Performance and wake characteristics of tidal turbines in an infinitely large array

TL;DR

This study combines theoretical analysis and large-eddy simulations to examine how turbine layout affects the efficiency and wake behavior of tidal turbines in large arrays, revealing optimal spacing strategies.

Contribution

It extends Linear Momentum Actuator Disc Theory and applies LES to analyze the hydrodynamics of large tidal turbine arrays with various layouts and spacings.

Findings

Aligned arrays' efficiency decreases with closer streamwise spacing.

Staggered arrays maintain high efficiency even at small spacings.

Wake meandering amplitude decreases with smaller lateral spacing.

Abstract

The efficiency of tidal-stream turbines in a large array depends on the balance between negative effects of turbine-wake interactions and positive effects of bypass-flow acceleration due to local blockage, both of which are functions of the layout of turbines. Here we investigate the hydrodynamics of turbines in an infinitely large array with aligned or staggered layouts for a range of streamwise and lateral turbine spacing. First, we present a theoretical analysis based on an extension of the Linear Momentum Actuator Disc Theory (LMADT) for perfectly aligned and staggered layouts, employing a hybrid inviscid-viscous approach to account for the local blockage effect within each turbine row and the viscous (turbulent) wake mixing behind each row in a coupled manner. We perform Large-Eddy Simulation (LES) of open-channel flow for 28 layouts of tidal turbines using an Actuator-Line Method with periodic boundary conditions. Both theoretical and LES results show that the efficiency of turbines (or the power of turbines for a given bulk velocity) in an aligned array decreases as we reduce the streamwise spacing, whereas that in a staggered array remains high and may even increase due to the positive local blockage effect (causing the local flow velocity upstream of each turbine to exceed the bulk velocity) if the lateral turbine spacing is sufficiently small. The LES results further reveal that the amplitude of wake meandering tends to decrease as we reduce the lateral spacing, which leads to a lower wake recovery rate in the near-wake region. These results will help to understand and improve the efficiency of tidal turbines in future large arrays, even though the performance of real tidal arrays may depend not only on turbine-to-turbine interactions but also on macro-scale interactions between the array and natural tidal currents, the latter of which are outside the scope of this study.