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An assessment of the accuracy of numerical solutions to the graetz problem
INT. COMM. HR~TMASS TRANSFER 0735-1933/85 $3.00 + .00 Vol. 12, pp. 209-218, 1985 @Pergamon Press Ltd. Printed in the United States
AN ASSESSMENT OF THE ACCURACY OF NUMERICAL SOLUTIONS TO THE GRAETZ PROBLEM Nancy Conley, Adeniyi Lawal and Arun S. Mujumdar Department of Chemical Engineering McGill University Montreal, Quebec Canada (Ctamalnicated by J.P. Hartnett and W.J. Minkowycz) ABSTRACT I t has been w e l l documented i n p r i o r s t u d i e s t h a t n u m e r i c a l s o l u t i o n s t o t h e c l a s s i c a l Graetz problem i n t h e e n t r a n c e r e g i o n o f p i p e s produce e s t i m a t e s o f N u s s e l t number t h a t are greatly in error. I n t h i s r e p o r t , we examine t h i s problem and a t t e m p t t o p r o v i d e p l a u s i b l e e x p l a n a t i o n f o r t h e d i s c r e pancy.
Introduction In spite of the gross idealizations involved in its formulation,
the
classical Graetz problem surprisingly, provides valuable guidance in the design and development of compact heat exchangers.
Of greater significance
is the fact that this problem has served for decades as a model for testing various solution techniques since its solution has been adequately verified and widely disseminated [I]. Since the historical attempt by Graetz [2] in 1883 considerable effort has been expended on the solution of this problem or one of its many variations; the discussion here will he limited to only the most relevant ones. Hmploying the separation of variables technique, a closed-form solution is obtainable in the form of an infinite series, the eigenvalues and eigenfunctions of which satisfy the Sturm-Louiville system. were evaluated by Graetz.
The first two terms
Sellars et al. [3] subsequently extended this
work by providing the first ten eigenvalues and constants.
The major draw-
back of this solution approach is the poor convergence behaviour of the series near the entrance to the duet where even with 121 terms the series does not converge
[13.
The difficulty was partially resolved by Leveque ~4~ 209
210
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
who employed the 'flat plate' solution near the singularity at the entrance. Transport problems commonly encountered in industrial practice are almost always more involved than the Graetz problem.
Furthermore, the re-
sulting mathematical models do not generally admit of closed-form solutions. Usually recourse must be made to numerical solution techniques.
Inherently
numerical methods suffer from a major weakness -- the absence in most situations of a means of internally verifying the accuracy of the solutions which they generate.
This becomes even more pertinent since for every new
combination of parameters, their repetitive nature demands that the computer codes be validated.
The Graetz problem and other such standard prob-
lems that possess exact or closed-form solutions have served this useful purpose. The extended Graetz problem which included axial heat conduction was solved numerically by Schmidt and Zeldin [53.
For very high Peclet numbers
this problem reduces to the classical Graetz problem.
Thus it is expected
that the numerical solutions at very high Peclet numbers should closely
approach the closed-form solutions.
However, as noted in
[13, close
to the
duct entrance a deviation in local Nusselt number of up to 25% was observed making the numerical results in this region (for any Pe number) highly suspect.
Another numerical effort in the solution of the Graetz problem was
reported by Grigull and Tratz [6~; here again the values of the mean Nusselt number were about 16% lower than those evaluated from the closed-form solutions.
The implications of this general observation for other more comp-
lex problems that do not possess verifiable analytical solutions are greatly disturbing. Intuitively, the discrepancy between numerical and exact solutions can be attributed to the singularity at the entrance and the associated method of treatment by the numerical
algorithm[13. There
in the literature in favour of this argument.
is no compelling evidence
Another possible explanation
is rooted in the observation made by Collins [73 that I percent general errors (even greater near entrance) are common in the energy balance when the wall thermal condition is explicitly imposed numerically.
He therefore
suggested replacing the discretization equation at the wall node but one by an integral energy balance reminiscent of the overall continuity equation for mass conservation.
This hypothesis is tested in this report.
Because
of the large axial gradients in the vicinity of the entrance and also the occurrence of rapid radial changes in the thermal profile one might want to appropriately concentrate the grids in these regions.
The obvious
VOl. 12, No. 2
NIIMERICAL S(X;/rlCNS TO THE GRAETZ ~
211
advantage of t h i s procedure i s t h a t i t affords the placement of a v a i l a b l e computing power i n a r e a s where i t i s d e s i r e d most. f u n c t i o n s i n t h e r a d i a l d i r e c t i o n were t e s t e d ,
Two c o o r d i n a t e s p a c i n g
one o f which had been p r e -
v i o u s l y employed by Schmidt and Z e l d i n f o r a s i m i l a r problem. The a u t h o r s a r e unaware o f any e f f o r t s t o n u m e r i c a l l y r e p l i c a t e t h e e x a c t r e s u l t s o f t h e Graetz problem ( e s p e c i a l l y i n terms o f t h e l o c a l Nuss e l t number) i n t h e e n t r a n c e r e g i o n . on t h e v a l i d i t y
Such an e x e r c i s e w i l l shed some l i g h t
of various numerical procedures.
Herein l i e s t h e prime m o t i -
vation for this study. Analysis Of i n t e r e s t
i s the entrance region laminar heat t r a n s f e r to viscous i n -
c o m p r e s s i b l e c o n s t a n t p r o p e r t y Newtonian f l u i d f l o w i n g i n a c i r c u l a r t u b e w i t h a f u l l y developed e n t r a n c e v e l o c i t y p r o f i l e .
The f l u i d e n t e r s t h e
duct w i t h a u n i f o r m t e m p e r a t u r e T and i t i s t h e n h e a t e d or cooled t h r o u g h e t h e duct w a l l whose t e m p e r a t u r e i s m a i n t a i n e d u n i f o r m a t Tw ( d i f f e r e n t from the entrance value).
The n e g l e c t o f such e f f e c t s as v i s c o u s d i s s i p a t i o n ,
i n t e r n a l h e a t g e n e r a t i o n and a x i a l h e a t c o n d u c t i o n completes t h e d e f i n i t i o n of the c l a s s i c a l
Graetz problem,
For t h e model i d e a l i z e d above t h e t h e r m a l energy e q u a t i o n r e d u c e s t o : 1 3
( r 3T
= u 3T
(la)
w h i l e t h e t h e r m a l boundary c o n d i t i o n s a r e g i v e n by: T ( r , 0 ) = Te; T(ro,X ) = Tw and -3T ~ (0,x) = 0
(lb)
With t h e i n t r o d u c t i o n o f t h e f o l l o w i n g d i m e n s i o n l e s s v a r i a b l e s ; R = r/r ° 0 = T-Tw_ T -T e w
X = (x/2ro)/P e t h e e n e r g y e q u a t i o n a l o n g w i t h t h e boundary c o n d i t i o n s become: 2 ~ (R 30 30 3--R " -~) = (l-R2) * ~X 30 O(R,O) = 1 . 0 ; O(1,X ) = 0 and ~-~
(2a)
(0,X*) = 0
(2b)
where t h e v e l o c i t y p r o f i l e has assumed i t s u s u a l p a r a b o l i c form. finitions
The de-
o f o t h e r v a r i a b l e s have been r e l e g a t e d t o t h e n o m e n c l a t u r e .
212
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
Method of Solution: To exercise control on the grid near the wall we introduce a new variable such that variable spacing in the R direction corresponds with uniform spacing in ~. R
=
If ~ and R are related as below:
cA
(3)
with A suitably chosen we can generate a mesh that is fine near the wall and progressively coarser near the center.
We refer to this as COORDI.
If
the necessary substitution is made, Eq. (2a) can be written as: __ ~2-2A 3 2 0 + A2 3~2
gl-2A (~A-~---) 3 0 _ i (i_ 2A) 30 3~ 2 3X*
(4)
In order to confine grids near the wall, Schmidt and Zeldin employed a logarithmic relationship (herein called COORD2) which can be generalized as: R
=
1
In (I + (ea-l)~)
(5)
The parameter a serves the same purpose as previously stated, and the energy equation rewritten in the new coordinate becomes:
a2 (1+ E ( e a - 1 ) ) 2
__320
(ea-1) 2
a 2 (1 + E ( e a - 1 ) )
3~2 +
(1 +
(ea-1)
1
30
In (1 + ( e a - 1 ) ~ ) ) - ~ ' =
2 (1 - ( l n ( l + ( e a - 1 ) ~ ) ) 2) 830 -~
(6)
A s t a n d a r d g r i d network w i t h t h e dependent v a r i a b l e
s t o r e d a t each g r i d
p o i n t i s l a i d out on t h e c o m p u t a t i o n a l domain h a v i n g a u n i f o r m r a d i a l o f Ag.
Second o r d e r c e n t r a l
all partial
derivatives
the first-order
difference
in the radial
derivative
spacing
scheme i s employed i n a p p r o x i m a t i n g
direction
and t h e upwind scheme f o r
in the axial direction.
The r e s u l t i n g
discretiza-
t i o n e q u a t i o n s a r e s o l v e d u s i n g t h e TDMA ( T r i d i a g o n a l M a t r i x A l g o r i t h m ) . As remarked e a r l i e r
i n s t e a d o f forming a d i s c r e t i z a t i o n
w a l l node b u t one u s i n g Eq. ( l a ) , which r e l a t e s the vicinity
we employ t h e i n t e g r a l
equation at the
energy balance
t h e a x i a l change i n b u l k t e m p e r a t u r e t o t h e t e m p e r a t u r e s i n of the wall.
point using regular radial
The f i n a l
form o f t h e e q u a t i o n f o r t h i s node
s p a c i n g in R i s g i v e n b y :
Ob(X* ) _ 0b(X*_AX* )
=
4~X ARR (30(M) - 4 0 ( M - l )
+ 0(M-2))
(7) In t h i s c a s e , however, t h e d i s c r e t i z a t i o n
e q u a t i o n s a r e n o t amenable
t o s o l u t i o n s by TDMA. T h e r e f o r e , t h e s u c c e s s i v e o v e r - r e l a x a t i o n
(SOR)
Vol. 12, NO. 2
NL~ERICAL~GNS
p r o c e d u r e was u t i l i z e d . two q u a n t i t i e s
TO THEGRAETZ P ~
Upon o b t a i n i n g t h e t e m p e r a t u r e p r o f i l e we c a l c u l a t e
of s p e c i a l i n t e r e s t ,
t h e l o c a l N u s s e l t number, t h e l a t t e r
t h e d i m e n s i o n l e s s b u l k t e m p e r a t u r e and o f which i s d e f i n e d a s :
~_.__RRIR=I -2~e
Nu . = X
213
(8)
eb
The bulk temperature was computed using Simpson's rule while the thermal gradient at the wall was numerically evaluated from the 3-point rule except otherwise implied.
The other choices for the approximation of the latter
quantity include the 5-point rule and the log relationship presented in detail i n [5]. Results and Discussion In Fig. 1 is depicted the effect of the number of axial steps on Nu
at X*=I0 -6 for varying degrees of radial grid refinement. Clearly with X* 21 regular radial grid points the Nu which is substantially in error, X*'
15£
M= 101
lOG
. . . . . . . . . . . . . . . . EXACT . . . . . . . . . . . SOLN. ...............................
M= 301
Nu x, M=21
5(:;
0
I
I
5
No oFIOAxIAL
I
15 STEPS N
FIG. 1 Effect of axial step size for regular radial grids *
with X =10
-6
.
20
214
N. Conley, A. Lawal and A.S. Mujumdar
shows no noticeable dependence on the axial grid distribution.
Vol. 12, No. With M=301
the numerical solution is almost indistinguishable from the exact solution except for N
Keeping the number of axial steps fixed and varying M
produced the effects illustrated in Fig. 2 from which we infer that no matter what value M attains an optimal number of axial steps is required for
. . . . . . . ~NA~Y-gb-Cg-- -
1OO
~
~
=
~
5O
o
~
I~o
,~o No
OF
~o
2~o
36o
RADIAL POINTS M
FIG. 2 Effect of radial grid refinement for three values of *
N with X =I0
reasonable accuracy.
-6
.
The profiles presented on these figures provide con-
vincing evidence that the conventional test of numerical convergence of finite difference solutions may not be conclusive especially with regard to derived properties such as NUx,.
For illustration, in Fig. 2 there is
no a p p r e c i a b l e are greatly
c h a n g e i n Nu . when M l i e s b e t w e e n 75 a n d 125 y e t t h e v a l u e s X in error. The s a m e a p p l i e s t o F i g . 1 w h e r e t h i s b e h a v i o u r i s
strikingly clear for M=21. The radial grid points can be conveniently concentrated near the wall with the parameter A
Figure 3 examines its effect on Nu .. X Evidently in contrast to the regular grid an appropriate choice of A can assuredly replicate the exact solution even for a coarse grid of M=21 but the @b (not shown) begins to deviate quite significantly from the exact solution for A<0.6 and M
The behaviour of Nu , for different values X of parameter a is not dissimilar from that for A as can be observed from Fig. 4.
In fact when a~0.0 and A=I.0 (regular grid) the NUx, values are
Vol. 12, No. 2
~ C A L
SOLUTIONS X D T H E I
t
I
•5
of parameter * -6 M with X =i0 . 1
.
.
.
.
.
.
.
M with X =I0
I
.7
!
!
/
I
~B
A
.9
I
1J
values
-I
of
"
. . . .
FIG. 4 a on Nu . f o r X
.
........
.
of parameter -6
I
.6
215
i
FIG. 3 A o n Nu . f o r t h r e e X
Effect
*
1
-~--~:
10(
Effect
I
GRAETZ P N 0 ~
three
values
of
216
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
* -6 Ten uniform axial steps were taken to reach X =I0 .
the same.
Since the intent of this work is to examine Nu ~nd @b near the entrance, further results are presented in Table 1 for the t~ree types of grid employed in the analysis.
The initial step size AX
was 10 -7 , and for each order of
TABLE 1 Ob and NUX. distributions using different radial grid distributions
Regular Grid M
21
X
0b
,000001 .000004 .000008 .000020 .000060 .000100 X
.000001 .000004 101 .000008 .000020 .000060 .000100 X
.99979 .99919 .99842 .99634 .99092 .98685
Nu . X 59.345 57.452 55.075 49.002 35.443 27.951
@b
NUx*
.99937 130.561 .99842 71.557 .99748 54.674 .99542 40.142 .99048 27.066 .98665 22,558 @b
.000001 .000004 .000008 301 .000020 .000060 .000100
99937 99841 99747 99540 99047 98664
magnitude change in
Nu . X 109.811 68.375 53,492 39.757 26.985 22.519
X*
COORD1 (A=. 6) 0b
(a=l. O)
.98656 .98565 .98462 .98239 .97745 .97365
Nu . X 96.607 84.536 72.004 51.218 29.879 24.014
.99968 .99880 .99779 .99552 .99055 .98677
Ob
NUx*
Ob
.99747 113.856 .99652 69.103 .99558 53.813 .99351 39.903 .98857 27.050 ,98475 22.568 @b
Shah & London
COORD2
NUx*
.99886 109.252 .99790 68,313 .99696 53.483 .99496 40.122 .98996 26.996 .98613 22.529
Ob
.99957 .99841 .99748 .99541 .99047 .98664 @b .99937 .99841 .99747 ,99540 .99047 .98664
Nu . X 91.195 81.418 70.849 51.833 30.075 23.940 Nu . X 114.463 69.098 53.756 39.841 27.007 22.525 Nu . X 109.225 68.283 53.457 39.746 26.982 22.517
Ob .99936 .99839 .99745 .99534 .99039 .98657 Ob .99936 .99839 .99745 .99534 .99039 .98657 @b .99936 .99839 .99745 .99534 .99039 .98657
a corresponding change in AX* was made.
Nu . X 106.538 66.731 52.763 38.637 26.544 22.275 Nu . X 106.538 66.731 52.763 38.637 26.544 22.275 Nu . X 106.538 66.731 52.763 38.637 26.$44 22.275
With M=21 and
X*=I0 -4 the Nu . values show a maximum deviation of about 26% from Shah and X London's results which were obtained from analytical solution of Leveque's problem.
However, when M=I01 the numerical results regardless of the radial *
grid employed can be accepted as accurate to within 3.6% for X >8XI0
-5
.
The results of Table 2 indicate that for coarse radial grids Nu . is X dependent on the expression employed in approximating the wall thermal gradient, the arbitrariness so introduced further attests to the unsuitability of such *
grids even though this becomes less pronounced for X =i0
-4
.
The integral
energy balance was incorporated into the code and the Nu . evaluated at X
Vol. 12, No. 2
Nu . a t X
~
N~CAL
selected
values
SOLUTIGNS TO THE GRAETZ P R ~
, TABLE 2 of X using three thermal
gradient
different
methods for wail
evaluation
M
3-Point
X*=10 -6 5-Point
LOG
21
59.345
82.017
38.674
27.951
25.304
22.641
ioi 130.561 ~ 301 109.811
116.340
109.474
22.558
22.514
22.517
108.761
109.026
22.519
22.517
22.517
,-,
21
96.607
131.316
63.548
24.014
20.904
22.802
~
101
113.856
103.208
109.203
22.568
22.560
22.560
"-~ 301
109.308
109.071
109.082
22.529
22.529
22.529
21
91.195
124.395
59.870
23.940
19.963
22.643
101
114.463
101.572
109.130
22.525
22.517
22.547
301
109.225
109.012
109.074
22.517
22.517
22.527
0°5
~ O II or.~ , .m w
X*=10 -6 for the coarse grid of M=21.
217
X*=10 -4 3-Point 5-Point
LOG
There is no noticeable improvement
(Nu ,=59.244) when compared with the corresponding value in Table I, an outX come similar to that obtained when the control volume method was utilized in discretizing the energy equation E83.
It is appropriate to comment that all
the results require about the same number of CPU seconds so there are no cost differences as far as computing is concerned. Based on the above, it may be concluded that very close to the entrance an optimal grid size, both in the radial and axial directions, is required and a simple redistribution of grid points may not eliminate the inaccuracy of the results.
As no exact solutions exist in general for the more compli-
cated entrance problems such as the d e v e l o p i n g
flow and heat transfer
in ducts, the findings cannot strictly be generalized, except in so far as they provide usable guidelines.
Prior results obtained with few grid-
lines may not be sufficiently accurate very near the entrance. Acknowledgements The authors are indebted to Professor W. Thorpe for providing extensive computer time on the Amdahl V7A of the McGill Computing Centre. Nomenclature a
- Coordinate spacing parameter
A
- Coordinate spacing parameter
218
N. Conley, A. Lawal and A.S. Y~/jumdar
M
Number of radial grid points
N
- Number of axial steps
Nu .
Local Nusselt number
Pe X
Peclet number = 2roPCpUm/k
r r
Vol. 12, No. 2
- Radial coordinate o
R
- Tube radius - Radial coordinate (dimensionless)
T
- Temperature
Te
- Entrance temperature
Tw
- Wall temperature
um
- Mean velocity
x
- Axial coordinate
X*
- Axial coordinate (dimensionless)
Greek Symbols: - Thermal diffusivity (pCp/k) - Radial coordinate @
- Temperature (dimensionless)
@b
- Bulk temperature (dimensionless) References
i.
R.K. Shah and A.L. London, Laminar Forced Convection in Ducts, Advances in Heat Transfer, New York; Academic Press.
2.
L. Graetz, On the Thermal Conductivity of Liquids, Part I; Ann. Phys. Chem. 18, 79 (1883).
3.
J.R. Sellers, M. Tribus and J.S. Klein, Heat Transfer to Laminar Flow in a Round Tube or Flat Conduit -- the Graetz Problem Extended, Trans. ASME 78, 441 (1956).
4.
M.A. Leveque, Les lois de la transmission de chaleur par convection, Ann. Mines, Mem., Ser. 1 2 1 3 , 201 (1928).
5.
F.W. Schmidt and B. Zeldin, Laminar Heat Transfer in the Entrance Region of Ducts, Applied Scientific Research 2_33, 73 (1970).
6.
U. Grigull and H. Tratz, Thermischer einlauf in ausgebildeter laminarer Rohrstromung, Int. J. Heat Mass Transfer 8, 669 (1965).
7.
M.W. Collins, Finite Difference Analysis for Developing Laminar Flow in Circular Tubes Applied to Forced and Combined Convection, Int. Journal for Numerical Methods in Engineering, 15, 381 (1980).
8.
N.A. Poirier, Numerical Solution of the Graetz Problem in the Entrance Region, Internal Report Chemical Eng. Dept. McGill University (1984).
AN ASSESSMENT OF THE ACCURACY OF NUMERICAL SOLUTIONS TO THE GRAETZ PROBLEM Nancy Conley, Adeniyi Lawal and Arun S. Mujumdar Department of Chemical Engineering McGill University Montreal, Quebec Canada (Ctamalnicated by J.P. Hartnett and W.J. Minkowycz) ABSTRACT I t has been w e l l documented i n p r i o r s t u d i e s t h a t n u m e r i c a l s o l u t i o n s t o t h e c l a s s i c a l Graetz problem i n t h e e n t r a n c e r e g i o n o f p i p e s produce e s t i m a t e s o f N u s s e l t number t h a t are greatly in error. I n t h i s r e p o r t , we examine t h i s problem and a t t e m p t t o p r o v i d e p l a u s i b l e e x p l a n a t i o n f o r t h e d i s c r e pancy.
Introduction In spite of the gross idealizations involved in its formulation,
the
classical Graetz problem surprisingly, provides valuable guidance in the design and development of compact heat exchangers.
Of greater significance
is the fact that this problem has served for decades as a model for testing various solution techniques since its solution has been adequately verified and widely disseminated [I]. Since the historical attempt by Graetz [2] in 1883 considerable effort has been expended on the solution of this problem or one of its many variations; the discussion here will he limited to only the most relevant ones. Hmploying the separation of variables technique, a closed-form solution is obtainable in the form of an infinite series, the eigenvalues and eigenfunctions of which satisfy the Sturm-Louiville system. were evaluated by Graetz.
The first two terms
Sellars et al. [3] subsequently extended this
work by providing the first ten eigenvalues and constants.
The major draw-
back of this solution approach is the poor convergence behaviour of the series near the entrance to the duet where even with 121 terms the series does not converge
[13.
The difficulty was partially resolved by Leveque ~4~ 209
210
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
who employed the 'flat plate' solution near the singularity at the entrance. Transport problems commonly encountered in industrial practice are almost always more involved than the Graetz problem.
Furthermore, the re-
sulting mathematical models do not generally admit of closed-form solutions. Usually recourse must be made to numerical solution techniques.
Inherently
numerical methods suffer from a major weakness -- the absence in most situations of a means of internally verifying the accuracy of the solutions which they generate.
This becomes even more pertinent since for every new
combination of parameters, their repetitive nature demands that the computer codes be validated.
The Graetz problem and other such standard prob-
lems that possess exact or closed-form solutions have served this useful purpose. The extended Graetz problem which included axial heat conduction was solved numerically by Schmidt and Zeldin [53.
For very high Peclet numbers
this problem reduces to the classical Graetz problem.
Thus it is expected
that the numerical solutions at very high Peclet numbers should closely
approach the closed-form solutions.
However, as noted in
[13, close
to the
duct entrance a deviation in local Nusselt number of up to 25% was observed making the numerical results in this region (for any Pe number) highly suspect.
Another numerical effort in the solution of the Graetz problem was
reported by Grigull and Tratz [6~; here again the values of the mean Nusselt number were about 16% lower than those evaluated from the closed-form solutions.
The implications of this general observation for other more comp-
lex problems that do not possess verifiable analytical solutions are greatly disturbing. Intuitively, the discrepancy between numerical and exact solutions can be attributed to the singularity at the entrance and the associated method of treatment by the numerical
algorithm[13. There
in the literature in favour of this argument.
is no compelling evidence
Another possible explanation
is rooted in the observation made by Collins [73 that I percent general errors (even greater near entrance) are common in the energy balance when the wall thermal condition is explicitly imposed numerically.
He therefore
suggested replacing the discretization equation at the wall node but one by an integral energy balance reminiscent of the overall continuity equation for mass conservation.
This hypothesis is tested in this report.
Because
of the large axial gradients in the vicinity of the entrance and also the occurrence of rapid radial changes in the thermal profile one might want to appropriately concentrate the grids in these regions.
The obvious
VOl. 12, No. 2
NIIMERICAL S(X;/rlCNS TO THE GRAETZ ~
211
advantage of t h i s procedure i s t h a t i t affords the placement of a v a i l a b l e computing power i n a r e a s where i t i s d e s i r e d most. f u n c t i o n s i n t h e r a d i a l d i r e c t i o n were t e s t e d ,
Two c o o r d i n a t e s p a c i n g
one o f which had been p r e -
v i o u s l y employed by Schmidt and Z e l d i n f o r a s i m i l a r problem. The a u t h o r s a r e unaware o f any e f f o r t s t o n u m e r i c a l l y r e p l i c a t e t h e e x a c t r e s u l t s o f t h e Graetz problem ( e s p e c i a l l y i n terms o f t h e l o c a l Nuss e l t number) i n t h e e n t r a n c e r e g i o n . on t h e v a l i d i t y
Such an e x e r c i s e w i l l shed some l i g h t
of various numerical procedures.
Herein l i e s t h e prime m o t i -
vation for this study. Analysis Of i n t e r e s t
i s the entrance region laminar heat t r a n s f e r to viscous i n -
c o m p r e s s i b l e c o n s t a n t p r o p e r t y Newtonian f l u i d f l o w i n g i n a c i r c u l a r t u b e w i t h a f u l l y developed e n t r a n c e v e l o c i t y p r o f i l e .
The f l u i d e n t e r s t h e
duct w i t h a u n i f o r m t e m p e r a t u r e T and i t i s t h e n h e a t e d or cooled t h r o u g h e t h e duct w a l l whose t e m p e r a t u r e i s m a i n t a i n e d u n i f o r m a t Tw ( d i f f e r e n t from the entrance value).
The n e g l e c t o f such e f f e c t s as v i s c o u s d i s s i p a t i o n ,
i n t e r n a l h e a t g e n e r a t i o n and a x i a l h e a t c o n d u c t i o n completes t h e d e f i n i t i o n of the c l a s s i c a l
Graetz problem,
For t h e model i d e a l i z e d above t h e t h e r m a l energy e q u a t i o n r e d u c e s t o : 1 3
( r 3T
= u 3T
(la)
w h i l e t h e t h e r m a l boundary c o n d i t i o n s a r e g i v e n by: T ( r , 0 ) = Te; T(ro,X ) = Tw and -3T ~ (0,x) = 0
(lb)
With t h e i n t r o d u c t i o n o f t h e f o l l o w i n g d i m e n s i o n l e s s v a r i a b l e s ; R = r/r ° 0 = T-Tw_ T -T e w
X = (x/2ro)/P e t h e e n e r g y e q u a t i o n a l o n g w i t h t h e boundary c o n d i t i o n s become: 2 ~ (R 30 30 3--R " -~) = (l-R2) * ~X 30 O(R,O) = 1 . 0 ; O(1,X ) = 0 and ~-~
(2a)
(0,X*) = 0
(2b)
where t h e v e l o c i t y p r o f i l e has assumed i t s u s u a l p a r a b o l i c form. finitions
The de-
o f o t h e r v a r i a b l e s have been r e l e g a t e d t o t h e n o m e n c l a t u r e .
212
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
Method of Solution: To exercise control on the grid near the wall we introduce a new variable such that variable spacing in the R direction corresponds with uniform spacing in ~. R
=
If ~ and R are related as below:
cA
(3)
with A suitably chosen we can generate a mesh that is fine near the wall and progressively coarser near the center.
We refer to this as COORDI.
If
the necessary substitution is made, Eq. (2a) can be written as: __ ~2-2A 3 2 0 + A2 3~2
gl-2A (~A-~---) 3 0 _ i (i_ 2A) 30 3~ 2 3X*
(4)
In order to confine grids near the wall, Schmidt and Zeldin employed a logarithmic relationship (herein called COORD2) which can be generalized as: R
=
1
In (I + (ea-l)~)
(5)
The parameter a serves the same purpose as previously stated, and the energy equation rewritten in the new coordinate becomes:
a2 (1+ E ( e a - 1 ) ) 2
__320
(ea-1) 2
a 2 (1 + E ( e a - 1 ) )
3~2 +
(1 +
(ea-1)
1
30
In (1 + ( e a - 1 ) ~ ) ) - ~ ' =
2 (1 - ( l n ( l + ( e a - 1 ) ~ ) ) 2) 830 -~
(6)
A s t a n d a r d g r i d network w i t h t h e dependent v a r i a b l e
s t o r e d a t each g r i d
p o i n t i s l a i d out on t h e c o m p u t a t i o n a l domain h a v i n g a u n i f o r m r a d i a l o f Ag.
Second o r d e r c e n t r a l
all partial
derivatives
the first-order
difference
in the radial
derivative
spacing
scheme i s employed i n a p p r o x i m a t i n g
direction
and t h e upwind scheme f o r
in the axial direction.
The r e s u l t i n g
discretiza-
t i o n e q u a t i o n s a r e s o l v e d u s i n g t h e TDMA ( T r i d i a g o n a l M a t r i x A l g o r i t h m ) . As remarked e a r l i e r
i n s t e a d o f forming a d i s c r e t i z a t i o n
w a l l node b u t one u s i n g Eq. ( l a ) , which r e l a t e s the vicinity
we employ t h e i n t e g r a l
equation at the
energy balance
t h e a x i a l change i n b u l k t e m p e r a t u r e t o t h e t e m p e r a t u r e s i n of the wall.
point using regular radial
The f i n a l
form o f t h e e q u a t i o n f o r t h i s node
s p a c i n g in R i s g i v e n b y :
Ob(X* ) _ 0b(X*_AX* )
=
4~X ARR (30(M) - 4 0 ( M - l )
+ 0(M-2))
(7) In t h i s c a s e , however, t h e d i s c r e t i z a t i o n
e q u a t i o n s a r e n o t amenable
t o s o l u t i o n s by TDMA. T h e r e f o r e , t h e s u c c e s s i v e o v e r - r e l a x a t i o n
(SOR)
Vol. 12, NO. 2
NL~ERICAL~GNS
p r o c e d u r e was u t i l i z e d . two q u a n t i t i e s
TO THEGRAETZ P ~
Upon o b t a i n i n g t h e t e m p e r a t u r e p r o f i l e we c a l c u l a t e
of s p e c i a l i n t e r e s t ,
t h e l o c a l N u s s e l t number, t h e l a t t e r
t h e d i m e n s i o n l e s s b u l k t e m p e r a t u r e and o f which i s d e f i n e d a s :
~_.__RRIR=I -2~e
Nu . = X
213
(8)
eb
The bulk temperature was computed using Simpson's rule while the thermal gradient at the wall was numerically evaluated from the 3-point rule except otherwise implied.
The other choices for the approximation of the latter
quantity include the 5-point rule and the log relationship presented in detail i n [5]. Results and Discussion In Fig. 1 is depicted the effect of the number of axial steps on Nu
at X*=I0 -6 for varying degrees of radial grid refinement. Clearly with X* 21 regular radial grid points the Nu which is substantially in error, X*'
15£
M= 101
lOG
. . . . . . . . . . . . . . . . EXACT . . . . . . . . . . . SOLN. ...............................
M= 301
Nu x, M=21
5(:;
0
I
I
5
No oFIOAxIAL
I
15 STEPS N
FIG. 1 Effect of axial step size for regular radial grids *
with X =10
-6
.
20
214
N. Conley, A. Lawal and A.S. Mujumdar
shows no noticeable dependence on the axial grid distribution.
Vol. 12, No. With M=301
the numerical solution is almost indistinguishable from the exact solution except for N
Keeping the number of axial steps fixed and varying M
produced the effects illustrated in Fig. 2 from which we infer that no matter what value M attains an optimal number of axial steps is required for
. . . . . . . ~NA~Y-gb-Cg-- -
1OO
~
~
=
~
5O
o
~
I~o
,~o No
OF
~o
2~o
36o
RADIAL POINTS M
FIG. 2 Effect of radial grid refinement for three values of *
N with X =I0
reasonable accuracy.
-6
.
The profiles presented on these figures provide con-
vincing evidence that the conventional test of numerical convergence of finite difference solutions may not be conclusive especially with regard to derived properties such as NUx,.
For illustration, in Fig. 2 there is
no a p p r e c i a b l e are greatly
c h a n g e i n Nu . when M l i e s b e t w e e n 75 a n d 125 y e t t h e v a l u e s X in error. The s a m e a p p l i e s t o F i g . 1 w h e r e t h i s b e h a v i o u r i s
strikingly clear for M=21. The radial grid points can be conveniently concentrated near the wall with the parameter A
Figure 3 examines its effect on Nu .. X Evidently in contrast to the regular grid an appropriate choice of A can assuredly replicate the exact solution even for a coarse grid of M=21 but the @b (not shown) begins to deviate quite significantly from the exact solution for A<0.6 and M
The behaviour of Nu , for different values X of parameter a is not dissimilar from that for A as can be observed from Fig. 4.
In fact when a~0.0 and A=I.0 (regular grid) the NUx, values are
Vol. 12, No. 2
~ C A L
SOLUTIONS X D T H E I
t
I
•5
of parameter * -6 M with X =i0 . 1
.
.
.
.
.
.
.
M with X =I0
I
.7
!
!
/
I
~B
A
.9
I
1J
values
-I
of
"
. . . .
FIG. 4 a on Nu . f o r X
.
........
.
of parameter -6
I
.6
215
i
FIG. 3 A o n Nu . f o r t h r e e X
Effect
*
1
-~--~:
10(
Effect
I
GRAETZ P N 0 ~
three
values
of
216
N. Conley, A. Lawal and A.S. Mujumdar
Vol. 12, No. 2
* -6 Ten uniform axial steps were taken to reach X =I0 .
the same.
Since the intent of this work is to examine Nu ~nd @b near the entrance, further results are presented in Table 1 for the t~ree types of grid employed in the analysis.
The initial step size AX
was 10 -7 , and for each order of
TABLE 1 Ob and NUX. distributions using different radial grid distributions
Regular Grid M
21
X
0b
,000001 .000004 .000008 .000020 .000060 .000100 X
.000001 .000004 101 .000008 .000020 .000060 .000100 X
.99979 .99919 .99842 .99634 .99092 .98685
Nu . X 59.345 57.452 55.075 49.002 35.443 27.951
@b
NUx*
.99937 130.561 .99842 71.557 .99748 54.674 .99542 40.142 .99048 27.066 .98665 22,558 @b
.000001 .000004 .000008 301 .000020 .000060 .000100
99937 99841 99747 99540 99047 98664
magnitude change in
Nu . X 109.811 68.375 53,492 39.757 26.985 22.519
X*
COORD1 (A=. 6) 0b
(a=l. O)
.98656 .98565 .98462 .98239 .97745 .97365
Nu . X 96.607 84.536 72.004 51.218 29.879 24.014
.99968 .99880 .99779 .99552 .99055 .98677
Ob
NUx*
Ob
.99747 113.856 .99652 69.103 .99558 53.813 .99351 39.903 .98857 27.050 ,98475 22.568 @b
Shah & London
COORD2
NUx*
.99886 109.252 .99790 68,313 .99696 53.483 .99496 40.122 .98996 26.996 .98613 22.529
Ob
.99957 .99841 .99748 .99541 .99047 .98664 @b .99937 .99841 .99747 ,99540 .99047 .98664
Nu . X 91.195 81.418 70.849 51.833 30.075 23.940 Nu . X 114.463 69.098 53.756 39.841 27.007 22.525 Nu . X 109.225 68.283 53.457 39.746 26.982 22.517
Ob .99936 .99839 .99745 .99534 .99039 .98657 Ob .99936 .99839 .99745 .99534 .99039 .98657 @b .99936 .99839 .99745 .99534 .99039 .98657
a corresponding change in AX* was made.
Nu . X 106.538 66.731 52.763 38.637 26.544 22.275 Nu . X 106.538 66.731 52.763 38.637 26.544 22.275 Nu . X 106.538 66.731 52.763 38.637 26.$44 22.275
With M=21 and
X*=I0 -4 the Nu . values show a maximum deviation of about 26% from Shah and X London's results which were obtained from analytical solution of Leveque's problem.
However, when M=I01 the numerical results regardless of the radial *
grid employed can be accepted as accurate to within 3.6% for X >8XI0
-5
.
The results of Table 2 indicate that for coarse radial grids Nu . is X dependent on the expression employed in approximating the wall thermal gradient, the arbitrariness so introduced further attests to the unsuitability of such *
grids even though this becomes less pronounced for X =i0
-4
.
The integral
energy balance was incorporated into the code and the Nu . evaluated at X
Vol. 12, No. 2
Nu . a t X
~
N~CAL
selected
values
SOLUTIGNS TO THE GRAETZ P R ~
, TABLE 2 of X using three thermal
gradient
different
methods for wail
evaluation
M
3-Point
X*=10 -6 5-Point
LOG
21
59.345
82.017
38.674
27.951
25.304
22.641
ioi 130.561 ~ 301 109.811
116.340
109.474
22.558
22.514
22.517
108.761
109.026
22.519
22.517
22.517
,-,
21
96.607
131.316
63.548
24.014
20.904
22.802
~
101
113.856
103.208
109.203
22.568
22.560
22.560
"-~ 301
109.308
109.071
109.082
22.529
22.529
22.529
21
91.195
124.395
59.870
23.940
19.963
22.643
101
114.463
101.572
109.130
22.525
22.517
22.547
301
109.225
109.012
109.074
22.517
22.517
22.527
0°5
~ O II or.~ , .m w
X*=10 -6 for the coarse grid of M=21.
217
X*=10 -4 3-Point 5-Point
LOG
There is no noticeable improvement
(Nu ,=59.244) when compared with the corresponding value in Table I, an outX come similar to that obtained when the control volume method was utilized in discretizing the energy equation E83.
It is appropriate to comment that all
the results require about the same number of CPU seconds so there are no cost differences as far as computing is concerned. Based on the above, it may be concluded that very close to the entrance an optimal grid size, both in the radial and axial directions, is required and a simple redistribution of grid points may not eliminate the inaccuracy of the results.
As no exact solutions exist in general for the more compli-
cated entrance problems such as the d e v e l o p i n g
flow and heat transfer
in ducts, the findings cannot strictly be generalized, except in so far as they provide usable guidelines.
Prior results obtained with few grid-
lines may not be sufficiently accurate very near the entrance. Acknowledgements The authors are indebted to Professor W. Thorpe for providing extensive computer time on the Amdahl V7A of the McGill Computing Centre. Nomenclature a
- Coordinate spacing parameter
A
- Coordinate spacing parameter
218
N. Conley, A. Lawal and A.S. Y~/jumdar
M
Number of radial grid points
N
- Number of axial steps
Nu .
Local Nusselt number
Pe X
Peclet number = 2roPCpUm/k
r r
Vol. 12, No. 2
- Radial coordinate o
R
- Tube radius - Radial coordinate (dimensionless)
T
- Temperature
Te
- Entrance temperature
Tw
- Wall temperature
um
- Mean velocity
x
- Axial coordinate
X*
- Axial coordinate (dimensionless)
Greek Symbols: - Thermal diffusivity (pCp/k) - Radial coordinate @
- Temperature (dimensionless)
@b
- Bulk temperature (dimensionless) References
i.
R.K. Shah and A.L. London, Laminar Forced Convection in Ducts, Advances in Heat Transfer, New York; Academic Press.
2.
L. Graetz, On the Thermal Conductivity of Liquids, Part I; Ann. Phys. Chem. 18, 79 (1883).
3.
J.R. Sellers, M. Tribus and J.S. Klein, Heat Transfer to Laminar Flow in a Round Tube or Flat Conduit -- the Graetz Problem Extended, Trans. ASME 78, 441 (1956).
4.
M.A. Leveque, Les lois de la transmission de chaleur par convection, Ann. Mines, Mem., Ser. 1 2 1 3 , 201 (1928).
5.
F.W. Schmidt and B. Zeldin, Laminar Heat Transfer in the Entrance Region of Ducts, Applied Scientific Research 2_33, 73 (1970).
6.
U. Grigull and H. Tratz, Thermischer einlauf in ausgebildeter laminarer Rohrstromung, Int. J. Heat Mass Transfer 8, 669 (1965).
7.
M.W. Collins, Finite Difference Analysis for Developing Laminar Flow in Circular Tubes Applied to Forced and Combined Convection, Int. Journal for Numerical Methods in Engineering, 15, 381 (1980).
8.
N.A. Poirier, Numerical Solution of the Graetz Problem in the Entrance Region, Internal Report Chemical Eng. Dept. McGill University (1984).