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A numerical investigation on capturing the maximum transverse amplitude in vortex induced vibration for low mass ratio.

Authors :
Kang, Zhuang
Ni, Wenchi
Sun, Liping
Source :
Marine Structures. Mar2017, Vol. 52, p94-107. 14p.
Publication Year :
2017

Abstract

According to Jauvtis and Williamson's experiment, when the mass ratio is 2.6, the maximum transverse amplitude of the cylinder reaches 1.5 D in the super-upper branch. Many researchers have tried to capture the maximum transverse amplitude in numerical simulation. However, according to the existing references, few of the numerical results can reach such amplitude and the maximum vibration amplitudes are obviously smaller than the experimental values. In order to get more accurate results, a modified SST turbulence model is applied for the numerical simulations based on OpenFOAM. The influence of the magnitude of inflow acceleration in numerical simulation is also investigated. Firstly, the performance of modified SST model is tested by example of flow around a circular cylinder. Secondly, the appropriate inflow acceleration magnitude is determined by analyzing the numerical response under different acceleration magnitudes, finding that the inflow acceleration must be less than 0.017 per normalization time in order to capture the maximum transverse amplitude. Then, the two degrees of freedom vortex induced vibration of a cylinder with a mass ratio of 2.6 and reduced velocity from 2 to 14 is simulated. The numerical results are compared in detail with the experimental data and the maximum transverse amplitude, mutations of phase angle between lift force and displacement, the characteristics and change trends of the trajectory as well as the “2T” vortex model are captured clearly. The results show that the maximum transverse amplitude can be captured more accurately with modified SST turbulence model and appropriate inflow acceleration value. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
09518339
Volume :
52
Database :
Academic Search Index
Journal :
Marine Structures
Publication Type :
Academic Journal
Accession number :
120799153
Full Text :
https://doi.org/10.1016/j.marstruc.2016.11.006