轨道交通杂散电流对交流电网变压器偏磁直流影响因素分析

doi:10.19781/j.issn.1673-9140.2024.06.009

首页 > 过刊浏览>2024年第39卷第6期 >79-91. DOI:10.19781/j.issn.1673-9140.2024.06.009

轨道交通杂散电流对交流电网变压器偏磁直流影响因素分析
DOI:
                        10.19781/j.issn.1673-9140.2024.06.009
                    
CSTR:
                        
                    
作者:
                        张璐科1张璐科
上海电力大学电气工程学院，上海 200090
在期刊界中查找
在百度中查找
在本站中查找
暴家良2暴家良
国网河南省电力公司安阳供电公司，河南 安阳 455000
在期刊界中查找
在百度中查找
在本站中查找
李晓华1李晓华
上海电力大学电气工程学院，上海 200090
在期刊界中查找
在百度中查找
在本站中查找
陈 璐3陈 璐
国网上海市电力公司，上海 200122
在期刊界中查找
在百度中查找
在本站中查找

                    
作者单位:(1.上海电力大学电气工程学院，上海 200090;2.国网河南省电力公司安阳供电公司，河南 安阳 455000;3.国网上海市电力公司，上海 200122)
作者简介:
通讯作者:李晓华（1974—），女，博士，主要从事交流电网变压器偏磁直流和永磁同步电机振动噪声研究；E?mail:1719885294@qq.com
中图分类号:TM401+.1
基金项目:国家自然科学基金(51607110)

Factors of stray current in rail transit affecting DC magnetic bias of AC power grid transformer

Author:

ZHANG Luke ^¹
ZHANG Luke
College of Electrical Engineering, Shanghai University of Electric Power, Shanghai 200090, China
在期刊界中查找
在百度中查找
在本站中查找
BAO Jialing ^²
BAO Jialing
Anyang Power Supply Company, State Grid Henan Electric Power Company, Anyang 455000, China
在期刊界中查找
在百度中查找
在本站中查找
LI Xiaohua ^¹
LI Xiaohua
College of Electrical Engineering, Shanghai University of Electric Power, Shanghai 200090, China
在期刊界中查找
在百度中查找
在本站中查找
CHEN Lu ^³
CHEN Lu
State Grid Shanghai Municipal Electric Power Company, Shanghai 200122, China
在期刊界中查找
在百度中查找
在本站中查找

Affiliation:

(1.College of Electrical Engineering, Shanghai University of Electric Power, Shanghai 200090, China; 2.Anyang Power Supply Company, State Grid Henan Electric Power Company, Anyang 455000, China; 3.State Grid Shanghai Municipal Electric Power Company, Shanghai 200122, China)

Fund Project:

摘要

图/表

访问统计

参考文献 [24]

相似文献

引证文献

资源附件

文章评论

摘要:

城市轨道交通杂散电流在大地中流动分布时会侵入附近交流电网变压器。为研究不同土壤特性下轨道交通杂散电流对沿线变电站的偏磁影响，基于上海某变电站及其邻近轨道交通系统，利用CDEGS软件建立城市轨道交通?交流电网变电站耦合仿真模型，对不同混凝土、土壤电阻率下杂散电流对交流电网变压器偏磁直流影响进行研究，并利用土壤等电流密度幅值分布曲线，结合可视化技术显示杂散电流的影响范围与流通路径。结果表明，混凝土电阻率和土壤电阻率对钢轨泄漏电流空间电场分布和变压器中性点偏磁直流影响存在较大差异。在仿真模型中，杂散电流的最大影响范围为1 421.33 m，以分布距离与土壤电阻率的微分作为土壤电阻率对杂散电流流动范围影响指标，土壤电阻率最大为1.42 m/(Ω ? m)。列车启动33 s后行至500.3 m位置处，土壤电阻率对变电站中性点偏磁直流影响最大，可达0.003 431 A/(Ω ? m）。

关键词:地铁杂散电流;偏磁直流;耦合仿真;CDEGS;动态变化;土壤电阻率

Abstract:

The flow distribution of stray current in urban rail transit in the ground makes it intrude into the nearby alternating current (AC) power grid transformer. In order to study the influence of stray current in rail transit on the magnetic bias of substations along the line under different soil characteristics, based on a substation in Shanghai and its nearby rail transit system, CDEGS software is used to establish the coupling simulation model of “urban rail transit-AC power grid substation”, so as to study the influence of stray current on the direct current (DC) magnetic bias of the AC power grid transformer under different concrete-soil resistivity. The distribution curve of soil iso-current density amplitude is used, combined with visualization technology, to display the influence range and flow path of stray current. The results show that there is a big difference in the influence of concrete resistivity and soil resistivity on the spatial electric field distribution of the leakage current of the rail and the DC magnetic bias of the neutral point of the transformer. In the simulation model, the maximum influence range of stray current is 1 421.33 m, and the differential of distribution distance and soil resistivity is used as the influence index of soil resistivity on the flow range of stray current. The maximum soil resistivity is 1.42 m/(Ω?m). When the train moves 500.3 m after 33 s, the soil resistivity has the greatest influence on the DC magnetic bias of the neutral point of the substation, which can reach 0.003 431 A/(Ω?m).

Key words:stray current in subway; DC magnetic bias; coupling simulation; CDEGS; dynamic change; soil resistivity

参考文献

[1] 刘燕,王京梅,赵丽,等.地铁杂散电流分布的数学模型[J].工程数学学报,2009,26(4):571-576. LIU Yan,WANG Jingmei,ZHAO Li,et al.Mathematical model of distribution of metro stray current[J].Chinese Journal of Engineering Mathematics,2009,26(4):571-576.

[2] 吴天逸,冯楠,高凯,等.轨道交通影响下上海电网直流偏磁多参量监测及治理研究[J].高压电器,2023,59(11): 84-91. WU Tianyi,FENG Nan,GAO Kai,et al.Research on multi parameters monitoring and suppression of DC bias in Shanghai power grid under influence of rail transit[J].High Voltage Apparatus,2023,59(11): 84-91.

[3] YU J G.The effects of earthing strategies on rail potential and stray currents in DC transit railways[C]//International Conference on Developments in Mass Transit Systems.London,UK,1998.

[4] 庞源冰.城市轨道交通杂散电流研究[D].成都：西南交通大学，2008. PANG Yuanbing.Study on stray current of urban rail transit and rail potential suppression measures[D].Chengdu:Southwest Jiaotong University,2008.

[5] 李威.地铁杂散电流腐蚀监测及防护技术[M].徐州:中国矿业大学出版社,2004. LI Wei.Monitoring and protection technology of stray current corrosion in subway[M].Xuzhou:China University of Mining & Technology Press,2004.

[6] 曹阿林.埋地金属管线的杂散电流腐蚀防护研究[D].重庆:重庆大学,2010. CAO Alin.Protection against stray current corrosion of buried metals pipeline[D].Chongqing:Chongqing University,2010.

[7] 吴书煜,汲胜昌,孙建涛,等.在运换流变压器振动监测及其变化规律[J].高电压技术,2022,48(4):1561-1570. WU Shuyu,JI Shengchang,SUN Jiantao,et al.Vibration monitoring and variation law of converter transformer in operation[J].High Voltage Engineering,2022,48(4):1561-1570.

[8] 熊奇,王沐雪,黄浩,等.复杂地质情况下接地极土壤模型建立及研究[J].中国电机工程学报,2020,40(7):2269-2277. XIONG Qi,WANG Muxue,HUANG Hao,et al.Establishment of earth model for HVDC earth electrode in complicated terrain[J].Proceedings of the CSEE,2020,40(7):2269-2277.

[9] 苗浩铭,申巍,曹雯,等.连续冲击作用下不同土壤地区接地装置的散流特性研究[J].电网与清洁能源,2022,38(11): 71-79+87. MIAO Haoming,SHEN Wei,CAO Wen,et al.A study on dispersion characteristics of grounding devices in different soil areas under continuous impact[J].Power System and Clean Energy,2022,38(11): 71-79+87.

[10] 曾嵘,陈水明.CDEGS 软件包及其在多层土壤接地设计中的应用[J].华东电力,1998,26(6):27-32. ZENG Rong,CHEN Shuiming.CDEGS software package and its application in multi-layer soil grounding design[J].East China Electric Power,1998,26(6):27-32.

[11] ALAMUTI M M,NOURI H,JAMALI S.Effects of earthing systems on stray current for corrosion and safety behaviour in practical metro systems[J].IET Electrical Systems in Transportation,2011,1(2):69-79.

[12] 胡士信.阴极保护工程手册[M].北京:化学工业出版社,1999. HU Shixin.Handbook of cathodic protection engineering[M].Beijing:Chemical Industry Press,1999.

[13] 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.

[14] 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.

[15] 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.

[16] 刘炜,娄颖,张戬,等.计及城市轨道逆变回馈装置的交直流统一供电计算[J].电工技术学报,2019,34(20):4381-4391. LIU Wei,LOU Ying,ZHANG Jian,et al.Unified AC/DC power supply calculation taking into account urban rail inverter feedback devices[J].Transactions of China Electrotechnical Society,2019,34(20):4381-4391.

[17] LEE C H,LU C J.Assessment of grounding schemes on rail potential and stray currents in a DC transit system[J].IEEE Transactions on Power Delivery,2006,21(4):1941-1947.

[18] 胡颖.城市轨道交通供电系统对电网的影响及控制[J].建材技术与应用,2020(1):38-41. HU Ying.Influence and control of urban rail transit power supply system on power grid[J].Research & Application of Building Materials,2020(1):38-41.

[19] 阮羚,唐泽洋,张波,等.城市轨道交通杂散电流与电网直流偏磁电流耦合关系与检测的研究展望[J].湖北电力,2021,45(2):33-48. RUAN Ling,TANG Zeyang,ZHANG Bo,et al.Research and prospect of detection and coupling relationship between stray current in urban rail transit and grid DC bias magnetic current[J].Hubei Electric Power,2021,45(2):33-48.

[20] 彭平,曾祥君,倪砚茹,等.考虑地铁杂散电流影响的变压器直流偏磁电流建模方法[J].电力科学与技术学报,2021,36(1):192-198. PENG Ping,ZENG Xiangjun,NI Yanru,et al.Modeling for the DC bias current of transformer caused by the metro stray current[J].Journal of Electric Power Science and Technology,2021,36(1):192-198.

[21] 刘君,牛唯,赵露,等.基于振动信号的城市电网变压器直流偏磁状态辨识方法[J].电力科学与技术学报,2021,36(5):169-178. LIU Jun,NIU Wei,ZHAO Lu,et al.State identification method for transformer of urban power grid under DC bias based on vibration signal[J].Journal of Electric Power Science and Technology,2021,36(5):169-178.

[22] 黄华,陈璐,吴天逸,等.城市轨道交通动态运行对交流电网变压器偏磁直流的影响[J].电网技术,2022,46(11):4524-4533. HUANG Hua,CHEN Lu,WU Tianyi,et al.Influence of dynamic operation of urban rail transit on DC magnetic bias of AC power grid transformer[J].Power System Technology,2022,46(11):4524-4533.

[23] 孙晓鹏,张宇华,暴家良,等.城市轨道交通杂散电流对沿线变电站偏磁特性的影响研究[J].机车电传动,2023(4):107-116. SUN Xiaopeng,ZHANG Yuhua,BAO Jialiang,et al.Research on the influence of stray current from urban rail transit on the magnetic bias characteristics of substations along the line[J].Electric Drive for Locomotives,2023(4):107-116.

[24] 汪佳.多列车运行下地铁杂散电流分布研究[D].成都:西南交通大学,2012. WANG Jia.Study on distribution of metro stray current based on multi-locomotive operation[D].Chengdu:Southwest Jiaotong University,2012.

引用本文

张璐科,暴家良,李晓华,等.轨道交通杂散电流对交流电网变压器偏磁直流影响因素分析[J].电力科学与技术学报,2024,39(6):79-91.
ZHANG Luke, BAO Jialing, LI Xiaohua, et al. Factors of stray current in rail transit affecting DC magnetic bias of AC power grid transformer[J]. Journal of Electric Power Science and Technology,2024,39(6):79-91.

复制

文章指标

点击次数:115
下载次数: 128
HTML阅读次数: 0
引用次数: 0

历史

收稿日期:
最后修改日期:
录用日期:
在线发布日期: 2025-02-14
出版日期:

引用本文

相关视频

分享

文章指标

历史

文章二维码

引用本文

相关视频

分享

微信扫一扫：分享

文章指标

历史

文章二维码