[1]周文俊,鄭 宇,楊 帥,等.替代SF6的環保型絕緣氣體研究進展與趨勢[J].高壓電器,2016,52(12):8-14.[doi:10.13296/j.1001-1609.hva.2016.12.002]
 ZHOU Wenjun,ZHENG Yu,YANG Shuai,et al.Research Progress and Trend of SF6 Alternative with Environment Friendly Insulation Gas[J].High Voltage Apparatus,2016,52(12):8-14.[doi:10.13296/j.1001-1609.hva.2016.12.002]



綜 述


Research Progress and Trend of SF6 Alternative with Environment Friendly Insulation Gas
周文俊1 鄭 宇1 楊 帥1 覃兆宇12 王寶山3
1. 武漢大學電氣工程學院, 武漢 430072; 2. 國網電力科學研究院武漢南瑞有限責任公司, 武漢 430074; 3. 武漢大學化學與分子科學學院, 武漢 430072
ZHOU Wenjun1 ZHENG Yu1 YANG Shuai1 QIN Zhaoyu12 WANG Baoshan3
1. School of Electrical Engineering, Wuhan University, Wuhan 430072, China; 2. Wuhan NARI Limited Company of State Grid Electric Power Research Institute, Wuhan 430074, China; 3. College of Chemistry and Molecular Sciences, Wuhan University, Wuhan 430072, China
SF6 替代氣體 環保絕緣 研究趨勢 量子化學
SF6 alternative gases environment friendly insulation research trend quantum chemistry
Progress on the environment friendly insulation gases for replacement of SF6 has been reviewed including both unity gases and gaseous mixtures. Criteria for the physical chemical properties, environmental effect, and dielectric features of the alternative gases are proposed. In the consideration of ozone depletion, no chlorine or bromine should be involved in the molecular structures. The perspective of the SF6 replacement is presented as well. It is suggested that the theoretical study of the novel alternative gases using quantum chemistry methods should be taken into account in a long-term research plan. Meanwhile, rational design on the basis of the available insulation gas mixtures appears to be a promising approach for SF6 replacement.


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收稿日期:2016- 06- 22; 修回日期:2016 - 07 - 27 基金項目:國家電網公司科技項目(2014-1192);國家自然科學基金資助項目(51277136,21273166)。 Project Supported by Science and Technology Project of SGCC(2014-1192),National Natural Science Foundation of China(51277136,21273166).周文俊(1959—),男,博士,教授(二級),博導,IEEE高級會員,研究方向爲高電壓絕緣與測試技術、防雷接地技術。
更新日期/Last Update: 1900-01-01