Optimization of Pool Boiling Heat Transfer on microporous metal coating surfaces with FC-72 as a working fluid

Mudhafar, Mudhafar A. H.; Wang, Zhenghao

doi:10.1007/s00231-022-03229-8

Cited by 7 publications

(1 citation statement)

References 13 publications

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“…This approach directly deals with the inclusion in the heat transfer surface of structures at the nano/microscale [8], including porous coatings, nanoparticles [9], nanofibers, nanotubes covering, and mixed wettability characteristics [10,11]. Usually, physical [12] and chemical [13] methodologies are employed to process the intended heating surface modification, along with the exploration of a wide range of different materials, such as metals [14], metal oxides [15], ceramics [16], carbon [17], graphene, and graphene oxide [18]. The methodologies include physical vapor deposition (PVD), all types of chemical vapor deposition (CVD), electrochemical etching, spraying, magnetron sputtering, spin coating, plasma coating, and sintering, among many others.…”

Section: Introductionmentioning

confidence: 99%

An Overview of the Recent Advances in Pool Boiling Enhancement Materials, Structrure, and Devices

Pereira,

Souza,

Lima

et al. 2024

Micromachines

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This review attempts to provide a comprehensive assessment of recent methodologies, structures, and devices for pool boiling heat transfer enhancement. Several enhancement approaches relating to the underlying fluid route and the capability to eliminate incipient boiling hysteresis, augment the nucleate boiling heat transfer coefficient, and improve the critical heat flux are assessed. Hence, this study addresses the most relevant issues related to active and passive enhancement techniques and compound enhancement schemes. Passive heat transfer enhancement techniques encompass multiscale surface modification of the heating surface, such as modification with nanoparticles, tunnels, grooves, porous coatings, and enhanced nanostructured surfaces. Also, there are already studies on the employment of a wide range of passive enhancement techniques, like displaced enhancement, swirl flow aids, and bi-thermally conductive surfaces. Moreover, the combined usage of two or more enhancement techniques, commonly known as compound enhancement approaches, is also addressed in this survey. Additionally, the present work highlights the existing scarcity of sufficiently large available databases for a given enhancement methodology regarding the influencing factors derived from the implementation of innovative thermal management systems for temperature-sensitive electronic and power devices, for instance, material, morphology, relative positioning and orientation of the boiling surface, and nucleate boiling heat transfer enhancement pattern and scale. Such scarcity means the available findings are not totally accurate and suitable for the design and implementation of new thermal management systems. The analysis of more than 100 studies in this field shows that all such improvement methodologies aim to enhance the nucleate boiling heat transfer parameters of the critical heat flux and nucleate heat transfer coefficient in pool boiling scenarios. Finally, diverse challenges and prospects for further studies are also pointed out, aimed at developing important in-depth knowledge of the underlying enhancement mechanisms of such techniques.

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Section: Introductionmentioning

confidence: 99%

An Overview of the Recent Advances in Pool Boiling Enhancement Materials, Structrure, and Devices

Pereira,

Souza,

Lima

et al. 2024

Micromachines

View full text Add to dashboard Cite

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Fluid flow and heat transfer characteristics on uncoated and micro porous straight and divergent heat exchangers for high-powered electronic devices

Mudhafar

2022

Heat Mass Transfer

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The measurement of friction factors and heat transfer Nusselt numbers for the flow of air and CO2 through micro tubes

Mudhafar

2022

Heat Mass Transfer

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Optimization of Pool Boiling Heat Transfer on microporous metal coating surfaces with FC-72 as a working fluid

Cited by 7 publications

References 13 publications

An Overview of the Recent Advances in Pool Boiling Enhancement Materials, Structrure, and Devices

An Overview of the Recent Advances in Pool Boiling Enhancement Materials, Structrure, and Devices

Fluid flow and heat transfer characteristics on uncoated and micro porous straight and divergent heat exchangers for high-powered electronic devices

The measurement of friction factors and heat transfer Nusselt numbers for the flow of air and CO2 through micro tubes

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