Assessment of Debris Bed Formation Characteristics Following Core Melt Down Scenario With Simulant System

Harvey, J. K.; Narayanan, KS; Das, Sanjay; Rao, E. V. H. M.; Lydia, G.; Malarvizhi, B.; Murthy, S. Srinivasa; Kumaresan, M.; Kasinathan, N.; Rajan, M.

doi:10.1115/icone16-48172

Cited by 7 publications

(4 citation statements)

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“…en, the gas-injection method was further employed in the three-dimensional (3D) large-scale self-leveling experiments at Kyushu University, JAEA, and Xi'an Jiao Tong University to diminish the wall effect as well as extend the parametric range (e.g., gas flow rate) for extrapolating the experimental data and findings [32][33][34][35][36][37][38][39][40]. However, recognizing that the debris beds are probably composed of solid fragments and particles with varying sizes and porosities in the hypothetical CDAs of SFR through the interaction between melt and coolant [11,41], various particle components, such as single-size non-spherical particles as well as mixed particles (i.e., mixed-density, mixed-size, and mixed-shape particles), were subsequently applied to form the particle beds for the large-scale macroscopic self-leveling experiments [38-40, 42, 43].…”

Section: Gas-injection Induced Leveling Experimentsmentioning

confidence: 99%

Debris Bed Self-Leveling Mechanism and Characteristics for Core Disruptive Accident of Sodium-Cooled Fast Reactor: Review of Experimental and Modeling Investigations

Xu¹,

Cheng²

2022

Science and Technology of Nuclear Installations

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Evaluations of the Core Disruptive Accident (CDA) are significantly important for safety analysis of Sodium-cooled Fast Reactor (SFR) despite the very low probability of occurrence for CDA. During the material-relocation phase in CDA of SFR, the molten materials are possibly released from the core region into subcooled sodium, subsequently forming the debris bed on the lower part of the reactor vessel after being quenched and fragmented. The accumulated high-temperature debris with decay heat can cause sodium coolant boiling, leading to the so-called “debris bed self-leveling behavior” during which the shape of the debris bed becomes flattered (leveling). It is important to investigate the debris bed self-leveling behavior due to its potential capacity to induce the transfer of debris and affect the ability of cooling and criticality of the debris bed. Thus, in recent years, valuable knowledge concerning the mechanism and characteristics of this behavior was accumulated through lots of experimental results and modeling developments. Aimed at providing a valuable guideline for future investigations on this issue, in this study, the past experimental and modeling investigations on debris bed self-leveling mechanism and characteristics are systematically summarized and reviewed, and some future remarks are also proposed to promote the progression of further research for SFR severe accident analysis.

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Section: Gas-injection Induced Leveling Experimentsmentioning

confidence: 99%

Debris Bed Self-Leveling Mechanism and Characteristics for Core Disruptive Accident of Sodium-Cooled Fast Reactor: Review of Experimental and Modeling Investigations

Xu¹,

Cheng²

2022

Science and Technology of Nuclear Installations

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“…During the past decades, studies focusing on heat transfer within debris beds were performed [32][33][34][35][36][37][38][39][40][41]. In these investigations, in general, the initial debris bed shape was supposed to be homothetically piled [37], cylindrical [38], heap-like [40,41], and Gaussianshaped [39] or conical [16,[42][43][44].…”

Section: Introductionmentioning

confidence: 99%

Characteristics and Mechanisms of Debris Bed Formation Behavior in Severe Accidents of Sodium-Cooled Fast Reactors: Experimental and Modeling Studies

Cheng

2023

Applied Sciences

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A Sodium-cooled Fast Reactor (SFR) is one of the optimized candidates in Generation IV nuclear reactor systems, but safety is an essential issue for SFR development and application. Most knowledge was accumulated through SFR safety investigations, especially for Core Disruptive Accidents (CDAs). During the CDA of SFRs, the molten materials in the core region are likely to discharge into subcooled sodium and form a debris bed on the lower region of the reactor vessel. Noticing that elaboration on the characteristics and mechanisms of Debris Bed Formation (DBF) behavior should be essential for the subsequent analysis of debris bed coolability and accident progression through various experimental and modeling studies, much knowledge was obtained during the past decades. Motivated to promote future investigations on CDAs of SFRs, the previous experiments and modeling studies on DBF behavior are systematically reviewed and discussed in this paper. The experimental results showed that the flow-regime and accumulated-bed characteristics during DBF were influenced by varying parameters and realistic conditions. Through the modeling studies, several empirical models were proposed for predicting the flow regime and accumulated-bed characteristics in DBF. In addition, to promote further development of research, the future prospects concerning DBF behavior are also described.

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“…A 92-mm long nozzle is attached at the lower part of the funnel with its lower end 720 mm from the debris tray (i.e., particle collector plate). The tray has an area of 1104 cm 2 and is located at the bottom of the vessel. The lower end of the nozzle was immersed in the water column of the vessel by maintaining water levels 105 mm above the release point of the nozzle.…”

Section: Experimental Conditions and Geometriesmentioning

confidence: 99%

“…Over the past decades, many researchers have studied the interactions between molten fuel and coolant. They mostly focused on the jet breakup characteristics [2][3][4] jet fragmentation and premixing -and on the debris formation processes [5]. However, there are very little exper- * Corresponding author.…”

Section: Introductionmentioning

confidence: 99%

Numerical study on sedimentation behavior of solid particles used as simulant fuel debris

Shamsuzzaman

Zhang

Horie

et al. 2014

Journal of Nuclear Science and Technology

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This paper presents numerical simulations using the discrete element method (DEM) to model sedimentation behavior of solid debris particles, which is significant for estimates of the coolability of debris beds. A series of experiments of gravity driven discharge of solid particles into a quiescent water pool was used to validate the DEM simulation method. We evaluated the effects of three crucial factors: particle density, particle diameter, and nozzle diameter on three key quantitative parameters: particle dispersion angle, particle fall time in the pool, and the height of the deposited particle bed to express the particle sedimentation behavior. The three crucial factors play a significant role in the particle sedimentation behavior. We compared the experimental and simulated results of the particle dispersion angle and particle fall time in the pool, and the height and shape of the deposited particle bed. The general trend of the simulation results indicates a reasonable agreement with the experimental observations. The simulations exhibit the potential applicability of the DEM-based simulation technique for the prediction of particle sedimentation behavior.

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Assessment of Debris Bed Formation Characteristics Following Core Melt Down Scenario With Simulant System

Cited by 7 publications

References 0 publications

Debris Bed Self-Leveling Mechanism and Characteristics for Core Disruptive Accident of Sodium-Cooled Fast Reactor: Review of Experimental and Modeling Investigations

Debris Bed Self-Leveling Mechanism and Characteristics for Core Disruptive Accident of Sodium-Cooled Fast Reactor: Review of Experimental and Modeling Investigations

Characteristics and Mechanisms of Debris Bed Formation Behavior in Severe Accidents of Sodium-Cooled Fast Reactors: Experimental and Modeling Studies

Numerical study on sedimentation behavior of solid particles used as simulant fuel debris

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