The Transactions of The Korean Institute of Electrical Engineers (전기학회논문지)

The Korean Institute of Electrical Engineers (대한전기학회)
권호 표지

Corona Discharge and Ozone Generation Characteristics of a Slit Dielectric Barrier Discharge Type Plasma Reactor with a Third Electrode

3전극이 부설된 틈새 장벽방전형 플라즈마장치의 코로나 방전 및 오존발생 특성

  • 문재덕 (경북대 전자전기컴퓨터학부) ;
  • 정재승 (경북대 대학원 전기공학과)
  • Published : 2007.03.01
Download PDF
⟨ Previous Next ⟩

Abstract

Corona discharge and ozone generation characteristics of a slit dielectric barrier discharge type wire-plate plasma reactor with a third electrode have been investigated. When a third electrode is installed on a slit of the slit barrier, where an intense corona discharge occurs, it is found that a significantly increased ozone output could be obtained. This, however, indicates that the third electrode can activate the corona discharges both of the discharge wire and the slit of the slit barrier in the plasma reactor. As a result, a thin stainless wire, used as the third electrode has a strong effect to influence the corona discharge of the slit and corona wire, especially to the negative corona discharge. Higher amounts of the output ozone and ozone yield, about 1.27 and 1.29 times for the negative corona discharge, can be obtained with the third electrode, which reveals the effectiveness of the third electrode.

Keywords

References

  1. H. H. Kim, et al, Performance evaluation of discharge plasma processfor gaseous pollutant removal, Journal of Electrostatics, 55 (2002) 25-41 https://doi.org/10.1016/S0304-3886(01)00182-6
  2. M. L. Balmer, et al, Non-thermal plasma for exhaust emission control: NOx, HC, and particulates, ISBN 0-7680-0490-X, USA (1999)
  3. K. Yan, Corona Plasma Generation, Eindhoven (2001)
  4. U. Kogelschatz, Ozone generation and dust collection, in electrical discharge for environmental purposes: Fundamentals and Applications, edited by E. M. van Veldhuizen, Nova Science Publishers, Inc., New York 11743 (2000)
  5. NATO Advanced Research Workshop on Non-thermal Plasma Techniques for Pollution Control, Cambridge Univ, England UK (Sept 21-25, 1992) 1-8
  6. G. Sathiamoorthy, et al, Chemical reaction kinetics and reactor modeling of NOx removal in a pulsed streamer corona discharge reactor, Ind. Eng. Chem. Res. 38 (5) (1999) 1944-1855
  7. W. Niessen, et al, The influence of ethane on the conversion of NOx in a dielectric barrier discharge, J. Phys, D: Appl. Phys, 31 (1998) 542-550 https://doi.org/10.1088/0022-3727/31/5/011
  8. T. Oda, et al, Decomposition of gaseous organic contaminants by surface discharge induced plasma chemical processing-SPCP, IEEE Trans. on IA, 32, 1 (1996) 118-123
  9. M. G. Nickelsen, et al, Removal of benzene and selected alkylsubstituted benzene from aqueous solution utilizing continuous electron radiation, Environmental Science Technology, 26 (1992) 144-152 https://doi.org/10.1021/es00025a016
  10. T. Yamamoto, Decomposition of Toluene, o-Xylene, Trichloroethylene, and Their Mixture Using a $BaTiO_{3}$ Packed-Bed Plasma Reactor, Journal of Advanced Technology, 1, 1 (1996) 67-78
  11. Jae-Seung Jung, et al, Effective Ozone Generation of a Wire-Plate Discharge System with a Slit Barrier, Proceeding of 2005 Annual Meeting of The Institute of Electrostatics Japan (2005) 245-250
  12. 日本靜電氣學會編, 靜電氣ハンドブツク (1981) 507-519
  13. 大木正路, 高電壓工學 (1980) 74-75