A discrete adjoint framework for trailing-edge noise minimization via porous material

•Discrete adjoint framework developed for trailing-edge noise minimization.•Algorithmic differentiation enables highly accurate and robust adjoint computation.•Noise reduction achieved by optimal design of a porous trailing-edge.•Design space of porous trailing-edge problem shown to be multi-modal....

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Bibliographic Details
Published in:Computers & fluids 2018-08, Vol.172, p.97-108
Main Authors: Zhou, Beckett Y., Ryong Koh, Seong, Gauger, Nicolas R., Meinke, Matthias, Schöder, Wolfgang
Format: Article
Language:English
Subjects:
Adjoint optimization
Algorithms
Broadband
Computational fluid dynamics
Computer simulation
Design optimization
Flat plates
Large eddy simulation
Noise levels
Noise reduction
Noise spectra
Porosity
Porous material
Porous materials
Porous media
Sensitivity analysis
Subsonic flow
Trailing edges
Trailing-edge noise
Turbulent flow
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Summary:•Discrete adjoint framework developed for trailing-edge noise minimization.•Algorithmic differentiation enables highly accurate and robust adjoint computation.•Noise reduction achieved by optimal design of a porous trailing-edge.•Design space of porous trailing-edge problem shown to be multi-modal. A discrete adjoint framework on the basis of algorithmic differentiation (AD) is developed for trailing-edge noise minimization. Turbulent flow through porous media is modeled based on the conservative transport equations filtered by a local volume-averaging method in which the effect of the porous media is modeled as viscous source terms. This framework is applied to identify the optimal distribution of porous material of a flat plate with a porous trailing edge in subsonic flow resolved with a high resolution large-eddy simulation (LES) method. The AD-based noise adjoint is shown to be highly accurate and allows for efficient evaluation of the entire design sensitivity vector in one stroke, at a cost comparable to that of a single primal LES simulation. Noise minimization is performed to determine the optimal distribution of the design variables that govern the porosity and permeability of the trailing edge. The optimal design obtained is found to attain a maximum noise reduction of 12 dB from a flat plate with solid trailing edge and 3 dB from the baseline design with a linear porosity variation, respectively. Comparison of noise spectra reveals that the optimization has little effect on the broadband noise component compared to its baseline level. The design space of this optimization problem is also shown to be multi-modal.
ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2018.06.017