Formation of convective roll patterns over a longitudinal throughflow in an active inhomogeneous porous medium with weak clogging
DOI:
https://doi.org/10.7242/1999-6691/2024.17.1.9Keywords:
layered porous medium, adsorption, desorption, weak clogging, oscillatory solutal convection, forced longitudinal throughflow, local and large-scale rolls, linear stability analysis, nonlinear MIM modelAbstract
The convective stability of a plane-parallel longitudinal throughflow in a system consisting of two porous sublayers with distinct permeability is studied taking into account the weak pore clogging effect and given a finite difference in concentration between the upper and lower boundaries of the system. A system of differential equations for convection is derived within the framework of the continuum approach and the nonlinear MIM model. A linear stability analysis of the basic longitudinal flow is carried out. The boundary value problem is solved using the numerical technique for constructing a fundamental system of solutions. The neutral stability curves of the basic flow with respect to the disturbances in the form of rolls with different wavelength are obtained. For the absence of pore clogging, the convective stability maps of the critical solutal Rayleigh-Darcy number versus the permeability ratio for the initial uncontaminated sublayers, as well as the plots of the critical disturbance frequency and wave number versus the permeability ratio for some values of the Peclet number, are constructed. It is shown that these results have symmetry with respect to the solution for equal initial permeability of sublayers. The clogging effect associated with the solute adsorption and desorption in a porous medium is studied in the two-layered systems with the values 0.1 and 10 of the ratio of initial permeabilities of the sublayers; convection localization occurs in distinct sublayers. It was found that clogging increases the stability of the longitudinal basic flow relative to solutal inhomogeneity and breaks the symmetry of solutions with respect to the case when the two-layered system is reduced to a single layer with the same filtration properties of the porous medium throughout its volume. The influence of sorption effects on the critical parameters of oscillatory convection is investigated by plotting the critical solutal Rayleigh-Darcy number, disturbance frequency and wave number against the adsorption coefficient at fixed values of the desorption coefficient. The isolines of the stream function are constructed to analyze convective flow patterns. It was established that there is a weak relationship between the typical size of local convective roll patterns and the clogging parameters. It is shown that the sorption processes, which can lead to clogging, have a significant impact on the velocity of convective rolls moving along the two-layered system at a slight variation in their sizes.
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Gershuni G.Z., Zhukovitskii E.M. Convective Stability of Incompressible Fluids. Keter Publications, Wiley, 1976. 330 p.
Nield D.A., Bejan A. Convection in Porous Media. Switzerland: Springer, 2017. 988 p.
Prats M. The effect of horizontal fluid flow on thermally induced convection currents in porous mediums. Journal of Geophysical Research. 1966. Vol. 71. P. 4835-4838. DOI: 10.1029/JZ071i020p04835.
Yoon D.-Y., Kim D.-S., Choi C.K. Convective instability in packed beds with internal heat sources and throughflow. Korean Journal of Chemical Engineering. 1998. Vol. 15. P. 341-344. DOI: 10.1007/BF02707091.
Maryshev B.S. The Effect of Sorption on Linear Stability for the Solutal Horton-Rogers-Lapwood Problem. Transport in Porous Media. 2015. Vol. 109, no. 3. P. 747-764. DOI: 10.1007/s11242-015-0550-5.
SelimH.M., Amacher M.C. Reactivity and transport of heavy metals in soils. Boca Raton: CRC, 1997. 240 p.
Pang L., Close M., Greenfield H., Stanton G. Adsorption and transport of cadmium and rhodamine WT in pumice sand columns. New Zealand Journal of Marine and Freshwater Research. 2004. Vol. 38. P. 367-378. DOI: 10.1080/00288330.2004.9517244.
Genuchten M.T. van, Wierenga P.J. Mass Transfer Studies in Sorbing Porous Media I. Analytical Solutions. Soil Science Society of America Journal. 1976. Vol. 40, no. 4. P. 473-480. DOI: 10.2136/sssaj1976.03615995004000040011x.
Genuchten M.T. van, Wierenga P.J. Mass Transfer Studies in Sorbing Porous Media: II. Experimental Evaluation with Tritium (3H2O). Soil Science Society of America Journal. 1977. Vol. 41, no. 2. P. 272-278. DOI: 10.2136/sssaj1977 . 03615995004100020022x.
Klimenko L.S., Maryshev B.S. Effect of solute immobilization on the stability problem within the fractional model in the solute analog of the Horton-Rogers-Lapwood problem. The European Physical Journal E. 2017. Vol. 40.104. DOI: 10.1140/epje/i2017-11593-5.
Maryshev B.S., Klimenko L.S. Convective Stability of aNetMass Flow Through a Horizontal Porous Layer with Immobilization and Clogging. Transport in Porous Media. 2021. Vol. 137. P. 667-682. DOI: 10.1007/s11242-021-01582-6.
Maryshev B.S., Klimenko L.S. Solutal convection in a horizontal porous layer with clogging at a high solute concentration. Journal of Physics: Conference Series. 2021. Vol. 1809. 012009. DOI: 10.1088/1742-6596/1809/1/012009.
Khabin M.R., Maryshev B.S. Identification of the parameters of transport through porous media with clogging. Bulletin of Perm University. Physics. 2021. No. 3. P. 44-55. DOI: 10.17072/1994-3598-2021-3-44-55.
Maryshev B.S., Khabin M.R., Evgrafova A.U Identification of transport parameters for the solute filtration through porous media with clogging. Journal of Porous Media. 2023. Vol. 26, no. 6. DOI: 10.1615/JPorMedia.2022044645.
Kolchanova E.A., Kolchanov N.V. Onset of solutal convection in layered sorbing porous media with clogging. International Journal of Heat and Mass Transfer. 2022. Vol. 183. 122110. DOI: 10.1016/j.ijheatmasstransfer.2021.122110.
Chen F., Chen C.F. Onset of Finger Convection in a Horizontal Porous Layer Underlying a Fluid Layer. Journal of Heat Transfer. 1988. Vol. 110, no. 2. P. 403-409. DOI: 10.1115/1.3250499.
Liubimov D.V., Muratov I.D. O konvectivnoj neustojchivosti v sloistoj sisteme [On convective instability of a fluid in a layered system]. Gidrodinamica [Hydrodynamics]. 1977. No. 10. P. 38-46.
Zubova N.A., Lyubimova T.P. Nonlinear convection regimes of a ternary mixture in a two-layer porous medium. Computational Continuum Mechanics. 2021. Vol. 14, no. 1. P. 110-121. DOI: 10.7242/1999-6691/2021.14.1.10.
Guerrero-Martinez F.J., Younger P.L., Karimi N., Kyriakis S. Three-dimensional numerical simulations of free convection in a layered porous enclosure. International Journal of Heat and Mass Transfer. 2017. Vol. 106. P. 1005-1013. DOI: 10.1016/j.ijheatmasstransfer.2016.10.072.
Chang M. -H. Thermal convection in superposed fluid and porous layers subjected to a horizontal plane Couette flow. Physics of Fluids. 2005. Vol. 17. 064106. DOI: 10.1063/1.1932312.
Liu I.-C., Wang H.-H., Umavathi J.C. Poiseuille-Couette Flow and Heat Transfer in an Inclined Channel for Composite Porous Medium. Journal of Mechanics. 2012. Vol. 28, no. 1. P. 171-178. DOI: 10.1017/jmech.2012.18.
Suma S.P., Gangadharaiah Y.H., Indira R., Shivakumara I.S. Throughflow Effects on Penetrative Convection in Superposed Fluid and Porous Layers. Transport in Porous Media. 2012. Vol. 95, no. 1. P. 91-110. DOI: 10.1007/s11242-012-0034-9.
Kolchanova E., Sagitov R. Throughflow Effect on Local and Large-scale Penetrative Convection in Superposed Air-porous Layer with Internal Heat Source Depending on Solid Fraction. Microgravity Science and Technology. 2022. Vol. 34, no. 52. DOI: 10.1007/s12217-022-09971-2.
Carman P.C. Fluid flow through granular beds. Transactions of the Institution of Chemical Engineers. 1997. Vol. 15. S32-S48. DOI: 10.1016/S0263-8762(97)80003-2.
Fand R.M., Kim B.Y.K., Lam A.C.C., Phan R.T. Resistance to the Flow of Fluids Through Simple and Complex Porous Media Whose Matrices Are Composed of Randomly Packed Spheres. Journal of Fluids Engineering. 1987. Vol. 109, no. 3. P. 268-273. DOI: 10.1115/1.3242658.
Lobov N.I., Ljubimov D.V, LjubimovaT.P. Chislennye metody resheniya zadach teorii gidrodinamicheskoj ustojchivosti [Numerical methods for solving problems in the theory of hydrodynamic stability]. Perm: Perm State University, 2004. 101 p.
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