Numerical study of steam condensation inside a long inclined flattened channel

•CFD simulation of steam condensation inside flattened channel with high aspect ratio.•The main condensation mechanism was drop-wise mode.•Increase in inclination angle caused an increase in heat transfer coefficient.•Performance of κ-ω sst turbulence model was better than κ-ε model. In this work, c...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2019-05, Vol.134, p.450-467
Main Authors: Abadi, S.M.A. Noori Rahim, Davies, William A., Hrnjak, Pega, Meyer, Josua P.
Format: Article
Language:English
Subjects:
Computational fluid dynamics
Computer simulation
Condensation
Cooling
Flattening
Fluid flow
Heat transfer coefficient
Heat transfer coefficients
High aspect ratio
Inclination angle
Inclined flattened channel
Multiphase flow
Pressure drop
Saturation
Temperature
VOF
Wall temperature
Working fluids
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Summary:•CFD simulation of steam condensation inside flattened channel with high aspect ratio.•The main condensation mechanism was drop-wise mode.•Increase in inclination angle caused an increase in heat transfer coefficient.•Performance of κ-ω sst turbulence model was better than κ-ε model. In this work, condensation of steam inside a long inclined flattened channel was studied numerically. The simulated case is a flattened channel with a length of 10.7 m and a very high aspect ratio. The channel width and height are 0.0063 m and 0.214 m, respectively. The volume of fluid (VOF) multiphase flow formulation was used to present the governing equations. The flow field was assumed to be three-dimensional, unsteady and turbulent. Furthermore, the working fluid was water with constant properties at the specified saturation temperature. The effects of various parameters such as inclination angle, steam mass flux and saturation temperature on the condensation heat transfer coefficient, cooling wall temperature, and pressure drop along the channel were investigated. The present results showed very good agreement with the previous experimental work and available correlations. It was found that the increase in the inclination angle, steam mass flux and the decrease in the saturation temperature caused an increase in the heat transfer coefficient. The results also showed that the dominant mode of condensation was the drop-wise mode on the cooling wall. Furthermore, in some cases, complete condensation was observed, which caused sub-cooling in the condensate river and backflow from the exit region of the channel.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2019.01.063