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Combustion Science and Technology Volume 76, 1991 - Issue 1-3
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Original Articles

The Influence of Transport Properties on Droplet Burning

ISHWAR K. PURI Department of Applied Mechanics and Engineering Sciences, University of California San Diego, La Jolla, California, 92093
&
PAUL A. LIBBY Department of Applied Mechanics and Engineering Sciences, University of California San Diego, La Jolla, California, 92093
Pages 67-80 | Received 06 Jul 1990, Accepted 06 Nov 1990, Published online: 06 Apr 2007

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John Sisti & PaulE. DesJardin. (2013) A semi-analytical, multizone model of droplet combustion with varying properties. Combustion Theory and Modelling 17:4, pages 657-681.
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Chia-Hung Wang & Ta-Hui Lin. (2013) A compound drop in a hot inert environment. Journal of the Chinese Institute of Engineers 36:2, pages 137-145.
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G. S. JACKSON & C. T. AVEDISIAN. (1996) Modeling of Spherically Symmetric Droplet Flames Including Complex Chemistry: Effect of Water Addition on n-Heptane Droplet Combustion. Combustion Science and Technology 115:1-3, pages 125-149.
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Articles from other publishers (15)

Anand Sankaranarayanan, Sohan Lal, Irishi Namboothiri, Arindrajit Chowdhury & Neeraj Kumbhakarna. (2021) Combustion characteristics of novel bishomocubane propellants in oxygen-enriched environments. Fuel 305, pages 121508.
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Hiroshi Nomura, Shinji Nakaya & Mitsuhiro Tsue. 2020. High-Pressure Flows for Propulsion Applications. High-Pressure Flows for Propulsion Applications 1 47 .
Shinji Nakaya, Kotaro Fujishima, Mitsuhiro Tsue, Michikata Kono & Daisuke Segawa. (2013) Effects of droplet diameter on instantaneous burning rate of isolated fuel droplets in argon-rich or carbon dioxide-rich ambiences under microgravity. Proceedings of the Combustion Institute 34:1, pages 1601-1608.
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Etim S. Udoetok. (2012) Modified Quasi-Steady Fuel Droplet Combustion Model. Journal of Combustion 2012, pages 1-8.
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Shinji Nakaya, Daisuke Segawa, Toshikazu Kadota, Yoshiaki Nagashima & Tomoya Furuta. (2011) Combustion behaviors of isolated n-decane and ethanol droplets in carbon dioxide-rich ambience under microgravity. Proceedings of the Combustion Institute 33:2, pages 2031-2038.
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Vedha Nayagam. (2010) Quasi-steady flame standoff ratios during methanol droplet combustion in microgravity. Combustion and Flame 157:1, pages 204-205.
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Vedha Nayagam, Anthony J. Marchese & Kurt R. Sacksteder. 2008. Progress in Scale Modeling. Progress in Scale Modeling 169 178 .
X. Mercier, M. Orain & F. Grisch. (2007) Investigation of droplet combustion in strained counterflow diffusion flames using planar laser-induced fluorescence. Applied Physics B 88:1, pages 151-160.
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S. Ulzama & E. Specht. (2007) An analytical study of droplet combustion under microgravity: Quasi-steady transient approach. Proceedings of the Combustion Institute 31:2, pages 2301-2308.
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L. P. Yarin & G. HetsroniL. P. Yarin & G. Hetsroni. 2004. Combustion of Two-Phase Reactive Media. Combustion of Two-Phase Reactive Media 1 298 .
Andrei Kazakov, Jordan Conley & Frederick L. Dryer. (2003) Detailed modeling of an isolated, ethanol droplet combustion under microgravity conditions. Combustion and Flame 134:4, pages 301-314.
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. (1997) The effect of initial diameter in spherically symmetric droplet combustion of sooting fuels. Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences 446:1927, pages 255-276.
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G. JACKSON & C. AVEDISIAN. (1993) Experiments on the effect of initial diameter in spherically symmetric droplet combustion of sooting fuels. Experiments on the effect of initial diameter in spherically symmetric droplet combustion of sooting fuels.
N.-H. Chen & B. Rogg. 1993. Instabilities in Multiphase Flows. Instabilities in Multiphase Flows 149 160 .
N.-H. Chen, B. Rogg & K.N.C. Bray. (1992) Modelling laminar two-phase counterflow flames with detailed chemistry and transport. Symposium (International) on Combustion 24:1, pages 1513-1521.
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