Computational Fluid Dynamics for Fixed Bed Reactor Design

Dixon, Anthony G.; Partopour, Behnam

doi:10.1146/annurev-chembioeng-092319-075328

Cited by 124 publications

(59 citation statements)

References 142 publications

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“…Da mithilfe von PRCFD Festbettreaktoren detailliert modelliert werden können, stellt sich die Frage, welcher Detailgrad die Kinetik aufweisen soll. Formalkinetiken, Langmuir-Hinshelwood-als auch mikrokinetische Ansätze wurden in der Literatur mit PRCFD angewendet und diskutiert, s. dazu [14]. Unsere bisherigen Studien haben gezeigt, dass es möglich ist, Mikrokinetiken in PRCFD von Festbettreaktoren einzuführen [2].…”

Section: Festbettreaktorenunclassified

Young Scientists – Juniorprofessor Gregor D. Wehinger stellt sich vor

Wehinger

2021

Chemie Ingenieur Technik

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In diesem Beitrag stellt sich Juniorprofessor Gregor D. Wehinger vom Institut für Chemische und Elektrochemische Verfahrenstechnik der TU Clausthal vor. Neben aktuellen Forschungsarbeiten und Lehraktivitäten gibt er auch einen Ü berblick darüber, wie er sich in der Community engagiert. Fachlich berichtet er von aktuellen Ergebnissen im Bereich der CFD-Modellierung von Festbettreaktoren, Redox-Flow-Batterien und Mehrphasensystemen. Zudem wird der Einsatz von virtueller Realität in einem aktuellen Lehrprojekt vorgestellt.

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Section: Festbettreaktorenunclassified

Young Scientists – Juniorprofessor Gregor D. Wehinger stellt sich vor

Wehinger

2021

Chemie Ingenieur Technik

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“…Heat transfer and chemical reactions in these processes introduce a substantial complexity due to the presence of inhomogeneous flow structures 1 . A deep understanding of the complex flow, transport, and reaction behavior is of great importance for optimal design and scale‐up of processing devices 2–4 . To this end, numerous empirical correlations have been proposed to describe interphase heat, mass, and momentum transport for fluid–solid flows.…”

Section: Introductionmentioning

confidence: 99%

“…However, the empirical correlations cannot provide the specific spatial distribution information of key transfer parameters 1 . Over the last decades, computational fluid dynamics (CFD) has gained much attention and is increasingly used as a tool for studying the details of the local flow, transport, and reactions 4 . Particularly, the information from highly resolved direct numerical simulation (DNS) of fluid‐particle systems can be used for developing microscopic interphase exchange closures used in the unresolved models, such as the two‐fluid model (TFM) and CFD–discrete element method (CFD–DEM).…”

Section: Introductionmentioning

confidence: 99%

Conventional anddata‐drivenmodeling of filtered drag, heat transfer, and reaction rate ingas–particleflows

Zhu

Ouyang

et al. 2021

AIChE Journal

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This study presents conventional and artificial neural network‐based data‐driven modeling (DDM) methods to model simultaneously the filtered mesoscale drag, heat transfer and reaction rate in gas–particle flows. The dataset used for developing the DDM is filtered from highly resolved simulations closed by our recently formulated microscopic drag and heat transfer coefficients (HTCs). Results reveal that the filtered drag correction is nearly independent of filter size when including the filtered gas phase pressure gradient. We further find that the filtered HTC correction critically depends on the added filtered temperature difference marker while the filtered reaction rate correction shows weak dependence on the additional markers. Moreover, compared with conventional correlations, DDM predictions agree better with filtered resolved data. Comparative analysis is also conducted between existing HTC corrections and our work. Finally, the applicability of conventional and data‐driven models coupled with coarse‐grid computational fluid dynamics simulations for pilot‐scale (reactive) gas–particle flows is validated comprehensively.

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“…• Particle-resolved computational fluid dynamics (CFD), where each pellet and the fluid, including the interstices between the particles are fully spatially resolved, and Navier-Stokes equations are solved. A detailed description of this modeling approach is presented in the comprehensive review articles by Dixon [6], Jurtz et al [7] and Dixon and Partopour [8].…”

Section: Introductionmentioning

confidence: 99%

Influence of Macroscopic Wall Structures on the Fluid Flow and Heat Transfer in Fixed Bed Reactors with Small Tube to Particle Diameter Ratio

2021

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Fixed bed reactors are widely used in the chemical, nuclear and process industry. Due to the solid particle arrangement and its resulting non-homogeneous radial void fraction distribution, the heat transfer of this reactor type is inhibited, especially for fixed bed reactors with a small tube to particle diameter ratio. This work shows that, based on three-dimensional particle-resolved discrete element method (DEM) computational fluid dynamics (CFD) simulations, it is possible to reduce the maldistribution of mono-dispersed spherical particles near the reactor wall by the use of macroscopic wall structures. As a result, the lateral convection is significantly increased leading to a better radial heat transfer.This is investigated for different macroscopic wall structures, different air flow rates (Reynolds number Re = 16 ...16,000) and a variation of tube to particle diameter ratios (2.8, 4.8, 6.8, 8.8). An increase of the radial velocity of up to 40%, a reduction of the thermal entry length of 66% and an overall heat transfer increase of up to 120% are found.

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Computational Fluid Dynamics for Fixed Bed Reactor Design

Cited by 124 publications

References 142 publications

Young Scientists – Juniorprofessor Gregor D. Wehinger stellt sich vor

Young Scientists – Juniorprofessor Gregor D. Wehinger stellt sich vor

Conventional anddata‐drivenmodeling of filtered drag, heat transfer, and reaction rate ingas–particleflows

Influence of Macroscopic Wall Structures on the Fluid Flow and Heat Transfer in Fixed Bed Reactors with Small Tube to Particle Diameter Ratio

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