The flow of a thin liquid film on a stationary and rotating disk. II - Theoretical prediction
Abstract
The existing theoretical models are improved and a systematic procedure to compute the free surface flow of a thin liquid film is suggested. The solutions for axisymmetric radial flow on a stationary horizontal disk and for the disk rotating around its axis are presented. The theoretical predictions are compared with the experimental data presented in Part I of this report. The analysis shows results for both supercritical and subcritical flows and the flow structure in the vicinity of a hydraulic jump which isolates these two flow types. The detailed flow structure in a hydraulic jump was computed and shown to contain regions of separation including a 'surface roller'. The effects of surface tension are found to be important near the outer edge of the disk where the fluid experiences a free fall. At other locations, the surface tension is negligible. For a rotating disk, the frictional resistance in the angular direction is found to be as important as that in the radial direction.
- Publication:
-
Heat Transfer in Space Systems; Proceedings of the Symposium, AIAA/ASME Thermophysics and Heat Transfer Conference
- Pub Date:
- January 1990
- Bibcode:
- 1990asme.conf..135R
- Keywords:
-
- Flow Theory;
- Fluid Films;
- Liquid Flow;
- Radial Flow;
- Rotating Fluids;
- Axisymmetric Flow;
- Heat Pumps;
- Interfacial Tension;
- Rotating Disks;
- Thin Films;
- Fluid Mechanics and Heat Transfer