期刊
INTERNATIONAL JOURNAL OF PRESSURE VESSELS AND PIPING
卷 194, 期 -, 页码 -出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.ijpvp.2021.104559
关键词
Vortex-induced vibration; Flow-induced vibration; Multi-modal interaction; Time-frequency-energy
资金
- National Natural Science Foundation of China [41776105]
- Zhejiang Province Natural Science Foundation [LY20E090003]
- Basic Science Research Fund for Universities of Zhejiang Province [2021JD002]
The study found that both external current and internal flow play important roles in determining vibration modes, with vibration intensity closely associated with internal flow velocity. Increasing internal flow velocity can excite new vibration mode responses.
The coupling response of flexible pipe subject to external shear current and internal uniform flow is numerically investigated in this paper. Firstly, without the internal flow being considered, the quantified comparisons of root mean square vibration amplitudes in relation with VIV responses between the numerical results and experimental data were made to verify the efficiency of numerical method. Subsequently, the instantaneous root mean square vibration amplitudes, spanwise waveforms, and 3D time-frequency-energy spectra related to the numerical results were analyzed in detail. It is found that both the external current and internal flow play important roles in determining the vibration modes, and that the vibration intensity is tightly associated with the internal flow velocity. It is worth noting that the increase of internal flow velocity can excite new vibration mode response. The position-depended mono- and multi-modal coexistence, multi-modal dominance, mode switch/shift and fluid-structure interaction are clearly observed along the pipe span, followed by the alternative occurrence of standing and traveling waveforms, due to the combination of vortex-induced vibration and flowinduced vibration.
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