OpenMC-PARCS快堆两步法临界和燃耗计算模型开发及初步验证

扈恒霖; 张广春; 肖鹏; 夏榜样; 王连杰

doi:10.13832/j.jnpe.2025.S1.0250

OpenMC-PARCS快堆两步法临界和燃耗计算模型开发及初步验证

doi: 10.13832/j.jnpe.2025.S1.0250

1.
哈尔滨工业大学能源科学与工程学院，哈尔滨，150001
2.
中国核动力研究设计院核反应堆技术全国重点实验室，成都，610213

基金项目: 中国核动力研究设计院核反应堆系统设计技术重点实验室项目（KFKT-05-FW-HT-20220003）

详细信息

作者简介:
扈恒霖（2001—），男，博士研究生，现主要从事核反应堆物理研究，E-mail: 24b902028@stu.hit.edu.cn

通讯作者:
张广春，E-mail: gczhang@hit.edu.cn

中图分类号: TL323
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- 被引次数: 0
出版历程
- 收稿日期: 2025-01-15
- 修回日期: 2025-04-12
- 刊出日期: 2025-06-15

Development and Preliminary Verification of OpenMC-PARCS Two-step Criticality and Burnup Calculation Model for Fast Reactors

1.
School of Energy Science and Engineering, Harbin Institute of Technology, Harbin, 150001, China
2.
National Key Laboratory of Nuclear Reactor Technology, Nuclear Power Institute of China, Chengdu, 610213, China

摘要

摘要: 快堆因具有能谱硬、共振现象复杂等特点而无法直接采用压水堆计算模型进行中子学分析。蒙特卡罗（MC）方法使用连续能量中子截面，能够准确模拟快堆中的共振干涉现象，得到精度较高的均匀化少群截面。本文研究了基于MC方法和三角形多项式展开节块（TPEN）方法的OpenMC-PARCS快堆两步法临界和燃耗计算模型，并且以OpenMC一步法计算结果为参考，利用钠冷快堆基准题MET-1000对假设微观截面不变的燃耗计算方案进行初步验证。初始稳态计算时，OpenMC-PARCS两步法堆芯有效增殖因子（k_eff）偏差约为−104pcm（1pcm=10⁻⁵），径向功率分布偏差不大于1%；燃耗计算时，堆芯k_eff与参考解的最大偏差为591.2pcm，大部分主要核素核子密度偏差不大于1%。初步验证结果表明，OpenMC-PARCS两步法模型有望用于大型金属快堆核设计和燃料管理。
- 钠冷快堆 /
- 蒙特卡罗（MC）方法 /
- 三角形多项式展开节块（TPEN）方法 /
- 两步法 /
- 燃耗计算
Abstract: Fast reactors cannot directly use PWR calculation models for neutronics analysis due to their hard spectra and complex resonance phenomena. Monte Carlo (MC) method utilizes continuous-energy neutron cross-sections, which can accurately simulate resonance interference phenomena in fast reactors, yielding highly precise homogenized few-group cross-sections. This paper, based on MC method and the Triangle-based Polynomial Expansion Nodal (TPEN) method, investigates an OpenMC-PARCS two-step method of criticality and burnup calculation for fast reactors. Based on the OpenMC one-step method calculation results, a preliminary validation of the assumed constant microscopic cross-section burnup calculation scheme is conducted using the sodium-cooled fast reactor benchmark problem MET-1000. In the initial steady-state calculation, the deviation of the core effective multiplication factor (k_eff) using the OpenMC-PARCS two-step method is −104pcm (1pcm=10⁻⁵), and the deviation in the radial power distribution is no greater than 1%. During burnup calculations, the maximum deviation of the core k_eff from the reference solution is 591.2pcm, while most major nuclide number density deviation is no greater than 1%. The preliminary validation results indicate that the OpenMC-PARCS two-step method model can be used for large metallic fast reactor core design and fuel management.
- Sodium-cooled fast reactor /
- Monte Carlo method /
- Triangle-based Polynomial Expansion Nodal (TPEN) method /
- Two-step method /
- Burnup calculation

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图 1 二维单组件模型和超组件模型

Figure 1. 2D Single Assembly Model and Supercell Model

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图 2 径向反射层模型

Figure 2. Radial Reflector Model

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图 3 OpenMC-PARCS快堆两步法稳态计算过程

Figure 3. OpenMC-PARCS Fast Reactor Two-step Steady-state Calculation Process

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图 4 OpenMC-PARCS快堆稳态与燃耗计算流程图

Figure 4. OpenMC-PARCS Fast Reactor Steady-state and Burnup Calculation Flowchart

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图 5 MET-1000堆芯布置

Figure 5. Radial and Axial Arrangement of the MET-1000 Reactor Core

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图 6 MET-1000驱动组件

Figure 6. MET-1000 Driver Assembly

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图 7 非均匀两圈超组件模型（左）和等效均匀两圈超组件模型（右）

Figure 7. Non-uniform Two-ring Supercell Model (Left) and Equivalent Uniform Two-ring Supercell Model (Right)

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图 8 SPH因子迭代计算流程图

Figure 8. SPH Factor Iterative Calculation Flowchart

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图 9 OpenMC计算得到的MET-1000 1/6 堆芯径向功率分布

Figure 9. The Radial Power Distribution of MET-1000 1/6 Core Obtained from OpenMC Calculations

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图 10 OpenMC-PARCS计算得到的MET-1000 1/6 堆芯径向功率分布

Figure 10. The Radial Power Distribution of MET-1000 1/6 Core Obtained from OpenMC-PARCS Calculations

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图 11 MET-1000 1/6堆芯径向功率相对偏差

Figure 11. MET-1000 1/6 Core Radial Power Relative Deviation

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图 12 MET-1000堆芯轴向功率分布及相对偏差

Figure 12. Axial Power Distribution and Relative Deviation of the MET-1000 Reactor Core

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图 13 堆芯k_eff随时间的变化

Figure 13. Variation of the k_eff over Time

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图 14 OpenMC一步法和OpenMC-PARCS两步法之间主要核素核子密度的相对偏差

Figure 14. Relative Deviation of the Nuclear Density of Major Nuclides between OpenMC and OpenMC-PARCS

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表 1 MET-1000堆芯名义工作条件

Table 1. Nominal Operating Conditions of MET-1000 Reactor Core

参数名	参数值
反应堆功率/MW	1000.0
冷却剂温度/℃	432.5
结构平均温度/℃	432.5
燃料平均温度/℃	534.0

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表 2 由ECCO-33群简化的24群能群结构

Table 2. 24-group Energy Group Structure Simplified from ECCO-33

能群序号	能量上界/MeV	能量下界/MeV	能群序号	能量上界/MeV	能量下界/MeV
1	1.964033×10¹	1.000000×10¹	13	4.086771×10⁻²	2.478752×10⁻²
2	1.000000×10¹	6.065307×10⁰	14	2.478752×10⁻²	1.503439×10⁻²
3	6.065307×10⁰	3.678794×10⁰	15	1.503439×10⁻²	9.118820×10⁻³
4	3.678794×10⁰	2.231302×10⁰	16	9.118820×10⁻³	5.530844×10⁻³
5	2.231302×10⁰	1.353353×10⁰	17	5.530844×10⁻³	3.354626×10⁻³
6	1.353353×10⁰	8.208500×10⁻¹	18	3.354626×10⁻³	2.034684×10⁻³
7	8.208500×10⁻¹	4.978707×10⁻¹	19	2.034684×10⁻³	1.234098×10⁻³
8	4.978707×10⁻¹	3.019738×10⁻¹	20	1.234098×10⁻³	7.485183×10⁻⁴
9	3.019738×10⁻¹	1.831564×10⁻¹	21	7.485183×10⁻⁴	4.539993×10⁻⁴
10	1.831564×10⁻¹	1.110900×10⁻¹	22	4.539993×10⁻⁴	3.043248×10⁻⁴
11	1.110900×10⁻¹	6.737947×10⁻²	23	3.043248×10⁻⁴	1.486254×10⁻⁴
12	6.737947×10⁻²	4.086771×10⁻²	24	1.486254×10⁻⁴	1.000010×10⁻¹¹

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表 3 堆芯反应性效应计算结果

Table 3. Core Reactivity Calculation Results

堆芯参数	OpenMC	OpenMC-PARCS	偏差/pcm
${k_{{\text{eff}}}}$（提棒工况）	1.030524±0.00003	1.029484	−104±3
${k_{{\text{eff}}}}$（插棒工况）	0.867201±0.00003	0.866372	−82.9±3
$\Delta {\rho _{{\mathrm{CR}}}}$/pcm	16332.3±6	16311.2	−21.1±6
$\Delta {\rho _{{\mathrm{Doppler}}}}$/pcm	−354.9±9	−401.9	−47±9
$\Delta {\rho _{{\mathrm{Na}}}}$/pcm	2308.4±6	1553.1	−755.3±6

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表 4 不同燃耗计算模型花费的计算时间

Table 4. Computational Time Spent by Different Burnup Calculation Models

计算模型	组件阶段计算时间/核时			堆芯阶段计算时间/核时	总计算时间/核时
计算模型	OpenMC随机体积计算	OpenMC生成均匀化群常数	OpenMC生成微观燃耗计算参数库	接口程序+PARCS堆芯扩散计算+组件燃耗计算	总计算时间/核时
OpenMC一步法^①					7464.4
OpenMC-PARCS两步法^②	0.028	221.573	559.028	0.614	781.24
注：①OpenMC一步法执行MC全堆输运计算，直接统计总计算时间；②OpenMC-PARCS两步法分阶段统计计算时间。

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