A model has been developed for predicting the amount of condensate retained as drops on the air-side of heat exchangers operating under dehumidifying conditions. For a coil with a given surface wettability, characterized by the advancing contact angle, the maximum diameter for a retained drop is obtained from a balance between gravitational and surface tension forces. A logarithmic function is used to describe the size-distribution of drops on fins, based on the fraction of fin-area covered by liquid. The volumes of individual drops are calculated by a geometric method for approximating the three-dimensional shapes of drops on vertical and inclined surfaces. The total volume of condensate accumulated on a coil is then found by multiplying the size-distribution and volume functions and integrating over all drop diameters. The model is successful in predicting measurements by other researchers of the mass of condensate retained on plain-fin heat exchangers. The critical fin spacing to avoid the formation of condensate bridges is also predicted.

Issue Section:
Heat Exchangers
Keywords:
condensation, heat exchangers, two-phase flow, drops, wetting, contact angle, surface tension, condensation, retention, heat exchangers
Topics:
Condensed matter, Heat exchangers, Surface tension, Bridges (Structures), Condensation
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Copyright © 2006
 by American Society of Mechanical Engineers
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