The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment

J. Porter; A. Laverón-Simavilla; M.M. Bou-Ali; X. Ruiz; F. Gavalda; J.M. Ezquerro; P. Salgado Sánchez; U. Martínez; D. Gligor; I. Tinao; J. Gómez; J. Fernández; J. Rodríguez; A. Borshchak Kachalov; V. Lapuerta; B. Seta; J. Massons; D. Dubert; A. Sanjuan; V. Shevtsova; L. García-Fernández

doi:10.1016/j.actaastro.2023.05.026

The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment

J. Porter
, A. Laverón-Simavilla
, M.M. Bou-Ali
, X. Ruiz
, F. Gavalda
, J.M. Ezquerro
, P. Salgado Sánchez^*
, U. Martínez
, D. Gligor
, I. Tinao
, J. Gómez
, J. Fernández
, J. Rodríguez
, A. Borshchak Kachalov
, V. Lapuerta
, B. Seta
, J. Massons
, D. Dubert
, A. Sanjuan
, V. Shevtsova

L. García-Fernández

^*Corresponding author for this work

Universidad Politécnica de Madrid
Mondragon University
Complutense University
Universidad Rovira i Virgili

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

Present as well as future challenges of space exploration point to the need for improved thermal control systems. The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment, which is approved by ESA for execution on board the International Space Station, aims to contribute directly to current knowledge and basic understanding of heat and mass transport in phase change materials (PCMs) that incorporate a free surface in reduced gravity. The experiment will apply fixed temperatures to opposite ends of PCM samples held in cuboidal and cylindrical containers in order to drive controlled melting and solidification cycles that will be observed by means of optical cameras. The recorded images will be complemented by thermal measurements at key positions along the samples, which will allow different thermocapillary flow regimes to be distinguished according to their temporal dynamics. It is anticipated that thermal Marangoni (thermocapillary) convection will increase the heat transfer rate in these PCM devices by a significant factor (on the order of two or more) compared to melting governed by thermal diffusion (conduction). If the PCM designs prove robust, the experiment results can be expected to lead to substantial improvements in future designs for passive PCM applications in space missions.

Original language	English
Journal	Acta Astronautica
Volume	210
Pages (from-to)	212-223
ISSN	0094-5765
DOIs	https://doi.org/10.1016/j.actaastro.2023.05.026
Publication status	Published - 2023

Keywords

Microgravity
Phase change materials
Thermal control
Thermocapillary effect

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Porter, J., Laverón-Simavilla, A., Bou-Ali, M. M., Ruiz, X., Gavalda, F., Ezquerro, J. M., Salgado Sánchez, P., Martínez, U., Gligor, D., Tinao, I., Gómez, J., Fernández, J., Rodríguez, J., Borshchak Kachalov, A., Lapuerta, V., Seta, B., Massons, J., Dubert, D., Sanjuan, A., ... García-Fernández, L. (2023). The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment. Acta Astronautica, 210, 212-223. https://doi.org/10.1016/j.actaastro.2023.05.026

@article{aafb5d88aef74ee0a71e96c2f16e9384,

title = "The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment",

abstract = "Present as well as future challenges of space exploration point to the need for improved thermal control systems. The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment, which is approved by ESA for execution on board the International Space Station, aims to contribute directly to current knowledge and basic understanding of heat and mass transport in phase change materials (PCMs) that incorporate a free surface in reduced gravity. The experiment will apply fixed temperatures to opposite ends of PCM samples held in cuboidal and cylindrical containers in order to drive controlled melting and solidification cycles that will be observed by means of optical cameras. The recorded images will be complemented by thermal measurements at key positions along the samples, which will allow different thermocapillary flow regimes to be distinguished according to their temporal dynamics. It is anticipated that thermal Marangoni (thermocapillary) convection will increase the heat transfer rate in these PCM devices by a significant factor (on the order of two or more) compared to melting governed by thermal diffusion (conduction). If the PCM designs prove robust, the experiment results can be expected to lead to substantial improvements in future designs for passive PCM applications in space missions.",

keywords = "Microgravity, Phase change materials, Thermal control, Thermocapillary effect",

author = "J. Porter and A. Laver{\'o}n-Simavilla and M.M. Bou-Ali and X. Ruiz and F. Gavalda and J.M. Ezquerro and \{Salgado S{\'a}nchez\}, P. and U. Mart{\'i}nez and D. Gligor and I. Tinao and J. G{\'o}mez and J. Fern{\'a}ndez and J. Rodr{\'i}guez and \{Borshchak Kachalov\}, A. and V. Lapuerta and B. Seta and J. Massons and D. Dubert and A. Sanjuan and V. Shevtsova and L. Garc{\'i}a-Fern{\'a}ndez",

year = "2023",

doi = "10.1016/j.actaastro.2023.05.026",

language = "English",

volume = "210",

pages = "212--223",

journal = "Acta Astronautica",

issn = "0094-5765",

publisher = "Elsevier",

}

Porter, J, Laverón-Simavilla, A, Bou-Ali, MM, Ruiz, X, Gavalda, F, Ezquerro, JM, Salgado Sánchez, P, Martínez, U, Gligor, D, Tinao, I, Gómez, J, Fernández, J, Rodríguez, J, Borshchak Kachalov, A, Lapuerta, V, Seta, B, Massons, J, Dubert, D, Sanjuan, A, Shevtsova, V & García-Fernández, L 2023, 'The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment', Acta Astronautica, vol. 210, pp. 212-223. https://doi.org/10.1016/j.actaastro.2023.05.026

TY - JOUR

T1 - The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment

AU - Porter, J.

AU - Laverón-Simavilla, A.

AU - Bou-Ali, M.M.

AU - Ruiz, X.

AU - Gavalda, F.

AU - Ezquerro, J.M.

AU - Salgado Sánchez, P.

AU - Martínez, U.

AU - Gligor, D.

AU - Tinao, I.

AU - Gómez, J.

AU - Fernández, J.

AU - Rodríguez, J.

AU - Borshchak Kachalov, A.

AU - Lapuerta, V.

AU - Seta, B.

AU - Massons, J.

AU - Dubert, D.

AU - Sanjuan, A.

AU - Shevtsova, V.

AU - García-Fernández, L.

PY - 2023

Y1 - 2023

N2 - Present as well as future challenges of space exploration point to the need for improved thermal control systems. The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment, which is approved by ESA for execution on board the International Space Station, aims to contribute directly to current knowledge and basic understanding of heat and mass transport in phase change materials (PCMs) that incorporate a free surface in reduced gravity. The experiment will apply fixed temperatures to opposite ends of PCM samples held in cuboidal and cylindrical containers in order to drive controlled melting and solidification cycles that will be observed by means of optical cameras. The recorded images will be complemented by thermal measurements at key positions along the samples, which will allow different thermocapillary flow regimes to be distinguished according to their temporal dynamics. It is anticipated that thermal Marangoni (thermocapillary) convection will increase the heat transfer rate in these PCM devices by a significant factor (on the order of two or more) compared to melting governed by thermal diffusion (conduction). If the PCM designs prove robust, the experiment results can be expected to lead to substantial improvements in future designs for passive PCM applications in space missions.

AB - Present as well as future challenges of space exploration point to the need for improved thermal control systems. The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment, which is approved by ESA for execution on board the International Space Station, aims to contribute directly to current knowledge and basic understanding of heat and mass transport in phase change materials (PCMs) that incorporate a free surface in reduced gravity. The experiment will apply fixed temperatures to opposite ends of PCM samples held in cuboidal and cylindrical containers in order to drive controlled melting and solidification cycles that will be observed by means of optical cameras. The recorded images will be complemented by thermal measurements at key positions along the samples, which will allow different thermocapillary flow regimes to be distinguished according to their temporal dynamics. It is anticipated that thermal Marangoni (thermocapillary) convection will increase the heat transfer rate in these PCM devices by a significant factor (on the order of two or more) compared to melting governed by thermal diffusion (conduction). If the PCM designs prove robust, the experiment results can be expected to lead to substantial improvements in future designs for passive PCM applications in space missions.

KW - Microgravity

KW - Phase change materials

KW - Thermal control

KW - Thermocapillary effect

U2 - 10.1016/j.actaastro.2023.05.026

DO - 10.1016/j.actaastro.2023.05.026

M3 - Journal article

SN - 0094-5765

VL - 210

SP - 212

EP - 223

JO - Acta Astronautica

JF - Acta Astronautica

ER -

The “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” experiment

Abstract

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