Interference and Mitigation of HVDC Grounding Electrode on Buried Pipelines

doi::10.3969/j.issn.1006-396X.2017.06.014

Journal of Petrochemical Universities ›› 2017, Vol. 30 ›› Issue (6): 72-79.DOI: :10.3969/j.issn.1006-396X.2017.06.014

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Interference and Mitigation of HVDC Grounding Electrode on Buried Pipelines

Zhao Yalei¹， Li Zili¹， Fang Xiangpeng²， Yang Chao¹， Cui Gan¹

1. Shandong Provincial Key Laboratory of Oil & Gas Storage and Transportation Safety, Qingdao Key Laboratory of  Circle Sea Oil & Gas Storage and Transportation Technology, China University of Petroleum (East China), Qingdao Shandong 266580,China; 2. Qingdao Xinao Gas Co.Ltd, Qingdao Shandong 266580,China

Received:2017-09-16 Revised:2017-09-29 Online:2017-12-20 Published:2018-02-27

高压直流接地极对埋地管道的干扰及防护研究

赵雅蕾¹，李自力¹，房翔鹏²，杨超¹，崔淦¹

1.中国石油大学（华东）山东省油气储运安全省级重点实验室青岛市环海油气储运技术重点实验室，山东青岛 266580；2.青岛新奥燃气有限公司，山东青岛 266580

通讯作者: :李自力(1963-),男,博士,教授,从事油气储运系统安全工程技术研究;E-mail:zilimenhuzu@163.com。
作者简介::赵雅蕾(1992-),女,硕士研究生,从事油气储运系统安全工程技术研究;E-mail:zhaoyaleix@163.com。

Abstract

Abstract: Due to the similarity of the routing between HVDC transmission lines and buried pipelines, the local pipelines inevitably enter the HVDC transmission interference zone. In order to study the law of interference and mitigation of HVDC grounding electrode on buried pipeline, boundary element software was used to calculate the effectiveness of various mitigation methods including anti-corrosion coating, the distance between the pipeline and the grounding electrode, insulating joints and zinc ribbon. The results indicated that the smaller the coating breakdown factor was, the more concentrated the interference current was , and the higher the local corrosion risk was. After installing the insulating joints, the strongest interfered section of pipe was alleviated, while the interference of the other section of pipe was aggravated. The protection range of the zinc ribbon was equivalent to the length of the zinc ribbon. Finally, the paper put forward the comprehensive protection measures which included insulating joints, cathodic protection and zinc ribbon.

Key words: Electrode, Pipeline, DC interference, Mitigation, Numerical simulation

摘要： 高压直流输电线路与埋地管道路由选择的相似性导致管道不可避免地进入高压直流干扰影响区。为探究公共走廊内高压直流接地极对埋地管道的干扰与防护规律，采用边界元软件计算了不同防腐层破损率、不同管道到接地极距离下的高压直流干扰强度,分析了分段绝缘措施和缓解锌带的防护效果。结果表明，防腐层均匀破损率越小，干扰电流越集中，局部腐蚀风险越高；绝缘法兰之间的管段受到的干扰得到缓解，而隔离区外管段受到的干扰加剧；缓解锌带的保护范围有限，与锌带长度相当。最后，提出了分段绝缘、阴极保护、缓解锌带相结合的综合防护措施。

关键词: 接地极, 管道, 直流干扰, 防护措施, 数值计算

Zhao Yalei，Li Zili，Fang Xiangpeng，Yang Chao，Cui Gan. Interference and Mitigation of HVDC Grounding Electrode on Buried Pipelines[J]. Journal of Petrochemical Universities, 2017, 30(6): 72-79.

赵雅蕾，李自力，房翔鹏，杨超，崔淦. 高压直流接地极对埋地管道的干扰及防护研究[J]. 石油化工高等学校学报, 2017, 30(6): 72-79.

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Interference and Mitigation of HVDC Grounding Electrode on Buried Pipelines

高压直流接地极对埋地管道的干扰及防护研究

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