Study of the coupling interference of high-voltage transmission lines on adjacent buried steel pipelines based on CDEGS

被引:2
|
作者
Wang, Xinhua [1 ]
Wang, Yuexin [1 ]
Sun, Tao [1 ]
Yang, Xuyun [2 ]
Yang, Lin [1 ]
Qi, Yongsheng [1 ]
机构
[1] Beijing Univ Technol, Fac Mat & Mfg, Beijing 100124, Peoples R China
[2] China Special Equipment Inspect & Res Inst, Beijing 100013, Peoples R China
关键词
AC interference; Buried pipelines; Transmission line; Mitigation measures; UNDERGROUND METAL PIPELINE; OVERHEAD;
D O I
10.1016/j.epsr.2023.109125
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
Generally, transmission lines and buried pipelines constantly share the same corridor to save land and public resources during urban construction. In this paper, the electromagnetic interference of high-voltage transmission lines on the surrounding buried steel pipelines is studied by considering a public corridor. This corridor com-prises a 220 kV AC transmission line project and buried metal pipelines in Shanghai. The Current Distribution, Electromagnetic Field, Grounding and Soil Structure Analysis (CDEGS) software is used to study the AC inter-ference situation in this corridor. The level of interferences caused by the AC transmission lines on the pipelines under normal load and single-phase fault conditions is investigated. Zinc strip mitigation measures are set up for the normal load and single-phase fault operation results, effectively reducing the degree of AC interference on the pipelines. Moreover, several new mitigation measures are proposed. The safe implementation of the stable and reliable operation of the transmission line and pipelines is ensured in this paper. The research conclusions can provide reference and guidance for solving the problem of AC interference generated by high-voltage trans-mission lines on the surrounding buried pipelines and generate new ideas designing of mitigation measures.
引用
收藏
页数:13
相关论文
共 50 条
  • [31] DANGER OVERHEAD + HIGH-VOLTAGE TRANSMISSION-LINES
    DIAMOND, S
    OMNI, 1978, 1 (03) : 37 - 37
  • [32] Live maintenance robot for high-voltage transmission lines
    Jiang, Wei
    Yan, Yu
    Zhang, An
    Yu, Lianqing
    Zuo, Gan
    Li, Hong Jun
    Chen, Wei
    INDUSTRIAL ROBOT-THE INTERNATIONAL JOURNAL OF ROBOTICS RESEARCH AND APPLICATION, 2019, 46 (05): : 711 - 718
  • [33] FAULT PREDICTION ON HIGH-VOLTAGE TRANSMISSION-LINES
    HALASA, GH
    ELECTRIC POWER SYSTEMS RESEARCH, 1982, 5 (04) : 281 - 284
  • [34] What drives opposition to high-voltage transmission lines?
    Cain, Nicholas L.
    Nelson, Hal T.
    LAND USE POLICY, 2013, 33 : 204 - 213
  • [35] TRANSMISSION CHARACTERISTICS OF HIGH-VOLTAGE LINES AT CARRIER FREQUENCIES
    EGGIMANN, F
    SENN, W
    MORF, K
    BROWN BOVERI REVIEW, 1977, 64 (08): : 449 - 459
  • [36] IMPACTS OF OVERHEAD HIGH-VOLTAGE TRANSMISSION-LINES
    COLEMAN, DM
    JOURNAL OF ENVIRONMENTAL SYSTEMS, 1981, 10 (04): : 283 - 304
  • [37] EXPOSURE TO HIGH-VOLTAGE ELECTRICAL TRANSMISSION-LINES
    WHEATER, RH
    JAMA-JOURNAL OF THE AMERICAN MEDICAL ASSOCIATION, 1980, 243 (21): : 2242 - 2242
  • [38] HIGH-VOLTAGE TRANSMISSION-LINES - PROS AND CONS
    BINGHAM, GS
    CIVIL ENGINEERING, 1978, 48 (09): : 89 - 89
  • [39] Multistage converter of high-voltage subnanosecond pulses based on nonlinear transmission lines
    Ulmaskulov, M. R.
    Shunailov, S. A.
    Sharypov, K. A.
    Yalandin, M. I.
    JOURNAL OF APPLIED PHYSICS, 2019, 126 (08)
  • [40] Sag Prediction of High-voltage Transmission Lines based on PSO-SVM
    Liao Ruchao
    Liao Jiandong
    Zhang Ying
    Li Guoqiang
    Li Xionggang
    Wu Yunfa
    2020 35TH YOUTH ACADEMIC ANNUAL CONFERENCE OF CHINESE ASSOCIATION OF AUTOMATION (YAC), 2020, : 772 - 777