Wind Tunnel Experiments on Parallel Blade–Vortex Interaction with Static and Oscillating Airfoil

IF 1.8 Q3 MECHANICS
Fluids Pub Date : 2024-05-10 DOI:10.3390/fluids9050111
Andrea Colli, Alex Zanotti, G. Gibertini
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Abstract

This study aims to experimentally investigate the effects of parallel blade–vortex interaction (BVI) on the aerodynamic performances of an airfoil, in particular as a possible cause of blade stall, since similar effects have been observed in literature in the case of perpendicular BVI. A wind tunnel test campaign was conducted reproducing parallel BVI on a NACA 23012 blade model at a Reynolds number of 300,000. The vortex was generated by impulsively pitching a second airfoil model, placed upstream. Measurements of the aerodynamic loads acting on the blade were performed by means of unsteady Kulite pressure transducers, while particle image velocimetry (PIV) techniques were employed to study the flow field over the blade model. After a first phase of vortex characterisation, different test cases were investigated with the blade model both kept fixed at different incidences and oscillating sinusoidally in pitch, with the latter case, a novelty in available research on parallel BVI, representing the pitching motion of a helicopter main rotor blade. The results show that parallel BVI produces a thickening of the boundary layer and can induce local flow separation at incidences close to the stall condition of the airfoil. The aerodynamic loads, both lift and drag, suffer important impulsive variations, in agreement with literature on BVI, the effects of which are extended in time. In the case of the oscillating airfoil, BVI introduces hysteresis cycles in the loads, which are generally reduced. In conclusion, parallel BVI can have a detrimental impact on the aerodynamic performances of the blade and even cause flow separation, which, while not being as catastrophic as in the case of dynamic stall, has relatively long-lasting effects.
静态和振动翼面平行叶片-涡流相互作用的风洞试验
本研究旨在通过实验研究平行叶片-涡流相互作用(BVI)对机翼气动性能的影响,特别是可能导致叶片失速的原因,因为在文献中已观察到垂直 BVI 的类似影响。我们在雷诺数为 300,000 的 NACA 23012 叶片模型上进行了平行 BVI 的风洞试验。涡流是由放置在上游的第二个机翼模型脉冲式俯仰产生的。通过非稳定库莱特压力传感器对作用在叶片上的空气动力载荷进行测量,同时采用粒子图像测速仪(PIV)技术研究叶片模型上的流场。在第一阶段的涡流特征描述之后,对不同的测试案例进行了研究,叶片模型既在不同的发生率下保持固定,又在俯仰方向上正弦摆动,后一种情况是现有平行 BVI 研究中的一种新情况,代表了直升机主旋翼叶片的俯仰运动。研究结果表明,平行 BVI 会导致边界层增厚,并在接近机翼失速条件时引起局部气流分离。气动载荷,包括升力和阻力,都受到了重要的脉冲变化影响,这与有关 BVI 的文献一致,其影响在时间上是扩展的。在振荡机翼的情况下,BVI 在载荷中引入了滞后周期,但这种滞后周期一般会减小。总之,平行 BVI 会对叶片的气动性能产生不利影响,甚至导致气流分离,虽然不像动态失速那样具有灾难性,但其影响相对持久。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Fluids
Fluids Engineering-Mechanical Engineering
CiteScore
3.40
自引率
10.50%
发文量
326
审稿时长
12 weeks
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