@ARTICLE{Wang_Sihua_Multiphysics_2021, author={Wang, Sihua and Wang, Junjun and Zhou, Lijun and Chen, Long and Zhao, Lei}, volume={vol. 70}, number={No 3}, journal={Archives of Electrical Engineering}, pages={675-688}, howpublished={online}, year={2021}, publisher={Polish Academy of Sciences}, abstract={It is not easy to make the insulators of the railway catenary for the dry and cold environment of the icy Qinghai-Tibet plateau, without causing serious ice-related flashover accidents. To study the operating status of catenary icing insulators, a two-dimensional icing model of catenary cantilever insulators was established based on the winter environmental characteristics of the Golmud station on the Qinghai-Tibet Railway. Compared different directions of ice growth, the spatial electric field distribution, and surface temperature distribution characteristics of icing insulatorswere analyzed by multi-physical field coupling simulation. The results show that as the thickness of the ice layer increases and the length of the icicle increases, the field intensity of the insulator gradually increases, and the surface temperature continues to rise. When the ice edge grows vertically downward, the electric field intensity of the insulator is the smallest, and the electric field intensity is the largest when the ice edge grows horizontally. Although the surface temperature of the insulator will rise with the increase of icing degree, it is lower than the freezing point and will not have a great impact on insulation performance. Secondly, when the cantilever insulator is arranged obliquely, the increase in the inclination angle will cause the electric field to increase and the temperature to rise slightly, so the inclination angle of the oblique cantilever should be reduced as much as possible during installation. Finally, the insulator with better insulation performance is obtained by optimizing the structure of the flat cantilever insulator.}, type={Article}, title={Multiphysics simulation and shed structure optimization of catenary icing insulator}, URL={http://ochroma.man.poznan.pl/Content/120526/art12_corr.pdf}, doi={10.24425/aee.2021.137581}, keywords={cantilever icing insulator, electrostatic field, finite element simulation, multiphysical field coupling, temperature field}, }