This study presents the first set of experiments with the Controlled-Diffusion (CD) airfoil in the newly-built anechoic wind-tunnel at Universite de Sherbrooke. Velocity measurements in the latter show very uniform mean flow and low turbulence level (0.4 %) up to 56 m/s in the 30 cm square nozzle exit section. Acoustic and velocity measurements have been carried out at several flow velocities and angles of attack. Three distinct flow regimes are observed. At high angle of attack and high velocity the usual broadband noise signature found in the Ecole Centrale de Lyon anechoic wind tunnels is recovered. At low angle of attack, the power spectral density of the microphone signal is dominated by a primary tone with secondary tones, typical of Tollmien-Schlichting noise radiation. This dominant tone is also recovered in the power spectral density of the flow velocity signal. Signal processing tools (spectrogram and bicoherence) are used to investigate the presence of the secondary tones. Two tonal regimes can then be distinguished: one stationnary and one intermittent where some tones disappear intermittently and are formed by a non-linear process. Finally, two parallel microphone arrays associated with high resolution imaging is used to localize the noise sources at the primary tone frequency, which are found at the airfoil trailing edge. At this low frequency, the L1-GIB algorithm is clearly seen more efficient than classical beamforming.
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机译:本研究介绍了在Universily de Sherbroke的新建的Anechoic风隧道中的受控扩散(CD)翼型的第一组实验。后者的速度测量显示在30cm方形喷嘴出口部分中非常均匀的平均流量和低至56米/秒的低湍流水平(0.4%)。已经在几个流速和攻击角度进行了声学和速度测量。观察到三个不同的流动制度。在高攻角和高速度高速度,恢复了Ecole Centrale De Lyon中发现的通常的宽带噪声签名。在低攻角处,麦克风信号的功率谱密度由具有二次色调的主要音调为主,典型的Tollmien-Schlichting噪声辐射。该主导音调也在流速信号的功率谱密度中恢复。信号处理工具(谱图和双相轴)用于研究次要音调的存在。然后可以区分两个色调的制度:一个施行和一个间歇,其中一些色调间歇地消失,并且通过非线性过程形成。最后,使用与高分辨率成像相关联的两个并行麦克风阵列用于在主音频下定位噪声源,该噪声频率在翼型上发现在翼型后缘。在这种低频下,L1-GIB算法比经典波束形成更有效。
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