Abstract

Actual calculation tools for the multi-physical numerical modeling (wind, waves, current, etc.) of a floating wind turbine need validation through experimental campaigns. The objective of this work is the development and validation of an experimental apparatus dedicated to floating wind turbines wave tank testing, focusing on the representation of wind turbine forces. A hybrid approach combining physical and numerical modeling is developed, called “software-in-the-loop” (SIL).

The development of the different subsystems of an SIL system includes

  •     the selection and development of the numerical model
  •     the design of the force reproduction system (actuators)
  •     the definition of the real-time environment for the integration of the numerical model, the control of actuators, and the data acquisition.

To characterize and identify the performances of the SIL system, dedicated methodologies are developed. Specific test benches are built, and wave tank tests of a floating wind turbine are carried out. These wave tank tests are then compared to coupled aero-hydro-servo-structure simulations to investigate the hypotheses of the hydrodynamic force model.

Committee

  • Erin BACHYNSKI, Professeur, NTNU, Norvège (rapporteur)
  • Olivier KIMMOUN, Maître de conférences HDR, Centrale Marseille , Belgique (rapporteur)
  • Franck PLESTAN, Professeur, Centrale Nantes, France (examinateur)
  • Marco BELLOLI, Professeur, Université Polytechnique de Milan, Italie (examinateur)
  • Alan TASSIN, Ingénieur de recherche, IFREMER, France(examinateur)
  • Sandrine AUBRUN, Professeur, Centrale Nantes, France (directrice de thèse)
  • Félicien BONNEFOY, Maître de conférences, Centrale Nantes, France (co-encadrant de thèse)
  • Jean-Christophe GILLOTEAUX, Ingénieur de recherche, Centrale Nantes, France (co-encadrant de thèse)
  • Sofien KERKENI, CEO D-ICE Engineering (invité)