chapter 3 exact one-dimensional solutions 3.1 introduction temperature solution depends on velocity...
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CHAPTER 3
EXACT ONE-DIMENSIONAL SOLUTIONS3.1 Introduction Temperature solution depends on velocity
Velocity is governed by non-linear Navier-Stokes eqs.
Exact solution are based on simplifications governing equations
3.2 Simplification of the Governing EquationsSimplifying assumptions:
(1) Laminar flow
(3.1)(2) Parallel streamlines
0v
1
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(3.1) into continuity for 2-D, constant density fluid:
0
xu
, everywhere (3.2)
02
2
x
u(3.3)
(3) Negligible axial variation of temperature
(3.4) is valid under certain conditions. It follows that
(4) Constant properties: velocity and temperature fields are uncoupled (Table 2.1, white box)
02
2
x
T(3.5)
0
xT , everywhere (3.4)
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Basic lawNo. of
Equations Unknowns
Viscosity relation
Conductivity relation)( Tpkk ,
)( Tp,
1
1
T u v w p k
T k
TABLE 2.1
p
v1
3
1
1
T
T
p
p
p
w
wv
u
u
T1 v wu
Continuity
Momentum
Energy
State of Equation
Similar results are obtained for certain rotating flows.
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Fig. 3.2: Shaft rotates inside sleeve
Streamlines are concentric circles
Axisymmetric conditions, no axial variations
3.3 Exact Solutions 3.3.1 Couette Flow Flow between parallel plate
Motion due to pressure drop and/or moving plate
Channel is infinitely long
02
2
T
(3.7)
0T
(3.6)
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Example 3.1: Couette Flow with Dissipation
Incompressible fluid
Upper plate at To moves with velocity Uo
Insulate lower plate
Account for dissipation
Laminar flow, no gravity, no pressure drop
Determine temperature distribution (1) Observations Plate sets fluid in motion
No axial variation of flow
Incompressible fluid
Cartesian geometry 5
Very large parallel plates
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(2) Problem Definition. Determine the velocity and temperature distribution
(3) Solution Plan Find flow field, apply continuity and Navier-Stokes
equations
Apply the energy to determine the temperature distribution
(4) Plan Execution(i) Assumptions
Steady state
Laminar flow
Constant properties
Infinite plates
No end effects
Uniform pressure
No gravity 6
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(ii) AnalysisStart with the energy equation
is dissipation
2
2
2
2
2
2
z
T
y
T
x
Tk
zT
wyT
xT
utT
c v
(3.19b)
2
3
2
222
2222
z
w
yx
u
z
u
x
w
y
w
zxy
u
z
w
yx
u
v
vv
v
(3.17)7
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Need u, v and w. Apply continuity and the Navier-Stokes equations Continuity
Constant density
Infinite plates
(a) and (b) into (2.2b)
Integrate (c)
0
zw
yxu
wyx
ut
vv
z (2.2b)
0
zyxt
(a)
0
wzx
(b)
0
yv
(c)
)(xfv (d)8
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)(xf is “constant” of integration
Apply the no-slip condition
(d) and (e) give 0)( xf
Substitute into (d)
Streamlines are parallel
To determine u we apply the Navier-Stokes eqs.
0)0,( xv (e)
0v (f)
2
2
2
2
2
2
z
u
y
u
x
uxp
g
zu
wyu
xu
utu
x
v
(2.10x)
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Simplify:
Steady state
No gravity
Negligible axial pressure variation
(b) and (f)-(i) into (2.10x) gives
Solution to (j) is
Boundary conditions
0
t
u(g)
0xg (h)
0x
p(i)
02
2
dy
ud(j)
21 CyCu (k)
0)0( u oUHu )( and (l)10
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(k) and (I) give
(m) into (k)
Dissipation: (b) and (f) into (2.17)
Use (3.8) into (n)
0/ tTSteady state: Infinite plates at uniform temperature:
02
2
x
TxT
oUC 1 02 C and (m)
H
y
U
u
o (3.8)
2
yu (n)
2
2
H
Uo (o)
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Use above, (b), (f) and (o) into energy (2.10b)
Integrate
B.C.
B.C. and solution (q) give
(s) into (q)
02
2
2
2
H
U
dy
Tdk o (p)
432
2
2
2CyCy
kH
UT o
(q)
0)0(
dy
dTk oTHT )( and (r)
03 Ck
UTC o
o 2
2
4 and (s)
2
2
21
2
1
H
y
k
U
TT
o
o
(3.9)
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Fourier’s law gives heat flux at y = H
dxHdT
kHq)(
)(
(3.9) into the above
(iii) Checking
Dimensional check: Each term in (3.8) and (3.9) is dimensionless. Units of (3.10) is W/m2
Differential equation check: Velocity solution (3.8) satisfies (j) and temperature solution (3.9) satisfies (p)
Boundary conditions check: Solution (3.8) satisfies B.C. (l), temperature solution (3.9) satisfies B.C. (r)
H
UHq o
2
)(
(3.10)
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(ii) Stationary upper plate: no dissipation, uniform temperature To, no surface flux. Set Uo = 0 in (o), (3.9) and
(3.10) gives T(y) = To and ,0 0)( Hq
(iii) Inviscid fluid: no dissipation, uniform temperature To.
Set in (3.9) gives T(y) = To 0
Limiting check: (i) Stationary upper plate: no fluid motion. Set Uo = 0 in (3.8) gives u(y) = 0
(iv) Global conservation of energy: Frictional energy is conducted through moving plate:
W = Friction work by plate )(Hq = Heat conducted through plate
where oUHW )( (t)
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)(H = shearing stress
(3.8) into (u)
(v) and (t)
(w) agrees with (3.10)
(4) Comments Infinite plate is key assumption. This eliminates x as a
variable
Maximum temperature: at y = 0 Set y = 0 in (3.9)
k
UTT o
o 2)0(
2
dy
HduH
)()( (u)
H
UH o )( (v)
HU
W o2 (w)
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Example 3.2: Flow in a Tube at Uniform Surface Temperature
Problems associated with axial flow in channels
Motion due to pressure drop
Channel is infinitely long
3.3.2 Hagen-Poiseuille Flow
Incompressible fluid flows in a long tube
zp / Motion is due to
pressure gradient
Surface temperature To Account for dissipation Assuming axisymmetric laminar flow 16
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Neglecting gravity and end effects Determine:
[a] Temperature distribution
[b] Surface heat flux
oTT )0([c] Nusselt number based on [ ]
(1) Observations Motion is due to pressure drop
Long tube: No axial variation
Incompressible fluid
Heat generation due to dissipation
Dissipated energy is removed by conduction at the surface
Heat flux and heat transfer coefficient depend on temperature distribution
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Temperature distribution depends on the velocity distribution
Cylindrical geometry
(2) Problem Definition.
Determine the velocity and temperature distribution.
(3) Solution Plan
Apply continuity and Navier-Stokes to determine flow field
Apply energy equation to determine temperature distribution
Fourier’s law surface heat flux
Equation (1.10) gives the heat transfer coefficient.
(4) Plan Execution
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(i) Assumptions
Steady state
Laminar flow
Axisymmetric flow
Constant properties
No end effects
Uniform surface temperature
Negligible gravitational effect
(ii) Analysis
[a] Start with energy equation (2.24)
2
2
2
2
2
11
z
TT
rr
Tr
rrk
z
TT
rr
T
t
Tc zrP v
vv
(2.24)
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where
220
2
222
01
01
21
22
rzzrrrr
zrrr
zrzr
zrr
vvvvvvv
vvvv
(2.25)
Need , andrv v zv Flow field: use continuity and Navier-Stokes eqs.
0
zr zrr
rrtvvv
11
(2.4)
Constant
Axisymmetric flow
0
zrt
(a)
0v (b)
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Long tube, no end effects
(a)-(c) into (2.4)
Integrate
)(zf is “constant” of integration. Use the no-slip B.C.
(e) and (f) give
Substitute into (e)
Streamlines are parallel
0z
(c)
0rrdrd
v (d)
)(zfr vr (e)
0),( zrov (f)
0)( zf
0rv (g)
zv Determine : Navier-Stokes eq. in z-direction21
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2
2
2
2
2
11
zrrr
rrzp
g
tzrr
zzzz
zzz
zzr
vvv
vvv
vvv
v
(2.11z)Simplify
Steady state:
No gravity:
(b), (c) and (g)-(i) into (2.11z)
zv depends on r only, rewrite (3.11)
0t
(h)
0 zr gg (i)
01
dr
dr
drd
rzp zv (3.11)
)(1
rgdr
dr
drd
rzp z
v
(j)
22
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Integrate
Apply Navier-Stokes in r-direction
2
2
22
2
2
2
21)(
1
zrrr
rrrr
pg
tzrrr
rrrr
rrz
rrr
vvvv
vvv
vvvvv
(2.11r) (b), (g) and (i) into (2.11r)
Integrate
)(zf = “constant” of integration
oCzrgp )( (k)
0
r
p(l)
)(zfp (m)
Equate two solutions for p: (k) and (m):23
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C = constant. Use (o) into (j)
Integrate
12
2
1Cr
zd
pd
dr
dr z
v
integrate again
zvTwo B.C. on :
)()( zfCzrgp o (n)
g(r) = C (o)
Cdr
dr
drd
rzp z
v1 (p)
212 ln
41
CrCrzdpd
z
v (q)
0)(,0)0(
ozz rdr
dv
v(r)
(q) and (r) give C1and C224
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221 4
1,0 orzd
pdCC
Substitute into (q)
For long tube at uniform temperature:
(b), (c), (g), (h) and (s) into energy (2.24)
(b), (c) and (g) into (2.25) 2
dr
d zv
Substitute velocity solution (3.11) into the above
)(41 22
oz rrzdpd
v (3.12)
02
2
z
T
z
T(s)
01
dr
dTr
dr
d
rk (t)
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(u) in (t) and rearrange
Integrate
Need two B.C.
(v) and (w) give 4
2
43 641
,0 oo rzdpd
kTCC
Substitute into (v)
22
2
1r
zd
pd
(u)
32
41
rzdpd
kdrdT
rdrd
(3.13)
434
2
ln64
1CrCr
zd
pd
kT
(v)
oo TrTanddr
dT )(0)0(
(w)
4
424
164 o
oo
r
r
zd
pd
k
rTT
(3.14a)
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In dimensionless form:
[b] Use Fourier’s
dr
rdTkrq o
o)(
)( (3.14) into above
[c] Nusselt number:
(1.10) gives h
(3.14a) into (y)
4
4
241
64oo
o
r
r
zd
pd
k
r
TT
(3.14b)
23
16)(
zd
pdrrq oo
(3.15)
k
hr
k
hDNu o2
(x)
dr
rdT
TT
kh o
o
)(
])0([ (y)
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(z) into (x)
(iii) Checking
Dimensional check:
Each term in (3.12) has units of velocity
Each term in (3.14a) has units of temperature
Each term in (3.15) has units of W/m2
Differential equation check: Velocity solution (3.12) satisfies (p) and temperature solution (3.14) satisfies (3.13)
Boundary conditions check: Velocity solution (3.12) satisfies B.C. (r) and temperature solution (3.14) satisfies B.C. (w)
Limiting check:
or
kh
2 (z)
4Nu (3.16)
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(i) Uniform pressure ( ): No fluid motion. Set in (3.12) gives
0/ dzdp0/ dzdp 0zv
(ii) Uniform pressure ( ): No fluid motion, no dissipation, no surface flux. Set in (3.15) gives0/ dzdp
0/ dzdp
0)( orq
(iii) Global conservation of energy:
work Pump tube leavingHeat
Pump work W for a tube of length L
1p = upstream pressure
2p = downstream pressure
= flow rate
(z-1)
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(3.12) into the above, integrate
(z-1) and (z-2)
W Work per unit area
Lr
WW
o2
(z-3) into the above
However dz
dp
L
pp
)( 21
Combine with (z-4) 23
16
dz
dprW o
(z-2)
)(8 21
4
ppdz
dprW o
(z-3)
L
pp
dz
dprW o )(
1621
3
(z-4)
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This agrees with (3.15)
(5) Comments Key simplification: long tube with end effects. This is
same as assuming parallel streamlines
According to (3.14), maximum temperature is at center r = 0
The Nusselt number is constant independent of Reynolds and Prandtl numbers
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3.3.3 Rotating Flow Example 3.3: Lubrication Oil Temperature
in Rotating Shaft
Lubrication oil between shaft and housing
Angular velocity is
Assuming laminar flow
Account for dissipation
Determine the maximum temperature rise in oil
(1) Observations Fluid motion is due to shaft rotation
Housing is stationary32
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No axial variation in velocity and temperature
No variation with angular position Constant
Frictional heat is removed at housing
No heat is conducted through shaft
Maximum temperature at shaft
Cylindrical geometry
(2) Problem Definition.
Determine the velocity and temperature distribution of oil
(3) Solution Plan Apply continuity and Navier-Stokes eqs. to determine flow
field
Use energy equation to determine temperature field
Fourier’s law at the housing gives frictional heat33
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(4) Plan Execution(i) Assumptions
Steady state Laminar flow Axisymmetric flow Constant properties No end effects Uniform surface temperature Negligible gravitational effect(ii) Analysis Energy equation governs temperature
2
2
2
2
2
11
z
TT
rr
Tr
rrk
z
TT
rr
T
t
Tc zrP v
vv
(2.24)
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where
220
2
222
01
01
21
22
rzzrrrr
zrrr
zrzr
zrr
vvvvvvv
vvvv
(2.25)
Need flow field , and rv v zv
Apply continuity and Navier-Stokes to determine flow field
0
zr zrr
rrtvvv
11
(2.4)
Constant
Axisymmetric flow
0
zrt
(a)
(b)0 35
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Long shaft:
(a)-(c) into (2.4)
Integrate
0rrdrd
v (d)
(c)0zzv
(e)Cr rv
Apply B.C. to determine C
(e) and (f) give C = 0
Use (e)
Streamlines are concentric circles
vApply the Navier-Stokes to determine
0)( or rv (f)
0rv (g)
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2
2
22
2
2
21)(
11
zrrr
rrr
p
rg
tzrrr
r
zr
r
vvvv
vvv
vvvvvv
(2.11 )For steady state:
0t
(h)
Neglect gravity, use (b),(c), (g), (h) into (2.11 )
Integrate
B.C. are
0)(1
vrdrd
rdrd
(3.17)
rC
rC 21
2v (i)
ii rr )(v 0)( orv (j)
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1C 2C(j) gives and
(k) into (i)
Simplify energy equation (2.24) and dissipation function (2.25). Use(b), (c), (g), (h)
and 2
rdr
d vv
(3.18) into above
22
2
12
io
i
rr
rC
22
22
2io
oi
rr
rrC
(k)
1)/(
)/()/()/()(2
2
io
iiio
i rr
rrrrrr
r
r
v (3.18)
01
dr
dTr
dr
d
rk (l)
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Combine (m) and (l)
Integrate(3.19) twice
Need two B.C.
3C 4C(n) and (o) give and
2
2
2
2
31
)/(1
2
2 ioi
i
rrr
r
kC
4
2
2
2 1
)/(1
2
rrr
r
oi
i
(m)
3
2
2
2 1
)/(1
2
rrr
r
kdrdT
rdrd
oi
i
(3.19)
432
2
2
2
ln1
)/(1
2
4)( CrC
rrr
r
krT
oi
i
(n)
0)(
dr
rdT ioo TrT )( and (o)
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o
iooi
io r
rrrr
r
kTC ln
21
)/(1
2
4 22
2
2
2
4
Substitute into (o)
or
Maximum temperature at irr
)( orqUse Fourier’s law to determine frictional energy per unit length
)/ln(2)/()/()/(1
2
4)( 22
2
2rrrrrr
rr
r
kTrT oioi
oi
io
(3.20a)
)/ln(2)/()/(
)/(1
2
4
)( 222
2
rrrrrr
rr
r
k
TrToioi
oi
i
o
(3.20b)
)/ln(2)/(1)/(1
2
4)( 2
2
2 iooioi
ioi rrrr
rr
r
kTrT
(3.21)
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drrdT
krrq ooo
)(2)(
(3.20a) in above
(iii) Checking
Each term in solutions (3.18) and (3.20b) is dimensionless
Equation (p) has the correct units of W/mDifferential equation check:
Velocity solution (3.18) satisfies (3.17) and temperature solution (3.20) satisfies (3.19)
Boundary conditions check:
Velocity solution (3.18) satisfies B.C. (j) and temperature solution (3.20) satisfies B.C. (o)
2
2
)/(1
)(4)(
oi
io
rr
rrq
(3.22)
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Limiting check: Stationary shaft: No fluid motion. Set in (3.18) gives0
0v Stationary shaft: No dissipation, no heat loss Set in
(3.22) gives0
0)( orq
Global conservation of energy:
workshaft housing leavingHeat
Shaft work per unit length
)( ir = shearing stress
(3.18) into the above
iii rrrW )(2 (p)
irri rdr
dr
vv
)( (q)
1)/(
)/(2)(
2
2
io
iioi
rr
rrrr
(r)
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Combining (p) and (r)
This is identical to surface heat transfer (3.22)
(5) Comments The key simplifying assumption is axisymmetry
Temperature rise due to frictional heat increase as the clearance s decreased
)/( oi rr Single governing parameter:
2
2
)/(1
)(4
oi
i
rr
rW
(s)
43