Abstract
In the present study, a large number of acoustic simulations are carried out for a low noise airfoil with different Trailing Edge Serrations (TES). The Ffowcs Williams-Hawkings (FWH) acoustic analogy is used for noise prediction at trailing edge. The acoustic solver is running on the platform of our in-house incompressible flow solver EllipSys3D. The flow solution is first obtained from the Large Eddy Simulation (LES), the acoustic part is then carried out based on the instantaneous hydrodynamic pressure and velocity field. To obtain the time history data of sound pressure, the flow quantities are integrated around the airfoil surface through the FWH approach. For all the simulations, the chord based Reynolds number is around 1.5x106. In the test matrix, the effects from angle of attack, the TE flap angle, the length/width of the TES are investigated. Even though the airfoil under investigation is already optimized for low noise emission, most numerical simulations and wind tunnel experiments show that the noise level is further decreased by adding the TES device.
Highlights
Large Eddy Simulation (LES) tests on airfoil trailing edge serrationJournal of Physics: Conference Series (Online), 753, 022062
During the parametric study of the Trailing Edge Serrations (TES), it is found that the noise level of the current airfoil is reduced nearly in all the configurations over a large range of frequency
It is observed that when the ‘L/c’ ratio increases, the change of the turbulent stress is large which indicates stronger spanwise variation
Summary
Journal of Physics: Conference Series (Online), 753, 022062. Users may download and print one copy of any publication from the public portal for the purpose of private study or research.
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