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A Finite Element Model for Hydro-thermal Convective Flow in a Porous Medium: Effects of Hydraulic Resistivity and Thermal Diffusivity (2402.15917v1)

Published 24 Feb 2024 in math.NA and cs.NA

Abstract: In this article, a finite element model is implemented to analyze hydro-thermal convective flow in a porous medium. The mathematical model encompasses Darcy's law for incompressible fluid behavior, which is coupled with a convection-diffusion-type energy equation to characterize the temperature in the porous medium. The current investigation presents an efficient, stable, and accurate finite element discretization for the hydro-thermal convective flow model. The well-posedness of the proposed discrete Galerkin finite element formulation is guaranteed due to the decoupling property and the linearity of the numerical method. Computational experiments confirm the optimal convergence rates for a manufactured solution. Several numerical results are obtained for the variations of the hydraulic resistivity and thermal diffusivity. In the present study, the bottom wall is maintained at a constant higher hot temperature while side vertical walls are thermally insulated and the top wall is maintained at a constant cold temperature. Heat transfer rates at the heated bottom wall are presented in terms of local Nusselt number. A linear variation in hydraulic resistivity and a quadratic variation in thermal diffusivity show an increase in the heat transfer rate.

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References (48)
  1. Numerical investigation of natural convection in a rectangular enclosure due to partial heating and cooling at vertical walls. Communications in Nonlinear Science and Numerical Simulation, 17(6):2403–2414, 2012.
  2. The deal.II library, version 9.2. Journal of Numerical Mathematics, 2020.
  3. Effects of thermal boundary conditions on natural convection flows within a square cavity. International Journal of Heat and Mass Transfer, 49(23-24):4525–4535, 2006.
  4. Finite element study of nonlinear two-dimensional deoxygenated biomagnetic micropolar flow. Communications in Nonlinear Science and Numerical Simulation, 15(5):1210–1223, 2010.
  5. D. Bhatta and D. Riahi. Convective flow in an aquifer layer. Fluids, 2(4):52, 2017.
  6. D. Bhatta and D. N. Riahi. Thermal diffusivity variation effect on a hybrid-thermal convective flow in a porous medium. Journal of Porous Media, 23(5), 2020.
  7. Mixed discontinuous Galerkin methods for Darcy flow. Journal of Scientific Computing, 22(1-3):119–145, 2005.
  8. S. Chandrasekhar. Hydrodynamic and Hydromagnetic Stability. Dover, New York, 1981.
  9. P. G Ciarlet. The Finite Element Method for Elliptic Problems. SIAM, 2002.
  10. A. Çıbık and S. Kaya. A projection-based stabilized finite element method for steady-state natural convection problem. Journal of Mathematical Analysis and Applications, 381(2):469–484, 2011.
  11. Unconditionally stable mixed finite element methods for Darcy flow. Computer Methods in Applied Mechanics and Engineering, 197(17-18):1525–1540, 2008.
  12. T. A. Davis. Algorithm 832: UMFPACK V4. 3—an unsymmetric-pattern multifrontal method. ACM Transactions on Mathematical Software (TOMS), 30(2):196–199, 2004.
  13. T. A. Davis. Direct Methods for Sparse Linear Systems. SIAM, 2006.
  14. H. N. El Dine and M. Saad. Analysis of a finite volume–finite element method for Darcy–Brinkman two-phase flows in porous media. Journal of Computational and Applied Mathematics, 337:51–72, 2018.
  15. Numerical simulation of mode-III fracture incorporating interfacial mechanics. International Journal of Fracture, 192(1):47–56, 2015.
  16. Mathematical Models in the Applied Sciences, volume 17. Cambridge University Press, 1997.
  17. A. V. Getling. Rayleigh-Bénard Convection: Structures and Dynamics, volume 11. World Scientific, 1998.
  18. V. Girault and P.-A. Raviart. Finite Element Methods for Navier-Stokes Equations: Theory and Algorithms, volume 5. Springer Science & Business Media, 2012.
  19. Numerical simulation of two-dimensional Rayleigh-Bènard convection. In AIP Conference Proceedings, volume 1907, page 030031. AIP Publishing LLC, 2017.
  20. A numerical study of natural convection in a horizontal porous layer subjected to an end-to-end temperature difference. ASME journal of heat transfer, 1981.
  21. Convective instabilities in porous media with through flow. AIChE Journal, 22(1):168–174, 1976.
  22. Convection currents in a porous medium. Journal of Applied Physics, 16(6):367–370, 1945.
  23. E. L. Koschmieder. Bénard Cells and Taylor Vortices. Cambridge University Press, 1993.
  24. G. Kosec and B. Sarler. Local RBF collocation method for Darcy flow. Computer Modeling in Engineering and Sciences, 25(3):197, 2008.
  25. O. A. Ladyzhenskaya. The Mathematical Theory of Viscous Incompressible Flow, volume 2. Gordon and Breach New York, 1969.
  26. E. R. Lapwood. Convection of a fluid in a porous medium. In Mathematical Proceedings of the Cambridge Philosophical Society, volume 44, pages 508–521. Cambridge University Press, 1948.
  27. Finite element simulation of quasi-static tensile fracture in nonlinear strain-limiting solids with the phase-field approach. Journal of Computational and Applied Mathematics, 399:113715, 2022.
  28. M. T. Manzari. An explicit finite element algorithm for convection heat transfer problems. International Journal of Numerical Methods for Heat & Fluid Flow, pages 860–877, 1999.
  29. A. Masud and T. J. R. Hughes. A stabilized mixed finite element method for Darcy flow. Computer methods in applied mechanics and engineering, 191(39-40):4341–4370, 2002.
  30. A finite volume method for numerical simulations of adiabatic shear bands formation. Communications in Nonlinear Science and Numerical Simulation, 101:105858, 2021.
  31. D. A. Nield. The onset of transient convective instability. Journal of Fluid Mechanics, 71(3):441–454, 1975.
  32. D. A. Nield and A. Bejan. Convection in Porous Media, volume 3. Springer, 2006.
  33. J. T. Oden and L. Demkowicz. hp adaptive finite element methods in computational fluid dynamics. Computer Methods in Applied Mechanics and Engineering, 89(1-3):11–40, 1991.
  34. S. Ostrach. Natural convection in enclosures. ASME Journal of Heat Transfer, 110:1175–1190, 1988.
  35. F. Otto and C. Seis. Rayleigh–bénard convection: improved bounds on the nusselt number. Journal of mathematical physics, 52(8):083702, 2011.
  36. J. N. Reddy. Introduction to the Finite Element Method. McGraw-Hill Education, 2019.
  37. The onset of Darcy-Bénard convection in an inclined layer heated from below. Acta Mechanica, 144(1):103–118, 2000.
  38. Effects of nonuniform thermal gradient and adiabatic boundaries on convection in porous media. ASME Journal of Heat Transfer, 102(2):254–260.
  39. Y. Saad. Iterative Methods for Sparse Linear Systems. SIAM, 2003.
  40. The cause and cure (?) of the spurious pressures generated by certain fem solutions of the incompressible navier-stokes equations: Part 1. International Journal for Numerical Methods in Fluids, 1(1):17–43, 1981.
  41. Natural convection in porous media—dual reciprocity boundary element method solution of the Darcy model. International journal for numerical methods in fluids, 33(2):279–312, 2000.
  42. A consistent projection finite element method for the non-stationary incompressible thermally coupled mhd equations. Communications in Nonlinear Science and Numerical Simulation, page 107496, 2023.
  43. Darcy-Bénard convection of newtonian liquids and newtonian nanoliquids in cylindrical enclosures and cylindrical annuli. Physics of Fluids, 31(8):084102, 2019.
  44. K. Walker and G. M. Homsy. A note on convective instabilities in Boussinesq fluids and porous media. ASME Journal of Heat Transfer, 99(2):338–339.
  45. Convection in a porous cavity. Journal of Fluid Mechanics, 87(3):449–474, 1978.
  46. Quasi-static anti-plane shear crack propagation in nonlinear strain-limiting elastic solids using phase-field approach. International Journal of Fracture, pages 1–20, 01 2021.
  47. Preferential stiffness and the crack-tip fields of an elastic porous solid based on the density-dependent moduli model. arXiv preprint arXiv:2212.08181, 2022.
  48. Finite element model for a coupled thermo-mechanical system in nonlinear strain-limiting thermoelastic body. Communications in Nonlinear Science and Numerical Simulation, 108:106262, 2022.
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