A review of nucleate pool-boiling heat transfer in different liquids and nanofluids

Zarrag, Khudir Z; Ismail, Firas B; Sann, Tan E; Habeeb, Laith J

doi:10.1177/09576509231174692

Cited by 1 publication

(1 citation statement)

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“…Other researchers [9][10][11][12][13][14] studied nanofluids and boiling heat transfer for different applications, boundary conditions, geometries, configurations, based nanofluids, nanoparticles, and range of parameters. They concluded that when adding nanoparticles to base fluid, heat transfer enhanced clearly.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Pool Boiling Heat Transfer Through Micro-Finned Surfaces and Al2O3-Water Nanofluids: A Numerical Study

Fadhl,

Habeeb

2024

JSE

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Among the various heat transfer mechanisms, boiling heat transfer is distinguished by its capacity to dissipate substantial heat via the latent heat of vaporization with minimal temperature differentials. This phenomenon is pivotal across a range of industrial applications, including the cooling of macro-and micro-electronic devices, boiler tubes in power generation plants, evaporators in refrigeration systems, and nuclear reactors, where the nucleate pool boiling regime and two-phase flow are of particular interest. The drive to enhance heat exchange systems' efficiency has consistently focused on minimizing heat loss through system miniaturization. This investigation employs numerical simulations via the Fluent software to elucidate the heat transfer and cooling processes facilitated by nanofluids with varied concentrations on differently shaped finned surfaces, alongside the utilization of water and ethylene glycol as base fluids. Specifically, the thermal performance of Al 2 O 3 -water nanofluids at different concentrations (0, 0.3, 0.6, 1, 1.2, and 1.4 percent by volume) was scrutinized under boiling conditions across surfaces endowed with circular, triangular, and square fins. The study confirmed that the incorporation of Al 2 O 3 nanoparticles into the water base fluid not only enhances its thermal conductivity but, in conjunction with micro-finned surfaces, also augments the available surface area, thereby improving wettability. These modifications collectively contribute to a marked increase in the heat transfer coefficient (HTC) and a reduction in the critical heat flux (CHF). Furthermore, it was observed that at a 0.3% volume concentration of Al 2 O 3 with square fins, the temperature span extends from 373.1 to 383.1 K. Nonetheless, the long-term stability and efficacy of nanofluids are subject to potential impacts from nanoparticle aggregation and sedimentation. This study underlines the synergistic effect of nanoparticle-enhanced fluids and micro-finned surface architectures in bolstering pool boiling heat transfer, signifying a promising avenue for thermal management advancements in various industrial domains.

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