Litcius/Paper detail

Broadband trailing edge noise reduction through porous velvet-coated serrations

Peng Zhou, Siyang Zhong, Xiangtian Li, Yuhong Li, Wangqiao Chen, Hanbo Jiang, Xin Zhang

2022Physics of Fluids17 citationsDOI

Abstract

This study experimentally investigates the potential of using combinations of trailing edge serrations and thin porous membrane/velvet structures for turbulent boundary layer trailing edge noise reduction. The experiments were conducted in an anechoic wind tunnel, with a flat plate model as the baseline model. The chord-based Reynolds number ranged between 2×105 and 5×105, and the boundary layers were fully tripped near the leading edge. Two different installation methods were tested, where the serration structure was aligned/misaligned with the undisturbed wake flow. It was observed that the noise reduction capability of the conventional serrations deteriorates significantly when the serrations are misaligned with the flow, while the performances of the combined structures are only slightly affected by flow misalignment. A novel combined treatment is developed, in which the trailing edge serrations are surrounded by serrated porous velvet structures. This treatment is found to outperform the unmodified serrations and can achieve approximately 10 dB noise reduction in both flow-aligned and flow-misaligned conditions, within a wide frequency range corresponding to a boundary layer thickness-based Strouhal number Stδ between 0.3 to 1. A 30%–40% increase in the aerodynamic drag due to the velvet structures was observed. Further hotwire wake survey revealed the possible mechanisms for the additional noise reduction capability of the combined treatments.

Topics & Concepts

SerrationTrailing edgeStrouhal numberWakeBoundary layerNoise reductionPhysicsLeading edgeDragNoise (video)TurbulenceVortex sheddingAcousticsWater tunnelAeroacousticsReynolds numberMechanicsMaterials scienceComposite materialVortexSound pressureImage (mathematics)Computer scienceArtificial intelligenceAerodynamics and Acoustics in Jet FlowsWind and Air Flow StudiesAerodynamics and Fluid Dynamics Research