Abstract
Mixed-flow pumps compromise large flow rate and high head in fluid transferring. Long-axis mixed-flow pumps with radial–axial “spacing” guide vanes are usually installed deeply under water and suffer strong cavitation due to strong environmental pressure drops. In this case, a strategy combining the Diffusion-Angle Integral Design method, the Genetic Algorithm, and the Computational Fluid Dynamics method was used for optimizing the mixed-flow pump impeller. The Diffusion-Angle Integral Design method was used to parameterize the leading-edge geometry. The Genetic Algorithm was used to search for the optimal sample. The Computational Fluid Dynamics method was used for predicting the cavitation performance and head–efficiency performance of all the samples. The optimization designs quickly converged and got an optimal sample. This had an increased value for the minimum pressure coefficient, especially under off-design conditions. The sudden pressure drop around the leading-edge was weakened. The cavitation performance within the 0.5–1.2 Qd flow rate range, especially within the 0.62–0.78 Qd and 1.08–1.20 Qd ranges, was improved. The head and hydraulic efficiency was numerically checked without obvious change. This provided a good reference for optimizing the cavitation or other performances of bladed pumps.
Highlights
The head and hydraulic efficiency was numerically checked without obvious change
This provided a good reference for optimizing the cavitation or other performances of bladed pumps
Cavitation is a liquid–gas phase change phenomenon which happens in the liquid medium when pressure drops below the saturation pressure [1]
Summary
Cavitation is a liquid–gas phase change phenomenon which happens in the liquid medium when pressure drops below the saturation pressure [1]. Traveling cavitation vapour bubbles collapse immediately while going into high pressure sites [2]. The collapsing bubble may release shock waves and form re-entrant jets. These waves and jets cause noise, pressure pulsation, and vibration [3,4]. If cavitation happens near the surfaces of materials, the shock waves, re-entrant jets, and following rigid particles [5] cause material damage, like spotted erosion [6]. Cavitation in pumps occurs mainly in the leading-edge cavitation style because the impeller blade leading-edge is usually the lowest-pressure site [7]. The collapse of a bubble or cavity directly shocks the blade surface and induces cavitation erosion [10]
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