A general analytical model for the design of conventional heat pipes

Lips, Stéphane; Lefèvre, Frédéric

doi:10.1016/j.ijheatmasstransfer.2013.12.068

Cited by 22 publications

(13 citation statements)

References 26 publications

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“…The Young-Laplace equation has been previously used to determine the maximum heat transfer rate of FMHPs using the capillary limit [5][6][7][8]10,26]. However, previous research did not consider whether the maximum surface temperature of FMHPs at the maximum heat transfer rate exceeded the allowable maximum temperature of the electronic components, which is crucial for ensuring the longevity of these components.…”

Section: Theoretical Approach For Maximum Heat Transfer Rate Of Fmhpsmentioning

confidence: 99%

“…In recent years, continuous improvements in thermal management technology for electronic devices, such as tablet PCs, smart-phones, and various kinds of mobile electronic devices, have been developed to meet the increasingly higher heat flux requirements due to their dramatic reduction in size [1][2][3]. 1 One solution that has been devised by researchers [1,[4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22] to meet the high heat flux duty is flat-micro heat pipes (hereafter FMHPs). FMHPs have a thickness of less than 1 mm; however, there are several challenges in developing devices at this scale.…”

Section: Introductionmentioning

confidence: 99%

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Effect of mesh wick geometry on the maximum heat transfer rate of flat-micro heat pipes with multi-heat sources and sinks

Subedi

Kim

Jang

et al. 2019

International Journal of Heat and Mass Transfer

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This paper presents a theoretical investigation of the thermal characteristics of flat-micro heat pipes (FMHPs) with multi-heat sources and sinks. Analytical solutions of the pressure and the temperature distributions of FMHPs with multi-heat sources and sinks were obtained based on the modified liquid pressure drop. The solutions were used to identify the key engineering parameters of a mesh wick with microscale length that affect the maximum heat transfer rate of the FMHPs with multi-heat sources and sinks. The effects of the key engineering parameters on the maximum heat transfer rate of the FMHPs were presented for two limits. The first limit is the capillary limit and the other is the allowable maximum temperature limit which is used to ensure that the maximum surface temperature of the FMHP with the maximum heat transfer rate calculated at the capillary limit does not exceed the allowable maximum temperature of the electronic components. Finally, the theoretically results for the optimized wick structure for the corresponding maximum heat transfer rate and the surface temperature distribution of the FMHP were compared for the capillary limit only and for the maximum temperature limit cases, respectively.

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Section: Theoretical Approach For Maximum Heat Transfer Rate Of Fmhpsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effect of mesh wick geometry on the maximum heat transfer rate of flat-micro heat pipes with multi-heat sources and sinks

Subedi

Kim

Jang

et al. 2019

International Journal of Heat and Mass Transfer

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“…The basic assumptions are two-dimensional, constant material properties, constant saturation temperature and linear temperature profile across the structure of the wick. -Conduction in wall [9] The non-dimensional temperature, heat flux and coordinates can be defined as:…”

Section: Heat Pipe Configurations and Associated Equationsmentioning

confidence: 99%

“…A second axis of very important work, these last years, consists in designing the chips in a more effective way compared to thermal dimension. Thermal models can thus be integrated into DK-like with the tools of floorplaning for an either electronic or thermoelectric design [4][5][6][7][8][9][10]:.…”

Section: Introductionmentioning

confidence: 99%

Study of Miniaturization of a Silicon Vapor Chamber for Compact 3D Microelectronics, via a Hybrid Analytical and Finite Element Method

Shirazy

Struss

et al. 2019

TNC

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The interest in silicon vapor chambers (SVCs) has increased in the recent years as they have been identified as efficient cooling systems for microelectronics. They present the advantage of higher thermal conductivity and smaller form factor compared to conventional heat spreaders. This work aims to investigate the potential miniaturization of these devices, preliminary to integration on the backside of mobile device chips, located as close as possible to hotspots. While detailed numerical models of vapor chamber operation are developed, an easy modeling with low computational cost is needed for an effective parametric study. Based on the study of the operating limits, this paper shows the thinning potential of a water filled micropillar for a device operating below 10 W and identify the corresponding vapour core height, and wick thickness.

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“…Both solutions enable to determine parasitic heat losses through the wick and the evaporator body, the sensible heat given to the liquid flowing through the porous structure as well as the heat dissipated by evaporation at the wick-groove interface. A similar approach was implemented in the case of conventional heat pipes by Lefèvre and Lallemand [10] and later extended by Lips and Lefèvre [11]. These features, coupled with energy balances and thermodynamic relationships in the rest of the LHP, give a simple solution for the operating temperature.…”

Section: Introductionmentioning

confidence: 99%

Complete analytical model of a loop heat pipe with a flat evaporator

Siedel

Sartre

Lefèvre

2015

International Journal of Thermal Sciences

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International audienceA steady-state analytical model has been developed to determine the thermohydraulic behaviour of a loop heat pipe with a flat evaporator. Its main originality lies in the combination of energy balance equations for each component of the system with 2D analytical solutions for the temperature field in the evaporator. Based on Fourier series expansion, heat transfer in the wick as well as in the evaporator casing are accurately modelled, enabling a thorough consideration of the parasitic heat fluxes. The model is based on the thermal contact resistance between the wick and the casing, the thermal conductivity of the wick and the accommodation coefficient. This analytical method offers a simple solution that can be implemented in LHP design analysis without the need of large computational resources. A sensitivity analysis has been carried out to evaluate the influence of several parameters on the LHP behaviour. The results show that the main parameters of the model are independent. Therefore, they could be experimentally determined using an appropriate test bench with only few temperature measurements. The model has been validated with a set of experimental data from the literature. A good agreement is found between the theoretical and the experimental results

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A general analytical model for the design of conventional heat pipes

Cited by 22 publications

References 26 publications

Effect of mesh wick geometry on the maximum heat transfer rate of flat-micro heat pipes with multi-heat sources and sinks

Effect of mesh wick geometry on the maximum heat transfer rate of flat-micro heat pipes with multi-heat sources and sinks

Study of Miniaturization of a Silicon Vapor Chamber for Compact 3D Microelectronics, via a Hybrid Analytical and Finite Element Method

Complete analytical model of a loop heat pipe with a flat evaporator

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