Improving the hydraulic performance of a high-speed submersible axial flow pump based on CFD technology

International Journal of Fluid Engineering Pub Date : 2024-02-29 DOI:10.1063/5.0191683

Lu Rong, Martin Böhle, Yandong Gu

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Abstract

The hydraulic performance of a high-speed submersible axial flow pump is investigated to reduce its energy consumption. A more efficient and stable optimization method that combines parametric design, computational fluid dynamics, and a computer algorithm is proposed. The main aim is to broaden the high-efficiency operating zone, so the average efficiency under multiple conditions is optimized while considering rotor–stator matching. The design-of-experiments method and a radial-basis-function neural network are combined to form the optimization platform, and automatic optimization of the pump design is realized through repeated execution of design and simulation. The flow loss mechanism inside the pump is studied in depth via the entropy generation rate, and regression analysis shows that the pump efficiency is influenced mainly by the blade angles. After optimization, the target efficiency is increased by 8.34%, and the flow field distribution shows that the channel vortex and hydraulic loss are controlled effectively. Finally, the results are validated by experiment. The proposed optimization approach has advantages in saving manpower and obtaining globally optimal solutions.

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基于 CFD 技术提高高速潜水轴流泵的水力性能

研究了高速潜水轴流泵的水力性能，以降低其能耗。提出了一种结合参数化设计、计算流体动力学和计算机算法的更高效、更稳定的优化方法。其主要目的是扩大高效运行区域，从而在考虑转子-定子匹配的同时优化多种条件下的平均效率。实验设计法与径向基函数神经网络相结合构成了优化平台，通过反复执行设计和仿真，实现了泵设计的自动优化。通过熵产生率深入研究了泵内部的流动损失机理，回归分析表明泵效率主要受叶片角度的影响。优化后，目标效率提高了 8.34%，流场分布显示通道涡流和水力损失得到了有效控制。最后，实验对结果进行了验证。所提出的优化方法具有节省人力和获得全局最优解的优势。

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International Journal of Fluid Engineering

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