Naphthalene sublimation experiments have been conducted to study the effects of channel orientation, rotational Coriolis force, and a sharp turn, on the local heat (mass) transfer distributions in a two-pass square channel with a sharp turn and smooth walls, rotating about a perpendicular axis. The test channel was oriented so that the direction of rotation was perpendicular to or at a 45 deg angle to the leading and trailing walls. The Reynolds number was kept at 5,500 and the rotation number ranged up to 0.24. For the radial outward flow in the first straight pass of the diagonally oriented channel, rotation-induced Coriolis force caused large monotonic spanwise variations of the local mass transfer on both the leading and trailing walls, with the largest mass transfer along the outer edges of both walls. Rotation did not lower the spanwise average mass transfer on the leading wall and did not increase that on the trailing wall in the diagonally oriented channel as much as in the normally oriented channel. The combined effect of the channel orientation, rotation, and the sharp turn caused large variations of the local mass transfer distributions on the walls at the sharp turn and immediately downstream of the sharp turn. The velocity fields that were obtained with a finite difference control-volume-based computer program helped explain how rotation and channel orientation affected the local mass transfer distributions in the rotating two-pass channel.

Issue Section:
Forced Convection
Keywords:
Convection, Experimental, Heat Transfer, Mass Transfer, Rotating, Turbines
Topics:
Heat, Mass transfer, Rotation, Coriolis force, Computer software, Convection, Flow (Dynamics), Heat transfer, Reynolds number, Turbines
1.
Ambrose
D.
,
Lawrenson
I. J.
, and
Sprake
C. H. S.
,
1975
, “
The Vapor Pressure of Naphthalene
,”
Journal of Chem. Thermodynamics
, Vol.
7
, pp.
1173
1176
.
2.
Dutta, S., Andrews, M. J., and Han, J. C., 1994, “Numerical Prediction of Turbulent Heat Transfer in a Rotating Square Duct with Variable Rotational Buoyancy Effects,” ASME HTD-Vol. 271, ASME, New York, pp. 161–170.
3.
Goldstein
R. J.
, and
Cho
H. H.
,
1995
, “
A Review of Mass Transfer Measurements Using Naphthalene Sublimation
,”
Experimental Thermal and Fluid Science
, Vol.
10
, pp.
416
434
.
4.
Han
J. C.
,
Zhang
Y. M.
, and
Kalkuehler
K.
,
1993
, “
Uneven Wall Temperature Effect on Local Heat Transfer in a Rotating Two-Pass Square Channel With Smooth Walls
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
115
, pp.
912
920
.
5.
Kline
S. J.
, and
McClintock
F. A.
,
1953
, “
Describing Uncertainties in Single Sample Experiments
,”
Mechanical Engineering
, Vol.
75
, pp.
3
8
.
6.
Launder
B. E.
,
1989
, “
Second-Moment Closure: Present. . .and Future?
,”
International Journal of Heat and Fluid Flow
, Vol.
10
, pp.
282
300
.
7.
Launder
B. E.
,
Reece
G. J.
, and
Rodi
W.
,
1975
, “
Progress in the Development of a Reynolds-Stress Turbulence Closure
,”
Journal of Fluid Mechanics
, Vol.
68
, pp.
537
566
.
8.
Launder, B.E., and Spalding, D. B., 1973, “The Numerical Computation of Turbulent Flows,” Imperial College of Science and Technology, London, England, NTIS N74-12066.
9.
McGrath, D. B., and Tse, D. G. N., 1995, “A Combined Experimental/Computational Study of Flow in Turbine Blade Passage: Part II—Computational Investigation,” ASME Paper 95-GT-149.
10.
McMillin
R. D.
, and
Lau
S. C.
,
1994
, “
Effect of Trailing-Edge Ejection on Local Heat (Mass) Transfer in Pin Fin Cooling Channels in Turbine Blades
,”
ASME Journal of Turbomachinery
, Vol.
116
, pp.
159
168
.
11.
Park
C. W.
,
Lau
S. C.
, and
Kukreja
R. T.
,
1998
a, “
Heat/Mass Transfer Distribution in a Rotating Two-Pass Square Channel—Part II: Local Heat Transfer, Smooth Channel
,”
International Journal of Rotating Machinery
, Vol.
4
, No.
1
, pp.
1
15
.
12.
Park
C. W.
,
Lau
S. C.
, and
Kukreja
R. T.
,
1998
b, “
Heat/Mass Transfer in a Rotating Two-Pass Square Channel With Transverse Ribs
,”
Journal of Thermophysics and Heat Transfer
, Vol.
12
, pp.
80
86
.
13.
Sparrow
E. M.
, and
Tao
W. Q.
,
1983
, “
Enhanced Heat Transfer in a Flat Rectangular Duct with Streamwise-Periodic Disturbances at One Principal Wall
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
105
, pp.
851
861
.
14.
Prakash
C.
, and
Zerkle
R.
,
1992
, “
Prediction of Turbulent Flow and Heat Transfer in a Radially Rotating Square Duct
,”
ASME Journal of Turbomachinery
, Vol.
114
, pp.
835
846
.
15.
Tekriwal
P.
,
1994
, “
Heat Transfer Predictions with Extended k-ε Turbulence Model in Radial Cooling Ducts Rotating in Orthogonal Mode
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
116
, pp.
369
380
.
16.
Tse, D. G. N., and McGrath, D. B., 1995, “A Combined Experimental/Computational Study of Flow in Turbine Blade Passage: Part I—Experimental Study,” ASME Paper 95-GT-355.
17.
Wagner
J. H.
,
Johnson
B. V.
, and
Yeh
F. C.
,
1991
, “
Heat Transfer in Rotating Serpentine Passages With Smooth Walls
,”
ASME Journal of Turbomachinery
, Vol.
113
, pp.
321
330
.
This content is only available via PDF.
Copyright © 1998
 by The American Society of Mechanical Engineers
You do not currently have access to this content.