A time dependent, two dimensional Navier-Stokes code employing the method of body fitted coordinate technique was developed for supersonic flows past blunt bodies of arbitrary shapes. The bow shock ahead of the body is obtained as part of the solution, viz., by shock capturing. A first attempt at mesh refinement in the shock region was made by using the forcing function in the coordinate generating equations as a linear function of the density gradients. The technique displaces a few lines from the neighboring region into the shock region. Numerical calculations for Mach numbers 2 and 4.6 and Reynolds numbers from 320 to 10,000 were performed for a circular cylinder with and without a fairing. Results of Mach number 4.6 and Reynolds number ...
A numerical method, which is simpler and more efficient than others currently in use, is proposed fo...
Numerical solutions for blunt axisymmetric bodies in supersonic spherical source flo
Two-dimensional axisymmetric, reacting viscous flow over blunt projectiles is computed to study shoc...
A formulation of the complete Navier-Stokes problem for a viscous hypersonic flow in general curvili...
A coordinate transformation, which can approximate many different two-dimensional and axisymmetric b...
Numerical methods and computer programs for two-dimensional and axisymmetric supersonic flow over bl...
A general orthogonal coordinate system is used to describe various axisymmetric and two-dimensional ...
Time-dependant method for calculating supersonic blunt body flow fields with sharp corners and embed...
Numerical analysis of free flow fields around axisymmetric blunt bodies in supersonic fligh
The numerical solution of the full Navier-Stokes Equations for viscous flows with high Mach numbers ...
A numerical solution to the Navier-Stokes equations was obtained for blunt axisymmetric entry bodies...
This paper reports on numerical results for supersonic and hypersonic steady flows over axisymmetri...
The steady-state Navier-Stokes equations are solved for hypersonic flow about blunt axisymmetric bod...
Direct calculation method for supersonic inviscid flow around axisymmetric blunt body with conically...
A numerical method for solving the parabolic approximation to the steady-state compressible Navier-S...
A numerical method, which is simpler and more efficient than others currently in use, is proposed fo...
Numerical solutions for blunt axisymmetric bodies in supersonic spherical source flo
Two-dimensional axisymmetric, reacting viscous flow over blunt projectiles is computed to study shoc...
A formulation of the complete Navier-Stokes problem for a viscous hypersonic flow in general curvili...
A coordinate transformation, which can approximate many different two-dimensional and axisymmetric b...
Numerical methods and computer programs for two-dimensional and axisymmetric supersonic flow over bl...
A general orthogonal coordinate system is used to describe various axisymmetric and two-dimensional ...
Time-dependant method for calculating supersonic blunt body flow fields with sharp corners and embed...
Numerical analysis of free flow fields around axisymmetric blunt bodies in supersonic fligh
The numerical solution of the full Navier-Stokes Equations for viscous flows with high Mach numbers ...
A numerical solution to the Navier-Stokes equations was obtained for blunt axisymmetric entry bodies...
This paper reports on numerical results for supersonic and hypersonic steady flows over axisymmetri...
The steady-state Navier-Stokes equations are solved for hypersonic flow about blunt axisymmetric bod...
Direct calculation method for supersonic inviscid flow around axisymmetric blunt body with conically...
A numerical method for solving the parabolic approximation to the steady-state compressible Navier-S...
A numerical method, which is simpler and more efficient than others currently in use, is proposed fo...
Numerical solutions for blunt axisymmetric bodies in supersonic spherical source flo
Two-dimensional axisymmetric, reacting viscous flow over blunt projectiles is computed to study shoc...