Suzhou Electric Appliance Research Institute
期刊号: CN32-1800/TM| ISSN1007-3175

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多回路高压电缆群稳态温度场建模与分析

来源:电工电气发布时间:2020-06-18 14:18 浏览次数:877
多回路高压电缆群稳态温度场建模与分析
 
付明星,王善红,王雁冰,潘恒
(国网江苏省电力有限公司盐城供电分公司,江苏 盐城 224002)
 
摘 要:为解决多回路电缆群温度场计算问题,以220 kV高压电缆为研究对象,采用有限元法建立多回路电缆群稳态温度场的磁热耦合计算模型,计算得到多回路电缆群的电磁损耗和温度场分布结果,经与IEC 60287标准计算结果对比,验证了模型有效性,并结合仿真模型,探讨了空气温度、土壤热阻系数等各种因素对多回路电缆群温度场分布的影响,为电缆群运行维护提供了参考。
关键词:高压电缆;多回路;有限元法;稳态温度场;磁热耦合
中图分类号:TM726.4     文献标识码:A      文章编号:1007-3175(2020)06-0019-05
 
Modeling and Analysis of Steady Temperature Field of Multi-Circuit High-Voltage Cables in Group
 
FU Ming-xing, WANG Shan-hong, WANG Yan-bing, PAN Heng
(Yancheng Power Supply Company of State Grid Jiangsu Electric Power Company, Yancheng 224002, China)
 
    Abstract: In order to solve the calculation of the temperature field of the multi-loop cable group, 220 kV high-voltage cable is taken as the research object, and a finite element method is used to establish a magnetic-thermal coupling calculation model of the multi-loop cable group. The electromagnetic loss and temperature distribution of the multi-loop cable group are calculated. Compared with the calculation results of the IEC 60287 standard, the validity of the model is verified. Combined with the simulation model, the effects of various factors such as air temperature and soil thermal resistance coefficient on the temperature field distribution of the multi-loop cable group are discussed, which provides a reference for the operation and maintenance of the cable group.
    Key words: high-voltage cables; multi-circuit; finite element method; steady temperature field; magnetic-thermal coupling
 
参考文献
[1] 王丽, 罗健斌. 城市电网高压电缆光纤传感在线监测技术比对试验研究[J]. 高压电器,2015,51(7):63-68.
[2] CHOO W, CHEN G, SWINGLER S G.Electric Field in Polymeric Cable due to Space Charge Accumulation under DC and Temperature Gradient[J].IEEE Transactions on Dielectrics and Electrical
Insulation,2011,18(2):596-606.
[3] 梁永春. 高压电力电缆温度场和载流量评估研究动态[J]. 高电压技术,2016,42(4):1142-1150.
[4] MARC D A, FRANCISCO D L.Adaptive soil model for real-time thermal rating of underground power cables[J].IET Science, Measurement & Technology,2015,9(6):654-660.
[5] 梁永春,李延沐,李彦明,等. 利用模拟热荷法计算地下电缆稳态温度场[J]. 中国电机工程学报,2008,28(16):129-134.
[6] 雷鸣,刘刚,邱景生,等. 单芯电缆线芯温度的非线性有限元法实时计算[J]. 电网技术,2011,35(11):163-168. 
[7] 牛海清,周鑫,王晓兵,等. 外皮温度监测的单芯电缆暂态温度计算与试验[J]. 高电压技术,2009,35(9):2138-2143. 
[8] 梁永春,柴进爱,李彦明,等. 有限元法计算交联电缆涡流损耗[J]. 高电压技术,2007,33(9):196-199. 
[9] 崔厚坤,王庭华,安增军,等. 基于有限元法的电缆涡流损耗计算[J]. 三峡大学学报( 自然科学版),2016,38(5):87-90. 
[10] 茅大钧,肖礼,刘国建. 基于有限元分析的埋地电缆温升影响因素研究[J]. 电力科学与技术学报,2016,31(4):136-142. 
[11] 杜兆斌,杨泽明,谌军,等. 超高压海底电缆护套环流的理论计算新方法[J]. 华南理工大学学报( 自然科学版),2013,41(12):63-69. 
[12] 陶文铨. 数值传热学[M].2 版. 西安:西安交通大学出版社,2001.