Surface temperature distribution along a thin liquid layer due to thermocapillary convection
Abstract
The surface temperature distributions due to thermocapillary convections in a thin liquid layer with heat fluxes imposed on the free surface were investigated. The nondimensional analysis predicts that, when convection is important, the characteristics length scale in the flow direction L, and the characteristic temperature difference delta T sub o can be represented by L and delta T sub o approx. (A2Ma)/1/4 delta T sub R, respectively, where L sub R and delta sub R are the reference scales used in the conduction dominant situations with A denoting the aspect ratio and Ma the Marangoni number. Having L and delta sub o defined, the global surface temperature gradient delta sub o/L, the global thermocapillary driving force, and other interesting features can be determined. Numerical calculations involving a Gaussian heat flux distribution are presented to justify these two relations.
- Publication:
-
NASA STI/Recon Technical Report N
- Pub Date:
- 1985
- Bibcode:
- 1985STIN...8534357L
- Keywords:
-
- Free Convection;
- Liquid Surfaces;
- Surface Temperature;
- Temperature Distribution;
- Convective Flow;
- Gauss Equation;
- Heat Flux;
- Marangoni Convection;
- Microgravity Applications;
- Normal Density Functions;
- Numerical Analysis;
- Space Commercialization;
- Fluid Mechanics and Heat Transfer