Pulsating Heat Pipe in Hypergravity Conditions

Mameli, Mauro; Manzoni, Miriam; Araneo, L.; Filippeschi, Sauro; Marengo, Marco

doi:10.1615/heatpipescietech.2016013605

Cited by 8 publications

(2 citation statements)

References 8 publications

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“…Ma et al [5] in 2011 conducted experiments using a rotating table. The performance did not change up to a maximum acceleration of 10 g. Mameli et al [6] and Ayel et al [7] in 2015 tested the PHP during parabolic flight campaigns. They noted that hyper-gravity conditions of up to 2 g, resulted in the prevention of thermal instabilities after applying micro-gravity conditions.…”

Section: Introductionmentioning

confidence: 99%

Geometrical Shape of Pulsating Heat Pipe under Hyper Gravity Condition

Czajkowski¹,

Pietrowicz²,

Kassai³

et al. 2022

Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering

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The paper concerns a heat transfer characteristics for a pulsating heat pipe (PHP) under hyper-gravity condition. Two loops of pulsating heat pipe with the internal diameter of 1.5 mm were filled and tested with HFE-7000 as a working fluid. The experimental setup allows for the investigation of two crucial parameters affecting the thermal process i.e. rotational speed (acceleration from 1 to 8g) and filling ratio (44 and 66, %). As a result, the dependences of the thermal resistance on the rotational speeds were obtained, thus declaring the optimal conditions for the heat transport process. The increase in filing ratio (FR) of the working fluid in hyper-gravity condition improves the thermal efficiency of PHP, as well as the direction of the evaporation section bending.

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Section: Introductionmentioning

confidence: 99%

Geometrical Shape of Pulsating Heat Pipe under Hyper Gravity Condition

Czajkowski¹,

Pietrowicz²,

Kassai³

et al. 2022

Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering

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“…Varying the effects of gravity on the OHP orientation has become one of the popular topics in the recent investigations (Mameli et al, 2014;Mameli et al, 2015;Ayel et al, 2015;Mangini et al 2017). The results of such studies show that both gravity and heat input level influence the device operation.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of a Large Scale-oscillating Heat Pipe at Different Inclinations

Winarta

Putra²,

Koestoer³

et al. 2019

IJTech

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As a family of heat pipes, oscillating heat pipes have many additional unique operating parameters. This paper examined the heat transfer characteristics of an oscillating heat pipe that has an effective length (leff) of 500 mm and uses methanol as the working fluid. The effective length of 500 mm is not typically used in previous experimental setups. This structural dimension of the oscillating heat pipe is widely used as a heat recovery device. The heat pipe was tested with various heat supplies and inclinations. The results show that the inclination makes a substantial contribution to the heat transfer capability for large scale heat pipes. Decreasing the degree of inclination reduces the capability of the heat pipe in handling the heat load. Reducing the inclination also decreases the oscillatory motion, which is an obvious "heat carrier" from the evaporator to the condenser.

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Advanced numerical method for a thermally induced slug flow: application to a capillary closed loop pulsating heat pipe

Manzoni

Mameli

Falco

et al. 2016

Numerical Methods in Fluids

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Summary An advanced hybrid lumped parameter code for the simulation of Pulsating Heat Pipes is developed. Being able to simulate transient operative conditions and removing common physical simplified assumptions, it represents a step forward with respect to the present models of passive two‐phase systems. Mass, momentum and energy balances account for the thermal and fluid‐dynamics phenomena. Heterogeneous and homogeneous phase changes are directly integrated. In addition, a fitting correlation for the wall/vapour heat transfer coefficient is implemented and tuned against experimental data in order to evaluate the influence of the liquid film on conjugate heat transfer. The resulting numerical tool have been validated against experimental data achieved testing a copper pulsating heat pipe during the 58th ESA Parabolic Flight Campaign in several operative conditions and transient gravity levels. The predicted results show very good matching with the actual thermo‐physical behaviour of the system. Copyright © 2016 John Wiley & Sons, Ltd.

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Pulsating Heat Pipe in Hypergravity Conditions

Cited by 8 publications

References 8 publications

Geometrical Shape of Pulsating Heat Pipe under Hyper Gravity Condition

Geometrical Shape of Pulsating Heat Pipe under Hyper Gravity Condition

Experimental Investigation of a Large Scale-oscillating Heat Pipe at Different Inclinations

Advanced numerical method for a thermally induced slug flow: application to a capillary closed loop pulsating heat pipe

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