Impact of Thermal-hydraulic Feedback and Differential Thermal Expansion On European Sfr Core Power Distribution

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY
Ben Lindley, Francisco Álvarez Velarde, Una Baker, J. Bodi, P. Cosgrove, Alan Charles, C. Fiorina, E. Fridman, J. Křepel, J. Lavarenne, K. Mikityuk, E. Nikitin, A. Ponomarev, S. Radman, E. Shwageraus, B. Tollit
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引用次数: 1

Abstract

The objective of this paper is to quantify the coupling effect on the power distribution of sodium-cooled fast reactors (SFRs), specifically the European SFR. Calculations are performed with several state-of-the-art reactor physics and Multiphysics codes (TRACE/PARCS, DYN3D, WIMS, COUNTHER and GeN-Foam) to build confidence in the methodologies and validity of results. Standalone neutronics calculations were generally in excellent agreement with a reference Monte Carlo-calculated power distribution (from Serpent). Next, the impact of coolant density and fuel temperature Doppler feedback was calculated. Reactivity coefficients for perturbations in the inlet temperature, flow rate and core power were shown to be negative with values of around -0.5 pcm/°C, -0.3 pcm/°C and -3.5 pcm/% respectively. Fuel temperature and coolant density feedback was found to introduce a roughly -1%/+1% in/out power tilt across the core. Calculations were then extended to axial expansion for cases where fuel is linked and unlinked to the clad. Core calculations are in good agreement with each other. The impact of differential fuel expansion is found to be larger for fuel both linked and unlinked to the clad, with the in/out power tilt increasing to around -4%/+2%. Thus, while broadly confirming the known result that standalone physics calculations give good results, the expansion coupling effect is perhaps more than anticipated a priori. These results provide a useful benchmark for the further development of Multiphysics codes and methodologies in support of advanced reactor calculations.
热液反馈和差动热膨胀对欧洲堆芯功率分布的影响
本文的目的是量化钠冷快堆(SFRs)功率分布的耦合效应,特别是欧洲的SFRs。使用几种最先进的反应堆物理和多物理场代码(TRACE/PARCS, DYN3D, WIMS, COUNTHER和GeN-Foam)进行计算,以建立对方法和结果有效性的信心。独立的中子计算通常与参考蒙特卡罗计算的功率分布(来自Serpent)非常一致。其次,计算了冷却剂密度和燃油温度多普勒反馈的影响。入口温度、流量和堆芯功率扰动的反应性系数分别为负值,约为-0.5 pcm/°C、-0.3 pcm/°C和-3.5 pcm/%。研究发现,燃料温度和冷却剂密度反馈会在堆芯处引入大约-1%/+1%的输入/输出功率倾斜。然后将计算扩展到燃料与包层连接和不连接的情况下的轴向膨胀。堆芯计算结果吻合良好。对于连接和未连接到包层的燃料,差异燃料膨胀的影响更大,输入/输出功率倾斜增加到-4%/+2%左右。因此,虽然广泛地证实了已知的结果,即独立的物理计算给出了良好的结果,但膨胀耦合效应可能比先验预期的要多。这些结果为进一步开发支持先进反应堆计算的多物理场代码和方法提供了有用的基准。
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
CiteScore
1.30
自引率
0.00%
发文量
56
期刊介绍: The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.
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