Abstract
To study the effects of different guide vane numbers on the unsteady performance of pump as turbine based on the Navier–Stokes equation and standard k-epsilon turbulence model, computation fluid dynamics technology was used to simulate the flow field in pump as turbine. The turbulent kinetic energy, unsteady radial forces, and power losses were also clarified. The results show that for turbines with a guide vane, the distribution of turbulent kinetic energy is more uniform than before, and the radial force vector distribution is more symmetrical within four quadrants. The time-domain distribution of radial force is more periodic, the number of fluctuation periods is equal to the guide vane numbers, and the dominant frequency of the radial force is equal to the blade frequency. For different guide vane numbers, the effects on the unsteady performance of pump as turbine are different. When the guide vane number is equal to 9, the distribution of turbulence kinetic energy is optimal. In addition, at an optimal flow rate, both the time domains of the radial force and the power losses of the impeller are minimal, so to the geometric parameters of the hydraulic turbine are definite, the optimal guide vane number exists.
Highlights
A centrifugal pump running in inverse mode can be applied to residual pressure energy recovery in industries
Keywords Pump as turbine, guide vane numbers, turbulent kinetic energy, radial force, power losses
An unsteady three-dimensional (3D) simulation based on Reynolds time-averaged governing equations and the standard k À e turbulence model was presented, and the effects of different guide vane numbers on the distribution of turbulence kinetic energy, unsteady radial force, and unsteady power losses are obtained
Summary
A centrifugal pump running in inverse mode (pump as turbine) can be applied to residual pressure energy recovery in industries. Keywords Pump as turbine, guide vane numbers, turbulent kinetic energy, radial force, power losses
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