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An Experimental Investigation of A Non-Mixing Type Corona-Needle Charger for Submicron Aerosol Particles

  • Panich IntraEmail author
  • Artit Yawootti
Original Article

Abstract

Aims

In this study, the non-mixing type corona-needle charger for submicron aerosol particles was designed and experimentally investigated.

Methods

The current-to-voltage characteristics, charger response and particle losses of the charger were experimentally studied and discussed at different corona voltage of about 0–5 kV and particle diameter of about 10–1000 nm and aerosol flow rate of about 1.5 L/min.

Results

It was shown that the highest ion number concentration in the discharge zone of the charger was found to be about 3.48 × 1014 ions/m3 for a corona voltage of about 5 kV. The charger response was found to increase when the particle diameter decreased for particle smaller than 80 nm. For particle larger than 80 nm, the charger response was found to slightly increase with the particle diameter. The highest diffusion loss was seen to occur at particle diameter of 10 nm to be about 49.74 %. For the electrostatic loss, the highest particle loss was observed to occur at particles diameter of about 10 nm to be about 52.87 % for the corona voltages of 3.2 kV.

Conclusions

From the findings, this non-mixing type charger proved to be particularly useful as an aerosol charger before the detector in an electrical aerosol detector.

Keywords

Corona discharge Particle charging Aerosol charger Particle loss 

Notes

Acknowledgements

The authors gratefully acknowledge the Electricity Generating Authority of Thailand (EGAT), Research contract no. GGR010100089000. The authors wish to thank the Department of Chemical Engineering, Faculty of Engineering, Chulalongkorn University for the Electrostatic Classifiers 3080 and the Ultrafine Condensation Particle Counter 3776 and also Prof. Dr. Rainer Zawadzki of Governor State University for the valuable contribution during the preparation of the manuscript.

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Copyright information

© The Korean Institute of Electrical Engineers 2019

Authors and Affiliations

  1. 1.Research Unit of Applied Electric Field in Engineering (RUEE), College of Integrated Science and TechnologyRajamangala University of Technology LannaChiang MaiThailand

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