Thermal analysis of Al<sub>2</sub>O<sub>3</sub>/water nanofluid-filled micro heat pipes

Gan, Jie Sheng; Hung, Yew Mun

doi:10.1039/c5ra01492a

Cited by 11 publications

(4 citation statements)

References 38 publications

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“…In particular, the cooling of modern electronic devices requires a suitable configuration for high-performance devices with reduced-size because heat loads and heat fluxes increase exponentially [5,6]. In light of the continued miniaturization of electronic components, micro heat pipes are promising micro-scale cooling devices and their operation is sustained by two-phase heat transfer and capillary forces [7]. Therefore, capillary-based flows can replace electric pumps that consume space Appl.…”

Section: Introductionmentioning

confidence: 99%

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

et al. 2021

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Capillary-driven action is an important phenomenon which aids the development of high-performance heat transfer devices, such as microscale heat pipes. This study examines the capillary rise dynamics of n-butanol/water mixture in a single vertical capillary tube with different radii (0.4, 0.6, and 0.85 mm). For liquids, distilled water, n-butanol, and their blends with varying concentrations of butanol (0.3, 0.5, and 0.7 wt.%) were used. The results show that the height and velocity of the capillary rise were dependent on the tube radius and liquid surface tension. The larger the radius and the higher the surface tension, the lower was the equilibrium height (he) and the velocity of rise. The process of capillary rise was segregated into three characteristic regions: purely inertial, inertial + viscous, and purely viscous regions. The early stages (purely inertial and inertial + viscous) represented the characteristic heights h1 and h2, which were dominant in the capillary rise process. There were linear correlations between the characteristic heights (h1, h2, and he), tube radius, and surface tension. Based on these correlations, a linear function was established between each of the three characteristic heights and the consolidated value of tube radius and surface tension (σL/2πr2).

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Section: Introductionmentioning

confidence: 99%

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

et al. 2021

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“…and Hung[33], however, intro-386 duced an equation for calculating the latent heat of a nanofluid,387 incorporating the volume fraction of the nanoparticles and the den-388 sities of both the nanofluid and base fluid using a lever rule.The average heat transfer coefficient between the condenser 390 surface and cooling water is calculated separately in cases of lam-391 inar and turbulent flow regimes as follows.…”

mentioning

confidence: 99%

“…The heat pipe is divided into two heat carriers; evaporator and condenser. An 33 energy balance for each carrier is carried out to estimate temperatures, heat transfer coefficients, thermal 34 resistances, time constants, and other thermal characteristics at three different heat loads; 500, 1000, and 35 1500 W. Governing equations of the transient behavior can be simplified into first-order linear ordinary 36 differential equations, which can be solved by the linear algebra formalism method yielding the heat-pipe 37 temperatures. The transient response of a gravity-assisted heat pipe is found to depend mainly on the 38 average evaporator thermal resistance.…”

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confidence: 99%

Effect of operating parameters on the transient behavior of gravity-assisted heat-pipe using radio-chemically prepared Al 2 O 3 nano-fluid

Abdelaziz

Ali

Elkhatib

et al. 2016

Advanced Powder Technology

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“…Micro heat pipe – a microscale electronics cooling device, has received considerable interests among the thermal management community. In view of the demanding needs for electronics cooling and advances in miniaturization of electronic components, micro heat pipe manifests itself to be a very promising candidate for effective cooling of electronic equipment, because of its high reliability, efficiency and cost-saving features (Babin et al , 1990; Suman, 2009; Liu and Chen, 2013; Gan and Hung, 2015; Sun et al , 2017; Qu et al , 2017; Ye et al , 2018; Yoon and Kim, 2018; Chen et al , 2019; Wang et al , 2019). Micro heat pipe is a heat transfer device with extremely high thermal conductance.…”

Section: Introductionmentioning

confidence: 99%

Gravitational effects on electroosmotic flow in micro heat pipes

Chang

Hung

2019

HFF

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Purpose This paper aims to investigate the coupled effects of electrohydrodynamic and gravity forces on the circulation effectiveness of working fluid in an inclined micro heat pipe driven by electroosmotic flow. The effects of the three competing forces, namely, the capillary, the gravitational and the electrohydrodyanamic forces, on the circulation effectiveness of a micro heat pipe are compared and delineated. Design/methodology/approach The numerical model is developed based on the conservations of mass, momentum and energy with the incorporation of the Young–Laplace equation for electroosmotic flow in an inclined micro heat pipe incorporating the gravity effects. Findings By inducing electroosmotic flow in a micro heat pipe, a significant increase in heat transport capacity can be attained at a reasonably low applied voltage, leading to a small temperature drop and a high thermal conductance. However, the favorably applied gravity forces pull the liquid toward the evaporator section where the onset of flooding occurs within the condenser section, generating a throat that shrinks the vapor flow passage and may lead to a complete failure on the operation of micro heat pipe. Therefore, the balance between the electrohydrodyanamic and the gravitational forces is of vital importance. Originality/value This study provides a detailed insight into the gravitational and electroosmotic effects on the thermal performance of an inclined micro heat pipe driven by electroosmotic flow and paves the way for the feasible practical application of electrohydrodynamic forces in a micro-scale two-phase cooling device.

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Thermal analysis of Al₂O₃/water nanofluid-filled micro heat pipes

Abstract: The comparison of heat transport capacity and the thermal resistance as the performance indicators provides valuable insights into the underlying physical significance of the use of a nanofluid on the performance of micro heat pipes.

Cited by 11 publications

References 38 publications

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

Effect of operating parameters on the transient behavior of gravity-assisted heat-pipe using radio-chemically prepared Al 2 O 3 nano-fluid

Gravitational effects on electroosmotic flow in micro heat pipes

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Thermal analysis of Al2O3/water nanofluid-filled micro heat pipes

Abstract: The comparison of heat transport capacity and the thermal resistance as the performance indicators provides valuable insights into the underlying physical significance of the use of a nanofluid on the performance of micro heat pipes.

Cited by 11 publications

References 38 publications

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

Effects of Tube Radius and Surface Tension on Capillary Rise Dynamics of Water/Butanol Mixtures

Effect of operating parameters on the transient behavior of gravity-assisted heat-pipe using radio-chemically prepared Al 2 O 3 nano-fluid

Gravitational effects on electroosmotic flow in micro heat pipes

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Thermal analysis of Al₂O₃/water nanofluid-filled micro heat pipes