Local electron mean energy profile of positive primary streamer discharge with pin-plate electrodes in oxygen nitrogen mixtures 被引量：4

Local electron mean energy profile of positive primary streamer discharge with pin-plate electrodes in oxygen nitrogen mixtures

下载PDF

导出

摘要 Local electron mean energy （LEME） has a direct effect on the rates of collisional ionization of molecules and atoms by electrons. Electron-impact ionization plays an important role and is the main process for the production of charged particles in a primary streamer discharge. Detailed research on the LEME profile in a primary streamer discharge is extremely important for a comprehensive understanding of the local physical mechanism of a streamer. In this study, the LEME profile of the primary streamer discharge in oxygen-nitrogen mixtures with a pin-plate gap of 0.5 cm under an impulse voltage is investigated using a fluid model. The fluid model includes the electron mean energy density equation, as well as continuity equations for electrons and ions and Poisson＇s electric field equation. The study finds that, except in the initial stage of the primary streamer, the LEME in the primary streamer tip tends to increase as the oxygen-nitrogen mole ratio increases and the pressure decreases. When the primary streamer bridges the gap, the LEME in the primary streamer channel is smaller than the first ionization energies of oxygen and nitrogen. The LEME in the primary streamer channel then decreases as the oxygen-nitrogen mole ratio increases and the pressure increases. The LEME in the primary streamer tip is primarily dependent on the reduced electric field with mole ratios of oxygen-nitrogen given in the oxygen-nitrogen mixtures. Local electron mean energy （LEME） has a direct effect on the rates of collisional ionization of molecules and atoms by electrons. Electron-impact ionization plays an important role and is the main process for the production of charged particles in a primary streamer discharge. Detailed research on the LEME profile in a primary streamer discharge is extremely important for a comprehensive understanding of the local physical mechanism of a streamer. In this study, the LEME profile of the primary streamer discharge in oxygen-nitrogen mixtures with a pin-plate gap of 0.5 cm under an impulse voltage is investigated using a fluid model. The fluid model includes the electron mean energy density equation, as well as continuity equations for electrons and ions and Poisson＇s electric field equation. The study finds that, except in the initial stage of the primary streamer, the LEME in the primary streamer tip tends to increase as the oxygen-nitrogen mole ratio increases and the pressure decreases. When the primary streamer bridges the gap, the LEME in the primary streamer channel is smaller than the first ionization energies of oxygen and nitrogen. The LEME in the primary streamer channel then decreases as the oxygen-nitrogen mole ratio increases and the pressure increases. The LEME in the primary streamer tip is primarily dependent on the reduced electric field with mole ratios of oxygen-nitrogen given in the oxygen-nitrogen mixtures.

作者司马文霞彭庆军杨庆袁涛施健

机构地区 State Key Laboratory of Power Transmission Equipment & System Security and New Technology

出处《Chinese Physics B》 SCIE EI CAS CSCD 2013年第1期394-402,共9页 中国物理B（英文版）

基金 Project supported by the Funds for Innovative Research Groups of China (Grant No. 51021005) the National Basic Research Program of China (Grant No. 2009CB724504) the National Natural Science Foundation of China (Grant No. 50707036)

关键词 local electron mean energy profile primary streamer discharge electric field distribution gas discharge local electron mean energy profile, primary streamer discharge, electric field distribution, gas discharge

分类号 O561.5 [理学—原子与分子物理]

引文网络
相关文献

参考文献49

1Wang X, Yang Q, Yao C, Zhang X and Sun C 2011 Energies 4 2133.
2Quoc An H, Pham Huu T, Le Van T, Cormier J M and Khacef A 2010Catalysis Today.
3Ono R and Oda T 2007 J. Phys. D: Appl. Phys. 40 176.
4Rossi F, Kyli~in O, Rauscher H, Hasiwa M and Gilliland D 2009 New J. Phys. 11 115017.
5Kutasi K, Guerra V and S~i P A 2011 Plasma Sources Sci. Technol. 20 35006.
6Takashima K, Adamovich I V, Xiong Z, Kushner M J, Starikovskaia S, Czarnetzki U and Luggenh61scher D 2011 Phys. Plasmas 18 83505.
7Kong M G, Shang W L and Wang D Z 2007 Chin. Phys. 16 485.
8Lu B, Wang X X, Luo H Y and Liang Z 2009 Chin. Phys. B 18 646.
9Zhao H Y and Mu Z X 2008 Chin. Phys. B 17 1475.
10Ebert U and Sentman D D 2008 J. Phys. D: Appl. Phys. 41 230301.

同被引文献48

1何孟兵,贺臣,李劲.气体火花开关电极的烧蚀研究[J].高电压技术,2004,30(10):54-55. 被引量：22
2贾伟,邱爱慈,孙凤举,郭建民.百纳秒脉冲下水压对水开关击穿特性的影响[J].高电压技术,2006,32(1):50-51. 被引量：5
3王瑞兰.复杂电路本质安全特性的PSPICE仿真评价[J].潍坊学院学报,2005,5(6):47-49. 被引量：2
4刘振亚主编.特高压电网[M]. 中国经济出版社, 2005
5彭庆军.空气中流注放电等离子体化学模型研究及其影响因素分析[D].重庆大学2012
6M. Akel,S. Alsheikh Salo,C. S. Wong.Electron Temperature Measurement of Argon Focussed Plasma Based on Non-local Thermodynamic Equilibrium Model[J]. Journal of Fusion Energy . 2013 (3)
7Fada Feng,Lingling Ye,Ji Liu,Keping Yan.Non-thermal plasma generation by using back corona discharge on catalyst[J]. Journal of Electrostatics . 2012
8T N Tran,I O Golosnoy,P L Lewin,G E Georghiou.Numerical modelling of negative discharges in air with experimental validation[J]. Journal of Physics D: Applied Physics . 2011 (1)
9Dion S Antao,David A Staack,Alexander Fridman,Bakhtier Farouk.Atmospheric pressure dc corona discharges: operating regimes and potential applications[J]. Plasma Sources Science and Technology . 2009 (3)
10Chao Li,Ute Ebert,Willem Hundsdorfer.Spatially hybrid computations for streamer discharges with generic features of pulled fronts: I. Planar fronts[J]. Journal of Computational Physics . 2009 (1)

引证文献4

1赵永秀,殷晓虎.爆炸性环境低压感性电路开路电弧放电研究综述[J].煤矿安全,2016,47(6):63-66. 被引量：1
2廖瑞金,伍飞飞,刘康淋,汪可,高竣,左志平.棒-板电极直流负电晕放电脉冲过程中的电子特性研究[J].电工技术学报,2015,30(10):319-329. 被引量：26
3詹艳艳,刘晓明,吴楠.三电极开关系统自击穿特性微观分析[J].沈阳理工大学学报,2018,37(1):11-16.
4牛海清,徐乐平,李小潇,艾嘉伟,罗新,庄小亮.SF_(6)气体正极性电晕放电特性仿真研究[J].高电压技术,2021,47(11):4063-4071. 被引量：9

二级引证文献36

1王成江,涂鸣麟,方洋洋,沈书林,李亚莎.初始种子电子团对短空气间隙流注放电行为的影响[J].绝缘材料,2019,52(1):57-62. 被引量：3
2汪沨,李敏,李锰,皮建民,许松枝,黄墀志.基于ETG-通量校正传输法的短间隙SF_6/N_2混合气体流注放电数值仿真[J].电工技术学报,2016,31(6):234-241. 被引量：12
3何旺龄,何俊佳,张锦,万保权.同轴电极的负电晕特里切尔脉冲特性分析[J].电工技术学报,2016,31(11):211-218. 被引量：5
4黄克捷,张小青,肖翔.负极性衰减振荡冲击电晕的数学物理模型[J].电工技术学报,2016,31(13):200-208. 被引量：1
5张小芳,白敏冬,张晓晔,田一平,俞哲,张芝涛.大气压强电场放电在外来海洋生物应急防控处理装置中的应用实验研究[J].高压电器,2017,53(4):45-52. 被引量：1
6李庆,刘晓娃,剧晓晨,殷宇朝.针–板电极负电晕放电下离子分布状态的影响因素[J].高电压技术,2017,43(5):1700-1706. 被引量：9
7李杰,关银霞,姜楠,姚晓妹,王世强,刘全桢.负直流电晕诱发低压电极多孔绝缘层微放电的参数优化[J].高电压技术,2017,43(6):1759-1765. 被引量：6
8田一平,周新颖,袁晓莉,俞哲,张芝涛.强电离放电等离子体在应急净化饮用水中的应用[J].高电压技术,2017,43(6):1792-1799. 被引量：24
9邱志斌,阮江军,黄道春,舒胜文.基于支持向量机的棒-板空气间隙击穿电压预测方法及其应用[J].电工技术学报,2017,32(19):220-228. 被引量：15
10邱志斌,阮江军,唐烈峥,徐闻婕,黄从鹏.空气间隙的储能特征与放电电压预测[J].电工技术学报,2018,33(1):185-194. 被引量：8

1ZHUANG Chijie ZENG Rong.Research and Development on Short Gap Streamer Discharge Simulation Methods[J].中国电机工程学报,2012,32(22). 被引量：17
2汪家铭.流光放电氨法烟气脱硫技术及其应用[J].甘肃石油和化工,2012,26(4):10-12.
3汪家铭.流光放电氨法烟气脱硫技术及其应用[J].精细化工原料及中间体,2012(8):24-26.
4张芝涛,白敏冬,白希尧.常温常压流光放电合成NH_3[J].合成化学,1998,6(4):418-421. 被引量：1
5周杰,朱贤伟,马在斌,袁灿伦,刘峰.AutoCAD11.0高级造型扩展(AME)在长轴类锻件锻模CAD中的应用[J].锻压技术,1993,18(6):49-52.
6汪家铭.流光放电氨法烟气脱硫脱硝技术实现工业化应用[J].硫酸工业,2011(3):16-16. 被引量：2
7李玲玉.电焊机产品档案分类编号初探[J].电焊机,1990,20(1):19-22.
8Modeling of Electronic Energy Loss Induced Modification of Collisional Defects in Pure Metal[J].IMP & HIRFL Annual Report,1998(0):132-132.
9张树栋.苯乙烯系热塑性弹性体发展概况及研究开发动向[J].燕山油化,1989(3):233-239.
10徐文骥,王涛,方建成,刘非,周锦进.金属板件等离子体弧柔性成形技术基础研究[J].大连理工大学学报,2004,44(6):810-814. 被引量：10

Chinese Physics B

2013年第1期

浏览历史

内容加载中请稍等...

Local electron mean energy profile of positive primary streamer discharge with pin-plate electrodes in oxygen nitrogen mixtures 被引量：4

参考文献49

同被引文献48

引证文献4

二级引证文献36

相关作者

相关机构

相关主题

浏览历史