Design and Fabrication of a Phase Change Material Heat Storage Device for the Thermal Control of Electronics Components of Space Applications

Garmendia, Iñaki; Vallejo, Haritz; Seco, Miguel; Anglada, Eva

doi:10.3390/aerospace9030126

Cited by 22 publications

(3 citation statements)

References 17 publications

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“…Recent advances in spacecraft thermal control have been significant in both passive and active devices. 181,182 Research on passive components includes phase change materials for heat storage to reduce radiator size, 183 materials, such as graphene and aerosols, 184 and multifunctional nanostructure surfaces that modulate the emissivity and absorptivity to optimize the thermal performance. 185 Miniaturization of active thermal devices, such as cryocoolers 181 and pumped fluid loops for small satellites, 186 will be also relevant for future FSOC systems.…”

Section: Future Workmentioning

confidence: 99%

Opto-thermo-mechanical phenomena in satellite free-space optical communications: survey and challenges

Badás,

Piron,

Bouwmeester

et al. 2023

Opt. Eng.

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Growing interest in free-space optical communication, due to the high bandwidth and security provided by these links, has generated the necessity of designing high-performance satellite terminals. In order to develop these terminals, the optothermo-mechanical phenomena that appear in the space environment and their effect on optical communication links have to be understood in detail. A review of the opto-thermo-mechanical phenomena occurring in spaceborne terminals is presented, describing the relevance of each of them. The methods found to compute the impact on the communication performance due to opto-thermo-mechanical phenomena are collected by building the bridge between the optical and communication performance parameters. Finally, techniques available to mitigate the detrimental effects of these phenomena are classified, and the relevant research challenges are identified.

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Section: Future Workmentioning

confidence: 99%

Opto-thermo-mechanical phenomena in satellite free-space optical communications: survey and challenges

Badás,

Piron,

Bouwmeester

et al. 2023

Opt. Eng.

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“…The use of PCMs, therefore, opens the possibility of new passive thermal control devices and energy storage applications. Examples of current relevance can be found in different technological fields ranging from manufacturing [2], food storage [3] and net-zero energy buildings [4,5] to renewable energies [6], electronics [7,8] and space exploration [9,10].…”

Section: Introductionmentioning

confidence: 99%

Preliminary Design of a Space Habitat Thermally Controlled Using Phase Change Materials

Kachalov

Sánchez

Martínez

et al. 2023

Thermo

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We explore the preliminary design of a space habitat thermally controlled using phase change materials (PCMs). The PCM is used to maintain a suitable, habitable temperature inside the habitat by isolating it from the external solar radiation. The system is studied numerically considering only diffusive heat transport (conduction), a scenario with practical application to microgravity or reduced gravity environments. The system dynamics are explored for a wide range of governing parameters, including the length of the PCM cell L, the thermo-optical properties—absorptivity α and emissivity ε—at the external boundary of the habitat wall exposed to solar radiation, the eclipse (illumination) fraction τe (τi) of the solar cycle, and the PCM used. We find that the thermo-optical properties at the external radiated boundary, characterized by the absorptivity–emissivity ratio (α/ε), play a key role in the system response and largely define the optimal design of the habitat. This optimum balances the heat absorbed and released by the PCM during repeated illumination and eclipse cycles.

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“…Phase change materials (PCM) can absorb/release large amounts of latent heat near the isothermal range. Thus, PCM-based thermal storage technologies are widely used in solar photothermal power generation [1], low-temperature refrigeration [2], building HVAC [3], thermal management of electric vehicles [4], and spacecraft thermal control [5,6]. Both organic PCMs and low melting point alloys can be used for thermal management.…”

Section: Introductionmentioning

confidence: 99%

Comparative Study of the Thermal Enhancement for Spacecraft PCM Thermal Energy Storage Units

et al. 2022

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To access the enhancement effect of the topology optimization and porous foam structure, numerical studies were conducted to investigate the heat conduction enhancement (by metal foam, graphite foam, topologically optimized fins, and combinations of metal foam and topologically optimized fins) of phase change material (PCM (n-octadecane)) based tubular thermal energy storage unit for spacecraft. The results showed that metal foam performed better than topologically optimized fins and a combination of metal foam and topology optimized fins, of which conductive material, unit mass, and volume fraction of PCM were the same. Graphite foam (140 W/(m·K)) had the best heat transfer enhancing effect, making PCM melt much faster than other enhancing methods investigated. A multi-criteria decision-making (MCDM) method integrated with the combined weight and TOPSIS method was introduced to evaluate the preferred alternatives’ performance based on the energy storage time, equivalent density, and energy storage. The evaluation pointed out that 3% topologically optimized aluminum fins with 98% copper foam had the best comprehensive performance. This study guided the optimal design of latent heat thermal energy storage units for spacecraft under microgravity.

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Design and Fabrication of a Phase Change Material Heat Storage Device for the Thermal Control of Electronics Components of Space Applications

Cited by 22 publications

References 17 publications

Opto-thermo-mechanical phenomena in satellite free-space optical communications: survey and challenges

Opto-thermo-mechanical phenomena in satellite free-space optical communications: survey and challenges

Preliminary Design of a Space Habitat Thermally Controlled Using Phase Change Materials

Comparative Study of the Thermal Enhancement for Spacecraft PCM Thermal Energy Storage Units

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