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VIV-induced strain on a lazy wave dynamic marine power cable in a steady current

VIV-induced strain on a lazy wave dynamic marine power cable in a steady current
VIV-induced strain on a lazy wave dynamic marine power cable in a steady current
Marine power cables are commonly used to transfer electricity from offshore renewable energy (ORE) devices to shore. Such cables are susceptible to fatigue failure due to flow-induced vibration. We present results from physical model tests conducted at Edinburgh University’s FloWave wave-current facility on an instrumented flexible cable in a lazy wave configuration subjected to a steady, unidirectional current. The Reynolds number was subcritical, ranging from 3,100 to 24,800. Bending strain was measured at seven locations along the length of the cable and the results are presented in terms of cable curvature. The data analysis shows that, currents propagating normal to the longitudinal axis of the cable caused large local variations in curvature. The maximum variation in curvature occurred near the touchdown zone and at the sag bend. Repeated high-amplitude cyclic loading was observed in currents directed at angles within ± 30o normal to the longitudinal axis of the cable. Significant shifts in peak frequency and spectral energy distribution were evident with increasing reduced velocity. At certain locations along the cable, the strain frequency corresponded to a Strouhal number of 0.127 - 0.144, whereas very low peak strain frequencies occurred elsewhere. The strain behaviour was sensitive to the current speed and direction relative to the orientation of the cable. Mono-frequency strain responses occurred at lower reduced velocity and multi-frequency responses at higher reduced velocity.
Vortex induced vibration (VIV) , Offshore power cable, Lazy wave configuration, Strouhal number, Bending strain, Offshore renewable energy
0029-8018
Moideen, Rameeza
cb4f3505-9d29-486d-aa41-98fd2681c3a4
Venugopal, Venki
7570a226-72de-444e-9a7b-c54d9d137dbc
Chaplin, John
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Borthwick, A.G.L.
e49dc647-c505-4684-becc-95e8f75931ba
Moideen, Rameeza
cb4f3505-9d29-486d-aa41-98fd2681c3a4
Venugopal, Venki
7570a226-72de-444e-9a7b-c54d9d137dbc
Chaplin, John
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Borthwick, A.G.L.
e49dc647-c505-4684-becc-95e8f75931ba

Moideen, Rameeza, Venugopal, Venki, Chaplin, John and Borthwick, A.G.L. (2025) VIV-induced strain on a lazy wave dynamic marine power cable in a steady current. Ocean Engineering, 328, [121081]. (doi:10.1016/j.oceaneng.2025.121081).

Record type: Article

Abstract

Marine power cables are commonly used to transfer electricity from offshore renewable energy (ORE) devices to shore. Such cables are susceptible to fatigue failure due to flow-induced vibration. We present results from physical model tests conducted at Edinburgh University’s FloWave wave-current facility on an instrumented flexible cable in a lazy wave configuration subjected to a steady, unidirectional current. The Reynolds number was subcritical, ranging from 3,100 to 24,800. Bending strain was measured at seven locations along the length of the cable and the results are presented in terms of cable curvature. The data analysis shows that, currents propagating normal to the longitudinal axis of the cable caused large local variations in curvature. The maximum variation in curvature occurred near the touchdown zone and at the sag bend. Repeated high-amplitude cyclic loading was observed in currents directed at angles within ± 30o normal to the longitudinal axis of the cable. Significant shifts in peak frequency and spectral energy distribution were evident with increasing reduced velocity. At certain locations along the cable, the strain frequency corresponded to a Strouhal number of 0.127 - 0.144, whereas very low peak strain frequencies occurred elsewhere. The strain behaviour was sensitive to the current speed and direction relative to the orientation of the cable. Mono-frequency strain responses occurred at lower reduced velocity and multi-frequency responses at higher reduced velocity.

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More information

Accepted/In Press date: 25 March 2025
e-pub ahead of print date: 3 April 2025
Published date: 3 April 2025
Keywords: Vortex induced vibration (VIV) , Offshore power cable, Lazy wave configuration, Strouhal number, Bending strain, Offshore renewable energy

Identifiers

Local EPrints ID: 510311
URI: http://eprints.soton.ac.uk/id/eprint/510311
DOI: doi:10.1016/j.oceaneng.2025.121081
ISSN: 0029-8018
PURE UUID: 848f2d52-6ba8-4800-8a16-b7548f07af8d
ORCID for John Chaplin: ORCID iD orcid.org/0000-0003-2814-747X

Catalogue record

Date deposited: 25 Mar 2026 17:37
Last modified: 26 Mar 2026 02:37

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Contributors

Author: Rameeza Moideen
Author: Venki Venugopal
Author: John Chaplin ORCID iD
Author: A.G.L. Borthwick

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