This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Rentschler, A., Kuhn, G., Delzenne, M., & Kuhn, O. (2018, April). Medium voltage dc, challenges related to the building of long overhead lines. In 2018 IEEE/PES Transmission and Distribution Conference and Exposition (T&D) (pp. 1-5). IEEE.RentschlerA.KuhnG.DelzenneM.KuhnO. (2018, April). Medium voltage dc, challenges related to the building of long overhead lines. In 2018 IEEE/PES Transmission and Distribution Conference and Exposition (T&D) (pp. 1-5). IEEE.Search in Google Scholar
Moghadam, M. A., Bagheri, S., Salemi, A. H., & Tavakoli, M. B. (2023). Long-term maintenance planning of medium voltage overhead lines considering the uncertainties and reasons for interruption in a real distribution network. Reliability Engineering & System Safety, 233, 109089.MoghadamM. A.BagheriS.SalemiA. H.TavakoliM. B. (2023). Long-term maintenance planning of medium voltage overhead lines considering the uncertainties and reasons for interruption in a real distribution network. Reliability Engineering & System Safety, 233, 109089.Search in Google Scholar
Piantini, A., Borghetti, A., & Nucci, C. A. (2020). Lightning interaction with medium-voltage overhead power distribution systems. In Lightning interaction with power systems (pp. 113-172). Institution of Engineering and Technology.PiantiniA.BorghettiA.NucciC. A. (2020). Lightning interaction with medium-voltage overhead power distribution systems. In Lightning interaction with power systems (pp. 113-172). Institution of Engineering and Technology.Search in Google Scholar
Velásquez, R. M. A. (2019). Performance improvement in long overhead lines associated to single-phase faults due to atmospheric discharges. Engineering Failure Analysis, 105, 347-372.VelásquezR. M. A. (2019). Performance improvement in long overhead lines associated to single-phase faults due to atmospheric discharges. Engineering Failure Analysis, 105, 347-372.Search in Google Scholar
Alsumaidaee, Y. A. M., Yaw, C. T., Koh, S. P., Tiong, S. K., Chen, C. P., & Ali, K. (2022). Review of medium-voltage switchgear fault detection in a condition-based monitoring system by using deep learning. Energies, 15(18), 6762.AlsumaidaeeY. A. M.YawC. T.KohS. P.TiongS. K.ChenC. P.AliK. (2022). Review of medium-voltage switchgear fault detection in a condition-based monitoring system by using deep learning. Energies, 15(18), 6762.Search in Google Scholar
Bindi, M., Piccirilli, M. C., Luchetta, A., & Grasso, F. (2023). A comprehensive review of fault diagnosis and prognosis techniques in high voltage and medium voltage electrical power lines. Energies, 16(21), 7317.BindiM.PiccirilliM. C.LuchettaA.GrassoF. (2023). A comprehensive review of fault diagnosis and prognosis techniques in high voltage and medium voltage electrical power lines. Energies, 16(21), 7317.Search in Google Scholar
Jeong, D. I., Sushama, L., Vieira, M. J., & Koenig, K. A. (2018). Projected changes to extreme ice loads for overhead transmission lines across Canada. Sustainable Cities and Society, 39, 639-649.JeongD. I.SushamaL.VieiraM. J.KoenigK. A. (2018). Projected changes to extreme ice loads for overhead transmission lines across Canada. Sustainable Cities and Society, 39, 639-649.Search in Google Scholar
Zhao, Q., Liu, Z., Yu, P., Chen, L., & Guan, F. (2022, April). Review of transmission line icing and anti-icing technologies. In The proceedings of the 16th Annual Conference of China Electrotechnical Society: Volume II (pp. 1224-1232). Singapore: Springer Nature Singapore.ZhaoQ.LiuZ.YuP.ChenL.GuanF. (2022, April). Review of transmission line icing and anti-icing technologies. In The proceedings of the 16th Annual Conference of China Electrotechnical Society: Volume II (pp. 1224-1232). Singapore: Springer Nature Singapore.Search in Google Scholar
Brettschneider, S., & Fofana, I. (2021). Evolution of countermeasures against atmospheric icing of power lines over the past four decades and their applications into field operations. Energies, 14(19), 6291.BrettschneiderS.FofanaI. (2021). Evolution of countermeasures against atmospheric icing of power lines over the past four decades and their applications into field operations. Energies, 14(19), 6291.Search in Google Scholar
Velásquez, R. A., & Mejía, J. (2020, September). Structures in power lines and ice overload on cables. In 2020 IEEE PES Transmission & Distribution Conference and Exhibition-Latin America (T&D LA) (pp. 1-6). IEEE.VelásquezR. A.MejíaJ. (2020, September). Structures in power lines and ice overload on cables. In 2020 IEEE PES Transmission & Distribution Conference and Exhibition-Latin America (T&D LA) (pp. 1-6). IEEE.Search in Google Scholar
Huang, W., Hu, B., Shahidehpour, M., Sun, Y., Sun, Q., Yan, M., & Xie, K. (2021). Preventive scheduling for reducing the impact of glaze icing on transmission lines. IEEE Transactions on Power Systems, 37(2), 1297-1310.HuangW.HuB.ShahidehpourM.SunY.SunQ.YanM.XieK. (2021). Preventive scheduling for reducing the impact of glaze icing on transmission lines. IEEE Transactions on Power Systems, 37(2), 1297-1310.Search in Google Scholar
Wang, J. (2024, August). Automatic location method for high-risk area of ice dance disaster on 220kV high voltage transmission line. In Ninth International Conference on Electromechanical Control Technology and Transportation (ICECTT 2024) (Vol. 13251, pp. 625-630). SPIE.WangJ. (2024, August). Automatic location method for high-risk area of ice dance disaster on 220kV high voltage transmission line. In Ninth International Conference on Electromechanical Control Technology and Transportation (ICECTT 2024) (Vol. 13251, pp. 625-630). SPIE.Search in Google Scholar
Zhang, Z., Zhang, H., Yue, S., & Zeng, W. (2023). A review of icing and anti-icing technology for transmission lines. Energies, 16(2), 601.ZhangZ.ZhangH.YueS.ZengW. (2023). A review of icing and anti-icing technology for transmission lines. Energies, 16(2), 601.Search in Google Scholar
Zhu, Y., Tan, Y., Huang, Q., Huang, F., Zhu, S., & Mao, X. (2019, November). Research oTroppauer, W., Lovrenčić, V., Gubeljak, N., Nemeth, B., Kovač, M., Gocsei, G., & Krisper, U. (2019, June). Advanced monitoring of icing and prevention against icing on overhead power lines. In Proceedings of Int. Workshop on Atmospheric Icing of Structures IWAIS.n melting and de-icing methods of lines in distribution network. In 2019 IEEE 3rd Conference on Energy Internet and energy system Integration (EI2) (pp. 2370-2373). IEEE.ZhuY.TanY.HuangQ.HuangF.ZhuS.MaoX. (2019, November). Research oTroppauerW.LovrenčićV.GubeljakN.NemethB.KovačM.GocseiG.KrisperU. (2019, June). Advanced monitoring of icing and prevention against icing on overhead power lines. In Proceedings of Int. Workshop on Atmospheric Icing of Structures IWAIS.n melting and de-icing methods of lines in distribution network. In 2019 IEEE 3rd Conference on Energy Internet and energy system Integration (EI2) (pp. 2370-2373). IEEE.Search in Google Scholar
Zhou, X., Zhu, Y., Zhang, Y., & Li, H. (2022, February). A review of anti-icing and de-icing technology of overhead ground wire. In 2022 International Symposium on Electrical, Electronics and Information Engineering (ISEEIE) (pp. 282-286). IEEE.ZhouX.ZhuY.ZhangY.LiH. (2022, February). A review of anti-icing and de-icing technology of overhead ground wire. In 2022 International Symposium on Electrical, Electronics and Information Engineering (ISEEIE) (pp. 282-286). IEEE.Search in Google Scholar
Wang, Z. (2017). Recent progress on ultrasonic de-icing technique used for wind power generation, high-voltage transmission line and aircraft. Energy and Buildings, 140, 42-49.WangZ. (2017). Recent progress on ultrasonic de-icing technique used for wind power generation, high-voltage transmission line and aircraft. Energy and Buildings, 140, 42-49.Search in Google Scholar
Farzaneh, M., & Chisholm, W. A. (2022). Systems for De-Icing Overhead Power Line Conductors and Ground Wires. In Techniques for Protecting Overhead Lines in Winter Conditions: Dimensioning, Icephobic Surfaces, De-Icing Strategies (pp. 157-194). Cham: Springer International Publishing.FarzanehM.ChisholmW. A. (2022). Systems for De-Icing Overhead Power Line Conductors and Ground Wires. In Techniques for Protecting Overhead Lines in Winter Conditions: Dimensioning, Icephobic Surfaces, De-Icing Strategies (pp. 157-194). Cham: Springer International Publishing.Search in Google Scholar
Ji, K., Zhang, L., Zhan, X., Liu, B., & Yang, J. (2020, June). Analysis of mechanical de-icing method for low voltage overhead transmission lines. In 2020 IEEE 5th Information Technology and Mechatronics Engineering Conference (ITOEC) (pp. 1652-1656). IEEE.JiK.ZhangL.ZhanX.LiuB.YangJ. (2020, June). Analysis of mechanical de-icing method for low voltage overhead transmission lines. In 2020 IEEE 5th Information Technology and Mechatronics Engineering Conference (ITOEC) (pp. 1652-1656). IEEE.Search in Google Scholar
Guo, Z., Zhang, T., Jia, L., Liu, R., & Duan, W. (2024). Intelligent control and optimization of uninterrupted power serving de-icing technology for 110 kV power lines. International Journal of Low-Carbon Technologies, 19, 1910-1918.GuoZ.ZhangT.JiaL.LiuR.DuanW. (2024). Intelligent control and optimization of uninterrupted power serving de-icing technology for 110 kV power lines. International Journal of Low-Carbon Technologies, 19, 1910-1918.Search in Google Scholar
Mingting Wu, Yunlong Zhou & Mei Yang. (2025). Effect of forced lateral vibration on flow and heat transfer performance within an annular fuel element. International Journal of Thermal Sciences109523-109523.MingtingWuYunlongZhouMeiYang (2025). Effect of forced lateral vibration on flow and heat transfer performance within an annular fuel element. International Journal of Thermal Sciences109523-109523.Search in Google Scholar
Werner, Ulrich. (2021). Foundation forces caused by dynamic air gap torques of converter driven induction motors influenced by active vibration control: a theoretical analysis. Electrical Engineering(4), 1-18.WernerUlrich. (2021). Foundation forces caused by dynamic air gap torques of converter driven induction motors influenced by active vibration control: a theoretical analysis. Electrical Engineering(4), 1-18.Search in Google Scholar
Christopher DeLaFuente Navarro, Pedro Lastra González, Irune Indacoechea Vega & Daniel Castro Fresno. (2024). Mechanical, rheological and functional consequences of healing of porous asphalt mixtures by magnetic induction. Construction and Building Materials139090-139090.Christopher DeLaFuenteNavarroPedro LastraGonzálezIrune IndacoecheaVegaDaniel CastroFresno (2024). Mechanical, rheological and functional consequences of healing of porous asphalt mixtures by magnetic induction. Construction and Building Materials139090-139090.Search in Google Scholar
