Design of a Lunar Solar Wind Volatiles Extraction System
DOI:
https://doi.org/10.17307/wsc.v1i1.100Palabras clave:
fusion reactor, helium extractionResumen
Two devices are being developed as part of a project to demonstrate the extraction of helium-3 and other volatiles from lunar regolith. The first is an implantation system to embed helium ions into JSC-1A lunar regolith simulant and the second is a counter flow heat pipe heat exchanger for the subsequent diffusion of the helium out of the regolith. This will simulate the previously proposed acquisition of helium-3 from the Moon for use in nuclear fusion reactors on Earth. Preliminary designs of both of these systems are discussed.1
Citas
Wittenberg, L. J., "Terrestrial Sources of Helium-3 Fusion Fuel- A Trip to the Center of the Earth," Fusion Technology, vol. 15, 1989.
Wittenberg, L. J., Santarius, J. F., and Kulcinski, G. L., "Lunar Source of He-3 for Commercial Fusion Power," Fusion Technology, vol. 10, 1986, p. 167.
Sviatoslavsky, I. N., and Jacobs, M. K., "Mobile Helium-3 Mining and Extraction System and Its Benifits Toward Lunar Base Self-Sifficiency," Wisconsin Center for Space Automation and Robotics Technical Report (WCSAR-TR) AR3-8808-1, 1988.
Sviatoslavsky, I. N., "The Challenge of Mining He-3 on the Lunar Surface: How All the Parts Fit Together," Space 94, The 4th International Conference and Exposition on Engineering, Construction and Operations in Space, and The Conference and Exposition/Demonstration on Robotics for Challenging Environments, February 26 - March 3, 1994, Albuquerque NM Also: WCS, 1993.
Gajda, M., "A Lunar Volatiles Miner," University of Wisconsin-Madison, M.S. Thesis, 2006.
Schmitt, H. H., "Return to the Moon," Return to the Moon, Praxis, 2005, p. 89.
Olson, A. D. S., "The Mark IV: A Scalable Lunar Miner Prototype," International Astronautical Congress 2013, Beijing, China, IAC-13.A3.2B.7, 2013.
Gibson Jr., E. R., and Johnson, S. M., "Thermal Analysis-Inorganic Gas Release Studies of Lunar Samples," 2nd Lunar Science Conference Vol. 2, 1971, pp. 1351–1366.
Nellis, G., and Klein, S., "Heat Exchangers," Heat Transfer, 2009, p. 857.
Thermacore, "Heat pipe and thermal management solutions, Thermacore," Thermacore.com Available: http://www.thermacore.com/thermal-basics/heat-pipe- technology.aspx.
Yuan, Z. G., and Kleinhenz, J. E., "Gas Phase Pressure Effects on the Apparent Thermal Conductivity of JSC-1A Lunar Regolith Simulant," 41st International Conference on Environmental Systems, 2011, pp. 1750–1757.
http://dx.doi.org/10.2514/6.2011-5138
Deissler, R. G., and Boegli, J. S., "An Investigation of Effective Thermal Conductivities of Powders in Various Gases," Transactions of American Society of Mechanical Engineers, vol. 81, 1958, pp. 1417–1425.
Fan, L. S., and Zhu, C., "Ch.5. Basic Equations," Principles of Gas Solid Flow, 1997, p. 224.
Nellis, G., and Klein, S., "Ch. 5. Internal Forced Convection," Heat Transfer, 2009, p. 686.
Lieberman, M. A., and Lichtenberg, A. J., "Ch. 14. Direct Current (DC) Discharges," Principles of Plasma Discharges and Materials Processing, 2005, p. 545.
Descargas
Publicado
Cómo citar
Número
Sección
Licencia
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.