On a finite-difference method for solving transient viscous flow problems
Abstract
A method has been developed to solve the unsteady, compressible Navier-Stokes equation with the property of consistency and the ability of minimizing the equation stiffness. It relies on innovative extensions of the state-of-the-art finite-difference techniques and is composed of: (1) the upwind scheme for split-flux and the central scheme for conventional flux terms in the inviscid and viscous regions, respectively; (2) the characteristic treatment of both inviscid and viscous boundaries; (3) an ADI procedure compatible with interior and boundary points; and (4) a scalar matrix coefficient including viscous terms. The performance of this method is assessed with four sample problems; namely, a standing shock in the Laval duct, a shock reflected from the wall, the shock-induced boundary-layer separation, and a transient internal nozzle flow. The results from the present method, an existing hybrid block method, and a well-known two-step explicit method are compared and discussed. It is concluded that this method has an optimal trade-off between the solution accuracy and computational economy, and other desirable properties for analyzing transient viscous flow problems.
- Publication:
-
AIAA, Aerospace Sciences Meeting
- Pub Date:
- January 1983
- Bibcode:
- 1983aiaa.meetS....L
- Keywords:
-
- Compressible Flow;
- Computational Fluid Dynamics;
- Finite Difference Theory;
- Navier-Stokes Equation;
- Unsteady Flow;
- Viscous Flow;
- Boundary Layer Separation;
- Ducted Flow;
- Nozzle Flow;
- Scalars;
- Shock Wave Interaction;
- Surges;
- Wall Pressure;
- Wave Reflection;
- Fluid Mechanics and Heat Transfer