An analytical model is presented Cor predicting film condensation of vapor flowing inside a vertical mini triangular channel. The Concurrent liquid vapor two-phase flow field is divided into three zones: the thin liquid film flow oil the sidewall. the condensate in the corners and the vapor core flow in the center. The model takes into account the effects of capillary force induced by the free liquid film curvature variation, interfacial shear stress. interfacial thermal resistance. gravity, axial pressure gradient. and saturation temperatures, The axial variation of the cross-sectional average heat transfer coefficient of steam condensing inside an equilateral triangular channel is found to be substantially higher than that inside a round tube having the same hydraulic diameter in particular in the entry region. This enhancement is attributed to the extremely thin liquid film on the sidewall that results front the liquid from the liquid flow toward the channel corners due to surface tension. The influences of the inlet vapor flow rates. the inlet subcooling. and the channel size on the heat transfer coefficients are also examined.