细长圆柱构件表面扰流降噪机理的研究

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振动与冲击 ›› 2022, Vol. 41 ›› Issue (10) : 170-176.

论文

细长圆柱构件表面扰流降噪机理的研究

张石宸1，王春江1，孙向东2，常邑2

作者信息 +

Noise reduction mechanism of the surface vortex generator set on a slender cylinder

ZHANG Shichen1,WANG Chunjiang1,SUN Xiangdong2,CHANG Yi2

Author information +

文章历史 +

摘要

通过大涡模拟结合声比拟的方法，研究长方形截面扰流条对光滑圆柱气动噪声的影响。研究中光滑圆柱直径D=0.016m，设置了四种扰流条圆柱工况，即扰流条高度直径比H/D分别为1/8,1/4,3/8和1/2。无扰流措施时，圆柱噪声源位于边界层分离点附近。在圆柱两侧设置扰流措施后，圆柱附近流域具有低湍流特性，大尺度涡结构的展向相关性被破坏，使得圆柱表面压力脉动存在较大相位差；扰流条上游出现滞留涡结构，抑制了上游分离剪切层增长，降低了圆柱上下表面压力脉动。两机制共同作用抑制了圆柱绕流噪声。当扰流条高度直径比H/D=3/8时，降噪效果最好，在主要辐射方向上，音调噪声下降了18.17dB。

Abstract

Using large eddy simulation and acoustic analogy, the influence of rectangular strip as vortex generator on aerodynamic noise of cylinder was studied. The diameter of cylinder was 0.016m in this research. Besides, four analysis of cylinder with strips were conducted, and the height diameter ratio of strip were respectively 1/8, 1/4, 3/8 and 1/2. Without strips, the noise source of cylinder is near boundary layer separation point. After setting strips, it was found that the flow around cylinder is low-turbulent, and the transverse correlation of large scale vortex structure is destroyed resulting in large phase difference of pressure fluctuation on the surface of the cylinder. The trapped vortex structure appears in the upstream of strip, which inhibits the growth of separated shear layer and reduces pressure fluctuation on the upper and lower surfaces of cylinder. The couple of two mechanisms suppresses aerodynamic noise around cylinder. When the height diameter ratio of strip is 3/8, noise reduction measure performs best and in the main radiation direction, the tonal noise is reduced by 18.17dB.

导出引用

张石宸1，王春江1，孙向东2，常邑2. 细长圆柱构件表面扰流降噪机理的研究[J]. 振动与冲击, 2022, 41(10): 170-176

ZHANG Shichen1,WANG Chunjiang1,SUN Xiangdong2,CHANG Yi2. Noise reduction mechanism of the surface vortex generator set on a slender cylinder[J]. Journal of Vibration and Shock, 2022, 41(10): 170-176

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