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H. Hieronymus, Ph. Henschen, M. Hofmann, J. Bender, R. Wendler, J. Steinbach, B. Plewinsky (2001)
Hazards of surface explosions
Y. Nikolaev, D. Zak (1988)
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Thermodynamic Properties of Individual Substances
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Surface Detonations and Indirect Ignition Processes
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Thermodynamic Properties of GasesIndustrial & Engineering Chemistry, 38
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An approximate calculation of the isentrope of a gas in chemical equilibriumCombustion, Explosion and Shock Waves, 31
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Characterization of surface explosionsArch Combustionis, 21
Y. Nikolaev, P. Fomin (1982)
Analysis of equilibrium flows of chemically reacting gasesCombustion, Explosion and Shock Waves, 18
S. Frolov, B. Gel’fand, A. Borisov (1985)
Simple model of detonation in a gas-film system with consideration of mechanical fuel removalCombustion, Explosion and Shock Waves, 21
P. Fomin, K. Mitropetros, H. Hieronymus, J. Steinbach (2002)
Modelling of detonation wave parameters, initiation and hazard of chemically active bubble systemsJournal De Physique Iv, 12
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Transport phenomena with drops and bubbles
FA Williams (1985)
Combustion theory
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Modeling of detonation processes in chemically active bubble systems at normal and elevated initial pressuresJournal of Loss Prevention in The Process Industries, 16
J. Burgoyne, L. Cohen (1954)
The effect of drop size on flame propagation in liquid aerosolsProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 225
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K. Mitropetros, P. Fomin, J. Steinbach, B. Plewinsky, H. Hieronymus (2004)
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Interaction of a liquid film with a high-velocity gas flow behind a shock waveCombustion, Explosion and Shock Waves, 20
Y. Nikolaev, P. Fomin (1983)
Approximate equation of kinetics in heterogeneous systems of the gas-condensed-phase typeCombustion, Explosion and Shock Waves, 19
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Explosions Near the Surface of Organic LiquidsProcess Safety and Environmental Protection, 83
K. Mitropetros, H. Hieronymus, J. Steinbach, B. Plewinsky (2002)
Shock induced ignitions of oxygen bubbles in cyclohexane under normal conditions
Y. Nikolaev, P. Fomin (1984)
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In safety engineering, one position of interest inside heterogeneous systems of the type liquid–gas is the contact surface between these two phases. Under certain conditions, e.g. shock wave impact, phenomena can take place at this position that can have a significant influence on the explosion behavior of the system. In this work an investigation is presented about the existence of such phenomena on the surface of liquid cyclohexane with or without the existence of oxygen containing bubbles. The observations have been performed during the time before, as well as after, a detonation wave reflection on that surface. High-speed pressure and optical measurements have been applied. Apart from the experimental observations, also a theoretical analysis and discussion is presented in this contribution, which contains the comparison between calculated and experimental values.
Experiments in Fluids – Springer Journals
Published: Dec 8, 2005
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