期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

柔性直流输电系统用直流交联聚乙烯绝缘电缆导体最高温度提高到90℃的可行性 被引量:7

Feasibility of Raising the Maximum Conductor Temperature to 90℃ of DC XLPE Cables with Rated Voltages up to 320 kV for VSC System
下载PDF
导出
摘要 以实际直流交联聚乙烯(DC XLPE)电缆工程设计示例,表明将柔性直流输电(VSC)系统用DC XLPE电缆的导体的最高运行温度提高到90℃,其技术经济效果显著。按DC XLPE电缆抑制空间电荷要求,阐明DC XLPE电缆绝缘的直流恒定电流电场中空间电荷密度与绝缘温度梯度和XLPE绝缘的体积电阻率的温度系数成正比而与导体最高温度不直接相关。通过合理的DC XLPE电缆工程设计和正确选用DC XLPE电缆,可以在提高DC XLPE电缆传输功率和减小绝缘温差抑制空间电荷方面取得优化结果。320 kV及以下XLPE电缆在导体最高温度90℃下运行,绝缘损耗远低于导体损耗,DC XLPE电缆发生热不稳定的可能性很低。对VSC系统用DC XLPE电缆导体运行温度提高到90℃的可行性表示肯定的意见,对实现目标提出具体的措施建议。 The significant techno-economic effect by raising the maximum conductor temperature of DC XLPE cable to 90℃ for VSC system is confirmed with example of DC XLPE cable engineering design as shown in the paper. The paper illustrates that space charge density is proportional to the temperature coefficient of resistivity as well as temperature gradient in DC XLPE insulation rather than relating directly the maximum conductor temperature of DC XLPE cable. It is possible to optimize DC XLPE cable property aiming at higher transmission power and less space charge accumulation for DC XLPE cable operated at maximum conductor temperature of 90℃. Besides the" paper indicates that insulation loss caused by leakage current of DC XLPE cable with rated vohage up to 320 kV is much lower than conductor current transmission loss at 90℃. Very low possibility of thermal instability for DC cable insulation is expected. It is concluded that raising the maximum temperature of DC XLPE cable to 90℃ is feasible and some concrete measures are proposed to realize the target.
作者 应启良
机构地区 上海电缆研究所
出处 《电线电缆》 2014年第3期1-4,共4页 Wire & Cable
关键词 柔性直流输电 直流交联聚乙烯绝缘电缆 导体最高运行温度 绝缘空间电荷 绝缘热不稳定性 VSC transmission DC XLPE cable maximum conductor temperature space charge accumulation thermal instability of insulation
分类号 TM247.1 [一般工业技术—材料科学与工程]
  • 相关文献

参考文献4

  • 1Jeroence M, Gustafsson A, Berkvist M. HVDC Light cable sys- tem extended to 320 kV [ C ]//CIGRE 2008, B1-304.
  • 2Baeeini M, Westerweller T, Kelley N. 200 kV DC extruded eables erossing the San Francisco Bay [ C]//CIGRE 2010,B1-105.
  • 3Eoll C K. Theory of stress distribution in insulation of high voh- age DC eable :Part 1 [J]. IEEE Trans on Eleetrieal Insulation, 1975 ,EI(10) :27-35.
  • 4Fabiani D, Montanari G C, Laurent C, et al . HVDC Cable de- sign and spaee charge aeeumulation. Part 3 : effect of temperature gradient [ J ]. IEEE Eleetrieal Insulation Magazine ,2008,24 (2) : 5-13.

同被引文献86

  • 1郑飞虎,张冶文,肖春.聚合物电介质的击穿与空间电荷的关系[J].材料科学与工程学报,2006,24(2):316-320. 被引量:51
  • 2孟凡凤,李香龙,徐燕飞,梁永春,李彦明,李忠魁.地下直埋电缆温度场和载流量的数值计算[J].绝缘材料,2006,39(4):59-61. 被引量:45
  • 3Calculation of the current rating of electric cables: Part 1 current rating equations (100% load factor) and calculation of losses: Section 1 general: IEC 60287 1-1: 1994[S]. Geneva: IEC Publication, 1994.
  • 4Calculation of the current rating of electric cables: Part 1 current rating equations (100% load factor) and calculation of losses: Section 2 sheath eddy current loss factor for two circuits in flat formation: IEC 60287-1 2: 1993[S]. Geneva: IEC Publication, 1993.
  • 5Calculation of the current rating of electric cables: Part 2 thermal resistance: Section l calculation of thermal resistance: IEC 60287-2-1: 1994[S]. Geneva: IEC Publication, 1994.
  • 6Calculation of the current rating of electric cables: Part 3 sections on operating conditions: Section 1 reference operating conditions and selection of cable type: IEC 60287-3-1: 1995[S]. Geneva: IEC Publication, 1995.
  • 7ANDERS G J, CHAABAN M, BEDARD N, et al. New approach to ampacity evaluation of cables in ducts using finite element teehnique[J]. IEEE Trans on Power Delivery, 1987, 2(3) : 969-975.
  • 8GELA G, DAI J J. Calculation of thermal fields of underground cables using the boundary element method[J]. IEEE Trans on Power Delivery, 1988, 5(3): 1341-1347.
  • 9HIRANANDANI A. Calculation of conductor temperatures and ampacities of cable systems using a generalized finite difference model[J]. IEEE Trans on Power Delivery, 1991, 6(1): 15-24.
  • 10GIOVANNI M, MASSIMO M. Extruded cables for high voltage direct current transmission: advances in research and development[M]. Wiley-IEEE Press, 2013.

引证文献7

二级引证文献93

电线电缆
2014年 第3期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部