李杰

个人信息Personal Information

教授

博士生导师

硕士生导师

性别:男

毕业院校:大连理工大学

学位:博士

所在单位:电气工程学院

学科:环境工程. 电工理论与新技术. 高电压与绝缘技术

办公地点:大连理工大学电气工程学院静电所

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Discharge and optical characterizations of nanosecond pulse sliding dielectric barrier discharge plasma for volatile organic compound degradation

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论文类型:期刊论文

发表时间:2017-04-20

发表刊物:JOURNAL OF PHYSICS D-APPLIED PHYSICS

收录刊物:SCIE、EI

卷号:50

期号:15

ISSN号:0022-3727

关键字:sliding DBD; discharge characteristic; nanosecond pulse discharge; VOC degradation

摘要:In this work, a nanosecond bipolar pulsed voltage coupled with a negative DC component is employed to generate sliding dielectric barrier discharge (DBD) plasma in a three-electrode geometry reactor and improve volatile organic compound (VOC) degradation at room temperature. The effects of the bipolar pulsed voltage (U-+/- pulse) and negative DC voltage (U-DC) on the discharge characteristic, optical characteristic, plasma gas temperature (T-gas), and vibrational temperature (T-vib) are discussed. The horizontal distribution characteristics of the N-2(C-3 IIu -> (BIIg)-I-3) emission intensity, T-gas, and T-vib are also investigated to understand the propagation mechanism of sliding DBD along the dielectric surface. The experimental results reveal that a negative DC component applied to a third electrode can extend the plasma extension region, indicating that the gas ionization is ignited by the nanosecond high-voltage pulse, while charge drift is forced by the surface potential difference caused by the negative high-voltage DC. The T-gas is measured by optical emission spectroscopy related to the rotational bands of N-2(C-3 IIu -> (BIIg)-I-3), and is approximately 375 +/- 5 K under the condition of U (+/- pulse) = 20 kV and U-DC = -20 kV. Compared with typical surface DBD plasma, sliding DBD plasma is quasi-diffusive and distributed more uniformly within the whole discharge gap. Furthermore, both surface DBD and sliding DBD are used for removing toluene from flowing air. It is found that sliding DBD has higher toluene degradation efficiency and energy yield than surface DBD when they are excited by the positive pulsed voltage (U+pulse).