Tidal turbine array optimisation using the adjoint approach

TitleTidal turbine array optimisation using the adjoint approach
Publication TypeJournal Article
Year of Publication2014
AuthorsFunke, SW, Farrell, PE, Piggott, MD
JournalRenewable Energy
Volume63
Pagination658 - 673
Date Published03/2014
ISBN Number0960-1481
KeywordsAdjoint method, Array layout, Gradient-based optimisation, Marine renewable energy, Shallow water equations, Tidal turbines
Abstract

Oceanic tides have the potential to yield a vast amount of renewable energy. Tidal stream generators are one of the key technologies for extracting and harnessing this potential. In order to extract an economically useful amount of power, hundreds of tidal turbines must typically be deployed in an array. This naturally leads to the question of how these turbines should be configured to extract the maximum possible power: the positioning and the individual tuning of the turbines could significantly influence the extracted power, and hence is of major economic interest. However, manual optimisation is difficult due to legal site constraints, nonlinear interactions of the turbine wakes, and the cubic dependence of the power on the flow speed. The novel contribution of this paper is the formulation of this problem as an optimisation problem constrained by a physical model, which is then solved using an efficient gradient-based optimisation algorithm. In each optimisation iteration, a two-dimensional finite element shallow water model predicts the flow and the performance of the current array configuration. The gradient of the power extracted with respect to the turbine positions and their tuning parameters is then computed in a fraction of the time taken for a flow solution by solving the associated adjoint equations. These equations propagate causality backwards through the computation, from the power extracted back to the turbine positions and the tuning parameters. This yields the gradient at a cost almost independent of the number of turbines, which is crucial for any practical application. The utility of the approach is demonstrated by optimising turbine arrays in four idealised scenarios and a more realistic case with up to 256 turbines in the Inner Sound of the Pentland Firth, Scotland.

URLhttp://www.sciencedirect.com/science/article/pii/S0960148113004989
DOI10.1016/j.renene.2013.09.031
Short TitleRenewable Energy