Three-Dimensional Simulation of Cross-Flow Microfilter Fouling in Tortuous Pore Profiles With Semisynthetic Metalworking Fluids

Fouling mechanisms and models for flux decline are investigated with a three-dimensional simulation of the tortuous, verisimilar geometry of an α-alumina microfilter. Reconstruction of the three-dimensional geometry was accomplished from two-dimensional cross-sectional cuts. A wall collision model and a particle trapping model are developed for the investigation of fouling mechanisms. The reconstructed geometry and the two models were used in computational fluid dynamics to simulate metalworking colloidal particles travelling through and becoming trapped in the tortuous pore paths of a microfilter. Results reveal sharp flux decline initiating from partial pore blocking and subdued flux decline transitioning to cake layer development with steady-state flow. This flow behavior is in agreement with experimental data from earlier studies. The inclusion of the wall collision model and particle trapping model enabled the revelation of cake layer development as a fouling mechanism. Additional simulations of microfilters at different particle size distributions were conducted and discussed.

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Three-Dimensional Simulation of Cross-Flow Microfilter Fouling in Tortuous Pore Profiles With Semi-Synthetic Metalworking Fluids

ASME 2010 International Manufacturing Science and Engineering Conference, Volume 2 ◽

10.1115/msec2010-34269 ◽

2010 ◽

Cited By ~ 2

Author(s):

Bingyi Yu ◽

Shiv G. Kapoor ◽

Richard E. DeVor

Keyword(s):

Colloidal Particles ◽

Three Dimensional ◽

Particle Trapping ◽

Collision Model ◽

Flux Decline ◽

Cake Layer ◽

Trapping Model ◽

Wall Collision ◽

Dimensional Simulation ◽

Layer Development

Fluid flow and fouling mechanisms are examined with a three-dimensional simulation of the tortuous, verisimilar geometry of an α-alumina microfilter. Reconstruction of the three-dimensional geometry was accomplished from two-dimensional cross-sectional cuts, obtained from a focused ion beam. A wall collision model and a particle trapping model are developed for the investigation of fouling mechanisms. The reconstructed geometry and the two models were used in computational fluid dynamics to simulate metalworking colloidal particles travelling through and trapping in the tortuous pore paths of a microfilter. Results reveal sharp flux decline initiating from partial pore blocking and subdued flux decline finalizing in cake layer development with steady-state flow. This flow behavior is in agreement with experimental data from earlier studies. The inclusion of the wall collision model and particle trapping model enabled the revelation of cake layer development as a fouling mechanism.

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Three-Dimensional Simulation of Turbulent Gas-Solid Flow and Heat Transfer in a Pipe

Volume 1: Symposia, Parts A, B and C ◽

10.1115/fedsm2009-78007 ◽

2009 ◽

Author(s):

Z. Mansoori ◽

A. Dadashi ◽

M. Saffar-Avval ◽

F. Behzad ◽

G. Ahmadi

Keyword(s):

Heat Transfer ◽

Inelastic Collision ◽

Three Dimensional ◽

Wall Heat Transfer ◽

Vertical Pipe ◽

Solid Flow ◽

Collision Model ◽

Flow And Heat Transfer ◽

Dimensional Simulation ◽

Wall Interactions

Three-dimensional simulation of turbulent gas-solid flow with heat transfer for a vertical pipe is performed in this study and the results are presented. The approach is based on an Eulerian/Lagrangian four-way interaction formulation considering turbulent hydrodynamic and thermal intensities and time scales equations. Inter-particles and particle-wall interactions are accounted for with an inelastic collision model. Numerical model validation is performed for an upward pipe gas-solid flow with constant wall heat transfer.

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