Niloofar Hosseini, Mehran Tadjfar, Mohammad Saeedi, Antonella Abbà
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引用次数: 0
摘要
本研究采用数值方法研究了在低雷诺数流动条件下,摆动机翼产生的涡流与置于摆动前翼下游的后翼之间的相互作用。前翼在大振幅俯仰振荡的诱导下进入深度动态失速。动态失速过程的特点是不稳定分离和形成强烈的顺时针旋涡。计算流场时采用了壁面分辨大涡流模拟方法。对不可压缩流进行了数值测量,其雷诺数为 Re = 30 000,基于弦长,俯仰降低频率为 K=0.5,在 Selig-Donovan 7003 机翼上的振幅为 A=14.1°。根据数值和实验测量结果对单翼面情况进行了验证。在本研究中,我们采用大涡流模拟方法研究了与微型空气飞行器应用相关的串联翼面配置中俯仰前翼的深度动态失速和涡流相互作用产生的流场和气动系数。大涡流模拟还与二维非稳态雷诺平均纳维-斯托克斯模拟进行了比较,以确定低保真方法在预测低雷诺数流动的深度动态失速和涡流相互作用时的准确性和有效性。
Large-eddy simulation of vortex interaction in pitching-fixed tandem airfoils
In this study, the interaction of vortices generated from an oscillating airfoil with a hindfoil placed downstream of the oscillating forefoil at low-Reynolds-number flow was investigated numerically. The forefoil entered a deep dynamic stall induced by large-amplitude pitching oscillation. The dynamic stall process is characterized by unsteady separation and the formation of a strong clockwise vortex. A wall-resolved large-eddy simulation approach was applied to compute the flowfield. The numerical measurements were performed for an incompressible flow at a Reynolds number of Re = 30 000 based on chord length with a pitching reduced frequency of K= 0.5, and amplitude of A = 14.1° over Selig–Donovan 7003 airfoils. A single-airfoil case was validated against numerical and experimental measurements. In the present study, we investigated the flowfield and aerodynamic coefficients resulting from the deep dynamic stall of the pitching forefoil and the vortex interaction in tandem-airfoil configuration related to micro-air vehicle applications by employing large-eddy simulation approach. Large-eddy simulation was also compared to two-dimensional unsteady Reynolds-averaged Navier–Stokes simulation to determine the accuracy and validity of the low-fidelity approach in prediction of deep dynamic stall and vortex interaction at low-Reynolds-number flow.
期刊介绍:
Physics of Fluids (PoF) is a preeminent journal devoted to publishing original theoretical, computational, and experimental contributions to the understanding of the dynamics of gases, liquids, and complex or multiphase fluids. Topics published in PoF are diverse and reflect the most important subjects in fluid dynamics, including, but not limited to:
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