Surface Dielectric Barrier Discharge

Xiaotong Li (University of Strathclyde, Glasgow, Scotland, United Kingdom)

Abstract


This project is concerned with surface dielectric barrier discharge (DBD), which involve designing the configuration of discharge and experiment, collecting and analysis data from experiment and simulation. Therefore, this report includes the objective of the project and general information of background. It also briefly introduces the history and theory of dielectric barrier discharge. For the experiment how to design the discharge implement and why. Then it will show the experiment in different configurations, and the analysis data collected in experiment also explain the data for finding out the properties of surface dielectric barrier discharge and what the difference between surface discharge and vertical discharge are. High frequency power supplied will be used for viewing the phenomenon of discharge. Compare the spectrums of discharge on dielectric and air discharge. Finally, it is the main conclusions and introduction of the difference of surface dielectric barrier discharge and vertical discharge. There are some conclusions. Discharge voltage increase linearly with applied voltage. Discharge power increase non-linearly with the discharge voltage. The gap of high voltage electrodes will not affect discharge voltage and discharge power. Discharge power increases with the frequency of power supply. Discharge area will expand when the applied voltage increases.


Keywords


DBD (dielectric barrier discharge); Lissajous figure; Paschen law

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References


[1] Xueji Xu Institute for Electric Light Sources, Fudan University, Shanghai 200433, PR China. “Dielectric barrier discharge properties and applications.” Thin Solid Films, 2001, 390: 237-242

[2] Ulrich Kogelschatz.” Dielectric barrier discharges their history discharge physics and industrial applications.”Plasma Chemistry and Plasma Processing, 2003, 23(1). (@ 2003)

[3] M.V.Kozlov, M.V.Sokolova, A.G.Temnikov, V.V.Timatkov, I.P.Vereshchagin . “Surface discharge characteristics for different types of applied voltage and dielectrics”

[4] http://active.quickfield.com

[5] http://2.bp.blogspot.com/_7vKteIzL3xQ/SbxQ2dW2aVI/AAAAAAABDdE/kHv2o7lpvHQ/s1600-h/!!!Paschen-Curve.jpg

[6] L.Lalston. High-Voltage Technology. Oxford University Press, 1968.

[7] U. Konelschatz, B. Eliasson and W. Egli. “Dielectric-Barrier Discharges. Principle and Applications.” Colloque C4, Supplement au Journal de Physique, I11 d'octobre, 1997.

[8] Luo Yi, Fang Zhi, Qu Yu Chang, Wang Hui. Analysis of Influencing Facors on Dielectric Barrier Discharge. 1001-1609(2004)02-0081-03.

[9] Hao Yan-peng, Yang Lin , Tu En-lai , Chen Jian-yang. Equivalent “Capacitance and its Influence on Electrical Parameter Calculations of Dielectric Barrier Glow Discharges in Helium at Atmospheric-pressure.” School of Electric Power , South China University of Technology , Guangzhou, 510640 , China.

[10] J. Reece Roth. Potential industrial applications of the one atmosphere uniform glowdischarge plasma operating in ambient aira). Plasma Sciences Laboratory, Department of Electrical and Computer Engineering, University of Tennessee, Knoxville, Tennessee, 37996-2100, 2005.

[11] “Dielectric barrier discharge.”

[12] http://en.wikipedia.org/wiki/Paschen's_law

[13] Ulrich Kogelschatz. “Filamentary, Patterned, and DiffuseBarrier Discharges.” IEEE Transactions on Plasma Science, 2002, 30(4).



DOI: https://doi.org/10.30564/ese.v1i1.713

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