基于mPOD和EEMD的射流泵障碍物控制叶片空化的能量贡献研究

IF 1.8 3区 工程技术 Q3 ENGINEERING, MECHANICAL
Guoshou Zhao, Ning Liang, Qianqian Li, Wei Dong, Linlin Cao, Dazhuan Wu
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引用次数: 0

摘要

研究表明,被动障碍物能有效抑制喷水泵前缘空化现象。结合实验和数值模拟,本文回顾了叶片空化的演变过程,以证明障碍物对空化非定常的稳定作用。采用多尺度POD (mPOD)和EEMD对空化载荷和推力的能量贡献进行了研究。mPOD模式表明,在空化完全抑制的情况下,障碍物叶片的前缘加载振荡被消除,障碍物空化尾迹对加载激励有很大的作用。推力统计表明,在一些转数中,推力极值和标准差可以很好地减小,因为前缘有大规模的空腔凹陷。EEMD获得的自适应谱进一步表明,叶片推力的音调分量和宽带分量都有一定程度的合理退化。作为一种改进策略,对单障碍物泵进行了对比研究,结果表明,与双障碍物相比,单障碍物配置由于升压效应对前缘空腔的抑制有积极的效果,可以减少不必要的能量损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Energy Contribution Study Of Blade Cavitation Control By Obstacles In A Waterjet Pump Based On mPOD And EEMD
Abstract It has been confirmed that the passive obstacles would substantially depress the leading-edge cavitation in a waterjet pump. Combined with the experiments and numerical simulations, this work revisits blade cavitation evolutions to demonstrate the stabilizing effects of obstacles on cavitation unsteadiness. The multiscale POD (mPOD) and EEMD are adopted to study the energy contributions regarding the cavitation-induced loading and thrust. The mPOD modes illuminate that the leading-edge loading oscillations of the obstacle blade are consequently eliminated where the cavitation is completely depressed and the obstacle cavitation wakes greatly contribute to loading excitation. The thrust statistics demonstrate that the thrust extremes and standard deviation in some revolutions can be well reduced as the large-scale leading-edge cavity depression. The adaptive spectrums obtained by EEMD further illuminate that both the tonal and broadband components of blade thrust would be reasonably degraded to some degree. The pump with only one obstacle implementation, as an improvement strategy, is comparatively studied and indicates that single obstacle configuration presents positive effects on the leading-edge cavity depression owing to the pressure-raising effects and can reduce the unnecessary energy loss compared with two obstacles.
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来源期刊
CiteScore
4.60
自引率
10.00%
发文量
165
审稿时长
5.0 months
期刊介绍: Multiphase flows; Pumps; Aerodynamics; Boundary layers; Bubbly flows; Cavitation; Compressible flows; Convective heat/mass transfer as it is affected by fluid flow; Duct and pipe flows; Free shear layers; Flows in biological systems; Fluid-structure interaction; Fluid transients and wave motion; Jets; Naval hydrodynamics; Sprays; Stability and transition; Turbulence wakes microfluidics and other fundamental/applied fluid mechanical phenomena and processes
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