三种绝缘气体下开关设备的温度场及流场对比与分析

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摘要基于热传导微分方程、流体运动控制方程及辐射换热方程,建立了开关设备的传导、对流和辐射换热相互耦合的数学模型,并采用壁函数法处理对流换热边界条件。利用棱边单元法计算了考虑集肤效应、邻近效应及涡流效应下载流导体和外壳的焦耳热损耗。以某型号开关设备为对象,采用有限容积法和六面体网格,分别计算分析SF₆、N₂、空气中开关设备的三维温度场与气流场,从温升角度探讨空气、N₂作为SF₆替代气体的可行性。计算结果表明,三种气体中温度分布基本相同,温升大小表现为SF₆气体内的最高,N₂内与空气内的差别不大;三种气体中的气流速度大小顺序也表现为相似的规律。从温升角度考虑,在满足绝缘条件的前提下,空气、氮气具有替代SF₆的可行性。

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	张俊民
	高荟凯
	冯昊

关键词 ：温度场, 气流场, 开关设备, SF6, N2, 空气

Abstract：Based on the heat conduction equation, fluid flow governing equation and radiation heat transfer equation, a multi-physics coupled mathematical model is established, in which the convec- tion heat transfer problem between solid and fluid is solved by wall function for simulating the temperature in the switchgear. The joule heat losses of current-carrying conductors and shell are calculated respectively including skin, proximity and eddy current effects with the use of 3D edge element method. The three dimensional thermal and fluid field in a type of switchgear filled respec- tively with SF₆, N₂, and air are calculated numerically by the finite volume method and the hexahedral grid and analyzed to discuss the feasibility of using air or N₂ as the substitution of SF₆. The results show that the temperature field and fluid field in three gases are similar in the switchgear. The temperature rise of current-carrying loop is the highest in SF₆ and is approximately equal in the N₂ and air. The flow velocity in SF₆ is the highest and is the lowest in the air. So the conclusion could be made that under the qualified withstand voltage air or N₂could replace SF₆as the insulating gas of switchgear from the perspective of temperature rise.

Key words： Temperature rise fluid field switchgear SF6 N2 air

收稿日期: 2013-11-10 出版日期: 2015-04-10

PACS:

TM591

基金资助:国家自然科学基金资助项目（51177005,51477004）

作者简介: 张俊民男,1962年生,博士,副教授,研究方向为断路器及其仿真、故障检测与诊断。高荟凯女,1990年生,硕士研究生,研究方向为断路器及仿真。

引用本文:

张俊民,高荟凯,冯昊. 三种绝缘气体下开关设备的温度场及流场对比与分析[J]. 电工技术学报, 2015, 30(6): 155-161. Zhang Junmin,Gao Huikai,Feng Hao. Analysis of Thermal and Fluid Field of Switchgear in Three Insulating Gases. Transactions of China Electrotechnical Society, 2015, 30(6): 155-161.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2015/V30/I6/155

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