A numerical calculation of the hydraulic permeability of three-dimensional disordered fibrous media

Viscous flow through fibrous media is characterized macroscopically by the Darcy permeability ( K D). The relationship between K D and the microscopic structure of the medium has been the subject of experimental and theoretical investigations. Calculations of K D based on the solution of the hydrodynamic flow at fiber scale exist in literature only for two-dimensional arrays of parallel fibers. We considered a fiber matrix consisting of a three-dimensional periodic array of cylindrical fibers with uniform radius ( r) and length connected in a tetrahedral structure. According to recent ultrastructural studies, this array of fibers can represent a model for the glomerular basement membrane (GBM). The Stokes flow through the periodic array was simulated using a Galerkin finite element method. The dimensionless ratio K* = K D/ r 2 was determined for values of the fractional solid volume (φ) in the range 0.005 ≤ φ ≤ 0.7. We compared our numerical results, summarized by an interpolating formula relating K* to φ, with previous theoretical determinations of hydraulic permeability in fibrous media. We found a good agreement with the Carman-Kozeny equation only for φ > 0.4. Among the other theoretical analysis considered, only that of Spielman and Goren ( Environ. Sci. Technol. 2: 279–287, 1968) gives satisfactory agreement in the whole range of φ considered. These results can be useful to model combined transport of water and macromolecules through the GBM for the estimation of the radius and length of extracellular protein fibrils.

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Development of Permeability Models for Saturated Fluid Flow across Arrays of Fibre Clusters

Advanced Composites Letters ◽

10.1177/096369350201100303 ◽

2002 ◽

Vol 11 (3) ◽

pp. 096369350201100

Author(s):

E.M. Gravel ◽

T.D. Papathanasiou

Keyword(s):

Analytical Models ◽

Dual Porosity ◽

Hydraulic Permeability ◽

Fibrous Media ◽

Fibre Bundles ◽

Hexagonal Packing ◽

Composites Manufacturing ◽

Starting Point ◽

Wide Range ◽

Flow Through

Dual porosity fibrous media are important in a number of applications, ranging from bioreactor design and transport in living systems to composites manufacturing. In the present study we are concerned with the development of predictive models for the hydraulic permeability ( Kp) of various arrays of fibre bundles. For this we carry out extensive computations for viscous flow through arrays of fibre bundles using the Boundary Element Method (BEM) implemented on a multi-processor computer. Up to 350 individual filaments, arranged in square or hexagonal packing within bundles, which are also arranged in square of hexagonal packing, are included in each simulation. These are simple but not trivial models for fibrous preforms used in composites manufacturing – dual porosity systems characterised by different inter- and intra-tow porosities. The way these porosities affect the hydraulic permeability of such media is currently unknown and is elucidated through our simulations. Following numerical solution of the governing equations, ( Kp) is calculated from the computed flowrate through Darcy's law and is expressed as function of the inter- and intra-tow porosities (φ, φt) and of the filament radius ( Rf). Numerical results are also compared to analytical models. The latter form the starting point in the development of a dimensionless correlation for the permeability of such dual porosity media. It is found that the numerically computed permeabilities follow that correlation for a wide range of φ i, φt and Rf.

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FUNDAMENTAL ANALYSIS OF THREE-DIMENSIONAL ‘NEAR FLING’

Journal of Experimental Biology ◽

10.1242/jeb.183.1.217 ◽

1993 ◽

Vol 183 (1) ◽

pp. 217-248 ◽

Cited By ~ 8

Author(s):

S. Sunada ◽

K. Kawachi ◽

I. Watanabe ◽

A. Azuma

Keyword(s):

Numerical Calculation ◽

Hydrodynamic Force ◽

Dynamic Pressure ◽

Three Dimensional ◽

Added Mass ◽

Opening Angle ◽

Rotation Axes ◽

Adequate Accuracy ◽

Series Of Experiments ◽

The Moment

A series of experiments on three-dimensional ‘near fling’ was carried out. Two pairs of plates, rectangular and triangular, were selected, and the distance between the rotation axes of the two plates of each pair was varied. The motion of the plates as well as the forces and the moment were measured, and the interference between the two plates of a pair was studied. In addition, a method of numerical calculation was developed to aid in the understanding of the experimental results. The interference between the two plates of a pair, which acted to increase both the added mass of each plate and the hydrodynamic force due to dynamic pressure, was noted only when the opening angle between the plates was small. The hydrodynamic forces were strongly influenced by separated vortices that occurred during the rotation. A method of numerical calculation, which took into account the effect both of interference between the plates and of separated vortices, was developed to give adequate accuracy in analyzing beating wings in ‘near fling’.

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Numerical Calculation of Three-Dimensional Displacement Effect on Bodies of Revolution

10.21236/ada083296 ◽

1980 ◽

Author(s):

Robert P. Reklis

Keyword(s):

Numerical Calculation ◽

Three Dimensional ◽

Displacement Effect ◽

Bodies Of Revolution

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On the microstructural origin of brain white matter hydraulic permeability

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2105328118 ◽

2021 ◽

Vol 118 (36) ◽

pp. e2105328118

Author(s):

Marco Vidotto ◽

Andrea Bernardini ◽

Marco Trovatelli ◽

Elena De Momi ◽

Daniele Dini

Keyword(s):

White Matter ◽

Corpus Callosum ◽

Drug Transport ◽

Three Dimensional ◽

Principal Component ◽

Hydraulic Permeability ◽

Convection Enhanced Delivery ◽

Brain White Matter ◽

Significant Difference ◽

The Brain

Brain microstructure plays a key role in driving the transport of drug molecules directly administered to the brain tissue, as in Convection-Enhanced Delivery procedures. The proposed research analyzes the hydraulic permeability of two white matter (WM) areas (corpus callosum and fornix) whose three-dimensional microstructure was reconstructed starting from the acquisition of electron microscopy images. We cut the two volumes with 20 equally spaced planes distributed along two perpendicular directions, and, on each plane, we computed the corresponding permeability vector. Then, we considered that the WM structure is mainly composed of elongated and parallel axons, and, using a principal component analysis, we defined two principal directions, parallel and perpendicular, with respect to the axons’ main direction. The latter were used to define a reference frame onto which the permeability vectors were projected to finally obtain the permeability along the parallel and perpendicular directions. The results show a statistically significant difference between parallel and perpendicular permeability, with a ratio of about two in both the WM structures analyzed, thus demonstrating their anisotropic behavior. Moreover, we find a significant difference between permeability in corpus callosum and fornix, which suggests that the WM heterogeneity should also be considered when modeling drug transport in the brain. Our findings, which demonstrate and quantify the anisotropic and heterogeneous character of the WM, represent a fundamental contribution not only for drug-delivery modeling, but also for shedding light on the interstitial transport mechanisms in the extracellular space.

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