一种新型配电网电流互感器三维电热耦合仿真计算与分析

Gu Yu, Bingbing Dong, Zelin Zhang, N. Xiang, Du Bin, Zhang Zhu
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引用次数: 2

摘要

近年来,新型套管结构电流互感器因其小型化、机械强度高、免维护、安全环保等优点,在配电网系统中得到了广泛的应用。变压器内部电场和温度场的分布是表征变压器电绝缘和老化性能的重要特征参数。CT内导体、二次绕组和绝缘介质的电场分布主要由外加电压和相对介电常数决定,而温度场分布主要由一次电流的欧姆热和绝缘介质的焦耳热决定。因此,对CT的电热耦合场的研究更加复杂和必要。本文利用有限元软件建立了一种基于热电耦合的新型配电网电流互感器的三维仿真模型。考虑到CT的实际热传导过程主要是通过传导、对流和辐射进行的,因此对CT采用了固体传热边界条件、热对流边界条件和表面辐射边界条件三种不同的边界条件。通过上述建立的模型,研究了CT在不同电流条件下的温升过程和温度分布特征。同时,计算了电流互感器的最大场强和最高温度。据此确定变压器弱绝缘的位置。研究结果可为新型电流互感器的工厂化生产提供参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulation calculation and analysis on three-dimensional electrothermal coupling of a new type of current transformer for distribution network
In recent years, the new type current transformer with bushing structure has been widely used in the distribution network system due to its advantages of miniaturization, high mechanical strength, maintenance-free, safety and environmental protection. The distribution of electric field and temperature field inside the transformer are important characteristic parameters to characterize its electrical insulation and aging performance. Then, the electric field distribution of inner conductor, secondary winding and insulating medium of CT is mainly determined by the applied voltage and relative dielectric constant, while the distribution of the temperature field mainly comes from ohmic heat of primary current and joule heat of insulating medium. Therefore, the study on the electro-thermal coupling field of CT is more complicated and necessary. In this paper, a 3D simulation model of a new type of current transformer for distribution network based on electric-thermal coupling is established by using finite element software. Considering that the actual thermal conduction process of CT is mainly by conduction, convection and radiation, three different kinds of boundary conditions such as solid heat transfer boundary condition, heat convection boundary condition and surface radiation boundary condition are applied to the CT. Through the model created above, the temperature rise process and the distribution characteristics of temperature of the CT under different current conditions are studied. Meanwhile, the maximum field strength and the hottest temperature of the CT are calculated. According to this, the position of weak insulation of the transformer is determined. The research results can provide a reference for the factory production of new type current transformer.
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