A New Mathematical Model for Permeability of Composites
Subject Areas : EngineeringM.M Shahmardan 1 , M Nazari 2 , M Khaksar 3 , M Khatib 4
1 - Department of Mechanical Engineering, Shahrood University of Technology
2 - Department of Mechanical Engineering, Shahrood University of Technology
3 - Department of Mechanical Engineering, Shahrood University of Technology
4 - Department of Mechanical Engineering, Shahrood University of Technology
Keywords: permeability, mathematical model, Elliptical, Composite, Scale analysis,
Abstract :
Study of permeability of Fibrous Composites is important in several natural and industrial processes in mechanical engineering. In this study, a comprehensive mathematical model is presented for calculation of normal permeability of ordered elliptical fibrous media. An innovative scale-analysis technique is employed for determining the normal permeability of elliptical fibrous media. In this technique, the permeability is related to the porosity, elliptical fiber diameters, and tortuosity of the medium. In other word, the normal permeability of the circular fibrous structures, which presented in the literature, is extended to the general case of elliptical fibrous media. The composite material is represented by a “unit cell” which is assumed to be repeated throughout the media. A closed-form relation is obtained for non-dimensional permeability using scale analysis approach. Due to lack of experimental data for permeability of fibrous porous media (composite media), with elliptical cross section, a numerical analysis is also employed. The governing equations are solved numerically in the unit cells using finite volume method. The results obtained by numerical solution are compared with those presented by scale analysis method. The presented relation for normal permeability can suitably cover the case of fibrous media with circular cross section. The results are also compared with those presented in the literature for the case of cylindrical fibers. The developed compact relationships are successfully verified through comparison with the present experimental results and the data reported by others.
[1] Tomadakis M.M., Robertson T., 2005, Viscous permeability of random fiber structures: comparison of electrical and diffusion estimates with experimental and analytical results, Journal of Composite Materials 39:163-188.
[2] Gostick J.T., Fowler M.W., Pritzker M.D, Ioannidis M.A., Behra L.M., 2006, In-Plane and through-plane gas permeability of carbon fiber electrode backing layers, Journal of Power Sources 162:228-238.
[3] Clauge D.S., Philips R. J., 1997, A numerical calculation of the hydraulic permeability of three-dimensional disordered Fibrous media, Physics of Fluids 9 (6):1562-1572.
[4] Kaviani M.,1992, Principles of Heat Transfer in Porous Media, Springer-Verlag.
[5] Astrom B.T., Pipes R. B., Advani S. G., 1992, On flow through aligned fiber beds and its application to composite processing, Journal of Composite Materials 26 (9):1351-1373.
[6] Tamayol A., Bahrami M., 2010, Transverse Permeability of Fibrous Porous Media , ICPM3,Montecatini.
[7] Sullivan R. R., 1942, Specific surface measurements on compact bundles of parallel fibers, Journal of Applied Physics 13:725-730.
[8] Carman P.C., 1937, The determination of the specific surface of powders, Journal of the Society of Chemical Industry 57:225-234.
[9] Sparrow E. M., Loeffler A.L., 1959, Longitudinal laminar flow between cylinders arranged in regular array, AICHE Journal 5:325-330.
[10] Hasimoto H., 1959, On the periodic fundamental solutions of the stokes equations and their application to viscous flow past a cubic array of spheres, Journal of Fluid Mechanics 5:317-328.
[11] Kuwabara S., 1959, The forces experienced by randomly distributed parallel circular cylinders or spheres in a viscous flow at small reynolds numbers, Journal of Physical Society of Japan 14:527-532.
[12] Happel J., Brenner H., 1973, Low Reynolds Number Hydrodynamics, Noordhoff.
[13] Sangani A.S., Acrivos A., 1982, Slow flow past periodic arrays of cylinders with application to heat transfer, International Journal of Multiphase Flow 8:193-206.
[14] Drummond J.E., Tahir M. I., 1984, Laminar viscous flow through regular arrays of parallel solid cylinders, International Journal of Multiphase Flow 10:515-540.
[15] Sangani A.S., Yao C., 1988, Transport processes in random arrays of cylinders: II-viscous flow, Physics of Fluids 31(9):2435-2444.
[16] Van der Westhuizen J., Du Plessis J. P., 1996, An attempt to quantify fiber bed permeability utilizing the phase average navier-stokes equation, Composites A 27:263-269.
[17] Sahraoui M., Kaviani M., 1994, Slip and no-slip boundary condition at interface of porous, plain media, International Journal of Heat Mass Transfer 37:1029-1044.
[18] Hellou M., Martinez J., Yazidi M. E., 2004, Stokes flow through microstructural model of fibrous media, Mechanics Research Communications 31:97-103.
[19] Sobera M. P., Kleijn C. R., 2006, Hydraulic permeability of ordered and disordered single-layer arrays of cylinders, Physical Review E 74:036301-036311.
[20] Jackson G.W., James D.F.,1986, The permeability of fibrous porous media, Canadian Journal of Chemical Engineering 64:364-374.
[21] Tomadakis M.M., Sotirchos S.V., 1993, Transport properties of random arrays of freely overlapping cylinders with various orientation distributions, Journal of Chemical Physics 98:616-626.
[22] Avellaneda M., Torquato S., 1991, Rigorous link between fluid permeability, electrical conductivity, and relaxation times for transport in porous media, Physics of Fluids 11:2529-2540.
[23] Kyan C.P., Wasan D.T., Kinter R.C., 1970, Flow of single-phase fluids through fibrous beds, Industrial Engineering and Chemical Fundamentals 9:596-603.
[24] Bergelin O.P., Brown G.A., Hull H.L., Sullivan F.W., 1950, Heat transfer and fluid friction during viscous flow across banks of tubes: III–a study of tube spacing and tube Ssize, ASME Transactions 72:881-888.
[25] Kirsch A.A., Fuchs N.A., 1967, Studies on fibrous aserosol filters-II pressure drops in systems of parallel cylinders, Annals of Occupational Hygiene 10:23-30.
[26] Sadiq T.A.K., Advani S. G., Parnas R. S., 1995, Experimental investigation of transverse flow through aligned cylinders, International Journal of Multiphase Flow 21(5):755-774.
[27] Khomami B., Moreno L. D., 1997, Stability of viscoelastic flow around periodic arrays of cylinders, Rheologica Acta 36 (4):367-383.
[28] Zhong W. H., Currie I.G., James D. F., 2006, Creeping flow through a model fibrous porous medium, Experiments in Fluids 40:119-126.
[29] Skartsis L., Kardos J.L., 1990, The newtonian permeability and consolidation of oriented carbon fiber beds, Proceedings of American Society of Composites Technical Conference 5:548-556.
[30] Tamayol A., Bahrami M., 2008, Analytical Determination of Viscous Permeability, ASME FED, Jacksonville.
[31] Tamayol A., McGregor F., Bahrami M., 2012, Single phase through-plane permeability of carbon paper gas diffusion layers, Journal of Power Sources 204:94-99.
[32] Nabovati A., Hinebaugh J., Bazylak A., Amon C.H., 2014, Effect of porosity heterogeneity on the permeability and tortuosity of gas diffusion layers in polymer electrolyte membrane fuel cells, Journal of Power Sources 248:83-90.
[33] Nazari M., Salehi A., Khaksar M., 2012, Analytical and numerical calculation of flow permeability in a porous medium with square cross section, Modares Mechanical Engineering 12:21-32.
[34] Clauge D.S., Kandhai B.D., Zhang R., Sloot P.M.A., 2000, Hydraulic permeability of (un)bounded fibrous media using the lattice boltzmann method, Physical Review E 61:616-625.
[35] Bahrami M., Yovanovich M.M., Culham J. R., 2006, Effective thermal conductivity of rough spherical packed beds, International Journal of Heat and Mass Transfer 49:3691-3701.
[36] Tamayol A., Bahrami M., 2008, Numerical investigation of flow in fibrous porous media, ECI International Conference on Heat Transfer and Fluid Flow , Whistler.
[37] Choi M.A., Lee M.H., Chang J., Lee S.J., 1999, Permeability modeling of fibrous media in composite processing, Journal of Non-Newtonian Fluid Mechanics 79:585-598.
[38] White F.M., 1984, Viscous Fluid Flow, McGraw- Hill, New York.
[39] Shen L., Chen Z., 2007, Critical review of the impact of tortuosity on diffusion, Chemical Engineering Science 62: 3748-3755.
[40] Boudreau B.P., 1996, The diffusive tortuosity of fine-grained unlithified sediments, Geometrica et Cosmochimica Acta 60:3139-3142.
[41] Archie G., 1942, The electrical resistivity log as an aid in determining some reservoir characteristics, Transactions of AIME 146:54-62.
[42] Chmielewski C., Jayaraman K., 1992, The effect of polymer extensibility on cross flow of polymer solutions through cylinder arrays, Journal of Rheology 36:1105-1126.