Role of Duty Cycle in Burst-Modulated Synthetic Jet Flow Control

This paper presents an experimental study on flow reattachment over a stalled airfoil using an array of microblowers operating as synthetic jet actuators (SJAs). The effects of burst duty cycle (DC) and blowing ratio, alongside power requirements, are examined in relation to SJA-induced vortical structures and aerodynamic performance. Results show that increasing the DC or blowing ratio can achieve the threshold momentum coefficient required for flow reattachment. While both DC and blowing ratios impact control efficacy, achieving a specific momentum coefficient generally corresponds to a consistent lift coefficient, regardless of the individual parameter values. Substantial lift improvements are observed at DCs as low as 5%, indicating that brief, high-momentum perturbations to the flow are sufficient for reattachment, resulting in significant power savings. However, analysis of the flow dynamics reveals that low-DC control strategies result in unsteady, phase-dependent flow behavior due to the induced vortices' rapid dissipation and inconsistent evolution. Higher DCs produce stronger, more persistent vortices that remain closer to the airfoil surface, leading to a more stable and effective control strategy. The study also highlights the challenge of achieving full spanwise control across the finite-span array, as even high-power strategies could not achieve a control length greater than 40% of the array's span. Additionally, a strong correlation between the lift coefficient and the suction peak pressure coefficient is observed, indicating that single-point measurements suffice for rapid assessment of control effectiveness.