Print Email Facebook Twitter Process-based modelling of turbidity-current hydrodynamics and sedimentation Title Process-based modelling of turbidity-current hydrodynamics and sedimentation Author Groenenberg, R.M. Contributor Kroonenberg, S.B. (promotor) Luthi, S.M. (promotor) Faculty Civil Engineering and Geosciences Date 2007-03-05 Abstract The production potential of deep-water reservoirs is primarily determined by rock bulk volume, porosity and permeability. Quantification of the geometry and spatial distribution of reservoir sands in deep-water deposits can provide crucial information to assess sand body volume, connectivity and the distribution of permeability baffles. This study aims to investigate the influence of turbidity-current process, sediment composition and basin-floor relief, on the geometry and spatial distribution of reservoir sands in turbidite fans. For this purpose, a process-based model has been developed which simulates turbidity-current flow, erosion, and deposition based on principles of fluid dynamics that can deal with arbitrary basin-floor topography and accommodates various grain sizes. It employs the depth-averaged shallow-water approximation in combination with the Boussinesq approximation for density-driven flow in three dimensions. Sediment transport is modelled by an advection-diffusion type equation, and exchange with the bed is largely based on existing empirical models for sediment entrainment and deposition. The model is solved numerically on a rectangular grid representing topography by means of a second-order finite-difference approximation, and employs a shock-capturing technique to accurately model the discontinuous flow front characteristic of density-driven flows. Results are presented of laboratory-scale model validation tests, in which modelling results are quantitatively and qualitatively compared to experimental data. Laboratory experiments involve small-scale flows interacting with complex topographic features as well as multiple successive flows over the same erodible bed. Results indicate that the model is capable of simulating turbidity-current hydrodynamics and sedimentation with an acceptable degree of accuracy under a wide range of conditions. Subject deep-water reservoirsturbidity currentsdepositsnumerical modellingfinite-differenceschock-capturinglaboratory experimentsvalidation To reference this document use: http://resolver.tudelft.nl/uuid:d8b275cd-2797-4214-922d-6febafa9a87b ISBN 978-90-8570-155-2 Part of collection Institutional Repository Document type doctoral thesis Rights (c) 2007 R.M. Groenenberg Files PDF ceg_groenenberg_20070305.pdf 65.8 MB Close viewer /islandora/object/uuid:d8b275cd-2797-4214-922d-6febafa9a87b/datastream/OBJ/view