A brief review of damping is followed by a comparison of three sets of lift-force data for circular cylinders, subjected only to transverse oscillation. Then the significance of two-dimensional or biharmonic oscillations (in both the in-line and transverse directions) is discussed in light of experiments undertaken for that purpose, to simulate more closely the true nature of flow-induced oscillations.
Issue Section:
Research Papers
1.
Alexander
C. M.
1981
, “The Complex Vibrations and Implied Drag of a Long Oceanographic Wire in Cross-Flow
,” Ocean Engineering
, Vol. 8
, No. 4
, pp. 379
–406
.2.
Anaturk
A. R.
Tromans
P. S.
van Hazendonk
H. C.
Sluis
C. M.
Otter
A.
1992
, “Drag Force on Cylinders Oscillating at Small Amplitude: A New Model
,” ASME JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING
, Vol. 114
, pp. 91
–103
.3.
Bishop
R. E. D.
Hassan
A. Y.
1963
, “The Lift and Drag Forces on a Circular Cylinder in a Flowing Fluid
,” Proceedings Royal Society, London
, Vol. 277A
, pp. 32
–50
.4.
Feng, C. C., 1968, “The Measurement of Vortex-Induced Effects in Flow Past Stationary and Oscillating Circular and D-Section Cylinders,” M.A. Sc. thesis, University of British Columbia, Vancouver, B.C., Canada.
5.
Gopalkrishnan, R., 1992, “Vortex-Induced Forces on Oscillating Bluff Cylinders,” Ph.D. thesis, Massachusetts Institute of Technology, Cambridge, MA.
6.
Gopalkrishnan, R., Grosenbaugh, M. A., and Triantafyllou, M. S., 1992, “Amplitude-Modulated Cylinders in Constant Flow: Fundamental Experiments to Predict Response in Shear Flow,” Proceedings of Bluff-Body/Fluid and Hydraulic Machine Interactions, ASME PVP-Vol. 245, Book No. G00727-1992, pp. 87–101.
7.
Griffin, O. M., 1985a, “Vortex-Induced Vibrations of Marine Cables and Structures,” NRL Memorandum Report 5600, Naval Research Laboratory, Washington, DC.
8.
Griffin
O. M.
1985
b, “Vortex Shedding from Bluff Bodies in a Shear Flow: A Review
,” ASME Journal of Fluids Engineering
, Vol. 107
, pp. 298
–306
.9.
Griffin
O. M.
Hall
M. S.
1991
, “Review-Vortex Shedding Lock-on and Flow Control in Bluff Body Wakes
,” ASME Journal of Fluids Engineering
, Vol. 113
, pp. 526
–537
.10.
Griffin, O. M., 1994, private communication; copy of the tabulated data may be obtained either from Dr. Griffin or from the author.
11.
Haritos, N., 1989, “Dynamic Response of Offshore Structures to Environmental Loading,” Research Report Struc/01/89, Department of Civil and Agricultural Engineering, University of Melbourne, Australia.
12.
Iwan
W. D.
Botelho
D. L. R.
1985
, “Vortex Induced Oscillation of Structures in Water
,” Journal of Waterways, Port, Coastal and Ocean Division
, ASCE, Vol. 111
, No. WW2
, pp. 289
–303
.13.
Iwan
W. D.
Jones
N. P.
1987
, “On the Vortex-Induced Oscillation of Long Structural Elements
,” ASME Journal of Energy Resources Technology
, Vol. 109
, pp. 161
–167
.14.
Kim
Y.-H.
Vandiver
J. K.
Holler
R.
1986
, “Vortex-Induced Vibration and Drag Coefficients of Long Cables Subjected to Sheared Flows
,” ASME Journal of Energy Resources Technology
, Vol. 108
, pp. 77
–83
.15.
Mercier, J. A., 1973, “Large Amplitude Oscillations of a Circular Cylinder in a Low-Speed Stream,” Ph.D. dissertation, Stevens Institute of Technology.
16.
Moe
G.
Wu
Z.-J.
1990
, “The Lift Force on a Cylinder Vibrating in a Current
,” ASME JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING
, Vol. 112
, pp. 297
–303
.17.
Moe, G., Holden, K., and Yttervoll, P. O., 1994, “Motion of Spring Supported Cylinders in Subcritical and Critical Flows,” Proceedings Fourth Offshore and Polar Engineering Conference, Osaka, Japan, Vol. III, pp. 468–475.
18.
Pantazopoulos, M. S., 1994, “Vortex-Induced Vibration Parameters: Critical Review,” Proceedings of the Offshore Mechanics and Arctic Engineering Conference, Vol. 1, pp. 199–254.
19.
Patrikalakis
N. M.
Chryssostomidis
C.
1985
, “Vortex-Induced Response of a Flexible Cylinder in a Constant Current
,” ASME Journal of Energy Resources Technology
, Vol. 107
, pp. 244
–249
.20.
Sarpkaya, T., 1977, “Transverse Oscillations of a Circular Cylinder in Uniform Flow, Part I,” Report No. NPS-69SL77071, Naval Postgraduate School, Monterey, CA, July 20.
21.
Sarpkaya
T.
1978
, “Fluid Forces on Oscillating Cylinders
,” Journal of Waterways, Port, Coastal and Ocean Division
, Vol. 104
, No. WW4
, pp. 275
–290
.22.
Sarpkaya
T.
1979
, “Vortex-Induced Oscillations—A Selective Review
,” ASME Journal of Applied Mechanics
, Vol. 46
, pp. 241
–258
.23.
Sarpkaya
T.
1986
a, “Force on a Circular Cylinder in Viscous Oscillatory Flow at Low Keulegan-Carpenter Numbers
,” Journal of Fluid Mechanics
, Vol. 165
, pp. 61
–71
.24.
Sarpkaya, T., 1986b, “In-Line and Transverse Forces on Smooth and Rough Cylinders in Oscillatory Flow at High Reynolds Numbers,” Technical Report No. NPS-69-86-003, Naval Postgraduate School, Monterey, CA.
25.
Sarpkaya
T.
1987
, “Oscillating Flow About Smooth and Rough Cylinders
,” ASME JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING
, Vol. 109
, pp. 307
–313
.26.
Sarpkaya, T., 1994, “Unsteady Flows: A Selective Review,” to appear in Handbook of Fluid Dynamics, ed., Joseph A. Schetz, McGraw-Hill, New York, NY.
27.
Stansby
P. K.
1974
, “The Effects of End Plates on the Base Pressure Coefficient of a Circular Cylinder
,” Aeronautical Journal
, Vol. 87
, pp. 36
–37
.28.
Staubli
T.
1983
, “Calculation of the Vibration of an Elastically Mounted Cylinder Using Experimental Data From Forced Oscillation
,” Journal of Fluids Engineering
, Vol. 105
, pp. 225
–229
.29.
Wang
C.-Y.
1968
, “On High-Frequency Oscillating Viscous Flows
,” Journal of Fluid Mechanics
, Vol. 32
, pp. 55
–68
.30.
Williamson
C. H. K.
Roshko
A.
1988
, “Vortex Formation in the Wake of an Oscillating Cylinder
,” Journal of Fluids and Structures
, Vol. 2
, pp. 355
–381
.31.
Zdravkovich
M. M.
1982
, “Modification of Vortex Shedding in the Synchronization Range
,” ASME Journal of Fluids Engineering
, Vol. 104
, pp. 513
–517
.
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