关键词: 大涡模拟;钝体绕流;流动控制减阻;流动分离;雷诺数

Abstract: The drag reduction for bluff body flow has high potential for application in aeronautical engineering, and it is also a hot research topic for fundamental study. In order to explore the fine flow structures and develop efficient passive flow control method for drag reduction, using high fidelity large eddy simulation, the present study numerically conducts passive flow control of drag reduction for a simplified D-shaped cylinder. Firstly, based on previous research, a small smooth circular cylinder is placed near the shear layer in the wake region of the D-shaped cylinder, and its effect on the drag reduction is numerically studied. It is found that the total drag can be reduced by 17.7%, which agrees with the experimental data very well. The predicted velocity flow fields are found to agree with the experimental results well too. Furthermore, the present study proposes a new flow control approach, i.e. to apply the grooved-surface circular cylinder to replace the previous smooth one to disturb the wake flow after the D-shaped cylinder. The numerical study is performed and it is found that the total drag can be reduced by 21.4%. The larger drag reduction confirms that the proposed flow control method can work well. At last, the Reynolds number effect is studied and three cases with different Reynolds number are carried out. The drag reduction methods with two different small cylinder disturbances work quite well at different Reynolds numbers, and the maximum drag reductions by the two small cylinder disturbances are 19.6% and 23.1%, respectively. Based on the numerical results from the large eddy simulation, the relevant flow mechanism of the drag reduction is also explored. The obtained results demonstrate that by controlling the flow fields properly, a better drag reduction method can be obtained.

Key words: Large eddy simulation;Turbulent flow around bluff body;Flow control for drag reduction;Flow separation;Reynolds number