Title :
Towards computations of ocean flows using Navier-Stokes equations
Author :
Beddhu, Murali ; Jiang, Min-Yee ; Taylor, Lafayette K. ; Whitfield, David L.
Author_Institution :
NSF Eng. Res. Center, Mississippi State Univ., MS, USA
Abstract :
The equations for mass, momentum, temperature and salinity are formulated in a non-inertial general curvilinear coordinate system to be solved numerically. A flux-difference split type of numerical flux formulation is used for the convective fluxes and the equations are numerically solved in a strongly coupled manner using the discretized Newton-relaxation scheme. The addition of artificial viscosity is not required for stability. Test cases were considered that included laminar flow over a flat plate with prescribed wall temperature and salinity as well as laminar flow with heat transfer over a backward facing step. These computations compare well with existing results. The present numerical scheme was also applied to a body-fitted grid that approximates the entire Atlantic Ocean and rotates with the Earth. These results, though encouraging, must be considered preliminary
Keywords :
Navier-Stokes equations; geophysical fluid dynamics; geophysics computing; heat transfer; laminar flow; oceanography; Atlantic Ocean; Earth; Navier-Stokes equations; artificial viscosity; body-fitted grid; convective fluxes; discretized Newton-relaxation scheme; flat plate; flux-difference split type; heat transfer; laminar flow; mass; momentum; noninertial general curvilinear coordinate system; numerical flux formulation; ocean flow computation; salinity; stability; temperature; Computational fluid dynamics; Difference equations; Electric shock; Laboratories; Mesh generation; Navier-Stokes equations; Ocean temperature; Stability; Testing; Viscosity;
Conference_Titel :
Supercomputing '94., Proceedings
Conference_Location :
Washington, DC
Print_ISBN :
0-8186-6605-6
DOI :
10.1109/SUPERC.1994.344274
