Lamellar Periodic Structure Evolution of XLPE Cable Insulation and Its Influence on Electrical Properties

被引:0
|
作者
Zhou S. [1 ]
Men Y. [1 ]
Liu B. [1 ]
Ji H. [1 ]
Chen D. [2 ]
Gao J. [2 ]
Li J. [2 ]
机构
[1] State Grid Beijing Electric Power Research Institute, Fengtai District, Beijing
[2] Xi’an Jiaotong University, Shaanxi Province, Xi’an
来源
Zhongguo Dianji Gongcheng Xuebao/Proceedings of the Chinese Society of Electrical Engineering | 2024年 / 44卷 / 03期
关键词
cross-linked polyethylene; DC breakdown; lamellar long period; threshold field intensity; transitional interphase;
D O I
10.13334/j.0258-8013.pcsee.222655
中图分类号
学科分类号
摘要
In order to study the effect of evolutions in the lamellar periodic structure of cross-linked polyethylene (XLPE) insulation for high-voltage DC cables on the DC dielectric properties under thermal aging, the thin slice samples of XLPE insulation layer of 500 kV DC cable are subjected to accelerated thermal aging at 135℃. The size of the lamellae/amorphous interphase, lamellae, and the long period of lamellae are analyzed by using small angle X-ray scattering (SAXS). The changes of DC conductance and breakdown characteristics under thermal aging are also analyzed. The experimental results show that the interphase thickness of lamellae/amorphous area, lamellar thickness and lamellar long period size increase slightly first and then gradually decrease with aging time, and the maximum value occurs when aging for 336 h, which has a similar change rule to the threshold field strength and DC breakdown strength. But it is opposite to the variation of the carrier mobility and the variation of the amorphous region size between lamellae. The effects of periodic structure of lamellae changes on DC breakdown strength are analyzed based on trap-controlled threshold field strength and free volume breakdown model. Comprehensive analysis shows that short-term thermal aging helps to improve the microcrystalline structure of XLPE, thereby improving the DC breakdown strength. © 2024 Chin.Soc.for Elec.Eng.
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页码:1205 / 1213
页数:8
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共 31 条
  • [21] CONTAT-RODRIGO L, GREUS A R., Biodegradation studies of LDPE filled with biodegradable additives: morphological changes.I[J], Journal of Applied Polymer Science, 83, 8, pp. 1683-1691, (2002)
  • [22] UPADHYAY A K, REDDY C C., On the mechanism of charge transport in low density polyethylene[J], Journal of Applied Physics, 122, 6, (2017)
  • [23] CHEN Xiangrong, MENG Fanbo, XIA Feng, Et al., Effect of degassing treatment on 500kV XLPE insulation characteristics and aggregation structure, Proceedings of the CSEE, 41, 10, pp. 3645-3656, (2021)
  • [24] HE Pingsheng, Structure and properties of polymers, pp. 198-200, (2009)
  • [25] LI Jianying, ZHOU Fusheng, MIN Daomin, Et al., The energy distribution of trapped charges in polymers based on isothermal surface potential decay model[J], IEEE Transactions on Dielectrics and Electrical Insulation, 22, 3, pp. 1723-1732, (2015)
  • [26] FLORY P J., The configuration of real polymer chains, The Journal of Chemical Physics, 17, 3, pp. 303-310, (1949)
  • [27] HOU Shuai, FU Mingli, LI Xiaolin, Et al., Comparative study on performances of 220kV XLPE cable insulation materials, Proceedings of the CSEE, 43, 6, pp. 2483-2495, (2023)
  • [28] KAO K C., Electrical conduction and breakdown in insulating polymers, 6th International Conference on Properties and Applications of Dielectric Materials, pp. 1-17, (2000)
  • [29] DISSADO L A, FOTHERGILL J C., Electrical degradation and breakdown in polymers, pp. 311-312, (1992)
  • [30] SABUNI M H, NELSON J K, Et al., The effects of plasticizer on the electric strength of polystyrene [J], Journal of Materials Science, 14, 12, pp. 2791-2796, (1979)
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