numerical heat transfernht.xjtu.edu.cn/nht_chapter_13_a_2_2020.pdfnumerical heat transfer chapter 13...
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![Page 1: Numerical Heat Transfernht.xjtu.edu.cn/NHT_Chapter_13_A_2_2020.pdfNumerical Heat Transfer Chapter 13 Application examples of fluent for flow and heat transfer problem 1/76 多孔介质流动换热问题](https://reader036.vdocuments.site/reader036/viewer/2022071501/6120cb580d7da15939223f37/html5/thumbnails/1.jpg)
Instructor Chen, Li; Tao, Wen-Quan
CFD-NHT-EHT Center
Key Laboratory of Thermo-Fluid Science & Engineering
Xi’an Jiaotong University
Xi’an, 2020-Dec.-21
Numerical Heat Transfer
Chapter 13 Application examples of fluent for flow and heat transfer problem
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多孔介质流动换热问题
13. 2 Flow and heat transfer in porous media
Focus: in this example, first the background of porous
media is introduced, and then governing equations for
fluid flow and heat transfer in porous media are
discussed in detail.
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13. 2 Flow and heat transfer in porous media
Known:Steady state fluid flow and heat transfer of
air in a channel filled with porous medium made of
Aluminum (铝). The porosity (孔隙率) of the porous
medium is 0.8. The permeability (渗透率) of the
porous medium is 7.E-8 m2. The computational domain
is shown in Fig. 2. The boundary condition is as follows.
Inlet: u---5m/s ; T---300K
Pressure outlet: Gauge pressure(表压): 0 Pa.
Top and bottom boundary: 2rd boundary condition
Heat flux: q=10000 W/m23/76
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Fig. 2 Computational domain
Inlet:
u=5m/s
T=300K
Outlet:
Pressure
outlet
q=10000 W/m2
Porous media
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Solution:
Find: Temperature and velocity distribution in the domain.
Continuity, momentum and energy equation for
porous media??
The governing equations for porous media are
different from the original NS equation. Thus, we will
study together background information of porous
media and then derive the governing equations.
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Introduction to Porous media
A porous medium is a material that contains plenty of
pores (孔) between solid skeleton (骨架).
Two necessary elements in a porous medium:
Skeleton : maintaining the shape of a porous medium
Pores: providing pathway for fluid transport.
Black: solid
White: pores
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Porosity (孔隙率)
ε =𝑉pore
𝑉total
The volume ratio between pore volume and total volume
Pore size (孔径分布)
The size of pores. Use pore
size distribution (PSD) to
character (表征)size of
pores in a porous medium.
In the range of 0~1.
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Structure Characterization (结构表征)
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Two velocity definition in a porous medium:
superficial physicalv v
Vphysical(真实速度): the actual flow velocity in the
pores.
𝑣physical
Vsuperficial(表观速度):the averaged velocity in the
entire domain.Vsuperficial < Vphysical
Porosity
Fluent uses superficial velocity as the default velocity. 12/76
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Mass conservation equation for porous media:
2(( )( p
t
u)u u) u
Original continuity and momentum equation
( 0t
u)
physical
( )( 0
t
u )
As the total mass of fluid is Vf = Vtotal = ∆x∆y∆z
Fluent uses superficial velocity as the default velocity.
superficial
( )( 0
t
)u
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Momentum conservation equation for porous media:
physical 2
physical physical physical
(( )( ( )p
t
u )u u u F)
superficial superficial superficial
superficial
2(
( )( ( ) ( )pt
u)u F
u u)
For incompressible steady state problem:
superficial 0 u
superficial
superficial superficia
2
l
1( )( ( ) ( )p )u u Fu
Force due to porous media
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upVf = upVtotal = up∆x∆y∆z
2(( )( p
t
u)u u) u
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The fluid-solid interaction is strong in porous media.
Porous media are modeled by adding a momentum
source term:
superficial superficial superficial- - | |F
k k
u u uF
The first term is the viscous loss term (黏性项)or the
Darcy term.
The second term is inertial loss term (惯性项)or the
Forchheimer term.
k is the permeability (渗透率) of a porous media, one
of the most important parameter of a porous medium.15/76
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Permeability (渗透率)
In 1856, Darcy (法国工程师) noted that for laminar
flow through porous media, the flow rate <u> is linearly
proportional to the applied pressure gradient Δp, thus
he introduced permeability to describe the conductivity
of the porous media. The Darcy’ law is as follows
k pu
µ l
Δp
𝜇u
k is permeability with unit of
m216/76
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In Fluent, this force source term is expressed as
2
1- -C | |
2kF u u u
k: permeability; C2: inertial resistance factor (惯性阻力)
Permeability is a transport property of a porous
medium, and there are database of k for different
porous materials. 18/76
Here, viscous resistance(黏性阻力) is 1/k!
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2
1C |-
2- |
kF uu u
The second term can be canceled if the fluid flow is slow
u is small, <<1, thus u*u is smaller.
Otherwise, this term should be considered.
There have been lots of experiments in the literature to
determine the relationship between pressure drop and
velocity of different kinds of porous media, and thus to
determine permeability. 19/76
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2
2
2 3 3
1 1Δ 150 1.75
p p
Pu u
l D D
2
1C |-
2- |
kF uu u
Ergun equation is one of the most adopted empirical
equations (经验公式) for packed bed porous media.
Comparing the two equations, you can obtain k and C2.
2 3
13.5
p
CD
2 3
2150 1
pDk
Diameter of solid particle
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Energy equation
2(
( )(p
p
C TC T
t
)u ) T + S
For porous media:
Heat transfer in fluid phase as well as in solid phase.
There are two models for heat transfer:
Equilibrium thermal model (热平衡模型)
Non-Equilibrium thermal model (非热平衡模型) 21/76
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Equilibrium thermal model (热平衡模型)
Assume solid phase and fluid phase are in thermal
equilibrium. In other words, the temperature of fluid
and solid in a mesh is the same.
(( )( ( )
p
p
C TC T T S
t
)u ) +
solid solid fluid fluid
solid fluid
(1 ) ( ) ( )
(1 )( ) ( )
p p p
p p
C TV V C T V C T
C C VT
Original
For the first term :
solid fluid(1 )( ) ( )p p pC T C C T 22/76
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For the second convection term:
( )( pC Tu )
As convective term is only for fluid phase!
For the diffusion term:
eff
( ) ( ) (1 ) ( )
( (1 ) ) ( )
( (1 ) )
( )
s s f f
s f
s f
T V T V T V
T V T V
V T T
V T
2 2(1 ) s fT T
For the source term
(1 )V s fSV S VS 23/76
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solid fluid
2
(( )
(1 )( ) ( )
(1 )
(
(1 )
p p
s f s f
p
TC T
C
t
S ST
C
)u )
+
eff solid fluid( ) (1 )( ) ( )p p pC C C
eff (1 ) s f eff (1 ) s fS S S
eff
superficial eff
2
eff
(( )(
( )u
p
p
TC
CST T
t
)) +
The final energy equation for porous media
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No equilibrium thermal model (非平衡热模型)
Solid phase and fluid phase are not in thermal
equilibrium. The energy equation are solved for fluid
and solid region respectively. At the fluid-solid phase,
they are coupled by convective boundary condition.
fluid
2
(( )
((
)
)
(
f
p f
f sf f
p
f
TC T
t
T S T
C
hA T
)u )
+
Fluid region
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Solid region
i 2sol d(1 )( )
(1(
( )) (1 )p
s s f s
TT hA T T
t
CS
)
+
TfTs
Two equations are solved separately, and 3rd boundary
condition is adopted to couple the two equations.26/76
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Start the Fluent software
1. Choose 2-Dimension
2. Choose display options
3. Choose Serial
processing option
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Step 1: Read and check the mesh
Read the mesh and check the quality and topological
information of the mesh.
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Step 2: Scale the domain size
The mesh is generated in ICEM using unit of mm. Fluent
import it as unit of m. Thus, “Convert units” is used.29/76
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Step 4: Define the material
Define the materials and their properties required for
modeling!
In Fluent, the default fluid is air and the default solid is
Al. They are the materials we will use in Example A2.
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Step 5: Define zone condition
There are two options in
Fluent for zone condition:
Porous media is treated as Fluid in Fluent.
Fluid Solid
Here you can click “Porous zone”
to define the porous media.
Porous zone Then you can define related
porosity and transport
properties. 32/76
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2
1C |-
2- |
kF uu u
2
2 3
1Δ 180
p
Pu
l D
2 3
2180 1
pDk
2 0C
KC equation is adopted, another equation obtained
from experiments
Dp=1mm =0.8
k=7.11E-8, 1/k=1.4E7 C2=034/76
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For pressure outlet boundary condition, Fluent asks you
to input the Backflow Total Temperature. However, it
will play a role only if there is backflow. There is no
information provided by Fluent Help File about what is
the actual boundary condition for heat transfer.
Backflow Total Temperature
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For algorithm and schemes, keep it as default. For more
details of this step, one can refer to Example A1 of
Chapter 13.
7st step: Define the solution
Algorithm: simple
Gradient: Least Square Cell Based
Pressure: second order
Momentum: second order upwind
Energy: second order Upwind
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7st step: Define the solution
For under-relaxation factor, keep it default. For more
details, refer to Example A1.
8st step: Initialization
Use the standard initialization, for more details of
Hybrid initialization, refer to Example A1.
Step 9: Run the simulation
Step 10: Post-processing results
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2: Operating the Fluent software to simulate the
example and post-process the results. (运行软件)
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