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Numerical modeling of flow and scour below a pipeline in currents
Part I. Flow simulation
AbstractThe performance of the standard k–ε, Wilcox high-Reynolds-number k–ω, Wilcox low-Reynolds-number k–ω and Smagorinsky's subgrid scale (SGS) turbulence models is examined against the flow around a circular cylinder 0.37 diameter above a rigid wall. The governing equations are solved using finite difference method in a non-orthogonal boundary-fitted curvilinear coordinate system. A mesh dependence study for the four turbulence models is carried out on computational meshes with different densities. In addition, the performance of the k–ω models with either wall function or no-slip boundary condition on the cylinder surface is examined on the finest mesh. It is found that the SGS model over-predicts the shedding of vortices from the cylinder and is sensitive to the computational mesh and the model constant Cs used. The standard k–ε and the Wilcox k–ω models predict the mean velocity field quite well but generally under-predict the velocity and hydrodynamic force oscillations using wall functions on the cylinder surface. It is also found that the Wilcox k–ω models with the no-slip boundary condition on the cylinder surface give better predictions on the shedding of vortices than their counterparts using the wall function boundary condition.
Numerical modeling of flow and scour below a pipeline in currents
Part I. Flow simulation
AbstractThe performance of the standard k–ε, Wilcox high-Reynolds-number k–ω, Wilcox low-Reynolds-number k–ω and Smagorinsky's subgrid scale (SGS) turbulence models is examined against the flow around a circular cylinder 0.37 diameter above a rigid wall. The governing equations are solved using finite difference method in a non-orthogonal boundary-fitted curvilinear coordinate system. A mesh dependence study for the four turbulence models is carried out on computational meshes with different densities. In addition, the performance of the k–ω models with either wall function or no-slip boundary condition on the cylinder surface is examined on the finest mesh. It is found that the SGS model over-predicts the shedding of vortices from the cylinder and is sensitive to the computational mesh and the model constant Cs used. The standard k–ε and the Wilcox k–ω models predict the mean velocity field quite well but generally under-predict the velocity and hydrodynamic force oscillations using wall functions on the cylinder surface. It is also found that the Wilcox k–ω models with the no-slip boundary condition on the cylinder surface give better predictions on the shedding of vortices than their counterparts using the wall function boundary condition.
Numerical modeling of flow and scour below a pipeline in currents
Part I. Flow simulation
Liang, Dongfang (author) / Cheng, Liang (author)
Coastal Engineering ; 52 ; 25-42
2004-09-09
18 pages
Article (Journal)
Electronic Resource
English
Numerical modeling of flow and scour below a pipeline in currents
Online Contents | 2005
Numerical modeling of flow and scour below a pipeline in currents
Online Contents | 2004
Numerical modeling of flow and scour below a pipeline in currents
| British Library Online Contents | 2005
Numerical modeling of flow and scour below a pipeline in currents
Online Contents | 2004
Numerical modeling of flow and scour below a pipeline in currents
Online Contents | 2005