Heat and mass transfer rates during flow of dissociated hydrogen gas over graphite surface
Abstract
To improve upon the performance of chemical rockets, the nuclear reactor has been applied to a rocket propulsion system using hydrogen gas as working fluid and a graphite-composite forming a part of the structure. Under the boundary layer approximation, theoretical predictions of skin friction coefficient, surface heat transfer rate and surface regression rate have been made for laminar/turbulent dissociated hydrogen gas flowing over a flat graphite surface. The external stream is assumed to be frozen. The analysis is restricted to Mach numbers low enough to deal with the situation of only surface-reaction between hydrogen and graphite. Empirical correlations of displacement thickness, local skin friction coefficient, local Nusselt number and local non-dimensional heat transfer rate have been obtained. The magnitude of the surface regression rate is found low enough to ensure the use of graphite as a linear or a component of the system over an extended period without loss of performance.
- Publication:
-
International Journal of Turbo and Jet Engines
- Pub Date:
- 1986
- Bibcode:
- 1986IJTJE...3....1N
- Keywords:
-
- Gas Flow;
- Graphite;
- Heat Transfer;
- Hydrogen;
- Mass Transfer;
- Nuclear Reactors;
- Rocket Thrust;
- Erosion;
- Laminar Flow;
- Nusselt Number;
- Prandtl Number;
- Skin Friction;
- Transition Flow;
- Turbulent Flow;
- Fluid Mechanics and Heat Transfer