How Temperature Measurement Impacts Pressure Drop and Heat Transport in Slender Fixed Beds of Raschig Rings

Kutscherauer, Martin; Reinold, Philipp; Böcklein, Sebastian; Mestl, Gerhard; Turek, Thomas; Wehinger, Gregor D.

doi:10.1021/acsengineeringau.2c00039

“…The packed beds are typically generated synthetically employing the discrete element method (Jurtz, Waldherr, and Kraume (2019)) or the rigid body approach (Flaischlen and Wehinger (2019)). Most of the PRCFD studies available in literature neglect chemical reaction to investigate the impact of the particle shape (Dixon, Nijemeisland, and Stitt (2005)), the Dt /dp ratio (Flaischlen, Kutscherauer, and Wehinger (2021)) or inserts, such as heat fins (Jurtz, Flaischlen, Scherf, Kraume, and Wehinger (2020)) and thermowells (Kutscherauer et al (2023)) on pressure drop and heat transport. However, the strong interplay between the transport phenomena and the catalytic chemistry requires to implement reaction in the PRCFD simulations in order to analyse the fixed bed reactor to a sufficiently high degree of detail.…”

Section: Introductionmentioning

confidence: 99%

A conjugated heat and mass transfer model to implement reaction in particle-resolved CFD simulations of catalytic fixed bed reactors

Kutscherauer,

Anderson,

Böcklein

et al. 2023

Preprint

0

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Modeling catalytic fixed bed reactors with a small tube-to-particle diameter ratio requires a detailed description of the interactions between fluid flow, intra-particle transport, and the chemical reaction(s) within the catalyst. Particle-resolved computational fluid dynamics (PRCFD) simulations are the most promising approach to accurately predict the behavior of these reactors, since they take explicitly into account the local packed bed structure. In this work, a conjugated heat and mass transfer model for use in PRCFD simulations is presented to couple the fluid flow through the fixed bed with transport and reaction in the porous catalyst, while guaranteeing the no-slip boundary condition at the fluid-solid interface. For this purpose, the solutions of the solid and fluid domain are computed separately and are coupled by calculation and updating the boundary condition at the particle surface. Due to the consideration of secondary gradients, the developed transfer model is also valid for unstructured calculation meshes containing non-orthogonal cells at the fluid-solid interface. Such meshes are often used to resolve complex geometries, such as a packed bed, in a computationally efficient manner. The coupling approach is validated using cases for which an analytical solution or literature correlations derived from experimental data are available. The simulation results of a short catalytic packed bed with rings catalyzing the partial oxidation of n-butane to maleic anhydride exemplify the potential of PRCFD involving reactions to analyze the catalyst performance in great detail.

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“…The packed beds are typically generated synthetically employing the discrete element method (Jurtz, Waldherr, and Kraume (2019)) or the rigid body approach (Flaischlen and Wehinger (2019)). Most of the PRCFD studies available in literature neglect chemical reaction to investigate the impact of the particle shape (Dixon, Nijemeisland, and Stitt (2005)), the Dt /dp ratio (Flaischlen, Kutscherauer, and Wehinger (2021)) or inserts, such as heat fins (Jurtz, Flaischlen, Scherf, Kraume, and Wehinger (2020)) and thermowells (Kutscherauer et al (2023)) on pressure drop and heat transport. However, the strong interplay between the transport phenomena and the catalytic chemistry requires to implement reaction in the PRCFD simulations in order to analyse the fixed bed reactor to a sufficiently high degree of detail.…”

Section: Introductionmentioning

confidence: 99%

A conjugated heat and mass transfer model to implement reaction in particle-resolved CFD simulations of catalytic fixed bed reactors

Kutscherauer

¹

,

Anderson

²

,

Böcklein

³

et al. 2023

Preprint

0

View full text Add to dashboard Cite

Modeling catalytic fixed bed reactors with a small tube-to-particle diameter ratio requires a detailed description of the interactions between fluid flow, intra-particle transport, and the chemical reaction(s) within the catalyst. Particle-resolved computational fluid dynamics (PRCFD) simulations are the most promising approach to accurately predict the behavior of these reactors, since they take explicitly into account the local packed bed structure. In this work, a conjugated heat and mass transfer model for use in PRCFD simulations is presented to couple the fluid flow through the fixed bed with transport and reaction in the porous catalyst, while guaranteeing the no-slip boundary condition at the fluid-solid interface. For this purpose, the solutions of the solid and fluid domain are computed separately and are coupled by calculation and updating the boundary condition at the particle surface. Due to the consideration of secondary gradients, the developed transfer model is also valid for unstructured calculation meshes containing non-orthogonal cells at the fluid-solid interface. Such meshes are often used to resolve complex geometries, such as a packed bed, in a computationally efficient manner. The coupling approach is validated using cases for which an analytical solution or literature correlations derived from experimental data are available. The simulation results of a short catalytic packed bed with rings catalyzing the partial oxidation of n-butane to maleic anhydride exemplify the potential of PRCFD involving reactions to analyze the catalyst performance in great detail.

show abstract

Experimental analysis of the orientation distribution of cylindrical particles with different aspect ratios in random packed beds

Marek,

Niegodajew

2023

Advanced Powder Technology

1

0

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How Temperature Measurement Impacts Pressure Drop and Heat Transport in Slender Fixed Beds of Raschig Rings

Cited by 7 publications

References 47 publications

A conjugated heat and mass transfer model to implement reaction in particle-resolved CFD simulations of catalytic fixed bed reactors

A conjugated heat and mass transfer model to implement reaction in particle-resolved CFD simulations of catalytic fixed bed reactors

A conjugated heat and mass transfer model to implement reaction in particle-resolved CFD simulations of catalytic fixed bed reactors

Experimental analysis of the orientation distribution of cylindrical particles with different aspect ratios in random packed beds

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