Your search keyword '"Ludovic Bouy"' showing total 2 results

1. OC5 project phase II: validation of global loads of the deepCwind floating semisubmersible wind turbine

Author

Roger Bergua, Climent Molins, Habib J. Dagher, Jacob Qvist, Koen Hermans, Carlos Barrera Sanchez, Rob Harries, Pauline Bozonnet, Carlos Guedes Soares, Yannick Debruyne, E. Uzunoglu, Fabian Wendt, Jacobus Bernardus De Vaal, Ludovic Bouy, Anders Yde, Wojciech Popko, Amy Robertson, Jason Jonkman, Sho Oh, José Azcona, Ilmas Bayati, Josean Galván, Christos Galinos, Hyunkyoung Shin, Felipe Vittori, Sebastien Gueydon, Iñigo Mendikoa, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. ATEM - Anàlisi i Tecnologia d'Estructures i Materials, and Publica

Subjects

020209 energy, floating offshore wind turbine, IEA Wind, 020101 civil engineering, ComputingMilieux_LEGALASPECTSOFCOMPUTING, 02 engineering and technology, Turbine, 0201 civil engineering, Floating offshore wind turbine, Numerical modeling, Validation, 0202 electrical engineering, electronic engineering, information engineering, Parcs eòlics marins, Physics::Atmospheric and Oceanic Physics, DeepCwind semisubmersible, validation, Wind power, business.industry, Enginyeria civil::Materials i estructures::Materials i estructures de formigó [Àrees temàtiques de la UPC], Aerodynamics, Mooring, verifcation, Offshore wind power plants, Offshore wind power, floating offshore wind turbine DeepCwind semisubmersible numerical modeling verifcation validation IEA Wind, Test case, numerical modeling, Environmental science, Verifcation, Submarine pipeline, business, Tower, Marine engineering

Abstract

This paper summarizes the findings from Phase II of the Offshore Code Comparison, Collaboration, Continued, with Correlation project. The project is run under the International Energy Agency Wind Research Task 30, and is focused on validating the tools used for modeling offshore wind systems through the comparison of simulated responses of select system designs to physical test data. Validation activities such as these lead to improvement of offshore wind modeling tools, which will enable the development of more innovative and cost-effective offshore wind designs. For Phase II of the project, numerical models of the DeepCwind floating semisubmersible wind system were validated using measurement data from a 1/50th-scale validation campaign performed at the Maritime Research Institute Netherlands offshore wave basin. Validation of the models was performed by comparing the calculated ultimate and fatigue loads for eight different wave-only and combined wind/wave test cases against the measured data, after calibration was performed using free-decay, wind-only, and wave-only tests. The results show a decent estimation of both the ultimate and fatigue loads for the simulated results, but with a fairly consistent underestimation in the tower and upwind mooring line loads that can be attributed to an underestimation of waveexcitation forces outside the linear wave-excitation region, and the presence of broadband frequency excitation in the experimental measurements from wind. Participant results showed varied agreement with the experimental measurements based on the modeling approach used. Modeling attributes that enabled better agreement included: the use of a dynamic mooring model; wave stretching, or some other hydrodynamic modeling approach that excites frequencies outside the linear wave region; nonlinear wave kinematics models; and unsteady aerodynamics models. Also, it was observed that a Morison-only hydrodynamic modeling approach could create excessive pitch excitation and resulting tower loads in some frequency bands. This work was supported by the U.S. Department of Energy under Contract No. DEAC36- 08GO28308 with the National Renewable Energy Laboratory. Some of the funding for the work was provided by the DOE Office of Energy Efficiency and Renewable Energy, Wind and Water Power Technologies Office.

Published

2017

2. OC5 Project Phase Ib: Validation of Hydrodynamic Loading on a Fixed, Flexible Cylinder for Offshore Wind Applications

Author

Hyunkyoung Shin, Tjeerd van der Zee, Matthieu Guerinel, Carlos Barrera Sanchez, Jacob Qvist, Ying Tu, Pauline Bozonnet, Tor Anders Nygaard, Anders Yde, Wojciech Popko, Michael Borg, Roger Bergua, Flemming Schlütter, Friedemann Borisade, Amy Robertson, Jason Jonkman, Erin Elizabeth Bachynski, Ludovic Bouy, Luca Oggiano, Raul Guanche Garcia, Henrik Bredmose, Rob Harries, Jacobus Bernardus De Vaal, Ilmas Bayati, Fabian Wendt, and Publica

Subjects

Engineering, cylinder, 020209 energy, Phase (waves), 020101 civil engineering, 02 engineering and technology, 7. Clean energy, 0201 civil engineering, Energy(all), 0202 electrical engineering, electronic engineering, information engineering, Cylinder, offshore wind, validation, Wind power, business.industry, Verification, Offshore wind power, 13. Climate action, monopile, Technical university, hydrodynamics, Submarine pipeline, Physical test, business, Marine engineering, Verification and validation

Abstract

This paper summarizes the findings from Phase Ib of the Offshore Code Comparison, Collaboration, Continued with Correlation (OC5) project. OC5 is a project run under the International Energy Agency (IEA) Wind Research Task 30, and is focused on validating the tools used for modelling offshore wind systems through the comparison of simulated responses of select offshore wind systems (and components) to physical test data. For Phase Ib of the project, simulated hydrodynamic loads on a flexible cylinder fixed to a sloped bed were validated against test measurements made in the shallow water basin at the Danish Hydraulic Institute (DHI) with support from the Technical University of Denmark (DTU). The first phase of OC5 examined two simple cylinder structures (Phase Ia and Ib) to focus on validation of hydrodynamic models used in the various tools before moving on to more complex offshore wind systems and the associated coupled physics. Verification and validation activities such as these lead to improvement of offshore wind modelling tools, which will enable the development of more innovative and cost-effective offshore wind designs. © 2016 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Published

2016