Experimental investigation of the effect of sectional airfoil profile deviation on propeller noise

This paper presents a comprehensive experimental aeroacoustic investigation of a propeller under turbulence ingestion. Two turbulence-generating passive grids were utilized to quantify the effect of turbulence intensity on the aeroacoustic characteristics of the propeller. A two-component hot-wire anemometry was employed to study the flow field. The flow field results demonstrate a substantial increase in fluctuating velocity components in both axial and radial directions, concentrated at the mid-span of the blade and near the tip, respectively. Energy spectral analysis in the vicinity of the propeller blade shows significantly higher broadband energy levels with multiple haystacking peaks at the harmonics of the blade passage frequency. Far-field noise and load measurement results show that turbulence ingestion has a strong effect on the aerodynamic loading and acoustic response at the blade passage frequency. The directivity of noise radiation at low frequency shows a significant tonal noise contribution. Meanwhile, broadband noise radiation is more dominant at a higher range of frequency, especially when the propeller is operated with turbulence ingestion and at higher advance ratio settings. The far-field noise results revealed the haystacking trends in the low frequency domain of the spectra and are most significant for propellers operating in turbulent inflows.

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Experimental investigation of ducted fan noise control by turbulence grids insertion between propellers and struts

Wang,

Ma,

Huang

2024

Physics of Fluids

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The control of turbulence-ingested propeller noise remains a challenging topic for unmanned aerial vehicles and urban air mobility applications. In this work, passive noise control by inserting turbulence grids between a propeller and struts for a ducted fan system is experimentally studied. The 3-bladed, 8 in. diameter propeller is mounted in a short duct downstream of 7 struts, each featuring symmetrical airfoil shapes with a chord length of 30 mm. Two turbulence grid configurations, namely, fully shaded and tip-shaded, are investigated by comparing the spectra and directivity characteristics of the aeroacoustic noise and their aerodynamic performance. Beamforming technology and hot-wire anemometry are employed to explore the fluid mechanics. The results show that at same rotating speed, the fully shaded turbulence grid is more effective in reducing the tonal noise. The overall noise reduction capability for the two cases is similar, and an overall sound pressure level noise reduction of roughly 3 dB is achieved. Due to the blockage effect of the turbulence grid, the fully shaded case bears a 20% thrust loss, while the tip-shaded case has a marginal deficit of thrust. When the rotating speed is adjusted to produce the same thrust of the baseline, the fully shaded case shows an increase in the overall noise, while the tip-shaded case maintains the noise reduction capability. The beamforming results and turbulence intensity measurements show that the propeller tip region has a strong interaction of the turbulence ingestion flow and tip leakage flow where the broadband noise source is dominant.

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Experimental investigation of the effect of sectional airfoil profile deviation on propeller noise

Cited by 6 publications

References 38 publications

Numerical investigation of cavitation induced noise and noise reduction mechanism for the leading-edge protuberances

Numerical investigation of cavitation induced noise and noise reduction mechanism for the leading-edge protuberances

Experimental analysis of a propeller noise in turbulent flow

Experimental investigation of ducted fan noise control by turbulence grids insertion between propellers and struts

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