LINEAR STABILITY ANALYSIS AND CFD SIMULATION OF DOUBLE-LAYER RAYLEIGH-BÉNARD CONVECTION

Selected papers from the 20th Brazilian Congress of Chemical Engineering (COBEQ-2014) • Braz. J. Chem. Eng. 33 (3) • Jul-Sep 2016 • https://doi.org/10.1590/0104-6632.20160333s20150050 copy

LINEAR STABILITY ANALYSIS AND CFD SIMULATION OF DOUBLE-LAYER RAYLEIGH-BÉNARD CONVECTION

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

Natural convection in superimposed layers of fluids heated from below is commonly observed in many industrial and natural situations, such as crystal growth, co-extrusion processes and atmospheric flow. The stability analysis of this system reveals a complex dynamic behavior, including the potential multiplicity of stationary states and occurrence of periodic regimes. In this study, a linear stability analysis (LSA) was performed to determine the onset of natural convection as a function of imposed boundary conditions, geometrical configuration and specific perturbations. To investigate the effects of the non-linear terms neglected in LSA, a direct simulation of the full nonlinear problem was performed using computational fluid dynamics (CFD) techniques. The numerical simulation results show an excellent agreement with the LSA results near the onset of convection and an increase in the deviation as the Rayleigh number increases above the critical value.

Keywords
Hydrodynamic Stability; Natural Convection; Multiphase Flow

Authorship

É. Fontana ^**E-mail: eliton.fontana@ufsc.br^**To whom correspondence should be addressed

Universidade Federal de Santa Catarina, Departamento de Engenharia Química e de Alimentos, 88040-970, Florianópolis - SC, Brazil. Phone/Fax: (55) (48) 3721 3375. E-mail: antonio.augusto.souza@ufsc.br; selene.souza@ufsc.br Universidade Federal de Santa CatarinaBrazilFlorianópolis, SC, BrazilUniversidade Federal de Santa Catarina, Departamento de Engenharia Química e de Alimentos, 88040-970, Florianópolis - SC, Brazil. Phone/Fax: (55) (48) 3721 3375. E-mail: antonio.augusto.souza@ufsc.br; selene.souza@ufsc.br

Universidade Federal de Santa Catarina, Campus Blumenau, 89065-300, Blumenau - SC, Brazil.Universidade Federal de Santa CatarinaBrazilBlumenau, SC, BrazilUniversidade Federal de Santa Catarina, Campus Blumenau, 89065-300, Blumenau - SC, Brazil.

E. Mancusi

Università del Sannio, Facoltà di Ingegneria, 82100 Benevento, Italy. E-mail: mancusi.erasmo@gmail.comUniversità del SannioItalyBenevento, ItalyUniversità del Sannio, Facoltà di Ingegneria, 82100 Benevento, Italy. E-mail: mancusi.erasmo@gmail.com

A. A. Ulson De Souza

S. M. A. Guelli U. Souza

*E-mail: eliton.fontana@ufsc.br

*To whom correspondence should be addressed

SCIMAGO INSTITUTIONS RANKINGS

Figures | Tables | Formulas

Figures (6)
Tables (2)
Formulas (20)

Boundary condition	Ra_c	α_c
Rigid - rigid	1707.8	3.117
Rigid - free	1100.7	2.682
Free - free	657.5	2.221

d	Fluid layer thickness (m)
g	Acceleration of gravity (m/s²)
Pr	Prandtl number (–)
Ra	Rayleigh number (–)
Ra_ρ	Density-based Rayleigh number (–)
S	Interfacial tension-based Schmidt number (–)
T	Temperature (K)
T_C	Temperature of the upper wall (cold) (K)
T_H	Temperature of the bottom wall (hot) (K)
T_k	Chebyshev Polynomial of order k (–)
U	Horizontal velocity (m/s)
x	Dimensionless horizontal direction (–)
y	Dimensionless vertical direction (–)
z	Dimensionless transversal direction (–)
*Greek Letters*
α	Perturbation wavenumber in the x direction (–)
β	Perturbation wavenumber in the z direction (–)
β_i	Thermal expansion coefficient of the i-fluid (1/K)
γ	Interfacial tension (N/m)
η	Interface deformation (m)
θ	Perturbation of the temperature (–)
κ	Thermal diffusivity (m²/s)
ν	Kinematic viscosity (m²/s)
ρ	Fluid density (kg/m³)
φ	Perturbation of the vertical velocity (–)
ψ	Static temperature gradient (K)
ω	Wave velocity/eigenvalue (–)
Subscripts
B	Base state
c	Critical value
0	Ratio between upper and lower layer
1	Lower layer
2	Upper layer