Effect of pore size on the nucleate pool boiling of structured enhanced tubes

Kim, Nae-Hyun; Kim, Jong-Won; Kim, Tae-Hyung

doi:10.1007/s11630-000-0056-4

Cited by 5 publications

(2 citation statements)

References 8 publications

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“…The convective medium streaming over the surface is disrupted by nano structures on the surface. The capillary action of convective medium in the nano pores helps in achieving turbulence expeditiously [9][10][11]. The turbulent flow carries away more heat energy from the surface.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of anodized/ spray pyrolysed nanoporous structure on heat transfer augmentation

et al. 2009

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This paper analyzes the effects of nanoporous surface on heat transfer temperaments of assorted thermal conducting materials. A phenomenal proposal of wielding the surface roughness to ameliorate the heat transfer rate has been discovered. The maximum increase of heat transfer rate procured by nanoporous layers is 133.3% higher than the polished bare metals of surface roughness 0.2 μm. This plays an imperative role in designing compact refrigeration systems, chemical and thermal power plants. Experimental results picture a formidable upswing of 58.3% heat transfer in chemically etched metals of surface roughness 3 μm, 133.3% in nanoporous surface of porosity 75−95 nm formed by electrochemical anodization, and porosity of 40−50 nm formed by spray pyrolysis increases the heat transfer by 130%. Effects of porosity, flow velocity and scaling on the energy transfer are also scrutinized. This paper also analyzes the multifarious modes of nanoporous fabrication, to contrive both prodigious and provident system.

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Section: Introductionmentioning

confidence: 99%

Experimental investigation of anodized/ spray pyrolysed nanoporous structure on heat transfer augmentation

et al. 2009

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“…The mushroom-shaped (or doubly reentrant) features, could stabilize the intruding menisci of wetting liquids in 'metastable states' by trapping air in the microtexture, regardless of the wettability of the material. The DRC architecture has been extensively investigated for enhancing boiling nucleation [31][32][33][34] . In their pioneering contribution, Kim et al 32 inverted the DRC architecture to realize a doubly reentrant pillar (DRP) microtexture that can repel droplets of wetting liquids with surface tension as low as 10 mN/m (placed from the top) 16 .…”

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confidence: 99%

Insect-inspired breathing interfaces: investigating robustness of coating-free gas entrapping microtextured surfaces under pressure cycles

Arunachalam,

Sadullah,

Mishra

2024

Commun Eng

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Numerous natural and engineering scenarios necessitate the entrapment of air pockets or bubbles on submerged surfaces. Current technologies for bubble entrapment rely on perfluorocarbon coatings, limiting their sustainability. Herein, we investigated the efficacy of doubly reentrant cavity architecture towards realizing gas-entrapping microtextured surfaces under static and dynamic pressure cycling. The effects of positive (>1 atm), negative (<1 atm), and positive–negative cycles on the stability the gas entrapment inside individual doubly reentrant cavities were studied across a range of pressures, ramp rates, intercycle intervals, and water-column heights. Remarkably, the fate of the trapped air under pressure cycling fell into either of the following regimes: the bubble (i) monotonically depleted (unstable), (ii) remained indefinitely stable (stable), or (iii) started growing (bubble growth). This hitherto unrealized richness of underwater bubble dynamics should guide the development of coating-free technologies and help us understand the curious lives of air-breathing aquatic and marine insects.

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Heat transfer on microstructured surfaces with pool boiling of various liquids

Aksianov

Kokhanova

Kuimov

et al. 2020

J. Phys.: Conf. Ser.

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Recommendations for predicting heat transfer coefficients and critical heat fluxes are developed on the basis of available experimental data on heat transfer and critical heat fluxes for boiling of different liquids on microstructured surfaces realized by deformed cutting method. Microstructured surfaces allow intensifying heat transfer 1.1 to 6 times. Due to the variable wettability of microstructured surface elements, critical heat fluxes increase over 4 times. The proposed criteria equations allow predicting heat transfer coefficients with an error of 30%, and critical heat fluxes with an error of 30-35%. The equations are of interest for designing cooling systems for microelectronic devices, heat and mass transfer devices, boiling zones of heat pipes and thermosyphons, etc.

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Effect of pore size on the nucleate pool boiling of structured enhanced tubes

Cited by 5 publications

References 8 publications

Experimental investigation of anodized/ spray pyrolysed nanoporous structure on heat transfer augmentation

Experimental investigation of anodized/ spray pyrolysed nanoporous structure on heat transfer augmentation

Insect-inspired breathing interfaces: investigating robustness of coating-free gas entrapping microtextured surfaces under pressure cycles

Heat transfer on microstructured surfaces with pool boiling of various liquids

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