The effect of metal foam fins on pool boiling of DI-water

The effect of metal foam fins on pool boiling of DI-water

•Porous materials influence liquid flow patterns, enhancing boiling heat transfer performance.•Different porous microstructured surfaces affect vapor bubble dynamics during water pool boiling.•The interplay between metal foam thickness and inter-fin space is analyzed.•Distinct advantages at low and...

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Bibliographic Details
Published in:Experimental thermal and fluid science Vol. 154; p. 111151
Main Authors: Gomes da Silva Vilaronga, Arthur, Lachi Manetti, Leonardo, Sheshrao Gajghate, Sameer, Diehl de Oliveira, Jeferson, Maria Cardoso, Elaine
Format: Journal Article
Language:English
Published: Elsevier Inc 01-05-2024
Subjects:
Enhancement techniques
Metal foam
Micro-pin fins
Microchannels
Pool boiling
Micro-pin fins
Enhancement techniques
Pool boiling
Metal foam
Microchannels
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Summary:•Porous materials influence liquid flow patterns, enhancing boiling heat transfer performance.•Different porous microstructured surfaces affect vapor bubble dynamics during water pool boiling.•The interplay between metal foam thickness and inter-fin space is analyzed.•Distinct advantages at low and high heat fluxes, giving insights for optimizing heat transfer surfaces. The technology industry's growth has motivated the development of optimized thermal control techniques, such as pool boiling. Different surface designs have been developed to enhance the heat transfer coefficient in different heat transfer applications. These designs aim to improve thermal performance, increase efficiency, and address specific challenges associated with heat exchange. Introducing porous materials or modifying the permeability of surfaces can influence liquid flow patterns and enhance convective heat transfer. Metal foams, for example, have been employed to increase surface area and promote liquid replacement on the surface, enhancing the capillary action and improving heat transfer performance. The current work investigates the effect of different porous microstructured surfaces, based on microchannels and micro-pin fins, on pool boiling heat transfer of deionized water. This work addressed pool boiling tests using copper metal foams fins with different thicknesses, 3 mm and 1 mm, to study the vapor bubble dynamics in the foam cell. The results indicate that porous copper microchannels with a thickness smaller than the capillary length of the working fluid promote vapor bubble departure, thereby enhancing heat transfer (25 % and 21 % for 0.5 and 1 mm of inter-fin-spacing, respectively). The interplay between foam thickness and inter-fin space in porous microchannel surfaces revealed nuanced effects, with smaller inter-fin spaces demonstrating higher enhancement factors at low heat fluxes due to vapor bubble dynamics and capillary effects. In comparison, larger inter-fin spaces showed improved heat transfer coefficients at high heat fluxes by reducing vapor bubble escaping resistance. These findings contribute valuable insights into optimizing pool boiling heat transfer through surface modifications.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2024.111151