Polynomial Filtration Laws for Low Reynolds Number Flows Through Porous Media

In this study, we use the method of homogenization to develop a filtration law in porous media that includes the effects of inertia at finite Reynolds numbers. The result is much different than the empirically observed quadratic Forchheimer equation. First, the correction to Darcy’s law is initially cubic (not quadratic) for isotropic media. This is consistent with several other authors (Mei and Auriault, J Fluid Mech 222:647–663, 1991; Wodié and Levy, CR Acad Sci Paris t.312:157–161, 1991; Couland et al. J Fluid Mech 190:393–407, 1988; Rojas and Koplik, Phys Rev 58:4776–4782, 1988) who have solved the Navier–Stokes equations analytically and numerically. Second, the resulting filtration model is an infinite series polynomial in velocity, instead of a single corrective term to Darcy’s law. Although the model is only valid up to the local Reynolds number, at the most, of order 1, the findings are important from a fundamental perspective because it shows that the often-used quadratic Forchheimer equation is not a universal law for laminar flow, but rather an empirical one that is useful in a limited range of velocities. Moreover, as stated by Mei and Auriault (J Fluid Mech 222:647–663, 1991) and Barree and Conway (SPE Annual technical conference and exhibition, 2004), even if the quadratic model were valid at moderate Reynolds numbers in the laminar flow regime, then the permeability extrapolated on a Forchheimer plot would not be the intrinsic Darcy permeability. A major contribution of this study is that the coefficients of the polynomial law can be derived a priori, by solving sequential Stokes problems. In each case, the solution to the Stokes problem is used to calculate a coefficient in the polynomial, and the velocity field is an input of the forcing function, F, to subsequent problems. While numerical solutions must be utilized to compute each coefficient in the polynomial, these problems are much simpler and robust than solving the full Navier–Stokes equations.

[1]  S. Whitaker The Forchheimer equation: A theoretical development , 1996 .

[2]  Grégoire Allaire,et al.  Homogenization of the stokes flow in a connected porous medium , 1989 .

[3]  George H. Fancher,et al.  Flow of Simple Fluids through Porous Materials , 1933 .

[4]  Joel Koplik,et al.  Nonlinear flow in porous media , 1998 .

[5]  Douglas Ruth,et al.  The microscopic analysis of high forchheimer number flow in porous media , 1993 .

[6]  J.-C. Wodie,et al.  Correction non linéaire de la loi de Darcy , 1991 .

[7]  Anthony J. C. Ladd,et al.  The first effects of fluid inertia on flows in ordered and random arrays of spheres , 2001, Journal of Fluid Mechanics.

[8]  Lloyd E. Brownell,et al.  Pressure drop through porous media , 1956 .

[9]  Chiang C. Mei,et al.  The effect of weak inertia on flow through a porous medium , 1991, Journal of Fluid Mechanics.

[10]  A. Mikelić Homogenization theory and applications to filtration through porous media , 2000 .

[11]  Joseph A. Ayoub,et al.  Applicability of the Forchheimer Equation for Non-Darcy Flow in Porous Media , 2008 .

[12]  J. Auriault,et al.  New insights on steady, non-linear flow in porous media , 1999 .

[13]  Discussion of SPE 89325, "Beyond Beta Factors: A Complete Model for Darcy, Forchheimer, and Trans-Forchheimer Flow in Porous Media" , 2005 .

[14]  J. Bear Hydraulics of Groundwater , 1979 .

[15]  J. Auriault,et al.  Nonlinear seepage flow through a rigid porous medium , 1994 .

[16]  Reply to Discussion of "Beyond Beta Factors: A Complete Model for Darcy, Forchheimer, and Trans-Forchheimer Flow in Porous Media" , 2005 .

[17]  William G. Gray,et al.  High velocity flow in porous media , 1987 .

[18]  Zhangxin Chen,et al.  Derivation of the Forchheimer Law via Homogenization , 2001 .

[19]  W. R. Schowalter,et al.  Flow through tubes with sinusoidal axial variations in diameter , 1979 .

[20]  D. Ruth,et al.  Numerical analysis of viscous, incompressible flow in a diverging-converging RUC , 1993 .

[21]  Pinhas Z. Bar-Yoseph,et al.  The influence of Reynolds number upon the apparent permeability of spatially periodic arrays of cylinders , 1990 .

[22]  Alain Bourgeat,et al.  WEAK NONLINEAR CORRECTIONS FOR DARCY’S LAW , 1996 .

[23]  A. Mikelić On the justification of the Reynolds equation, describing isentropic compressible flows through a tiny pore , 2007 .

[24]  Douglas Ruth,et al.  On the derivation of the Forchheimer equation by means of the averaging theorem , 1992 .

[25]  Jacques-Louis Lions,et al.  Some Methods in the Mathematical Analysis of Systems and Their Control , 1981 .

[26]  J. Lions On Some Problems Connected with Navier Stokes Equations , 1978 .

[27]  H. Eugene Stanley,et al.  Physics of the cigarette filter: fluid flow through structures with randomly-placed obstacles , 2001 .

[28]  Julio A. Deiber,et al.  FLOW OF NEWTONIAN FLUIDS THROUGH SINUSOID ALLY CONSTRICTED TUBES. NUMERICAL AND EXPERIMENTAL RESULTS , 1992 .

[29]  Andro Mikelić,et al.  The derivation of a nonlinear filtration law including the inertia effects via homogenization , 2000 .

[30]  Jean-Luc Guermond,et al.  Nonlinear corrections to Darcy's law at low Reynolds numbers , 1997, Journal of Fluid Mechanics.

[31]  Hydrodynamics in Porous Media , 1963 .

[32]  M. W. Conway,et al.  Beyond Beta Factors: A Complete Model for Darcy, Forchheimer, and Trans-Forchheimer Flow in Porous Media , 2004 .

[33]  A. Bourgeat,et al.  NONLINEAR EFFECTS FOR FLOW IN PERIODICALLY CONSTRICTED CHANNEL CAUSED BY HIGH INJECTION RATE , 1998 .

[34]  O. Coulaud,et al.  Numerical modelling of nonlinear effects in laminar flow through a porous medium , 1988, Journal of Fluid Mechanics.

[35]  V. Cvetkovic A continuum approach to high velocity flow in a porous medium , 1986 .

[36]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[37]  E. S. Palencia Non-Homogeneous Media and Vibration Theory , 1980 .