R.P., Kobylin V.P., Kobylin A.V. Sposob otbora moshchnosti iz polu-volnovoy elektroperedachi v “elektricheskom tsentre” [Method of Power Take-Off from Half-Wave Power Transmission in “Electrical Center”]. Patent RF, no. 2607649, 2015.

Kobylin A.V., Samorodov G.I., Zil'berman S.M., Kobylin V.P., Khoyutanov A.M. Promezhutochnyy otbor moshchnosti iz poluvolnovoy elektroperedachi [Intermediate Power Take-Off from Half-Wave Power Transmis-sion]. Electrical Technology Russia, 2015, no. 6, pp. 4–11.