Liquid film–induced critical heat flux enhancement on structured surfaces

Li, Jiaqi; Kang, Daniel; Rabbi, Kazi Fazle; Fu, Wuchen; Yan, Xiao; Fang, Xiaolong; Fan, Li‐Wu; Miljkovic, Nenad

doi:10.1126/sciadv.abg4537

Cited by 38 publications

(12 citation statements)

References 53 publications

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“…Here, the autonomous curation of massive in situ bubble datasets enabled by our framework stands to compliment recent advances in imaging techniques, that exclusively study top- and bottom-view bubble statistics to identify the fundamental physics governing pool boiling. 58,59,66,67 The datasets acquired at the ONB confirmed the correlations between bubble statistics and heat transfer performances. Due to the multidimensionality of the problem, innate structural heterogeneity of the hybrid NWs, and intrinsic variability of pool boiling experiments, still it is challenging to precisely predict overall HTC and CHF.…”

Section: Discussionmentioning

confidence: 63%

Computer vision-assisted investigation of boiling heat transfer on segmented nanowires with vertical wettability

Lee¹,

Suh

Kuciej

et al. 2022

Nanoscale

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Section: Discussionmentioning

confidence: 63%

Computer vision-assisted investigation of boiling heat transfer on segmented nanowires with vertical wettability

Lee¹,

Suh

Kuciej

et al. 2022

Nanoscale

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“…Rishi et al [26] utilized a combination of ball milling, salt templating, and sintering techniques to achieve a porous coating. This sample exhibited a CHF of 289 W/cm 2 at a wall superheat of only 2.2 • C. Nanoflower structures fabricated by chemical etching presented a high CHF of 299.7 W/cm 2 [27]. The CHF of MCM-5 is 210 W/cm 2 , lower than the micro-nanostructures proposed in Refs.…”

Section: Comparison With Other Samplesmentioning

confidence: 59%

“…This sample exhibited a CHF of 289 W/cm 2 at a wall superheat of only 2.2 °C. Nanoflower structures fabricated by chemical etching presented a high CHF of 299.7 W/cm 2 [ 27 ]. The CHF of MCM-5 is 210 W/cm 2 , lower than the micro-nanostructures proposed in Refs.…”

Section: Resultsmentioning

confidence: 99%

Pool Boiling Performance of Multilayer Micromeshes for Commercial High-Power Cooling

et al. 2021

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With the rapid development of electronics, thermal management has become one of the most crucial issues. Intense research has focused on surface modifications used to enhance heat transfer. In this study, multilayer copper micromeshes (MCMs) are developed for commercial compact electronic cooling. Boiling heat transfer performance, including critical heat flux (CHF), heat transfer coefficients (HTCs), and the onset of nucleate boiling (ONB), are investigated. The effect of micromesh layers on the boiling performance is studied, and the bubbling characteristics are analyzed. In the study, MCM-5 shows the highest critical heat flux (CHF) of 207.5 W/cm2 and an HTC of 16.5 W(cm2·K) because of its abundant micropores serving as nucleate sites, and outstanding capillary wicking capability. In addition, MCMs are compared with other surface structures in the literature and perform with high competitiveness and potential in commercial applications for high-power cooling.

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“…Flow patterns have previously been shown to affect heat transfer coefficient values, and numerous flow regime maps exist to identify local regimes and threshold criteria for transition between flow regimes. , As shown in Figure D, an appropriate flow regime map (see Section S9) was chosen to identify the regime near the entrance of the test section. , Nucleation and the resulting bubbles formed drive the thermal performance in this region of high heat transfer enhancement at low vapor qualities ( x < 0.1). Concentrating on the bubble characteristics (Figure E), an increase in the rate at which bubbles depart from the surface, known as the bubble departure frequency ( f ), contributes to an increase in heat transfer during nucleate boiling. The duration of bubble growth is dependent on the time required for the bubble to reach departure diameter size, and therefore, the departure frequency is inversely proportional to bubble departure diameter ( D d ).…”

Section: Resultsmentioning

confidence: 99%

“…52,53 Nucleation and the resulting bubbles formed drive the thermal performance in this region of high heat transfer enhancement at low vapor qualities (x < 0.1). Concentrating on the bubble characteristics (Figure 4E), an increase in the rate at which bubbles depart from the surface, known as the bubble departure frequency (f), 54 contributes to an increase in heat transfer during nucleate boiling. The duration of bubble growth is dependent on the time required for the bubble to reach departure diameter size, and therefore, the departure frequency is inversely proportional to bubble departure diameter (D d ).…”

Section: ■ Introductionmentioning

confidence: 99%

Scalable and Resilient Etched Metallic Micro- and Nanostructured Surfaces for Enhanced Flow Boiling

Upot

Mahvi

Rabbi

et al. 2021

ACS Appl. Nano Mater.

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Flow boiling and evaporation in tubes and channels occur in a wide variety of energy systems, such as refrigeration, air conditioning, power generation, electronics cooling, distillation, and purification. In this work, we demonstrate remarkably increased heat transfer coefficients of 270% during refrigerant flow boiling in scalable microstructured (∼40 μm), industrial-scale (∼1 m long) aluminum (Al) tubes, when compared to smooth unstructured Al tubes. To achieve scalable nanomanufacturing, we create highly conformal and durable structured surfaces by relying on hydrochloric acid Al etching. Flow boiling tests were conducted in 6.35 mm diameter Al tubes using R134a refrigerant as the working fluid. To benchmark our approach and to elucidate the effect of the structure length scale, we also fabricated ultrascalable boehmite (AlO(OH)) nanostructured (∼300 nm) Al tubes, showing that etched microscale features are necessary and key to enhancement. Durability tests conducted using a 28 day long continual flow boiling experiment demonstrated negligible degradation of the etched surfaces. The scalable and cost-effective techniques used to create these durable, etched-Al microstructures may significantly reduce manufacturing cost when contrasted with current enhancement approaches such as extrusion, drawing, and welding.

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Liquid film–induced critical heat flux enhancement on structured surfaces

Cited by 38 publications

References 53 publications

Computer vision-assisted investigation of boiling heat transfer on segmented nanowires with vertical wettability

Computer vision-assisted investigation of boiling heat transfer on segmented nanowires with vertical wettability

Pool Boiling Performance of Multilayer Micromeshes for Commercial High-Power Cooling

Scalable and Resilient Etched Metallic Micro- and Nanostructured Surfaces for Enhanced Flow Boiling

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