Full-Scale Reynolds Number VIV Testing of Tri-Helically Grooved Drill Riser Buoyancy Module

Gaskill, Collin; Wu, Jie; Yin, Decao

doi:10.1115/omae2018-78605

Volume 2: CFD and FSI 2018

DOI: 10.1115/omae2018-78605

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Full-Scale Reynolds Number VIV Testing of Tri-Helically Grooved Drill Riser Buoyancy Module

Collin Gaskill¹,

Jie Wu

Decao Yin

Abstract: A newly developed Tri-Helically Grooved drilling riser buoyancy module design was tested in the towing tank of SINTEF Ocean in June 2017. This new design aims to reduce riser drag loading and suppress vortex-induced vibrations (VIV). Objectives of the test program were two-fold: to assess the hydrodynamic performance of the design allowing for validation of previous computational fluid dynamics (CFD) studies through empirical measurements, and, to develop a hydrodynamic force coefficient database to be used in… Show more

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CFD Hydrodynamic Performance Comparison between Conventional and VIV-Mitigating Buoyancy Modules

Lai

2018

IADC/SPE Drilling Conference and Exhibition

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Vortex-induced vibration (VIV) is a significant factor in causing cyclic stress and fatigue damage in drilling risers. A new design of drill riser buoyancy is introduced with tri-helical grooves formed into the module to mitigate against VIV. The focus of this work is to characterize the hydrodynamic performance improvement of this new design helically grooved buoyancy over the conventional buoyancy design. Computational fluid dynamics (CFD) is employed to simulate the buoyancy module hydrodynamic behavior in 3-d space. A current speed representative of offshore environment corresponding to Re = 106 is considered using a Reynolds-averaged (k-epsilon) turbulence model. This methodology is based on previously validated domain, mesh and temporal independence studies for a circular cylinder that also showed agreement with published literature. The hydrodynamic performance is characterized primarily by the in-line and cross-flow drag coefficients Cdx and Cdy. For the helical buoyancy, Cdx is benchmarked between CFD simulation and physical town tank testing which showed similar results. Direct comparison of Cdx for the static buoyancy module (bluff body) sees Cdx being higher for the helical form compared to the circular form due to the circular form's inherent drag crisis characteristic. However simply comparing Cdx would be erroneous. A complete hydrodynamic performance representation requires the consideration of the full flow field and Cdy. This exposes that periodic vortex shedding occurs for the circular form but is mitigated for the helical form. Vortex shedding occurring for the circular form results in significantly larger Cdy values as well as potentially larger dynamic Cdx for a non-fixed bluff body. For the helically grooved form, vortex shedding is successfully mitigated and Cdy is significantly lower. The helical grooves form channels that allow flow along different directions away from the free-field flow directions which function to disrupt the downstream regular flow order. This prevents the regular formation of vortex shedding in the wake of the riser which is a pre-cursor to VIV. The omnidirectional nature of the helical grooves also ensures this mechanism for breaking regular flow is achievable regardless of the environmental current direction acting on the riser. VIV is an increasingly significant problem with deep-water exploration in harsh weather environments. The new buoyancy design provides passive vortex shedding mitigation to top-tensioned risers which would reduce the propensity of VIV occurrence.

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CFD Hydrodynamic Performance Comparison between Conventional and VIV-Mitigating Buoyancy Modules

Lai

2018

IADC/SPE Drilling Conference and Exhibition

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VIV-Mitigating Buoyancy Module Performance Characterization Using Computational Fluid Dynamics

Lai

2018

Day 3 Wed, May 02, 2018

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A new design of drill riser buoyancy is introduced with tri-helical grooves formed into the module. The primary purpose is to mitigate vortex-induced vibration (VIV) of the riser string which is a significant factor in causing riser cyclic stress and fatigue damage. Computational fluid dynamics (CFD) is employed to simulate the buoyancy module hydrodynamic behavior. A range of representative offshore environments is considered using a Reynolds-averaged (k-epsilon) turbulence model in 3-dimensional space. The hydrodynamic performance is mainly characterized in terms of the in-line and cross-flow drag coefficients (Cdk, Cdy) and lift coefficients (Cl). The CFD results show comparable drag coefficients with tow-tank testing data performed at SINTEF in Trondheim, Norway in July 2017. Cdx is shown to be consistent at approximately 0.60 – 0.65 for the Re = 105 – 107 range whereas Cdy and Cl approximates zero and is negligible. This, evaluated from a global riser perspective, means the riser has a predictably consistent drag performance with little variation in cross-flow and axial motion. The helical grooves form channels that divert flow axially away from the free-field flow directions which functions to disrupt regular flow order. This prevents the formation of a von Karman vortex street which is a requirement for vortex-induced vibration. The omni-directional nature of the helical grooves ensures this mechanism for breaking regular flow is achievable regardless of the environmental current direction acting on the riser. VIV is an increasingly significant problem with deep-water exploration in harsh weather environments. The new buoyancy design provides passive vortex shedding mitigation to top-tensioned risers which would reduce the propensity of VIV occurrence.

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Full-Scale Reynolds Number VIV Testing of Tri-Helically Grooved Drill Riser Buoyancy Module

Cited by 2 publications

References 0 publications

CFD Hydrodynamic Performance Comparison between Conventional and VIV-Mitigating Buoyancy Modules

CFD Hydrodynamic Performance Comparison between Conventional and VIV-Mitigating Buoyancy Modules

VIV-Mitigating Buoyancy Module Performance Characterization Using Computational Fluid Dynamics

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