Authors: Khaleel Sami Hamdan, Dong-Eok Kim, Sang-Ki Moon

Abstract:

An appropriate model to predict the size of the droplets resulting from the break-up with the structures will help in a better understanding and modeling of the two-phase flow calculations in the simulation of a reactor core loss-of-coolant accident (LOCA). A droplet behavior impacting on a hot surface above the Leidenfrost temperature was investigated. Droplets of known size and velocity were impacted to an inclined plate of hot temperature, and the behavior of the droplets was observed by a high-speed camera. It was found that for droplets of Weber number higher than a certain value, the higher the Weber number of the droplet the smaller the secondary droplets. The COBRA-TF model over-predicted the measured secondary droplet sizes obtained by the present experiment. A simple model for the secondary droplet size was proposed using the mass conservation equation. The maximum spreading diameter of the droplets was also compared to previous correlations and a fairly good agreement was found. A better prediction of the heat transfer in the case of LOCA can be obtained with the presented model.

Keywords: Break-up, droplet, impact, inclined hot plate, Leidenfrost temperature, LOCA.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092340

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References:

[1] M. J. Holowach, L. E. Hochreiter, J. H. Mahaffy, F. B. Cheung, "Modeling of Droplet Entrainment Phenomena at a Quench Front,” International Journal of Heat and Fluid Flow 24 (2003), 902-918.
[2] Y. Guo, K. Mishima, "A non-equilibrium Mechanistic Heat Transfer Model for Post-Dryout Dispersed Flow Regime,” Experimental Thermal and Fluid Science 26 (2006), 861-869.
[3] S. M. Bajorek, and M. Y. Young, "Direct-Contact Heat Transfer Model for Dispersed-Flow Film Boiling,” Nuclear Technology 2000; 132:375-388.
[4] A. J. Ireland, L. E. Hochreiter, and F-B. Cheung, "Droplet Size and Velocity Measurements in a Heated Rod Bundle,” The 6th ASME-JSME Thermal engineering Joint Conference, March 16-20, 2003.
[5] L. H. J. Watchters, N. A. J. Westerling, "The Heat Transfer from a Hot Wall to Impinging Water Drops in the Spheroidal State,” Chemical Engineering Science, 1966, Vol.21, pp. 1047-1056.
[6] S-C. Yao, K-Y Ci`a, "The Dynamics and Leidenfrost Temperature of Drops Impacting on a Hot Surface at Small Angles,” Experimental Thermal and Fluid Science 1988; 1:363-371.
[7] A. Karl, A. Frohn, "Experimental Investigation of Interaction Processes Between Droplets and Hot Walls,” Phys. Fluids, Vol. 12, No 4, April 200.
[8] T. Udea, T. Enomoto and M. Kanetsuki, "Heat Transfer Characteristics and Dynamic Behavior of Saturated Droplets Impinging on a Heated Vertical Surface,” Bulletin of the japan society of mechanical engineers, Vol, 22 No.167, pp. 724-732.
[9] C. Weber, Z. Angew. "Zum Zerfall eines Flussigkeitstahles,” Mech. 11, 136-155, 1931.
[10] "Analysis of FLECHT-SEASET 163-Rod Blocked Bundle Data Using COBRA-TF,” NRC/EPRI/Westinghouse Report No. 15, October 1985.