非定常空化流致噪声数值模拟研究

doi:10.3969/j.issn.1674-8530.16.0157

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摘要采用计算流体力学与声学边界元法相结合对绕水翼非定常空化流动的负载噪声进行计算,同时基于球空泡理论的脉动体积法预测了空泡噪声．研究结果表明:无空化发生时,负载噪声以低频线谱特性为主,声波基频与尾涡脱落频率基本一致,线谱峰值发生于低阶谐频处;空化发生时,相比于负载噪声的线谱成分,连续谱增强较为显著,且负载噪声的总声压级相比无空化时有所增大,并且空泡噪声成为最主要噪声源,辐射噪声频谱呈宽谱特性;空泡噪声功率谱密度的第一和第二个峰值频率分别与空化脱落频率和尾涡脱落频率相对应,而空泡噪声的声能量密度集中在相对较高的频带范围内,这可能是由于云状空化阶段空穴尾部伴随着多尺度的空化泡生长脱落行为所致．

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关键词 ：水翼, 非定常空化流动, 空泡噪声, 负载噪声, 数值模拟

Abstract：The loading noise of unsteady cavitating flow around a hydrofoil is calculated by combining CFD and acoustic boundary element method, meanwhile, the corresponding cavitation noise is predicted by bubble volume pulse method in spherical cavitation bubble theory. The results indicate that noncavitation loading noise is mainly subject to a linear spectrum at low frequency. Moreover, the acoustic fundamental frequency is basically the same as the vortex shedding frequency, and the spectrum peaks are at its loworder harmonics. However, when cavitation occurs, the continuous spectrum is significantly enhanced compared with the linear composition, and the overall acoustic pressure level of loading noise is increased compared with that of noncavitation. In addition, the bubble noise becomes the main noise source with a broad spectrum. The first and second peak frequencies of the acoustic power spectrum density are consistent with the cloud cavitation and trailing vortex shedding frequencies, respectively. Nevertheless, the acoustic power density of bubble noise is concentrated in the higher frequency bands, which may be resulted from the growth and shedding behavior of multiscale bubbles behind the tail of cavity.

Key words： hydrofoil;unsteady cavitating flow bubble noise loading noise numerical simulation

收稿日期: 2016-07-04

通讯作者: 朱明明(1986—),男,安徽淮北人,硕士研究生(zhumingming6@163.com),主要从事流体机械空化噪声研究.

作者简介: 黄彪(1985—),男,湖北武汉人,副教授(huangbiao@bit.edu.cn),主要从事水力机械内部空化流动研究.

引用本文:

朱明明, 黄彪, 王国玉, 王宁. 非定常空化流致噪声数值模拟研究[J]. 排灌机械工程学报, 2017, 35(11): 933-940. ZHU Mingming, HUANG Biao, WANG Guoyu, WANG Ning. Numerical investigation on noise induced by unsteady cavitating flow over hydrofoil. Journal of Drainage and Irrigation Machinery Engin, 2017, 35(11): 933-940.

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