Thermal hydraulic study of NuScale iPWR passive containment cooling behaviour during loss-of-coolant accident

Thermal hydraulic study of NuScale iPWR passive containment cooling behaviour during loss-of-coolant accident

Operation of the NuScale emergency core cooling system (ECCS) was studied, with an emphasis on the crucial role of the containment vessel (CNV). Design parameters such as vessel volume were varied to explore the resulting thermal hydraulic (TH) behaviour at the system level in the case of a loss-of-...

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Bibliographic Details
Main Authors: Zhexi Guo, Sicong Xiao
Format: Article
Language:English
Published: KeAi Communications Co., Ltd. 2025-06-01
Series:International Journal of Advanced Nuclear Reactor Design and Technology
Subjects:
NuScale
ECCS
ASTEC
LOCA
Containment behaviour
Online Access:http://www.sciencedirect.com/science/article/pii/S2468605025000493
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Summary:Operation of the NuScale emergency core cooling system (ECCS) was studied, with an emphasis on the crucial role of the containment vessel (CNV). Design parameters such as vessel volume were varied to explore the resulting thermal hydraulic (TH) behaviour at the system level in the case of a loss-of-coolant accident (LOCA) initiated by a chemical and volume control system (CVCS) injection line break within the CNV. Results showed that an important phenomenon of concern was core fluid vaporisation, which could be suppressed with smaller vessels to keep system pressure and water levels in the core higher. Break elevation was found to be less significant, unless it were to occur below the reactor recirculation valves (RRV), which would result in backflow into the core and disrupt natural circulation. Increasing nominal power from 160 MW to 250 MW did not result in very different TH phenomena and could be managed by similar CNV designs and properties. Combined effects of a break at high elevation at the higher power of 250 MW appeared to reduce overall in-core vaporisation. Long-term cooling of the system was finally shown to be ensured up to 3 days with monotonously decreasing or constant core void fractions and pressures.
ISSN:2468-6050

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