Blade Thickness Redesign to Improve Efficiency and Decrease Unsteady Pressure Pulsation of a Low Specific Speed Centrifugal Pump

Cheng-shuo Wu, Peng Wu, Dazhuan Wu
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Abstract

The existence of secondary flow in the impeller brings extra energy loss and aggravates the pressure pulsation which will worsen the hydraulic and dynamic performance of the pump. In this paper, based on the forces balance in the direction perpendicular to the streamline, an optimal design method for the blade thickness of a low specific speed centrifugal pump is proposed to suppress the secondary flow in the impeller. The origin impellers with 5 and 7 cylinder blades are redesigned and the hydraulic and dynamic performance of the model pump are investigated by numerical simulation and experimental. Results show that the blade modification proposed in this paper can effectively improve the efficiency of the model pump and reduce the internal pressure pulsations. The internal flow analysis shows that the performance improvement attributes to the suppression of secondary flow in the impeller. And the entropy generation rate is introduced to measure and locate the loss in the pump. Results show that on the one hand, the suppression of secondary flow can reduce the energy loss in the pump and improve the efficiency; on the other hand, it can repress the jet wake structure at impeller outlet and alleviate the intensity of pressure pulsations.
低比转速离心泵叶片厚度设计提高效率,减小非定常压力脉动
叶轮内二次流的存在带来了额外的能量损失,加剧了压力脉动,使泵的水力和动力性能恶化。本文基于垂直于流线方向的力平衡,提出了一种抑制叶轮二次流的低比转速离心泵叶片厚度优化设计方法。对5缸叶片和7缸叶片的原始叶轮进行了重新设计,并通过数值模拟和实验对模型泵的水力和动力性能进行了研究。结果表明,本文提出的叶片改造能有效地提高模型泵的效率,减小内压脉动。内部流动分析表明,性能的提高主要归功于抑制了叶轮内的二次流。并引入熵产率来测量和定位泵内的损耗。结果表明,抑制二次流一方面可以减少泵内能量损失,提高效率;另一方面,它可以抑制叶轮出口的射流尾迹结构,减轻压力脉动的强度。
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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