穿孔板对 NACA0012 机翼冲击结构改变的影响

IF 2.1 Q2 ENGINEERING, MULTIDISCIPLINARY Inventions Pub Date : 2024-03-05 DOI:10.3390/inventions9020028
Mihnea Gall, O. Dumitrescu, V. Dragan, D. Crunțeanu
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引用次数: 0

摘要

这项研究调查了一种被动流量控制技术,以减轻冲击波-边界层相互作用对 NACA 0012 机翼的不利影响。研究采用了一种穿孔板,该穿孔板在冲击波锚定点下方战略性地设置了一个空腔。采用不同的制造技术制造了带有不同孔径(从 0.5 毫米到 1.2 毫米不等)穿孔板的机翼。实验分析利用了 "埃菲尔 "型开放式风洞和 Z 型 Schlieren 系统进行流动可视化,以及从底壁获得的静压测量值。经验观察结果与在 Ansys FLUENT 中进行的基于稳定三维密度的数值模拟结果进行了比较,以进行综合分析和验证。穿孔板的实施显著改变了冲击波的结构,使其从强正常冲击波转变为大λ型冲击波。被动控制情况下,总压力损失降低了 0.2%,这归功于穿孔板能够减弱上方锚定冲击波的强度。穿孔板带来了显著的剪切应力波动,在穿孔板区域观察到的剪切应力较低,这是由于空腔吹气导致气流脱离。事实证明,平衡冲击损失和粘性损失是这种被动流量控制方法取得良好效果的关键。
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Effects of Perforated Plates on Shock Structure Alteration for NACA0012 Airfoils
This research investigated a passive flow control technique to mitigate the adverse effects of shock wave–boundary layer interaction on a NACA 0012 airfoil. A perforated plate with a strategically positioned cavity beneath the shock wave anchoring spot was employed. Airfoils with perforated plates of varying orifice sizes (ranging from 0.5 to 1.2 mm) were constructed using various manufacturing techniques. Experimental analysis utilized an “Eiffel”-type open wind tunnel and a Z-type Schlieren system for flow visualization, along with static pressure measurements obtained from the bottom wall. Empirical observations were compared with steady 3D density-based numerical simulations conducted in Ansys FLUENT for comprehensive analysis and validation. The implementation of the perforated plate induced a significant alteration in shock structure, transforming it from a strong normal shock wave into a large lambda-type shock. The passive control case exhibited a 0.2% improvement in total pressure loss and attributed to the perforated plate’s capability to diminish the intensity of the shock wave anchored above. Significant fluctuations in shear stress were introduced by the perforated plate, with lower stress observed in the plate area due to flow detachment from cavity blowing. Balancing shock and viscous losses proved crucial for achieving a favorable outcome with this passive flow control method.
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来源期刊
Inventions
Inventions Engineering-Engineering (all)
CiteScore
4.80
自引率
11.80%
发文量
91
审稿时长
12 weeks
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