Approximations for the Thermodynamic and Transport Properties of High-temperature Air
Approximations for the Thermodynamic and Transport Properties of High-temperature Air

Author: C. Frederick Hansen

Publisher:

Published: 1958

Total Pages: 724

ISBN-13:

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The thermodynamic and transport prorerties of high-temperature air are found in closed form starting from approximate partition functions for the major components in air and neglecting all minor components. The compressibility, energy, entropy, the specific heats, the speed of sound, the coefficients of viscosity and of thermal conductivity, and the Prandtl numbers for air are tabulated from 500 degrees to 15,000 degrees K over a range of pressure from 0.0001 to 100 atmospheres. The enthalpy of air and the mol fractions of the major components of air can easily be found from the tabulated values for compressibility and energy. It is predicted that the Prandtl number for fully ionized air will become small compared to unity, the order of 0.01, and this implies that boundary layers in such flow will be very transparent to heat flux.

The High-Temperature Hypersonic Gasdynamics Facility Estimated Mach Number 6 Through 14 Performance
The High-Temperature Hypersonic Gasdynamics Facility Estimated Mach Number 6 Through 14 Performance

Author: Paul Czysz

Publisher:

Published: 1963

Total Pages: 116

ISBN-13:

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The High Temperature Gas Dynamics Facility was developed as a result of the Aeronautical Systems Division's effort to extend the state-of the-art in hypersonic aerodynamic simulation. The facility is a hypersonic wind tunnel supplied with high pressure air, heated from a zirconia dioxide pebble heater. The maximum stagnation pressure and temperature is 40 atres and 4700 R, respectively. This facility is one of four of its kind in this hemisphere and the only Air Force facility of its type. This report discusses the modification of the facility to a two foot diameter test section with a Mach number range of 6 through 14 and its expected performance. This facility is scheduled to be operational in the Fall of 1963.