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交联聚乙烯(cross-linked polyethylene, XLPE)因其优异的力学性能和绝缘性能广泛应用于电力电缆领域中, 但在高压电缆的运行过程中XLPE不可避免会受到电老化、热老化和电-热联合老化的影响, 使得材料的性能和寿命下降, 因此需要对XLPE的老化性能和使用寿命进行调控. 本文介绍了XLPE的结构特性和交联机理, 系统分析了其老化过程及影响机制, 并概述了接枝、共混和纳米粒子改性等调控策略, 同时基于寿命评估模型探究了XLPE因老化而导致的寿命衰减问题. 最后, 展望了调控XLPE电缆绝缘材料使用寿命策略的未来方向, 为XLPE电缆绝缘材料的进一步改进和长期稳定运行提供理论指导.Cross-linked polyethylene (XLPE) has been widely used in the field of power cables due to its excellent mechanical properties and insulating properties. However, during the manufacturing of high voltage cables, XLPE will inevitably be affected by electrical aging, thermal aging and electro-thermal combined aging, which makes the resistance and life of the material decline. Therefore, it is necessary to enhance the aging resistance of XLPE without affecting its mechanical properties and insulating properties, so as to extend its service life. In this work, the structural characteristics and cross-linking mechanism of XLPE are introduced, the aging process and influencing mechanism are systematically analyzed, and the life decay problems of XLPE due to aging are explored by using methods such as the temperature Arrhenius equation and the inverse power law of voltage. The improvement strategies such as grafting, blending, and nanoparticle modification can be used to enhance the thermal stability, antioxidant properties, and thermal aging resistance of XLPE, thereby extending its service life. Finally, the strategies of adjusting and controlling the service life of XLPE cable insulation materials in the future are discussed, which provide theoretical guidance for further improving long-term stable operation of XLPE cable insulation materials.
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Keywords:
- cross-linked polyethylene /
- cross-linking mechanism /
- aging resistance /
- long service life
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Zhang C, Zha J W, Wang S J, Wu Y H, Yan H D, Li W K, Chen X, Dang Z M 2016 Insul. Mater. 49 1Google Scholar
[4] 郑元浩 2022 硕士学位论文(青岛: 青岛科技大学)
Zheng Y H 2022 M. S. Thesis (Qingdao: Qingdao University Science & Technology
[5] D’Auria S, Pourrahimi A M, Favero A, Neuteboom P, Xu X D, Haraguchi S, Bek M, Kádár R, Dalcanale E, Pinalli R, Müller C, Vachon J 2023 Adv. Funct. Mater. 33 2301878Google Scholar
[6] Wang S J, Zha J W, Wu Y H, Ren L, Dang Z M, Wu J 2015 IEEE Trans. Dielectr. Electr. Insul. 22 3350Google Scholar
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[9] 张雅茹, 邵清, 李娟, 袁浩, 李琦, 何金良 2022 石油化工 51 587Google Scholar
Zhang Y R, Shao Q, Li J, Yuan H, Li Q, He J L 2022 Petrochem. Technol. 51 587Google Scholar
[10] 俞葆青, 夏兵, 杨晓砚, 万宝全, 查俊伟 2023 物理学报 72 068402Google Scholar
Yu B Q, Xia B, Yang X Y, Wan B Q, Zha J W 2023 Acta Phys. Sin. 72 068402Google Scholar
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[14] Zha J W, Wu Y H, Wang S J, Wu D H, Yan H D, Dang Z M 2016 IEEE Trans. Dielectr. Electr. Insul. 23 2337Google Scholar
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[16] 聂永杰, 赵现平, 李盛涛 2019 物理学报 68 227201Google Scholar
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[41] 王春逢 2021 硕士学位论文(大连: 大连理工大学)
Wang C F 2021 M. S. Thesis (Dalian: Dalian University of Technology
[42] 张宇涵 2019 硕士学位论文(上海: 东华大学)
Zhang Y H 2019 M. S. Thesis (Shanghai: Donghua University
[43] 朱健 2017 硕士学位论文(成都: 西南交通大学)
Zhu J 2017 M. S. Thesis (Chengdu: Southwest Jiaotong University
[44] 廖瑞金, 解兵, 杨丽君, 梁帅伟, 程涣超, 孙才新, 向彬 2006 电工技术学报 21 17Google Scholar
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[48] Li L, Ma X M, Guo W 2022 Secur. Commun. Netw. 2022 1Google Scholar
[49] Alghamdi A S, Desuqi R K 2020 Heliyon 6 e03120Google Scholar
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[51] Li G C, Wang Z C, Lan R, Wei Y H, Nie Y J, Li S T, Li Q Q 2023 IEEE Trans. Dielectr. Electr. Insul. 30 761Google Scholar
[52] 马超, 闵道敏, 李盛涛, 郑旭, 李西育, 闵超, 湛海涯 2017 物理学报 66 067701Google Scholar
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