Dust and water droplets effect on the flow field developed behind strong normal shock waves
Abstract
The propagation of strong normal shock waves into a quiescent suspension composed of argon gas, water droplets and solid dust particles is studied. For evaluating the flow behavior in the relaxation zone, the conservation equations for a steady, one-dimensional suspension flow are formulated and solved numerically. The solution indicates that the presence of waver droplets and dust particles has a significant effect on the flow inside the relaxation zone and on the eventually reached post-shock suspension equilibrium state. Higher pressures and temperatures are obtained in the suspension as compared with a similar pure argon gas. Changes in the physical properties of the dust have noticeable effect on the dust behavior in the relaxation zone. However, these changes have only small effect on either the behavior of the gaseous phase or the eventually reached post-shock suspension equilibrium state.
- Publication:
-
26th Conference on Aviation and Astronautics
- Pub Date:
- 1984
- Bibcode:
- 1984avas.conf...98B
- Keywords:
-
- Conservation Equations;
- Drops (Liquids);
- Dust;
- Flow Distribution;
- Normal Shock Waves;
- Shock Wave Propagation;
- Argon Plasma;
- Atomic Collisions;
- Hugoniot Equation Of State;
- Maxwell-Boltzmann Density Function;
- Shock Fronts;
- Water;
- Fluid Mechanics and Heat Transfer