挤塑交联程度对高压直流海缆软接头界面电气性能与力学性能的影响

doi:10.19595/j.cnki.1000-6753.tces.250719

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摘要软接头是高压直流交联聚乙烯（XLPE）海缆的关键部件,其挤塑绝缘界面是海缆绝缘系统性能的薄弱区域。通过调控软接头挤塑材料参数改善界面的电气性能与力学性能具有重要工程实践意义。该文以低密度聚乙烯为挤塑材料,搭配不同质量分数的过氧化二异丙苯交联剂以实现多级挤塑交联程度,探究挤塑交联程度对双层交联聚乙烯试样界面电气性能及力学性能的影响规律,并结合微观形态分析阐释深层作用机理。结果表明,当挤塑交联程度较低（交联度低于本体材料的84.5%）时,界面处无定型区占比随交联程度的增加而明显降低,晶胞形态趋于均一连贯,导致电气性能与力学性能显著提高。随着挤塑交联程度进一步提高到与本体相同时,虽然电导率与直流击穿场强稍有改善,但界面处形成的大量小尺寸晶区反而导致界面拉伸强度下降,并会加剧界面空间电荷积聚。考虑到高交联挤塑会增加焦烧风险,适当降低挤塑交联程度可提升工艺稳定性,并保障高压直流海缆软接头的质量。

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关键词 ：海缆软接头, 交联聚乙烯, 界面性能, 交联度, 结晶形态

Abstract：High-voltage direct current (HVDC) cross-linked polyethylene (XLPE) submarine cables serve as the core transmission equipment for grid integration of offshore wind power, with the interfacial performance of factory joints directly determining the long-term reliability of the cable system. This study systematically investigates the influence of extrusion crosslinking degree on the interfacial electrical and mechanical properties of factory joints, focusing on the critical weak area of the extruded insulation interface. By adjusting the dicumyl peroxide (DCP) content to achieve graded crosslinking degrees and combining microstructural characterization with macro-performance testing, the relationship between extrusion crosslinking degree and interfacial properties is revealed.
Low-density polyethylene (LDPE) was used as the base material, and extrusion materials with DCP content gradients ranging from 0% to 3.5% were prepared via the impregnation absorption method. XLPE with 2% DCP content served as the bulk material. Single-layer (S-series) and double-layer (D-series) specimens simulating factory joint interfaces were fabricated using a flat-plate hot-pressing method. The crosslinking degree was measured by xylene extraction, interfacial crystalline morphology was observed via scanning electron microscopy (SEM), and interfacial performance was comprehensively evaluated through tensile strength testing, conductivity testing, space charge distribution (PEA method), and DC breakdown testing.
Physicochemical results indicate that an appropriate increase in DCP content enhances XLPE crosslinking degree, while excessive DCP (>2%) reduces it. SEM observations reveal that the interface of double-layer XLPE specimens exhibits tortuous and discontinuous microstructural features, with localized amorphous regions, coherent crystalline regions, and small-sized crystalline regions. The extrusion crosslinking degree significantly influences interfacial microstructure distribution: at relatively low crosslinking degrees (DCP content <1%, crosslinking degree <84.5% of the bulk material), the proportion of amorphous regions at the interface decreases markedly with increasing crosslinking degree, and crystallite size distribution becomes more uniform and continuous. When the extrusion crosslinking degree matches that of the bulk material, the interface develops numerous small-sized crystalline regions, while excessive DCP leads to the formation of microcracks.
Electrical and mechanical tests demonstrate that, except for conductivity, the DC electrical and mechanical properties of double-layer specimens are inferior to those of bulk material without interfaces, confirming that the XLPE interface is a weak point in HVDC submarine cable factory joints. When the extrusion crosslinking degree is below 84.5% of the bulk material, interfacial tensile strength, space charge characteristics, conductivity, and DC breakdown voltage improve significantly with increasing crosslinking degree, with space charge accumulation nearly disappearing at 84.5% crosslinking. However, when the extrusion crosslinking degree matches that of the bulk material, although conductivity decreases and DC breakdown strength slightly improves, interfacial tensile strength and space charge characteristics deteriorate, increasing the risk of deformation, electric field distortion, and even insulation failure under HVDC conditions. Notably, excessive DCP (>2%) causes severe degradation in both electrical and mechanical performance.
In summary, moderately reducing the extrusion crosslinking degree (to approximately 84.5% of the bulk material) enhances interfacial mechanical strength and space charge suppression. This approach not only mitigates scorching risks and improves process stability but also ensures the quality of HVDC submarine cable factory joint interfaces. These findings provide critical theoretical guidance for optimizing the manufacturing process of factory joints.

Key words： Submarine cable factory joint cross-linked polyethylene interfacial properties crosslinking degree crystalline morphology

收稿日期: 2025-04-30

PACS:

TM215

基金资助:国家自然科学基金（92266110）、福建省自然科学基金（2024J09019）和新型电力系统运行与控制国家重点实验室开放基金课题（SKLD24KZ05）资助项目

通讯作者: 张云霄男,1990年生,博士,副教授,研究方向为绝缘材料老化及检测、绝缘新材料和绝缘测试方法等。E-mail：zhangyxthu@163.com

作者简介: 陈予翔男,2001年生,硕士研究生,研究方向为高压绝缘材料等。E-mail：2080634472@qq.com

引用本文:

张云霄, 陈予翔, 林温馨, 胡昊, 刘育豪. 挤塑交联程度对高压直流海缆软接头界面电气性能与力学性能的影响[J]. 电工技术学报, 2026, 41(7): 2457-2467. Zhang Yunxiao, Chen Yuxiang, Lin Wenxin, Hu Hao, Liu Yuhao. Effect of Extrusion Crosslinking Degree on the Interfacial Electrical and Mechanical Properties of HVDC Submarine Cable Factory Joints. Transactions of China Electrotechnical Society, 2026, 41(7): 2457-2467.

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[1] 王皓, 王继轩, 于思洋, 等. 双定子风力发电机及关键技术发展综述[J]. 电工技术学报, 2025, 40(18): 5786-5804.
Wang Hao, Wang Jixuan, Yu Siyang, et al.Overview of dual-stator wind power generator and its key technology[J]. Transactions of China Electrotech-nical Society, 2025, 40(18): 5786-5804.
[2] Paul S, Nath A P, Rather Z H.A multi-objective planning framework for coordinated generation from offshore wind farm and battery energy storage system[J]. IEEE Transactions on Sustainable Energy, 2020, 11(4): 2087-2097.
[3] 姚钢, 杨浩猛, 周荔丹, 等. 大容量海上风电机组发展现状及关键技术[J]. 电力系统自动化, 2021, 45(21): 33-47.
Yao Gang, Yang Haomeng, Zhou Lidan, et al.Development status and key technologies of large-capacity offshore wind turbines[J]. Automation of Electric Power Systems, 2021, 45(21): 33-47.
[4] 李根, 杜志叶, 肖湃, 等. 海上风电送出J型管段海底电缆载流量计算模型研究[J]. 电工技术学报, 2023, 38(13): 3619-3629.
Li Gen, Du Zhiye, Xiao Pai, et al.Study on calculation model of submarine cable ampacity in J-tube section of offshore wind power transmission[J]. Transactions of China Electrotechnical Society, 2023, 38(13): 3619-3629.
[5] Mazzanti G.High voltage direct current transmission cables to help decarbonisation in Europe: recent achievements and issues[J]. High Voltage, 2022, 7(4): 633-644.
[6] 赵皓琳, 刘英, 吴婧, 等. 基于异质异径线芯选型实现载流量优化匹配的高压XLPE海缆系统设计[J]. 电工技术学报, 2025, 40(15): 4954-4965.
Zhao Haolin, Liu Ying, Wu Jing, et al.Design of high-voltage XLPE submarine cable system based on ampacity optimized matching of cores with different materials and sizes[J]. Transactions of China Electro-technical Society, 2025, 40(15): 4954-4965.
[7] 杜伯学, 李忠磊, 杨卓然, 等. 高压直流交联聚乙烯电缆应用与研究进展[J]. 高电压技术, 2017, 43(2): 344-354.
Du Boxue, Li Zhonglei, Yang Zhuoran, et al.Application and research progress of HVDC XLPE cables[J]. High Voltage Engineering, 2017, 43(2): 344-354.
[8] 钟力生, 任海洋, 曹亮, 等. 挤包绝缘高压直流电缆的发展[J]. 高电压技术, 2017, 43(11): 3473-3489.
Zhong Lisheng, Ren Haiyang, Cao Liang, et al.Development of high voltage direct current extruded cables[J]. High Voltage Engineering, 2017, 43(11): 3473-3489.
[9] 张添胤, 陈向荣, 王恩哲, 等. 硫化压力对500kV超高压直流XLPE电缆工厂接头恢复绝缘性能的影响[J]. 电工技术学报, 2025, 40(9): 2931-2943.
Zhang Tianyin, Chen Xiangrong, Wang Enzhe, et al.Effect of vulcanization pressure on the return insulation performance of 500 kV EHVDC XLPE cable factory joints[J]. Transactions of China Electrotechnical Society, 2025, 40(9): 2931-2943.
[10] 史润普. 高压海缆工厂接头绝缘层界面区微观结构及电树枝化行为研究[D]. 哈尔滨: 哈尔滨理工大学, 2022.
Shi Runpu.Study on microstructure and electrical treeing behavior of insulation layer interface of high voltage submarine cable factory joint[D]. Harbin: Harbin University of Science and Technology, 2022.
[11] 李忠磊, 吴优, 郑重, 等. 高压直流海缆XLPE绝缘空间电荷与电场分布特性研究进展及展望[J]. 高电压技术, 2024, 50(7): 3128-3144.
Li Zhonglei, Wu You, Zheng Zhong, et al.Advances and prospects of space charge and electric field distribution characterization of XLPE insulation for HVDC submarine cables[J]. High Voltage Engineering, 2024, 50(7): 3128-3144.
[12] Zhang Zhenpeng, Zheng Changji, Zheng Mei, et al.Interface damages of electrical insulation in factory joints of high voltage submarine cables[J]. Energies, 2020, 13(15): 3892.
[13] 张振鹏, 胡列翔, 赵健康, 等. 500 kV海缆工厂接头绝缘恢复过渡区形成过程及电树枝特性[J]. 高电压技术, 2019, 45(11): 3413-3420.
Zhang Zhenpeng, Hu Liexiang, Zhao Jiankang, et al.Formation process and electrical tree characteristics of insulation recovery transition zone of factory joints in 500 kV submarine cable[J]. High Voltage Engineering, 2019, 45(11): 3413-3420.
[14] Zhao Wei, Li Huaqiang, Li Wenpeng, et al.Charge accumulation in the homo-crosslinked-polyethylene bilayer[J]. Materials, 2022, 15(9): 3024.
[15] 李震, 郑海峰, 陈俊岐, 等. 基于磁感应联合加热的高压海缆工厂接头制备技术[J]. 电工技术学报, 2024, 39(3): 820-835.
Li Zhen, Zheng Haifeng, Chen Junqi, et al.Manufacture technologies of high-voltage submarine cable factory joint based on magnetic induction combined heating[J]. Transactions of China Electro-technical Society, 2024, 39(3): 820-835.
[16] 朱俊杰, 陈卫东, 任冰, 等. 悬跨海底电缆涡激振动特性及疲劳损伤分析[J]. 海洋工程, 2023, 41(5): 116-127.
Zhu Junjie, Chen Weidong, Ren Bing, et al.Analysis of vortex-induced vibrations and fatigue damage of a free spanning submarine power cable[J]. The Ocean Engineering, 2023, 41(5): 116-127.
[17] 祝曦, 林国海, 张洪亮, 等. 直流电压下XLPE电树枝化过程中的局部放电特性[J]. 中国电机工程学报, 2022, 42(6): 2416-2427.
Zhu Xi, Lin Guohai, Zhang Hongliang, et al.Characteristics of partial discharge during electrical treeing in XLPE under DC voltage[J]. Proceedings of the CSEE, 2022, 42(6): 2416-2427.
[18] Meng Fanbo, Chen Xiangrong, Hong Zelin, et al.Insulation properties and interfacial quantum chemical analysis of cross-linked polyethylene under different degassing time for HVDC cable factory joint applications[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2022, 30(1): 271-278.
[19] Meng Fanbo, Chen Xiangrong, Shi Yiwen, et al.Temperature-dependent charge dynamics of double layer interface in 500 kV HVDC XLPE cable factory joint with different interfacial roughness[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2022, 29(2): 655-662.
[20] Qin Yao, Ge Yi, Zhao Juntao, et al.Characteristics of charge accumulation at the interface of double-layer XLPE under DC voltage[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2025, 32(2): 707-716.
[21] 孟繁博, 陈向荣, 洪泽林, 等. 界面喷涂Mg(OH)₂对直流电缆工厂接头绝缘交接层直流电气性能的影响[J]. 电工技术学报, 2023, 38(23): 6471-6482.
Meng Fanbo, Chen Xiangrong, Hong Zelin, et al.Influence of interface spraying Mg(OH)₂ on DC electrical properties of DC cable factory joints insulation transition layer[J]. Transactions of China Electrotechnical Society, 2023, 38(23): 6471-6482.
[22] Akbarian D, Hamedi H, Damirchi B, et al.Atomistic-scale insights into the crosslinking of polyethylene induced by peroxides[J]. Polymer, 2019, 183: 121901.
[23] 王要辉. 线型低密度聚乙烯电缆料交联过程与性能研究[D]. 杭州: 浙江大学, 2024.
Wang Yaohui.Study of the crosslinking process and performance of LLDPE cable material[D]. Hangzhou: Zhejiang University, 2024.
[24] 李盛涛, 王诗航, 杨柳青, 等. 高压电缆交联聚乙烯绝缘的关键性能与基础问题[J]. 中国电机工程学报, 2022, 42(11): 4247-4255.
Li Shengtao, Wang Shihang, Yang Liuqing, et al.Important properties and fundamental issues of the crosslinked polyethylene insulating materials used in high-voltage cable[J]. Proceedings of the CSEE, 2022, 42(11): 4247-4255.
[25] 周远翔, 吴优, 张灵, 等. 预交联对XLPE直流电缆料空间电荷特性的影响[J]. 绝缘材料, 2022, 55(3): 23-31.
Zhou Yuanxiang, Wu You, Zhang Ling, et al.Effect of pre-crosslinking on space charge characteristics of XLPE DC cable materials[J]. Insulating Materials, 2022, 55(3): 23-31.
[26] 白健, 张亚, 詹陶, 等. 脱气时间对电缆绝缘中交联副产物含量和直流特性的影响[J/OL]. 高压电器, 2024: 1-11[2025-03-09]. https://kns.cnki.net/KCMS/detail/detail.aspx?filename=GYDQ20240306001&dbname=CJFD&dbcode=CJFQ.
Bai Jian, Zhang Ya, Zhan Tao, et al. Effect of degassing time on byproducts content and DC characteristics of cable insulation[J/OL]. High Voltage Apparatus, 2024: 1-11[2025-03-09]. https://kns.cnki.net/KCMS/detail/detail.aspx?filename=GYDQ20240306001&dbname=CJFD&dbcode=CJFQ.
[27] 王兆琛, 段玉兵, 魏艳慧, 等. 高压电缆绝缘热老化特性及破坏机理研究[J]. 高压电器, 2023, 59(11): 56-64.
Wang Zhaochen, Duan Yubing, Wei Yanhui, et al.Research on insulation thermal aging characteristic and destruction mechanism of high voltage cable[J]. High Voltage Apparatus, 2023, 59(11): 56-64.
[28] Qu Jinfei, Wang Shihang, Li Shengtao, et al.The enhanced physical properties of XLPE insulation for high voltage cable based on LDPE/LLDPE or LDPE/ HDPE blends[J]. Polymer Degradation and Stability, 2023, 218: 110573.
[29] Wang Chuang, Lei Kang, Sun Qing, et al.Stress concentration effect in interface between conductor and epoxy resin in coaxial components of power equipment[J]. CSEE Journal of Power and Energy Systems, 2024, 10(1): 412-420.