多重雷击下±500kV直流架空线转海缆的雷电侵入波过电压防护OA
Lightning Intruding Overvoltage Protection for the±500 kV DC Overhead Transmission Line-submarine Cable System Under Multiple Lightning Strikes
为保障多重雷击下绝缘水平较低的直流海缆安全,基于PSCAD/EMTDC搭建阳江三山岛海上风电±500 kV海陆一体化柔性直流输电系统转换站电磁暂态模型,仿真计算站内关键设备及海缆过电压分布,分析不同雷电流幅值、波形及冲击次数对站内设备过电压的影响,研究了加装电抗器对各设备雷电过电压的抑制效果,并对比了不同避雷器配置方案下转换站对多重雷击的耐受能力.研究结果表明:雷电流幅值越高、波前时间越短,靠近架空线侧的设备过电压幅值越高;而波尾越长,海缆接入点的过电压越大.当绕击雷电流限制在30 kA以内时,无需采取额外防护措施;而在40 kA绕击下,海缆反极性过电压高达631 kV,绝缘裕度不足.通过配置4 mH的电抗器可将海缆处过电压抑制至384 kV,安全裕度提高至33%;同时在转换站进线侧和电抗器架空线侧增设避雷器,可进一步降低设备过电压并保证避雷器的电气应力均处于安全范围.研究结果可为大容量海上风电采用直流海陆一体输送工程站线协同雷电防护设计提供参考.
To ensure the safety of the DC submarine cable with relatively low insulation level under multiple lightning strikes,a transition station model of the±500 kV integrated offshore-onshore flexible DC transmission system for the Yangjiang Sanshan Island offshore wind power project is established in PSCAD/EMTDC.The overvoltage distributions of key equipment and submarine cables in the station are simulated,and the effects of multiple lightning current wave-forms and the number of return strokes on equipment overvoltage in the station are analyzed.Furthermore,the suppression effects of installing reactors on lightning overvoltage are investigated,and the station's withstand capabilities against multiple lightning strikes are compared under different arrester configuration schemes.The results indicate that higher lightning current amplitudes and shorter front time lead to higher overvoltages on equipment near the overhead transmission line,whereas longer tail time results in larger overvoltages at the submarine cable connection point.When the lightning current is limited to 30 kA,no additional protective measures are required.However,under 40 kA lightning strokes,the reverse-polarity overvoltage at the submarine cable terminal reaches 631 kV with an insufficient insulation margin.Installing a 4 mH reactor can suppress the cable terminal overvoltage to 384 kV,increasing the insulation margin to 33%.Additionally,adding arresters at both the station inlet and the overhead transmission line side of the reactor can further reduce equipment overvoltages and ensure that the electrical stress of all arresters remains within safe limits.These findings provide a coordinated transition station-transmission line lightning protection design methodology for large-scale offshore wind power projects using integrated offshore-onshore DC transmission.
何少敏;韩永霞;林昊君;李端姣;孙文星;陈宇慧
华南理工大学电力学院,广州 510640华南理工大学电力学院,广州 510640华南理工大学电力学院,广州 510640广东电网有限责任公司,广州 510620广东电网有限责任公司,广州 510620广东电网有限责任公司,广州 510620
海上风电直流转换站海陆一体协同多重雷击雷电侵入波过电压防护方案
offshore wind powerDC transition stationoffshore-onshore integrationmultiple lightning strokeslight-ning intruding overvoltageprotection scheme
《高电压技术》 2026 (3)
1080-1089,10
智能电网重大专项(2030)(2025ZD0807000)广东省基础与应用基础研究基金(2024A1515010276). Project supported by Smart Grid-National Science and Technology Major Project(2025ZD0807000),Guangdong Basic and Applied Basic Research Founda-tion(2024A1515010276).
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