Experimental study on ice monitoring method for 10 kV transmission line with tangent tower in alpine landform

IF 4.4 2区 工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC High Voltage Pub Date : 2023-09-09 DOI:10.1049/hve2.12372
Lin Yang, Zhiqiang Chen, Yanpeng Hao, Xinhao Lin, Lei Yu, Yue Li, Zhiyong Yuan, Licheng Li
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Abstract

Ice monitoring methods were applied for 110 kV and above transmission lines with tangent towers. However, the change in the vertical span is not considered, and a significant difference lies in the tower-conductor structure of 10 kV transmission lines. For this reason, a proposal is made about the ice monitoring method for the 10 kV transmission line with tangent tower in alpine landform, which includes the ice monitoring system based on pressure measurement and corresponding equivalent ice thickness calculating methods. Different methods calculate the vertical span under different height difference coefficients. A finite element simulation model and a simulated ice load experiment system are established based on real conductors and insulators. Experiments and simulations under four simulated terrains are conducted within 2.5–20 mm ice thickness range. The comparison is made between this method and the method without considering the change in vertical span. The results show that the two methods are consistent and the relative errors are lower than ±4% in simulation and ±10% in experiment when the height difference coefficient is 0. When it is not 0, the relative errors of this method fall between +0.38% and +6.78% in simulation and −6.40% to +6.60% in experiment, while the relative errors of the method without considering the change in vertical span ranges between −11.13% and −20.23% in simulation and −11.65% to −23.20% in experiment.

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高山地貌切线塔 10 千伏输电线路覆冰监测方法试验研究
冰监测方法适用于 110 千伏及以上的切线塔输电线路。但没有考虑垂直跨度的变化,而 10 千伏输电线路的杆塔-导线结构存在显著差异。因此,本文提出了高寒地貌切线塔 10 千伏输电线路的覆冰监测方法,包括基于压力测量的覆冰监测系统和相应的等效冰厚计算方法。不同方法计算不同高差系数下的垂直跨度。建立了基于真实导体和绝缘体的有限元模拟模型和模拟冰载荷实验系统。在 2.5-20 毫米冰厚范围内,在四种模拟地形下进行了实验和模拟。该方法与不考虑垂直跨度变化的方法进行了比较。结果表明,当高度差系数为 0 时,这两种方法是一致的,模拟的相对误差小于 ±4%,实验的相对误差小于 ±10%;当高度差系数不为 0 时,模拟的相对误差在 +0.38% 到 +6.78% 之间,实验的相对误差在 -6.40% 到 +6.60% 之间;而不考虑垂直跨度变化的方法,模拟的相对误差在 -11.13% 到 -20.23% 之间,实验的相对误差在 -11.65% 到 -23.20% 之间。
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来源期刊
High Voltage
High Voltage Energy-Energy Engineering and Power Technology
CiteScore
9.60
自引率
27.30%
发文量
97
审稿时长
21 weeks
期刊介绍: High Voltage aims to attract original research papers and review articles. The scope covers high-voltage power engineering and high voltage applications, including experimental, computational (including simulation and modelling) and theoretical studies, which include: Electrical Insulation ● Outdoor, indoor, solid, liquid and gas insulation ● Transient voltages and overvoltage protection ● Nano-dielectrics and new insulation materials ● Condition monitoring and maintenance Discharge and plasmas, pulsed power ● Electrical discharge, plasma generation and applications ● Interactions of plasma with surfaces ● Pulsed power science and technology High-field effects ● Computation, measurements of Intensive Electromagnetic Field ● Electromagnetic compatibility ● Biomedical effects ● Environmental effects and protection High Voltage Engineering ● Design problems, testing and measuring techniques ● Equipment development and asset management ● Smart Grid, live line working ● AC/DC power electronics ● UHV power transmission Special Issues. Call for papers: Interface Charging Phenomena for Dielectric Materials - https://digital-library.theiet.org/files/HVE_CFP_ICP.pdf Emerging Materials For High Voltage Applications - https://digital-library.theiet.org/files/HVE_CFP_EMHVA.pdf
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