CFD-Based Aerodynamic Analysis of the Flow Past an Airfoil With Passive Trapezoidal and Perforated Vortex Generators

Charbel Bou-Mosleh, R. Himo, C. Habchi
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引用次数: 1

Abstract

Passive vortex generators are widely used for heat and mass transfer enhancement in static mixers and heat exchangers. Trapezoidal vortex generators are used in the high efficiency vortex static mixer (HEV) because they generate a complex flow structure enhancing the transport phenomena. Moreover, vortex generators are used on airfoils and cars to delay or suppress flow separation. The flow past triangular and rectangular winglets was studied in the open literature showing good performance in enhancing the lift and drag coefficients. In the present study, a non-conventional vortex generator is proposed consisting on an inclined trapezoidal tab similar to that used in the HEV static mixer. In addition, the tab is perforated at its center (circular perforation). Inline array of several vortex generators are fixed on an airfoil and the drag and lift coefficients are analyzed for different geometries using computational fluid dynamics. Different cases are analyzed where the inclination angles of the vortex generators are changed and their effect is investigated. Furthermore, the effect of changing the size of the vortex generator is also assessed. The results are then compared to conventional vortex generators, mainly triangular winglets. The present results are validated against experimental and numerical data from the literature. The results show that the drag coefficient can be reduced with such vortex generators. They also show good agreement with experimental results for the lift coefficient.
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基于cfd的被动梯形和穿孔涡发生器翼型气流动力学分析
被动涡发生器广泛应用于静态混合器和换热器的强化传热传质。由于梯形涡发生器产生复杂的流动结构,增强了输运现象,因此被应用于高效静态涡混合器中。此外,在翼型和汽车上使用涡发生器来延迟或抑制流动分离。在公开文献中对三角形小翼和矩形小翼的流动进行了研究,结果表明三角形小翼和矩形小翼在提高升力和阻力系数方面有很好的效果。在本研究中,提出了一种非传统的涡发生器,由类似于HEV静态混合器中使用的倾斜梯形片组成。此外,标签在其中心穿孔(圆形穿孔)。采用计算流体力学的方法,对不同几何形状的涡发生器进行了阻力系数和升力系数分析。分析了不同情况下改变涡发生器倾角的情况,并对其影响进行了研究。此外,还评估了改变涡发生器尺寸的影响。然后将结果与传统的涡流发生器(主要是三角形小翼)进行比较。本文的结果与文献中的实验数据和数值数据进行了验证。结果表明,采用这种涡发生器可以降低阻力系数。升力系数的计算结果与实验结果吻合较好。
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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