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Experimental and Numerical Investigation of Solidification of Gallium in an Initially Emptied Vertical Pipe

Alex Pegarkov, Shawn Somers-Neal, Edgar Matida, Vinh Tang, Tarik Kaya

Nuclear Science and Engineering / Volume 196 / Number 10 / October 2022 / Pages 1161-1171

Technical Paper / dx.doi.org/10.1080/00295639.2022.2067738

Received:November 19, 2021
Accepted:April 15, 2022
Published:August 29, 2022

During a severe power reactor accident, the plant core can melt. The resulting mixture of molten nuclear fuel and other in-core materials is known as corium. For a Canada Deuterium Uranium (CANDU) reactor, the corium is expected to settle at the bottom of the calandria vessel, but there is a potential for some melt to flow through connecting piping and other penetrations. The flow of corium through these structures can be contained if melt solidification and thus plugging occur. A numerical model was created to simulate the flow of molten metal through an empty vertical pipe. This model was benchmarked to a previous analytical model and validated against experimental results with gallium metal (which is a metal with low melting temperature) as an alternative for corium. The numerical model predicted the penetration length of gallium with an average percent error of 10.3% when compared to the experimental penetration length results of gallium. The model was also updated to predict the corium penetration length in cooling pipes of the CANDU reactor during a severe accident.