References
- C. Rabe, J. Malet, and F. Feuillebois, “On the Influence of Droplet Coalescence in Spray Systems for Containment Safety,” Proc. 13th Int. Topl. Mtg. Nuclear Reactor Thermal Hydraulics (NURETH-13), Kanazawa City, Japan, September 27–October 2, 2009.
- M. Arai and M. Saito, “Atomization Characteristics of Jet-to-Jet and Spray-to-Spray Impingement Systems,” Atom. Sprays, 9, 399 (1999).
- T. Chiba et al., “Inter-Spray Impingement of Two Diesel Sprays,” Proc. Int. Conf. Liquid Atomization and Spray Systems (ICLASS), Pasadena, California, July 16–20, 2000.
- G. H. Ko and H. S. Ryou, “Droplet Collision Processes in an Inter-Spray Impingement System,” J. Aerosol Sci., 36, 1300 (2005).
- A. A. Mostafa and H. C. Mongia, “On the Modelling of Turbulent Evaporating Sprays: Eulerian Versus Lagrangian Approaches,” Int. J. Heat Mass Transfer, 30, 2583 (1987).
- J. B. Greenberg, I. Silverman, and Y. Tambour, “On the Origin of Spray Sectional Conservation Equations,” Combustion Flame, 93, 90 (1993).
- F. Laurent, M. Massot, and P. Villedieu, “Eulerian Multi-Fluid Modeling for the Numerical Simulation of Coalescence in Polydisperse Dense Liquid Sprays,” J. Comput. Phys., 194, 505 (2004).
- P. Villedieu and J. Hylkema, “Une méthode particulaire aléatoire reposant sur une équation cinétique pour la simulation numérique des sprays denses de gouttelettes liquides,” Comptes Rendus de l’Académie des Sciences de Paris, 325, Série I, 323 (1997).
- R. O. Fox, F. Laurent, and M. Massot, “Numerical Simulation of Spray Coalescence in an Eulerian Framework: Direct Quadrature Method of Moments and Multi-Fluid Method,” J. Comput. Phys., 227, 3058 (2008).
- D. Wunsch, “Theoretical and Numerical Study of Collision and Coalescence—Statistical Modeling Approaches in Gas-Droplet Turbulent Flows,” PhD Thesis, University of Toulouse (2010).
- N. Ashgriz and J. Y. Poo, “Coalescence and Separation in Binary Collisions of Liquid Drops,” J. Fluids Mech., 221, 183 (1990).
- J. P. Estrade, “Experimental Investigation of Dynamic Binary Collision of Ethanol Droplets—A Model for Droplet Coalescence and Bouncing,” Int. J. Heat Fluid Flow, 20, 486 (1999).
- C. Rabe, J. Malet, and F. Feuillebois, “Experimental Investigation of Water Droplet Binary Collisions and Description of Outcomes with a Symmetric Weber Number,” Phys. Fluids, 22, 047101 (2010).
- N. Roth et al., “Droplet Collision Outcomes at High Weber Number,” Proc. 21st Conf. Institute for Liquid Atomization and Spray Systems (ILASS), Mugla, Turkey, September 10–12, 2007.
- W. D. Bachalo and M. J. Houser, “Phase Doppler Spray Analyzer for Simultaneous Measurements of Drop Size and Velocity Distributions,” Opt. Eng., 23, 583 (1984).
- A. Foissac et al., “Droplet Size and Velocity Measurements at the Outlet of a Hollow-Cone Spray Nozzle,” Atom. Sprays, 21, 893 (2011).
- S. Mimouni et al., “Modelling of Sprays in Containment Applications with a CMFD Code,” Nucl. Eng. Des., 240, 9, 2260 (2010).
- O. Simonin, “Combustion and Turbulence in Two-Phase Flows,” von Karman Institute for Fluid Dynamics, Lecture Series, 1996–2002 (1996).
- L. I. Zaichik, O. Simonin, and V. M. Alipchen-Kov, “Two Statistical Models for Predicting Collision Rates of Inertial Particles in Homogeneous Isotropic Turbulence,” Phys. Fluids, 15, 2995 (2003).
- O. Simonin, “Prediction of the Dispersed Phase Turbulence in Particle-Laden Jets,” Proc. 4th Int. Symp. Gas-Solid Flows, ASME FED, Vol. 121, p. 197, ASME Fluids Engineering Division (1991).
- J. Pozorski and J. P. Minier, “Probability Density Function Modelling of Dispersed Two-Phase Turbulent Flows,” Phys. Rev. E, 59, 855 (1999).
- A. Foissac, “Modélisation des interactions entre gouttes en environnement hostile,” PhD Thesis, University of Paris VI (2011).
- F. Pigeonneau and F. Feuillebois, “Collision and Size Evolution of Drops in Homogeneous Isotropic Turbulence,” J. Aerosol Sci., 49, S1279 (1998).
- G. Patino-Palacios and O. Simonin, “General Derivation of Eulerian-Eulerian Equations for Multiphase Flows,” Institut de Mécanique des Fluides Toulouse (2003).
- A. Foissac et al., “Binary Water Droplet Collision Study in Presence of Solid Aerosols in Air,” Proc. 7th Int. Conf. Multiphase Flow (ICMF), Tampa, Florida, May 30–June 4, 2010.
- G. E. Cossali, “An Integral Model for Gas Entrainment into Full Cone Sprays,” J. Fluids Mech., 439, 353 (2001).
- J. Malet et al., “Numerical Study on the Influence of Simplified Spray Boundary Conditions for the Characterisation of Large Industrial Safety Spray Systems Used in Nuclear Reactors,” Proc. Int. Conf. Atomication and Spray Systems (ICLASS 2012), Heidelberg, Germany, September 2–6, 2012.
- J. Malet et al., “Gas Entrainment by One Single French PWR Spray, SARNET-2 Spray Benchmark,” Proc. 15th Int. Topl. Mtg. Nuclear Reactor Thermalhydraulics (NURETH-15), Pisa, Italy, May 12–16, 2013 (submitted for publication).