直流牵引供电回流系统与杂散电流扩散的联合仿真模型

doi:10.19595/j.cnki.1000-6753.tces.220937

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Abstract Currently, there are many factors affecting the rail potential and stray current, but the influence of the superposition of the depot and the mainline on the distribution and diffusion of stray current is not considered. Considering the complex operation conditions of multiple trains in the depot and main line, the distribution characteristics of stray current and its diffusion in the ground were studied. The return system and the stray current diffusion model were jointly simulated. The layered model based on the precise integration principal component weighted iteration method can dynamically evaluate the dynamic stray current in a certain period, reduce the calculation cost, and obtain high-precision and efficient calculation results. The return system was equivalently replaced by distributed parameters and concentrated parameters, and the node voltage method is used for power supply calculation. The distribution of the rail potential and stray current leakage across the line is obtained. Considering the layered soil medium, the model of the stray current potential distribution in the ground along the mainline superimposed by the power supply at the section points was established. Based on the ground potential distribution model of the point current source in layered medium, the dynamic change model of the ground potential gradient with time was obtained.
It is important to transform the ill-conditioned problem into a benign problem that is easy to solve for the problem of solving the ill-conditioned matrix of Green's function. The weight of the principal component weighting was determined by the weighting factor q and the weighting matrix P. Different weights were superimposed on each principal component to better reduce the number of conditions. A precise integration principal component weighted iteration method for the layered model was proposed, which can solve Green's function of the layered model with high accuracy and efficiency. The validity of the layered model of stray current potential distribution in the ground was verified by physical experiments and the average error between the field results and calculated results is within 6.98%.
Combined with the engineering case of the actual line in China, comparing the field measured and calculated rail potential and ground potential gradient distribution process, the relative error range between the field measured and calculated results is within 8.46%, which shows that the model is effective. The influence of different connection modes between the mainline and the depot on the DC interference propagation process was discussed. The rail in the depot is directly grounded, and the one-way conduction device becomes the bridge connecting the depot and the mainline. The maximum current flowing into the mainline in the throat area reaches 106.62 A and the minimum current flowing into the main line reaches -330.28 A when the unidirectional connection device was put into operation. The maximum surface potential gradient mode at 6.52 km away from the depot is 6.77 mV/m, and the degree of stray current is serious. Under the condition of removing the diode branch and thyristor branch fuses of the unidirectional connection device, the upstream unidirectional connection device current flowing into the mainline was significantly reduced, and the maximum ground potential gradient modulus is 3.62 mV/m, which is 46.53% less than that under the operating condition of the unidirectional connection device.

Key words： DC traction power supply system rail potential stray current diffusion model co-simulation

Received: 26 May 2022

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TM922

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	Liu Wei
	Zhou Linjie
	Tang Yuning
	Pan Zhe
	Yin Yichen

Cite this article:

Liu Wei,Zhou Linjie,Tang Yuning等. Co-Simulated Model of DC Traction Power Supply Return System and Stray Current Diffusion[J]. Transactions of China Electrotechnical Society, 2023, 38(16): 4421-4432.

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https://dgjsxb.ces-transaction.com/EN/10.19595/j.cnki.1000-6753.tces.220937 OR https://dgjsxb.ces-transaction.com/EN/Y2023/V38/I16/4421

[1] 朱峰, 李嘉成, 曾海波, 等. 城市轨道交通轨地过渡电阻对杂散电流分布特性的影响[J]. 高电压技术, 2018, 44(8): 2738-2745.
Zhu Feng, Li Jiacheng, Zeng Haibo, et al.Influence of rail-to-ground resistance of urban transit systems on distribution characteristics of stray current[J]. High Voltage Engineering, 2018, 44(8): 2738-2745.
[2] 顾靖达, 杨晓峰, 郑琼林, 等. 基于不同接地方式与列车工况的负阻变换器牵引供电系统轨道电位与杂散电流[J]. 电工技术学报, 2021, 36(8): 1703-1717.
Gu Jingda, Yang Xiaofeng, Zheng T Q, et al.Rail potential and stray current on negative resistance converter traction power system under different grounding schemes and train conditions[J]. Transactions of China Electrotechnical Society, 2021, 36(8): 1703-1717.
[3] Liu Wei, Li Tian, Zheng Jie, et al.Evaluation of the effect of stray current collection system in DC-electrified railway system[J]. IEEE Transactions on Vehicular Technology, 2021, 70(7): 6542-6553.
[4] Du Guifu, Wang Jun, Jiang Xingxing, et al.Evaluation of rail potential and stray current with dynamic traction networks in multitrain subway systems[J]. IEEE Transactions on Transportation Electrification, 2020, 6(2): 784-796.
[5] 杨晓峰, 薛皓, 郑琼林. 基于双向可变电阻模块的杂散电流与轨道电位动态模拟系统[J]. 电工技术学报, 2019, 34(13): 2793-2805.
Yang Xiaofeng, Xue Hao, Zheng T Q.Stray current and rail potential dynamic simulation system based on bidirectional variable resistance module[J]. Transactions of China Electrotechnical Society, 2019, 34(13): 2793-2805.
[6] 王慧康, 杨晓峰, 倪梦涵, 等. 轨道电位与杂散电流动模实验平台[J]. 电工技术学报, 2020, 35(17): 3609-3618.
Wang Huikang, Yang Xiaofeng, Ni Menghan, et al.Rail potential and stray current dynamic emulator[J]. Transactions of China Electrotechnical Society, 2020, 35(17): 3609-3618.
[7] 于继来, 王江, 柳焯. 电力系统潮流算法的几点改进[J]. 中国电机工程学报, 2001, 21(9): 88-93.
Yu Jilai, Wang Jiang, Liu Zhuo.Improvements on usual load flow algorithms of power system[J]. Proceedings of the CSEE, 2001, 21(9): 88-93.
[8] 吴命利. 电气化铁道牵引网的统一链式电路模型[J]. 中国电机工程学报, 2010, 30(28): 52-58.
Wu Mingli.Uniform chain circuit model for traction networks of electric railways[J]. Proceedings of the CSEE, 2010, 30(28): 52-58.
[9] Tzeng Y S, Lee C H.Analysis of rail potential and stray currents in a direct-current transit system[J]. IEEE Transactions on Power Delivery, 2010, 25(3): 1516-1525.
[10] 杜贵府, 张栋梁, 王崇林, 等. 直流牵引供电系统电流跨区间传输对钢轨电位影响[J]. 电工技术学报, 2016, 31(11): 129-139.
Du Guifu, Zhang Dongliang, Wang Chonglin, et al.Effect of traction current transmission among power sections on rail potential in DC mass transit system[J]. Transactions of China Electrotechnical Society, 2016, 31(11): 129-139.
[11] 刘炜, 杨龙, 李国玉, 等. 计及回流系统设备行为过程的钢轨电位动态仿真[J]. 电工技术学报, 2022, 37(4): 1000-1009.
Liu Wei, Yang Long, Li Guoyu, et al.Dynamic simulation of rail potential considering the equipment behavior process of recirculation system[J]. Transactions of China Electrotechnical Society, 2022, 37(4): 1000-1009.
[12] 王爱民, 林圣, 李俊逸, 等. 城市轨道交通长线路杂散电流仿真模型[J]. 高电压技术, 2020, 46(4): 1379-1386.
Wang Aimin, Lin Sheng, Li Junyi, et al.Stray current simulation model of the long line of DC metro systems[J]. High Voltage Engineering, 2020, 46(4): 1379-1386.
[13] 刘炜, 郑杰, 李田, 等. 排流装置对直流牵引供电系统杂散电流分布的影响[J]. 电工技术学报, 2022, 37(18): 4565-4574.
Liu Wei, Zheng Jie, Li Tian, et al.The influence of drainage device on stray current distribution in DC traction power supply system[J]. Transactions of China Electrotechnical Society, 2022, 37(18): 4565-4574.
[14] Cotton I, Charalambous C, Aylott P, et al.Stray current control in DC mass transit systems[J]. IEEE Transactions on Vehicular Technology, 2005, 54(2): 722-730.
[15] Kim H J, Choi K, Lee H B, et al.A new algorithm for solving ill conditioned linear systems[J]. IEEE Transactions on Magnetics, 1996, 32(3): 1373-1376.
[16] 富明慧, 张文志. 病态代数方程的精细积分解法[J]. 计算力学学报, 2011, 28(4): 530-534.
Fu Minghui, Zhang Wenzhi.Precise integration method for solving ill-conditioned algebraic equations[J]. Chinese Journal of Computational Mechanics, 2011, 28(4): 530-534.
[17] Rump S M.Approximate inverses of almost singular matrices still contain useful information[R]. Technical Report 90.1, Faculty for Information and Communication Sciences, Hamburg University of Technology, 1990.
[18] 潘卓洪, 李嘉思, 刘曳君, 等. 分层土壤接地格林函数的多精度多分辨率计算[J]. 中国电机工程学报, 2019, 39(15): 4451-4459.
Pan Zhuohong, Li Jiasi, Liu Yejun, et al.Multi-precision-resolution computation of the green's function for the grounding problems of layered soils[J]. Proceedings of the CSEE, 2019, 39(15): 4451-4459.
[19] 刘炜, 尹乙臣, 潘卫国, 等. 直流动态杂散电流在分层介质中的扩散模型[J]. 电工技术学报, 2021, 36(23): 4864-4873.
Liu Wei, Yin Yichen, Pan Weiguo, et al.Diffusion model of DC dynamic stray current in layered soil[J]. Transactions of China Electrotechnical Society, 2021, 36(23): 4864-4873.
[20] 薛正林. 基于主元加权的病态线性方程组算法研究[D]. 成都: 四川师范大学, 2016.
[21] 刘炜, 李富强, 唐靖坤, 等. 城市轨道走行轨过渡电阻测量方法与计算误差[J]. 高电压技术, 2020, 46(8): 2856-2863.
Liu Wei, Li Fuqiang, Tang Jingkun, et al.Measurement method and calculation error of rail-to-earth resistance in urban rail[J]. High Voltage Engineering, 2020, 46(8): 2856-2863.