A universal wall-bubble growth model for water in component-scale high-pressure boiling systems

•A generalized wall-bubble growth model for water is proposed.•Wall bubble growth formulation encompasses wide experimental data.•Model is applicable for pressures of 1–180 bar, pool, flow boiling, low &high subcooling.•Applicable for bubble growth on both vertical & horizontal surfaces.•Bas...

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Bibliographic Details
Published in:International journal of heat and mass transfer Vol. 122; pp. 161 - 181
Main Authors: Murallidharan, Janani Srree, Prasad, B.V.S.S.S., Patnaik, B.S.V.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-07-2018
Elsevier BV
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Summary:•A generalized wall-bubble growth model for water is proposed.•Wall bubble growth formulation encompasses wide experimental data.•Model is applicable for pressures of 1–180 bar, pool, flow boiling, low &high subcooling.•Applicable for bubble growth on both vertical & horizontal surfaces.•Base-TL depends on global temperature difference & Apex - TL on local temperature. Development of an accurate bubble growth model is central to the prediction of heat transfer coefficient in component scale wall-boiling formulations. The bubble growth models available in the literature are not generic enough to be applicable over a wide range of pressures. For example, pressurized water reactors operate at high pressures, where the experimental correlations are sparse. In this study, a framework for modeling wall bubble growth is developed, for water. This generalized model is synthesized in a form, which takes into account the factors that contribute to the bubble thermal layer deformation in a physically consistent way. These factors have been systematically evolved to account for a wide range of conditions (i) pressures of 1–180 bar, (ii) pool as well as flow boiling conditions, (iii) low as well as high subcooling, (iv) horizontal and vertical test section orientations, etc. Bubble growth predictions from the present model have shown very good agreement across a wide range of pressures. It was observed that, for pool boiling, the wake effect at the apex of the bubble has influenced the overall growth rate. On the contrary, for flow boiling, the flow induced distortions to the thermal layer were found to be dominant both at the base as well as the apex. In the latter case, bubble growth rate was found to be significantly dependent on the magnitude of these individual distortions.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2018.01.070