Abstract
When a laminar boundary layer is subjected to an adverse pressure gradient, laminar separation bubbles can occur. At low Reynolds numbers, the bubble size can be substantial, and the aerodynamic performance can be reduced considerably. At higher Reynolds numbers, the bubble bursting can determine the stall characteristics. For either setting, an active control that suppresses or delays laminar separation is desirable. A combined numerical and experimental approach was taken for investigating active flow control and its interplay with separation and transition for laminar separation bubbles for chord-based Reynolds numbers of Re ≈ 64,200–320,000. Experiments were carried out both in the wind tunnel and in free flight using an instrumented 1:5 scale model of the Aeromot 200S, which has a modified NACA 643-618 airfoil. The same airfoil was also used in the simulations and wind tunnel experiments. For a wide angle of attack range below stall, the flow separates laminar from the suction surface. Separation control via a dielectric barrier discharge plasma actuator and unsteady blowing through holes were investigated. For a properly chosen actuation amplitude and frequency, the Kelvin–Helmholtz instability results in strong disturbance amplification and a “roll-up” of the separated shear layer. As a result, an efficient and effective laminar separation control is realized.
Highlights
Laminar separation bubbles (LSBs) form when a laminar boundary layer detaches from a surface, undergoes transition, and reattaches as a transitional or turbulent flow
At low Reynolds number conditions, LSBs can significantly affect the aerodynamic performance of lifting surfaces even at low angles of attack (AoAs)
For small fixed and rotary wing unmanned aerial vehicles (UAVs), the flow can separate at the beginning of the adverse pressure gradient, and the LSB can extend over a significant portion of the airfoil
Summary
Laminar separation bubbles (LSBs) form when a laminar boundary layer detaches from a surface, undergoes transition, and reattaches as a transitional or turbulent flow. At larger Reynolds numbers (Re ≈ 1 million), LSBs play an important role for laminar flow airfoils. For such airfoils at the design AoA, short and shallow LSBs trip the boundary layers to turbulence. The resulting abrupt drop in lift is known as “hard stall”, and has to be avoided during routine operation. This sequence of events has recently been revealed in great detail in large-eddy simulations by Benton and Visbal [1,2]
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