Continuum modeling of slightly wet fluidization with electrical capacitance tomograph validation
Continuum modeling of slightly wet fluidization with electrical capacitance tomograph validation
Gas–solid fluidized bed reactors are widely used in the power generation industry. The critical effect of the presence of liquid phase, either as a result of heat, chemical reaction or physical interaction, on the hydrodynamics of the reactor is well recognized by academic researchers and industrial operators. However, theory and simulation frameworks to predict such a condition using the continuum modeling approach are not yet available. This study first shows the significant changes in the flow pattern and distinguishable flow regimes in a slightly wet fluidized bed recorded by an advanced imaging technique. The study then describes the development and implementation of new mathematical formulations for wet particle-particle interactions in a continuum model based on the classic kinetic theory of granular flow (KTGF). Quantitative validation, carried out by comparing the predicted and measured fluidization index (FI) expressed in terms of pressure drop, has shown a good match. The prediction also demonstrates increased bubble splitting, gas channeling, slugging fluidization, and energy dissipation induced by liquid bridges developing from wet particle interactions. These characteristics are similar to those commonly observed in the fluidization of cohesive powders. This model constitutes an important step in extending the continuum theories of dry flow to wet particle-particle interactions. This will allow accurate description and simulation of the fluidized bed in its widest application including power generation systems that involve wet particle fluidization
numerical simulation, wet particulate, fluidized bed reactor, granular flows
Makkawi, Yassir
217bdad4-a83f-44a9-ab54-b52633298456
Yu, Xi
7e4f553f-cc11-4c6e-ad6d-9fb5c3c07a60
Ocone, Raffaella
89db17bd-1848-4c75-ac00-40b9c077b1a8
Generalis, Sotos
4489b9f3-1072-495f-b713-4f6d8c54a46f
30 May 2024
Makkawi, Yassir
217bdad4-a83f-44a9-ab54-b52633298456
Yu, Xi
7e4f553f-cc11-4c6e-ad6d-9fb5c3c07a60
Ocone, Raffaella
89db17bd-1848-4c75-ac00-40b9c077b1a8
Generalis, Sotos
4489b9f3-1072-495f-b713-4f6d8c54a46f
Makkawi, Yassir, Yu, Xi, Ocone, Raffaella and Generalis, Sotos
(2024)
Continuum modeling of slightly wet fluidization with electrical capacitance tomograph validation.
Energies, 17 (11), [2656].
(doi:10.3390/en17112656).
Abstract
Gas–solid fluidized bed reactors are widely used in the power generation industry. The critical effect of the presence of liquid phase, either as a result of heat, chemical reaction or physical interaction, on the hydrodynamics of the reactor is well recognized by academic researchers and industrial operators. However, theory and simulation frameworks to predict such a condition using the continuum modeling approach are not yet available. This study first shows the significant changes in the flow pattern and distinguishable flow regimes in a slightly wet fluidized bed recorded by an advanced imaging technique. The study then describes the development and implementation of new mathematical formulations for wet particle-particle interactions in a continuum model based on the classic kinetic theory of granular flow (KTGF). Quantitative validation, carried out by comparing the predicted and measured fluidization index (FI) expressed in terms of pressure drop, has shown a good match. The prediction also demonstrates increased bubble splitting, gas channeling, slugging fluidization, and energy dissipation induced by liquid bridges developing from wet particle interactions. These characteristics are similar to those commonly observed in the fluidization of cohesive powders. This model constitutes an important step in extending the continuum theories of dry flow to wet particle-particle interactions. This will allow accurate description and simulation of the fluidized bed in its widest application including power generation systems that involve wet particle fluidization
Text
energies-17-02656
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More information
Accepted/In Press date: 2 May 2024
Published date: 30 May 2024
Keywords:
numerical simulation, wet particulate, fluidized bed reactor, granular flows
Identifiers
Local EPrints ID: 493414
URI: http://eprints.soton.ac.uk/id/eprint/493414
ISSN: 1996-1073
PURE UUID: 60fc28ff-ffe8-4f01-a315-a7432662bc52
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Date deposited: 02 Sep 2024 18:10
Last modified: 03 Sep 2024 02:12
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Contributors
Author:
Yassir Makkawi
Author:
Xi Yu
Author:
Raffaella Ocone
Author:
Sotos Generalis
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