Title :
3-D model of electric field and space charge in the barbed plate-to-plate precipitator
Author :
Davidson, Jane H. ; McKinney, Peter J. ; Linnebur, Paul
Author_Institution :
Particle Technol. Lab., Minnesota Univ., Minneapolis, MN, USA
Abstract :
A finite element method of a characteristics model of 3-dimensional electrode geometries with corona discharge is used to predict space charge density, current density, electric potential and electric field in point-to-plane, single barb plate-to-plane, and hexagonal barbed plate-to-plate geometries. Although a modification of Peak´s formula for the hyperboid-to-plane was initially used to establish a boundary condition at the edge of the corona, predicted total current did not agree with measured values. As a result, it was necessary to use measured current-voltage characteristics to establish the space charge density at the corona. An additional problem in modeling point discharges is specification of shape and size of the corona sheath. Both the results and much earlier work by Trichel suggest that the thickness of the corona sheath cannot be automatically neglected
Keywords :
corona; current density; electric fields; electrodes; electrostatic precipitators; finite element analysis; space charge; 3-D model; 3-dimensional electrode; Peak´s formula modification; barbed plate-to-plate precipitator; corona discharge; corona sheath thickness; current density; current-voltage characteristics; electric field; electric potential; finite element method; hexagonal barbed plate-to-plate geometry; hyperboid-to-plane; point-to-plane geometry; single barb plate-to-plane geometry; space charge; space charge density; Corona; Current density; Current measurement; Electric potential; Electrodes; Finite element methods; Geometry; Predictive models; Solid modeling; Space charge;
Conference_Titel :
Industry Applications Society Annual Meeting, 1994., Conference Record of the 1994 IEEE
Conference_Location :
Denver, CO
Print_ISBN :
0-7803-1993-1
DOI :
10.1109/IAS.1994.377646
