论文信息 - CFD Simulation of the Filtration Performance of Fibrous Filter Considering Fiber Electric Potential Field

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

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.

[1] Qinghai Li,et al. The effect of electrostatic forces on filtration efficiency of granular filters , 2015 .

[2] Ludovic F. Dumée,et al. High Efficiency Poly(acrylonitrile) Electrospun Nanofiber Membranes for Airborne Nanomaterials Filtration , 2018 .

[3] L. Ye,et al. Filtration Efficiency of Non-Uniform Fibrous Filters , 2015 .

[4] B. Ding,et al. Low-Resistance Dual-Purpose Air Filter Releasing Negative Ions and Effectively Capturing PM2.5. , 2017, ACS applied materials & interfaces.

[5] H. Vahedi Tafreshi,et al. Modeling particle-loaded single fiber efficiency and fiber drag using ANSYS–Fluent CFD code , 2012 .

[6] K. W. Lee,et al. Experimental study of aerosol filtration by fibrous filters , 1981 .

[7] Li-Zhi Zhang,et al. Modeling of dynamic deposition and filtration processes of airborne particles by a single fiber with a coupled lattice Boltzmann and discrete element method , 2016 .

[8] Malay K. Mazumder,et al. Twenty-first century research needs in electrostatic processes applied to industry and medicine , 2006 .

[9] John Happel,et al. Viscous flow relative to arrays of cylinders , 1959 .

[10] David Y. H. Pui,et al. Experimental Study of Submicrometer and Ultrafine Particle Penetration and Pressure Drop for High Efficiency Filters , 1990 .

[11] A. Kamra,et al. Effect of coagulation on the particle charge distribution and air conductivity , 2001 .

[12] M. Aguiar,et al. Characterization and evaluate the efficiency of different filter media in removing nanoparticles , 2017 .

[13] Q. Song,et al. Experimental investigation on the particle capture by a single fiber using microscopic image technique , 2006 .

[14] Meghan A. Wallace,et al. Comparing the performance of 3 bioaerosol samplers for influenza virus , 2017, Journal of Aerosol Science.

[15] F. Wang,et al. Electrospun Nanofibers Membranes for Effective Air Filtration , 2017 .

[16] Parham Soltani,et al. Effect of 3D fiber orientation on permeability of realistic fibrous porous networks , 2014 .

[17] R. Axelbaum,et al. Predicting particle deposition for flow over a circular cylinder in combustion environments , 2019, Proceedings of the Combustion Institute.

[18] K. Okuyama,et al. Synthesis and evaluation of straight and bead-free nanofibers for improved aerosol filtration , 2015 .

[19] L. Ricciardi,et al. Simulations of filter media performances from microtomography-based computational domain. Experimental and analytical comparison , 2015 .

[20] James C. Hill,et al. Capture of Particles on Spheres by Inertial and Electrical Forces , 1976 .

[21] S. Kuwabara,et al. The Forces experienced by Randomly Distributed Parallel Circular Cylinders or Spheres in a Viscous Flow at Small Reynolds Numbers , 1959 .

[22] Chikao Kanaoka,et al. Stochastic simulation of the agglomerative deposition process of aerosol particles on an electret fiber , 2001 .

[23] H. Zhang,et al. Pilot-plant production of xylo-oligosaccharides from corncob by steaming, enzymatic hydrolysis and nanofiltration , 2004 .

[24] Chun Shun Cheung,et al. Inertial impaction-dominated fibrous filtration with rectangular or cylindrical fibers , 2000 .

[25] L. Burmeister,et al. Field evaluation of endotoxin air sampling assay methods. , 1997, American Industrial Hygiene Association journal.

[26] C. Zheng,et al. Simulating and Modeling Particulate Removal Processes by Elliptical Fibers , 2014 .

[27] Haibo Zhao,et al. Numerical study of pressure drop and diffusional collection efficiency of several typical noncircular fibers in filtration , 2016 .

[28] Chuguang Zheng,et al. Simulation of filtration process for multi-fiber filter using the Lattice-Boltzmann two-phase flow model , 2013 .

[29] C. Wang,et al. Electrostatic forces in fibrous filters—a review , 2001 .

[30] Sai Kishore Ravi,et al. Transparent Nanofibrous Mesh Self-Assembled from Molecular LEGOs for High Efficiency Air Filtration with New Functionalities. , 2017, Small.

[31] Sufen Li,et al. Numerical investigation on deposition process of submicron particles in collision with a single cylindrical fiber , 2019, Journal of Aerosol Science.

[32] Young-Chull Ahn,et al. Development of high efficiency nanofilters made of nanofibers , 2006 .

[33] A. C. Payatakes,et al. Dendritic deposition of aerosol particles in fibrous media by inertial impaction and interception , 1980 .

[34] Haibo Zhao,et al. Numerical investigation on non-steady-state filtration of elliptical fibers for submicron particles in the ‘‘Greenfield gap’’ range , 2017 .

[35] D. Pui,et al. Filtration efficiency and loading characteristics of PM2.5 through commercial electret filter media , 2018 .

[36] H. Vahedi Tafreshi,et al. 3-D simulation of particle filtration in electrospun nanofibrous filters , 2010 .

[37] K. W. Lee,et al. Theoretical Study of Aerosol Filtration by Fibrous Filters , 1982 .

[38] K. Adamiak. Aerosol deposition on an arbitrarily oriented single rectangular fibre in a uniform electric field , 1995, IAS '95. Conference Record of the 1995 IEEE Industry Applications Conference Thirtieth IAS Annual Meeting.

[39] N. Fuchs,et al. Studies on Fibrous Aerosol Filters—I. Calculation of Diffusional Deposition of Aerosols in Fibrous Filters , 1966 .

[40] R. C. Brown. A many-fibre model of airflow through a fibrous filter , 1984 .

[41] M. L. Laucks,et al. Aerosol Technology Properties, Behavior, and Measurement of Airborne Particles , 2000 .

[42] K. W. Lee,et al. Note on the approximation of interceptional collection efficiencies , 1980 .

[43] Christopher J. Hogan,et al. Nanoparticle filtration by electrospun polymer fibers , 2007 .

[44] Hu Yule. Numerical simulation of three dimensional flow fields of fiber filter media , 2011 .

[45] Sampling submicron T1 bacteriophage aerosols. , 1965, Applied microbiology.

[46] Wamadeva Balachandran,et al. A lab-scale system to study submicron particles removal in wet electrostatic scrubbers , 2013 .

[47] H. Chan,et al. Measuring Bipolar Charge and Mass Distributions of Powder Aerosols by a Novel Tool (BOLAR). , 2015, Molecular pharmaceutics.

[48] Wallace Woon-Fong Leung,et al. Filtration of nano-aerosol using nanofiber filter under low Peclet number and transitional flow regime , 2011 .

[49] H. Vahedi Tafreshi,et al. Modeling particle filtration in disordered 2-D domains: A comparison with cell models , 2010 .

[50] Shoji Takeuchi,et al. A glass fiber sheet-based electroosmotic lateral flow immunoassay for point-of-care testing. , 2012, Lab on a chip.

[51] B. Pourdeyhimi,et al. Influence of fiber orientation distribution on performance of aerosol filtration media , 2010 .

[52] O. Abouali,et al. Numerical investigation on dust-loaded fibrous filters , 2018 .

[53] Electrostatic Charge Measurement and Charge Neutralization of Fine Aerosol Particles during the Generation Process , 2005 .

[54] B. Pourdeyhimi,et al. Boehmite nanoparticles incorporated electrospun nylon-6 nanofiber web for new electret filter media , 2010 .

[55] B. Pourdeyhimi,et al. An analytical approach to predict pressure drop and collection efficiency of dust-load pleated filters , 2016 .

[56] A. Renoux,et al. PENETRATION AND PRESSURE DROP OF A HEPA FILTER DURING LOADING WITH SUBMICRON LIQUID PARTICLES , 1992 .

[57] Leon Gradoń,et al. Application of nanofibers to improve the filtration efficiency of the most penetrating aerosol particles in fibrous filters , 2006 .

[58] Hamaguchi,et al. Polarization force on a charged particulate in a nonuniform plasma. , 1994, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[59] Xiaoze Du,et al. Modeling filtration performance of elliptical fibers with random distributions , 2017 .

[60] Bandaru V. Ramarao,et al. Calculation of single fiber efficiencies for interception and impaction with superposed brownian motion , 1994 .

[61] Xie Ying-hui. Resource utilization of concentrated seawater generated during desalination , 2013 .

[62] M. R. Tek. Development of a Generalized Darcy Equation , 1957 .

[63] W. Hoppel. Ion-aerosol attachment coefficients, ion depletion, and the charge distribution on aerosols , 1985 .

[64] X. Qin,et al. Filtration properties of electrospinning nanofibers , 2006 .