Energy Performance and Flow Patterns of a Mixed-Flow Pump with Different Tip Clearance Sizes

Liu, Yabin; Tan, Lei; Hao, Yong Ping; Xu, Ye

doi:10.3390/en10020191

Cited by 104 publications

(52 citation statements)

References 28 publications

(23 reference statements)

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“…The boundary conditions are set as: the total pressure at pump inlet, the mass flow rate at the pump outlet, and no slip wall at the walls. The methods of frozen-rotor and transient-rotor-stator are applied to couple the rotational and stationary domains for steady and unsteady calculations, respectively [22][23][24]. The relative position between the stable suction pipe and the volute and the rotational impeller remains unchanged in the frozen-rotor method, while it varies according to the angular velocity of the impeller in the transient-rotor-stator method.…”

Section: Methodsmentioning

confidence: 99%

Influence of Prewhirl Angle and Axial Distance on Energy Performance and Pressure Fluctuation for a Centrifugal Pump with Inlet Guide Vanes

et al. 2017

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Abstract:The energy performance and pressure fluctuations in a centrifugal pump with inlet guide vanes (IGVs) are investigated experimentally and numerically in a prewhirl angle range of −24 • to 24 • and in an axial distance range of 280 mm, 380 mm, and 460 mm. The reliability and accuracy of the numerical method are validated by the satisfactory agreement between the experimental data and numerical results. Prewhirl regulation with IGVs can significantly increase the energy performance and broaden the efficient operation range for the centrifugal pump due to the improvement of flow pattern at the impeller inlet. The prewhirl angle has an obvious impact on pump energy performance, and the maximum amplitudes of pressure fluctuations on the blade leading edge of the pressure and suction sides decrease by 69% and 89%, respectively. The axial distance has a slight impact on pump energy performance, but the maximum amplitudes of pressure fluctuations drop by 35.4% on the blade leading edge of pressure side when the axial distance extends from 280 mm to 460 mm.

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Section: Methodsmentioning

confidence: 99%

Influence of Prewhirl Angle and Axial Distance on Energy Performance and Pressure Fluctuation for a Centrifugal Pump with Inlet Guide Vanes

et al. 2017

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“…Leakage flow through tip clearance interacts with the main flow and results in complex vortex structures and an unstable flow pattern in the tip-clearance region [7], such as cavitation [8] and pressure fluctuation [5,9]. Figure 2 illustrates the tip-leakage vortex (TLV) cavitation of an axial pump at cavitation number (σ) 0.481.…”

Section: -03 MMmentioning

confidence: 99%

“…Machinery Type Performance Change 0-1 mm Mixed-flow pump [5,6] Head drops by 10% at design flow rate; efficiency drops by 4% at design flow rate; pressure fluctuation near blade-trailing edge increases by 20 times; unsymmetrical tip clearance deteriorates cavitation performance and increases radial-force fluctuation.…”

Section: Tip-clearance Rangementioning

confidence: 99%

“…As shown in Table 1, tip clearance can induce tip-leakage flow and further influence the energy performance and operation stability of pump and turbine. The head and efficiency can be significantly influenced by the variation of tip clearance [5,6]. Therefore, the appropriate design of tip clearance is necessary to optimize the performance of pumps and turbines.…”

Section: Introductionmentioning

confidence: 99%

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A Review of Tip Clearance in Propeller, Pump and Turbine

2018

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Propellers, pumps, and turbines are widely applied in marine equipment, water systems, and hydropower stations. With the increasing demand for energy conservation and environmental protection, the high efficiency and the stable operation of pumps and turbine have been drawing great attention in recent decades. However, the tip clearance between the rotating impeller and the stationary shroud can induce leakage flow and interact with the main stream, introducing complex vortex structures. Consequently, the energy performance and the operation stability of pumps and turbines deteriorate considerably. Constant efforts are exerted to investigate the flow mechanism of tip-clearance flow and its induced influence on performance. However, due to various pump and turbine types and the complexity of tip-clearance flow, previous works are usually focused on a specific issue. Therefore, a systematic review that synthesizes the related research is necessary and meaningful. This review investigates related research in the recent two decades in the perspectives from fundamental physics to engineering applications. Results reveal the vortex types, trajectory, evolution, and cavitation behaviors induced by tip-clearance flow. It is concluded that the influence characteristics of tip clearance on energy performance are closely related to the machinery type. Tip-clearance size and tip shape are found to be crucial parameters for tip-leakage vortex (TLV). The proposed optimization schemes are also demonstrated to provide inspiration for future research. Overall, this review article provides a coherent insight into the characteristics of tip-clearance flow and the associated engineering-design applications. On the basis of these understandings, comments on conducted research and ideas on future research are proposed.

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“…The mechanism of tip clearance flow in impeller machinery has been studied deeply and systemically. [5][6][7][8][9] RL Miorini et al 10 and Wu et al [11][12][13] measured the flow field structure and the turbulent kinetic energy distribution of the leakage vortex in the tip clearance of water-jet propulsion through particle image velocimetry (PIV). The internal flow field and external characteristics of the axial-flow pump impeller with different tip clearances were studied by Zhang et al, 14,15 by means of CFD numerical simulation, PIV, and other test methods.…”

Section: Introductionmentioning

confidence: 99%

Influence of tip clearance on the performance of a screw axial-flow pump

Lin

Liu

Zhao

et al. 2017

Advances in Mechanical Engineering

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Screw axial-flow pumps, with three different tip clearance values (R TC = 1, 2, and 3 mm), were respectively investigated to analyze the influence of key parameters on external characteristics and cavitation performance. The simulation results were in good agreement with the experimental values. The results showed that the external characteristics and cavitation performance of the screw axial-flow pump decreased as tip clearance increased. The R TC was not sensitive to the efficiency of large flow condition, and the decrease in head and efficiency of the pump in large flow conditions was smaller than that for small flow conditions. With the increase in R TC , the vorticity distribution in the impeller gradually spreads from the hub to the tip of the blade inlet. In the incipient cavitation stage, the cavitation was mainly located at the inlet of the blade suction-side near the hub. When the cavitation number reduces to the fracture cavitation state, the cavitation area further increased, almost filled the entire blade suction-side, and the pump performance rapidly went down. The simulation results of the pump were slightly higher than the prototype test values. It can be seen that the computational fluid dynamics numerical simulation can be used to optimize the design of screw axial-flow pump.

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Energy Performance and Flow Patterns of a Mixed-Flow Pump with Different Tip Clearance Sizes

Cited by 104 publications

References 28 publications

Influence of Prewhirl Angle and Axial Distance on Energy Performance and Pressure Fluctuation for a Centrifugal Pump with Inlet Guide Vanes

Influence of Prewhirl Angle and Axial Distance on Energy Performance and Pressure Fluctuation for a Centrifugal Pump with Inlet Guide Vanes

A Review of Tip Clearance in Propeller, Pump and Turbine

Influence of tip clearance on the performance of a screw axial-flow pump

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