密闭空间内高压过冷水射流冲击高温铅铋熔池能质传输数值模拟研究

Numerical Simulation of Energy-mass Transfer in High-pressure Sub-cooled Water Jet Impacting High-temperature Lead-bismuth Molten Pool in Confined Space

  • 摘要: 蒸汽发生器传热管破裂(SGTR)事故是铅铋冷却快堆(LFR)最为严重的设计基准事故之一,将导致二回路高压过冷水通过管道破口高速射流注入一回路高温液态铅铋(LBE),强烈的相间热质传输可能引发蒸汽爆炸,严重威胁堆芯结构的完整性。为了揭示SGTR事故现象机理,本文基于VOF多相流模型、LES湍流模型和Lee相变模型,考虑容器内覆盖气体层作用,建立了密闭空间内高压过冷水射流冲击高温LBE多相流动与瞬态传热传质过程的三维数值计算模型,重点分析了过冷水温度及入口压力对射流发展和射流周围环境(即覆盖气体层和LBE区域)的影响。结果表明,典型的射流按相态可分为4个区域,即水-蒸汽过渡区、多相流区、末端水相区和蒸汽斑块区。射流沸腾主要发生在射流中心区域和两侧的相界面上,相变产生的蒸汽夹带残余水相沿着界面从射流的末端向顶部迁移,计算工况下最大沸腾速率通常在喷管出口处,为7 090 kg/(m3·s)。覆盖气体层和LBE区压力与过冷水温度和入口压力均呈正相关,LBE区压力会随着射流发展逐渐增加,同时蒸汽的迁移可能引起LBE区压力发生波动,在4.4 ms时间内在覆盖气体层和LBE区获得的最大压力分别为0.157 MPa和0.351 MPa。本文结果揭示了射流沸腾机理与压力演化特性,为铅铋冷却快堆SGTR事故系统安全评估提供了理论支撑。

     

    Abstract: The steam generator tube rupture (SGTR) accident is one of the most serious design-basis accidents in a lead-bismuth cooled fast reactor (LFR). This results in the injection of high-pressure sub-cooled water from the second loop into the first loop of high-temperature liquid lead-bismuth eutectic (LBE) through the tube rupture at high velocity. The strong interphase heat and mass transfer may trigger a steam explosion, which seriously threatens the structural integrity of the core. In order to investigate the interaction mechanism between a high-pressure sub-cooled water jet and high-temperature LBE, a three-dimensional numerical computational model of the liquid LBE-water-steam multicomponent multiphase flow and the transient heat and mass transfer process of the high-pressure sub-cooled water jet impacting on the high-temperature LBE in a confined space was established. The VOF multiphase flow model, the LES turbulence model, and the Lee phase transition model were employed, considering the role of the covering gas layer in the vessel. The results show that a typical jet can be divided into four zones according to the phase state, i.e., the water-steam transition zone, the multiphase flow zone, the end-water phase zone, and the steam block zone. Jet boiling occurs mainly in the center region of the jet and on both sides of the phase interface. The steam generated by the phase change will entrain the residual water phase migrating along the interface from the end to the top of the jet. The maximum boiling rate under the calculated conditions is usually at the outlet of the nozzle, with a maximum value of 7 090 kg/(m3·s). The pressure of the covering gas layer and the LBE region are positively correlated with both the sub-cooled water temperature and the inlet pressure. The pressure in the LBE region increases gradually as the jet develops, while the migration of steam may cause fluctuations in the pressure of the LBE region. In the 4.4 ms time, the maximum pressures obtained in the covering gas layer and the LBE region are 0.157 MPa and 0.351 MPa, respectively. The results of this paper reveal the jet boiling mechanism and pressure evolution characteristics, providing theoretical support for the safety assessment of the SGTR accident system for LFRs.

     

/

返回文章
返回