The study focuses on the in-place hydrodynamic behavior and Flow Induced Response of a novel design of Free Standing Riser (FSR) system tensioned by a 'Flat-Buoy'. The paper presents results review of both Experimental and Numerical approaches initiated in the framework of a comprehensive Research & Development program. Experimental and numerical study conclusions converge on the excellent hydrodynamic Stability of such FSR system. First, wind tunnel campaign, based on Reynolds similitude, has focused on the flow features over the fixed Flat Buoy. No Vortex Shedding has been clearly highlighted. Moreover, results have pointed out a more pronounced dependence of the hydrodynamic coefficients to the flow incidence than to the Reynolds number. Secondly, basin model tests, based on Reduced Velocity similitude, have highlighted the stability of such scaled FSR system concluding to maximum Cross-Flow and In-Line amplitude such as A/D<0.35 (A represents the amplitude and D the Buoy diameter). In parallel, hydrodynamic stability has been investigated Benchmarking Computational Fluid Dynamic (CFD) methods. Preliminary validation steps have pointed out ability of such CFD approaches to globally predict both Wind Tunnel and Basin Test results. Finally, extending CFD and Fluid Structure Interaction (FSI) modeling to full-scale configuration, stability of the FSR tensioned by a Flat-Buoy has been proved.
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机译:这项研究的重点是通过“平板浮标”张紧的新型立式立管(FSR)系统的就地流体力学行为和流致响应。本文介绍了在综合研究与开发计划的框架内启动的实验方法和数值方法的结果回顾。实验和数值研究的结论都集中在这种FSR系统的出色的水动力稳定性上。首先,基于雷诺兹相似性的风洞运动着重于固定平板浮标上的流动特征。没有清楚地突出显示涡旋脱落。此外,结果指出,流体动力学系数对流体入射的依赖性比对雷诺数的依赖性更大。其次,基于降低的速度相似性的流域模型测试强调了这种缩放后的FSR系统的稳定性,包括最大的错流和管道内振幅,例如A / D <0.35(A代表振幅,D代表浮标直径) 。同时,对水动力稳定性进行了基准计算流体动力(CFD)标定研究。初步的验证步骤指出了这种CFD方法能够全面预测风洞和盆地测试结果的能力。最后,将CFD和流体结构相互作用(FSI)建模扩展到全尺寸配置,证明了用平板浮标拉紧的FSR的稳定性。
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