纳米流体钠对SFR中SGTR事故缓解效果的评估

K. Ichikawa, H. Kanda, N. Yoshioka, K. Ara, Jun-ichi Saito, K. Nagai
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引用次数: 0

摘要

基于悬浮在液态钠(纳米流体钠)中的纳米颗粒的概念,对钠本身反应性的抑制进行了研究。根据纳流体研究的理论和实验结果,纳流体与水反应(纳流体/水反应)的速度和热量低于纯钠/水反应。考虑到这些抑制效应,作者建立了钠纳米流体/水反应射流峰值温度的解析模型。本文应用该反应射流峰值温度分析模型,建立了蒸汽发生器爆管事故中相邻管损伤缓解效果的预测方法。假设钠纳米流体作为钠冷快堆(SFR)的二次冷却剂,利用该方法对SFR在设计基础事故(DBA)条件和设计延伸条件(DEC)下的缓解效果进行了评估。研究结果表明,纳米流体钠作为二次冷却剂,有可能减少SGTR事故中损坏管的数量,并抑制事故产生的压力。
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Estimation of Mitigation Effects of Sodium Nanofluid for SGTR Accidents in SFR
Studies on the suppression of the reactivity of sodium itself have been performed on the basis of the concept of suspended nanoparticles in liquid sodium (sodium nanofluid). According to the theoretical and experimental results of studies for sodium nanofluid, velocity and heat of sodium nanofluid reaction with water (sodium nanofluid/water reaction) are lower than those of the pure sodium/water reaction. The analytical model for the peak temperature of a sodium nanofluid/water reaction jet has been developed by the authors in consideration of these suppression effects. In this paper, the prediction method for mitigation effects on damage of adjacent tubes in steam generator tube rupture (SGTR) accidents is developed by applying this analytical model for the peak temperature of the reaction jet. On the assumption that the sodium nanofluid is used for the secondary coolant of sodium-cooled fast reactor (SFR), mitigation effects under the design basis accident (DBA) condition and the design extension condition (DEC) of SGTR are estimated by using this method. The results indicate a clear possibility to reduce the number of damaged tubes and to suppress the pressure generated in SGTR accidents by using sodium nanofluid as the secondary coolant.
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