Dynamic simulation of pilot thickener operation using phenomenological model with results validation for continuous and discontinuous tests

Rahimi Mehdi; Unesi Majid; Rezai Bahram; Abdollahzadeh Ali

doi:10.1007/s11771-017-3524-7

Journal of Central South University ›› 2017, Vol. 24 ›› Issue (5) : 1207 -1216. DOI: 10.1007/s11771-017-3524-7

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Dynamic simulation of pilot thickener operation using phenomenological model with results validation for continuous and discontinuous tests

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Abstract

The phenomenological theory of sedimentation-thickening processes predicts the settling behavior of a flocculated suspension in dependence of two functions, the batch flux density function and the effective solid stress. These functions were determined using batch settling tests. The governing equations for sedimentation were then solved numerically for these functions and the predictions were compared to the experimental results from pilot scale thickener tests. Firstly, the continuous tests were performed in the plexiglass pilot thickener at different feed flow rates and discharge rates and the solid volume fraction of discharge, the bed height and the time were recorded for each condition. These tests were also simulated and it was observed that there is a good agreement between the results of continuous tests and the results of dynamic simulation. Secondly, the discontinuous tests were performed in the plexiglass pilot thickener at different feed flow rates with a discharge rate of zero. The bed formation rate was determined for each condition. These tests were also simulated and it was observed that there is a good agreement between the results of discontinuous tests and the results of simulation.

Keywords

dynamic simulation / dewatering / thickener behavior / pilot thickener / validation

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Rahimi Mehdi, Unesi Majid, Rezai Bahram, Abdollahzadeh Ali. Dynamic simulation of pilot thickener operation using phenomenological model with results validation for continuous and discontinuous tests. Journal of Central South University, 2017, 24(5): 1207-1216 DOI:10.1007/s11771-017-3524-7

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References

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[1]	BuscallR, MillsP, DA, StewartR F, SuttonD, WhiteL R, YatesG E. The rheology of strongly-flocculated suspensions [J]. Journal of Non-Newtonian Fluid Mechanics, 1987, 24(2): 183-202

[2]	VITASOVIC Z Z. Continuous settler operation: A dynamic model [M]// PATRY G G, CHAPMAN D. Dynamic Modelling and Expert Systems in Wastewater Engineering. USA: Lewis, Chelsea, MI, 1989.

[3]	VaccariD A, UchrinC G. Modeling and simulation of compressive gravity thickening of activated sludge [J]. Journal of Environmental Science and Health A, 1989, 24(6): 645-674

[4]	OtterpohlR, FreundM. Dynamic models for clarifiers of activated sludge plants with dry and wet weather flows [J]. Water Science and Technology, 1992, 26: 1391-1400

[5]	HartelL, PopelH J. A dynamic secondary clarifier model including processes of sludge thickening [J]. Water Science and Technology, 1992, 25: 267-284

[6]	HamiltonJ, JainR, AntoniouP, SvoronosS A, KoopmanB, LyberatosG. Modeling and pilot scale experimental verification for predenitrification process [J]. Journal of Environmental Engineering, 1992, 118(1): 38-55

[7]	OzinskyA E, EkamaG A, ReddyB DMathematical simulation of dynamic behaviour of secondary settling tanks [R], 1994, South Africa, Dept of Civil Engineering, University of Cape Town

[8]	WattsR W, SvoronosS A, KoopmanB. One-dimensional modeling of secondary clarifiers using a concentration and feed velocity-dependent dispersion coefficient [J]. Water Research, 1996, 30(29): 2112-2124

[9]	BurgerR, DiehlS, NopensI. A consistent modelling methodology for secondary settling tanks in wastewater treatment [J]. Water Research, 2001, 45: 2247-2260

[10]	BurgerR, ConchaF. Mathematical model and numerical simulation of the settling of flocculated suspensions [J]. International Journal of Multiphase Flow, 1998, 24: 1005-1023

[11]

BurgerR, BustosM C, ConchaF. Settling velocities of particulate systems: 9. Phenomenological theory of sedimentation processes: numerical simulation of the transient behavior of flocculated suspensions in an ideal batch or continuous thickener [J]. International Journal of Mineral Processing, 1999, 55(4): 267-282

[12]	GarridoP, BurgosR, ConchaF, BurgerR. Settling velocities of particulate systems: A simulator for batch and continuous sedimentation of flocculated suspensions [J]. International Journal of Mineral Processing, 2004, 73(2-4): 131-144

[13]	UsherS P, ScalesP J. Steady state thickener modeling from the compressive yield stress and hindered settling function [J]. Chemical Engineering Journal, 2005, 111: 253-261

[14]	GladmanB RThe effect of shear on dewatering of flocculated suspensions [D], 2005, Melbourne, Australia, Department of Chemical and Biomolecular Engineering, The University of Melbourne

[15]	UsherS P, SpeharR, ScalesP J. Theoretical analysis of aggregate densification: impact on thickener performance [J]. Chemical Engineering Journal, 2009, 151(1-3): 202-208

[16]	GladmanB R, RudmanM, ScalesP J. The effect of shear on gravity thickening: Pilot scale modeling [J]. Chemical Engineering Science, 2010, 65(14): 4293-4301

[17]	van DeventerB B G, UsherS P, KumarA, RudmanM, ScalesP J. Aggregate densification and batch settling [J]. Chemical Engineering Journal, 2011, 171(1): 141-151

[18]	EbrahimzadehM, GoharriziA S, ShahrivarA A, AbdollahiH. Modeling industrial thickener using computational fluid dynamics (CFD), A case study: Tailing thickener in the Sarcheshmeh copper mine [J]. International Journal of Mining Science and Technology, 2013, 23(6): 885-892

[19]	GalvezE D, CruzR, RoblesP A, CisternasL A. Optimization of dewatering systems for mineral processing [J]. Minerals Engineering, 2014, 63: 110-117

[20]	ZhouT M, LiM, LiQ L, LeiB, ChennQ Z, ZhouJ M. Numerical simulation of flow regions in red mud separation thickener’s feedwell by analysis of residence-time distribution [J]. Transactions of Nonferrous Metals Society of China, 2014, 24(4): 1117-1124

[21]	BetancourtF, BurgerR, DiehlS, MejiasC. Advanced methods of flux identification for clarifier–thickener simulation models [J]. Minerals Engineering, 2014, 63: 2-15

[22]	RahimiM, AbdollahzadehA, RezaiB. The effect of particle size, pH and flocculant dosage on the gel point, effective solid stress and thickener performance of coal washing plant [J]. International Journal of Coal Preparation and Utilization, 2015, 35: 125-142

[23]	RichardsonJ F, ZakiW N. The sedimentation of a suspension of uniform spheres under conditions of viscous flow [J]. Chemical Engineering Science, 1954, 3(2): 65-73

[24]	BuscallR, WhiteL R. The consolidation of concentrated suspensions part 1. The theory of sedimentation [J]. Journal of the Chemical Society, 1987, 83: 873-891