Numerical modelling of rock anchor uplift capacity for offshore applications
Numerical modelling of rock anchor uplift capacity for offshore applications
Mooring and anchoring represent a significant part of the cost of wave energy converter (WEC) systems. The most common offshore embedded anchor solutions are inapplicable to rocky seabeds, which are likely in zones of strong currents/waves of interest for WECs. A new type of anchor was recently proposed for hard seabeds. It is composed a self-drilling head, which leads the anchor shaft into the rocky seabed. The anchor is then mechanically locked into the rock by applying a pre-tension. This work investigates the rock failure mechanism around the anchor, while subjected to uplift (axial) loading, and for which few models exist. Limit analysis was undertaken to calculate the failure load of the anchor in different configurations (3 rock types, varying depths and anchor geometries). The results indicate that the anchor capacity increases with depth until a certain limit is reached, corresponding to the creation of a local failure mechanism around the anchor, while a wedge failure type takes place at shallower depth. The underreamed contact area must be carefully controlled to maximise the uplift capacity related to the local failure mechanism.
Cerfontaine, Benjamin
0730daf4-9d6b-4f2d-a848-a3fc54505a02
Brown, Michael
a653384d-4fa7-4987-b03c-8a6ce153c6e7
Caton, Adam
9a845d53-e896-4f32-b9e1-c4be2766a3aa
Hunt, Andy
5278140a-4501-49a2-9df0-d4a041f1429f
Cresswell, Nick
e24ae9d2-2bd3-4917-b23c-818b3623719f
5 September 2021
Cerfontaine, Benjamin
0730daf4-9d6b-4f2d-a848-a3fc54505a02
Brown, Michael
a653384d-4fa7-4987-b03c-8a6ce153c6e7
Caton, Adam
9a845d53-e896-4f32-b9e1-c4be2766a3aa
Hunt, Andy
5278140a-4501-49a2-9df0-d4a041f1429f
Cresswell, Nick
e24ae9d2-2bd3-4917-b23c-818b3623719f
Cerfontaine, Benjamin, Brown, Michael, Caton, Adam, Hunt, Andy and Cresswell, Nick
(2021)
Numerical modelling of rock anchor uplift capacity for offshore applications.
In Proceedings of the 14th European Wave & Tidal Energy Conference.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Mooring and anchoring represent a significant part of the cost of wave energy converter (WEC) systems. The most common offshore embedded anchor solutions are inapplicable to rocky seabeds, which are likely in zones of strong currents/waves of interest for WECs. A new type of anchor was recently proposed for hard seabeds. It is composed a self-drilling head, which leads the anchor shaft into the rocky seabed. The anchor is then mechanically locked into the rock by applying a pre-tension. This work investigates the rock failure mechanism around the anchor, while subjected to uplift (axial) loading, and for which few models exist. Limit analysis was undertaken to calculate the failure load of the anchor in different configurations (3 rock types, varying depths and anchor geometries). The results indicate that the anchor capacity increases with depth until a certain limit is reached, corresponding to the creation of a local failure mechanism around the anchor, while a wedge failure type takes place at shallower depth. The underreamed contact area must be carefully controlled to maximise the uplift capacity related to the local failure mechanism.
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Published date: 5 September 2021
Venue - Dates:
14th European Wave & Tidal Energy Conference, , Plymouth, United Kingdom, 2021-09-05 - 2021-09-09
Identifiers
Local EPrints ID: 452775
URI: http://eprints.soton.ac.uk/id/eprint/452775
PURE UUID: a5af255a-aeb1-4b00-a40b-22cef8cca44c
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Date deposited: 20 Dec 2021 17:33
Last modified: 28 Apr 2022 02:30
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Contributors
Author:
Michael Brown
Author:
Adam Caton
Author:
Andy Hunt
Author:
Nick Cresswell
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