This study explores the effects of varying the duty cycle (DC) and blowing ratio (CB) of an array of synthetic jet actuators (SJAs) on the aerodynamic performance and flow characteristics over a NACA 0025 airfoil. The key findings are:
Increasing the DC or blowing ratio can achieve the threshold momentum coefficient required for flow reattachment. However, once reattachment is achieved, further increases in DC or blowing ratio provide only marginal additional lift enhancement.
Low-DC (5-12.5%) control strategies with high blowing ratios (CB = 4.4-5.0) can achieve significant lift improvements (up to 280% over baseline) at low power consumption, indicating that brief, high-momentum perturbations are sufficient for reattachment.
Analysis of the flow dynamics reveals that low-DC control strategies result in unsteady, phase-dependent flow behavior due to the rapid dissipation of the induced vortices. Higher DCs (50-95%) produce stronger, more persistent vortices that remain closer to the airfoil surface, leading to a more stable and effective control strategy.
The spanwise control authority is limited, with the effective control region extending to only 40% of the SJA array span, even with high-power control strategies.
A strong correlation between the lift coefficient and the suction peak pressure coefficient is observed, indicating that single-point pressure measurements can be used for rapid assessment of control effectiveness.
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by Adnan Machad... om arxiv.org 10-03-2024
https://arxiv.org/pdf/2410.01015.pdfDiepere vragen