论文信息 - A new symmetry‐preserving Cartesian‐grid method for computing flow past arbitrarily shaped objects

A new symmetry‐preserving Cartesian‐grid method for computing flow past arbitrarily shaped objects

This paper deals with a numerical method for solving the unsteady, incompressible Navier-Stokes equations in domains of arbitrarily shaped boundaries, where the boundary is represented using the Cartesian-grid approach. We introduce a novel cut-cell discretization, which preserves the symmetry of convection and diffusion. That is, convection is discretized by a skew-symmetric operator and diffusion is approximated by a symmetric, positive-definite coefficient matrix. The resulting semi-discrete (continuous in time) system conserves the kinetic energy if the dissipation is turned off;, the energy decreases if dissipation is turned on. The method is successfully tested for an incompressible, unsteady flow around a circular cylinder at Re = 100. Copyright (c) 2005 John Wiley T Sons, Ltd.

Roel Verstappen | R. Verstappen | M. Dröge | Marc Dröge

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