Development and Validation of the Sub-channel Code for Helical Cruciform Fuel Assembly of PWR
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摘要: 为了开发压水堆螺旋燃料组件(HCF)的子通道程序,本研究将HCF的阻力模型和传热模型引入COBRA-TF程序,通过两组动量方程预测第一类棒间隙的双向交混和第二类棒间隙的单向交混,通过实验数据和数值模拟结果对新程序的准确性进行验证,对HCF的轴向壁面温度分布、质量通量分布等展开分析。研究结果表明,新程序可准确预测HCF的热工参数分布,并且可用于大规模燃料组件的计算和分析。本研究为HCF的优化设计和工程应用提供了可靠的分析工具。
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关键词:
- 螺旋燃料组件(HCF) /
- 子通道程序 /
- 压水堆 /
- 热工水力模型
Abstract: In order to develop the sub-channel code for the helical cruciform fuel (HCF) assembly of PWR, the frictional model and heat transfer model of the HCF assembly is introduced into the COBRA-TF code, the two-way mixing of the first type of rod gap and the one-way mixing of the second type of rod gap is predicted by two groups of momentum equations, the accuracy of new code is validated with the experimental data and numerical simulation results, and the axial distribution of the wall temperature, the mass flux distribution et al. of the HCF assembly are analyzed. According to the study results, the distribution of the thermal-hydraulic parameters of the HCF assembly can be accurately predicted by the new code, and the new code can be used for the calculation and analysis of the large-scale fuel assembly. This study provides a reliable analysis tool for the development and application of the HCF assembly.-
Key words:
- Helical cruciform fuel assembly(HCF) /
- Sub-channel code /
- PWR /
- Thermal-hydraulic model
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图 1 HCF子通道交混模式与棒间隙分类
Figure 1. Sub-channel Mixing Mode of HCF Assembly and the Classification of Rod Gap
图 3 HCF棒间隙随轴向位置的变化
Z—燃料组件轴向高度。
Figure 3. Variation of Rod Gap of HCF Assembly with Axial Position
图 5 子通道程序传热模型验证
Tin—入口流体温度;q—热流密度。
Figure 5. Validation of Heat Transfer Model of Sub-channel Code
图 6 交混模型对横向交混速度分布的影响
Figure 6. Influence of Mixing Model on the Transverse Mixing Rate
图 9 17×17HCF子通道质量通量分布
Figure 9. Mass Flux Distribution of Sub-channels of 17×17 HCF Assembly
表 1 4×4HCF几何参数汇总
Table 1. Summary of Geometrical Parameters of 4×4 HCF Assembly
参数 数值 肋片直径/m 5.60×10−3 肋根直径/m 1.00×10−2 连接段长度/m 2.00×10−3 湿周/m 1.72 流道面积/m2 6.02×10−3 矩形通道边长/m 1.01×10−1 水力直径/m 1.40×10−2 螺旋节距/m 1.00 燃料棒长度/m 2.0 
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