CFD Simulation of the Filtration Performance of Fibrous Filter Considering Fiber Electric Potential Field

Lei Hou; Ayang Zhou; Xiao He; Wei Li; Yan Fu; Jinli Zhang

doi:10.1007/s12209-019-00218-7

Transactions of Tianjin University ›› 2019, Vol. 25 ›› Issue (5) : 437 -450. DOI: 10.1007/s12209-019-00218-7

Research Article

CFD Simulation of the Filtration Performance of Fibrous Filter Considering Fiber Electric Potential Field

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Abstract

Aiming at disclosing the quantitative effects of Coulomb forces on the filtration efficiency of aerosol particles, a three-dimensional random fiber model was established to describe the microstructure of fibrous filters. Then, computational models including the flow model, particle model, and electric field model were constructed to estimate the filtration efficiency using the Fluent custom user-defined function program, neglecting the non-uniformity of the fiber potential and the particle charge distribution. The simulation results using the established models agreed with the data in the literature. In particular, the electric field force was found to be one of the important factors required to improve the filtration efficiency estimation accuracy for the ultrafine particles. Moreover, the variation tendencies of the filtration efficiency and the pressure drop of fibrous filters were studied based on the influence factors of the fiber potential, particle charge-to-mass ratio, solid volume fraction, fiber diameter, and face velocity. The established models and estimated results will provide important guidance on the design of high-efficiency particulate air filters for aerosol particles.

Keywords

Filtration efficiency / Coulomb force / Three-dimensional random fiber model / Interception capture / Brownian diffusion

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Lei Hou, Ayang Zhou, Xiao He, Wei Li, Yan Fu, Jinli Zhang. CFD Simulation of the Filtration Performance of Fibrous Filter Considering Fiber Electric Potential Field. Transactions of Tianjin University, 2019, 25(5): 437-450 DOI:10.1007/s12209-019-00218-7

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