0.5%掺氨氩气脉冲介质阻挡放电特性的实验与仿真研究

doi:10.19595/j.cnki.1000-6753.tces.250147

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5213 KB) HTML
输出: BibTeX | EndNote (RIS)

摘要等离子体具有工作温度低、电子能量范围分布宽等优势,已成为极具前景的氨气制氢技术,有效地调控等离子体对氨气高效制氢具有重要意义。该文采用方波脉冲电压驱动Ar-NH₃介质阻挡放电（DBD）,结合一维流体数值仿真研究了放电特性及产物分布。结果表明,一个放电周期内,在脉冲电压上升沿阶段,外施电压增加导致气体击穿,出现正电流脉冲;在脉冲电压下降沿阶段,自建电场主导产生负电流脉冲。放电演化过程呈现典型的辉光放电特性,电子密度、约化电场强度均在放电熄灭后的高电平起始阶段达到峰值,出现在阴极鞘层区附近。分析放电产物发现,主要粒子包括Ar*和$\text{NH}_{3}^{+}$以及中性粒子NH和NH₂,目标产物H₂主要产生在电压高电平阶段的阴极位降区附近,研究结果可为优化制氢效果和确定最优参数提供指导。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	赵妮
	田浩
	王婧
	付强
	常正实

关键词 ：脉冲介质阻挡放电, 氨气制氢, 放电特性, 放电产物

Abstract：Plasma technology, characterized by low operational temperatures and broad electron energy distribution, has emerged as a promising approach for hydrogen production through ammonia decomposition. Pulse voltage has the characteristics of steep rising/falling edges and narrow pulse width. The fast voltage change rate enhances the excitation and ionization processes and has significant superiority in improving discharge uniformity and increasing particle abundance. Precise regulation of pulsed voltage-driven plasma parameters is crucial for optimizing hydrogen generation efficiency.
In this paper, under normal temperature and pressure, square wave pulse voltage is used to drive the Ar-NH₃ dielectric barrier discharge (DBD) structure to generate uniform Ar-NH₃ discharge plasma. The barrier dielectric is quartz with ε_r=3.7. The diameters of the barrier dielectric are both 40 mm, the thickness is d₁=d₂=1 mm, and the air gap distance is d_g=4 mm. The proportion of NH₃ in the mixed gas is 0.5%, and the total pressure is maintained at 100 kPa. The discharge drive voltage is a pulse waveform (t_r=t_f=100 ns, t_w=1 000 ns, f =20 kHz). The voltage and current signals, discharge evolution behavior and emission spectra of Ar-NH₃ discharge plasma were tested and analyzed. To further explain the experimental results, a one-dimensional fluid simulation model was established, whose parameters were kept consistent with the experimental data. The discharge characteristics and product distribution characteristics of the Ar-NH₃ DBD plasma are systematically analyzed.
The results reveal that the development process of discharge mainly includes three stages: rising edge-flat top period-falling edge. During the rising stage of the applied voltage, the air gap voltage u_g increases rapidly with the increase of the applied voltage. The negative particles (mainly electrons) in the gas gap move towards the high-voltage side under the action of the electric field, and the positive ions produced by the reaction move towards the ground side. When u_g reaches the gas breakdown threshold, discharge occurs, and the positive current pulse reaches its peak. The applied electric field dominates the ionization process in the gap at this time. As the discharge proceeds, negative charges (mainly ions) and positive ions continuously accumulate on the surface of the dielectrics and form stable surface charges. The self-built electric field significantly increases, resulting in a rapid decrease in the net electric field in the gap. The voltage amplitude during the pulse flat-top period remains unchanged, equivalent to a DC voltage. Due to the capacitive property of the DBD device, the gap voltage drops to zero, and the discharge remains in an extinguished state all the time. When the applied voltage pulse enters the descending stage, the applied electric field rapidly decreases. Electrons rapidly migrate to the surface of the dielectric on the grounding side and neutralize the originally accumulated positive surface charges. It rapidly weakens the positive surface charge density σ₂, showing a steeper curve descending edge. Meanwhile, positive ions in the gap slowly migrate to the surface of the dielectric on the high-voltage side and neutralize the accumulated negative surface charges. This causes the negative surface charge density σ₁ to decrease slowly, showing more gentle curve descending edge. It results in the net electric field in the gap being mainly self-built and significantly enhanced, leading to the occurrence of negative discharge and the appearance of a negative discharge peak. The discharge exhibits characteristic of glow discharge behavior with peak electron density and reduced electric field occurring near the cathode sheath region during the initial high-voltage plateau. Spectral analysis identifies dominant species including Ar* excimers, $\text{NH}_{3}^{\text{+}}$ ions, and neutral NH and NH₂ radicals.
Reaction pathway analysis through time-integrated rate coefficients quantifies hydrogen production routes. Primary H₂ generation pathways are R7 ($\text{NH}_{3}^{\text{+}}$+e→NH+H₂), R8 (NH₂+NH₂→N₂H₂+H₂) and R9 (NH+H→N+H₂). Mechanistic insights demonstrate that electron density accumulation during voltage rising phases originates from initial electron energy accumulation, collisional excitation via metastable Ar atoms and secondary electron emission enhanced by cathode sheath acceleration. These cumulative effects promote intensive excitation/ ionization processes, generating substantial NH, NH₂ and H intermediates. Subsequent accumulation of these species during voltage plateau facilitates sustained R8 and R9 reactions, resulting in predominant H₂ production near the cathode sheath region. The research results provide guidance for optimizing the hydrogen production effect and determining the optimal parameters.

Key words： Pulse dielectric barrier discharge hydrogen generation from ammonia discharge characteristics discharge products

收稿日期: 2025-01-22

PACS:

TM835

基金资助:国家自然科学基金资助项目（52307187）

通讯作者: 赵妮女,1983年生,博士,讲师,硕士生导师,研究方向为复合电介质特性和等离子体催化制氢。E-mail: zhaoni@xaut.edu.cn

作者简介: 田浩男,2000年生,硕士研究生,研究方向为等离子体氨气制氢。E-mail: 2861273873@qq.com

引用本文:

赵妮, 田浩, 王婧, 付强, 常正实. 0.5%掺氨氩气脉冲介质阻挡放电特性的实验与仿真研究[J]. 电工技术学报, 2025, 40(21): 6819-6831. Zhao Ni, Tian Hao, Wang Jing, Fu Qiang, Chang Zhengshi. Experimental and Simulation Research of Nanosecond Pulse Dielectric Barrier Discharge Characteristics Doped 0.5% NH₃ in Argon. Transactions of China Electrotechnical Society, 2025, 40(21): 6819-6831.

链接本文:

https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.250147 https://dgjsxb.ces-transaction.com/CN/Y2025/V40/I21/6819

[1] Larouci B, Bendella S, Belasri A.Numerical investigation of Ar-NH₃ mixture in homogenous DBDs[J]. Plasma Science and Technology, 2018, 20(3): 035403.
[2] 梅丹华, 方志, 邵涛. 大气压低温等离子体特性与应用研究现状[J]. 中国电机工程学报, 2020, 40(4): 1339-1358, 1425.
Mei Danhua, Fang Zhi, Shao Tao.Recent progress on characteristics and applications of atmospheric pressure low temperature plasmas[J]. Proceedings of the CSEE, 2020, 40(4): 1339-1358, 1425.
[3] Liu Jin, Zhu Xinbo, Hu Xueli, et al.Plasma-assisted ammonia synthesis in a packed-bed dielectric barrier discharge reactor: effect of argon addition[J]. Vacuum, 2022, 197: 110786.
[4] 陈星宇, 陆晨, 熊紫兰. 表面微放电等离子体特性参数计算及介质片性质的影响[J]. 电工技术学报, 2024, 39(22): 7256-7265.
Chen Xingyu, Lu Chen, Xiong Zilan.Calculation of the characteristic parameters of surface micro- discharge and the effect of dielectric sheet properties[J]. Transactions of China Electrotechnical Society, 2024, 39(22): 7256-7265.
[5] 刘定新, 张基珅, 王子丰, 等. 等离子体活化介质技术及其生物医学应用[J]. 电工技术学报, 2024, 39(12): 3855-3868.
Liu Dingxin, Zhang Jishen, Wang Zifeng, et al.Plasma-activated media technology and its biomedical applications[J]. Transactions of China Electrotech- nical Society, 2024, 39(12): 3855-3868.
[6] 张国治, 王文祥, 张磊, 等. 介质阻挡放电等离子体处理变压器废弃绝缘油的实验探究[J]. 电工技术学报, 2025, 40(1): 325-334.
Zhang Guozhi, Wang Wenxiang, Zhang Lei, et al.Experimental exploration of dielectric barrier discharge plasma treatment of transformer waste insulating oil[J]. Transactions of China Electrotechnical Society, 2025, 40(1): 325-334.
[7] 董冰冰, 孟岩, 郭志远. 气体间隙开关触发失效分析及寿命提升方法[J]. 电工技术学报, 2025, 40(1): 264-272.
Dong Bingbing, Meng Yan, Guo Zhiyuan.Trigger failure analysis and life extension methods of gas gap switch[J]. Transactions of China Electrotechnical Society, 2025, 40(1): 264-272.
[8] 陈介夫, 孙昊, 李刚, 等. 基于激光诱导等离子体的Mach-Zehnder干涉法测量气体介质恢复特性的研究[J]. 高压电器, 2024, 60(12): 199-205.
Chen Jiefu, Sun Hao, Li Gang, et al.Research on gaseous medium recovery characteristics measure- ment by Mach-Zehnder interferometry based on laser- induced plasma[J]. High Voltage Apparatus, 2024, 60(12): 199-205.
[9] Jiang Hui, Shao Tao, Zhang Cheng, et al.Comparison of AC and nanosecond-pulsed DBDs in atmospheric air[J]. IEEE Transactions on Plasma Science, 2011, 39(11): 2076-2077.
[10] 李艳琴, 张秀玲. Ar/NH₃混合气体放电等离子体研究进展[J]. 真空科学与技术学报, 2017, 37(11): 1091-1101.
Li Yanqin, Zhang Xiuling.Progress of Ar/NH₃ mixture discharge plasma[J]. Chinese Journal of Vacuum Science and Technology, 2017, 37(11): 1091-1101.
[11] Zhang Li, Yang Dezheng, Wang Wenchun, et al.Needle-array to plate DBD plasma using sine AC and nanosecond pulse excitations for purpose of improving indoor air quality[J]. Scientific Reports, 2016, 6: 25242.
[12] 刘洋, 章子潇, 赵贤根, 等. 进气流量对滑动电弧放电分解CO₂的瞬态电-光-热特性和转化性能的影响[J]. 电工技术学报, 2024, 39(23): 7616-7627.
Liu Yang, Zhang Zixiao, Zhao Xiangen, et al.The effect of inlet flow rate on the transient electrical- optical thermal characteristics and conversion perfor- mance of CO₂ decomposition in gliding arc dis- charges[J]. Transactions of China Electrotechnical Society, 2024, 39(23): 7616-7627.
[13] 张增辉, 张冠军, 邵先军, 等. 大气压Ar/NH₃介质阻挡辉光放电的仿真研究[J]. 物理学报, 2012, 61(24): 400-410.
Zhang Zenghui, Zhang Guanjun, Shao Xianjun, et al.Modelling study of dielectric barrier glow discharge in Ar/NH₃ mixture at atmospheric pressure[J]. Acta Physica Sinica, 2012, 61(24): 400-410.
[14] El-Shafie M, Kambara S, Hayakawa Y.Energy and exergy analysis of hydrogen production from ammonia decomposition systems using non-thermal plasma[J]. International Journal of Hydrogen Energy, 2021, 46(57): 29361-29375.
[15] Arakoni R A, Bhoj A N, Kushner M J.H₂ generation in Ar/NH₃ microdischarges[J]. Journal of Physics D: Applied Physics, 2007, 40(8): 2476.
[16] Li Zhi, Zhao Zhen, Li Xuehui.Numerical analysis of a mixture of Ar/NH₃ microwave plasma chemical vapor deposition reactor[J]. Journal of Applied Physics, 2012, 111(11): 113304.
[17] Niu Yulong, Li Shouzhe, Wang Xingchang, et al.Characteristic study of nitrogen microwave plasma decomposition of ammonia at atmospheric pressure for hydrogen production[J]. Plasma Sources Science and Technology, 2024, 33(10): 105018.
[18] Zhang Xinhua, Cha M S.Ammonia cracking for hydrogen production using a microwave argon plasma jet[J]. Journal of Physics D: Applied Physics, 2024, 57(6): 065203.
[19] Bazinette R, Sadeghi N, Massines F.Dual frequency DBD: influence of the amplitude and the frequency of applied voltages on glow, Townsend and radio- frequency DBDs[J]. Plasma Sources Science and Technology, 2020, 29(9): 095010.
[20] Robert R, Hagelaar G, Sadeghi N, et al.Role of excimer formation and induced photoemission on the Ar metastable kinetics in atmospheric pressure Ar- NH₃ dielectric barrier discharges[J]. Plasma Sources Science and Technology, 2022, 31(6): 065010.
[21] Robert R, Massines F, Stafford L.Kinetics driving H₂(a) continuum emission in low-frequency Ar-NH₃ dielectric barrier discharges at atmospheric pressure[J]. Plasma Chemistry and Plasma Processing, 2024, 44(4): 1547-1561.
[22] Zhang Shuai, Wang Wenchun, Jiang Pengchao, et al.Comparison of atmospheric air plasmas excited by high-voltage nanosecond pulsed discharge and sinusoidal alternating current discharge[J]. Journal of Applied Physics, 2013, 114(16): 163301.
[23] Huang Bangdou, Takashima K, Zhu Ximing, et al.The influence of the voltage rise rate on the break- down of an atmospheric pressure helium nanosecond parallel-plate discharge[J]. Journal of Physics D: Applied Physics, 2015, 48(12): 125202.
[24] 赵勇, 王瑞雪, 章程, 等. 脉冲波形对氦等离子体射流子弹传播特性的影响[J]. 电工技术学报, 2019, 34(16): 3472-3479.
Zhao Yong, Wang Ruixue, Zhang Cheng, et al.The effect of pulse parameters on helium plasma bullet distribution properties[J]. Transactions of China Electrotechnical Society, 2019, 34(16): 3472-3479.
[25] 赵昱雷, 刘峰, 庄越, 等. 纳秒脉冲电压变化速率对氩气DBD均匀性的影响[J]. 高电压技术, 2022, 48(6): 2317-2325.
Zhao Yulei, Liu Feng, Zhuang Yue, et al.Influence of nanosecond pulse voltage slew rates on the uniformity of argon DBD[J]. High Voltage Engineering, 2022, 48(6): 2317-2325.
[26] Zhang Qian, Liu Zhiheng, Lin Deling, et al.Analysis of discharge characteristics of pulsed plasma power source in the microsecond scale[J]. Journal of Physics: Conference Series, 2022, 2313(1): 012023.
[27] Truong H T, Uesugi Y, Nguyen X B.Mechanisms of low-frequency dielectric barrier discharge (DBD) plasma driven by unipolar pulses and bipolar pulses[J]. AIP Advances, 2021, 11(2): 025022.
[28] Gong Weiwei, Huang Quanjun, Wang Zhan, et al.Effect of pulse rise time on plasma plume propagation velocity[J]. IEEE Transactions on Plasma Science, 2014, 42(10): 2868-2869.
[29] Uchida G, Takenaka K, Setsuhara Y.Effects of discharge voltage waveform on the discharge characteristics in a helium atmospheric plasma jet[J]. Journal of Applied Physics, 2015, 117(15): 153301.
[30] 赵妮, 田浩, 付强, 等. 大气压Ar-NH₃混合气体氧化锆介质阻挡放电特性与产物分布[J]. 石油学报(石油加工), 2023, 39(5): 1162-1172.
Zhao Ni, Tian Hao, Fu Qiang, et al.Characteristics and product distribution of zirconia dielectric barrier discharge in Ar-NH₃ mixture at atmospheric pressure[J]. Acta Petrolei Sinica (Petroleum Processing Section), 2023, 39(5): 1162-1172.
[31] Zhao Ni, Tian Hao, Fu Qiang, et al.Experimental study on the effects of gas mixture and barrier dielectric on the discharge characteristics and plasma- chemical reactions of Ar-NH₃ DBD[J]. IEEE Trans- actions on Plasma Science, 2024, 52(12): 5506-5514.
[32] Zhao Ni, Yang Huan, Yao Congwei, et al.Effects of dielectric constant and secondary electron emission coefficient on discharge characteristics and products of Ar/NH₃ DBD[J]. Physics of Plasmas, 2022, 29(3): 033512.
[33] Tian Hao, Zhao Ni.The effects of voltage amplitude and frequency on hydrogen by 1D fluid simulation of Ar/NH₃ DBD[C]//2023 IEEE 6th International Electrical and Energy Conference (CIEEC), Hefei, China, 2023: 4120-4123.
[34] 姚聪伟, 常正实, 张冠军, 等. 大气压氩气介质阻挡放电等离子体特性变化的一维仿真[J]. 高电压技术, 2015, 41(6): 2084-2092.
Yao Congwei, Chang Zhengshi, Zhang Guanjun, et al.One-dimensional simulation of evolution characteris- ics of dielectric barrier discharge in atmospheric pressure argon[J]. High Voltage Engineering, 2015, 41(6): 2084-2092.
[35] 龙凯华, 邵涛, 严萍, 等. 高压纳秒脉冲下介质阻挡放电的仿真研究[J]. 高电压技术, 2008, 34(6): 1249-1254.
Long Kaihua, Shao Tao, Yan Ping, et al.Simulation of dielectric barrier discharges using nanosecond high voltage pulses[J]. High Voltage Engineering, 2008, 34(6): 1249-1254.
[36] Wang Weiwei, Wang Xue, Fan Zhihui, et al.Very large-cale gap distances of atmospheric pressure dielectric barrier glow discharge using semiconductor materials[J]. Europhysics Letters, 2021, 133(6): 65001.
[37] Yu Tianze, Zhang Haotian, Zhao Zhixin, et al.Characteristics of an AC rotating gliding arc discharge in NH₃ and air atmospheres[J]. Physics of Plasmas, 2024, 31(2): 023501.
[38] Crispim L W S, da Silva C D, Amorim J, et al. Simulation of 1D atmospheric pressure dielectric barrier discharge in argon[J]. Physica Scripta, 2024, 99(6): 065521.
[39] Kong F R, Zhang Z L, Jiang B H.Numerical study of the discharge properties of atmospheric dielectric barrier discharge by using 200 kHz/13.56 MHz excitations[J]. AIP Advances, 2018, 8(7): 075009.
[40] Bazinette R, Paillol J, Massines F.Optical emission spectroscopy of glow, Townsend-like and radio- frequency DBDs in an Ar/NH₃ mixture[J]. Plasma Sources Science and Technology, 2015, 24(5): 055021.
[41] Sun Jinguo, Bao Yupan, Ravelid J, et al.Application of emission spectroscopy in plasma-assisted NH₃/air combustion using nanosecond pulsed discharge[J]. Combustion and Flame, 2024, 263: 113400.
[42] 赵越, 王丽, 张家良, 等. 非平衡等离子体放电模式及反应器结构对氨气分解制氢的影响[J]. 物理化学学报, 2014, 30(4): 738-744.
Zhao Yue, Wang Li, Zhang Jialiang, et al.Influence of non-thermal plasma discharge mode and reactor structure on ammonia decomposition to hydrogen[J]. Acta Physico-Chimica Sinica, 2014, 30(4): 738-744.
[43] Chang Zhengshi, Yao Congwei, Chen Sile, et al.Electrical and optical properties of Ar/NH₃ atmos- pheric pressure plasma jet[J]. Physics of Plasmas, 2016, 23(9): 093503.