Development of a numerical simulation method for air cooling of fuel debris by JUPITER

IF 0.4 Q4 ENGINEERING, MECHANICAL
Susumu YAMASHITA, Shinichiro UESAWA, Ayako ONO, Hiroyuki YOSHIDA
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引用次数: 1

Abstract

A detailed evaluation for air cooling of fuel debris in actual reactors will be essential in fuel debris retrieval under dry conditions. To understand the heat transfer in and around fuel debris, which is assumed as a porous medium in the primary containment vessel (PCV) mechanistically, we newly applied the porous medium model to the multiphase and multicomponent computational fluid dynamics code named JUPITER (JAEA Utility Program for Interdisciplinary Thermal-hydraulics Engineering and Research). We applied the Darcy–Brinkman model as for the porous medium model. This model has high compatibility with JUPITER because it can treat both a pure fluid and a porous medium phase simultaneously in the same manner as the one-fluid model in multiphase flow simulation. We addressed the case of natural convection with a high-velocity flow standing out nonlinear effects by implementing the Forchheimer model, including the term of the square of the velocity as a nonlinear effect to the momentum transport equation of JUPITER. We performed some simple verification and validation simulations, such as the natural convection simulation in a square cavity and the natural convective heat transfer experiment with the porous medium, to confirm the validity of the implemented model. We confirmed that the result of JUPITER agreed well with these simulations and experiments. In addition, as an application of the updated JUPITER, we performed the preliminary simulation of air cooling of fuel debris in the condition of the Fukushima Daiichi Nuclear Power Station unit 2 including the actual core materials. As a result, JUPITER calculated the temperature and velocity field stably in and around the fuel debris inside the PCV. Therefore, JUPITER has the potential to estimate the detailed and accurate thermal-hydraulics behaviors of fuel debris.
木星燃料碎片空气冷却数值模拟方法的发展
在干燥条件下的燃料碎片回收中,对实际反应堆中燃料碎片的空气冷却进行详细的评估是必不可少的。为了从力学上理解作为多孔介质的燃料碎片在主安全壳(PCV)内部和周围的传热,我们将多孔介质模型应用于多相多组分计算流体动力学程序JUPITER (JAEA跨学科热工水力学工程与研究实用程序)。对于多孔介质模型,我们采用了Darcy-Brinkman模型。该模型可以像多相流模拟中的单流体模型一样,同时处理纯流体和多孔介质相,与JUPITER具有较高的兼容性。采用Forchheimer模型,将速度的平方项作为木星动量输运方程的非线性效应,解决了自然对流中高速流动突出的非线性效应。通过方腔自然对流模拟和多孔介质自然对流换热实验等简单的验证和验证仿真,验证了所实现模型的有效性。我们证实,木星的结果与这些模拟和实验非常吻合。此外,作为升级版JUPITER的应用,我们对福岛第一核电站2号机组工况下包括实际堆芯材料的燃料碎片进行了空气冷却的初步模拟。结果,木星稳定地计算了PCV内部燃料碎片内部和周围的温度和速度场。因此,木星有可能估算燃料碎片的详细和准确的热工力学行为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Mechanical Engineering Journal
Mechanical Engineering Journal ENGINEERING, MECHANICAL-
自引率
20.00%
发文量
42
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