Effect of rheology and solids concentration on hydrocyclones performance: A study involving the design variables of an optimized hydrocyclone

Despite several advances in the field of separations in hydrocyclones, achieving high separation efficiency in these devices when operating with concentrated non-Newtonian suspensions is still a challenge, and any improvement in this aspect can be a significant contribution. Thus, the objective of t...

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Bibliographic Details
Published in:Journal of petroleum science & engineering 2022-03, Vol.210, p.110019, Article 110019
Main Authors: Gonçalves, Suélen Mara, Ullmann, Grégori, Morimoto, Murilo Guimarães, de Souza Barrozo, Marcos Antonio, Vieira, Luiz Gustavo Martins
Format: Article
Language:English
Subjects:
Dense slurry
Design variables
Geometric optimization
High efficiency
Pseudoplastic fluid
Shear-thinning
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Summary:Despite several advances in the field of separations in hydrocyclones, achieving high separation efficiency in these devices when operating with concentrated non-Newtonian suspensions is still a challenge, and any improvement in this aspect can be a significant contribution. Thus, the objective of this study was to evaluate the behavior of a hydrocyclone operating with concentrated pseudoplastic suspensions. The device used in this study was the Maximum Overall Efficiency Hydrocyclone (MOEH), which is the result of a geometric optimization study developed by our research group whose objective was to obtain a hydrocyclone geometry that led to high separation efficiencies. The polymer carboxymethyl cellulose (CMC) was used as a rheological modulator at different concentrations. Changing the concentration of CMC in the suspension from 0.2 wt% to 1.0 wt%, it was observed reductions of 27% and 23% for the Euler number and overall efficiency of the MOEH hydrocyclone, respectively. When operating with dilute pseudoplastic suspensions (CCMC < 0.6 wt%), the drop in the separation performance could be mitigated with appropriate increments in the dimensions of the underflow diameter and reductions in the vortex finder length. Above a concentration of 0.8 wt% CMC the hydrocyclone operated as a stream splitter, with reduced efficiency of less than 2%, and the modifications in the design variables were not sufficient to reverse the detrimental effect of the increased slurry viscosity. The results obtained in this study show the relevant effect of non-Newtonian fluids in the functioning of hydrocyclones and the importance of the correct choice of geometric configurations and operating conditions to reduce the impact of the rheology in the separation performance. [Display omitted] •Maximum Overall Efficiency Hydrocyclone was subjected to pseudoplastic suspensions.•Severe attenuation of the centrifugal field was caused by the viscosity increase.•The harmful effects of high CMC content were attenuated by longer vortex finders.•Separation intensification and energy saving by increasing the underflow diameter.•MOEH has practically become a flow splitter at high CMC concentrations (>0.8 wt%).
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2021.110019