Calculation and Analysis of Multiscale Coupling of Dispersion Plate-type Fuel

Xiang Fengrui; He Yanan; Wu Yingwei; Qiu Suizheng; Su Guanghui

doi:10.13832/j.jnpe.2024.S2.0093

Volume 45 Issue S2

Jan. 2025

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Xiang Fengrui, He Yanan, Wu Yingwei, Qiu Suizheng, Su Guanghui. Calculation and Analysis of Multiscale Coupling of Dispersion Plate-type Fuel[J]. Nuclear Power Engineering, 2024, 45(S2): 93-101. doi: 10.13832/j.jnpe.2024.S2.0093

Citation:

Xiang Fengrui, He Yanan, Wu Yingwei, Qiu Suizheng, Su Guanghui. Calculation and Analysis of Multiscale Coupling of Dispersion Plate-type Fuel[J]. Nuclear Power Engineering, 2024, 45(S2): 93-101. doi: 10.13832/j.jnpe.2024.S2.0093

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Calculation and Analysis of Multiscale Coupling of Dispersion Plate-type Fuel

doi: 10.13832/j.jnpe.2024.S2.0093

School of Nuclear Science and Technology, Xi’an Jiaotong University, Xi’an, 710049, China

Received Date: 2024-07-23
Rev Recd Date: 2024-09-30
Publish Date: 2025-01-06

Abstract

Abstract

The multi-scale characteristics of two-phase dispersion materials in dispersion-type plate fuel pose challenges to its performance research. To accurately analyze and evaluate the in-pile performance of U₃Si₂/Al dispersion-type plate fuel, based on the existing equivalent physical properties and behavior model of U₃Si₂/Al dispersion fuel meat, the creep attenuation coefficient model was established to accurately simulate the creep behavior of two-phase composites, particularly focusing on the complex creep characteristics of the equivalent fuel meat. Additionally, a three-dimensional macroscopic fuel plate model and a one-dimensional sphere model were constructed, and a multi-scale coupling method was proposed to couple these models, enabling simultaneous simulation at both scales. Based on the multi-scale multi-physics coupling analysis tool, the multi-physical field analysis of U₃Si₂/Al dispersion-type fuel was conducted, and the impact of fuel particle size and volume fraction was evaluated. The results inidcate that increasing the particle size and volume fraction only slightly increases the central temperature of the fuel; however, when the volume fraction increases from 30% to 40%, the fuel particle stress increases by 11.6%.
- Dispersion plate type fuel,
- Equivalent creep,
- Multi-scale coupling,
- Microscopic fuel particle

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References(9)

References

[1]	DENG Y B, WU Y W, ZHANG D L, et al. Thermal-mechanical coupling behavior analysis on metal-matrix dispersed plate-type fuel[J]. Progress in Nuclear Energy, 2017, 95: 8-22. doi: 10.1016/j.pnucene.2016.11.007
[2]	ZHAO Y M, GONG X, DING S R, et al. A numerical method for simulating the non-homogeneous irradiation effects in full-sized dispersion nuclear fuel plates[J]. International Journal of Mechanical Sciences, 2014, 81: 174-183. doi: 10.1016/j.ijmecsci.2014.02.012
[3]	严晓青. 弥散型核燃料板辐照力学行为的数值模拟[D]. 上海: 复旦大学,2009.
[4]	JEONG G Y, KIM Y S, PARK J. Analytical local stress model for UMo/Al dispersion fuel[J]. Journal of Nuclear Materials, 2020, 528: 151881. doi: 10.1016/j.jnucmat.2019.151881
[5]	JEONG G Y, KIM Y S, SOHN D S. Mechanical analysis of UMo/Al dispersion fuel[J]. Journal of Nuclear Materials, 2015, 466: 509-521.
[6]	REST J, HOFMAN G L. DART model for irradiation-induced swelling of uranium silicide dispersion fuel elements[J]. Nuclear Technology, 1999, 126(1): 88-101. doi: 10.13182/NT99-A2960
[7]	DAVIS L C, ALLISON J E. Micromechanics effects in creep of metal-matrix composites[J]. Metallurgical and Materials Transactions A, 1995, 26(12): 3081-3089. doi: 10.1007/BF02669438
[8]	KRAJEWSKI P E, ALLISON J E, JONES J W. The effect of SiC particle reinforcement on the creep behavior of 2080 aluminum[J]. Metallurgical and Materials Transactions A, 1997, 28(3): 611-620. doi: 10.1007/s11661-997-0046-1
[9]	ZHANG J, WANG H Y, WEI H Y, et al. Modelling of effective irradiation swelling for inert matrix fuels[J]. Nuclear Engineering and Technology, 2021, 53(8): 2616-2628. doi: 10.1016/j.net.2021.02.019