Distribution of Electric Field for EMU's Post Insulators Based on the Finite Element Method

Qing Bo Mu; Zhao Hua Zhang; Bu Chao Jia; Jian Qiao Ma

doi:10.4028/www.scientific.net/AMR.1070-1072.1652

Paper Titles

Research on Coordinated Charging Strategy for Electric Bus Battery Swapping Stations
p.1632

Study on Charging Business Operation Model of Electric Vehicle
p.1637

Economic Comparison of the Energy Saving and New Energy Vehicle – Taking China, US and Belgium as Examples
p.1642

Analysis of Transformer Overload Problem with EV Charging Load
p.1648

Distribution of Electric Field for EMU's Post Insulators Based on the Finite Element Method
p.1652

Study on Multi-Objective Optimal Planning of Electric Vehicle Charging Stations with Alternative Sites
p.1656

The Impact of Fast Charging for EVs on Distribution System
p.1664

Design on Electric Power Wheel Control System
p.1668

Braking Energy Recovery Research for Electric Vehicles
p.1672

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1070-1072Distribution of Electric Field for EMU's Post...

Distribution of Electric Field for EMU's Post Insulators Based on the Finite Element Method

Abstract:

Compared with power system, post insulators used in High-speed Electric Multiple Unit (EMU) have unique features such as limited space, low number of sheds and complex pantograph, which produces high electric field at some part of post insulators. When the insulators electric field exceeds a numerical value, it will produce corona discharge and reduce the reliability of High-speed EMU. At the same time, a distinct discharge phenomenon has been observed on the surface of the small curvature radius for pantograph. For guiding optimization of electric field for post insulators and pantograph, a simplified model of post insulators as well as the pantograph is established to calculate the distribution of potential and electric field based on ANSYS. Because the applied voltage cycle is far less than the relaxation time of the dielectric, electrostatic field module can be used in the ANSYS Simulation. By simulating, the maximum electric field is occurred at the pantograph angle and some measures should be taken to reduce the electric field to assure the reliability of the EMU. The potential would decrease along the axis of the post insulator and the first umbrella bear the largest voltage drop.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 1070-1072)

Pages:

1652-1655

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1070-1072.1652

Citation:

Cite this paper

Online since:

December 2014

Authors:

Qing Bo Mu*, Zhao Hua Zhang, Bu Chao Jia, Jian Qiao Ma

Keywords:

ANSYS, Electric Field, EMU, Finite Element Method (FEM), Post Insulator

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] ZezhongWang, Condensed Electromagnetic Calculation [M]. Beijing：Machinery Industry Press，2011: 106-122.

Google Scholar

[2] Guangzheng Ni, Shiyou Yang, JieQiu. Engineering Computational Electromagnetics [M]. Beijing：Machinery Industry Press, (2010).

Google Scholar

[3] XuchenWang. Finite Element Method [M]. Beijing: Tsinghua University Press, (2003).

Google Scholar

[4] JianyuanXu, FengWang, FengliangXiao. Total analysis and electric field calculation of GIS disconnectors for having 3 Poles in One Enclosure [J]. High Voltage Engineering, 2000, 26（1）: 11-13.

Google Scholar

[5] XingshanMa, JishiZhang. EMF foundation [M]. Beijing: Machinery Industry Press, 2004: 221-249.

Google Scholar

[6] XifongLiang. High Voltage Engineering [M]. Peking University Press, 2003: 33-34.

Google Scholar

[7] ANSYS Inc. Mechanical APDL, basic analysis guide, chapter 5: solution[R]. [S.L. ]: ANSYS Inc, (2009).

Google Scholar

[8] Wei Wang, YoupinTu. High Voltage Engineering [M]. Beijing: Machinery Industry Press, 2011: 56-59.

Google Scholar