Zhi-Jun Shuai scite author profile

Further optimal design of an axial-flow water pump calls for a thorough recognition of the characteristics of the complex turbulent flow field in the pump, which is however extremely difficult to be measured using the up-to-date experimental techniques. In this study, a numerical simulation procedure based on computational fluid dynamics (CFD) was elaborated in order to obtain the fully three-dimensional unsteady turbulent flow field in an axial-flow water pump. The shear stress transport (SST) k-ω model was employed in the CFD calculation to study the unsteady internal flow of the axial-flow pump. Upon the numerical simulation results, the characteristics of the velocity field and pressure field inside the impeller region were discussed in detail. The established model procedure in this study may provide guidance to the numerical simulations of turbomachines during the design phase or the investigation of flow and pressure field characteristics and performance. The presented information can be of reference value in further optimal design of the axial-flow pump.

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Vibration analysis of three-screw pumps under pressure loads and rotor contact forces

Zhang

et al. 2016

Journal of Sound and Vibration

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Development of a Semi-Active Electromagnetic Vibration Absorber and Its Experimental Study

Liu¹,

Feng²,

Shi³

et al. 2013

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In this work, a semiactive electromagnetic vibration absorber has been developed based on a proposed electromagnetic stiffness adjustable spring model, which presents a new solution for adjusting stiffness in the field of vibration absorber devices. Simulation study on the electromagnetic spring has been performed to determine the structural parameter of the semiactive vibration absorber. An experimental rig is also built up to investigate its practical vibration control effectiveness. Firstly, the finite element model of the test bench is used to analyze its vibration characteristics. Then, the vibration reduction effect is predicted through the simulation analysis, from which the optimal control positions are found. Finally, the experimental studies are also conducted, and the results show that this semiactive electromagnetic vibration absorber has a frequency adjustment range from 21 Hz to 25 Hz, in which considerable vibration reduction from 5 dB to 10 dB can be achieved.

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Zhi-Jun Shuai

Modal properties of a two-stage planetary gear system with sliding friction and elastic continuum ring gear

An indirect torsional vibration receptance measurement method for shaft structures

CFD Numerical Simulation of the Complex Turbulent Flow Field in an Axial-Flow Water Pump

Vibration analysis of three-screw pumps under pressure loads and rotor contact forces

Development of a Semi-Active Electromagnetic Vibration Absorber and Its Experimental Study

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