A large-eddy simulation on a deep-stalled aerofoil with a wavy leading edge
A large-eddy simulation on a deep-stalled aerofoil with a wavy leading edge
A numerical investigation on the stalled flow characteristics of a NACA0021 aerofoil with a sinusoidal wavy leading edge (WLE) at chord-based Reynolds number Re∞= 1.2×105 and angle of attack α =20◦ is presented in this paper. It is observed that laminar separation bubbles (LSBs) form at the trough areas of the WLE in a collocated fashion rather than uniformly/periodically distributed over the span. It is found that the distribution of LSBs and their influence on the aerodynamic forces is strongly dependent on the spanwise domain size of the simulation, i.e. the wavenumber of the WLE used. The creation of a pair of counter-rotating streamwise vortices from the WLE and their evolution as an interface/buffer between the LSBs and the adjacent fully separated shear layers are discussed in detail. The current simulation results confirm that an increased lift and a decreased drag are achieved by using the WLEs compared to the straight leading edge (SLE) case, as observed in previous experiments. Additionally, the WLE cases exhibit a significantly reduced level of unsteady fluctuations in aerodynamic forces at the frequency of periodic vortex shedding. The beneficial aerodynamic characteristics of the WLE cases are attributed to the following three major events observed in the current simulations: (i) the appearance of a large low-pressure zone near the leading edge created by the LSBs; (ii) the reattachment of flow behind the LSBs resulting in a decreased volume of the rear wake; and, (iii) the deterioration of von-Kármán (periodic) vortex shedding due to the breakdown of spanwise coherent structures.
23-52
Perez Torro, R.
6fed3e46-72f4-4d22-9e02-9c5f0fd24854
Kim, J.W.
fedabfc6-312c-40fd-b0c1-7b4a3ca80987
1 February 2017
Perez Torro, R.
6fed3e46-72f4-4d22-9e02-9c5f0fd24854
Kim, J.W.
fedabfc6-312c-40fd-b0c1-7b4a3ca80987
Perez Torro, R. and Kim, J.W.
(2017)
A large-eddy simulation on a deep-stalled aerofoil with a wavy leading edge.
Journal of Fluid Mechanics, 813, .
(doi:10.1017/jfm.2016.841).
Abstract
A numerical investigation on the stalled flow characteristics of a NACA0021 aerofoil with a sinusoidal wavy leading edge (WLE) at chord-based Reynolds number Re∞= 1.2×105 and angle of attack α =20◦ is presented in this paper. It is observed that laminar separation bubbles (LSBs) form at the trough areas of the WLE in a collocated fashion rather than uniformly/periodically distributed over the span. It is found that the distribution of LSBs and their influence on the aerodynamic forces is strongly dependent on the spanwise domain size of the simulation, i.e. the wavenumber of the WLE used. The creation of a pair of counter-rotating streamwise vortices from the WLE and their evolution as an interface/buffer between the LSBs and the adjacent fully separated shear layers are discussed in detail. The current simulation results confirm that an increased lift and a decreased drag are achieved by using the WLEs compared to the straight leading edge (SLE) case, as observed in previous experiments. Additionally, the WLE cases exhibit a significantly reduced level of unsteady fluctuations in aerodynamic forces at the frequency of periodic vortex shedding. The beneficial aerodynamic characteristics of the WLE cases are attributed to the following three major events observed in the current simulations: (i) the appearance of a large low-pressure zone near the leading edge created by the LSBs; (ii) the reattachment of flow behind the LSBs resulting in a decreased volume of the rear wake; and, (iii) the deterioration of von-Kármán (periodic) vortex shedding due to the breakdown of spanwise coherent structures.
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Manuscript-PerezTorro-Kim.pdf
- Accepted Manuscript
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Submitted date: 17 June 2016
Accepted/In Press date: 1 December 2016
e-pub ahead of print date: 17 January 2017
Published date: 1 February 2017
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 399809
URI: http://eprints.soton.ac.uk/id/eprint/399809
ISSN: 0022-1120
PURE UUID: d0236d7e-d3ca-438a-aca9-2e45ceb9888a
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Date deposited: 30 Aug 2016 08:48
Last modified: 15 Mar 2024 03:21
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