Condensation heat transfer enhancement
In this monograph analysis and generalisation of the results of theoretical and experimental investigations of heat exchange during film condensation with variable methods of enhancement are described. Comparison of different calculation methods of enhanced condensation and effect of temperature difference, vapour shear, presence of non-condensable gases and heat exchange surface non-isothermness on average heat transfer coefficients is included.
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Condensation on horizontal lowfinned tubes
Experimental study of condensation heat transfer
Condensation on vertical profiled surfaces and tubes
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ASHRAE average heat transfer axial bottom bundles of horizontal calculation capillary comparison condensate drainage condensate film flow condensate film thickness condensate flow condensation heat transfer condensation inside condensation on horizontal condensing surface decreasing diameter dimensionless effect electrical field equation experimental data film condensation film curvature fin height fin spacing fin top flooding flow mode fluted generatrix geometry Gogonin gravity grooves heat exchange heat transfer coefficient heat transfer enhancement heat transfer surface Honda horizontal finned tubes horizontal tube hydrodynamics increase influence inside tubes integral-fin tubes inter-fins Kabov length liquid low-finned tubes Marto mass flow rate Mass Transfer micro-fin tubes Minsk Nozu Nusselt obtained parameters predicted pressure Proc profiled surface profiled tubes radius Refrigerant-113 refrigerants Rifert Schlager smooth tube solution steam condensation surface tension Table temperature transfer at condensation tube bundle tube surface values vapor condensation vapor velocity vertical tube Webb wire finning zone