管内顶动对柔性隔水管涡激振动响应影响的实验研究

Wei Yang, Ma Chuanzhen, K. Zhuang, Zhang Cheng, Lian Shaojie
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摘要

为了了解柔性立管顶动与涡激振动的关系,本文对柔性立管的涡激振动与顶动激励进行了实验研究。立管可以垂直安装,直径为2厘米,长度为5米。详细分析了均匀流中不同激励幅值和频率条件下的幅值、频率等参数的响应。结果表明,与纯涡激振动试验相比,涡激振动和顶动激励对柔性圆柱响应有显著影响。振幅分析结果表明,当减速速度较小时(小于15左右),顶动激励对直线方向的振幅有重要影响。而直线方向的激励幅值和频率对横流方向的激励幅值影响不大。频率分析结果表明:当降速较小时(小于5左右),不同激励下立管运动幅值较小且不规则;当降速较大时(5 < Ur < 55),管内振动频率为横流振动频率的2倍。顶动激励频率与振动频率之间也存在较强的联系。综上所述,考虑顶动激励的涡动腔观察到的一些现象和特征与经典涡动腔有所不同,可为涉及浮体效应的涡动腔研究提供基础参考。
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Experimental Investigation of the Effects of the In-Line Top-Motion on the Vortex-Induced Vibration Response of a Flexible Riser
In order to understand the relation between top-motion and VIV of flexible risers, this paper presents an experimental investigation on concomitant vortex-induced vibration and top-motion excitation with flexible risers. The riser can was mounted vertically, with the diameter of 2 cm and the length of 5 m. The responses of amplitude, frequency and other parameters were analyzed in detail under conditions of different excitation amplitude and frequency in uniform flow. It was found that the concomitant VIV and top-motion excitation significantly affects the flexible cylinder response when compared to the pure VIV tests. The amplitude analysis results show that when the reduced velocity is small (less than about 15), the top-motion excitation has an important influence on amplitude of in-line directions. However, the excitation amplitude and frequency of in-line direction have a little influence on amplitude of cross flow direction. The frequency analysis results show that when the reduced velocity is small (less than about 5), the riser motion amplitude is small and irregular in different excitation and when the reduced velocity is large (5 < Ur < 55), the in-line vibration frequency is two times the cross-flow vibration frequency. A strong connection between the top-motion excitation frequency and the vibration frequency was also found. Overall, some phenomena and characteristics observed in the VIV considering top-motion excitation are different from those in classic VIV, which may provide basic reference for the VIV investigation involving the effect of floating bodies.
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