Study on the influence of transient processes in pantograph-catenary contact-loss on the characteristics of glue rail insulation

Abstract

Electrified railways are complex electromagnetic systems that feature strong-weak electrical interactions and the coexistence of dynamic and static components. In this system, rails serve dual roles as signaling circuits and traction return channels. With the increase in operating speeds and the optimization of operational strategies, greater traction currents and more frequent traction switching when passing neutral zones pose higher demands on the signaling system’s EMI immunity, and the insulation joints’ voltage tolerance. This paper investigates the impact of pantograph-catenary contact-loss during train passing neutral zones on the return current cut-off insulation joints (referred to as ‘cut-off joints’). First, a circuit model is established based on the traction return system principles and the cut-off joints’ configuration scheme. Key model parameters are determined to clarify the mechanisms, influencing factors, and coupling paths of transient pulses during the contact-loss process. The propagation characteristics of these pulses in rails are analyzed. The results indicate that in typical scenarios, cut-off joints experience an impulse voltage peak of 4 kV and a frequency of 109 kHz as the train exits the neutral zone. Using the ANSYS Maxwell platform, a finite element modeling simulation is conducted to analyze the electric field distribution of the insulation joint structure under both ideal and defect conditions when subjected to impulse voltages. Finally, all results are validated through field tests, and optimization suggestions are proposed. This study contributes to fault tracing in glue rail insulation, provides a basis for setting electrical standards, and offers guidance for designing stationary current channels.

Keywords

High-speed railway pantograph-catenary contact-loss transient analysis finite-element method insulation joints voltage withstand

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References

Wei

Liang

Yang

, et al. A novel method for detecting the pantograph–catenary arc based on the arc sound characteristics. Proceedings of The Institution of Mechanical Engineers, Part F-Journal of Rail and Rapid Transit 2019; 233(5): 506–515.

Liu

Quan

, et al. A novel arcing detection model of pantograph–catenary for high-speed train in complex scenes. IEEE Trans Instrum Meas 2023; 72: 1–13. DOI: 10.1109/TIM.2023.3267365.

Wang

Han

, et al. Mathematical model of pantograph arc based on probability distribution of arc parameters. IEEE Transactions on Transportation Electrification 2023; 9(2): 2026–2037.

Wen

Sun

, et al. Analysis of propagation characteristics of electromagnetic disturbance from the off-line of pantograph-catenary in high-speed railway viaducts. Chinese J. Electron; 29: 966–972. DOI: 10.1049/cje.2020.08.013.

Yang

Cao

Gao

, et al. Analysis of surge overvoltage of dropping pantograph for high-speed EMUs. J China Railw Soc 2015; 2015(7): 46–50. DOI: 10.3969/j.issn.1001-8360.2015.07.008.

Huang

Liu

Wang

, et al. Analysis on railcar's body over-voltage distributional characteristics considering operating conditions of high-speed railway station. J China Railw Soc 2016; 38(9): 38–45. DOI: 10.3969/j.issn.1001-8360.2016.09.006.

Wang

Gao

, et al. Analysis of EMUs vehicle body voltage caused by pantograph-catenary off-line arc. In: The 3rd International Conference on Electrical and Information Technologies for Rail Transportation (EITRT). Singapore: Springer, 2018, vol 483, pp. 165–173.

Yang

Cao

Zhang

, et al. Research on the influence of pantograph catenary contact loss arcs and zero-crossing stage on electromagnetic disturbance in high-speed railway. Energies 2024; 17: 138. DOI: 10.3390/en17010138.

Qian

Gao

Dong

, et al. Research on driving force and dynamic characteristics of pantograph–catenary arc. J Phys D Appl Phys; 56: 415205. DOI: 10.1088/1361-6463/ace064.

10.

Jin

Liu

Xing

, et al. Experimental study of electromagnetic radiation characteristics of pantograph-catenary off-line arcs in high-speed railway. Electric Power Automation Equipment 2022; 42(12): 177–183. DOI: 10.16081/j.epae.202204085.

11.

Yang

Liu

. Discrete modeling and calculation of traction return-current network for 400 km/h high-speed railway. Proc Inst Mech Eng F J Rail Rapid Transit 2023; 237(4): 445–457. DOI: 10.1177/09544097221116966.

12.

Zhou

Liu

Pan

, et al. Dynamic simulation of rail potential and stray current distribution based on fast adaptive boundary element algorithm. IEEE Trans Power Deliv 2024; 39(5): 2828–2840. DOI: 10.1109/TPWRD.2024.3441599.

13.

Yang

Jiang

Wang

, et al. Study and simulation tests of burning damage to insulation joints and rails in high-speed railway stations. J China Railw Soc 2013; 35(10): 82–88.

14.

Liu

Yang

Cui

, et al. Optimization method of switch jumper setting based on strategies for reducing conductive interference in railway. Proc Inst Mech Eng F J Rail Rapid Transit 2021; 235(5): 644–654. DOI: 10.1177/0954409720951300.

15.

Liu

Yang

Liu

, et al. Research on anti-interference algorithm for cab signal demodulation based on deep learning. In: 2020 16th international Conference on Control, Automation, Robotics and vision (ICARCV). Shenzhen, China, 2020, pp. 248–254. DOI: 10.1109/ICARCV50220.2020.9305349.

16.

Yang

Chu

Liu

, et al. Anti-interference Algorithm for cab signalling based on improved DnCNN. J Beijing Jiaot Univ 2022; 46(02): 73–81.

17.

Yang

Chen

, et al. Suppression solutions to transient traction current interference in neutral zone for track circuit. J Southwest Jiaot Univ 2019; 54(06): 1332–1341.

18.

Cui

Yang

Liu

, et al. Research on shielding and earthing methods of railway signal cables. J China Railw Soc 2017; 39(11): 77–82.

19.

Cui

Huang

Yang

. Research on cable crosstalk based on multiport network theory and MoM. J China Railw Soc 2017; 39(11): 77–82.

20.

Yang

. Study on overvoltage of rail when the electric locomotive passes through the neutral zone. Master’s Thesis. Beijing: Beijing Jiaotong University, China, 2020.

21.

TG/XH 102-2015 . High speed railway signalling maintenance rules.

22.

TB/T 2975-2018 . Bonded insulated rail joints.

23.

Mugele

Heikenfeld

. Electrostatics. Electrowetting: Fundamental Principles and Practical Applications. Wiley, 2019, pp. 61–94. DOI: 10.1002/9783527412396.ch2.