An automated method for the identification of interaction tone noise sources on the beamforming maps of counter-rotating rotors

Fenyvesi, Bence; Kriegseis, Jochen; Horváth, Csaba

doi:10.1063/5.0083634

Cited by 7 publications

References 44 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

On the prediction of noise generated by urban air mobility (UAM) vehicles. II. Implementation of the Farassat F1A formulation into a modern surface-vorticity panel solver

et al. 2022

View full text Add to dashboard Cite

This study focuses on the integration of established acoustic prediction techniques directly into a surface-vorticity solver. The main objective is to enhance an aircraft designer's ability to characterize the acoustic signatures generated by urban air mobility (UAM) vehicles in general, and Distributed Electric Propulsion (DEP) concepts in particular, including Unmanned Aerial Vehicles (UAVs). Our solver consists of a reliable, surface-vorticity panel code that incorporates viscous boundary-layer corrections. It thus offers a computationally efficient commercial tool for conceptual design and preliminary aerodynamic analysis. By implementing the Farassat F1A acoustics formulation directly into the solver, a new intuitive capability is achieved, which is both conversive with modern engineering tools and efficient in setup and speed of execution. Besides its application to the X-57 High-Lift Propeller and the Revolutionary Vertical Lift Technology (RVLT) Tiltwing electric Vertical Take-Off and Landing (eVTOL) vehicle by the National Aeronautics and Space Administration (NASA), this capability is systematically demonstrated using three particular case studies. These consist of both single- and six-propeller Joby S4 eVTOL as well as a small eight-propeller Kittyhawk KH-H1 DEP vehicle. Whereas the details of this tool and underlying equations are showcased in this article, the acoustic metrics that can be effectively used to characterize the noise level generated by a UAM in flight are described in a companion article. By embedding this assortment of insightful metrics into a simple and user-friendly flow solver, a much improved flow-acoustic analysis capability is thereby provided to support the design of future aircraft.

show abstract

On the prediction of noise generated by urban air mobility (UAM) vehicles. II. Implementation of the Farassat F1A formulation into a modern surface-vorticity panel solver

et al. 2022

View full text Add to dashboard Cite

show abstract

On the prediction of noise generated by urban air mobility (UAM) vehicles. I. Integration of fundamental acoustic metrics

et al. 2022

View full text Add to dashboard Cite

This work identifies and explores several aeroacoustic metrics that allow for urban air mobility (UAM) vehicle noise prediction. An increase in production and use of UAM and distributed electric propulsion (DEP) vehicles within populated civilian areas stands behind the need to minimize the noise produced by these vehicles. The FAA's strict noise regulations on UAM aircraft compels designers to place a significant emphasis, early in the design phase, on the characterization and analysis of the external noise generated by these vehicles, namely, to ensure their design viability. To accomplish this, the present study focuses on the analysis and interpretation of predicted noise signals using a set of characteristic metrics that can be instrumental at guiding the design process. Following a thorough review of metrics standardized by the International Civil Aviation Organization (ICAO) as well as the Federal Aviation Association (FAA), seven general metrics are identified, evaluated, and discussed in the context of UAM noise prediction. When used in conjunction with a modern surface-vorticity panel code, these metrics are shown to provide an effective assortment of tools to concisely describe UAM-based acoustic signal properties.

show abstract

Flow and acoustics of unmanned vehicles

Drikakis

Dbouk

2022

Physics of Fluids

View full text Add to dashboard Cite

An automated method for the identification of interaction tone noise sources on the beamforming maps of counter-rotating rotors

Cited by 7 publications

References 44 publications

On the prediction of noise generated by urban air mobility (UAM) vehicles. II. Implementation of the Farassat F1A formulation into a modern surface-vorticity panel solver

On the prediction of noise generated by urban air mobility (UAM) vehicles. II. Implementation of the Farassat F1A formulation into a modern surface-vorticity panel solver

On the prediction of noise generated by urban air mobility (UAM) vehicles. I. Integration of fundamental acoustic metrics

Flow and acoustics of unmanned vehicles

Contact Info

Product

Resources

About