Flow-induced vibration of an underwater lazy wave cable in unidirectional current
Flow-induced vibration of an underwater lazy wave cable in unidirectional current
This paper describes measurements of the flow-induced vibration of an instrumented model cable in a lazy wave configuration immersed in unidirectional currents in the 2 m deep FloWave Fa- cility at the University of Edinburgh. The cable model, designed to represent a dynamic power cable used in offshore renewable energy structures for electricity transmission, has an external diameter (D) of 31 mm and a mass ratio of 1.22. The current speed was varied from 0.1 to 0.9 m/s and its direction was set at 0, 90, and 180 degrees relative to the initial longitudinal axis of the cable. An underwater Qualisys motion capture system measured the in-line (IL) and cross-flow (CF) displacement components at 36 locations along the length of the submerged cable. Local displacements, response frequencies, and travelling wave modes are determined for reduced velocity Ur ε (5.29, 47.69), and Reynolds number Re ε (103, 104). It is found that the root mean square (RMS) values of the displacement components exhibited an increasing trend with reduced velocity reaching 0.40D in the in-line direction and 0.45D in the cross-flow direction. For reduced velocity in the range from 5.29 to 10.58, the cable exhibited single frequency vibrations. For Ur > 10.58, the cable experienced broad-banded, multi-frequency responses. Along the cable, certain locations were found to execute distinct circular, elliptical, nearly linear, and figure-of-eight orbits at low Ur. A sudden phase shift was observed along the cable length, related to unsteady vortex-induced vibration (VIV), which effectively prevented lock-in occurring at high Ur.
Dynamic power cable; Vortex-induced vibration; Lazy wave; Hydro-elastic cable; Unidirectional current; Reduced velocity, Lazy wave, Dynamic power cable, Hydro-elastic cable, Unidirectional current, Reduced velocity, Vortex-induced vibration
Moideen, R.
cb4f3505-9d29-486d-aa41-98fd2681c3a4
Venugopal, V.
7570a226-72de-444e-9a7b-c54d9d137dbc
Chaplin, J.R.
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Borthwick, A.G.L.
24aa894f-da2e-47e0-850f-5531573e3de3
23 September 2025
Moideen, R.
cb4f3505-9d29-486d-aa41-98fd2681c3a4
Venugopal, V.
7570a226-72de-444e-9a7b-c54d9d137dbc
Chaplin, J.R.
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Borthwick, A.G.L.
24aa894f-da2e-47e0-850f-5531573e3de3
Moideen, R., Venugopal, V., Chaplin, J.R. and Borthwick, A.G.L.
(2025)
Flow-induced vibration of an underwater lazy wave cable in unidirectional current.
Journal of Fluids and Structures, 137, [104385].
(doi:10.1016/j.jfluidstructs.2025.104385).
Abstract
This paper describes measurements of the flow-induced vibration of an instrumented model cable in a lazy wave configuration immersed in unidirectional currents in the 2 m deep FloWave Fa- cility at the University of Edinburgh. The cable model, designed to represent a dynamic power cable used in offshore renewable energy structures for electricity transmission, has an external diameter (D) of 31 mm and a mass ratio of 1.22. The current speed was varied from 0.1 to 0.9 m/s and its direction was set at 0, 90, and 180 degrees relative to the initial longitudinal axis of the cable. An underwater Qualisys motion capture system measured the in-line (IL) and cross-flow (CF) displacement components at 36 locations along the length of the submerged cable. Local displacements, response frequencies, and travelling wave modes are determined for reduced velocity Ur ε (5.29, 47.69), and Reynolds number Re ε (103, 104). It is found that the root mean square (RMS) values of the displacement components exhibited an increasing trend with reduced velocity reaching 0.40D in the in-line direction and 0.45D in the cross-flow direction. For reduced velocity in the range from 5.29 to 10.58, the cable exhibited single frequency vibrations. For Ur > 10.58, the cable experienced broad-banded, multi-frequency responses. Along the cable, certain locations were found to execute distinct circular, elliptical, nearly linear, and figure-of-eight orbits at low Ur. A sudden phase shift was observed along the cable length, related to unsteady vortex-induced vibration (VIV), which effectively prevented lock-in occurring at high Ur.
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More information
Accepted/In Press date: 17 July 2025
e-pub ahead of print date: 23 July 2025
Published date: 23 September 2025
Keywords:
Dynamic power cable; Vortex-induced vibration; Lazy wave; Hydro-elastic cable; Unidirectional current; Reduced velocity, Lazy wave, Dynamic power cable, Hydro-elastic cable, Unidirectional current, Reduced velocity, Vortex-induced vibration
Identifiers
Local EPrints ID: 503259
URI: http://eprints.soton.ac.uk/id/eprint/503259
ISSN: 0889-9746
PURE UUID: 13ab312f-5daf-410f-b690-2c8ac1676922
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Date deposited: 25 Jul 2025 16:39
Last modified: 18 Sep 2025 01:37
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Contributors
Author:
R. Moideen
Author:
V. Venugopal
Author:
A.G.L. Borthwick
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