A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Onset of instability in Darcy–Forchheimer porous layer with power‐law saturating fluid
AbstractThe paper investigates the effects of the Forchheimer term (form drag) and vertical pressure gradient on the buoyancy‐induced instability of power‐law saturating fluid in a porous plane medium. Two isobaric permeable layers are assumed to sandwich the horizontal porous plane. In the meantime, Dirichlet and Neumann equations are the thermal boundary conditions considered for the lower and upper layers. A base flow developed analytically via the governing equations is just in function of the Péclet number , with no dependence on the characteristic parameter of the power law fluid. A linear stability analysis consists of substituting a base flow with a small perturbation into the governing equations leads to a four‐order eigenvalue problem. An analytical solution is performed for the asymptotic cases of an infinite wavelength. The Runge–Kutta solver is applied together with the shooting technique to evaluate numerical solutions for the general case of nonnegligible wave numbers. Among the findings is the contribution of the Forchheimer term in the variation of the threshold Péclet number whose value can switch the wave numbers from zero to nonzero and increase the stability of the system.
Onset of instability in Darcy–Forchheimer porous layer with power‐law saturating fluid
AbstractThe paper investigates the effects of the Forchheimer term (form drag) and vertical pressure gradient on the buoyancy‐induced instability of power‐law saturating fluid in a porous plane medium. Two isobaric permeable layers are assumed to sandwich the horizontal porous plane. In the meantime, Dirichlet and Neumann equations are the thermal boundary conditions considered for the lower and upper layers. A base flow developed analytically via the governing equations is just in function of the Péclet number , with no dependence on the characteristic parameter of the power law fluid. A linear stability analysis consists of substituting a base flow with a small perturbation into the governing equations leads to a four‐order eigenvalue problem. An analytical solution is performed for the asymptotic cases of an infinite wavelength. The Runge–Kutta solver is applied together with the shooting technique to evaluate numerical solutions for the general case of nonnegligible wave numbers. Among the findings is the contribution of the Forchheimer term in the variation of the threshold Péclet number whose value can switch the wave numbers from zero to nonzero and increase the stability of the system.
Onset of instability in Darcy–Forchheimer porous layer with power‐law saturating fluid
Heat Trans
EL Fakiri, Hanae (author) / Lagziri, Hajar (author) / Lahlaouti, Mohammed Lhassane (author) / Bouardi, Abdelmajid El (author)
Heat Transfer ; 53 ; 1351-1370
2024-05-01
Article (Journal)
Electronic Resource
English
Quantitative evaluation of forchheimer equation for non-darcy flow in porous media
| DOAJ | 2024
Finite Element Method for One-Dimensional Darcy–Brinkman–Forchheimer Fluid Flow Model
| Springer Verlag | 2024
Parallel simulation of wormhole propagation with the Darcy–Brinkman–Forchheimer framework
| Online Contents | 2015