The hydrodynamic pressure fluctuations that occur on the solid surface beneath a turbulent boundary layer are a common source of flow noise. This paper reports multipoint surface pressure fluctuation measurements in water beneath a high-Reynolds-number turbulent boundary layer with wall injection of air to reduce skin-friction drag. The experiments were conducted in the U.S. Navy's Large Cavitation Channel on a 12.9-m-long, 3.05-m-wide hydrodynamically smooth flat plate at freestream speeds up to 20 m/s and downstream-distance-based Reynolds numbers exceeding 200 X 10(6). Air was injected from one of two spanwise slots through flush-mounted porous stainless steel frits (similar to 40 mu m mean pore diameter) at volume flow rates from 17.8 to 142.5 l/s per meter span. The two injectors were located 1.32 and 9.78 m from the model's leading edge and spanned the center 87% of the test model. Surface pressure measurements were made with 16 flush-mounted transducers in an "L-shaped" array located 10.7 m from the plate's leading edge. When compared to no-injection conditions, the observed wall-pressure variance was reduced by as much as 87% with air injection. In addition, air injection altered the inferred convection speed of pressure fluctuation sources and the streamwise coherence of pressure fluctuations. (c) 2008 Acoustical Society of America.
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机译:在湍流边界层下面的固体表面上发生的流体动力压力波动是流动噪声的常见来源。本文报告了在高雷诺数湍流边界层下方的水中多点表面压力波动的测量结果,并通过注入空气壁来减少皮肤摩擦阻力。实验是在美国海军的大型汽蚀通道上的一块12.9米长,3.05米宽的流体动力学光滑平板上进行的,自由流速度高达20 m / s,基于下游距离的雷诺数超过200 X 10( 6)。通过平齐安装的多孔不锈钢熔块(类似于平均孔径40μm)从两个跨度缝隙之一注入空气,体积流量为每米跨度17.8至142.5 l / s。这两个喷油嘴位于距模型前缘1.32和9.78 m处,并横跨了测试模型中心的87%。用16个齐平安装的传感器以“ L形”阵列的形式进行表面压力测量,该阵列位于距板前缘10.7 m处。与无喷射条件相比,通过空气喷射观察到的壁压变化降低了多达87%。另外,空气注入改变了压力波动源的对流速度和压力波动的沿流相干性。 (c)2008年美国声学学会。
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