Study on the Effect of Cone Angle Values on the Pressure and Velocity Field of Hydrocyclones

The established static hydrocyclone structure model was analyzed briefly. By using Reynolds stress turbulent model which was based on the anisotropy in CFD software, the PC-SIMPLEC algorithm was applied to simulate the bi-conical hydrocyclone flow field with a comprehensive in-depth three-dimensiona...

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Hauptverfasser:	Jiang Minghu, Liu Daoyou, Zhao Lixin, Jia Guichun
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Sprache:	eng
Schlagworte:	Cyclones Energy consumption Energy loss Fluids Numerical simulation Presses Structural engineering
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creator	Jiang Minghu Liu Daoyou Zhao Lixin Jia Guichun
description	The established static hydrocyclone structure model was analyzed briefly. By using Reynolds stress turbulent model which was based on the anisotropy in CFD software, the PC-SIMPLEC algorithm was applied to simulate the bi-conical hydrocyclone flow field with a comprehensive in-depth three-dimensional numerical simulation. Pressure distribution and velocity distribution in flow field are obtained. Combined with fluid mechanics and the theory of hydrodynamics, in order to test and verify the accuracy of simulation results. Research finding demonstrates that the hydrocyclone internal differential pressure decreases with increasing large cone angle during a certain range. As a result, increasing large cone angle moderately, it can reduce hydrocyclone internal pressure drop and energy consumption. The tangential velocity increases when the large and small cone angle increases. While cutting down the small cone angle correctly, it makes the prospective forced vortex radius r m reduce and improve separating efficiency.
doi_str_mv	10.1109/icbbe.2011.5781125
format	Conference Proceeding
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By using Reynolds stress turbulent model which was based on the anisotropy in CFD software, the PC-SIMPLEC algorithm was applied to simulate the bi-conical hydrocyclone flow field with a comprehensive in-depth three-dimensional numerical simulation. Pressure distribution and velocity distribution in flow field are obtained. Combined with fluid mechanics and the theory of hydrodynamics, in order to test and verify the accuracy of simulation results. Research finding demonstrates that the hydrocyclone internal differential pressure decreases with increasing large cone angle during a certain range. As a result, increasing large cone angle moderately, it can reduce hydrocyclone internal pressure drop and energy consumption. The tangential velocity increases when the large and small cone angle increases. 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By using Reynolds stress turbulent model which was based on the anisotropy in CFD software, the PC-SIMPLEC algorithm was applied to simulate the bi-conical hydrocyclone flow field with a comprehensive in-depth three-dimensional numerical simulation. Pressure distribution and velocity distribution in flow field are obtained. Combined with fluid mechanics and the theory of hydrodynamics, in order to test and verify the accuracy of simulation results. Research finding demonstrates that the hydrocyclone internal differential pressure decreases with increasing large cone angle during a certain range. As a result, increasing large cone angle moderately, it can reduce hydrocyclone internal pressure drop and energy consumption. The tangential velocity increases when the large and small cone angle increases. 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subjects	Cyclones Energy consumption Energy loss Fluids Numerical simulation Presses Structural engineering
title	Study on the Effect of Cone Angle Values on the Pressure and Velocity Field of Hydrocyclones
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