selected literatures introduction about gas-liquid flow in microchannels
DESCRIPTION
Selected literatures introduction about gas-liquid flow in microchannels. Reporter: Zhang Weihua Supervisor: Professor Xin Feng. Contents. Fundamentals. Flow patterns Mixer geometry Pressure drop. Fundamentals. Flow patterns. - PowerPoint PPT PresentationTRANSCRIPT
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Selected literatures introduction about gas-liquid flow in microchannels
Reporter: Zhang WeihuaSupervisor: Professor Xin Feng
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I • Fundamentals
II • Maldistribution
III• Producing droplets
IV• Simulation methods
V• Research orientation and aim
Contents
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Fundamentals
Flow patterns
Mixer geometry
Pressure drop
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Jean-François Manceau et al. New regime of droplet generation in a T-shape microfluidic junction (2013)
Flow patterns
minθ
Fundamentals
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Fundamentals
Mixer geometry
K.D.P. Nigam et al. Slug flowin curved microreactors: Hydrodynamic study (2007)
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Fundamentals
Pressure drop
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J.C.Schouten et al. Pressure drop of gas–liquid Taylor flow in round micro-capillaries for low to intermediate Reynolds numbers (2009)
BrethertonBretherton’s analysis is valid for very small liquid film thickness df and in absence of significant inertial and gravitational forces, i.e. Cab → 0 and
1<</= 21 σuDρWe bhb
And results in:32
67.0= bc
f CaDd
cbb D
σCaP 3
2
)3(16.7=Δ
Aussillous and Quéré:
32
32
34.3+1
67.0=
b
b
c
f
Ca
CaDd
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KreutzerKreutzer et al. consider the liquid flow in the slugs to be a fully developed Hagen–Poiseuille flow
cDUρf
zP 4
)21(=
dd 2
Fanning-
))(+1(16
= b
gl
gl
s
c
gls Ca
ReLD
aRe
f
)+
()dd(=)
dd(
sb
ssc LL
LzP
zP --
)32
)3(16.7+1(
16=
32
bs
bc
gls CaL
CaDRe
f
212
1
)+(Re2=
4))+(
21(=)
dd(
c
lggls
clgss D
UUμfD
UUρfzP-
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Fig. 1 Schematic of Taylor flow showing the definitions of the unit cell, gas bubble length Lb and the liquid slug length Ls. The lengths of the nose Lnose and tail Ltail sections of the gas bubble are also indicated
lgfb
bb UUu
AA
uAA
+=)1(+ -
Mass balance-based Model
fb
bbb
l uAA
δLFAA
U )1(+)+(= -sb
bb LL
uF
+=)(= δLF
AA
U bbb
g -
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)+()+(32
=)+)()+(21
)(4
)(Re16
(=Δ 22
1gl
δLD
UUμδLUUρ
DP b
c
lglblg
cs
)34.3+1()3(16.7
=Δ32
32
bc
bb CaD
CaσP
)34.3+1()3(16.7
+)+()+(32
=Δ+Δ=Δ32
32
2bc
bb
c
lglbsuc CaD
CaσδL
DUUμ
PPP
Accounting for a non-negligible liquid film thickness:
The frictional pressure loss in one liquid slug:
The pressure drop over a unit cell:
))34.3+1)(+)(+(32
)3(16.7+1(
)+()+)(+(32
=
))34.3+1(
)3(16.7+)+(
)+(32(
+1
=+
Δ=)
dd(
32
32
32
32
21
2
bblgl
bc
sbc
bgl
bc
bb
c
lgl
sbsb
uc
CaδLUUμCaDσ
LLDδLUUμ
CaDCaσ
δLD
UUμLLLL
PzP-
The pressure drop over a unit length of channel:
Pressure drop Model
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22
32=
)+()+)(+(32
c
ll
sbc
blgl
DUμ
LLDδLUUμ
bblgl CaAA
UUμσ 1
=)+(
)34.3+
1+32
3×16.7+1(
32=)
dd(
31
32
2bbbb
c
c
ll
CaCaAA
δLD
DUμ
zP-
)34.3+
1+32
3×16.7+1)(
Re16
(=31
32
gl bbbb
cs CaCaA
AδL
Df
l
b
bb UF
AA
δL=
+1
)34.3+
132
3×16.7+1)(
Re16
(=31
32
gl bbl
bcs CaCaU
FDf
)34.3+
132
3×16.7+1(
32=)
dd(
31
32
2bbl
bc
c
l
CaCaUFD
Dμ
zP-
Substituting, then get:
Rewritten by:
And:
For a stagnant liquid film:
Then:
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Experimental:
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Maldistribution
Elevated pressure
Microchannel Network
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MaldistributionElevated pressure
Chen Guangwe et al. Gas-liquid two-phase flow in microchannel at elevated pressure(2013)
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M. Saber,J.M.Commenge. Microreactor numbering-up in multi-scale networks for industrial-scale applications: Impact of flow maldistribution on the reactor performances. (2007)
MaldistributionMicrochannel Network
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1
1
1
=
2=1212 ++2=Δ n
ni
iqRQRQRP ∑
4
128=
m
mm Dπ
LμR
( ))max(
min)max(100=
qqq
Md-
q
qqN
Sd
N
ii
ˆ
)ˆ(1
1
100= 1=
2∑ --
optB
BoptB
CCC
dvˆ
100=-
∑ Nii i
Ni
iA
Bii
A
B
qCC
q
CC
=1=
=
1=0
0
∑ )(=
ˆ
The frictional pressure drop through the two-scale device:
The flow Maldistribution and Standard/Yield deviation defined as:
With:
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Robustness
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11
Δ=*Δ
QRPN
PNormalized pressure drop:
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Microdroplets
T-controlled bubble condensation method
Luo GS et al. Generation of monodispersed microdroplets by temperature controlled bubble condensation processes (2013)
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Figure 2. Main components of the temperature controlled microfluidic system. (a) The mini-evaporator fabricated from a stainless steel pipe (b) The air bath (bottom-up) fabricated with anodized aluminum. A glass window is placed on the metal shell to observe the inside. (c) The capillary embedded coflowing generators (d) The cooling unit with 2 m long cooling pipe.
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Simulation
Fan LS et al. Experiment and lattice Boltzmann simulation of two-phase gas–liquid flows in microchannels (2007)
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))v,(),x((1
=),x()1+,c+x( )( σσeqσi
σiσ
σii
σi nftf
τtftf ---
The simulation was performed on the D2Q9 lattice
),(=),( txftxni
σi
σ ∑
σσ
σσ
ρτ
F+u=v
∑ σσσ
σσσσ
τρ
τρ∑ u=u
The number density and momentum of each component:
),(c=),(u txftxni
σii
σσ ∑The equilibrium value of the velocity:
Where:
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σs
σf
σ F+F=F
),(=),( txfmtxρi
σi
σ
σ ∑∑),(F
21
+),(=),(U),( txtxfcmtxtxρi
σ
i
σii
σ
σ ∑∑∑),(),(
21
+),(=),( 22 txψtxψGctxnctxp σ
σσ
σσσs
σ
σs
∑∑
iiσ
σ iiσσ
σσf ψTGψ c)c+x()x(=F ∑ ∑-
iii i
isσσσ
s sTGψ c)c+x()x(=F ∑ ∑-
The interaction force on component σ:
The macroscopic variables:
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Research OrientationI
Influence of mixing zone geometry on gas-liquid flow pattern and slug formation
II
Novel method to reduce maldistribution or non-uniformity in microreactor numbering-up
III
Experimental and numerical simulation of suitable microdroplet producing method
IV
Explore applicable LBM method to simulate gas-liquid flow in microchannel
V
More …