A discussion of wind turbine interaction and stall contributions to wind farm noise

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“…With increasing AoA, separation rapidly propagates over the entire airfoil chord yielding an abrupt loss of lift. Furthermore, at high Reynolds numbers the vortical structures within the 20 separated flow region are unstable and the flow is turbulent. Although an important flow characteristic, airfoil stall has been less intensively studied than attached flows.…”

“…Changing the order in which integrals are performed in Eq. (20), the following three-fold integral appears as the most inner one:…”

A semi-empirical airfoil stall noise model based on surface pressure measurements

“…With increasing AoA, separation rapidly propagates over the entire airfoil chord yielding an abrupt loss of lift. Furthermore, at high Reynolds numbers the vortical structures within the 20 separated flow region are unstable and the flow is turbulent. Although an important flow characteristic, airfoil stall has been less intensively studied than attached flows.…”

“…Changing the order in which integrals are performed in Eq. (20), the following three-fold integral appears as the most inner one:…”

A semi-empirical airfoil stall noise model based on surface pressure measurements

“…Furthermore, a large hysteresis in the lift force is observed when the angles of the blade section reduces, indicating a delay in flow reattachment and lift recovery during the process. On the other hand, dynamic stall has also been observed on wind turbine blades [8e11], where it leads to increased fatigue damage accumulation at the rotor-hub joint due to large excursion in lift [12] as well as increased noise generation due to blade-vortex interaction [13]. In wind turbines, dynamic stall is caused by rapid variations of wind speed and direction [8,14,15] and is, therefore, more unpredictable compared to the rotor blades of helicopters.…”

Methods to control dynamic stall for wind turbine applications

“…Although dynamic stall is a dominating feature of vertical axis wind turbine flows, it has been studied extensively in many other contexts (McCroskey, 1976;Leishman and Beddoes, 1986;Carr, 1988;Geissler and Haselmeyer, 2006;Buchner et al, 2012;. On horizontal axis wind turbines, for example, even mild stall decreases performance and increases noise production significantly (Hibbs, 1986;Loratro et al, 2014), and similar effects are experienced to a greater magnitude by vertical axis turbines (Allet and Paraschivoiu, 1995;Scheurich and Brown, 2011).…”

Dynamic stall in vertical axis wind turbines: Comparing experiments and computations