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Título:
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Impact of the self-adaptive valve behavior on an array of microfluidic cells under unsteady and non-uniform heat load distributions
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Autor/a:
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Laguna Benet, Gerard; Vilarrubí, Montse; Ibáñez, Manuel; Rosell Urrutia, Joan Ignasi; Badia Pascual, Ferran; Azarkish, Hassan; Collin, Louis-Michel; Fréchette, L. G.; Barrau, Jérôme
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Notas:
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Selected papers from 17th International Days on Heat Transfer (JITH-2017), 2017
Previous studies have demonstrated that the performance of a cooling scheme based on a matrix of microfluidic cells with self-adaptive valves under unsteady and non-uniform heat load scenarios improves in terms of pumping power and temperature uniformity, compared to the ones from conventional microchannels and hybrid jet impingement/microchannel cooling devices. The behavior of the thermally dependent self-adaptive valves varies as a function of some design parameters. In this work, the impact of the valve’s characteristic curve on the cooling device is assessed to establish the basic rules for the valve design. The performance of a 3×3 microfluidic cell array is numerically studied under an unsteady and non-uniform heat load scenario. The results show that the valves which open at the most elevated temperature (control temperature of 90ºC) reduce by 15.5% the pumping power with respect to the valves opening at 60ºC, while improving by 25.0% the temperature uniformity and reducing both the overcooling and the fatigue.
The research leading to these results has been performed within the STREAMS project (www.project-streams.eu) and received funding from the European Community's Horizon 2020 program under Grant Agreement n° 688564. |
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Materia(s):
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-Adaptive cooling
-Temperature uniformity
-Distributed cooling
-Pumping power |
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Derechos:
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cc-by-nc-nd, (c) Laguna et al., 2019
http://creativecommons.org/licenses/by-nc-nd/4.0/
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Tipo de documento:
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Artículo
Artículo - Versión publicada |
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Editor:
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Regional Information Center for Science and Technology
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