触头分离瞬间真空金属蒸气电弧形成过程的仿真

doi:10.19595/j.cnki.1000-6753.tces.190708

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摘要维持真空金属蒸气电弧所需的导电介质由触头提供,故真空间隙中金属蒸气分布情况影响电弧等离子体形成全过程。统一真空开关触头分离瞬间导电触点热过程和液桥断裂后间隙击穿过程,以热传导方程为基础,考虑触点相变过程,获得间隙极小空间内金属蒸气非均匀的分布情况;建立真实金属蒸气分布情况下真空微观粒子动力学模型,求解电子、重粒子输运方程,揭示非均匀分布金属蒸气影响下电弧形成过程。仿真结果表明,分离瞬间导电触点相变产生金属蒸气密度由中心沿径向呈迅速衰减的非均匀分布;在非均布金属蒸气情况下,电弧形成过程经历电子崩发展、近极区形成和初始导电通道三个阶段;真空间隙导电通道形成取决于金属蒸气高密度区所在位置,是空间电荷密集区产生的源泉。

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	付思
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关键词 ：真空, 分离瞬间, 金属蒸气, 空间电荷, 导电通道

Abstract：The metal contacts provide the conductive medium needed to maintain the vacuum metal vapor. Therefore, the distribution of metal vapor affects the whole process of arc plasma formation. The conductive contact thermal process and gap breakdown process after the rupture of the molten metal bridge at the initial moment of contact parting are unified in the simulation. On the base of heat conduction equation and considering the phase transition process of the contact, the non-uniform distribution of metal vapor in the minimum space is obtained. Vacuum microscopic particle dynamics model is established under the influence of non-uniform distribution of metal vapor. The transport equations of electron and heavy particle are solved to reveal the arc formation process. Simulation results indicate that the metal vapor density produced by the phase transition of conductive contact is non-uniform distribution in the space, which is rapidly attenuated along the radial direction from the center. On account of the non-uniform distribution of metal vapor, the arc formation process goes through three stages: electron avalanche development, polar-region formation and initial conduction channel. The formation of vacuum gap conductive channel depends on the location of metal vapor density region.

Key words： Vacuum parting moment metal vapor space charge conductive channel

收稿日期: 2019-06-14

PACS:

TM561

基金资助:国家自然科学基金（51977132）、辽宁省自然科学基金（20180550280）和辽宁省教育厅科学研究项目（LQGD2019010）资助

通讯作者: 曹云东男,1963年生,教授,博士生导师,研究方向为现代电器理论及应用。E-mail：Caoyundong@sut.edu.cn

作者简介: 付思女,1985年生,硕士,讲师, 研究方向为开关电器电弧开断机理与技术。E-mail：fusiok1985@163.com

引用本文:

付思, 曹云东, 李静, 刘树鑫, 韩颖. 触头分离瞬间真空金属蒸气电弧形成过程的仿真[J]. 电工技术学报, 2020, 35(13): 2922-2931. Fu Si, Cao Yundong, Li Jing, Liu Shuxin, Han Ying. Simulation Researches on Vacuum Metal Vapor Arc Formation at the Initial Moment of Contact Parting. Transactions of China Electrotechnical Society, 2020, 35(13): 2922-2931.

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