ELECTROSTATIC PRECIPITATORS

1. ELECTROSTATIC PRECIPITATORS Presented by Dipti Ranjan Khuntia Roll # EE200117115 Under the Guidance of Mr. GAYADHAR PANDA

2. Particulate Collection Device used in industries to minimize air pollution Principle of operation Electrostatic attraction Efficiency of 99% in many industries Can handle large gas volumes with a wide range of inlet temperatures, pressures, dust volumes, and acid gas conditions Can collect particles of varying sizes in dry and wet states Introduction:

3. Theory of PrecipitationCharging, Collecting & Rapping Particle charging Discharge & Collection Electrodes Corona Discharge Avalanche Multiplication Ionization of gas molecules Particle Charging Mechanism Field charging, Diffusion charging, Electron charging Particle Collection Particle Removal Theory of Precipitation:

4. Particle Charging:

5. Corona Discharge

6. Ionization of Gas Molecules • Particle Charging Field charging, Diffusion charging, Electron charging

7. Particle collection • Particle Removal by rapping

8. Discharge electrodes Collection electrodes High voltage electrical systems Rappers Hoppers Shell Components of an Electrostatic Precipitator

10. Discharge Electrodes: Typical wire discharge electrodes Rigid frame discharge electrode design Typical rigid discharge electrode Flat-plate discharge electrode

11. Collection Electrodes:

12. High Voltage Electrical system • Transformer-rectifier (T-R) sets • Primary voltmeter • Primary ammeter • Secondary voltmeter • Secondary ammeter • Spark meter

13. Rappers: • Typical hammer/anvil rappers for collection plates • Typical magnetic-impulse rappers for collection plates

14. Hoppers: • Strike plates • Poke holes • Vibrators • Rappers Hopper Rotary airlock discharge device Double-dump discharge device

15. Conveyors: Drag conveyor Screw conveyor Pneumatic conveyor for transporting dust from ESP

16. Types of Electrostatic Precipitators Gas Flow through a tubular precipitator • Tubular Precipitators • Plate Precipitators Gas flow through a plate precipitator

17. Cold-side ESPs Cold side ESP’s • Cold side ESPs 1) volume of flue gas that is handled is less 2) less costly 3) overall size of the unit is smaller 4) used to remove fly ash from boilers that burn high sulfur coal

18. Hot Side ESPs • used in high-temperature applications (Cement kiln) • the gas volume treated in the ESP is larger • the overall size of the precipitator is larger making it more costly • structural and mechanical problems occur in the precipitator shell

19. Wet Side ESPs • Wet ESPs are used for industrial applications where the potential for explosion is high • When dust is very sticky, corrosive, or has very high resistivity • It does not have problems with rapping reentrainment or with back corona

20. Dry Side ESPs • Particles are charged and collected in a dry state • Dust particles collected are removed by rapping • Used in steel furnaces, cement kilns and fossil-fuel-fired boilers

21. All ESPs, no matter how they are grouped, have similar components and operate by charging particles or liquid aerosols, collecting them, and finally removing them from the ESP before ultimate disposal in a landfill or reuse in the industrial process The precipitator should be designed to provide easy access to strategic points of the collector for internal inspection of electrode alignment, for maintenance, and for cleaning electrodes, hoppers, and connecting flues during outages Conclusion

22. Thank You