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Modified porosity approach and laminar flamelet modelling for advanced simulation of accidental explosions
The production of oil and gas is an inherently hazardous task. Therefore it is crucial to provide reliable estimates of the risks involved. The major contributors to the risk level of an offshore installation, for example, arise from accidents involving explosion and fire. Computational Fluid Dynamics (CFD) can be a powerful tool to help with the calculation of accidental explosion scenarios. In this context, the present work suggests a novel implementation of a model based on a modified Porosity Distributed Resistance (MPDR) approach within an unstructured 3D Navier-Stokes solver. The model operates by representing parts of the filtered geometry from the original model through porosity values attributed to an unstructured tetrahedral mesh. Extra resistance terms are added in the momentum equation as well as extra sources of turbulence. Two extra sources of turbulence are modelled. The first of these is due to the shear layers of the non-resolved obstacles, whilst the second is due to the presence of wakes behind the non-resolved obstacles. Results for 2D and 3D test cases are compared against both experimental data and simulations with fully-resolved geometry and good agreement is observed.
Modified porosity approach and laminar flamelet modelling for advanced simulation of accidental explosions
The production of oil and gas is an inherently hazardous task. Therefore it is crucial to provide reliable estimates of the risks involved. The major contributors to the risk level of an offshore installation, for example, arise from accidents involving explosion and fire. Computational Fluid Dynamics (CFD) can be a powerful tool to help with the calculation of accidental explosion scenarios. In this context, the present work suggests a novel implementation of a model based on a modified Porosity Distributed Resistance (MPDR) approach within an unstructured 3D Navier-Stokes solver. The model operates by representing parts of the filtered geometry from the original model through porosity values attributed to an unstructured tetrahedral mesh. Extra resistance terms are added in the momentum equation as well as extra sources of turbulence. Two extra sources of turbulence are modelled. The first of these is due to the shear layers of the non-resolved obstacles, whilst the second is due to the presence of wakes behind the non-resolved obstacles. Results for 2D and 3D test cases are compared against both experimental data and simulations with fully-resolved geometry and good agreement is observed.
Modified porosity approach and laminar flamelet modelling for advanced simulation of accidental explosions
Modifizierter Ansatz zum Porositätsmodell der laminaren Verbrennung für eine bessere Simulation von Explosionsunfällen
Vianna, Savio S.V. (Autor:in) / Cant, R. Stewart (Autor:in)
2010
12 Seiten, 20 Bilder, 22 Quellen
Aufsatz (Zeitschrift)
Englisch
Barriere , Explosionsgefahr , explosiver Bereich , Gittergeometrie , Gitternetz , Impulsgleichung , laminare Verbrennung , Navier-Stokes-Gleichung , numerische Strömungssimulation , Off-Shore-Anlage , Ordnungsparameter , Software für numerische Strömungssimulation , statistische Verteilung , Turbulenzmodell
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Studies on accidental gas and dust explosions
| British Library Online Contents | 2017
Studies on accidental gas and dust explosions
| British Library Online Contents | 2017