Prediction and rational correlation of thermophoretically reduced particle mass transfer to hot surfaces across laminar or turbulent forced-convection gas boundary layers
Abstract
A formulation previously developed to predict and correlate the thermophoretically-augmented submicron particle mass transfer rate to cold surfaces is found to account for the thermophoretically reduced particle mass transfer rate to overheated surfaces such that thermophoresis brings about a 10-decade reduction below the convective mass transfer rate expected by pure Brownian diffusion and convection alone. Thermophoretic blowing is shown to produce effects on particle concentration boundary-layer (BL) structure and wall mass transfer rates similar to those produced by real blowing through a porous wall. The applicability of the correlations to developing BL-situations is demonstrated by a numerical example relevant to wet-steam technology.
- Publication:
-
Chemical Engineering Communications
- Pub Date:
- 1986
- Bibcode:
- 1986ChEnC..44..107G
- Keywords:
-
- Forced Convection;
- Hot Surfaces;
- Laminar Boundary Layer;
- Mass Transfer;
- Thermophoresis;
- Turbulent Boundary Layer;
- Deposition;
- Temperature Distribution;
- Wall Flow;
- Fluid Mechanics and Heat Transfer