Volume‐of‐fluid‐based model for multiphase flow in high‐pressure trickle‐bed reactor: Optimization of numerical parameters

Lopes, Rodrigo J.G.; Quinta‐Ferreira, Rosa M.

doi:10.1002/aic.11862

Cited by 24 publications

(29 citation statements)

References 36 publications

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“…An introductory parametric optimization was also accomplished querying the effect of different differencing schemes on the momentum and volume fraction balance equations. High-order differencing schemes based on Compressive Interface Capturing Scheme for Arbitrary Meshes (CICSAM) and High Resolution Interface Capturing (HRIC) schemes were found to agree better with the experimental data from the literature given that its formulation includes inherently the minimization of artificial numerical dissipation as described elsewhere (Lopes & Quinta-Ferreira, 2009). We begin with a base case querying the influence of numerical solution parameters including different mesh apertures.…”

Section: Mesh and Time Sensitivity Testssupporting

confidence: 50%

“…This task is sought to be accomplished by the experimental work devoted to investigate the suitability of this methodology as well as by state-of-the-art simulation tools considered by CFD codes. The case study encompasses the application of a trickle-bed reactor to the detoxification of phenolic wastewaters through a series of experimental runs accompanied and validated by a multiphase Volume-of-Fluid (VOF) model formerly reported (Lopes & Quinta-Ferreira, 2009). At a first glance, a brief prospect of literature on trickle-bed reactor modelling and validation is presented at reaction conditions.…”

Section: Literature Reviewmentioning

confidence: 99%

See 1 more Smart Citation

Computational Flow Modelling of Multiphase Reacting Flow in Trickle-bed Reactors with Applications to the Catalytic Abatement of Liquid Pollutants

Lopes¹,

Quinta‐Ferreira²

2011

Computational Fluid Dynamics Technologies and Applications

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Section: Mesh and Time Sensitivity Testssupporting

confidence: 50%

Section: Literature Reviewmentioning

confidence: 99%

Computational Flow Modelling of Multiphase Reacting Flow in Trickle-bed Reactors with Applications to the Catalytic Abatement of Liquid Pollutants

Lopes¹,

Quinta‐Ferreira²

2011

Computational Fluid Dynamics Technologies and Applications

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“…In the present work, we have used the polynomial form of the criterion presented by Attou and Ferschneider 10 coupled with the model originally investigated by Lopes and Quinta-Ferreira. 17 Continuity and momentum Eqs. 1 and 2 are functionally equivalent to the set of equations used by Grosser et al, 6 which were implemented in C language in the CFD framework for the trickle-to-pulse transition.…”

Section: Vof Equationsmentioning

confidence: 99%

“…17 It consists of a cylindrical vessel with 5-cm internal diameter and 1-m bed height packed with catalyst spherical particles 2-mm diameter. The catalytic bed is meshed in tetrahedral cells by means of the FLUENT preprocessor GAMBIT 2.…”

Section: Species Continuity and Energy Equationsmentioning

confidence: 99%

Numerical simulation of reactive pulsing flow for the catalytic wet oxidation in TBR using a VOF technique

2011

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Guided by the intrinsic advantages of the dynamic nature of mass/heat transfer fluctuations in pulsing flow, here we performed volume-of-fluid (VOF) numerical simulations to evaluate how liquid flow modulations can improve the detoxification of liquid effluents by catalytic wet oxidation. First, prominent numerical parameters were optimized in terms of mesh aperture and time step. Second, the effect of oxidation temperature and the influence of gas and liquid flow rates have been investigated comparatively under different flow regimes. The VOF computations have correctly handled the experimental observations both in terms of the axial conversion and temperature. The increase of oxidation temperature was found to move the trickling and pulsing intersection point on the conversion toward the top of the trickle bed. Finally, in comparison with trickling flow regimes, these computed and experimental findings revealed a considerable improvement on the detoxification of organic matter highlighting the benefits of process intensification covered by the periodic liquid flow modulations.

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“…Notwithstanding these values make these meshes inappropriate for using an standard wall 24 function, except for the cases at low Reynolds, FLUENT solver allows the range for wall The multiphase reactor in our trickle bed pilot plant comprises a cylindrical geometry with the 3 following dimensions 50 mm of internal diameter and 1.0 m length and the experimental 4 procedure has been described elsewhere (Lopes & Quinta-Ferreira, 2010 A c c e p t e d M a n u s c r i p t 16 schemes were found to agree better with the experimental data from the literature given that 1 its formulation includes inherently the minimization of artificial numerical dissipation as 2 described elsewhere (Lopes & Quinta-Ferreira, 2009 In order to properly capture the boundary layer now on the temperature profile and regarding 5 also the mesh sensitivity analysis, several computational runs were additionally performed 6 changing the mesh density on the catalyst particle surface. The effect of mesh aperture on the 7 thermal behavior of the trickle-bed reactor is portrayed in Fig.…”

mentioning

confidence: 99%

Numerical assessment of diffusion–convection–reaction model for the catalytic abatement of phenolic wastewaters in packed-bed reactors under trickling flow conditions

Lopes

Quinta‐Ferreira

2011

Computers & Chemical Engineering

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Computational Fluid Dynamics (CFD) modeling of trickle-bed reactors with detailed interstitial flow solvers has remained elusive mostly due to the extreme CPU and memory intensive constraints. Here, we developed a comprehensible and scalable CFD model based on the conservative unstructured finite volume methodology to bring new insights from the perspective of catalytic reactor engineering to gas-liquid-solid catalytic wet oxidation. First, the heterogeneous flow constitutive equations of the trickle bed system have been derived by means of diffusion-convection-reaction model coupled within a Volume-of-Fluid framework.The multiphase model was investigated to gain further evidence on how the effect of process variables such as liquid velocity, surface tension and wetting phenomena affect the overall performance of high-pressure trickle-bed reactor. Second, as long as the application of underrelaxation parameters, mesh density, and time stepping strategy play a major role on the final corroboration, several computational runs on the detoxification of liquid pollutants were validated accordingly and evaluated in terms of convergence and stability criteria. Finally, the analysis of spatial mappings for the reaction properties enables us to identify the existence of relevant dry zones and unveil the channeling phenomena within in the trickle-bed reactor.

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Volume‐of‐fluid‐based model for multiphase flow in high‐pressure trickle‐bed reactor: Optimization of numerical parameters

Cited by 24 publications

References 36 publications

Computational Flow Modelling of Multiphase Reacting Flow in Trickle-bed Reactors with Applications to the Catalytic Abatement of Liquid Pollutants

Computational Flow Modelling of Multiphase Reacting Flow in Trickle-bed Reactors with Applications to the Catalytic Abatement of Liquid Pollutants

Numerical simulation of reactive pulsing flow for the catalytic wet oxidation in TBR using a VOF technique

Numerical assessment of diffusion–convection–reaction model for the catalytic abatement of phenolic wastewaters in packed-bed reactors under trickling flow conditions

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