Simulation Research on the Influences of Temperature on Streamer Discharge of the Needle Plate Air Gap at Atmospheric Pressure

被引：0

作者：

Zhang Z. ^{[1
]}

Song H. ^{[1
]}

Dai J. ^{[2
]}

Luo L. ^{[1
]}

Sheng G. ^{[1
]}

Jiang X. ^{[1
]}

机构：

[1] Department of Electrical Engineering, Shanghai Jiao Tong University, Minhang District, Shanghai

[2] Shanghai Electric Power Company Shinan Power Supply Company of State Grid, Xuhui District, Shanghai

来源：

Zhongguo Dianji Gongcheng Xuebao/Proceedings of the Chinese Society of Electrical Engineering | 2021年 / 41卷 / 08期

基金：

中国国家自然科学基金;

关键词：

Fluid model; Key parameter; Micro-process; Simulation research; Streamer discharge; Temperature;

D O I：

10.13334/j.0258-8013.pcsee.200868

中图分类号：

学科分类号：

摘要：

Streamer discharge is a complex nonlinear dynamic process, which will be affected by many factors. However, at present, there are few studies on the mechanism of discharge micro-process affected by temperature. Therefore, in this paper, the simulation of the needle-plate air gap at atmospheric pressure was studied by using the fluid model simulation of the streamer discharge, and the key parameter system controlled by temperature in the streamer discharge fluid model and its calculation method were proposed. Comparing theoretical calculation and experimental results, the rationality of this simulation method was verified. The simulation study of the streamer discharge at different temperatures under atmospheric pressure shows that the increase in temperature leads to the acceleration of the movement of charged particles, which significantly increases the development rate of the streamer and the discharge current and current change rate. The increase in temperature has little effect on the ionization process, and will cause the electron concentration and electric field strength of the streamer head to decrease. The temperature control parameter system proposed in this paper comprehensively considers the influence of temperature on the process of ionization, adhesion and drift, and obtains the mechanism of temperature influencing the microscopic process of streamer discharge. © 2021 Chin. Soc. for Elec. Eng.

引用

页码：2929 / 2938

页数：9

共 38 条

[31]

TRAN T N, GOLOSNOY I O, LEWIN P L, Et al., Numerical modelling of negative discharges in air with experimental validation, Journal of Physics D: Applied Physics, 44, 1, (2011)

[32]

BOURDON A, PASKO V P, LIU N Y, Et al., Efficient models for photoionization produced by non-thermal gas discharges in air based on radiative transfer and the Helmholtz equations, Plasma Sources Science and Technology, 16, 3, pp. 656-678, (2007)

[33]

CAI Xinjing, WANG Xinxin, ZOU Xiaobing, Et al., Fast computation of photoionization in streamer discharges based on Helmholtz model, Proceedings of the CSEE, 35, 1, pp. 240-246, (2015)

[34]

ALEKSANDROV N L, BAZELYAN E M., Simulation of long-streamer propagation in air at atmospheric pressure, Journal of Physics D: Applied Physics, 29, 3, pp. 740-752, (1996)

[35]

WANG Liming, TANG Wenxi, YI Yong, Et al., Characteristics of positive streamer in low temperature environment based on three-electrode device, High Voltage Engineering, 46, 5, pp. 1586-1593, (2020)

[36]

ONO R, ODA T., Ozone production process in pulsed positive dielectric barrier discharge, Journal of Physics D: Applied Physics, 40, 1, pp. 176-182, (2007)

[37]

ALLEN N L, GHAFFAR A., The variation with temperature of positive streamer properties in air, Journal of Physics D: Applied Physics, 28, 2, pp. 338-343, (1995)

[38]

SATO N., Discharge current induced by the motion of charged particles, Journal of Physics D: Applied Physics, 13, 1, pp. L3-L6, (1980)

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