Abstract
A new theoretical approach is proposed to predict a practical upper limit to the efficiency of a very large wind farm. The new theory suggests that the efficiency of ideal turbines in an ideal very large wind farm depends primarily on a non-dimensional parameter λ/Cf0, where λ is the ratio of the rotor swept area to the land area (for each turbine) and Cf0 is a natural friction coefficient observed before constructing the farm. When X/Cf approaches to zero, the new theory goes back to the classical actuator disc theory, yielding the well-known Betz limit. When λ/Cf0 increases to a large value, the maximum power coefficient of each turbine reduces whilst a normalised power density of the farm increases asymptotically to an upper limit. A CFD analysis of an infinitely large wind farm with ‘aligned’ and ‘displaced’ array configurations is also presented to validate a key assumption used in the new theory.
Highlights
Evaluating the efficiency of a wind farm is not a trivial task
‘very large’ implies that the horizontal extent of the wind farm is at least an order of magnitude larger than the thickness of the atmospheric boundary layer (ABL), which is typically about 1km
The solver is based on a finite volume method, solving numerically the 3D incompressible Reynolds-averaged Navier-Stokes (RANS) equations with the Reynolds stress terms modelled using the standard k-ε model of Launder and Spalding [7]
Summary
Evaluating the efficiency of a wind farm is not a trivial task. Even without considering any financial factors that affect the overall (or economic) efficiency of a wind farm, aerodynamic efficiency of a number of turbines arrayed as a farm is much more difficult to evaluate compared to that of a single isolated turbine. A major problem here is that we do not have a good ‘absolute’ (rather than relative) basis of evaluation for farm efficiency, such as the well-known ‘Betz limit’ [1] for single turbine efficiency. The lack of such an absolute basis of evaluation makes it very difficult to evaluate how good, or not so good, the efficiency of a given/existing wind farm really is. I propose a new theoretical approach to predict (or at least help predict) a practical upper limit to the efficiency of a very large wind farm. Hornsea Project One wind farm (expected to be fully operational in the UK in 2020) can be seen as such a very large wind farm, the airflow through which may approach the so-called ‘fully developed’ state [2]
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