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This presentation was given on Tuesday, June 16th at the VII International Conference on Computational Methods in Marine Engineering (Marine 2015). | This presentation was given on Tuesday, June 16th at the VII International Conference on Computational Methods in Marine Engineering (Marine 2015). | ||
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[[Media:Draft_García-Espinosa_745184031_1770_MARINE_2015_Mooring.pptx|marine_2015_mooring.png]] | [[Media:Draft_García-Espinosa_745184031_1770_MARINE_2015_Mooring.pptx|marine_2015_mooring.png]] | ||
[[File:Draft_García-Espinosa_745184031_8253_marine_2015_mooring.png|link=Draft_García-Espinosa_745184031_2536_MARINE_2015_Mooring.zip]] | [[File:Draft_García-Espinosa_745184031_8253_marine_2015_mooring.png|link=Draft_García-Espinosa_745184031_2536_MARINE_2015_Mooring.zip]] |
The complexity of the dynamic response of offshore marine structures requires advanced simulations tools for the accurate assessment of the seakeeping behaviour of these devices. This presentation introduces a new time-domain model for solving the dynamics of moored floating marine devices, specifically offshore wind turbines, subjected to non-linear environmental loads. Different application examples are presented,including a GVA, and the OC3 and OC4 platforms.
This presentation was given on Tuesday, June 16th at the VII International Conference on Computational Methods in Marine Engineering (Marine 2015).
Published on 04/03/18
Submitted on 04/03/18
Licence: CC BY-NC-SA license
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