Revealing the complex conduction heat transfer mechanism of nanofluids

Sergis, A.; Hardalupas, Y.

doi:10.1186/s11671-015-0954-8

Cited by 4 publications

(1 citation statement)

References 39 publications

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“…Nanofluids dispersed in ethylene glycol have pulled in great attention in motor cooling applications [189]. Increment in the conventional coolant working temperature and the heat rejection rate can be done by utilizing nanofluids within the current motor cooling system [190]. A study used a 3.5% volume fraction of aluminum oxide nanoparticles dispersed in a standard motor coolant in a standard car engine and recorded enhanced thermal conductivity of 10.41% at room temperature [191].…”

Section: Nanofluids In Automotivementioning

confidence: 99%

Critical Review on Nanofluids: Preparation, Characterization, and Applications

Jama

Singh

Gamaleldin

et al. 2016

Journal of Nanomaterials

121

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Heat transfer fluids are a crucial parameter that affects the size and costs of heat exchangers. However, the available coolants like water and oils have low thermal conductivities, which put many limitations to the development of heat transfer to achieve high performance cooling. The need for development of new classes of fluids which enhance the heat transfer capabilities attracted the attention of many researchers. In the last few decades, modern nanotechnology developed nanoparticles, which have unique thermal and electrical properties that could help improve heat transfer using nanofluids. A “nanofluid” is a fluid with suspended fine nanoparticles which increases the heat transfer properties compared with the original fluid. Nanofluids are considered a new generation of heat transfer fluids and are considered two-phase fluids of liquid solid mixtures. The efficiency of the fluid could be improved by enhancing its thermal properties, especially the thermal conductivity, and it is expected that the nanofluids will have a greater thermal conductivity than the base fluids. This paper reviews the preparation of metallic and nonmetallic nanofluids along with the stability of the produced nanofluids. Physical and thermal properties as well as a range of applications are also discussed in detail.

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Section: Nanofluids In Automotivementioning

confidence: 99%

Critical Review on Nanofluids: Preparation, Characterization, and Applications

Jama

Singh

Gamaleldin

et al. 2016

Journal of Nanomaterials

121

View full text Add to dashboard Cite

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Critical analysis of thermal conductivity enhancement of alumina–water nanofluids

Iqbal

Kouloulias

Sergis

et al. 2023

J Therm Anal Calorim

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Nanofluids are colloidal suspensions constituted of nanoparticles and typical heat transfer fluids which have shown potential in yielding enhanced heat transport for many applications. Significant attention has been paid to their thermal conductivity enhancement which has been alleged, in some cases, to exceed theoretical limits classifying the enhancement as “anomalous”. The present study aims to quantitatively investigate the nature of the enhancements reported in the literature and classify their alignment with theoretical predictions. To do so, a rigorous and objective mathematical analysis method has been employed. The novelty and value of the present work lies in the deeper characterisation and understanding of the anomalous observations reported. The present analytical study focuses on (spherical) Al2O3–water nanofluids. It was discovered that studies involving low nanoparticle concentrations ($$\phi $$ ϕ ≤ 0.2 vol%) and the use of electrostatic stabilisation (through pH control) as opposed to steric stabilisation (using surfactants) as suspension stability control methods are likely to report anomalous effects. An exceptional case was observed for d < 15 nm, where to achieve anomalous enhancement, surfactants and pH controllers should not be used to prevent significant interfacial resistance. The shared characteristics of these anomalous observations indicate that nanofluid preparation effects are linked to the underlying physical mechanisms of heat transfer involved and those should be further investigated. The failure of studies attempting to replicate anomalous thermal conductivity enhancement in the literature could hence be understood, as these did not satisfy the conditions required to lead to an anomalous enhancement. The role of measurement errors was also considered.

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