Konuşmacılar
Açıklama
In the present study, the numerical modeling and simulations of a Floating Offshore Wind Turbine (FOWT) are presented. The analyses are carried out utilizing a variety of open-source codes and run on a High-Performance Computing (HPC) environment. The analysis is performed on the NREL 5 MW turbine atop the OC3 Hywind SPAR floating platform. The result shows that the multi-threading computation reduces the computational time for the hydrodynamic platform significantly. Despite using a serial code, the performance analysis of a single wind turbine can benefit from the batch simulation with multiple runs for multiple input scenarios. On a wind farm scale, a combination of the multi-threading and the batch simulations is effective in reducing the computation time. Extraction of power from the wind causes the wind velocity behind the turbine to be lower than the ambient velocity. The wake effect is stronger near the turbine downstream of the rotor. The rotor wake then diffuses and expands as it travels downstream causing the turbine located further behind the upstream turbine to produce more power than the closer one. The wake steering performed by yawing the upstream turbine with the correct yaw angle also proved to be able to increase the collective power production of the wind farm.