English

Wing sweep effects on laminar separated flows

Fluid Dynamics 2022-06-13 v1

Abstract

We reveal the effects of sweep on the wake dynamics around NACA 0015 wings at high angles of attack using direct numerical simulations and resolvent analysis. The influence of sweep on the wake dynamics is considered for sweep angles from 00^\circ to 4545^\circ and angles of attack from 1616^\circ to 3030^\circ for a spanwise periodic wing at a chord-based Reynolds number of 400400 and a Mach number of 0.10.1. Wing sweep affects the wake dynamics, especially in terms of stability and spanwise fluctuations with implications on the development of three-dimensional wakes. We observe that wing sweep attenuates spanwise fluctuations. Even as the sweep angle influences the wake, force and pressure coefficients can be collapsed for low angles of attack when examined in wall-normal and wingspan-normal independent flow components. Some small deviations at high sweep and incidence angles are attributed to vortical wake structures that impose secondary aerodynamic loads, revealed through the force element analysis. Furthermore, we conduct global resolvent analysis to uncover oblique modes with high disturbance amplification. The resolvent analysis also reveals the presence of wavemakers in the shear-dominated region associated with the emergence of three-dimensional wakes at high angles of attack. For flows at high sweep angles, the optimal convection speed of the response modes is shown to be faster than the optimal wavemakers speed suggesting a mechanism for the attenuation of perturbations. The present findings serve as a fundamental stepping stone to understanding separated flows at higher Reynolds numbers.

Keywords

Cite

@article{arxiv.2206.04718,
  title  = {Wing sweep effects on laminar separated flows},
  author = {Jean Hélder Marques Ribeiro and Chi-An Yeh and Kai Zhang and Kunihiko Taira},
  journal= {arXiv preprint arXiv:2206.04718},
  year   = {2022}
}
R2 v1 2026-06-24T11:45:38.984Z