Effect of Separation and Stall on Aerofoil Noise
Reference Number
EP/R010846/1
Title
Effect of Separation and Stall on Aerofoil Noise
Status
Completed
Energy Categories
Renewable Energy Sources(Wind Energy)
Energy Efficiency(Transport)
Energy Efficiency(Transport)
Research Types
Basic and strategic applied research
Science and Technology Fields
ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering)
UKERC Cross Cutting Characterisation
Sociological economical and environmental impact of energy (Environmental dimensions)
Sociological economical and environmental impact of energy (Other sociological economical and environmental impact of energy)
Sociological economical and environmental impact of energy (Other sociological economical and environmental impact of energy)
Principal Investigator
Dr M Azarpeyvand
Mechanical Engineering
University of Bristol
Mechanical Engineering
University of Bristol
Award Type
Standard
Funding Source
EPSRC
Start Date
01 June 2018
End Date
30 June 2022
Duration
49 months
Total Grant Value
£434,409
Industrial Sectors
Mechanical engineering
Region
South West
Programme
NC : Engineering
Investigators
Principal Investigator
Dr M Azarpeyvand, Mechanical Engineering, University of Bristol
Industrial Collaborator
Web Site
Objectives
Abstract
It is well established that long-term exposure to aircraft and wind turbine noise is responsible for many physiological and psychological effects. The World Health Organization estimated in 2011 that up to 1.6 million healthy life years are lost annually in the western European countries because of exposure to high levels of noise. This is in direct conflict with the further increase in the number of flights in the EU and US and development and further expansion of on-shore wind farms. Therefore, it is critical to better understand the noise generation mechanism from different aero-components and develop tailored noise reduction methods in order to reduce the noise at source. Amongst all components, understanding of noise generation from aerofoils is of great importance, due to its contribution to the overall noise of aircraft or wind turbine. To a great extent, our current knowledge of aerofoil noise generation is limited to aerofoils at low angles of attack. However, most aerofoils are operated at higher angles of attack to maximise aerodynamic performance where they are prone to separation and stall, especially when they are operating under varied conditions. In these situations, the noise generation as well as the flow mechanisms are substantially different compared to lower angles of attack. Our knowledge and understanding of the mechanisms as well as our ability to predict these noise sources is limited. This collaborative project, which includes contributions from industrial partners, aims to develop new understanding of noise generation mechanisms in the presence of separation and stall. The goal is to perform experiments and numerical simulations in order to establish a high-fidelity database of flow and noise for over a wide range of operating conditions. The data will then be used to identify flow mechanisms that contribute to the different aerofoil noise sources at high angles of attack. The experimental and numerical data will also be utilised to develop new fully-validated models for noise prediction, which can then be used by our industrial partners (GE-Dowty and Embraer) to improve the design of next generation of lifting surfaces across different applications. Overall, this project will bring about a step change in our understanding of noise generation mechanisms across the entire regime and pave the way to more accurate noise predictions and development of potential noise mitigation strategies
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Added to Database
17/09/18
