Energetics of marine turbine arrays - extraction, dissipation and diminution

Abstract

A two-scale modelling approach is discussed to predict the performance and energetics of a large number (more than a few hundred) of marine turbines installed as a power farm in a general coastal environment. The kernel of this approach is that the outer, or coastal-scale, model/simulation is to assess the reduction of flow passing through a given farm area as a function of the increase of head loss across the farm, whereas the inner, or device-scale, model/simulation employs this function to account for the (otherwise unknown) effect of coastal dynamics for that farm site, i.e. diminution of the power removed from the farm area due to the reduction of flow through the farm. Large-eddy simulations (LES) of periodic open channel flow (with a porous plate model representing turbines) are then presented as a device-scale part of such a two-scale model of large marine turbine arrays. Results demonstrate the usefulness of this approach to study how the overall energetics of turbine arrays (i.e. extraction, dissipation and diminution of energy within the entire farm area) may change depending on the characteristics of the farm site, array configuration and operating conditions of the turbines in the farm.