The mystery of how futuristic aircraft-embedded engines make noise has been solved by researchers at the University of Bristol.
The new study reveals for the first time how noise is generated by and propagated from engines known as boundary layer ingesting (BLI) ducted fans. BLI ducted fans are similar to the large engines found in modern airplanes but are partially embedded into the plane’s main body instead of under the wings. Because they ingest air both from the front and from the surface of the airframe, they don’t have to work as hard to move the plane, so it burns less fuel.
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The research, led by Feroz Ahmed from Bristol’s School of Civil, Aerospace and Design Engineering under the supervision of Professor Mahdi Azarpeyvand, utilised the University National Aeroacoustic Wind Tunnel Facility. The researchers were able to identify distinct noise sources originating from the duct, the rotating fan and the air flowing over the curved airframe surface.
They found that the noise pattern changes depending on how much thrust the fan is producing. When the fan is producing high thrust, they observed a noise pattern similar to that seen in fans without ducts. But when the fan is producing less thrust, the noise pattern changes because the duct itself starts making more noise.
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‘Our study addresses this urgent issue of noise, which poses a major obstacle in obtaining certifications, by uncovering the physics behind the noise these configurations produce,’ Ahmed said. ‘By understanding the noise mechanisms in BLI ducted fans, it is hoped that industrial guidelines can be developed for quieter airframe-integrated propulsion systems in future aircraft concepts, from large-scale conventional aircraft to small-scale electric vertical take-off and landing aircraft.’
Projects such as the Bell X-22A, Embraer X, Airbus E-fan, Lilium Jet, Green Jet and Hybrid Air Vehicle are leading the way in developing these systems for next-generation aircraft. They are becoming more popular due to advancements in powerful electric motors.
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‘But there is a catch for embedded ducted fans – how loud or quiet they are is still a mystery, especially when they are ingesting airflow from around the curved airframe surface,’ Ahmed said. ‘Previous research on BLI configurations mostly focused on fans without ducts, where the boundary layer forms over flat airframe surfaces. However, there is a knowledge gap when it comes to the ducted fans ingesting air around curved airframe surfaces, as seen in projects like ONERA NOVA, NASA/MIT Aurora D8, and Airbus Nautilus. ‘So, in this study, we have closely examined the various factors that contribute to the noise produced by the embedded ducted fans installed on curved airframe surfaces.’
The researchers designed a BLI test rig featuring an electric ducted fan mounted next to a curved wall, replicating the setup of embedded engines seen in designs such as the ONERA NOVA aircraft concept. They collected different types of data from the rig, including measurements of the fan’s thrust output and the amount of noise generated. By dissecting the complexities of noise interaction mechanisms among various sources, this framework helped uncover the underlying physics of where the noise originated and how it changed as the fan operated at different thrust levels.
‘With the growing demand for a pleasant flight experience with minimum environmental impact, there is a need for quieter aircraft. This research has potential applications in developing strategies to reduce noise emission in the aviation sector, Ahmed said. ‘Furthermore, our comprehensive investigation into unlocking the noise contributions in BLI ducted fans has the potential to steer significant research activity within the fluid mechanics community. This, in turn, could foster a deeper understanding and further exploration of aeroacoustics phenomena in ducted fans exposed to a broad spectrum of incoming turbulent flows.
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‘Our study sheds light on how noise is generated by futuristic embedded ducted fans mounted on curved airframe surfaces, revealing that noise patterns vary with fan thrust levels, offering crucial insights for quieter next-generation aircraft design,’ he concluded.
The research has been published in the Journal of Fluid Mechanics.