Radial forces of waterjet propulsion mixed-flow pump

Q3 Engineering

排灌机械工程学报 Pub Date : 2012-11-01 DOI:10.3969/J.ISSN.1674-8530.2012.06.004

Li Cheng, B. Esch, Chao Liu, Jiren Zhou, Yan Jin

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引用次数: 1

Abstract

Fluctuations of fluid pressure in hydraulic machinery can cause resonance and fatigue da-mage of blades. In order to study fluid-induced forces, which are caused by impeller-diffuser interaction, unsteady radial forces due such an effect was conducted in a mixed-flow pump with a vaned diffuser by using CFD computation and model experiment. A closed-loop test rig was built for the pump and a co-rotating dynamometer was installed between the impeller and the pump shaft to measure the instantaneous forces and moments on the impeller. The dynamic behavior of the experimental rotor-shaft system was determined by carrying out extensive calibrations. The measured forces at the blade passing frequency showed an unexpected dependency on flow rate. Another important observation was that the blade excitation forces cause the impeller to whirl in the direction opposite to shaft rotation. The computed global characteristics and the magnitude of blade interaction forces showed good agreement with measurements, respectively. The measured results were compared with the unsteady ones estimated by using CFD code-Fluent. Over a large range of flow rates, the trend of force variation agrees well with the measurements. The reasons for deviation of prediction from experiment were explained.

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水射流推进混流泵径向力

液压机械中流体压力的波动会引起叶片的共振和疲劳损伤。为了研究叶轮-扩压器相互作用引起的流体诱导力，采用CFD计算和模型实验的方法，对带叶片扩压器的混流泵进行了非定常径向力研究。建立了泵的闭环试验台，在叶轮和泵轴之间安装了共转测功仪，测量叶轮上的瞬时力和力矩。通过大量的标定，确定了实验转子-轴系统的动态特性。在叶片通过频率处测得的力与流量有意想不到的关系。另一个重要的观察结果是叶片的激励力使叶轮向与轴旋转相反的方向旋转。计算得到的叶片相互作用力的整体特性和大小与实测结果吻合较好。实测结果与CFD软件fluent计算的非定常结果进行了比较。在较大的流量范围内，力的变化趋势与测量结果吻合较好。分析了预测结果与实验结果偏差的原因。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

排灌机械工程学报 Engineering-Mechanical Engineering

CiteScore

1.90

自引率

0.00%

发文量

5192

期刊介绍：