Abstract
Wind turbines are often grouped together for financial reasons, but due to wake development this usually results in decreased turbine lifetimes and power capture, and thereby an increased levelized cost of energy (LCOE). Wind farm control aims to minimize this cost by operating turbines at their optimal control settings. Most state-of-the-art control algorithms are open-loop and rely on low fidelity, static flow models. Closed-loop control relying on a dynamic model and state observer has real potential to further decrease wind's LCOE, but is often too computationally expensive for practical use. In this paper two time-efficient Kalman filter (KF) variants are outlined incorporating the medium fidelity, dynamic flow model “WindFarmSimulator” (WFSim). This model relies on a discretized set of Navier-Stokes equations in two dimensions to predict the flow in wind farms at low computational cost. The filters implemented are an Ensemble KF and an Approximate KF. Simulations in which a high fidelity simulation model represents the true wind farm show that these filters are 101 —102 times faster than a regular KF with comparable or better performance, correcting for wake dynamics that are not modeled in WFSim (noticeably, wake meandering and turbine hub effects). This is a first big step towards real-time closed-loop control for wind farms.
Highlights
Introduction and backgroundThe action of vortices embedded in boundary layers is often exploited as a means of flow control for transition or separation delay using vortex generator (VG) devices [1]
We develop a periodic point vortex model (PPVM) to study the influence of unequal vortex strengths on cascades which are typically arranged for flow control purposes
The results presented have yielded useful insights into the dynamics of asymmetric vortex arrays
Summary
The action of vortices embedded in boundary layers is often exploited as a means of flow control for transition or separation delay using vortex generator (VG) devices [1]. For flows prone to separation, the use of vortices enhances momentum in the wall region, delaying or even preventing separation. Evidence of the complex inflow is for instance found in Micallef et al [2] and Herraez et al [3], through observations of appreciable spanwise flows in blade root regions. Assessing the impact of such inflow conditions for VG arrays is of prime importance for understanding flow control performance in more practical conditions and for improving the robustness of VG designs
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