The laminar separation bubble (LSB) that forms on the suction side of a modified NACA 64 ₃-618 airfoil at a chord-based Reynolds number of Re = 200 , 000 is studied using wind tunnel experiments. First, the LSB is characterized over a range of static angles of attack, in terms of the locations of separation, transition and reattachment—using surface pressure measurements, particle image velocimetry (PIV) and infrared thermography (IT). For the conditions tested, excellent agreement between the techniques is obtained. Subsequently, a pitching motion is imposed on the wind tunnel model, with reduced frequencies up to k = 0.25. While surface pressure measurements and PIV are not affected by the change in experimental conditions, the infrared approach is impaired by the thermal response of the surface. To overcome this, an extension of the differential infrared thermography (DIT) method for detecting the three characteristics of an unsteady LSB is considered. All three experimental techniques indicate a hysteresis in bubble location between the pitch up and pitch down phases of the motion, caused by the effect of the aerodynamic unsteadiness on the adverse pressure gradient. However, the DIT measurements suggest a larger hysteresis, which is attributed to the thermal response time of the model surface. The experimental results measured with the pressure sensors reveal that the hysteresis in bubble location is larger than the hysteresis in lift, indicating that the observed bubble hysteresis is not purely due to instantaneous flow conditions, but has an inherent component as well.

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This work presents experimental and computational results regarding the effects of structural motion on the aerodynamics of the X-56A airfoil. An oscillatory plunging mechanism has been fabricated and installed in a subsonic wind tunnel. The static characteristics of the X-56A were verified before focusing on unsteady behavior at Re=200k with nominal angles of attack of 10 and 12 degrees. The former contains a laminar separation bubble near the leading edge while the latter is nearly the angle of CLmax. Instantaneous angles of attack during the airfoil oscillations are outside the linear CL-alpha regime and extend into the region associated with static stall in most cases. Focus is placed on oscillations with dimensionless amplitude and frequency that produce CL values which are unattainable in static tests even at higher Re. A comparison with unsteady aerodynamic theory (Theodorsen) is very good for the lower angle of attack case (10 degrees), but unwarranted at the higher angle (12 degrees) since viscous effects become more prominent. The lower angle of attack case is also supported by CFD which reveals more detailed information on the laminar separation bubble near the leading edge and the turbulent flow downstream.@en