Computational Investigation of Liquid Holdup and Wetting Efficiency Inside Trickle Bed Reactors with Different Catalyst Particle Shapes

Deng, Hao; Guo, Baoqi; Dong, He; Liu, Cheng; Geng, Zhongfeng

doi:10.3390/app10041436

Cited by 9 publications

(7 citation statements)

References 26 publications

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“…The near-wall region, equivalent to 4 d p from the box wall in all directions, of the beds was trimmed to exclude the wall-influenced orientations of the cylindrical particles (see Figure b). In order to resolve the difficulties in the spatial discretization of the fluid domain, the particles were shrunk by 2% both in radial and axial directions to avoid sharp intersection angles formed in the region of particle–particle contacts (following the approch by Lopes and Quinta-ferreira, ,, Deng et al, and Qi et al). One such bed with h = 5 is shown in Figure b.…”

Section: Methodsmentioning

confidence: 99%

“…However, these studies consider oversimplified particle-resolved domains either in 2D (wherein the beds were represented by an array of circles) or in manually created 3D beds (wherein particles were arranged in a square or triangular pitch) with large interparticle distance. ,,,, Most of these 3D VOF simulations are performed with spherical particles due to challenges in the spatial discretization of complex void-topology of beds with shaped particles. Limited recent studies report the effect of particle shape on the aforementioned steady-state macroscopic parameters in small sections of realistic particle-resolved beds created using the discrete element method (DEM) and rigid body dynamic simulations (RBDS). ,, However, these studies do not report the particle-scale dynamics of liquid distribution as a function of particle shape which is crucial for improving the overall performance of packed beds. Further, these investigations were performed with a constant particle aspect ratio in the range of 1–2.67.…”

Section: Introductionmentioning

confidence: 99%

“…Limited recent studies report the effect of particle shape on the aforementioned steadystate macroscopic parameters in small sections of realistic particle-resolved beds created using the discrete element method (DEM) and rigid body dynamic simulations (RBDS). 16,18,19 However, these studies do not report the particle-scale dynamics of liquid distribution as a function of particle shape which is crucial for improving the overall performance of packed beds. Further, these investigations were performed with a constant particle aspect ratio in the range of 1−2.67.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Particle Aspect Ratio and Shape on the Particle-Scale Dynamics of Gas–Liquid Flow through Packed Beds

Ambekar

Singh

Kumari

et al. 2023

Ind. Eng. Chem. Res.

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Packed beds are widely used to perform solid-catalyzed gas–liquid reactions and gas cleanup processes. In the present work, we simulated gas–liquid flow through realistic 3D particle-resolved domains consisting of cylindrical particles of varying aspect ratio (h = 1–5) and different particle shapes (Raschig ring, trilobe, daisy, and sphere) using the volume-of-fluid method. With an increase in h, we found that the number fraction of laterally oriented particles decreases and length of elongated void-throats increases. Further, we found that liquid preferentially flows over surface of laterally oriented particles and through elongated void-throats. The combined effect of h, orientation distribution, and elongated void-throats results in improved hydrodynamic performance (liquid holdup, wetting efficiency, interfacial area, and liquid distribution) with an increase in h. We also found that the hydrodynamic performance of trilobe- and daisy-shaped particles is better than cylindrical particles in terms of interfacial area due to preferential flow of liquid through the grooves on externally shaped particles.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effect of Particle Aspect Ratio and Shape on the Particle-Scale Dynamics of Gas–Liquid Flow through Packed Beds

Ambekar

Singh

Kumari

et al. 2023

Ind. Eng. Chem. Res.

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“…Lopes & Quinta-Ferreira 2009, 2010, wettability (e.g. Du et al 2015Du et al , 2017 and particle shape (Kang et al 2019;Deng et al 2020) on the steady-state liquid distribution. However, the effect of the aforementioned parameters on the contribution of different forces at different temporal stages of liquid spreading and their relationship with void-scale flow behaviour has not been explored.…”

Section: Introductionmentioning

confidence: 99%

Forces governing the dynamics of liquid spreading in packed beds

2022

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Liquid spreading through a randomly packed particle-resolved bed influenced by capillary or inertial ( $AB_s \sim 1$ ), and gravitational force (moderately ( $AB_s \sim 0.1$ ) and strongly ( $AB_s \sim 0.01$ )) is investigated using the volume-of-fluid simulations. The relative contribution of governing forces at different stages of spreading is analysed using the time evolution of Weber ( $We_I$ ) and $AB_I$ numbers. We show that the dynamics of liquid spreading at $AB_s \sim 1$ is primarily governed by the inertial force in the beginning ( $AB_I > 1$ , $We_I > 1$ ) followed by the capillary force at $t/t^* \sim 1$ . This interplay of governing forces leads to inertia- and capillary-induced bubble entrapments at the void scale and promote lateral liquid spreading. When the $AB_s \sim 0.1$ , the $t/t^*$ for which the flow is governed by inertial ( $AB_I > 1$ , $We_I > 1$ ) and capillary forces ( $AB_I > 1$ , $We_I < 1$ ) decreases and the relative contribution of gravitational force is substantial at large $t/t^*$ ( $AB_I < 1$ ). This force balance leads to unified-void filling characterised by negligible bubble trapping and results in a decrease in the lateral spreading. Further decrease in the $AB_s$ to ${\sim } 0.01$ results in liquid spreading primarily governed by gravitational force ( $AB_I < 1$ ) with small contribution of inertial and capillary forces at the very beginning leading to trickling flow and a further decrease in lateral spreading. Finally, a regime map is proposed, which provides the relationship between different forces, void-scale events, and the resultant liquid spreading at $t/t^* \sim 1$ .

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“…To date, numerous studies have focused on modeling of trickle bed reactors. Applying computational fluid dynamics (CFD), particle-resolved models − and pseudocontinuous models − tackle the particle and reactor scale, respectively. Pseudocontinuous models are predominantly based on the Ergun equation and the Eulerian–Eulerian method.…”

Section: Introductionmentioning

confidence: 99%

Combined Two-Model CFD Simulation of Trickle Bed Reactors with Head-Sump Extension: Case Study on Hydrodynamics and Biological Methanation

Markthaler

Plankenbühler

Miederer

et al. 2022

Ind. Eng. Chem. Res.

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Trickle bed reactors are one of the world's most employed technologies for multiphase processing, and they have been scrutinized for decades. However, accurate prediction and scale-up of trickle bed reactors are still challenging owing to complex interactions of multiphase flow, interfacial mass transfer, and reaction kinetics. The present computational model provides an insight into process phenomena on the basis of Eulerian−Eulerian methodology. It captures all parts of a trickle bed reactorpacking, head, and sumpwhich enables simulation of co-and countercurrent flow, gas or liquid recycle, and arbitrary retention time. Applying this model, hydrodynamic simulations reveal an improved prediction of liquid holdup, liquid dispersion, and pressure drop compared to CFD models of only the trickle bed. Furthermore, the interfacial surface area is analyzed and validated on account of a literature correlation. Exemplifying the entire approach with chemical absorption and reaction, the simulation of biological methanation presents methane concentration and productivity which are of the same order of magnitude as experimental data for an operating pressure of p op = 0.1−1 MPa abs .

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Computational Investigation of Liquid Holdup and Wetting Efficiency Inside Trickle Bed Reactors with Different Catalyst Particle Shapes

Cited by 9 publications

References 26 publications

Effect of Particle Aspect Ratio and Shape on the Particle-Scale Dynamics of Gas–Liquid Flow through Packed Beds

Effect of Particle Aspect Ratio and Shape on the Particle-Scale Dynamics of Gas–Liquid Flow through Packed Beds

Forces governing the dynamics of liquid spreading in packed beds

Combined Two-Model CFD Simulation of Trickle Bed Reactors with Head-Sump Extension: Case Study on Hydrodynamics and Biological Methanation

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