Numerical calculation of backfilling of scour holes

BM Sumer, C Baykal, DR Fuhrman, NG Jacobsen… - 2014 - open.metu.edu.tr
2014open.metu.edu.tr
A fully-coupled hydrodynamic and morphologic CFD model is presented for simulating
backfilling processes around structures. The hydrodynamic model is based on Reynolds-
averaged Navier-Stokes equations, coupled with two-equation k-ω turbulence closure. The
sediment transport model consists of separate bed and suspended load descriptions, the
latter based on a turbulent diffusion equation coupled with a reference concentration
function near the sea bed boundary. Bed morphology is based on the sediment continuity …
A fully-coupled hydrodynamic and morphologic CFD model is presented for simulating backfilling processes around structures. The hydrodynamic model is based on Reynolds-averaged Navier-Stokes equations, coupled with two-equation k-ω turbulence closure. The sediment transport model consists of separate bed and suspended load descriptions, the latter based on a turbulent diffusion equation coupled with a reference concentration function near the sea bed boundary. Bed morphology is based on the sediment continuity (Exner) equation. The present simulations have utilized continuous morphologic updating in time, both the hydrodynamic and morphologic solutions being advanced with the same time increment. In this way, the simulations illustrate the ability to simulate fully-coupled hydrodynamic and morphologic developments based on continuous feedback. The model has been implemented for two kinds of structures: piles, and pipelines. Initial scour holes are generated by the same model. The numerical results appear to be in accord with the existing experimental information.
open.metu.edu.tr
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