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http://dx.doi.org/10.5516/NET.2009.41.9.1215

TRIGGERING AND ENERGETICS OF A SINGLE DROP VAPOR EXPLOSION: THE ROLE OF ENTRAPPED NON-CONDENSABLE GASES  

Hansson, Roberta Concilio (Division of Nuclear Power Safety, Royal Institute of Technology AlbaNova Center, Division of Nuclear Power Safety)
Publication Information
Nuclear Engineering and Technology / v.41, no.9, 2009 , pp. 1215-1222 More about this Journal
Abstract
The present work pertains to a research program to study Molten Fuel-Coolant Interactions (MFCI), which may occur in a nuclear power plant during a hypothetical severe accident. Dynamics of the hot liquid (melt) droplet and the volatile liquid (coolant) were investigated in the MISTEE (Micro-Interactions in Steam Explosion Experiments) facility by performing well-controlled, externally triggered, single-droplet experiments, using a high-speed visualization system with synchronized digital cinematography and continuous X-ray radiography. The current study is concerned with the MISTEE-NCG test campaign, in which a considerable amount of non-condensable gases (NCG) are present in the film that enfolds the molten droplet. The SHARP images for the MISTEE-NCG tests were analyzed and special attention was given to the morphology (aspect ratio) and dynamics of the air/ vapor bubble, as well as the melt drop preconditioning. Energetics of the vapor explosion (conversion ratio) were also evaluated. The MISTEE-NCG tests showed two main aspects when compared to the MISTEE test series (without entrapped air). First, analysis showed that the melt preconditioning still strongly depends on the coolant subcooling. Second, in respect to the energetics, the tests consistently showed a reduced conversion ratio compared to that of the MISTEE test series.
Keywords
Fuel-Coolant Interactions; Non-Condensable Gases; Preconditioning; X-ray Radiography;
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1 R. C. Hansson, T.N. Dinh, H.S. Park, “Simultaneous High Speed Digital Cinematographic and X-ray Radiographic Imaging of an Intense Multi-Fluid Interaction with Rapid Phase Changes,” Experimental Thermal and Fluid Sciences, Vol. 33, pp 754-756, 2009   DOI   ScienceOn
2 B. J. Kim, “Oscillatory Behaviors in Initial Film Boiling: Implications on the Triggerability of Single Droplet Vapor Explosions', KSME Journal, 3, 2(1989)   DOI
3 W. Lauterborn, C. D. Ohl, “The Peculiar Behavior of Cavitation Bubbles,” Applied Scientific Research, 58, (1998)   DOI
4 J. Lamône, R. Meignen, “Analysis of the Thermal Fragmentation as a Mechanism for the Initiation of Steam Explosion,” Proceedings of International Congress on Advances in Nuclear Power Plants (ICAPP 7), Nice, France, May 13-18, 2007
5 S. J. Board, C. L. Farmer, D.H. Poole, “Fragmentation in Thermal Explosions,” Int. J. Heat and Mass Transfer, 17, 2(1974)   DOI   ScienceOn
6 M. S. El-Genk, R. B. Matthews, S. G. Bankoff, “Molten-Fuel Coolant Interaction Phenomena with Application to Carbide Fuel Safety,” Progress in Nuclear Energy, 20, 3(1987)   DOI   ScienceOn
7 M. L. Corradini, “Phenomenological Modeling of the Triggering Phase of a Small-Scale Steam Explosion Experiments”, Nucl. Sci. and Eng., 78, (1981)
8 G. Ciccarelli, “Investigation of Vapor Explosions with Single Molten Metal Drops in Water Using Flash X-ray,” Ph.D. Thesis, McGill University, Canada (1991)
9 C. D. Ohl, R. Ikink, “Shock-Induced Jetting of Micron-Size Bubbles,” Physical Review Letters, 90, 21(2003)   DOI   ScienceOn
10 R. P. Taleyarkhan, “Vapor Explosion Studies for Nuclear and Non-Nuclear Industries,” Nucl. Eng. and Design, 235, (2005)   DOI   ScienceOn
11 M. H, Cunningham and D. L.Frost, “Effect of Coolant on the Fragmentation of Single Melt Drops in Water”, Proc. of 8th International Topical Meeting on Nuclear Reactor Thermohydraulics (NURTEH-8), Kyoto, Japan, September 30-October 4, 1997
12 B. Zimanowski, G. röhlich, V. Lorenz, “Nuclear Engineering and Design bu Interaction of Water with Silicate Melts”, Nucl. Eng. and Design, 155, (1995)
13 L. S. Nelson and P. M. Duda, “Steam Explosion Experiments with Single Drops of Iron Oxide Melted with a CO2 Laser,” High Temperature, 14, (1982)
14 D. J. Buchanan, “A Model for Fuel-Coolant Interactions,” J. Phys. D: Appl. Phys., 7, (1974)   DOI   ScienceOn
15 R. C. Hansson, T. N. Dinh, H. S. Park, “Dynamics and Preconditioning in a Single Droplet Vapor Explosion,” Nuclear Technology, Vol. 167, pp 223-234, 2008
16 T. B. Benjamin, A. T. Ellis, “The Collapse of Cavitation Bubbles and the Pressures Thereby Produced Against Solid Boundaries,” Philos. Trans. R. Soc. London, A260, 221(1966)   DOI
17 R. Akiyoshi, S. Nishio and I. Tanasawa, “A Study on the Effect of Non-Condensable Gas in the Vapor Film on Vapor Explosion”, Int. J. Heat Mass Transfer, 33, 4(1990)   DOI   ScienceOn
18 B. J. Kim, M. L. Corradini, “Recent Film Boiling Calculations: Implications on Fuel-Coolant Interactions,” Int. J. Heat Mass Transfer, 29, 8(1986)   DOI   ScienceOn