Molten core materials may relocate to the lower head of a reactor vessel in the latter stages of a severe accident. Under such circumstances, in-vessel retention (IVR) of the molten materials is a vital step in mitigating potential severe accident consequences. Whether IVR occurs depends on the interactions of a number of complex processes including heat transfer inside the accumulated molten pool, heat transfer from the molten pool to the reactor vessel (and to overlying fluids), and heat transfer from exterior vessel surfaces. SCDAP/RELAP5-3D© has been developed at the Idaho National Engineering and Environmental Laboratory to facilitate simulation of the processes affecting the potential for IVR, as well as processes involved in a wide variety of other reactor transients. In this paper, current capabilities of SCDAP/RELAP5-3D© relative to IVR modeling are described and results from typical applications are provided. In addition, anticipated developments to enhance IVR simulation with SCDAP/RELAP5-3D© are outlined.
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10th International Conference on Nuclear Engineering
April 14–18, 2002
Arlington, Virginia, USA
Conference Sponsors:
- Nuclear Engineering Division
ISBN:
0-7918-3597-9
PROCEEDINGS PAPER
In-Vessel Retention Modeling Capabilities of SCDAP/RELAP5-3D©
D. L. Knudson,
D. L. Knudson
Idaho National Engineering and Environmental Laboratory, Idaho Falls, ID
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J. L. Rempe
J. L. Rempe
Idaho National Engineering and Environmental Laboratory, Idaho Falls, ID
Search for other works by this author on:
D. L. Knudson
Idaho National Engineering and Environmental Laboratory, Idaho Falls, ID
J. L. Rempe
Idaho National Engineering and Environmental Laboratory, Idaho Falls, ID
Paper No:
ICONE10-22754, pp. 1121-1129; 9 pages
Published Online:
March 4, 2009
Citation
Knudson, DL, & Rempe, JL. "In-Vessel Retention Modeling Capabilities of SCDAP/RELAP5-3D©." Proceedings of the 10th International Conference on Nuclear Engineering. 10th International Conference on Nuclear Engineering, Volume 3. Arlington, Virginia, USA. April 14–18, 2002. pp. 1121-1129. ASME. https://doi.org/10.1115/ICONE10-22754
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