A relatively simple method is presented for including the effect of variable entropy at the boundary-layer edge in a heat transfer method developed previously. For each inviscid surface streamline an approximate shockwave shape is calculated using a modified form of Maslen's method for inviscid axisymmetric flows. The entropy for the streamline at the edge of the boundary layer is determined by equating the mass flux through the shock wave to that inside the boundary layer. Approximations used in this technique allow the heating rates along each inviscid surface streamline to be calculated independent of the other streamlines. The shock standoff distances computed by the present method are found to compare well with those computed by Maslen...
Conference on aerodynamic heat transfer in space shuttle configurations and procedures and technique...
Type IV shock wave interference heating on a blunt body causes extremely intense heating over a very...
Time dependent heat transfer rates have been calculated from time dependent temperature measurements...
Computer program for calculating inviscid surface streamlines and heat transfer on space shuttle con...
Procedures and methods for predicting aerothermodynamic heating to delta orbiter shuttle vehicles we...
The theoretical heat-transfer distributions are compared with experimental heat-transfer distributio...
Analytical studies have been conducted concerning the lee-surface flow phenomena over a space shuttl...
A description of the computer program used for heating rate calculation for blunt bodies in hyperson...
A general method developed for the analysis of inviscid hypersonic shock layers is discussed for app...
The objective is to provide useful engineering formulations and to instill a modest degree of physic...
Calculations of laminar heat transfer to windward wing and body surfaces of a straight wing MSC orbi...
The collection and analysis of aerodynamic heating data obtained from shock impingement experimental...
A method is presented for calculating the aerodynamic heating and shear stresses at the wall for tan...
The convective heat transfer distribution for space shuttle configurations is discussed. The viscous...
Convective heat transfer measurements, made on the conical portion of spherically blunted cones (30 ...
Conference on aerodynamic heat transfer in space shuttle configurations and procedures and technique...
Type IV shock wave interference heating on a blunt body causes extremely intense heating over a very...
Time dependent heat transfer rates have been calculated from time dependent temperature measurements...
Computer program for calculating inviscid surface streamlines and heat transfer on space shuttle con...
Procedures and methods for predicting aerothermodynamic heating to delta orbiter shuttle vehicles we...
The theoretical heat-transfer distributions are compared with experimental heat-transfer distributio...
Analytical studies have been conducted concerning the lee-surface flow phenomena over a space shuttl...
A description of the computer program used for heating rate calculation for blunt bodies in hyperson...
A general method developed for the analysis of inviscid hypersonic shock layers is discussed for app...
The objective is to provide useful engineering formulations and to instill a modest degree of physic...
Calculations of laminar heat transfer to windward wing and body surfaces of a straight wing MSC orbi...
The collection and analysis of aerodynamic heating data obtained from shock impingement experimental...
A method is presented for calculating the aerodynamic heating and shear stresses at the wall for tan...
The convective heat transfer distribution for space shuttle configurations is discussed. The viscous...
Convective heat transfer measurements, made on the conical portion of spherically blunted cones (30 ...
Conference on aerodynamic heat transfer in space shuttle configurations and procedures and technique...
Type IV shock wave interference heating on a blunt body causes extremely intense heating over a very...
Time dependent heat transfer rates have been calculated from time dependent temperature measurements...