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Numerical and Experimental Second Law Analysis of a Low Thickness High Chamber Wing Profile
Technical Paper
2018-01-1955
ISSN: 0148-7191, e-ISSN: 2688-3627
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Abstract
This paper presents a coupled numerical and experimental study of an unconventional wing profile such as cp-180-050-gn (Cambered plate C = 18% T = 5% R = 0.78). This wing profile deals with low speeds. It is not currently used on any aircraft model. Otherwise, it presents interesting performances that can be exploited for the design of low-speed STOL or VTOL aircraft by mean of the very high lift that it can generate and can fit with different uses such as VAWT, cyclorotors drones, which are designed explicitly for low-speed operations. After a preliminary CFD assessment of the wing a complete experimental characterisation also at high angles of attack has been performed. The excellent agreement between CFD and experiments has allowed producing a complete analysis of the behaviour of the wing profile both before and after stall conditions. This study has the objective of analysing the viability of such an unconventional wing in traditional or over-stalling conditions. A complete modelling of the specific wing is produced with the definition of its potential deployment into unconventional aircraft architectures and both Darreius and Savonius wind turbines.
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Trancossi, M. and Sharma, S., "Numerical and Experimental Second Law Analysis of a Low Thickness High Chamber Wing Profile," SAE Technical Paper 2018-01-1955, 2018, https://doi.org/10.4271/2018-01-1955.Data Sets - Support Documents
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