Analysis of entropy generation during natural convection in porous enclosures with curved surfaces

ABSTRACT

The natural convection is analyzed via the entropy generation approach in the differentially heated, porous enclosures with curved (concave or convex) vertical walls. The numerical simulations have been carried out for various fluids (Prandtl number: Pr_m = 0.015, 0.7, and 7.2) at various permeabilities (Darcy numbers: 10⁻⁵ ≤ Da_m ≤ 10⁻²) for a high value of Rayleigh number (Ra_m = 10⁶). The finite element method is employed to solve the governing equations and that is further used to calculate the entropy generation and average Nusselt number. The detailed spatial distributions of S_θ and S_ψ are analyzed for all the wall curvatures. Overall, the case with the highly concave surfaces (case 3) is the optimal case at low Da_m, whereas the cases with the less convex surfaces (cases 1 and 2) are the most efficient cases at high Da_m.

Nomenclature

Be	=	Bejan number
Dam	=	Darcy number
g	=	acceleration due to gravity, m s−2
L	=	height or length of base of the enclosure, m
N	=	total number of nodes
Nu	=	local Nusselt number
	=	average Nusselt number
p	=	pressure, Pa
P	=	dimensionless pressure
Prm	=	Prandtl number
Ram	=	Rayleigh number
S	=	dimensionless entropy generation
Sθ	=	dimensionless entropy generation due to heat transfer
Sψ	=	dimensionless entropy generation due to fluid friction
Stotal	=	dimensionless total entropy generation
T	=	temperature, K
Th	=	temperature of hot left wall, K
Tc	=	temperature of cold right wall, K
u	=	x component of velocity
U	=	x component of dimensionless velocity
v	=	y component of velocity
V	=	y component of dimensionless velocity
x	=	distance along x coordinate
X	=	dimensionless distance along x coordinate
y	=	distance along y coordinate
Y	=	dimensionless distance along y coordinate
Greek symbols	=
α	=	thermal diffusivity, m2 s−1
β	=	volume expansion coefficient, K−1
ϵ	=	medium porosity
γ	=	penalty parameter
θ	=	dimensionless temperature
ν	=	kinematic viscosity, m2 s−1
ρ	=	density, kg m−3
Φ	=	basis functions
ϕ	=	irreversibility distribution ratio
φ	=	angle made by the tangent of curved wall with positive X axis
ψ	=	dimensionless streamfunction
Ω	=	two-dimensional domain
Subscripts	=
eff	=	effective parameter
f	=	fluid
l	=	left wall
r	=	right wall

Nomenclature

Be	=	Bejan number
Dam	=	Darcy number
g	=	acceleration due to gravity, m s−2
L	=	height or length of base of the enclosure, m
N	=	total number of nodes
Nu	=	local Nusselt number
	=	average Nusselt number
p	=	pressure, Pa
P	=	dimensionless pressure
Prm	=	Prandtl number
Ram	=	Rayleigh number
S	=	dimensionless entropy generation
Sθ	=	dimensionless entropy generation due to heat transfer
Sψ	=	dimensionless entropy generation due to fluid friction
Stotal	=	dimensionless total entropy generation
T	=	temperature, K
Th	=	temperature of hot left wall, K
Tc	=	temperature of cold right wall, K
u	=	x component of velocity
U	=	x component of dimensionless velocity
v	=	y component of velocity
V	=	y component of dimensionless velocity
x	=	distance along x coordinate
X	=	dimensionless distance along x coordinate
y	=	distance along y coordinate
Y	=	dimensionless distance along y coordinate
Greek symbols	=
α	=	thermal diffusivity, m2 s−1
β	=	volume expansion coefficient, K−1
ϵ	=	medium porosity
γ	=	penalty parameter
θ	=	dimensionless temperature
ν	=	kinematic viscosity, m2 s−1
ρ	=	density, kg m−3
Φ	=	basis functions
ϕ	=	irreversibility distribution ratio
φ	=	angle made by the tangent of curved wall with positive X axis
ψ	=	dimensionless streamfunction
Ω	=	two-dimensional domain
Subscripts	=
eff	=	effective parameter
f	=	fluid
l	=	left wall
r	=	right wall