Framework for a Unified Model for Nucleate and Transition Pool Boiling

Dhir, Vijay K.; Liaw, S.P.

doi:10.1115/1.3250745

Cited by 217 publications

(70 citation statements)

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“…Furthermore, Dhir and Liaw [21] found that during pool boiling, α dry (T w ≈ Τ Ν ) varies between 0.68 and 0.8 when contact angles vary between 27 and 90 degrees respectively.…”

Section: Physics Of Boilingmentioning

confidence: 99%

A Comprehensive Model for Liquid Film Boiling in Internal Combustion Engines

Habchi

2010

Oil Gas Sci. Technol. – Rev. IFP

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Résumé -Un modèle complet pour l'ébullition de film liquide dans les moteurs à combustion interne -Dans cet article, les principaux processus physiques, régissant les régimes d'ébullition nucléée et de transition d'un film liquide, ont été examinés à partir des observations expérimentales disponibles dans la littérature. Les tendances physiques observées, ont été utilisées, pour développer un modèle phénoménologique complet pour l'ébullition de film liquide (LFB). Celui-ci permet le calcul de sa vaporisation, dans le régime d'ébullition nucléée, ainsi que, dans le régime d'ébullition de transition. Ces régimes sont identifiés par les températures de saturation, de Nukiyama et de Leidenfrost. L'estimation des températures de Nukiyama et de Leidenfrost, en fonction de la pression de gaz ambiante, a requis une attention toute particulière. Plusieurs courbes de durée de vie, de gouttes de grosse taille déposées sur une surface chaude dans diverses conditions, ont été choisies parmi celles qui sont disponibles dans la littérature récente pour la validation du modèle LFB. Les résultats numériques montrent que les ordres de grandeur et les tendances observées expérimentalement sont bien respectés. En particulier, le modèle LFB reproduit bien la disparition progressive du régime de Leidenfrost avec des pressions suffisamment élevées du gaz. D'autre part, l'augmentation progressive du taux de vaporisation du liquide avec la rugosité du mur, précédemment observée expérimentalement près du point de Leidenfrost, a été correctement prédite par le modèle LFB. Abstract -A Comprehensive Model for Liquid Film Boiling in Internal Combustion Engines -In this paper, the main physical processes governing the nucleate and transition regimes of the boiling of a liquid film were reviewed from the available experimental observations in the literature. The physical tendencies observed in most experiments have been used to develop a comprehensive phenomenological Liquid Film Boiling (LFB) model which allows the calculation of the vaporization of liquid films in the

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“…Furthermore, Dhir and Liaw [21] found that during pool boiling, α dry (T w ≈ Τ Ν ) varies between 0.68 and 0.8 when contact angles vary between 27 and 90 degrees respectively.…”

Section: Physics Of Boilingmentioning

confidence: 99%

A Comprehensive Model for Liquid Film Boiling in Internal Combustion Engines

Habchi

2010

Oil Gas Sci. Technol. – Rev. IFP

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“…First, nucleation sites in appropriate number and dimensions need to be provided such as cavities, rough areas or hydrophobic islands 2 . As of today, the performance of boiling surfaces has been increased by using wicking structures to prevent dry out 3 , by increasing the surface area with fins or fluidized bed [3][4][5][6] , and by enhancing the wettability of the surface [5][6][7][8][9] . The latter strategy is justified by experiments of Wang and Dhir 10 , showing that the CHF was increased by enhancing surface wettability.…”

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confidence: 99%

Do surfaces with mixed hydrophilic and hydrophobic areas enhance pool boiling?

Betz

Qiu

et al. 2010

Applied Physics Letters

377

150

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We demonstrate that smooth and flat surfaces combining hydrophilic and hydrophobic patterns improve pool boiling performance. Compared to a hydrophilic surface with 7º wetting angle, the measured critical heat flux and heat transfer coefficients of the enhanced surfaces are up to respectively 65 and 100% higher. Different networks combining hydrophilic and hydrophobic regions are characterized. While all tested networks enhance the heat transfer coefficient, large enhancements of critical heat flux are typically found for hydrophilic networks featuring hydrophobic islands. Hydrophilic networks indeed are shown to prevent the formation of an insulating vapor layer.

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“…Such modification generally increases surface wettability, which causes an increased CHF through the enhanced liquid spreading over the heated area. 14,15 Another effect of the surface modification is to increase the number of microscale cavities, which serve as the starting sites for heterogeneous nucleation of liquid for bubble formation. 1,2 The relevant sizes of such cavities are generally in the range of tens to hundreds of micrometers.…”

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confidence: 99%

Nanowires for Enhanced Boiling Heat Transfer

et al. 2009

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Boiling is a common mechanism for liquid−vapor phase transition and is widely exploited in power generation and refrigeration devices and systems. The efficacy of boiling heat transfer is characterized by two parameters: (a) heat transfer coefficient (HTC) or the thermal conductance; (b) the critical heat flux (CHF) limit that demarcates the transition from high HTC to very low HTC. While increasing the CHF and the HTC has significant impact on system-level energy efficiency, safety, and cost, their values for water and other heat transfer fluids have essentially remained unchanged for many decades. Here we report that the high surface tension forces offered by liquids in nanowire arrays made of Si and Cu can be exploited to increase both the CHF and the HTC by more than 100%.

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Framework for a Unified Model for Nucleate and Transition Pool Boiling

Cited by 217 publications

References 0 publications

A Comprehensive Model for Liquid Film Boiling in Internal Combustion Engines

A Comprehensive Model for Liquid Film Boiling in Internal Combustion Engines

Do surfaces with mixed hydrophilic and hydrophobic areas enhance pool boiling?

Nanowires for Enhanced Boiling Heat Transfer

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