Initial relocation behavior of control rod materials in boiling water reactors studied via time-resolved visualization

• Published in: Nuclear engineering and design Vol. 333; pp. 99 - 114
• Main Authors: Ueda, Shota, Jo, Byeongnam, Kondo, Masahiro, Erkan, Nejdet, Yajima, Takeshi, Okamoto, Koji
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.07.2018; Elsevier BV
• Subjects: Boiling water reactor; Boiling water reactors; Boron; Boron carbide; Collapse; Control rod; Control rods; Debris; Eutectic melting; Kinetics; Nuclear energy; Nuclear engineering; Nuclear fuels; Nuclear reactors; Powder; Reactors; Relocation; Severe accident; Stainless steel; Thermodynamics; Visualization; Visualization; Control rod; Boiling water reactor; Severe accident; Eutectic melting
• ISSN: 0029-5493; 1872-759X
• DOI: 10.1016/j.nucengdes.2018.04.006

•Relocation behavior of a control rod is studied via dynamic visualization.•Control rod is simulated by a stainless steel tube filled with B4C powder.•Effect of rod geometry on its initial relocation is examined.•Three relocation modes of the obtained eutectic melt are identified. For the Fukushima decommissioning, the distribution of boron species in the fuel debris must be determined to assess the risk of recriticality, the debris hardness and thus complicate its successful retrieval. As a result, the relocation behavior of boron carbide (B4C) control rod materials has attracted significant attention. In this work, the influence of the thickness of its stainless steel (SS) clad on the initial relocation behavior of the control rod was investigated. In particular, the initial relocation behavior of the B4C control rod materials was dynamically visualized using a technique previously developed by the authors. To simulate the control rod, a type-304 SS tube filled with B4C powder containing particles with sizes of approximately 20–30 µm was heated to a temperature exceeding its eutectic point (1473 K). The three relocation modes of the obtained eutectic melt corresponded to film formation, droplet formation without collapse and droplet formation with collapse.