顶部受强迫振荡的自由悬挂垂直管道的动力特性

Leonardo Sales, C. C. O. Trigo, L. C. Sevillano, C. Morooka
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引用次数: 0

摘要

垂直管的配置通常发生在井眼钻井、水下设备安装、深水进气立管等水下入井作业中,通常通过将海上立管悬挂在平台或船舶的顶部。简单的操作结构证明了它的广泛应用;然而,也有一些缺点,如应力集中,疲劳等问题。本研究的目的是通过对顶部被迫水平振荡的垂直管道的研究,提高对悬挂立管的理解,从而有助于克服这些问题。为此,通过机械装置在管道顶端施加振荡运动,建立了小口径管道模型的实验室实验。位移随时间的变化和沿管道长度的测量由光学测量系统。在本研究中,采用了一种数值模拟方案来支持对实验结果的评估。垂直管道的响应取决于几个参数,例如管道的总长度、频率和振荡本身的幅度等。由于振荡管道与周围水之间存在相对速度,沿管道长度方向会发生涡流脱落,影响隔水管的运动特性。实验和数值模拟的结果为描述和理解垂直管道的振荡行为、平面内和平面外的强迫顶部振荡提供了重要的见解。所获得的结果为海洋隔水管涡激振动(VIV)的建模提供了进一步的步骤,旨在促进相关技术的进步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dynamic Behaviour of a Free Hanging Vertical Pipe Forced to Oscillate at the Top
Vertical pipe configuration happens in subsea well re-entry operations for wellbore drilling, subsea equipment installations, deepwater intake risers, among other scenarios, usually by hanging the marine riser at the top from a platform or ship. The simple operational configuration justifies its wide application; however, there are some drawbacks such as stress concentration, fatigue, among other issues. The purpose of this study is to contribute for the overcoming of those problems by improving the understanding of hanging risers through investigations of a vertical pipe forced to oscillate horizontally at the top. For this purpose, laboratory experiments with small diameter pipe model have been developed with oscillatory motions applied at the top termination through a mechanical device. Displacements over time and along the pipe length were measured by an optical measurement system. In the present study, a numerical scheme has been implemented for simulations to support evaluations of the experimental results. A vertical pipe response depends on several parameters, such as pipe overall length, frequency and amplitude of oscillation itself, among others. Due to existing relative velocity between the oscillating pipe and the water surrounding it, vortex shedding occurs along the pipe length which influences riser motion behaviour. The results from experiment and numerical simulations bring important insights for describing and understanding oscillatory vertical pipe behaviour, in the plane and the out of plane of the forced top oscillation. The obtained results provide a further step toward the modelling of Vortex-Induced Vibration (VIV) in marine risers, aiming to contribute to relevant technological advancements.
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