Title :
Acoustic Agglomeration of PM2.5 Enhanced by Additional Particles
Author :
Fengxian, Fan ; Houtao, Chen ; Zhulin, Yuan
Author_Institution :
Sch. of Energy & Power Eng., Univ. of Shanghai for Sci. & Technol., Shanghai, China
Abstract :
The acoustic agglomeration model of suspended PM2.5 subjected to a standing-wave sound field is established based on the direct simulation Monte Carlo (DSMC) method. The particle motion and agglomeration are numerically investigated, and the simulated result is compared with experiment to validate the agglomeration model and the algorithm. The results show that the dynamic behaviors of sub micron particles and micron particles under the effect of sound field are very different, and that the removal efficiency of PM2.5 by acoustic agglomeration can be greatly improved by adding large particles into the gas stream. In a typical case, the PM2.5 removal efficiency can be increased from 21.5% to 47.4% with additional particles.
Keywords :
Monte Carlo methods; acoustic waves; atmospheric acoustics; numerical analysis; acoustic agglomeration model; direct simulation Monte Carlo method; micron particles; particle motion; sound field effect; standing-wave sound field; submicron particles; Acoustics; Computational modeling; Equations; Mathematical model; Numerical models; Trajectory; Vibrations; Monte Carlo method; acoustic agglomeration; fine particles (PM2.5); removal efficiency; sound field;
Conference_Titel :
Computer Distributed Control and Intelligent Environmental Monitoring (CDCIEM), 2011 International Conference on
Conference_Location :
Changsha
Print_ISBN :
978-1-61284-278-3
Electronic_ISBN :
978-0-7695-4350-5
DOI :
10.1109/CDCIEM.2011.579
