Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller

This study addressed the numerical modelling of flow and diffusion in packed beds of mono-sized spheres. Comprehensive research was conducted in order to implement various numerical approaches in explicit1 and implicit2 simulations of flow through packed beds of uniform spheres. It was noted from li...

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Main Author: Preller, Abraham Christoffel Naudé
Language:en
Published: North-West University 2013
Subjects:
TMD
Online Access:http://hdl.handle.net/10394/8499
id ndltd-netd.ac.za-oai-union.ndltd.org-nwu-oai-dspace.nwu.ac.za-10394-8499
record_format oai_dc
collection NDLTD
language en
sources NDLTD
topic Numerical modelling
Packed beds
Spheres
Explicit
Implicit
Contact treatment
Turbulence model
Enhanced diffusion
Mesh independency
Tortuosity
TMD
BETS
Effective thermal conductivity
spellingShingle Numerical modelling
Packed beds
Spheres
Explicit
Implicit
Contact treatment
Turbulence model
Enhanced diffusion
Mesh independency
Tortuosity
TMD
BETS
Effective thermal conductivity
Preller, Abraham Christoffel Naudé
Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
description This study addressed the numerical modelling of flow and diffusion in packed beds of mono-sized spheres. Comprehensive research was conducted in order to implement various numerical approaches in explicit1 and implicit2 simulations of flow through packed beds of uniform spheres. It was noted from literature that the characterization of a packed bed using porosity as the only geometrical parameter is inadequate (Van Antwerpen, 2009) and is still under much deliberation due to the lack of understanding of different flow phenomena through packed beds. Explicit simulations are not only able to give insight into this lack of understanding in fluid mechanics, but can also be used to develop different flow correlations that can be implemented in implicit type simulations. The investigation into the modelling approach using STAR-CCM+®, presented a sound modelling methodology, capable of producing accurate numerical results. A new contact treatment was developed in this study that is able to model all the aspects of the contact geometry without compromising the computational resources. This study also showed, for the first time, that the LES (large eddy simulation) turbulence model was the only model capable of accurately predicting the pressure drop for low Reynolds numbers in the transition regime. The adopted modelling approach was partly validated in an extensive mesh independency test that showed an excellent agreement between the simulation and the KTA (1981) and Eisfeld and Schnitzlein (2001) correlations' predicted pressure drop values, deviating by between 0.54% and 3.45% respectively. This study also showed that explicit simulations are able to accurately model enhanced diffusion due to turbulent mixing, through packed beds. In the tortuosity study it was found that the tortuosity calculations were independent of the Reynolds number, and that the newly developed tortuosity tests were in good agreement with techniques used by Kim en Chen (2006), deviating by between 2.65% and 0.64%. The results from the TMD (thermal mixing degree) tests showed that there appears to be no explicit link between the porosity and mixing abilities of the packed beds tested, but this could be attributed to relatively small bed sizes used and the positioning and size of the warm inlet. A multi-velocity test showed that the TMD criterion is also independent of the Reynolds number. It was concluded that the results from the TMD tests indicated that more elaborate packed beds were needed to derive applicable conclusions from these type of mixing tests. The explicit BETS (braiding effect test section) simulation results confirmed the seemingly irregular temperature trends that were observed in the experimental data, deviating by between 5.44% and 2.29%. From the detail computational fluid dynamics (CFD) results it was possible to attribute these irregularities to the positioning of the thermocouples in high temperature gradient areas. The validation results obtained in the effective thermal conductivity study were in good agreement with the results of Kgame (2011) when the same fitting techniques were used, deviating by 5.1%. The results also showed that this fitting technique is highly sensitive for values of the square of the Pearson product moment correlation coefficient (RSQ) parameter and that the exclusion of the symmetry planes improved the RSQ results. It was concluded that the introduction of the new combined coefficient (CC) parameter is more suited for this type of fitting technique than using only the RSQ parameter. === Thesis (M.Ing. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2012
author Preller, Abraham Christoffel Naudé
author_facet Preller, Abraham Christoffel Naudé
author_sort Preller, Abraham Christoffel Naudé
title Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
title_short Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
title_full Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
title_fullStr Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
title_full_unstemmed Numerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé Preller
title_sort numerical modelling of flow through packed beds of uniform spheres / abraham christoffel naudé preller
publisher North-West University
publishDate 2013
url http://hdl.handle.net/10394/8499
work_keys_str_mv AT prellerabrahamchristoffelnaude numericalmodellingofflowthroughpackedbedsofuniformspheresabrahamchristoffelnaudepreller
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-nwu-oai-dspace.nwu.ac.za-10394-84992014-04-16T03:53:13ZNumerical modelling of flow through packed beds of uniform spheres / Abraham Christoffel Naudé PrellerPreller, Abraham Christoffel NaudéNumerical modellingPacked bedsSpheresExplicitImplicitContact treatmentTurbulence modelEnhanced diffusionMesh independencyTortuosityTMDBETSEffective thermal conductivityThis study addressed the numerical modelling of flow and diffusion in packed beds of mono-sized spheres. Comprehensive research was conducted in order to implement various numerical approaches in explicit1 and implicit2 simulations of flow through packed beds of uniform spheres. It was noted from literature that the characterization of a packed bed using porosity as the only geometrical parameter is inadequate (Van Antwerpen, 2009) and is still under much deliberation due to the lack of understanding of different flow phenomena through packed beds. Explicit simulations are not only able to give insight into this lack of understanding in fluid mechanics, but can also be used to develop different flow correlations that can be implemented in implicit type simulations. The investigation into the modelling approach using STAR-CCM+®, presented a sound modelling methodology, capable of producing accurate numerical results. A new contact treatment was developed in this study that is able to model all the aspects of the contact geometry without compromising the computational resources. This study also showed, for the first time, that the LES (large eddy simulation) turbulence model was the only model capable of accurately predicting the pressure drop for low Reynolds numbers in the transition regime. The adopted modelling approach was partly validated in an extensive mesh independency test that showed an excellent agreement between the simulation and the KTA (1981) and Eisfeld and Schnitzlein (2001) correlations' predicted pressure drop values, deviating by between 0.54% and 3.45% respectively. This study also showed that explicit simulations are able to accurately model enhanced diffusion due to turbulent mixing, through packed beds. In the tortuosity study it was found that the tortuosity calculations were independent of the Reynolds number, and that the newly developed tortuosity tests were in good agreement with techniques used by Kim en Chen (2006), deviating by between 2.65% and 0.64%. The results from the TMD (thermal mixing degree) tests showed that there appears to be no explicit link between the porosity and mixing abilities of the packed beds tested, but this could be attributed to relatively small bed sizes used and the positioning and size of the warm inlet. A multi-velocity test showed that the TMD criterion is also independent of the Reynolds number. It was concluded that the results from the TMD tests indicated that more elaborate packed beds were needed to derive applicable conclusions from these type of mixing tests. The explicit BETS (braiding effect test section) simulation results confirmed the seemingly irregular temperature trends that were observed in the experimental data, deviating by between 5.44% and 2.29%. From the detail computational fluid dynamics (CFD) results it was possible to attribute these irregularities to the positioning of the thermocouples in high temperature gradient areas. The validation results obtained in the effective thermal conductivity study were in good agreement with the results of Kgame (2011) when the same fitting techniques were used, deviating by 5.1%. The results also showed that this fitting technique is highly sensitive for values of the square of the Pearson product moment correlation coefficient (RSQ) parameter and that the exclusion of the symmetry planes improved the RSQ results. It was concluded that the introduction of the new combined coefficient (CC) parameter is more suited for this type of fitting technique than using only the RSQ parameter.Thesis (M.Ing. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2012North-West University2013-05-07T14:04:07Z2013-05-07T14:04:07Z2011Thesishttp://hdl.handle.net/10394/8499en