Ключові слова
силові кабелі
макро- та мікрорівневі дефекти
фактори і механізми старіння ізоляції
перехідні процеси
високочастотні перенапруги
методи випробування
Як цитувати
Анотація
Наведено фактори та механізми старіння зшито-поліетиленової ізоляції силових кабелів, мультифізичні процеси та явища, що супроводжують деградацію і призводять до пробою ізоляції. Представлено характерні дефекти ізоляції, які виникають при виробництві, проектуванні, прокладанні та експлуатації кабелів. Проаналізовано причини виникнення дефектів і ушкоджень ізоляції. Показано роль електричних режимів роботи кабелів і переваги використання неруйнуючих методів їх випробування для тривалого терміну служби ізоляції. Бібл. 49, рис. 7, табл. 3.
Посилання
Burlakov E., Evdokunin G., Karpov A., Shatilov D. High-voltage lines with single-phase cables. Transients and overvoltages. Electrical Engineering News. 2016. No 5(101).
Verhoeven B. International practice of cable tests. Cables and wires. 2006. No 1 (296). Pp.10–14.
Guk D.A., Kamensky M.K., Makarov L.E., Obraztsov Yu.V., Ovsienko V.L., Shuvalov M.Yu. Experience in testing and research of power cables, fittings and materials for their production. Cables and wires. 2014. No 5(348). Pp. 35–42.
Dmitriev M.V. Features of the use of cables with cross-linked polyethylene insulation. Networks of Rus-sia. 2015. No 3 (30). Pp. 62–65.
Dmitriev M.V. Design and construction of cable lines 6–500 kV. Actual problems. Electrical Engineering News. 2016. No 4(100). http://www.news.elteh.ru/arh/2016/100/03.php
Kovrigin L.A. Technological and operational defects in cable insulation. Kabel-news. 2008. No10. Pp. 58 –60.
Kopchenkov D. Diagnostics of high-voltage cable lines. Implementation experience. Kabel -news. 2012. No 3.
Korolev A. Testing and diagnostics of cable lines with insulation from cross-linked polyethylene. Kabel -news. 2010. No 11.
Kucheryavaya I.N. Influence of microdefects in polyethylene insulation of power cables on the distribu-tion of electric field. Pratsi Instytutu Elektrodynamiky NANU. 2017. Issue. 47. Pp 85–92.
Kucheryavaya I.N. Investigation of operational defects of power cables with cross-linked polyethylene insulation. Pratsi Instytutu Elektrodynamiky NANU. 2017. Issue 46. Pp. 107–112.
Kucheryavaya I.N. Causes of failure of couplings of cables with insulation of cross-linked polyethylene for medium and high voltage. Hidroenerhetyka Ukrainy. 2017. No 1–2. Pp. 63–80.
Kuchinsky G.S. Partial discharges in high-voltage constructions. L.: Energiya, 1979. 224 p.
Makarov E.F. Handbook on electric networks 0.4–35 kV and 110–1150 kV. Ed. by I.T. Goryunov, A.A. Lyubimov. Vol. 3. M.: Papirus-Pro, 2004. 688 p.
Meshchanov G.I., Shuvalov M.Yu., Kamensky M.K., Obraztsov Yu.V., Ovsienko V.L. Cables for voltage 10–500 kV: state and prospects of development (analysis, forecast, research). Cables and wires. 2008. No 5 (312). Pp. 32–38.
Obraztsov Yu.V. Domestic cables of medium and high voltage with insulation of cross-linked polyethylene for power lines. Kabel-news. 2009–2010. No 12–1. Pp. 45–49.
Obraztsov Yu.V., Frick A.A., Slivov A.A. Power cables of medium voltage with insulation made of cross-linked polyethylene. Quality factors. Cables and wires. 2005. No 1 (290). Pp. 9–13.
Podoltsev A.D. Computer modeling of lightning overvoltages in a high-voltage overhead power line. Pratsi Instytutu Elektrodynamiky NANU. 2017. Issue 46. Pp. 94–106.
Podoltsev A.D., Kucheryavaya I.N. Multiphysical processes in the field of inclusion of power cable in polyethylene insulation (three-dimensional modeling and experiment). Tehnichna Elektrodynamika. 2015. No 3. Pp. 3–9.
Podoltsev A.D., Kucheryavaya I.N. Multiphysical modeling in electrical engineering. K.: Institute of Elec-trodynamics of the National Academy of Sciences of Ukraine, 2015. 305 p.
Shidlovsky A.K., Shcherba A.A., Zolotarev V.M., Podoltsev A.D., Kucheryavaya I.N. Cables with polymer insulation for ultrahigh voltages. Kyiv: Publishing House of the Institute of Electrodynamics of the Na-tional Academy of Sciences of Ukraine, 2013. 550 p.
Shuvalov M.Yu., Romashkin A.V., Ovsienko V.L. Analysis of defects in the insulation of power high-voltage cables by methods of videomicroscopy and microexperiment. Electricity. 2000. No 5. Pp. 49–57.
Shcherba A.A., Gurin A.G., Olshevsky A.M., Karpushenko V.P., Naumenko A.A. New technology of peroxide crosslinking of polyethylene insulation - the basis for the production of highly reliable power ca-bles for a voltage of 6-500 kV. Elektropanorama. 2012. 4. Pp. 16–21.
Shcherba A.A., Kucheryavaya I.N., Zolotarev V.M., Belyanin R.V. Features of production and operation of cross-linked-polyethylene insulation of power cables of different voltage classes. Hidroenerhetyka. Ukrainy. 2016. No 1–2. Pp. 30–40.
Shcherba A.A., Kucheryavaya I.N., Kirik V.V., Tsyganenko B.V. World experience in the use of cross-linked polyethylene insulation for the production of power cables of different voltage classes. Elektricheskiye seti I systemy. 2015. No 5. Pp. 11–20.
Bahadoorsingh S., Rowland S.M. A framework linking knowledge of insulation ageing to asset management. IEEE Electrical Insulation Magazine. 2008. Vol. 24. Is. 3. Pp. 38–46.
Bernstein B.S. Recent progress in understanding water treeing phenomena. IEEE International Symposium on Electrical Insulation. Montreal, June 11–13, 1984. Pp. 11–21.
Buchholz V. Finding the root cause of power cable failures.
Crine J-P., Jow J. A water treeing model. IEEE Trans. on Dielectrics and Electrical Insulation. 2005. Vol. 12. No 4. Pp. 801–808.
Densley J. Ageing and diagnostics in extruded insulations for power cables. IEEE 5th Internat. Conf. on Conduction and Breakdown in Solid Dielectrics. 1995. 15 p.
Densley J. Ageing mechanisms and diagnostics for power cables – an overview. IEEE Electrical Insulation Magazine. 2001. Vol. 17. No. 1. Pp. 14–22.
Dissado L., Fothergill J. Electrical degradation and breakdown in polymers. IEE Materials and Devices. Series 9. Peter Peregrinus Ltd., London, 1992. 601 p.
Doedens E.H. Organic contaminants in crosslinked polyethylene for demanding high voltage applications. Diploma Work in the Master Programme of Electric Power Engineering. 2012. Chalmers University of Technology, Gothenburg, Sweden. Report No. 83. 2012. 86 p.
Electrical power cable engineering. Third Edition. Ed. by W.A. Thue. CRC Press, 2011. 460 p.
Foottit E. Statistical, electrical and mathematical analysis of water treed cross-linked polyethylene cable insulation. Thesis for the degree of Doctor of Philosophy in the School of Engineering Systems Science and Engineering Faculty at the Queensland University of Technology. Brisbane, Australia. 2015. 214 p.
Hampton N. HV and EHV cable system aging and testing issues. Chapter 3. University System of Georgia, Institute of Technology NEETRAC. National Electric Energy Testing, Research and Application Center. Georgia Tech Research Corporation, February 2016. 19 p.
Hampton N. Medium voltage cable system issues. Chapter 2. University System of Georgia, Institute of Technology NEETRAC. National Electric Energy Testing, Research and Application Center. Georgia Tech Research Corporation, February 2016. 29 p.
Hampton N., Hartlein R., Lennartsson H., Orton H., Ramachadran R. Long-life XLPE insulated power ca-ble. – JiCable 2007. http://www.neetrac.gatech.edu/publications/jicable07_C_5_1_5.pdf
Hughes M.P. Numerical simulation of dielectrophoretic ratchet structures. Journal of Physics D: Applied Physics 2004. Vol. 37. Pp. 1275–1280.
Hvidsten S., Holmgren B., Adeen L., Wetterstrom J. Condition assessment of 12- and 24- kV XLPE cables installed during the 80s. Results from a joint Norwegian/Swedish research project. IEEE Electrical Insula-tion Magazine. 2005. Vol. 21. No 6. Pp. 17–23.
Kucheriava I.M. Coupled electrical and mechanical processes in polyethylene insulation with water tree having branches of complex structure. Tekhnichna Elektrodynamika. 2016. No 5. Pp. 5–10.
Kucheriava I.M. Power cable defects and their influence on electric field distribution in polyethylene in-sulation. Tekhnichna Elektrodynamika. 2017. No 2. Pp. 19–24.
Marcolongo P. Modeling electromechanical phenomena contributing to cable deterioration. Thesis for the degree of Master of Science in Engineering .Materials Science and Engineering. University of Puda, Italy, 2008. 58 p.
Mashikian M. S., Szatkowski A. Medium voltage cable defects revealed by off-line partial discharge testing at power frequency. IEEE Electrical Insulation Magazine. 2006. Vol. 22. No. 4. Pp. 24–32.
Nexans Technical Review. October 2004.– http://www.nexans.com/eservice/Corporate-en/fileLib rary/Download_540073071/eService/files/tech_review2d.pdf
Patsch R. The role of dielectrophoresis in the water treeing process. 1995 Annual Report. Conference on Electrical Insulation and Dielectric Phenomena. 22–25 Oct. 1995. Pp. 73–76.
Peshkov Iz. B., Shuvalov M. Yu., Ovsienko V.L. Water treeing in extruded cable insulation as Rehbinder electrical effect. Journal of Information Technology and Applications (JITA). 2015. No 5. Pp. 55–60.
Steennis E.F., Kreuger F.H. Water treeing in polyethylene cables. Review. IEEE Trans. on Electrical Insu-lation. 1990. Vol. 25. No 5. Pp. 989–1028.
Teyssedre G., Laurent C. Advances in high-field insulating polymeric materials over the past 50 years. IEEE Electrical Insulation Magazine. 2013. Vol. 29. No 5. Pp. 26–36.
Williams F.D. Cable accessory failure analysis. A Research Center in the School of Electrical and Computer Engineering at the Georgia Institute of Technology. 2010. 59 p.
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