Near-Field Aeroacoustic Shape Optimization at Low Reynolds Numbers

In this paper, we investigated the feasibility of gradient-free aeroacoustic shape optimization. The sound pressure level at a near-field observer is computed directly from the flow field, and the shape is optimized with the objective of minimizing the sound pressure level at this observer. The Flux Reconstruction (FR) approach, is used to study the flow over two-dimensional objects at low Reynolds numbers. The Sound Pressure Level (SPL) is computed using a direct acoustic approach at an observer in the near field. Aeroacoustic shape optimization is performed using the gradient-free Mesh Adaptive Direct Search (MADS) technique. A $7\%$ noise reduction is achieved for flow over an open deep cavity with a length-to-depth ratio of $L/D=4$ at Reynolds number of $Re=1500$ based on the cavity depth and free-stream Mach number of $M_\infty = 0.15$. The second case considers tandem cylinders at $Re=200$ and $M_\infty = 0.2$. Over $12\%$ noise reduction is achieved by optimizing the distance between the cylinders and their diameter ratio. Finally, a baseline NACA0012 airfoil is optimized at $Re=10000$ and $M_\infty = 0.2$ to reduce trailing edge noise. The airfoil's shape is optimized to generate a new 4-digit NACA airfoil at an appropriate angle of attack to reduce the SPL while ensuring the baseline time-averaged lift coefficient is maintained and prevent any increase in the baseline time-averaged drag coefficient. The optimized airfoil is silent with $0~dB$ noise and the drag coefficient is decreased by $24.95\%$. These results demonstrate the feasibility of shape optimization using MADS and FR for aeroacoustic design.