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| The study on liquefaction characteristics of SF6 mixed gas |
| Li Hongpeng1, Feng Chiyao2, Li Baofeng1, Liao Zhao1, Liu Tao1 |
1. Nanning Power Supply Bureau,Guangxi Power Grid Co.,Ltd,Nanning 530000;
2. Tiansheng Bridge Bureau,China Southern Power Grid Ultra-High Voltage Transmission Company,Xingyi,Guizhou 562400 |
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Abstract The liquefaction temperature of SF6/N2, SF6/CO2 and SF6/CF4 mixed gases, as potential substitute gases for SF6, is an important basis for people to evaluate the feasibility of substitution and a parameter that must be considered in engineering practice. Especially in the cold region, SF6 insulation equipment often faces the problem of loss of original insulation characteristics due to gas liquefaction. Studies have found that by incorporating difficult liquefied gas composition, can improve the critical value of mixed gas liquefaction temperature, based on the calculation target of mixed gas Antoine vapor pressure equation, and combining the fundamental laws of vapor liquid equilibrium, calculated three goals mixed gas under the conditions of different mix proportion coefficient k, saturated vapor pressure value of the mixed gas and the mixed gas liquefaction temperature changes in the relationship; The relationship between the liquefaction temperature of the mixed gas and the mixing ratio coefficient k was calculated and analyzed when the saturated vapor pressure of the mixed gas was 0.3MPa, 0.5MPa and 0.7MPa respectively. By comparing the liquefaction temperature data of the three target mixed gases, the superiority order of the three target mixed gases in solving the liquefaction temperature problem is obtained.
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Received: 20 April 2020
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[1] 国家发改委,国家能源局.电力发展“十三五”规划(2016—2020年)[R].北京,2016-11-07.
[2] 颜湘莲,高克利,郑宇,等.SF6混合气体及替代气体研究进展[J].电网技术,2018,42(6):1837-1844.
[3] 相震.减排六氟化硫应对全球气候变化[J].中国环境管理,2010(2):23-27.
[4] Maiss M,Brenninkmeijer C M.Atmospheric SF6:trends,sources,and prospects[J].Environmental Science & Technology,1998,32(20):3077-3086.
[5] Matsui R,Cvitkovitch D.History of atmospheric SF6 from 1973 to 2008[J].Atmospheric Chemistry and Physics,2010,10(21):10305-10320.
[6] 贾申利,赵虎,李兴文,等.SF6替代气体灭弧性能的研究进展综述[J].高压电器,2011,47(11):87-91,97.
[7] 苏镇西,刘伟.关于SF6混合绝缘气体几个重要问题的探讨[J].高压电器,2016,52(12):232-236.
[8] 李正瀛,刘文浩.低温SF6和SF6/N2中正针-板的放电特性[J].高电压技术,1990(4):5-8.
[9] 周文俊,郑宇,杨帅,等.替代SF6的环保型绝缘气体研究进展与趋势[J].高压电器,2016,52(12):8-14.
[10] 吴经锋,张璐,仲鹏峰,等.SF6绝缘电流互感器SF6/N2混合气体替代技术研究[J].高压电器,2018,54(5):223-229.
[11] 侯孟希,于昊洋,金钊,等.CF4及其N2组合物微观放电参数计算与绝缘特性仿真研究[J].高压电器,2020,56(1):121-127.
[12] 李璐维,林莘,徐建源,等.SF6/N2和SF6/CF4混合气体放电参数计算分析[J].高压电器,2016,52(12):60-65.
[13] 李兴文,赵虎.SF6替代气体的研究进展综述[J].高电压技术,2016(6):1695-1701.
[14] 张晓星,田双双,肖淞,等.SF6替代气体研究现状综述[J].电工技术学报,2018,33(12):2883-2893.
[15] 徐国政,李庆民,张节容.SF6/CF4作为变压器的冷却和绝缘介质的研究[J].清华大学学报:自然科学版,1997(9):18-21.
[16] 潘瑞琼,王文勇.一种SF6气体饱和蒸汽压曲线的拟合公式及其应用[J].高压电器,2006,42(2):155-156.
[17] 田雨,张晗,赵虎.SF6/CF4混合气体的饱和蒸气压与绝缘特性计算[J].高电压技术,2017(3):765-771. |
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2020, Vol. 21 
