Development of current-induced scour beneath elevated subsea pipelines

Development of current-induced scour beneath elevated subsea pipelines

•The scour time scale increases with the pipe elevation from the seabed.•An improved manner of non-dimensionalising the scour time scale is proposed.•A new empirical equation is proposed which accounted for the effect of the pipe elevation.•The influence of the Reynolds number on the time scale is s...

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Bibliographic Details
Published in:Journal of ocean engineering and science Vol. 3; no. 4; pp. 265 - 281
Main Authors: Lee, Jun Y., Forrest, Alexander L., Hardjanto, Fauzi A., Chai, Shuhong, Cossu, Remo, Leong, Zhi Q.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2018
Elsevier
Subjects:
Equilibrium scour depth
Pipe elevation
Scour time scale
Steady currents
Subsea pipelines
Pipe elevation
Steady currents
Scour time scale
Subsea pipelines
Equilibrium scour depth
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Summary:•The scour time scale increases with the pipe elevation from the seabed.•An improved manner of non-dimensionalising the scour time scale is proposed.•A new empirical equation is proposed which accounted for the effect of the pipe elevation.•The influence of the Reynolds number on the time scale is small. When scour occurs beneath a subsea pipeline and develops to a certain extent, the pipeline may experience vortex-induced vibrations, through which there can be a potential accumulation of fatigue damage. However, when a pipeline is laid on an uneven seabed, certain sections may have an elevation with respect to the far-field seabed, eo, at which the development of scour would vary. This work focused on predicting the development of the scour depth beneath subsea pipelines with an elevation under steady flow conditions. A range of pipe elevation-to-diameter ratios (i.e. 0 ≤ eo/D ≤ 0.5) have been considered for laboratory experiments conducted in a sediment flume. The corresponding equilibrium scour depths and scour time scales were obtained; experimental data from published literature have been collected and added to the present study to produce a more complete analysis database. The correlation between existing empirical equations for predicting the time scale and the experimental data was assessed, resulting in a new set of constants. A new manner of converting the scour time scale into a non-dimensional form was found to aid the empirical equations in attaining a better correlation to the experimental data. Subsequently, a new empirical equation has also been proposed in this work, which accounts for the influence of eo/D on the non-dimensional scour time scale. It was found to have the best overall correlation with the experimental data. Finally, full-scale predictions of the seabed gaps and time scales were made for the Tasmanian Gas Pipeline (TGP).
ISSN:2468-0133
2468-0133
DOI:10.1016/j.joes.2018.09.001