Gravity anchors astride subsea pipelines subject to oscillatory and combined steady and oscillatory flows

This writing presents results of simulating oscillatory and combined steady and oscillatory flows past gravity anchors astride subsea pipelines. It can be considered a companion to a previous numerical study on steady currents past gravity anchors. The gravity anchor system comprises large arch-shap...

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Bibliographic Details
Published in:Volume 5: Ocean Engineering; CFD and VIV
Main Authors: Zhao, Xu, Cheng, Liang, Zhao, Ming (R16667), An, Hongwei, He, Wei
Other Authors: School of Computing, Engineering and Mathematics (Host institution), International Conference on Ocean, Offshore and Arctic Engineering (Event place)
Format: Conference Object
Language:English
Published: U.S., ASME 2012
Subjects:
090599 - Civil Engineering not elsewhere classified
850203 - Oil and Gas Extraction
pipelines
oscillatory flows
subsea
gravity anchors
steady flows
hydrodynamic loads
Petrov-Galerkin finite element method
Navier-Stokes equations
Arctic
Online Access:http://handle.uws.edu.au:8081/1959.7/521584
https://www.asmeconferences.org/OMAE2012/
https://doi.org/10.1115/OMAE2012-83247
Description
Summary:This writing presents results of simulating oscillatory and combined steady and oscillatory flows past gravity anchors astride subsea pipelines. It can be considered a companion to a previous numerical study on steady currents past gravity anchors. The gravity anchor system comprises large arch-shaped concrete blocks positioned at intervals astride offshore pipelines, and it is engineered to provide innovative and cost-effective secondary stabilisation for high-capacity gas-transporting pipelines serving in severe metocean conditions, eg. cyclone-prone offshore areas. A free-settling marine object bottom-seated on the seabed, however, the gravity anchor may subside into scour pits around its base due to locally disturbed flow regimes, imposing integrity risks on the pipe. Also, the effect of gravity anchors on hydrodynamic loading on nearby pipeline lengths is of interest. The present study employed a Petrov-Galerkin finite element method to solve the three-dimensional Navier-Stokes equations in direct numerical simulation. Firstly sinusoidal flow oscillating perpendicularly to the pipe beneath gravity anchors on an immobile bed was simulated at a Keulegan-Carpenter number of 10 and a pipe Reynolds number of 1000. Then, a steady current co-directionally superimposed on the aforementioned oscillatory flow was modelled at a ratio of steady current velocity to oscillatory flow velocity amplitude of 1. With sediment transport capacity related to bed shear stresses, the time-averaged bed shear stress amplification around gravity anchors in oscillatory flow was revealed first, and found to be consistent with laboratory observations of scour patterns. The effect of superimposing steady flow onto oscillatory flow on bed shear stress amplification was then explored. Lastly, hydrodynamic forces on pipelines in the vicinity of gravity anchors were gauged. The present work intends to shed light on the initial seabed responses with regard to the scour process around gravity anchors immersed in the oceanic wave boundary layers, as well as the effect of gravity anchors on hydrodynamic loadings on pipelines.

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