3-D FEM Analysis of Loss and Temperature Distribution in Steady State for 550kV Oil Immersed Current Transformer

Ke Wang, Jinyuan Liu, Gang Li, Jinzhong Li, Shuqi Zhang, Yang Yan, Chao Wu
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Abstract

High voltage (HV) current transformer with oil-impregnated paper insulation is one of the most important electrical apparatus in power substation, where the temperature distribution as well as maximum hot-spot temperature have significant impacts on its long-term safe operation. In the current work, the loss and temperature distribution of 550kV inverted current transformer with oil-impregnated paper insulation are investigated by three-dimensional (3-D) finite element method (FEM) and computation. The electro-magnetic-thermal field coupling model is designed according to the rated operation condition. The computational results show that the Joule loss of conductive rod on the primary side is 180W which is the main heat source of the transformer in rated operation. The dielectric loss of insulating layer and the eddy current loss of cores are 63.2W and 69.3W, respectively, which cannot be ignored. The hot-spot temperature of current transformer is near the core. And the maximum temperature rise is obtained as 31K relevant to the rated current of 4000A.
550kV油浸式电流互感器稳态损耗及温度分布的三维有限元分析
油浸纸绝缘高压电流互感器是变电站中最重要的电气设备之一,其温度分布和最大热点温度对其长期安全运行有着重要的影响。本文采用三维有限元法对550kV油浸纸绝缘逆变电流互感器的损耗和温度分布进行了研究和计算。根据额定工况设计了电磁-热场耦合模型。计算结果表明,一次侧导电棒的焦耳损耗为180W,是变压器额定运行时的主要热源。绝缘层的介电损耗和铁芯的涡流损耗分别为63.2W和69.3W,不容忽视。电流互感器的热点温度在铁心附近。在额定电流为4000A时,最大温升为31K。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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