铝护套与缓冲层间气隙对高压电缆的电-热耦合影响Influence of Air Gap between Aluminum Sheath and Buffer on Electro-thermal Coupling Characteristics of HV Cables
刘黎,周路遥,李晋贤,王少华,杨帆,尚瑞琦
LIU Li,Zhou Luyao,LI Jinxian,WANG Shaohua,YANG Fan,SHANG Ruiqi
摘要(Abstract):
近年来,国内110 kV及以上电压等级电缆发生多起缓冲层烧蚀故障。采用有限元法建立了高压电缆轴向仿真模型并开展了电-热耦合仿真,研究了波纹铝护套在正常状态以及与缓冲层之间存在气隙时的温度场分布,得到以下仿真结果:当波纹铝护套与缓冲层间存在气隙时,不利于电缆本体的散热,将导致载流量下降;气隙放电会加剧阻水缓冲层烧蚀,气隙放电时的热源中心温升可达470 K,但在未造成缓冲层阻水粉析出时,短时气隙放电对电缆本体的宏观温度分布影响较小。
In recent years, multiple buffer layer ablation failures occurred in domestic cables with voltage levels of 110 kV and above. In this paper, the finite element method is used to establish an axial simulation model of HV cable, and the electro-thermal coupling simulation is carried out to study the distribution of temperature field of corrugated aluminum sheath operating in a normal situation and in the case of air gaps between buffer layers. The simulation results show that when there is an air gap between the corrugated aluminum sheath and the buffer layer, it is disadvantageous for heat dissipation, and thus ampacity decrease of cables; air-gap discharge aggravates the erosion of the buffer layer, and the temperature rise in the center of heat source can reach up to 470 K, but the macroscopic effect of short-time air gap discharge on the cable temperature distribution can be ignored before the water-blocking powder is separated out.
关键词(KeyWords):
波纹铝护套;缓冲层;电-热耦合场;气隙放电
corrugated aluminum sheath;buffer layer;electro-thermal coupling field;air-gap discharge
基金项目(Foundation): 国网浙江省电力有限公司科技项目(5211DS18002W)
作者(Author):
刘黎,周路遥,李晋贤,王少华,杨帆,尚瑞琦
LIU Li,Zhou Luyao,LI Jinxian,WANG Shaohua,YANG Fan,SHANG Ruiqi
DOI: 10.19585/j.zjdl.202111008
参考文献(References):
- [1]孟峥峥,李旭,于洋,等.高压XLPE电缆缓冲层故障研究现状综述[J].中国电力,2021,54(4):33-41.
- [2]汪传斌,金海云.高压XLPE绝缘电力电缆缓冲层与金属护层结构设计仿真计算与优化[J].电线电缆,2018(3):6-12.
- [3]张静,王伟,徐明忠,等.高压电缆缓冲层轴向沿面烧蚀故障机理分析[J].电力工程技术,2020,39(3):180-184.
- [4]陈云.高压XLPE电缆缓冲层故障特征与机理[D].广州:华南理工大学,2019.
- [5]张玮玮,严有祥,王蕾,等.110 kV XLPE电缆缓冲层放电灼伤问题的理化分析与仿真研究[J].高压电器,2020,56(5):155-162.
- [6]邓声华,江福章,刘和平,等.高压电缆缓冲层材料及结构特性研究[J].电线电缆,2019(2):19-27.
- [7]李陈莹,李鸿泽,陈杰,等.高压XLPE电力电缆缓冲层放电问题分析[J].电力工程技术,2018,37(2):61-66.
- [8]CHARLES Q S.Failure analysis of three 230 kV XLPE cables[C]//2010 IEEE/PES Transmission and Distribution Conference and Exposition:Latin America. Sao Paulo,Brazil. IEEE,2010:22-25.
- [9]NORDS S,HELLES?M S,HVIDSTEN S.Measurements and modeling of water diffusion in water blocking tapes for high voltage extruded cables[C]//2008 International Symposium on Electrical Insulating Materials:Yokkaichi,Japan. IEEE,2008:7-11.
- [10]GUO J J,ZHANG L L,BOGGS A S,et al.High frequency attenuation in transmission class solid dielectric cable[J].IEEE Transactions on Power Delivery,2008,23(4):1713-1719.
- [11]刘凯.短间隙电弧热等效方法及放电下绝缘卡套热力特性分析研究[D].重庆:重庆大学,2018.
- [12]程鹏.电缆接头内部缺陷下的电磁-热-力特性及表征方法研究[D].重庆:重庆大学,2016.
- [13]赵健康,樊友兵.高压电缆缓冲层的设计与工艺研究[J].电线电缆,2010(3):17-21.
- [14]侯帅,玉林威,于竞哲,等.不同温度与电场下XLPE的电导率测量与建模[J].浙江电力,2019,38(10):84-88.
- [15]朱晓辉,孟峥峥,王浩鸣,等.运行高压交联聚乙烯电力电缆的介电性能[J].高电压技术,2015,41(4):1090-1095.
- 波纹铝护套
- 缓冲层
- 电-热耦合场
- 气隙放电
corrugated aluminum sheath - buffer layer
- electro-thermal coupling field
- air-gap discharge