Bio-inspired optimization of leading edge slat

Mohamed, Mohamed Arif Raj; Reddy, Ketu Satish Kumar; Vishnu, Somaraju Sai Sri

doi:10.1108/aeat-06-2022-0150

Cited by 2 publications

(1 citation statement)

References 19 publications

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“…Incorporating an internally blowing flap and a leading edge slat can significantly improve the overall force coefficients (Burnazzi and Radespiel 2014). Bio-inspired leading-edge slats' performance was tested using the cambered aerofoil (Mandadzhiev et al 2017;Raj et al 2023). Javur et al (1982) demonstrated that the off-design performance of an axial flow fan was improved by a slat attachment, while Chen et al (2012) reported an improvement in off-design aerodynamic performance of fluid machinery by using slat augmentation.…”

Section: Introductionmentioning

confidence: 99%

Flow Separation Control of a Vertical Stabiliser using a Rudder-mounted Slat

Muhammad

Wang

Mao

et al. 2023

Preprint

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A joint study utilising experimental and numerical methods was carried out to investigate the aerodynamic effect of a rudder-mounted slat on a vertical stabiliser. The wind tunnel test results showed that the side force coefficient was increased by up to 4% while the drag coefficient was unchanged when the rudder deflection angle was set to δ = 30°. Large eddy simulation (LES) results suggested that the rudder-mounted slap can increase the circulation around the vertical stabiliser, showing that the flow from the upstream recirculating regions was drawn towards the rudder surface. Associated changes in the turbulent flow field, including the mean and turbulent flow field and the vortical structure are also presented to understand the flow control mechanism by the rudder-mounted slat.

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Section: Introductionmentioning

confidence: 99%

Flow Separation Control of a Vertical Stabiliser using a Rudder-mounted Slat

Muhammad

Wang

Mao

et al. 2023

Preprint

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Real-time optimization of wing drag and lift performance using a movable leading edge

Camacho,

da Silva,

Silva

et al. 2024

Physics of Fluids

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A real-time optimization strategy can provide any system with a considerable boost in performance on the fly, which in real-world applications can be translated to lower energy consumption or higher efficiency. This study investigates the particular case of using real-time optimization to improve wing aerodynamic performance with a dynamically activated deflectable leading edge. Its activation aims to minimize drag and maximize lift and is governed by real-time and gradient-based optimization. An extension to a classic method is suggested to enhance gradient estimation accuracy. Experimental data are obtained at a Reynolds number of 2.0×105 with the wing fixed at five positions. For each of these positions, optimal leading-edge deflections are found. The results indicate that deflecting the leading edge has a negligible impact on drag and lift before the stall onset. However, the reduction in the pitching moment cannot be ignored. When the wing is experiencing a proper stall, the movable leading edge yields remarkable enhancements, with the lift being approximately raised by 45% together with a substantial increase in the critical angle of attack. The findings highlight the potential of real-time optimization in experimental aerodynamic studies, reinvigorating its application in improving aircraft performance.

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Bio-inspired optimization of leading edge slat

Cited by 2 publications

References 19 publications

Flow Separation Control of a Vertical Stabiliser using a Rudder-mounted Slat

Flow Separation Control of a Vertical Stabiliser using a Rudder-mounted Slat

Real-time optimization of wing drag and lift performance using a movable leading edge

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