2025年4月5日 周六
首页 > 过刊浏览>2023年第38卷第2期 >96-104. DOI:10.19781/j.issn.1673-9140.2023.02.011
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基于工频磁场的电缆路径定位及其影响因素分析
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作者:
作者单位:

(1.广东工业大学自动化学院,广东 广州 510006;2.广东电网有限责任公司肇庆供电局,广东 肇庆 526060)

通讯作者:

聂一雄(1964—),男,博士,副教授,主要从事电工理论新技术、电仪表的应用研究;E?mail: gdutzdh997@163.com

中图分类号:

TM726.4

基金项目:

中国南方电网有限责任公司科技项目(GDKJXM20210892)


Analysis of cable path location and its influencing factors based on power frequency magnetic field
Author:
Affiliation:

(1.School of Automation, Guangdong University of Technology, Guangzhou 510006, China;2. Zhaoqing Power Supply Bureau, Guangdong Power Grid Co., Ltd., Zhaoqing 526060, China)

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    摘要:

    为避免城市施工过程中挖断电缆事故的频繁发生,需要科学合理地对电缆路径实施定位。以三芯电缆为研究对象,引入定位特征点和定位特征值K作为电缆上方磁感应强度判断依据,并根据电缆周围磁场分布特性确定电缆敷设路径;接着用该判据对影响检测点周围磁场环境变化的因素——线芯位置、电缆埋深、敷设间距和不同路径等进行分析论证。仿真结果表明:定位特征值K能较好地反应电缆周围磁场环境变化,定位特征点均出现在电缆正上方附近。最后,通过有限元和实验验证该判据的准确性和可行性,原理简单且可移植性强,可以为实现智能化和现代化的电缆路径定位提供重要参考。

    Abstract:

    In order to avoid the frequent occurrence of cable cutting accidents in urban construction, the cable path should be located scientifically and reasonably. Taking three core cable as the research object, locating characteristic point and locating characteristic value K are introduced as the judgment basis of magnetic induction intensity above the cable, and the cable laying path is determined by the distribution characteristics of magnetic field around the cable. Then, the factors affecting the change of magnetic field around the detection points?wire core position, cable buried depth, laying spacing and different paths are analyzed by using this criterion. Simulation results show that the value of K can reflect the change of magnetic field environment around the cable well. The characteristic points appear near the top of the cable. Finally, the accuracy and feasibility of the criterion are verified by finite element and experiments. The principle of the proposed method is simple and portable, which provides an important reference for realizing intelligent and modern cable path positioning.

    参考文献
    [1] 袁燕岭,周灏,董杰,等.高压电力电缆护层电流在线监测及故障诊断技术[J].高电压技术,2015,41(4):1194? 1203. YUAN Yanling,ZHOU Hao,DONG Jie,et al.Sheath current in HV cable systems and its on?line monitoring for cable fault diagnosis[J].High Voltage Engineering,2015,41(4):1194?1203.
    [2] 惠宝军,傅明利,刘通,等.110 kV及以上电力电缆系统故障统计分析[J].南方电网技术,2017,11(12):44?50+67. HUI Baojun,FU Mingli,LIU Tong,et al.Statistical analysis on failures of 110 kV and above power cable system[J].Southern Power System Technology,2017,11(12):44?50+67.
    [3] SHAALAN E M,WARD S A,YOUSSEF A.Analysis of a practical study for under?ground cable faults causes[C]//22nd International Middle East Power Systems Conference (MEPCON),Assiut,Egypt,2021.
    [4] 林志超,吴旭灿,罗步升,等.非接触式低压线缆漏电故障定位技术[J].供用电,2022,39(10):44?50+74. LIN Zhichao,WU Xucan,LUO Busheng,et al.Non?contact technology of low?voltage cable leakage fault location[J].Distribution & Utilization,2022,39(10):44?50+74.
    [5] 李巍巍,白欢,吴惟庆,等.基于振荡波局部放电检测的电力电缆绝缘老化状态评价与故障定位[J].电测与仪表,2021,58(9):147?151. LI Weiwei,BAI Huan,WU Weiqing,et al.Evaluation and fault location of power cable insulation aging based on oscillation?wave partial discharge detection[J].Electrical Measurement & Instrumentation,2021,58(9):147?151.
    [6] 李映桥,王学冬,徐青龙,等.城市地下电缆路径检测系统的研究与设计[J].电气技术,2020(8):73?79+86. LI Yingqiao,WANG Xuedong,XU Qinglong,et al.Research and design of urban underground cable path detection system[J].Electrical Technology,2020(8):73?79+86.
    [7] 黄兴曼,邬小玫,方祖祥.基于相位差的电磁定位系统设计[J].电子测量技术,2020,43(8):54?59. HUANG Xingman,WU Xiaomei,FANG Zuxiang.Design of electromagnetic positioning system based on phase difference[J].Electronic Measurement Technology,2020,43(8):54?59.
    [8] 叶远红,邓兴虞,梁戟,等.电子标识器技术在电缆路径探测中的应用[J].自动化与仪器仪表,2019(9):238?240. YE Yuanhong,DENG Xingyu,LIANG Ji,et al.Application of electronic identifier in cable path detection[J].Automation and Instrumentation,2019(9):238?240.
    [9] HUANG X,WANG W,Lü Z,et al.Precise positioning of the underground power cable by magnetic field detectio[C]//IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP),East Rutherford,NJ,USA,2019.
    [10] 郭智刚,高健,闫峰,等.长距离330 kV电缆依频模型局放传输特性分析及信号定位试验验证[J].电网与清洁能源,2022,38(11):17?26. GUO Zhigang,GAO Jian,YAN Feng,et al. Partial discharge transmission characteristic analysis of the frequency?dependent model of the long distance 330 kV cable and experimental verification of signal positioning[J].Power System and Clean Energy,2022,38(11):17?26.
    [11] 张丹丹,苏小婷,景晓东,等.基于阻抗谱的同轴电缆故障及中间接头定位实验研究[J].高压电器,2021,57(7):92?97. ZHANG Dandan,SU Xiaoting,JING Xiaodong,et al.Experimental study on coaxial cable faults and intermediate joints location based on impedance spectrum[J].High Voltage Apparatus,2021,57(7):92?97.
    [12] 尹丽菊,于毅,咸日常,等.基于无监督学习的交叉互联电缆行波测距方法[J].智慧电力,2021,49(4):89?94. YIN Liju,YU Yi,XIAN Richang,et al.Traveling wave ranging method for cross?bonded cable based on unsupervised learning[J].Smart Power,2021,49(4):89?94.
    [13] 蔡少飞.高压及控制电缆屏蔽层接地方式探析[J].黑龙江电力,2019,41(4):324?328. CAI Shaofei.Analysis on grounding mode for shield layer of high?voltage cable and control cable[J].Heilongjiang Electric Power,2019,41(4):324?328.
    [14] 刘浩然,周凯,王昱皓,等.基于电磁耦合注入的电力电缆局部缺陷在线定位方法[J].中国电力,2021,54(12):177?185+194. LIU Haoran,ZHOU Kai,WANG Yuhao,et al.An online location method for local defects in power cables based on electromagnetic coupling injection[J].Electric Power,2021,54(12):177?185+194.
    [15] 刘炎,夏向阳,李明德,等.高压电力电缆轨迹法在线监测方法[J].电力科学与技术学报,2019,34(3):202?210. LIU Yan,XIA Xiangyang,LI Mingde,et al.Research on online monitoring system based on locus method of HV power cable[J].Journal of Electric Power Science and Technology,2019,34(3):202?210.
    [16] 徐逸民.35 kV海底光电复合缆的电磁环境研究[D].大连:大连理工大学,2018. XU Yimin.Research on electromagnetic environment of 35 kV submarine cables[D].Dalian:Dalian University of Technology,2018.
    [17] 董灵鹏,邹国平,杨仕友.电力巡检无人机电磁场测距及校准技术研究[J/OL].电测与仪表:1?6[2020?11?04].http://kns.cnki.net/kcms/detail/23.1202.TH.20201103. 1807.002.html. DONG Lingpeng,ZOU Guoping,YANG Shiyou.Research on electromagnetic field ranging and calibration technology of electric patrol UAV[J/OL].Electrical Measurement & Instrumentation,1?6[2020?11?04].http://kns.cnki.net/kcms/detail/23.1202.TH.20201103.1807. 002.html.
    [18] 李蓉,周凯,万航,等.基于输入阻抗谱的电力电缆本体局部缺陷类型识别及定位[J].电工技术学报,2021,36(8):1743?1751. LI Rong,ZHOU Kai,WAN Hang,et al.Identification and location of local defects in power cable body based on input impedance spectroscopy[J].Transactions of China Electrotechnical Society,2021,36(8):1743?1751.
    [19] 冯慈璋.电磁场(第2版)[M].北京:高等教育出版社,1983:117?119. FENG Cizhang.Electromagnetic fields (second edition) [M].Beijing:Higher Education Press,1983:117?119.
    [20] 袁超,储海军,陈燕擎,等.考虑金属护层耦合的高压电缆单相接地故障定位方法[J].电力系统保护与控制,2021,49(2):115?120. YUAN Chao,CHU Haijun,CHEN Yanqing,et al.Single phase ground fault location method for high voltage cables considering the metal sheath coupling[J].Power System Protection and Control,2021,49(2):115?120.
    [21] GB 50217—2007.电力工程电缆设计规范[S]. GB 50217—2007.Code for design of power engineering cables[S].
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引用本文

王雪倩,聂一雄,李 哲,等.基于工频磁场的电缆路径定位及其影响因素分析[J].电力科学与技术学报,2023,38(2):96-104.
WANG Xueqian, NIE Yixiong, LI Zhe, et al. Analysis of cable path location and its influencing factors based on power frequency magnetic field[J]. Journal of Electric Power Science and Technology,2023,38(2):96-104.

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