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attributable to a combination of melt retention in the reactor cavity and melt droplet removal within the Surtsey vessel prior to complete transfer of thermal energy and prior to complete chemical reaction. The calculational procedure leads to prediction of the pressure and tem- perature responses of the containment vessel, along with additional parame- ters such as mass of oxygen remaining, chemical energy release, droplet and gas velocities and temperatures, etc. These additional quantities will be presented in the paper along with comparisons with actual experimental data (if 'available). References 1. Ginsberg, T., and N. K. Tutu, "DHCVIM - A Direct Heating Containment Vessel Interactions Module," to be presented at 1987 ASME National Heat Transfer Conference, Pittsburgh, PA (August 1987).
Ginsberg, T. & Tutu, N.K.DHCVIM: A direct heating containment vessel interactions module: Applications to Sandia National Laboratory Surtsey experiments,
article,
January 1, 1987;
Upton, New York.
(https://digital.library.unt.edu/ark:/67531/metadc1110033/m1/4/:
accessed April 25, 2024),
University of North Texas Libraries, UNT Digital Library, https://digital.library.unt.edu;
crediting UNT Libraries Government Documents Department.