Experimental analysis of helium bubble-driven flow for enhanced natural circulation in passive molten salt fast reactor
- Authors
- Choi, Won Jun; Hyeon, Seung Gyu; Park, Jae Hyung; Song, JinHo; Kim, Sung Joong
- Issue Date
- Jan-2026
- Publisher
- Elsevier BV
- Keywords
- Bubble-driven flow; Experimental studies; Helium bubbling; Natural circulation; Passive molten salt fast reactor
- Citation
- Nuclear Engineering and Design, v.446, pp 1 - 15
- Pages
- 15
- Indexed
- SCIE
SCOPUS
- Journal Title
- Nuclear Engineering and Design
- Volume
- 446
- Start Page
- 1
- End Page
- 15
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/209410
- DOI
- 10.1016/j.nucengdes.2025.114553
- ISSN
- 0029-5493
1872-759X
- Abstract
- A helium bubbling system is proposed for the Passive Molten salt Fast Reactor to remove insoluble fission products that could accelerate local corrosion and perturb reactivity. This process also induces bubble-driven flow, which enhances heat transfer efficiency and consequently elevates the target thermal power in naturally circulating systems. Thus, a comprehensive understanding of two-phase flow, particularly bubble-driven dynamics, is essential and requires well-designed experimental investigations. However, experimental studies on bubble-driven flow under diverse conditions remain limited, especially those utilizing helium as the dispersed phase. Thus, this study experimentally evaluated bubble-driven flow under adiabatic conditions, focusing on helium injection. The variations in key thermal-hydraulic parameters, including liquid velocity and void fraction, were analyzed with respect to hydraulic diameter, liquid viscosity, gas types, and superficial gas velocity. High-speed visualization captured bubble behavior, revealing strong bubble interactions such as coalescence and break-up. In the narrow channel, longer slugs were observed more frequently due to enhanced wake entrainment. Notably, a significant transition in liquid velocity was observed near a superficial gas velocity of 0.055 m/s at 8 mPa & sdot;s viscosity, likely due to competing viscous and inertial forces. In all cases, helium improved natural circulation performance by at least 4% compared to air, attributed to its lower density.
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