Performance of Helical Ribbon and Screw Impellers for Mixing Viscous Fluids in Cylindrical Reactors

Performance of Helical Ribbon and Screw Impellers for Mixing Viscous Fluids in Cylindrical Reactors

The present paper deals with the mixing of a highly viscous fluid by close-clearance impellers in cylindrical vessels. The study is performed via numerical simulations. Calculations are achieved by the discretization of continuity and momentum equations with the finite volume method. The effect of b...

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Veröffentlicht in:ChemEngineering 2018-06, Vol.2 (2), p.26
Hauptverfasser: Ameur, Houari, Kamla, Youcef, Sahel, Djamel
Format: Artikel
Sprache:eng
Schlagworte:
Chemical engineering
close-clearance impeller
Computational fluid dynamics
Computer simulation
cylindrical tank
Efficiency
Finite volume method
Fluid dynamics
Fluid flow
Fluid mechanics
Geometry
Granular materials
helical-screw impeller
Impellers
Investigations
mixing
Power consumption
Product design
Reynolds number
Simulation
Viscous fluids
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Beschreibung
Zusammenfassung:The present paper deals with the mixing of a highly viscous fluid by close-clearance impellers in cylindrical vessels. The study is performed via numerical simulations. Calculations are achieved by the discretization of continuity and momentum equations with the finite volume method. The effect of blade diameter and its shape on the well-stirred region size and the power consumption is investigated. For highly viscous fluids, the obtained results suggest the use of impellers rotating at low Reynolds number, and having a blade with the same shape of the tank to ensure mixing near the vessel base. A comparison is made between the performance of a simple helical ribbon (HR), a simple small screw (SS), helical ribbon-small screw (HR-SS) and a large screw (LS) impeller. The predicted results allow the following classification of impellers studied, based on less power requirements and small size of well-agitated region: SS < HR < HR-SS < LS.
ISSN:2305-7084
2305-7084
DOI:10.3390/chemengineering2020026