A semi-analytical model for simulating fluid transport in multi-layered fibrous sheets made up of solid and porous fibers

Abstract Direct simulation of fluid transport in fibrous media consisting of swelling (i.e., fluid-absorbing) and non-swelling (i.e., solid) fibers is a challenge. In this work, we have developed a semi-analytical modeling approach that can be used to predict the fluid absorption and release characteristics of multi-layered composite fabrics made up of swelling and non-swelling fibrous sheets. The simulations presented here are based on a numerical solution of Richards’ equation. Two different fibrous sheets composed of non-swelling (PET) and swelling (Rayon) fibers with different Solid Volume Fractions (SVFs) and thicknesses were arbitrarily chosen in this study for demonstration purposes. The sheets’ capillary pressure and relative permeability are obtained via a combination of numerical simulations and experiment. In particular, the capillary pressure expression for non-swelling media is obtained from the analytical expressions that we previously developed via 3-D microscale simulations, while the capillary pressure for swelling media is obtained via height rise experiments. The relative permeability expressions for both swelling and non-swelling media are obtained from the analytical expressions previously developed via 3-D microscale simulations, which are also in agreement with experimental correlations from the literature. On the macroscale, simulation results are reported for fluid transport in bi-layered composite fabrics, and comparison is made between the performances of these fabrics in terms of the order in which the layers are stacked on top of one another. A higher rate of absorption was observed when the layer in contact with the fluid is that comprised of swelling fibers. A similar study was conducted for motion-induced fluid release from the composite fabrics when partially-saturated with a fluid. It was shown that less fluid release is expected when the swelling sheet is placed in contact with the surface.

[1]  Andreas Wiegmann,et al.  Design of acoustic trim based on geometric modeling and flow simulation for non-woven , 2006 .

[2]  C. M. Reed,et al.  The fundamentals of absorbency of fibres, textile structures and polymers. I. The rate of rise of a liquid in glass capillaries , 1993 .

[3]  K. Pillai,et al.  Darcy's law‐based models for liquid absorption in polymer wicks , 2007 .

[4]  N. Pan,et al.  Thermal and moisture transport in fibrous materials , 2006 .

[5]  R. H. Brooks,et al.  Hydraulic properties of porous media , 1963 .

[6]  Markus Hilpert,et al.  Pore-morphology-based simulation of drainage in totally wetting porous media , 2001 .

[7]  Alan Cottenden,et al.  Infiltration into inclined fibrous sheets , 2005, Journal of Fluid Mechanics.

[8]  Behnam Pourdeyhimi,et al.  Analytical expressions for predicting permeability of bimodal fibrous porous media , 2009 .

[9]  Simon L. Goren,et al.  Model for predicting pressure drop and filtration efficiency in fibrous media , 1968 .

[10]  R. Braddock,et al.  Capillarity in fibrous filter media: Relationship to filter properties , 2007 .

[11]  H. Vahedi Tafreshi,et al.  Modeling fluid spread in thin fibrous sheets: Effects of fiber orientation , 2010 .

[12]  L. A. Richards Capillary conduction of liquids through porous mediums , 1931 .

[13]  Abraham Marmur,et al.  The radial capillary , 1988 .

[14]  Christoph Beckermann,et al.  A two-phase mixture model of liquid-gas flow and heat transfer in capillary porous media—I. Formulation , 1993 .

[15]  H. Vahedi Tafreshi,et al.  Influence of fiber orientation on the transverse permeability of fibrous media , 2009 .

[16]  Behnam Pourdeyhimi,et al.  A realistic modeling of fluid infiltration in thin fibrous sheets , 2009 .

[17]  Karsten E. Thompson,et al.  Pore-scale modeling of fluid transport in disordered fibrous materials , 2002 .

[18]  Van Genuchten,et al.  A closed-form equation for predicting the hydraulic conductivity of unsaturated soils , 1980 .

[19]  Anne Perwuelz,et al.  Wetting behavior of thermally bonded polyester nonwoven fabrics: The importance of porosity , 2006 .

[20]  A novel nozzle design for producing hydroentangled nonwoven materials with minimum jet-mark defects , 2007 .

[21]  Randy D. Hazlett,et al.  Simulation of capillary-dominated displacements in microtomographic images of reservoir rocks , 1995 .

[22]  F. Dullien Porous Media: Fluid Transport and Pore Structure , 1979 .

[23]  James H. Adair,et al.  An electrophoretic mobility study of uric acid with special reference to kidney stone formation , 1988 .

[24]  D. F. James,et al.  The permeability of fibrous porous media , 1986 .

[25]  M Kataja,et al.  Simulation of liquid penetration in paper. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[26]  Randel Haverkamp,et al.  A Comparison of Numerical Simulation Models For One-Dimensional Infiltration1 , 1977 .

[27]  Ningtao Mao,et al.  Capillary pressure and liquid wicking in three-dimensional nonwoven materials , 2008 .

[28]  H. Tafreshi,et al.  Simulating and Characterizing Water Flows Inside Hydroentangling Orifices , 2003 .

[29]  D. V. Parikh,et al.  Computer Simulation of 3-D Liquid Transport in Fibrous Materials , 2004, Simul..

[30]  H. Tafreshi,et al.  General capillary pressure and relative permeability expressions for through-plane fluid transport in thin fibrous sheets , 2009 .

[31]  Ning Pan,et al.  Computer Simulation of Liquid Wetting Dynamics in Fiber Structures Using the Ising Model , 1997 .

[32]  S. A. Hosseini,et al.  Modeling permeability of 3-D nanofiber media in slip flow regime , 2010 .

[33]  Chaoyang Wang,et al.  Modeling of Two-Phase Behavior in the Gas Diffusion Medium of PEFCs via Full Morphology Approach , 2007 .

[34]  B. Pourdeyhimi,et al.  A Case Study of Realistic Two-Scale Modeling of Water Permeability in Fibrous Media , 2008 .

[35]  H. Tafreshi,et al.  A two-scale modeling of motion-induced fluid release from thin fibrous porous media , 2009 .