Abstract
The interaction between wakes and rotors is typically detrimental in terms of the overall power production of a wind farm. The recently studied wind farm controllers represent a promising way to increase the energy harvested through the mitigation of the effects induced by wake impingement. Recently, a novel methodology, based on a dynamic variation of induction, has been proposed as an alternative to steady induction and wake redirection controls. According to this new technology, a periodic collective motion of blade pitch generates a dynamic induction, associated with a stronger flow mixing and therefore a faster wake recovery. Although this technique proved to be effective in terms of power increase, both in numerical simulations and in wind tunnel experiments, much is to be done in order to demonstrate its feasibility. In particular, the impact of dynamic induction control in terms of downstream turbine dynamics has not been yet analyzed in detail. This paper presents a CFD-based analysis aimed at describing the response of a downstream rotor inside the wake of an upstream machine performing dynamic induction control. Specifically, the periodic induction entails a pulsating flow downstream which interacts significantly with the aero-servo-elastic dynamics of the downstream turbines. For low wind speeds, such an oscillating flow may trigger a shut-down/start-up sequence any time the velocity results lower than the cut-in speed.
Highlights
Wind farm control represents a promising way to increase the energy harvested by a wind farm
A wind farm control can be based on static induction control (SIC), which consists in reducing the power of the machine so as to increase in-wake flow velocity [1], and on wake redirection (WR), which promotes a redirection of the wake out of the downstream rotors by yawing the upstream machines [2]
The present paper aims at studying the effects of dynamic induction control (DIC) based on periodic collective motion (PCM) on the aero-servo-elastic response of a downstream turbine, which is located within a pulsating wake
Summary
Wind farm control represents a promising way to increase the energy harvested by a wind farm. According to this technology, the operative conditions of the upstream turbines are modified so as to reduce the interaction between their wakes and the downstream machines. DIC method is based on a dynamic periodic variation of the axial induction, obtained by a rotor thrust modulation. Such a modulation can be effectively generated by a periodic collective motion (PCM) of the pitch of the blades. A wind turbine, which finds itself inside such wake, experiences a higher mean flow velocity
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