Abstract
The vortex-induced vibration test of the deep-sea riser was carried out with different excitation water depths in the wave-current combined water flume. By dimensionally changing the multi-stage water depth and hydrodynamic parameters such as outflow velocity at various water depths, the dynamic response parameters such as dominant frequency, dimensionless displacement and vibration trajectory evolution process of the riser under different excitation water depths were explored to reveal the sensitive characteristics of the dynamic response of vortex-induced vibration of the risers under different excitation water depths. The results show that different excitation water depths will change the additional mass of the riser and the fluid damping and other parameters, which will affect the spatial correlation and stability of the vortex shedding behind the riser. In the lock-in region, the distribution range of the characteristic frequency becomes narrow and centered on the lock-in frequency. The increase of the excitation water depth gradually advances the starting point of the lock-in region of the riser, and at the same time promotes the excitation of the higher-order vibration frequency of the riser structure. Within the dimensionless excitation water depth, the dominant frequency and dimensionless displacement are highly insensitive to the excitation water depth at high flow velocity. The change of the excitation water depth will interfere with the correlation of the non-linear coupling of the riser. The “8-shaped” gradually becomes irregular, and the vibration trajectories of the riser show “O-shape”, “X-shape” and “Crescent-shape”.
Highlights
The deep-sea pipeline structure is used to connect offshore platform and seabed wellhead
The theoretical lock-in region outflow velocity ranges under different excitation water depths are about: [0.441, 0.552], [0.419, 0.523], [0.400, 0.501], [0.383, 0.479], [0.368, 0.460], and [0.357, 0.447]
The variation of frequency intensity under different excitation water depths is unstable versus the time
Summary
The deep-sea pipeline structure (referred to as “riser”) is used to connect offshore platform and seabed wellhead. It is the basic device for transporting oil and gas from seabed wellhead to platform and is a relatively complicated structure in the deep-sea oil and gas development system (Gao et al, 2015; Song et al, 2018; Liu et al, 2018). During the operation of the deep-sea oil and gas development system, high-pressure oil or airflow usually passes through the inside of the riser, and the outside needs to bear the action of complex marine environment load such as wave, current, ice and earthquake. The vortex can be alternately formed on both sides of the riser due to the action of the current, and the vortex shedding produces a periodic variable force, which makes the riser produce “vortex-induced vibration”(VIV) in the lift direction
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