Abstract
Blade-tip vortices can lead to wakes, cavitation and noise, and their control remains a significant challenge for tidal and wind turbines. In the present work, we propose controlling tip vortices through local permeability on a model-scale horizontal-axis turbine. The numerical investigation follows a rigorous validation and verification process. The tip permeability is modelled by including a porous zone over the blade tip, within which Darcy’s law is applied. The results demonstrate that there is an optimal range of permeability, corresponding to a non-dimensional Darcy number, Da, of around 10-5 , that can substantially decrease the tip vortex intensity. The revealed flow physics show that the permeable tip can effectively enlarge the vortex viscous core radius with little change to the vortex circulation. The permeable tip treatment can increase the minimal pressure-coefficient at the vortex core by up to 63%, which significantly alleviates the cavitation risk. This approach has negligible influence on the turbine’s energy-harvesting performance because the spanwise extent of the permeable zone is only in the order of 0.1% turbine diameter. Our findings demonstrate this approach’s great promise to break the upper tip-speed ratio limit capped by cavitation for tidal turbines, contributing to developing more efficient and resilient turbines.