Microgravity Fluids and Combustion Research at NASA Glenn Research Center
Publication: Journal of Aerospace Engineering
Volume 26, Issue 2
Abstract
At the dawn of the Space Age, the design of early rocket and spacecraft systems presented significant challenges because of the low-gravity environment of space. Motivated by these challenges, the National Aeronautics and Space Administration (NASA) Glenn Research Center (GRC) pioneered the development of low-gravity facilities—including drop towers, sounding rockets, zero-gravity (zero-g) aircraft, and most importantly, space-based facilities—to advance microgravity research to further the nation’s space exploration efforts. These efforts resulted in improved spacecraft system designs and practices in areas as diverse as fluid handling and spacecraft fire safety. At the same time, researchers realized that the microgravity environment allows the study of fundamental combustion and fluid physics problems, without the complication of buoyancy-induced convection. Microgravity testing enabled advancements in areas of technological and ecological importance in terrestrial applications such as global atmospheric change, combustor design, groundwater pollution, oil production, and advanced materials manufacturing, which often rely on advances in fluid physics and chemically reacting flows. GRC has been a leader in microgravity fluid physics and combustion research for more than 50 years. This paper highlights the facilities and some of the many accomplishments.
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Acknowledgments
The authors thank Fred J. Kohl, ISS Research Project Manager at NASA GRC, for his wealth of information about the early days of microgravity fluids management through the current ISS microgravity research program. The success of this paper was also made possible by GRC researchers John B. McQuillen and Enrique Ramé, who contributed information regarding microgravity fluids experiments performed in GRC’s drop towers, zero-g aircraft, the Space Shuttle, and the ISS. The members of GRC's micorgravity combustion science and reacting systems branch are gratefully acknowledged for details regarding the history and accomplishments in microgravity combustion science. Finally, the authors acknowledge Robert S. Arrighi (Wyle Information Systems) from the NASA Glenn History Office for providing significant historical documentation about the zero-g drop tower facilities and aircraft.
References
Banu, B. (2008). “Fluids and combustion facility (FCF) and combustion integrated rack (CIR).” Payload accomodations handbook CIR-DOC-4064, NASA Glenn Research Center, Cleveland.
Busse, J. R., and Leffler, M. T. (1966). “A compendium of Aerobee sounding rocket launches from 1959 to 1963.” TR-R-226, NASA, Greenbelt, MD.
Chato, D. J. (2006). “The role of flight experiments in the development of cryogenic fluid management technologies.” TM-2006-214261, NASA, Cleveland.
Concus, P., and Finn, R. (1969). “On the behavior of a capillary surface in a wedge.” Proc. Natl. Acad. Sci. USA, 63(2), 292–299.
DeLombard, R., and Acevedo, J. (1998). “Space Acceleration Measurement System (SAMS) in Mir.” Investigation 8.8.1/SAMS Summary Rep., NASA, Cleveland.
Dhir, V. K., et al. (2012). “Nucleate (pool boiling experiments (NPBX) on the International Space Station.” J. Heat Transfer., 24(5), 307–325.
Dietrich, D. L., Haggard, J. B., Dryer, F. L., Nayagam, V., Shaw, B. D., and Williams, F. A. (1996). “Droplet combustion experiments in spacelab.” Proc. Combust. Inst., 26(1), 1201–1207.
Dietrich, D. L., Ross, H. D., Shu, Y., Chang, P., and T’ien, J. S. (2000). “Candle flames in non-buoyant atmospheres.” Combust. Sci. Technol., 156(1), 1–24.
Dukler, A. E., Fabre, J. A., McQuillen, J. B., and Vernon, R. (1988). “Gas-liquid flow at microgravity conditions: Flow patterns and their transitions.” Int. J. Multiph. Flow, 14(4), 389–400.
Friedman, R., and Ross, H. D. (2001). “Microgravity combustion: Fire in free fall.” Chapter 8, Combustion technology and fire safety for human-crew space missions, Academic Press, San Diego, 525–562.
Greenberg, P. S., Klimek, R. B., and Buchele, D. R. (1995). “Quantitative rainbow Schlieren deflectometry.” Appl. Opt., 34(19), 3810–3822.
Greenberg, P. S., and Ku, J. C. (1997a). “Soot volume fraction imaging.” Appl. Opt., 36(22), 5514–5522.
Greenberg, P. S., and Ku, J. C. (1997b). “Soot volume fraction maps for normal and reduced gravity laminar acetylene jet diffusion flames.” Combust. Flame, 108(1–2), 227–230.
Hall, N. R., et al. (2009). Preliminary findings from the SHERE ISS experiment, American Institute of Aeronautics and Astronautics, Reston, VA.
Hegde, U., Zhou, L., and Bahadori, M. Y. (1994). “The transition to turbulence of microgravity gas jet diffusion flames.” Combust. Sci. Technol., 102(1–6), 95–113.
Jaekle, D. E. (1991). Propellant management device conceptual design and analysis: Vanes, American Institute of Aeronautics and Astronautics, Reston, VA.
Lekan, J., Gotti, D. J., Jenkins, A. J., Owens, J. C., and Johnston, M. R. (1996). “User’s guide for the 2.2 second drop tower of the NASA Lewis Research Center.” TM-107090, NASA, Cleveland.
Miller, F. J., Ross, H. D., Kim, I., and Sirignano, W. A. (2000). “Parametric investigations of pulsating flame spread across 1-butanol pools.” Proc. Combust. Inst., 28(2), 2827–2834.
Nayagam, V., et al. (1998). “Microgravity n-heptane droplet combustion in oxygen-helium mixtures at atmospheric pressure.” AIAA J., 36(8), 1369–1378.
Nayagam, V., Dietrich, D. L., Ferkul, P. V., Hicks, M. C., and Williams, F. A. (2012). “Can cool flames support quasi-steady alkane droplet burning?” Combust. Flame, 159(12), 3583–3588.
Olson, S. L., Baum, H. R., and Kashiwagi, T. (1998). “Finger-like smoldering over thin cellulosic sheets in microgravity.” Proc. Combust. Inst., 27(2), 2525–2533.
Olson, S. L., Ferkul, P. V., and T’ien, J. S. (1988). “Near-limit flame spread over a thin solid fuel in microgravity.” Proc. Combust. Inst., 22(1), 1213–1222.
Olson, S. L., Hegde, U., Bhattacharjee, S., Deering, J. L., Tang, L., and Altenkirch, R. A. (2004). “Sounding rocket microgravity experiments elucidating diffusive and radiative transport effects on flame spread over thermally thick solids.” Combust. Sci. Technol., 176(4), 557–584.
Pearlman, H. G., and Ronney, P. D. (1994). “Near-limit behavior of high Lewis-number premixed flames in tubes at normal and low gravity.” Phys. Fluids, 6(12), 4009–4018.
Petrash, D. A., Nussle, R. C., and Otto, E. W. (1963). “Effect of the acceleration disturbances encountered in the MA-7 spacecraft on the liquid-vapor interface in a baffled tank during weightlessness.” TN-D-1577, NASA, Cleveland.
Qi, C., Chen, D., and Greenberg, P. S. (2008). “Fundamental study of a miniaturized mini-disk electrostatic aerosol precipitator for a personal nanoparticle sizer.” Aerosol Sci. Technol., 42(7), 505–512.
Raj, R., et al. (2012). “Pool boiling heat transfer on the International Space Station: Experimental results and model verification.” J. Heat Transfer, 134(10), 101504.
Ronney, P. D., Wu, M. S., Pearlman, H. G., and Weiland, K. J. (1998). “Experimental study of flame balls in space: Preliminary results from STS-83.” AIAA J., 36(8), 1361–1368.
Ross, H. D. (2001). Microgravity combustion: Fire in free fall, combustion treatise, Academic Press, London.
Ross, H. D., and Miller, F. J. (1996). “Detailed experiments of flame spread across deep butanol pools.” Proc. Combust. Inst., 26(1), 1327–1334.
Ruff, G. A., Urban, D. L., Pedley, M. D., and Johnson, P. T. (2009). “Safety design for space systems.” Chapter 27, Fire safety, Elsevier, New York, 829–883.
Siegel, R., and Keshock, E. G. (1964). “Effects of reduced gravity on nucleate boiling bubble dynamics in saturated water.” J. Amer. Inst. of Chem. Eng., 10(4), 509–517.
Urban, D. L., et al. (1998). “Structure and soot properties of nonbuoyant ethylene/air laminar jet diffusion flames.” AIAA J., 36(8), 1346–1360.
Useller, J. W., Enders, J. H., and Haise, F. W., Jr. (1966). “Use of aircraft for zero-gravity environment.” TN-D-3380, NASA, Cleveland.
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© 2013 American Society of Civil Engineers.
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Received: May 7, 2012
Accepted: Nov 7, 2012
Published online: Mar 15, 2013
Published in print: Apr 1, 2013
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