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Thermal entrance lengths for laminar flow in various ducts for constant surface heat flux
Pergamon Press Printed in the United States
IN HEAT AND MASS TRANSFER Vol. 3, pp. 8 9 - 98, 1976
THERMAL ENTRANCE LENGTHS FOR LAMINAR FLOW IN VARIOUS DUCTS FOR CONSTANT SURFACE HEAT FLUX
Owen T. Hanna, Orville C. Sandall and Bernard A. Paruit Department of Chemical and Nuclear Engineering University of california, Santa Barbara California
(Communicated b y J . P .
93106
HartnettandW.J.
Minkowycz)
ABSTRACT A method for the determination of thermal or diffusion entrance lengths for transport in ducts with a uniform flux is illustrated. The method requires only a knowledge of the asymptotic downstream solution of the transport equation, which is far easier to obtain than the full solution. The results have a simple form and include effects of axial conduction. Geometries considered are parallel planes, concentric annuli and rectangular ducts of varying aspect ratio. Effects of asymmetric boundary conditions and flow development are considered.
Introduction In this paper an analysis is made of the length required for temperature profiles to reach a fully developed shape for the case of laminar flow heat transfer inside ducts having a uniform or specified surface heat flux.
The
method used to compute the thermal entrance length has been presented by Sandall and Hanna
[i] and is based on an overall energy balance over the
total entrance length.
To apply the method one needs to know only the down-
stream velocity and temperature profiles.
These solutions are relatively
easy to obtain for the case of uniform surface heat flux.
The technique is
generally applicable to situations in which the wall heat flux is specified.
89
90
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
The approach given here should be useful primarily in problems where the solution of the energy equation in the entrance region is not available, such as for ducts of peculiar cross section, unsymmetrical boundary conditions, or for the flow of highly viscous, non-Newtonian fluids.
Such an approach might
also be useful for problems involving significant variations of fluid properties.
This method would also seem to have applications for the design of
compact heat exchangers. It must be emphasized that the entrance length technique discussed here is significant because of its broad and simple applicability to complicated cross sections and because of its inclusion of axial conduction.
The exam-
ples given, which correspond to well-known classical results of varying complexity, illustrate these features and indicate comparisons between the present method and classical results. The model used to compute the thermal entrance length may be illustrated with reference to FIG. i.
Fluid is flowing through a duct of arbitrary cross
section, A, having the perimeter, S.
The fluid enters the duct with a uni-
form temperature, T . An overall energy balance for the case of a uniform o wall heat flux is made including a section upstream from the start of heating, since due to axial conduction, the effect of heating propagates upstream. This balance is made over the length - L', the upstream point at which axial conduction effects are no longer felt, to L, the point at which the temperature profile first becomes fully developed.
This gives an expression for the
entrance length. 1 [u(T-T°)]LdA + ~
L = QsPCP ..... AI
AI
[Qa]LdA
(i)
~T The axial heat conduction flux, Qa' is given by Fourier's Law as Qa = - k ( ~ ) L For a uniform wall heat flux the axial temperature gradient becomes constant ~T Qs under fully developed (downstream) conditions and is given as ~ = uu~pCpA" Substitution of these relationships into Equation
(i) and dividing .
by
the equivalent diameter, D e gives L pCp D--= QSD e e
I A
1 [u(T-To)]L dA - --Pe
(2)
Thus it is seen that the effect of axial conduction on the entrance length is given by the term - i/Pe.
Vol. 3, NO. 2
THERMAL~TRANCE
I~%~THS I N ~
91
For the case of heating, the initial temperature must be less than the minimum temperature at the point where the temperature profile first becomes fully developed.
This inequality yields
pCp
_ _
L__ > De -- QSDe Equation
I A
u(T-T )dA m
1 Pe
(3)
(3) represents the basic model from which thermal entrance
lengths are estimated in this paper for laminar flow in various geometries. The integral in Equation
(3) may be expressed in terms of the fully developed
Stanton number and T -T by making the substitution, T-T = (T-Tw) + ( % - T m) w m m ' and noting the definition of the bulk temperature and bulk velocity. L__ > pcp
D
e
-- 4Q
(%-Tm) Ub
1 4St
1 Pe
(4)
Thus if the asymptotic Stanton number is known and if the temperature difference, Tw-T m, is known from a previous calculation, then the thermal entrance length may be simply determined using Equation
(4).
Parallel Planes The physical case considered here is laminar flow between parallel plates as shown in FIG. 2a.
The fluid enters the duct with a uniform temper-
ature, To, and with a fully developed velocity profile; each wall is heated with a uniform heat flux, Q.
The energy equation may be integrated, neglect-
ing viscous dissipation, to give the fully developed temperature distribution, T-T . Substitution of this result into Equation (3) and integrating gives an m expression for the thermal entrance length. L - - > 0.00871Pe D -e Equation
1 Pe
(5)
(5) predicts the interesting result that due to axial conduc-
tion for low Pe, as could occur in the case of liquid metals, or some polymer situations, the thermal entrance length vanishes. The predicted entrance length from Equation calculations of Cess and Schaffer
(5) may be compared to the
[2] which predict that the local Nusselt
number, neglecting axial conduction, has approached to within 5% of its fully developed value in an entrance length given by L/D e = 0.0115 Pe.
92
O.T. Hanna,
O.C.
Sandall
and B.A.
Concentric The case of a concentric and outer b o u n d a r i e s
The general
For the special
minimum this
algebraic
temperature
extremely reason,
grals were
evaluated
equation
to use because
thermal
the solution
of the m i n i m u m
tempera-
case of the outer wall insulated, at the insulated wall, analytically;
however,
r = R 2.
The results
entrance
length
of these
RI/R2,
of RI/R 2 over the complete
range
For is
For this
the inte-
integrations
L/D e is, within
the
the result
of the large number of terms.
they depend only on the p a r a m e t e r
less than 1%, not a function result may be e x p r e s s e d
of
(6)
for the location
common
numerically.
that the dimensionless
Application
heat fluxes on each wall requires
and most
and also because
flux on the inner
1 Pe
(6) may be e v a l u a t e d
inconvenient
heat
2b is now considered.
for heating occurs
case Equation
show
an error of in RI/R 2.
This
as
L__ > 0.0321 Pe - I__ D -Pe e
(7)
Equation
(7) may be compared
Lundberg
et al.
to the thermal
entrance
[3] for uniform wall h e a t i n g
RI/R 2 = 0.5 the exact calculations absence
of axial
2
Annuli
ur (T-T m) dr
case of different
of a n o n - l i n e a r ture.
in FIG.
3, No.
leads to
R 12 R1
L > pCp D--e -- (QIRI+O2R2) _ _ De
Vol.
annulus with a constant
as shown
the model to this geometry
Paruit
conduction,
in 5% of its fully d e v e l o p e d
calculations
in the concentric
of Lundberg
the local Nusselt value
region
et al. predict
annulus. that,
For
in the
number has a p p r o a c h e d
in an entrance
of
to with-
length given by L/D e =
0.039 Pe. The R e c t a n g u l a r Attention cross
section
right,
problem
is now focused on the case of a duct having as shown in FIG.
2c.
but the m e t h o d of solution
of arbitrary
Channel
cross
involving
Application
section.
is an interesting
problem
used here could also be applied
This point
unsymmetrical of Equation
This
a rectangular
is illustrated
in its own to a duct
by c o n s i d e r a t i o n
of a
heating.
(3) to this geometry
yields
b a 1 L > ,~ pcp S S u(T-T )dxdy ~ -eD e [ 2 a (QI+Q3)+2b(Q2+Q4 ) ] -b -a m -
(8)
Vol.
3, No. 2
THERMAL E N T R A N C E L E N G T H S
IN DUCI~
93
For a rectangular geometry it is possible to obtain analytical expressions for u(x,y)
and T(x,y), but in general,
differences might be used to determine ferences here.
for an arbitrary cross section, these profiles.
We employ finite dif-
The simplest finite difference approximations
second derivatives were used.
finite
to the various
The constant flux boundary conditions
in the
energy equation were implemented using a fictitious boundary approach in order to assure a uniformity of the difference approximations with respect to spatial increment. For the case of equal heat fluxes on all faces of the duct, the results of the entrance L D
--
e
>
--
length calculations
can be put into the form
1 Pe
8Pe
(9)
where 8 depends only on the aspect ratio b/a. b/a is shown in FIG.
3.
Numerical
The relationship between 8 and
experiments showed that an interior grid
of 256 points produced L/D e results having numerical errors of less than ten percent.
Since the model is itself approximate,
sufficient to demonstrate the approach.
this accuracy was felt to be
By using the calculated results for
a/b = 0.5, 0.2 and 0.i, the value of 8 for a/b = 0 (parallel planes) was estimated.
This estimate yielded 8(0) = 0.0074 versus 0.0087 from a direct
calculation.
When the finite difference and extrapolation
errors are consid-
ered, these values are not inconsistent. The previous straightforward, stream profile
calculations
for symmetrical heating were relatively
since the position of the minimum temperature
is known to be at the center of the duct.
arbitrary cross section or for unsymmetrical
heating,
cross section of the minimum of the temperature this more general state of affairs,
in the down-
In general,
the position in the
is unknown.
To illustrate
a rectangular duct case was considered
for which a/b = 0.5 and Q4 = 2QI" Q2 = Q3 = 0 with Q1 arbitrary. case the finite difference calculations located at approximately ter 8 is equal to 0.096
for an
In this
show that the minimum temperature
is
x = -b/2, y = +5a/16 and the entrance length parame(versus 0.083 for all heat fluxes being equal). Flow Development
It is of some interest to calculate
the effects of flow development
viscous dissipation on the thermal entrance length.
Results of this calcula-
tion for the circular tube geometry are presented here. flow development and heating begin simultaneously, temperature profiles that are radially uniform.
and
It is assumed that
with inlet velocity and
94
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
It would be expected that the velocity profile would develop faster than the temperature profile for Prandtl numbers greater than about unity.
This
assumption is made; the calculation then produces results that are entirely consistent with this assumption. With the above assumptions, an overall energy balance is made between the tube entrance and the first point downstream where the developed temperature profile applies.
Evaluation of this energy balance requires a value for
the flow entrance length.
For simplicity, a formula given by Schlichting
[4]
is used for this value. Results of this calculation show that in general, if both thermal and mechanical
(p~)
(Q)
effects are important,
3 PUb 32 ) 4) + (Pr - .08 Pe - Pe QPeRe 3 32 P ~ 4+---Re Q
7 > (~ D--
When Q >> p ~
(i0)
(which is usually the case) we get the zero dissipation result
(Sandall and Hanna, 1973).
On the other hand, for p ~
>> Q, the entrance
length expression is seen to be virtually identical to the previous case, if Pr >> .08.
These results only apply for Pr greater than about unity, since
it has been assumed that the velocity develops faster than the temperature. It is interesting to note that the term 32/PeRe in Equation the interaction of dissipation and axial conduction.
(i0) represents
The effects of dissipa-
tion on the thermal entrance length may be important for heat transfer in polymers, if Prandtl numbers are large and Reynolds numbers small. Constant Wall Temperature Although the development given here applies to a uniform flux boundary condition, it is natural to inquire in general about the possibility of the approach for the case of constant wall temperature.
Again the circular tube
is interesting and simple so it will be considered for steady, developed laminar flow.
In this case, the downstream temperature solution is repre-
sented by the first eigenfunction of the Graetz solution
[5].
The essential difficulty in a specified surface temperature problem is that the unknown surface heat flux is required, and this flux varies with distance.
The simplest approach for estimation of the flux, without solving
the energy equation in the entrance region, is to use a Leveque-type solution
VOl. 3, NO. 2
[6].
THERMAL~fRANCE ~
IN[X~I~S
95
The problem with this procedure is that the Leveque sclution does not
apply accurately over the whole entrance region, and indeed its use also leaves in doubt the question of the preservation of the inequality, Equation (3).
If we proceed, in spite of these questions, we obtain L/D ~ 0.0207Pe.
This value compares with L/D = 0.036Pe corresponding to the position where the local Nusselt number is within five percent of the asymptotic value given by Sellars et al.
[ 7 ] . Although the two Nusselt numbers corresponding to the
quoted values of L/D are not far apart, it is clear that the constant wall temperature prediction is inferior to those given earlier for uniform flux as would be expected. Nomenclature A
duct cross-sectional area
a,b
rectangular duct half-widths
C
heat capacity per unit mass
P D
circular tube diameter
D
duct equivalent diameter, 4A/S
e
h
heat transfer coefficient, Q/(Tw-Tb)
k
thermal conductivity
-L I L
position upstream of heating where T=-T o entrance length; first axial position where downstream temperature profile applies
Q
heat flux per unit area
r
radial coordinate
R
tube radius
RI,R 2
inner and outer annulus radii
R
position of minimum temperature in annulus
m S
duct perimeter
St
Stanton number = h/pCpU b_
T
temperature
%
bulk temperature =
T
wall temperature
T T
w m
c
1 UbA
I A
uTdA
minimtun temperature in cross section centerline temperature for circular tube or parallel planes
u
axial velocity
%
1 mean velocity = ~
I
udA
A x,y,z
rectangular coordinates
g
half-width for parallel planes
(z axial)
96
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
Greek Symbols thermal diffusivity aspect ratio function for rectangular ducts p
density
Subscripts 0
refers to entrance or upstream condition
1,2
denotes different wall fluxes in annulus or rectangular
3,4
duct geometries
Dimensionless Groups Pe
Peclet number, UbDe/~
Pr
Prandtl number, ~Cp/k
Re
Reynolds number, DUbP/~
St
Stanton number, h/(CpUbP) References
i.
O. C. Sandall and O. T. Hanna, AIChE Journal, 19, 867 (1973).
2.
R. D. Cess and E. C. Schaffer, App. Sci. Res., 8A, 339 (1959).
3.
R. E. Lundberg, W. C. Reynolds and W. M. Kays, NASA TN D-1972, Washington, D.C., Aug. (1963).
4.
H. Schlichting, Boundary Layer Theory, 6th ed., McGraw-Hill, New York (1968).
5.
M. Jakob, Heat Transfer, Vol. i, Wiley, New York
6.
J. Leveque, Ann. Mines, 13, 201, 305, 381 (1928); J. G. Knudsen and D. L. Katz, Fluid Dynamics and Heat Transfer, p. 363, McGraw-Hill, New York (1958).
7.
J. R. Sellars, M. Tribus and J. S. Klein, Trans. A.S.M.E. 78, 441
(1958).
(1956).
Vol. 3, No. 2
THERMAL~TRANCE~
INDUCTS
0.12
l
97
I
I
I
l
0.10 Q
s
+++,,.,. . . .
(~
+++++++I+,~I++++++~,
i)
x
o
+
--~
Y
L > riPe-~
0,08
.8
Cross-sectional
0.06
0.04 Q J',+
L'
-I
I_
L
"~
0.02
-I
bla~oo (ParalLel Planesj,C$- 0.00871 . . . .
I
I
J
I
I
2
4
6
8
10
0.00
ASPECT RATIO. b/a
FIG. 1
FIG. 3
Model for thermal entrance length estimation.
Thermal entrance lenqth for rectangular channels with uniform heat flux.
Center Li ne
+ol
(b) Concentric Annulus
(a) Parallel Plates
~+, oiz, yl
/ °'1
l°I
+ r ~ L--~' ,,'----I +------21b-+---~y-----~----I - CL~er
ceo,+,
Line
L---t- ---~+--L [
ioi
tot
(c) Rectangular Channel
(d) Circular Tube
FIG. 2 Geometries considered for thermal entrance length calculations.
12
IN HEAT AND MASS TRANSFER Vol. 3, pp. 8 9 - 98, 1976
THERMAL ENTRANCE LENGTHS FOR LAMINAR FLOW IN VARIOUS DUCTS FOR CONSTANT SURFACE HEAT FLUX
Owen T. Hanna, Orville C. Sandall and Bernard A. Paruit Department of Chemical and Nuclear Engineering University of california, Santa Barbara California
(Communicated b y J . P .
93106
HartnettandW.J.
Minkowycz)
ABSTRACT A method for the determination of thermal or diffusion entrance lengths for transport in ducts with a uniform flux is illustrated. The method requires only a knowledge of the asymptotic downstream solution of the transport equation, which is far easier to obtain than the full solution. The results have a simple form and include effects of axial conduction. Geometries considered are parallel planes, concentric annuli and rectangular ducts of varying aspect ratio. Effects of asymmetric boundary conditions and flow development are considered.
Introduction In this paper an analysis is made of the length required for temperature profiles to reach a fully developed shape for the case of laminar flow heat transfer inside ducts having a uniform or specified surface heat flux.
The
method used to compute the thermal entrance length has been presented by Sandall and Hanna
[i] and is based on an overall energy balance over the
total entrance length.
To apply the method one needs to know only the down-
stream velocity and temperature profiles.
These solutions are relatively
easy to obtain for the case of uniform surface heat flux.
The technique is
generally applicable to situations in which the wall heat flux is specified.
89
90
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
The approach given here should be useful primarily in problems where the solution of the energy equation in the entrance region is not available, such as for ducts of peculiar cross section, unsymmetrical boundary conditions, or for the flow of highly viscous, non-Newtonian fluids.
Such an approach might
also be useful for problems involving significant variations of fluid properties.
This method would also seem to have applications for the design of
compact heat exchangers. It must be emphasized that the entrance length technique discussed here is significant because of its broad and simple applicability to complicated cross sections and because of its inclusion of axial conduction.
The exam-
ples given, which correspond to well-known classical results of varying complexity, illustrate these features and indicate comparisons between the present method and classical results. The model used to compute the thermal entrance length may be illustrated with reference to FIG. i.
Fluid is flowing through a duct of arbitrary cross
section, A, having the perimeter, S.
The fluid enters the duct with a uni-
form temperature, T . An overall energy balance for the case of a uniform o wall heat flux is made including a section upstream from the start of heating, since due to axial conduction, the effect of heating propagates upstream. This balance is made over the length - L', the upstream point at which axial conduction effects are no longer felt, to L, the point at which the temperature profile first becomes fully developed.
This gives an expression for the
entrance length. 1 [u(T-T°)]LdA + ~
L = QsPCP ..... AI
AI
[Qa]LdA
(i)
~T The axial heat conduction flux, Qa' is given by Fourier's Law as Qa = - k ( ~ ) L For a uniform wall heat flux the axial temperature gradient becomes constant ~T Qs under fully developed (downstream) conditions and is given as ~ = uu~pCpA" Substitution of these relationships into Equation
(i) and dividing .
by
the equivalent diameter, D e gives L pCp D--= QSD e e
I A
1 [u(T-To)]L dA - --Pe
(2)
Thus it is seen that the effect of axial conduction on the entrance length is given by the term - i/Pe.
Vol. 3, NO. 2
THERMAL~TRANCE
I~%~THS I N ~
91
For the case of heating, the initial temperature must be less than the minimum temperature at the point where the temperature profile first becomes fully developed.
This inequality yields
pCp
_ _
L__ > De -- QSDe Equation
I A
u(T-T )dA m
1 Pe
(3)
(3) represents the basic model from which thermal entrance
lengths are estimated in this paper for laminar flow in various geometries. The integral in Equation
(3) may be expressed in terms of the fully developed
Stanton number and T -T by making the substitution, T-T = (T-Tw) + ( % - T m) w m m ' and noting the definition of the bulk temperature and bulk velocity. L__ > pcp
D
e
-- 4Q
(%-Tm) Ub
1 4St
1 Pe
(4)
Thus if the asymptotic Stanton number is known and if the temperature difference, Tw-T m, is known from a previous calculation, then the thermal entrance length may be simply determined using Equation
(4).
Parallel Planes The physical case considered here is laminar flow between parallel plates as shown in FIG. 2a.
The fluid enters the duct with a uniform temper-
ature, To, and with a fully developed velocity profile; each wall is heated with a uniform heat flux, Q.
The energy equation may be integrated, neglect-
ing viscous dissipation, to give the fully developed temperature distribution, T-T . Substitution of this result into Equation (3) and integrating gives an m expression for the thermal entrance length. L - - > 0.00871Pe D -e Equation
1 Pe
(5)
(5) predicts the interesting result that due to axial conduc-
tion for low Pe, as could occur in the case of liquid metals, or some polymer situations, the thermal entrance length vanishes. The predicted entrance length from Equation calculations of Cess and Schaffer
(5) may be compared to the
[2] which predict that the local Nusselt
number, neglecting axial conduction, has approached to within 5% of its fully developed value in an entrance length given by L/D e = 0.0115 Pe.
92
O.T. Hanna,
O.C.
Sandall
and B.A.
Concentric The case of a concentric and outer b o u n d a r i e s
The general
For the special
minimum this
algebraic
temperature
extremely reason,
grals were
evaluated
equation
to use because
thermal
the solution
of the m i n i m u m
tempera-
case of the outer wall insulated, at the insulated wall, analytically;
however,
r = R 2.
The results
entrance
length
of these
RI/R2,
of RI/R 2 over the complete
range
For is
For this
the inte-
integrations
L/D e is, within
the
the result
of the large number of terms.
they depend only on the p a r a m e t e r
less than 1%, not a function result may be e x p r e s s e d
of
(6)
for the location
common
numerically.
that the dimensionless
Application
heat fluxes on each wall requires
and most
and also because
flux on the inner
1 Pe
(6) may be e v a l u a t e d
inconvenient
heat
2b is now considered.
for heating occurs
case Equation
show
an error of in RI/R 2.
This
as
L__ > 0.0321 Pe - I__ D -Pe e
(7)
Equation
(7) may be compared
Lundberg
et al.
to the thermal
entrance
[3] for uniform wall h e a t i n g
RI/R 2 = 0.5 the exact calculations absence
of axial
2
Annuli
ur (T-T m) dr
case of different
of a n o n - l i n e a r ture.
in FIG.
3, No.
leads to
R 12 R1
L > pCp D--e -- (QIRI+O2R2) _ _ De
Vol.
annulus with a constant
as shown
the model to this geometry
Paruit
conduction,
in 5% of its fully d e v e l o p e d
calculations
in the concentric
of Lundberg
the local Nusselt value
region
et al. predict
annulus. that,
For
in the
number has a p p r o a c h e d
in an entrance
of
to with-
length given by L/D e =
0.039 Pe. The R e c t a n g u l a r Attention cross
section
right,
problem
is now focused on the case of a duct having as shown in FIG.
2c.
but the m e t h o d of solution
of arbitrary
Channel
cross
involving
Application
section.
is an interesting
problem
used here could also be applied
This point
unsymmetrical of Equation
This
a rectangular
is illustrated
in its own to a duct
by c o n s i d e r a t i o n
of a
heating.
(3) to this geometry
yields
b a 1 L > ,~ pcp S S u(T-T )dxdy ~ -eD e [ 2 a (QI+Q3)+2b(Q2+Q4 ) ] -b -a m -
(8)
Vol.
3, No. 2
THERMAL E N T R A N C E L E N G T H S
IN DUCI~
93
For a rectangular geometry it is possible to obtain analytical expressions for u(x,y)
and T(x,y), but in general,
differences might be used to determine ferences here.
for an arbitrary cross section, these profiles.
We employ finite dif-
The simplest finite difference approximations
second derivatives were used.
finite
to the various
The constant flux boundary conditions
in the
energy equation were implemented using a fictitious boundary approach in order to assure a uniformity of the difference approximations with respect to spatial increment. For the case of equal heat fluxes on all faces of the duct, the results of the entrance L D
--
e
>
--
length calculations
can be put into the form
1 Pe
8Pe
(9)
where 8 depends only on the aspect ratio b/a. b/a is shown in FIG.
3.
Numerical
The relationship between 8 and
experiments showed that an interior grid
of 256 points produced L/D e results having numerical errors of less than ten percent.
Since the model is itself approximate,
sufficient to demonstrate the approach.
this accuracy was felt to be
By using the calculated results for
a/b = 0.5, 0.2 and 0.i, the value of 8 for a/b = 0 (parallel planes) was estimated.
This estimate yielded 8(0) = 0.0074 versus 0.0087 from a direct
calculation.
When the finite difference and extrapolation
errors are consid-
ered, these values are not inconsistent. The previous straightforward, stream profile
calculations
for symmetrical heating were relatively
since the position of the minimum temperature
is known to be at the center of the duct.
arbitrary cross section or for unsymmetrical
heating,
cross section of the minimum of the temperature this more general state of affairs,
in the down-
In general,
the position in the
is unknown.
To illustrate
a rectangular duct case was considered
for which a/b = 0.5 and Q4 = 2QI" Q2 = Q3 = 0 with Q1 arbitrary. case the finite difference calculations located at approximately ter 8 is equal to 0.096
for an
In this
show that the minimum temperature
is
x = -b/2, y = +5a/16 and the entrance length parame(versus 0.083 for all heat fluxes being equal). Flow Development
It is of some interest to calculate
the effects of flow development
viscous dissipation on the thermal entrance length.
Results of this calcula-
tion for the circular tube geometry are presented here. flow development and heating begin simultaneously, temperature profiles that are radially uniform.
and
It is assumed that
with inlet velocity and
94
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
It would be expected that the velocity profile would develop faster than the temperature profile for Prandtl numbers greater than about unity.
This
assumption is made; the calculation then produces results that are entirely consistent with this assumption. With the above assumptions, an overall energy balance is made between the tube entrance and the first point downstream where the developed temperature profile applies.
Evaluation of this energy balance requires a value for
the flow entrance length.
For simplicity, a formula given by Schlichting
[4]
is used for this value. Results of this calculation show that in general, if both thermal and mechanical
(p~)
(Q)
effects are important,
3 PUb 32 ) 4) + (Pr - .08 Pe - Pe QPeRe 3 32 P ~ 4+---Re Q
7 > (~ D--
When Q >> p ~
(i0)
(which is usually the case) we get the zero dissipation result
(Sandall and Hanna, 1973).
On the other hand, for p ~
>> Q, the entrance
length expression is seen to be virtually identical to the previous case, if Pr >> .08.
These results only apply for Pr greater than about unity, since
it has been assumed that the velocity develops faster than the temperature. It is interesting to note that the term 32/PeRe in Equation the interaction of dissipation and axial conduction.
(i0) represents
The effects of dissipa-
tion on the thermal entrance length may be important for heat transfer in polymers, if Prandtl numbers are large and Reynolds numbers small. Constant Wall Temperature Although the development given here applies to a uniform flux boundary condition, it is natural to inquire in general about the possibility of the approach for the case of constant wall temperature.
Again the circular tube
is interesting and simple so it will be considered for steady, developed laminar flow.
In this case, the downstream temperature solution is repre-
sented by the first eigenfunction of the Graetz solution
[5].
The essential difficulty in a specified surface temperature problem is that the unknown surface heat flux is required, and this flux varies with distance.
The simplest approach for estimation of the flux, without solving
the energy equation in the entrance region, is to use a Leveque-type solution
VOl. 3, NO. 2
[6].
THERMAL~fRANCE ~
IN[X~I~S
95
The problem with this procedure is that the Leveque sclution does not
apply accurately over the whole entrance region, and indeed its use also leaves in doubt the question of the preservation of the inequality, Equation (3).
If we proceed, in spite of these questions, we obtain L/D ~ 0.0207Pe.
This value compares with L/D = 0.036Pe corresponding to the position where the local Nusselt number is within five percent of the asymptotic value given by Sellars et al.
[ 7 ] . Although the two Nusselt numbers corresponding to the
quoted values of L/D are not far apart, it is clear that the constant wall temperature prediction is inferior to those given earlier for uniform flux as would be expected. Nomenclature A
duct cross-sectional area
a,b
rectangular duct half-widths
C
heat capacity per unit mass
P D
circular tube diameter
D
duct equivalent diameter, 4A/S
e
h
heat transfer coefficient, Q/(Tw-Tb)
k
thermal conductivity
-L I L
position upstream of heating where T=-T o entrance length; first axial position where downstream temperature profile applies
Q
heat flux per unit area
r
radial coordinate
R
tube radius
RI,R 2
inner and outer annulus radii
R
position of minimum temperature in annulus
m S
duct perimeter
St
Stanton number = h/pCpU b_
T
temperature
%
bulk temperature =
T
wall temperature
T T
w m
c
1 UbA
I A
uTdA
minimtun temperature in cross section centerline temperature for circular tube or parallel planes
u
axial velocity
%
1 mean velocity = ~
I
udA
A x,y,z
rectangular coordinates
g
half-width for parallel planes
(z axial)
96
O.T. Hanna, O.C. Sandall and B.A. Paruit
Vol. 3, No. 2
Greek Symbols thermal diffusivity aspect ratio function for rectangular ducts p
density
Subscripts 0
refers to entrance or upstream condition
1,2
denotes different wall fluxes in annulus or rectangular
3,4
duct geometries
Dimensionless Groups Pe
Peclet number, UbDe/~
Pr
Prandtl number, ~Cp/k
Re
Reynolds number, DUbP/~
St
Stanton number, h/(CpUbP) References
i.
O. C. Sandall and O. T. Hanna, AIChE Journal, 19, 867 (1973).
2.
R. D. Cess and E. C. Schaffer, App. Sci. Res., 8A, 339 (1959).
3.
R. E. Lundberg, W. C. Reynolds and W. M. Kays, NASA TN D-1972, Washington, D.C., Aug. (1963).
4.
H. Schlichting, Boundary Layer Theory, 6th ed., McGraw-Hill, New York (1968).
5.
M. Jakob, Heat Transfer, Vol. i, Wiley, New York
6.
J. Leveque, Ann. Mines, 13, 201, 305, 381 (1928); J. G. Knudsen and D. L. Katz, Fluid Dynamics and Heat Transfer, p. 363, McGraw-Hill, New York (1958).
7.
J. R. Sellars, M. Tribus and J. S. Klein, Trans. A.S.M.E. 78, 441
(1958).
(1956).
Vol. 3, No. 2
THERMAL~TRANCE~
INDUCTS
0.12
l
97
I
I
I
l
0.10 Q
s
+++,,.,. . . .
(~
+++++++I+,~I++++++~,
i)
x
o
+
--~
Y
L > riPe-~
0,08
.8
Cross-sectional
0.06
0.04 Q J',+
L'
-I
I_
L
"~
0.02
-I
bla~oo (ParalLel Planesj,C$- 0.00871 . . . .
I
I
J
I
I
2
4
6
8
10
0.00
ASPECT RATIO. b/a
FIG. 1
FIG. 3
Model for thermal entrance length estimation.
Thermal entrance lenqth for rectangular channels with uniform heat flux.
Center Li ne
+ol
(b) Concentric Annulus
(a) Parallel Plates
~+, oiz, yl
/ °'1
l°I
+ r ~ L--~' ,,'----I +------21b-+---~y-----~----I - CL~er
ceo,+,
Line
L---t- ---~+--L [
ioi
tot
(c) Rectangular Channel
(d) Circular Tube
FIG. 2 Geometries considered for thermal entrance length calculations.
12