Anchor loads in taut moorings: The impact of inverse catenary shakedown
Anchor loads in taut moorings: The impact of inverse catenary shakedown
Taut mooring systems have become prospective alternatives for the station keeping of offshore floating facilities in deep water. The associated embedded anchors cause a part of the mooring line to be buried in the seabed − the inverse catenary − which introduces a requirement to predict the load and uplift angle at the padeye, where the chain is connected to the anchor. The padeye load and angle depend on the shape and tension profile of the inverse catenary, which must be assessed in the mooring system design. The dynamic interaction between the embedded chain and the soil in the inverse catenary is not usually considered in this analysis. Instead, the inverse catenary is assessed statically, albeit potentially using cyclically-degraded soil strength parameters. The present study employs the lumped mass method to simulate the dynamic response of mooring lines under different imposed oscillations at the fairlead, where the chain is connected to the floating facility. A new chain-soil interaction model, which includes hysteresis effects associated with irrecoverable relative chain-soil displacement is calibrated by experimental results. Simulations of cyclic vessel motion are then performed, and the resulting chain-seabed interaction is observed. During constant-amplitude vessel motion cycles, the load angle at the padeye significantly decreases due to progressive ratcheting or ‘shakedown’ of the inverse catenary from the initial static profile towards a straighter profile. This effect is due to the hysteretic soil response and creates a less onerous loading condition for the anchor which may be beneficial, but is conventionally overlooked in design. At the end of the present study, an elastic bound method is proposed to estimate the profile of the inverse catenary after shakedown. A parametric study illustrates the performance of this simple method for predicting the steady state condition.
Taut mooring sysm, chain soil interaction, hysteretic effect, anchor loads, shakedown
225-235
Xiong, Lingzhi
699c8580-1ee4-4bcb-b2ca-2e6dabf9bc9c
White, David J.
a986033d-d26d-4419-a3f3-20dc54efce93
Neubecker, Steven R.
1b5a0163-c410-4db0-a353-22bbd4bad3c2
Zhao, Wenhua
26bfd8b2-ebe7-4f75-be51-e363bb83636c
Yang, Jianmin
25c1532a-4f28-4d72-aef9-f0686616bf95
1 September 2017
Xiong, Lingzhi
699c8580-1ee4-4bcb-b2ca-2e6dabf9bc9c
White, David J.
a986033d-d26d-4419-a3f3-20dc54efce93
Neubecker, Steven R.
1b5a0163-c410-4db0-a353-22bbd4bad3c2
Zhao, Wenhua
26bfd8b2-ebe7-4f75-be51-e363bb83636c
Yang, Jianmin
25c1532a-4f28-4d72-aef9-f0686616bf95
Xiong, Lingzhi, White, David J., Neubecker, Steven R., Zhao, Wenhua and Yang, Jianmin
(2017)
Anchor loads in taut moorings: The impact of inverse catenary shakedown.
Applied Ocean Research, 67, .
(doi:10.1016/j.apor.2017.06.010).
Abstract
Taut mooring systems have become prospective alternatives for the station keeping of offshore floating facilities in deep water. The associated embedded anchors cause a part of the mooring line to be buried in the seabed − the inverse catenary − which introduces a requirement to predict the load and uplift angle at the padeye, where the chain is connected to the anchor. The padeye load and angle depend on the shape and tension profile of the inverse catenary, which must be assessed in the mooring system design. The dynamic interaction between the embedded chain and the soil in the inverse catenary is not usually considered in this analysis. Instead, the inverse catenary is assessed statically, albeit potentially using cyclically-degraded soil strength parameters. The present study employs the lumped mass method to simulate the dynamic response of mooring lines under different imposed oscillations at the fairlead, where the chain is connected to the floating facility. A new chain-soil interaction model, which includes hysteresis effects associated with irrecoverable relative chain-soil displacement is calibrated by experimental results. Simulations of cyclic vessel motion are then performed, and the resulting chain-seabed interaction is observed. During constant-amplitude vessel motion cycles, the load angle at the padeye significantly decreases due to progressive ratcheting or ‘shakedown’ of the inverse catenary from the initial static profile towards a straighter profile. This effect is due to the hysteretic soil response and creates a less onerous loading condition for the anchor which may be beneficial, but is conventionally overlooked in design. At the end of the present study, an elastic bound method is proposed to estimate the profile of the inverse catenary after shakedown. A parametric study illustrates the performance of this simple method for predicting the steady state condition.
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More information
Accepted/In Press date: 6 June 2017
e-pub ahead of print date: 8 August 2017
Published date: 1 September 2017
Keywords:
Taut mooring sysm, chain soil interaction, hysteretic effect, anchor loads, shakedown
Identifiers
Local EPrints ID: 417546
URI: http://eprints.soton.ac.uk/id/eprint/417546
ISSN: 0141-1187
PURE UUID: 8197249c-ffd9-4d47-b315-2c1fe63453ec
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Date deposited: 02 Feb 2018 17:30
Last modified: 16 Mar 2024 04:31
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Contributors
Author:
Lingzhi Xiong
Author:
Steven R. Neubecker
Author:
Wenhua Zhao
Author:
Jianmin Yang
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