Roles of surfactants and particle shape in the enhanced thermal conductivity of TiO2 nanofluids

Yang, Linjun; Chen, Xielei; Xu, Mengkai; Du, Kai

doi:10.1063/1.4962659

Cited by 28 publications

(12 citation statements)

References 35 publications

(34 reference statements)

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“…There are a few available thermal conductivity models for nanofluids with surfactants. Thus, there is a great need to state new thermal conductivity models to describe the effect of surfactants on the thermal conductivity of the nanofluids [91].…”

Section: A Surfactants Effect On Nanofluids Thermal Conductivitymentioning

confidence: 99%

Effect of Surfactant Addition on the Nanofluids Properties: A Review

Jehhef¹,

Siba²

2019

Acta mech. Malays.

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The applications and usage of surfactants in the field of nanofluids heat transfer and its stability were performed the present literature review. The usage of surfactants has been employed for the following areas of nanofluids study: nanofluid heat transfer, nanofluid agglomeration and nanofluid enhancement stability. Generally, a few interesting has been achieved to study the effects of using the surfactants on the nanofluids properties such as pH, thermal conductivity, specific heat, electrical conductivity, viscosity and stability mechanism of nanofluid. The using nanofluid in real applications is taken into consideration by two key issues emerge: erosion and settlement but there aare possible difficulties related to these issues that need to be studied and solved prior to the using of nanofluid in commercial applications. In addition, this paper summarizes the theoretical and experimental studies on the effects of applied various types of surfactants in nanofluids. This work can serve as a ready reference for application of surfactants in nanofluids.

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Section: A Surfactants Effect On Nanofluids Thermal Conductivitymentioning

confidence: 99%

Effect of Surfactant Addition on the Nanofluids Properties: A Review

Jehhef¹,

Siba²

2019

Acta mech. Malays.

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“…e particle volume concentration ϕ in (7), (11), and (12) is considered distribution inhomogeneity in the flow. In order to obtain the distribution of ϕ in the flow, it is necessary to solve the general dynamics equation for nanorods:…”

Section: General Dynamics Equation Formentioning

confidence: 99%

“…Although many researchers have reviewed lots of measured experimental data and demonstrated that particle shape plays an important role on convective heat transfer characteristic of nanofluids [10,11], few models can be found in literatures proposed for nanofluid flow containing nonspherical nanoparticles. Nanorods, as well as nanotubes, nanofibers, and nanobelts are used more and more for nanofluid preparation because of larger aspect ratio and surface area compared with spherical nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

“…By considering the thickness and thermal conductivity of the interfacial nanolayer, Jiang et al [24] proposed a model which provides good predictions for the effective thermal conductivity of CNTbased nanofluids. Other existing models are summarized by Yang et al [11], and three similar theoretical models are proposed for nanofluids with finite cylindrical particles by anisotropy analysis [25][26][27]. All of the three models give minimal relative errors to experimental results compared to other models.…”

Section: Introductionmentioning

confidence: 99%

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Numerical Research on Convective Heat Transfer and Resistance Characteristics of Turbulent Duct Flow Containing Nanorod-Based Nanofluids

Yuan

Lin

2018

Journal of Nanotechnology

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A coupled numerical model for nanorod-based suspension flow is constructed, and the convective heat transfer and resistance characteristics of the nanofluid duct flow are investigated.e numerical results are verified by experimental results and theoretical models. Most of nanorods are located randomly in the bulk fluid, while particles near the wall aligned with the flow direction. Friction factor of nanofluids with nanorods increases with higher particle volume concentration or aspect ratio, but the increment reduces when the Reynolds number gets larger. e relative Nusselt number is obtained to characterize the intensity of convective heat transfer. e results show that the Nusselt number of nanofluids increases when the particle volume concentration or aspect ratio becomes larger. Compared to increasing the aspect ratio of nanorods, increasing the particle volume concentration would be more effective on enhancing the convective heat transfer intensity in industrial applications although it will cause a slight increase of resistance.

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“…The classical models mainly considered the influences of nanoparticle's concentration and the thermal conductivity of the particles and base fluid, such as Maxwell model [49], Bruggeman model [51] etc. Other factors such as particle shape [61], Brownian motion, nanoparticles' aggregation [62] or clustering [63] and interfacial layer [64] between particle and liquid are also considered in the some other theoretical studies. Those models in Table 3 are mainly used for the spherical particles or nanotube based nanofluids and a few models are proposed specifically for CNTs nanofluids.…”

Section: Theoretical Investigationsmentioning

confidence: 99%