On the Flutter of a Smooth Circular Cylinder in a Wake

Alan Simpson

doi:10.1017/S000192590000562X

Summary

The stability of a smooth circular cylinder, free to translate horizontally and vertically against linear springs in the wake from an identical neighbouring cylinder, is studied using quasi-static aerodynamic derivatives and simple flutter theory. It is found that at spacing values between ten and twenty cylinder diameters (typical of the spacings employed on “bundled” overhead transmission lines) classical flutter of the leeward cylinder can occur in a certain critical range of wind speeds at certain orientations of this cylinder in the wake. However, the occurrence of flutter appears to be conditional on a positive difference of natural frequency between vertical and horizontal motions of the leeward cylinder in still air.

Classical static instability (divergence) of the leeward cylinder is also shown to be possible over the entire “incidence” range in the wake, but this occurs in a much higher wind speed range than that associated with flutter.

References

1. Simpson, A. and Lawson, T. V. Oscillations of twin power transmission lines. Proceedings of the Symposium on Wind Effects, Loughborough University, April 1968.Google Scholar

2. Counihan, J. Lift and drag measurements on stranded cables. Report 117, Imperial College, London, August 1963.Google Scholar

3. Maekawa, T. Study of wind pressure against an ACSR double conductor. Electrical Engineering in Japan, Vol. 84 (2), February 1964.Google Scholar

4. Best, M. S. and Cook, N. J. The forces on a circular cylinder in shear flow. Aero Report 103, Bristol University (Undergraduate Thesis), June 1967.Google Scholar

5. Niblett, Ll. T. A graphical representation of the binary flutter equations in normal coordinates. ARC R & M 3496, 1968.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Simpson, Alan 1971. Wake Induced Flutter of Circular Cylinders: Mechanical Aspects. Aeronautical Quarterly, Vol. 22, Issue. 2, p. 101.

Wardlaw, R.L. Cooper, K.R. Ko, R.G. and Watts, J.A. 1975. Wind tunnel and analytical investigations into the aeroelastic behaviour of bundled conductors. IEEE Transactions on Power Apparatus and Systems, Vol. 94, Issue. 2, p. 642.

Price, S.J. 1975. Wake induced flutter of power transmission conductors. Journal of Sound and Vibration, Vol. 38, Issue. 1, p. 125.

Rawlins, C.B. 1976. Fundamental concepts in the analysis of wake-induced oscillation of bundled conductors. IEEE Transactions on Power Apparatus and Systems, Vol. 95, Issue. 4, p. 1377.

Simpson, A. and Tabarrok, B. 1976. An elementary appraisal of structural problems arising from the provision of twist in overhead line conductor bundles. International Journal of Mechanical Sciences, Vol. 18, Issue. 5, p. 229.

Simpson, A. and Flower, J.W. 1977. An improved mathematical model for the aerodynamic forces on tandem cylinders in motion with aeroelastic applications. Journal of Sound and Vibration, Vol. 51, Issue. 2, p. 183.

Tsui, Y.T. 1978. Two-dimensional stability analyses of a circular conductor in the wake of another. Electric Power Systems Research, Vol. 1, Issue. 2, p. 87.

Oliveira, Agamenon and Mansour, William 1985. Nonlinear Analysis of Wake-Induced Oscillations. IEEE Transactions on Power Apparatus and Systems, Vol. PAS-104, Issue. 3, p. 727.

Tsui, Y.T. 1986. On wake-induced vibration of a conductor in the wake of another via a 3-D finite element method. Journal of Sound and Vibration, Vol. 107, Issue. 1, p. 39.

Price, S.J. and Piperni, P. 1988. An investigation of the effect of mechanical damping to alleviate wake-induced flutter of overhead power conductors. Journal of Fluids and Structures, Vol. 2, Issue. 1, p. 53.

ZDRAVKOVICH, M M 1988. Advances in Wind Engineering. p. 183.

Parkinson, Geoffrey 1989. Phenomena and modelling of flow-induced vibrations of bluff bodies. Progress in Aerospace Sciences, Vol. 26, Issue. 2, p. 169.

Price, S.J. and Abdallah, R. 1990. On the efficacy of mechanical damping and frequency detuning in alleviating wake-induced flutter of overhead power conductors. Journal of Fluids and Structures, Vol. 4, Issue. 1, p. 1.

Price, S.J. and Maciel, Y. 1990. Solution of the nonlinear equations for wake-induced flutter via the Krylov and Bogoliubov method of averaging. Journal of Fluids and Structures, Vol. 4, Issue. 5, p. 519.

Wardlaw, R.L. 1990. Wind effects on bridges. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 33, Issue. 1-2, p. 301.

Brito, J.L.V. and Riera, J.D. 1995. Aerodynamic instability of cylindrical bluff bodies in non-homogeneous flow. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 57, Issue. 1, p. 81.

Zhu, S. Cai, Y. and Chen, S. S. 1995. Experimental Fluid-Force Coefficients for Wake-Induced Cylinder Vibration. Journal of Engineering Mechanics, Vol. 121, Issue. 9, p. 1003.

Crawley, Edward F. Curtiss, Howard C. Peters, David A. Scanlan, Robert H. and Sisto, Fernando 1995. A Modern Course in Aeroelasticity. Vol. 32, Issue. , p. 297.

Kern, G. and Maitz, A. 1998. Normal form transformation and an application to a flutter-type of vibration. International Journal of Non-Linear Mechanics, Vol. 33, Issue. 5, p. 741.

Sri Namachchivaya, N. and Vedula, Lalit 2000. Stabilization of linear systems by noise: Application to flow induced oscillations. Dynamics and Stability of Systems, Vol. 15, Issue. 2, p. 185.

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On the Flutter of a Smooth Circular Cylinder in a Wake

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