Centrifuge modelling of suction anchors under multidirectional loading for shared mooring applications
Centrifuge modelling of suction anchors under multidirectional loading for shared mooring applications
Shared anchors for floating offshore wind turbines (FOWTs) offer potential cost savings, but their geotechnical performance under complex multidirectional mooring loads in soft clay requires better understanding. To address this, centrifuge modelling was conducted at 75 g on model suction anchors in normally consolidated kaolin clay. The experiments simulated several loading scenarios, including monotonic pull-out and multidirectional loading patterns representing shared anchor configurations (three lines at 45° inclination to the horizontal plane, spaced by 120° azimuthally). Three load tests were performed: a monotonic reference test and two multidirectional tests involving alternating and simultaneous line loading. Measurements included the anchor load–displacement response and excess pore pressures with complementary data from digital image correlation. The baseline monotonic test yielded an ultimate capacity of approximately 4 MN. Alternating line loading induced progressive downward displacements, while simultaneous two-line loading produced a trend of upward movement. Simultaneous loading also led to greater horizontal displacements, reflecting increased mobilisation of soil shear strength under compound loading paths. Post-multidirectional monotonic tests revealed reductions in anchor capacity between 10% and 38%, depending on the load path history and inclination. This work delivers benchmark data clarifying suction anchor behaviour under multidirectional loads to validate numerical models and optimise shared anchor designs for FOWTs.
Soriano, Cristian
0a24412c-56c1-4ac3-9176-5f828de38c23
Blanc, Matthieu
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Cerfontaine, Benjamin
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Thorel, Luc
f66e9e05-77c4-405f-a467-84ac20c555be
Soriano, Cristian
0a24412c-56c1-4ac3-9176-5f828de38c23
Blanc, Matthieu
c51496a7-697f-4f02-9d0f-8fce8d1e6e65
Cerfontaine, Benjamin
0730daf4-9d6b-4f2d-a848-a3fc54505a02
Thorel, Luc
f66e9e05-77c4-405f-a467-84ac20c555be
Soriano, Cristian, Blanc, Matthieu, Cerfontaine, Benjamin and Thorel, Luc
(2026)
Centrifuge modelling of suction anchors under multidirectional loading for shared mooring applications.
International Journal of Physical Modelling in Geotechnics.
(doi:10.1680/jphmg.25.00031).
Abstract
Shared anchors for floating offshore wind turbines (FOWTs) offer potential cost savings, but their geotechnical performance under complex multidirectional mooring loads in soft clay requires better understanding. To address this, centrifuge modelling was conducted at 75 g on model suction anchors in normally consolidated kaolin clay. The experiments simulated several loading scenarios, including monotonic pull-out and multidirectional loading patterns representing shared anchor configurations (three lines at 45° inclination to the horizontal plane, spaced by 120° azimuthally). Three load tests were performed: a monotonic reference test and two multidirectional tests involving alternating and simultaneous line loading. Measurements included the anchor load–displacement response and excess pore pressures with complementary data from digital image correlation. The baseline monotonic test yielded an ultimate capacity of approximately 4 MN. Alternating line loading induced progressive downward displacements, while simultaneous two-line loading produced a trend of upward movement. Simultaneous loading also led to greater horizontal displacements, reflecting increased mobilisation of soil shear strength under compound loading paths. Post-multidirectional monotonic tests revealed reductions in anchor capacity between 10% and 38%, depending on the load path history and inclination. This work delivers benchmark data clarifying suction anchor behaviour under multidirectional loads to validate numerical models and optimise shared anchor designs for FOWTs.
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Accepted/In Press date: 10 December 2025
e-pub ahead of print date: 2 January 2026
Identifiers
Local EPrints ID: 509046
URI: http://eprints.soton.ac.uk/id/eprint/509046
ISSN: 1346-213X
PURE UUID: d1e632d7-3008-4e94-a0f0-4bcbb13ca26f
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Date deposited: 10 Feb 2026 17:49
Last modified: 11 Feb 2026 03:01
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Author:
Cristian Soriano
Author:
Matthieu Blanc
Author:
Luc Thorel
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