Numerical Study of the Suitable Precharger Grounded Electrode Length in Two-Stage-Type Electrostatic Precipitators

The two-stage-type electrostatic precipitator has been used only in limited applications because of its need to accommodate a large flow rate with its compact size. A two-stage-type electrostatic precipitator comprises a precharger and a collecting unit. The grounded electrode in the precharger is g...

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Bibliographic Details
Published inIEEE transactions on industry applications Vol. 55; no. 1; pp. 833 - 839
Main Authors Kawada, Yoshihiro, Shimizu, Hirotaka, Zukeran, Akinori
Format Journal Article
LanguageEnglish
Published New York IEEE 01.01.2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Charge distribution
Corona discharge
Density distribution
Electric fields
Electric potential
Electric wire
Electrodes
Electrostatic precipitators
Finite element method
Flow velocity
gas discharge devices
High voltages
Ion density (concentration)
Ions
Mathematical model
numerical analysis
Particle charging
Precipitators
Space charge
Wire
Wires
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Summary:The two-stage-type electrostatic precipitator has been used only in limited applications because of its need to accommodate a large flow rate with its compact size. A two-stage-type electrostatic precipitator comprises a precharger and a collecting unit. The grounded electrode in the precharger is generally designed to be quite short. Previous studies on the influence of the grounded electrode length in the precharger on collection efficiency have reported that the amount of particle charge through the precharger decreases for grounded electrodes that are 20- or 80-mm long. The electric field and space charge distributions were calculated for various grounded electrode lengths using the finite-element method, where the ion density distribution was used as the space charge distribution. For a 20-mm-long grounded electrode, the electric field intensity around the high-voltage wire electrode decreased. Additionally, the electric field intensity distribution at close proximity to the grounded electrode has two additional peaks due to the edges of the electrode. With the 80-mm-long grounded electrode, the peaks of the electric field intensity distribution were outside of the high-ion-density region. These results show that the optimal grounded electrode length for particle charging is about three times the distance between the grounded electrode and the high-voltage wire electrode.
ISSN:0093-9994
1939-9367
DOI:10.1109/TIA.2018.2868553