Effect of passive porous surface on the trailing-edge noise

This study numerically investigates the effect of porous surfaces on the turbulent noise generated by a blunt trailing-edge of a flat plate. The three-dimensional turbulent flow over the flat plate ( Re c =1.3×10 5 and M =0.06) is computed by incompressible large eddy simulation (LES) based on the volume-averaged Navier-Stokes equations, while the acoustic field is calculated by the linearized perturbed compressible equations (LPCEs) coupled with LES. The porous surface is applied to a small, selected area near the trailing-edge where vortex shedding and edge-scattering of convecting eddies generate dipole noise. The computed results show that the trailing-edge with porosity ε = 0 . 25 and permeability (normalized) K * =0.01 yields a reduction of the tonal peak by 13 dB for the zero angle of attack ( α =0°) case, via breaking not only in the streamwise direction but also in the spanwise direction, the spatial correlation of the wall pressure fluctuations near the trailing-edge. For the separated flow case ( α =5°), the porous surface is found to weaken the pressure fluctuations at the trailing-edge and results in 3∼10 dB noise reduction over a wide range of frequency, via interrupting the edge-scattering and reducing the separated flow region over the upper surface of the plate.