不同絕緣介質下中壓GIL溫升特性研究
李松偉����,陳曉鳴�����,陳浩杰�,葛時帆
(江蘇安靠智電股份有限公司,江蘇 溧陽 213300)
摘 要:中壓金屬封閉氣體絕緣輸電線路(GIL)設計時需綜合考慮輸送容量�、結構尺寸、制造成本等因素�����,并重點關注低氣壓大容量 GIL 散熱問題����,而絕緣介質是中壓 GIL 的關鍵組成部分,直接影響 GIL 的絕緣性能及散熱性能��。以中壓 GIL 通流 2500 A 為例,對 GIL 基本結構及傳熱機理進行了闡述����,針對六氧化硫(SF6)、氮氣(N2) 等絕緣介質���,利用 COMSOL 軟件仿真計算相應壓力下的溫升數(shù)值�����,探究不同絕緣介質下 GIL 的溫升變化規(guī)律,并通過試驗進行驗證�����。對比相同工況下的試驗數(shù)據(jù)與仿真數(shù)據(jù)�����,發(fā)現(xiàn)兩者變化趨勢相似���,但具體計算結果存在差異�����,主要由于仿真計算時外殼對熱換流系數(shù)����、金屬表面輻射率等參數(shù)無法準確進行設置,以及采用了近似化簡計算導致結果存在差異����。
關鍵詞: 中壓輸電設備;金屬封閉氣體絕緣輸電線路�;絕緣介質;溫升特性
中圖分類號:TM751 文獻標識碼:A 文章編號:2097-6623(2026)01-0072-05
Research on Temperature Rise Characteristics of Medium-Voltage
GIL Under Different Insulating Media
LI Song-wei, CHEN Xiao-ming, CHEN Hao-jie, GE Shi-fan
(Jiangsu Ankura Smart Electric Co., Ltd., Liyang 213300, China)
Abstract: In the design of medium-voltage metal-enclosed gas-insulated transmission lines (GIL), factors such as transmission capacity,structural dimensions, and manufacturing costs need to be comprehensively considered, with a focus on the heat dissipation issue of low-pressure and large-capacity GIL. The insulating medium is a key component of medium-voltage GIL, directly affecting its insulation performance and heat dissipation performance. Taking a medium-voltage GIL with a current-carrying capacity of 2 500 A as an example, this paper elaborates on the basic structure and heat transfer mechanism of GIL. For insulating media such as SF? and N?, the COMSOL software is used to simulate and calculate the temperature rise values under corresponding pressures, explore the temperature rise variation laws of GIL under different insulating media, and verify the results through experiments. By comparing the experimental and simulation data under the same working conditions, it is found that the variation trends are similar, but there are differences in specific calculation results. These differences are mainly due to the inability to accurately set parameters such as the heat transfer coefficient of the shell and the emissivity of the metal surface during simulation calculations, as well as the use of approximate simplified calculations.
Key words: medium-voltage transmission equipment; metal-enclosed gas-insulated transmission line (GIL); insulating medium; temperature rise characteristic
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