Numerical simulations have been performed to study the stability of heated, incompressible Taylor-Couette flow for a radius ratio of 0.7 and a Prandtl number of 0.7. As Gr is increased, the Taylor cell that has the same direction of circulation as the natural convection current increases in size and the counterrotating cell becomes smaller. The flow remains axisymmetric and the average heat transfer decreases with the increase in Gr. When the cylinder is impulsively heated, the counterrotating cell vanishes and n = 1 spiral is formed for Gr = 1000. This transition marks an increase in the heat transfer due to an increase in the radial velocity component of the fluid. By slowly varying the Grashof number, the simulations demonstrate the existence of a hysteresis loop. Two different stable states with same heat transfer are found to exist at the same Grashof number. A time-delay analysis of the radial velocity and the local heat transfer coefficient time is performed to determine the dimension at two Grashof numbers. For a fixed Reynolds number of 100, the two-dimensional projection of the reconstructed attractor shows a limit cycle for Gr = −1700. The limit cycle behavior disappears at Gr = −2100, and the reconstructed attractor becomes irregular. The attractor dimension increases to about 3.2 from a value of 1 for the limit cycle case; similar values were determined for both the local heat transfer and the local radial velocity, indicating that the dynamics of the temperature variations can be inferred from that of the velocity variations.

1.
Ball
K. S.
,
Farouk
B.
, and
Dixit
V. C.
,
1989
, “
An experimental study of heat transfer in a vertical annulus with a rotating inner cylinder
,”
Int. J. Heat Mass Transfer
, Vol.
32
, No. 8, pp.
1517
1527
.
2.
Brandstater
A.
, and
Swinney
H. L.
,
1987
, “
Strange attractors in weakly turbulent Couette-Taylor flow
,”
Phys. Rev. A
, Vol.
35
, No.
5
, pp.
2207
2220
.
3.
Chen
J.
, and
Kuo
J.
,
1990
, “
The linear stability of steady circular Couette flow with a small radial temperature gradient
,”
Phys. Fluids A
, Vol.
2
, No.
9
, pp.
1585
1591
.
4.
Coles
D.
,
1965
, “
Transition in circular Couette flow
,”
J. Fluid Mech.
, Vol.
21
, pp.
385
425
.
5.
Farmer, J. Doyne, Ott, E., and Yorke, J. A., 1983, “The dimension of chaotic attractors,” Physica 7D, pp. 153–180.
6.
Fraser
A. M.
, and
Swinney
H. L.
,
1986
, “
Independent coordinates for strange attractors from mutual information
,”
Physical Review A
, Vol.
33
, No.
2
, pp.
1134
1140
.
7.
Kataoka
K.
,
Doi
H.
, and
Komai
T.
,
1977
, “
Heat/Mass transfer in Taylor vortex flow with constant axial flow rates
,”
Int. J. Heat Mass Transfer
, Vol.
20
, pp.
57
63
.
8.
Kedia, R., 1997, “An investigation of velocity and temperature fields in Taylor-Couette flows,” Ph.D. thesis, California Institute of Technology, Pasadena, CA.
9.
Kedia
R.
,
Hunt
M. L.
, and
Colonius
T.
,
1998
, “
Numerical Simulations of Heat Transfer in Taylor-Couette Flows
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
120
, pp.
65
71
.
10.
Koschmieder, E. L., 1993, Benard Cells and Taylor Vortices, Cambridge University Press, New York.
11.
Kuo
D. C.
, and
Ball
K. S.
,
1997
, “
Taylor-Couette flow with buoyancy: Onset of spiral flow
,”
Phys. Fluids A
, Vol.
9
, No.
10
, pp.
2872
2884
.
12.
Lathrop
D. P.
,
Fineberg
J.
, and
Swinney
H. L.
,
1992
, “
Turbulent flow between concentric rotating cylinders at large Reynolds number
,”
Physical Review Letters
, Vol.
68
, No.
10
, pp.
1515
1518
.
13.
Narabayashi, T., Miyano, H., Komita, H., Iikura, T., Shiina, K., Kato, K, Watanabe, A., and Takahashi, Y., 1993, “Study on temperature fluctuation mechanisms in an annulus gap between PLR Pump shaft and casing cover,” Proceedings of the Second ASME/JSME Joint Conference on Nuclear Engineering, P. F. Peterson, ed., Mar. 21–24, San Francisco, CA, ASME, New York.
14.
Takens, F., 1981, “Detecting strange attractors in turbulence,” Lecture Notes in Mathematics, 898, D. Rand and L. S. Young, eds., Springer, Berlin, pp. 366–381.
15.
Taylor
G. I.
,
1923
, “
Stability of a viscous liquid contained between two rotating cylinders
,”
Phils. Trans. R. Soc. London
, Vol.
A223
, pp.
289
343
.
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