微地形条件下220 kV朝峰线覆冰断线机理分析

doi:10.11930/j.issn.1004-9649.2016.05.001.07

中国电力 ›› 2016, Vol. 49 ›› Issue (5): 1-7.DOI: 10.11930/j.issn.1004-9649.2016.05.001.07

微地形条件下220 kV朝峰线覆冰断线机理分析

张宇娇¹，孔韬¹，苏攀¹，董晓虎²，雷成华²

1．三峡大学电气与新能源学院，湖北宜昌443002；
2.国网湖北省电力公司检修公司，湖北武汉430050

收稿日期:2015-08-24 出版日期:2016-05-16 发布日期:2016-05-16
作者简介:张宇娇（1979—），女，湖北武汉人，博士，副教授，从事超特高压输变电设备运行状态评估、灾害条件下超特高压输电线路故障防治技术研究。E-mail: jiao_zyj@163.com
基金资助:
国家自然科学基金资助项目（51577106）

Analysis of the Breakage Mechanism of Iced-Wire for a 220 kV Transmission Tower-Line System Considering the Microtopography

ZHANG Yujiao¹, KONG Tao¹, SU Pan¹, DONG Xiaohu², LEI Chenghua²

1. College of Electrical Engineering and New Energy, China Three Gorges University, Yichang 443002, China;
2. Maintenance Company, State Grid Hubei Electric Power Company, Wuhan 430050, China

Received:2015-08-24 Online:2016-05-16 Published:2016-05-16
Supported by:
This work is supported by National Natural Science Foundation of China (No. 51577106).

摘要/Abstract

摘要： 为了深入研究微地形对覆冰线路不平衡张力及覆冰断线冲击的扩大效应，针对处于微地形区朝峰线输电线路覆冰断线事故，建立事故区4塔3档塔线体系有限元模型，定量计算不同工况下塔线体系临界覆冰厚度及断线冲击响应情况，提取不同覆冰工况及不同地形下数据对比分析。结果表明，该微地形下形成的重度覆冰和大高差档距扩大了塔线体系不平衡张力，覆冰断线造成的冲击动力响应远大于非微地形区覆冰断线情况，微地形区形成的重度覆冰及大档距高差扩大了断线冲击效应。

关键词: 微地形, 塔线体系, 有限元分析, 导线找形, 覆冰, 断线冲击

Abstract: In order to analyze the effect of the microtopography on the imbalance tension of iced transmission lines and the amplifying effect when the iced wires are breaking, a finite model is developed for a four-tower-three-level tower-line system for the accident area. The model is applied to determine the critical thickness of the icing under different working conditions and the corresponding shocking responses when ice covered wires are breaking. Data is collected and cross-compared for different icing conditions and microtopographies. The results show that the heavy ice formulation in the microtopography and the large height difference between towers increase the imbalance tension. Further, the dynamic response effect caused by the breakage of the iced wires in the microtopography is significantly higher than in a non-microtopography area. Finally, the heavy formation of ice in the microtopography and the large height difference between towers increase the shocking effect of wire breakage.

Key words: microtopography, tower line system, finite element analysis, conductor form finding, icing, wire breakage shock

中图分类号:

TM 752+.5

张宇娇，孔韬，苏攀，董晓虎，雷成华. 微地形条件下220 kV朝峰线覆冰断线机理分析[J]. 中国电力, 2016, 49(5): 1-7.

ZHANG Yujiao, KONG Tao, SU Pan, DONG Xiaohu, LEI Chenghua. Analysis of the Breakage Mechanism of Iced-Wire for a 220 kV Transmission Tower-Line System Considering the Microtopography[J]. Electric Power, 2016, 49(5): 1-7.

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微地形条件下220 kV朝峰线覆冰断线机理分析

Analysis of the Breakage Mechanism of Iced-Wire for a 220 kV Transmission Tower-Line System Considering the Microtopography

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微地形条件下220 kV朝峰线覆冰断线机理分析

Analysis of the Breakage Mechanism of Iced-Wire for a 220 kV Transmission Tower-Line System Considering the Microtopography

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