高气压下三维旋转滑动弧放电光谱特性分析

doi:10.3964/j.issn.1000-0593(2024)06-1571-07

摘要
参考文献
相关文章 (15)

全文: PDF (4808 KB)
输出: BibTeX | EndNote (RIS)

摘要：为探究气体压力对滑动弧放电稳定性的影响规律，在高气压放电实验平台上，开展了滑动弧放电光谱特性研究。利用发射光谱法对滑动弧放电过程中的激发态物质进行诊断，并对不同气体压力条件下滑动弧放电的电子密度、振动温度、转动温度进行了计算。在滑动弧放电发射光谱中观测到氮气第二正带系N₂(C³Π_u→B³Π_g)和氮气第一负带系N⁺₂(B²Σ⁺_u→X²Σ⁺_g)的发射谱线，随着气体压力升高，氮气第二正带系谱线发射强度增强，氮气第一负带系的发射强度变化幅度较小。当气体压力超过0.26 MPa之后，在滑动弧放电发射光谱中发现了氮气Gaydon's Green带系507.4 nm的发射谱线，其发射强度为3 508.49 arb，随气体压力升高其谱线发射强度无明显变化。利用Stark展宽法对滑动弧放电过程中的电子密度进行了计算，得到电子密度在10²³量级，并且随着气体压力的增加，滑动弧放电的电子密度呈线性增加。针对氮气分子第二正带系的5条谱线，采用玻尔兹曼图解法对滑动弧放电的振动温度进行计算，振动温度随气体压力的变化并非单调变化，在0.3 MPa之前振动温度变化幅度较小，气体压力超过0.3 MPa之后振动温度迅速增加。对氮气分子第一负带系390～391.6 nm处的发射谱线进行拟合计算滑动弧放电的转动温度，结果表明在0.24 MPa之前转动温度随气体压力升高变化幅度较大，气体压力超过0.24 MPa之后转动温度增长幅度变小。

关键词：滑动弧等离子体；高气压放电；电子密度；振动温度；转动温度

Abstract：To investigate the influence of gas pressure on the process of gliding arc discharge, the spectral characteristics of gliding arc discharge were studied on a high-pressure discharge experimental platform. The excited state substances in gliding arc discharge are diagnosed by emission spectroscopy,and the electron density, vibration temperature and rotation temperature of gliding arc discharge under different gas pressures are calculated. The emission lines of the second positive system of nitrogen N₂(C³Π_u→B³Π_g) and the first negative system of nitrogen N⁺₂(B²Σ⁺_u→X²Σ⁺_g) are observed in the emission spectra of the gliding arc discharge. With the increase of gas pressure, the emission intensity of the emission line of the second positive system of nitrogen increases, whereas the emission intensity of the first negative system of nitrogen changes slightly. The Stark broadening method calculates the electron density in gliding arc discharge. It is found that the electron density is 10²³ orders of magnitude, and the electron density increases linearly with the increase of gas pressure. The vibration temperature of sliding arc discharge is calculated using the Boltzmann diagram method for the five spectral lines of the second positive system of nitrogen molecules. The change of vibration temperature with gas pressure is not monotone. The range of vibration temperature changes is small before 0.3 MPa and increases rapidly after the gas pressure exceeds 0.3 MPa. The rotational temperature of the discharge from the gliding arc was calculated by fitting the emission lines at 390~391.6 nm in the first negative nitrogen molecules system. The rotational temperature changed significantly with the increase of gas pressure before 0.24 MPa, and the addition of rotational temperature decreased when the gas pressure exceeded 0.24 MPa.

Key words：Gliding arc plasma; High air pressure discharge; Electron density; Vibration temperature; Rotation temperature

收稿日期: 2022-09-08 修订日期: 2023-10-24

中图分类号:

O433.4

基金资助: 国家自然科学基金项目(52276142，51776223)资助

通讯作者: 于锦禄 E-mail: smartaeroengine@163.com

作者简介: 张磊，1996年生，中国人民解放军空军工程大学航空工程学院博士研究生 e-mail: zhanglei1_dz@163.com

引用本文:

张磊，张登成，于锦禄，赵兵兵，徐哲霖，程伟达. 高气压下三维旋转滑动弧放电光谱特性分析[J]. 光谱学与光谱分析, 2024, 44(06): 1571-1577.
ZHANG Lei, ZHANG Deng-cheng, YU Jin-lu, ZHAO Bing-bing, XU Zhe-lin, CHENG Wei-da. Study of the Spectral Characteristics of 3D Rotating Gliding Arc Under High Pressure. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1571-1577.

链接本文:

https://www.gpxygpfx.com/CN/10.3964/j.issn.1000-0593(2024)06-1571-07 或 https://www.gpxygpfx.com/CN/Y2024/V44/I06/1571

[1] ZHANG Lei, YU Jin-lu, ZHAO Bing-bing, et al（张磊，于锦禄，赵兵兵，等）. Acta Physica Sinica（物理学报）, 2022, 71(7): 075204.
[2] YU Jin-lu, ZHAO Bing-bing, GUO Hao, et al（于锦禄，赵兵兵，郭昊，等）. Aeroengine（航空发动机）, 2022, 48(3): 52.
[3] ZHANG Lei, YU Jin-lu, CHEN Yi, et al（张磊，于锦禄，陈一，等）. Acta Aeronautica et Astronautica Sinica（航空学报）, 2021, 42(3): 124308.
[4] Zhang Lei, Zhang Dengcheng, Yu Jinlu, et al. Plasma Science and Technology, 2023, 25(3): 035502.
[5] Jennifer Martin-del-Campo, Marianna Uceda, Sylvain Coulombe, et al. Journal of CO₂ Utilization, 2021, 46: 101474.
[6] Kong Xiangzhi, Wu Angjian, Fu Siming, et al. Fuel, 2021, 298: 120745.
[7] HE Li-ming, YU Jin-lu, ZENG Hao（何立明, 于锦禄, 曾昊）. The Technology of Plasma Ignition and Assisted Combustion（等离子体点火与助燃技术）. Beijing: Aviation Industry Press（北京: 航空工业出版社）, 2019.
[8] Deng Jun, Cui Gang, Lu Yongji, et al. Vacuum, 2023, 207: 111621.
[9] LEI Jian-ping, HE Li-ming, CHEN Yi, et al（雷建平，何立明，陈一，等）. Acta Physica Sinica（物理学报）, 2020, 69(19): 195203.
[10] Yusuke Kikuchi, Tsubase Nakagawa. IEEE Transactions on Plasma Science, 2021, 49(1): 4.
[11] LIU Zhi-jie, CHEN Min, LIU Ding-xin（刘志杰，陈旻，刘定新）. High Voltage Engineering（高电压技术）, 2022, 48(10): 4196.
[12] FENG Bo-wen, WANG Ruo-yu, MA Yu-peng-xue, et al（冯博文，王若愚，马雨彭雪，等）. Acta Physica Sinica（物理学报）, 2021, 70(9): 095201.
[13] ZENG Xin, ZHANG Shuai, BAI Han, et al（曾鑫，张帅，白晗，等）. Proceedings of the Chinese Society for Electrical Engineering（中国电机工程学报）, 2023, doi:10.13334/j.0258-8013.pcsee.230256.
[14] Ananthanarasimhan J, Rao Lakshminarayana. Journal of Physics D: Applied Physics, 2022, 55: 245202.
[15] TIAN Yu, YU Jin-lu, JIANG Yong-jian, et al（田裕，于锦禄，蒋永健，等）. Journal of Combustion Science and Technology（燃烧科学与技术）, 2021, 27(5): 562.
[16] David Staack, Bakhtier Farouk, Alexander Gutsol, et al. Plasma Sources Science and Technology, 2005, 14(4): 700.
[17] SHEN Li-hua, YU Chun-xia, YAN Bei, et al（申丽华, 于春侠, 闫蓓，等）. Spectroscopy and Spectral Analysis（光谱学与光谱分析）, 2015, 35(3): 791.