Good modelling practice in applying computational fluid dynamics for WWTP modelling

Wicklein, Edward; Batstone, Damien J.; Ducoste, Joel J.; Laurent, Julien; Griborio, Alonso; Wicks, Jeffrey D.; Saunders, Stephen; Samstag, Randal W.; Potier, Olivier; Nopens, Ingmar

doi:10.2166/wst.2015.565

Cited by 68 publications

(16 citation statements)

References 34 publications

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“…However, oversimplification of the CFD model and a lack of calibration will lead to errors in the simulation results and validation data. Moreover, despite the vast opportunities for the use of CFD modeling in wastewater engineering, a lack of educational support, training and targeted guidelines has been recognized as a core reason for frequent software misuse by inexperienced users (Wicklein et al, 2016), usually originating from incorrect problem statement, poor model choice, incorrect setup assumptions or misinterpretation of the results (Nopens et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Towards a robust CFD model for aeration tanks for sewage treatment – a lab-scale study

Karpinska

Bridgeman

2017

Engineering Applications of Computational Fluid Mechanics

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Detailed insight into the hydrodynamics of aeration tanks is of crucial importance for improvements in treatment efficiency, optimization of the process design and energy-efficient operation. These factors have triggered increasing interest in the use of Computational Fluid Dynamics (CFD) to evaluate performance of wastewater treatment systems. Whilst factors such as incorrect input assumptions, poor model choice and excessive simplifications have been recognized as potential sources of output errors, there remains a need to identify the most robust strategy to faithfully simulate aeration tank performance. Therefore, the focus of this work was to undertake rigorous transient simulations of the hydrodynamics and oxygen mass transfer in a lab-scale aeration tank in order to work towards the development of robust modeling guidelines for activated sludge systems. Unlike most previous CFD analyses of aeration systems, the work reported here employed the shear stress transport (SST) k − ω turbulence model to account for the turbulent interactions between the phases inducing bubble breakup and/or coalescence, and as a consequence, promoting the formation of bubbles of different sizes and shapes. The results obtained were compared with those arising from an analysis using the standard k − ε (sk − ε) model -and assuming fixed bubble diameter-the most common CFD modeling framework used within the wastewater modeling community. Model validation was achieved using acoustic Doppler velocimetry and particle image velocimetry techniques, and experimentally derived oxygen mass transfer data. Limitations of both turbulence models used and modeling assumptions concerning bubbly flow are discussed. The benefits of the SST k − ω turbulence model are demonstrated, but the need to balance the increased computational expense of this approach compared to the sk − ε model and, indeed, bubble flow modeling are recognized. Thus, this paper presents the first rigorous analysis of turbulence model and bubble flow generation models together for activated sludge system optimization.

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Section: Introductionmentioning

confidence: 99%

Towards a robust CFD model for aeration tanks for sewage treatment – a lab-scale study

Karpinska

Bridgeman

2017

Engineering Applications of Computational Fluid Mechanics

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“…It is recognized as one of the WWTP processes that would most benefit from a deeper understanding of its mixing process at large volumes . The lack of hydrodynamic experiments combined with little validation studies using CFD models for AD mechanical mixers might explain the large uncertainties associated with these models . As for anaerobic digestion, even fewer work has been made to obtain local hydrodynamic data for mechanical mixers.…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamic analysis of an axial impeller in a non‐Newtonian fluid through particle image velocimetry

2020

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The rheology of non-Newtonian fluids in agitated vessels is complex making equipment sizing more an art than a science. To increase our understanding and to resolve the data gap for computational fluid dynamics validation, we present a detailed particle image velocimetry study of the hydrodynamics of Carbopol encountered in a 70 L mechanically mixed (A310) tank at three different rotational speeds (100, 250, 500 rpm). Bulk flow visualizations show that the flow field below the impeller is highly influenced by the rheological behavior of the fluid. Moreover, an analysis of the shear rate and viscosity revealed important spatial heterogeneities. An estimation of the Reynolds number classified the rotational speeds as the onset of the transitional regime (100), in the transitional regime (250) and turbulent conditions (500 rpm). This data set consists of local mean and fluctuating velocities at different locations below the impeller, which are available for validation and further study. K E Y W O R D SCarbopol, mechanical mixing, particle image velocimetry, proper orthogonal decomposition, shear rate

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“…Specifically, CFD models have been used to provide spatially resolved predictions of pathogen inactivation, disinfectant residual, and DBP formation (Angeloudis, Stoesser, & Falconer, ; Greene, Farouk, & Haas, ; Greene, Haas, & Farouk, ); three‐dimensional (3D) laser‐induced fluorescence was used to directly observe mixing in bench‐scale ozone contactors (Kim, Elovitz, Roberts, & Kim, ; Kim, Nemlioglu, Roberts, & Kim, ) and ultraviolet reactors (Gandhi, Roberts, & Kim, ; Gandhi, Roberts, Stoesser, Wright, & Kim, ); and a reactive tracer (i.e., ammonia) was used to observe mixing in a wastewater nitrification reactor equipped with axial mixers (Gresch, Braun, & Gujer, ). However, CFD modeling remains too computationally intensive for everyday reactor design and operation (Laurent et al, ), particularly for unsteady flows (Wicklein et al, ); 3D laser‐induced fluorescence is not applicable to full‐scale reactors (Kim, Nemlioglu, et al, ); and most drinking water treatment reactors (e.g., ozone contactors, clearwells) are unlike the nitrification reactor studied in some important ways (e.g., reactors are often baffled to encourage plug flow rather than actively mixed, and target contaminants do not lend themselves to real‐time measurement).…”

Section: Introductionmentioning

confidence: 99%

Assessing flow segregation and mixing by modeling residual disinfectant conversion

2019

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Microbial inactivation and chemical conversion in water treatment reactors depend on the degree of flow segregation and earliness of mixing (i.e., micromixing).However, little is known about micromixing in full-scale water treatment reactors. This study used the seasonal conversion of residual disinfectant between chloramines and free chlorine as reactive tracers to evaluate micromixing in full-scale baffled and unbaffled clearwells. Effluent tracer concentrations were modeled using segregated flow (SF), maximum mixedness (MM), tanks-in-series (TIS), and reactor network (RN) models. Breakpoint reactions were most accurately predicted by the TIS model for both clearwells. The MM model was only accurate in the unbaffled clearwell under steady flow conditions. Segregated flows with different residence times (e.g., SF, some RNs) poorly represented observations. Micromixing was significant in the full-scale reactors studied, and the TIS model most accurately represented observed micromixing. When modeling multiple reactions or nonfirst-order reactions, reactor models should incorporate micromixing.

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Good modelling practice in applying computational fluid dynamics for WWTP modelling

Cited by 68 publications

References 34 publications

Towards a robust CFD model for aeration tanks for sewage treatment – a lab-scale study

Towards a robust CFD model for aeration tanks for sewage treatment – a lab-scale study

Hydrodynamic analysis of an axial impeller in a non‐Newtonian fluid through particle image velocimetry

Assessing flow segregation and mixing by modeling residual disinfectant conversion

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