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用于球床反应堆的具有离散运动的超保真耗尽

Hyper-fidelity depletion with discrete motion for pebble bed reactors.

作者信息

Robert Yves, Siaraferas Tatiana, Fratoni Massimiliano

机构信息

University of California, Berkeley, Berkeley, CA, 94709, USA.

出版信息

Sci Rep. 2023 Aug 5;13(1):12711. doi: 10.1038/s41598-023-39186-3.

DOI:10.1038/s41598-023-39186-3
PMID:37543615
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10404221/
Abstract

Hyper-fidelity (HxF) depletion of pebble bed reactors (PBRs) is the capability to model depletion for every pebble while accounting for motion through the core. Previous HxF work demonstrated feasibility to deplete hundreds of thousands of stationary pebbles concurrently within reasonable timeframes. This work illustrates the second step towards HxF, coupling depletion with a discrete motion scheme. The model assumes an ordered bed with pebbles occupying fixed positions. Motion is simplified as discrete since pebbles move in straight lines from one set position to another. The methodology was implemented in Serpent 2, combined with its transport and depletion capabilities. Ad-hoc routines were developed ensuring compatibility with domain decomposition and pebble recirculation after each pass based on discharge criteria and fresh pebble insertion. Capabilities of HxF with discrete motion are demonstrated using a full-scale high-temperature gas-cooled reactor model. Specifically, an approach to equilibrium is performed, and example results are shown for in-core and discarded pebbles. The data illustrates how HxF provides unique insights into PBR fuel, producing information on statistical distributions rather than average values only, as obtained by traditional methods that rely on spectral zoning for depletion. Knowledge of these distributions can greatly improve analysis and assessment of PBRs.

摘要

球床反应堆(PBR)的超精细(HxF)燃耗计算能力是指在考虑球芯内球粒运动的情况下,对每个球粒的燃耗进行建模。先前的HxF研究表明,在合理的时间范围内同时对数十万个静止球粒进行燃耗计算是可行的。本文阐述了迈向HxF的第二步,即将燃耗计算与离散运动方案相结合。该模型假设球床有序,球粒占据固定位置。由于球粒沿直线从一个设定位置移动到另一个位置,因此运动被简化为离散运动。该方法在Serpent 2中实现,并结合了其输运和燃耗计算能力。开发了临时程序,以确保在每次循环后根据卸料标准和新球粒插入情况与区域分解和球粒再循环兼容。使用全尺寸高温气冷堆模型展示了具有离散运动的HxF的能力。具体而言,执行了一种达到平衡的方法,并给出了堆芯内球粒和卸料球粒的示例结果。数据表明,HxF如何为PBR燃料提供独特的见解,生成关于统计分布的信息,而不仅仅是依赖于用于燃耗计算的谱分区的传统方法所获得的平均值。了解这些分布可以大大改进对PBR的分析和评估。

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