Vibration response analysis of mobile liquid Pb-Bi micro-reactors under transportation with liquid sloshing

• Published in: Nuclear engineering and design Vol. 423; p. 113190
• Main Authors: Fan, Tiandi, Zhang, Yong, Yang, Guowei, Song, Yong, Jiang, Jieqiong, zhou, Tao
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2024
• Subjects: Fluid-structure interaction; Lead-bismuth eutectic; Liquid sloshing effect; Mobile micro-reactor; Transport vibration; Transport vibration; Mobile micro-reactor; Lead-bismuth eutectic; Fluid-structure interaction; Liquid sloshing effect
• ISSN: 0029-5493
• DOI: 10.1016/j.nucengdes.2024.113190

•Sloshing effects of the mobile reactors with the liquid metal coolant under transportation was founded.•Evaluation of the effects of transportation vibrations on the solidification of LBE.•Evaluation the varying length of the internal in reactor to suppress the vibrations. Mobile micro-reactors, which used the liquid lead–bismuth eutectic (LBE) as coolants, providing energy to remote regions had become a popular topic in nuclear energy due to their desirable characteristics, including inherent safety and modularity. However, the liquid sloshing effect in a reactor may exhibit fluid–structure interaction (FSI) coupling effects, which could have a significant impact on the relevant internal systems. And the ratio of coolant in liquid to solid form was correlated with the duration of heat dissipation. This paper aimed to investigate the liquid sloshing effect in a micro-reactor that was subject to vehicle vibrations, the objective was to provide recommendations for transportation scenarios involving various liquid sloshing. To achieve this, a full-vehicle dynamic model of the system was developed using multi-body dynamics. Additionally, MATLAB simulation software was utilized to simulate the road roughness loadings that the micro-reactor may encounter during transportation. Moreover, a finite element numerical model of the Mobile Micro-reactor had been developed in order to simulate the sloshing effect that occurred during transportation, the numerical models presented in this study were validated by comparing them with a previously-verified Housner model that involved a cylindrical tank. This study investigated the sloshing effects of the Mobile Micro-reactor under different liquid–solid ratios of coolant, internal component lengths, and liquid surface heights. The results indicated that the internal components within the reactor vessel can alleviate the sloshing effect. The solid ratios of liquid lead–bismuth coolant and the liquid surface height during transportation had an impact on the sloshing effect. These findings provided valuable insights for studying the sloshing response of on-board reactors during liquid sloshing transportation.