Thermoelectromagnetic Fluid Management in Microgravity

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HART-DISSERTATION-2024.pdf (21.7 MB)
Author(s)
Hart, Samuel T.
Advisor(s)
Romero-Calvo, Alvaro
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Daniel Guggenheim School of Aerospace Engineering
The Daniel Guggenheim School of Aeronautics was established in 1931, with a name change in 1962 to the School of Aerospace Engineering
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https://hdl.handle.net/1853/76933
Abstract
Modern microgravity fluid management is dominated by capillary systems, mechanical pumps, and positive expulsion devices such as bladders. These technologies, either singularly or in combination, are able to achieve the fluid management needs of most space missions. However, in the age of small spacecraft, increasing human spaceflight, and long-term space habitation, there is a desire for smaller, more reliable, and higher-performing fluid management systems. This research proposes and demonstrates the use of thermal phase change and electromagnetic devices to create improved fluid management technologies. The applications of these technologies range from propellant management and life support to heat transfer. This work first proposes several methods of phase separation for saturated or cryogenic fluids in conformal tanks using thermal, capillary, and electromagnetic means. The viability of a thermal phase change fluid management device is then demonstrated in laboratory tests, and the primary factors contributing to its performance are analyzed. Finally, electromagnetic forces are applied to dynamic fluid management in a small-scale cooling loop for spacecraft. An electromagnetic pump is developed and demonstrated in a benchtop prototype loop.
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2024-12-04
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Dissertation
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