Numerical Investigation of Corona Plasma Region in Negative Wire-to-duct Corona discharge

Aerosol and Air Quality Research

Volumn 10, Issue 5, 2010, Pages 446-455

  Kim, C ^a   Noh, K C ^a   Hwang, J ^a  

^a Yonsei University   (South Korea)

Author keywords

Charge density; Corona discharge; Numerical investigation.; Plasma region; Plasma region thickness

Indexed keywords

AIRBORNE DUSTS; APPLIED VOLTAGES; CHARGE CONSERVATION; CHARGE DENSITY DISTRIBUTIONS; COMPUTATION METHODS; COMPUTATION MODEL; CORONA DISCHARGES; CORONA PLASMAS; EXPERIMENTAL DATA; FLOW DYNAMICS; NUMERICAL INVESTIGATIONS; PARTICLE BEHAVIOR; PLASMA REGION; PLASMA REGION THICKNESS;

BOUNDARY CONDITIONS; CHARGE DENSITY; ELECTRIC CORONA; ELECTRIC FIELDS; ELECTROSTATIC PRECIPITATORS; ELECTROSTATIC SEPARATORS; PLASMAS; POISSON DISTRIBUTION; WIRE;

ELECTRIC DISCHARGES;

ATMOSPHERIC ELECTRICITY; ATMOSPHERIC MODELING; BOUNDARY CONDITION; CORONA; ELECTRIC FIELD; EXPERIMENTAL STUDY; NUMERICAL MODEL; PLASMA; POISSON RATIO;

EID: 77957702205     PISSN: 16808584     EISSN: 20711409     Source Type: Journal    
DOI: 10.4209/aaqr.2010.03.0019     Document Type: Article

References (15)

1. Adamiak, K. (1994). Simulation of Corona in Wire-duct Electrostatic Precipitator by Means of the BoundaryElement Method. IEEE Trans. Ind. Appl. 30: 381-386.
2. Adamiak, K. and Atten, P. (2004). Simulation of Corona Discharge in Point-plane Configuration. J. Electrostat.61: 85-98. (Pubitemid 38503382)
3. Anagnostopoulos, J. and Bergeles, G. (2002). Corona Discharge Simulation in Wire-duct Electrostatic Precipitator. J. Electrostat. 54: 129-147.
4. Chen, J. and Davidson, J.H. (2003). Model of the Negative dc Corona Plasma: Comparison to the Positive dc Corona Plasma. Plasma Chem. Plasma Process. 23: 83-102.
5. Cristina, S., Dinelli, G. and Feliziani, M. (1991). Numerical Computation of Corona Space Charge and V-I Characteristic in dc Electrostatic Precipitators. IEEE Trans. Ind. Appl. 27: 147-153.
6. Hinds, W. C. (1999). Aerosol Technology, John Wiley &Sons, Inc. 323.
7. Lami, E., Mattachini, F., Sala, R. and Vigl, H. (1997). A Mathematical Model of Electrostatic Field in Wires-plate Electrostatic Precipitators. J. Electrostat. 39: 1-21.
8. Lawless, P.A. and Sparks, L.E. (1980). A Mathematical Model for Back Corona in Wire-duct Precipitators. J. Appl. Phys. 51: 242-256.
9. Lowke, J.J. and Morrow, R. (1994). Theory of Electric Corona Including the Role of Plasma Chemistry. Pure Appl. Chem. 66: 1287-1294.
10. McDonald, J.R., Smith, W.B., Spencer, H.W. and Sparks, L.E. (1977). A Mathematical Model for Calculating Electrical Conditions in Wire-duct Electrostatic Precipitation Devices. J. Appl. Phys. 48: 2231-2243.
11. Neimarlija, N., Demirdžić, I. and Muzaferija, S. (2009). Finite Volume Method for Calculation of Electrostatic Fields in Electrostatic Precipitators. J. Electrostat. 67: 37-47.
12. Ohkubo, T., Nomoto, Y., Adachi, T. and McLean, K.J. (1986). Electric Field in a Wire-duct Type Electrostatic Precipitator. J. Electrostat. 18: 289-303.
13. Penny, G.W. and Matick, R.E. (1960). Potentials in dc Corona Fields. Trans. AIEE Part I 79: 91-99.
14. Sigmond, R.S. (1986). The Unipolar Corona Space Charge Flow Problem. J. Electrostat. 18: 249-272.
15. Takahashi, Y., Yoshida, M., Anma, Y., Kobayashi, S. andEndo, M. (1982). Thickness and Luminosity Distribution of Positive Corona Sheath in Air. J. Phys. D: Appl. Phys. 15: 639-653.