Study on multi-component particle behaviour in a hydrocyclone classifier using experimental and computational fluid dynamics techniques

•Hydrocyclone performance is evaluated using heterogeneous feed mixture.•Increasing the heavier component in the mixture results into increased Rs and D50.•An interaction coefficient is proposed to quantify the components cut-size change.•The modified ASM model predicts the component grade curves cl...

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Bibliographic Details
Published in:Separation and purification technology 2019-12, Vol.229, p.115698, Article 115698
Main Authors: Padhi, Mandakini, Mangadoddy, Narasimha, Sreenivas, T., Vakamalla, Teja Reddy, Mainza, A.N.
Format: Article
Language:English
Subjects:
CFD
Hydrocyclone
Mixture model
Multi-component
Segregation
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Summary:•Hydrocyclone performance is evaluated using heterogeneous feed mixture.•Increasing the heavier component in the mixture results into increased Rs and D50.•An interaction coefficient is proposed to quantify the components cut-size change.•The modified ASM model predicts the component grade curves close to the experiments.•With increased magnetite fraction, the silica LZVV shift towards the forced vortex. Feed to the hydrocyclone classifier in mineral comminution circuit is comprised of a mixture of different size and density particles having various degrees of liberation can be termed as multi-component particulate system. In this study, an artificial mixture of silica and magnetite with different proportions is used for multi-component classification experiments in a 75 mm hydrocyclone. The effect of magnetite fraction on the separation efficiency of silica is analyzed experimentally. An interaction is observed between the components during the classification leading to an increased component cut-size and reduced component mass recoveries in the mixture compared to when it is classified individually. Numerical simulations are also carried out using the modified mixture multiphase model with additional shear lift, hindered settling drag law and slurry viscosity by solids and fines content. The comparison of simulated and experimental performance data is found to be in close agreement. At similar particle sizes, the heavier density component influences the lighter component by placing it away from the wall region and thereby a shift in the locus of zero vertical velocity towards the forced vortex. This results a significant increment in the lighter particle cut-size. Separation characteristics of the silica and magnetite particles are analyzed fundamentally using the equilibrium radius concept.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2019.115698