论文信息 - Vibration frequency and lock-in bandwidth of tensioned, flexible cylinders experiencing vortex shedding

Vibration frequency and lock-in bandwidth of tensioned, flexible cylinders experiencing vortex shedding

Abstract In-water vortex-induced vibration (VIV) tests of top-tensioned, flexible cylindrical structures were conducted at Shell Westhollow Technology Center current tank. These tests revealed that the top tension and structural stiffness (both lateral and axial) can have a significant impact on vibration frequencies. During lock-in between the vortex-shedding frequency and the structure's natural frequency, the increase of the vibration frequency with flow speeds is strongly related to the rise of the axial tension. After an initial abrupt rise, the vibration frequency of a bending-stiffness-dominated structure only increased slightly during lock-in. Alternative explanations are provided on why the vibration frequency does not rise significantly but there can still exist a broad lock-in band, and why a more massive structure has a narrower lock-in bandwidth.

Li Lee | Don W. Allen | Li Lee | D. Allen

[1] R. Clough,et al. Dynamics Of Structures , 1975 .

[2] Li Lee,et al. The formula for motion magnitudes of cylinders experiencing vortex-shedding , 2009 .

[3] E. Achenbach. Influence of surface roughness on the cross-flow around a circular cylinder , 1971, Journal of Fluid Mechanics.

[4] J. K. Vandiver,et al. Dimensionless Parameters Important to the Prediction of Vortex-Induced Vibration of Long, Flexible Cylinders in Ocean Currents , 1993 .

[5] Charles H. K. Williamson,et al. Resonance forever: existence of a critical mass and an infinite regime of resonance in vortex-induced vibration , 2002, Journal of Fluid Mechanics.

[6] T. Sarpkaya. Fluid Forces on Oscillating Cylinders , 1978 .

[7] T. Sarpkaya. Vortex-Induced Oscillations: A Selective Review , 1979 .

[8] Li Li,et al. THE OCCURRENCE OF LOCK-IN UNDER HIGHLY SHEARED CONDITIONS , 1996 .

[9] Finn Gunnar Nielsen,et al. Large Scale Model Testing Of Deep Sea Risers , 1998 .

[10] D. W. Allen,et al. Surface Roughness Effects on Vortex-Induced Vibration of Cylindrical Structures at Critical and Supercritical Reynolds Numbers , 2001 .

[11] Charles Sparks,et al. Transverse Modal Vibrations of Vertical Tensioned Risers. a Simplified Analytical Approach , 2002 .

[12] Owen M. Griffin,et al. The Resonant, Vortex-Excited Vibrations of structures and Cable Systems , 1975 .

[13] M. Gharib. Vortex-induced vibration, absence of lock-in and fluid force deduction , 1999 .