A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles
Fracture near the U10Mo/cladding material interface impacts fuel service life. In this work, a mesoscale stress model is developed with the fuel foil considered as a porous medium having gas bubbles and bearing bubble pressure and surface tension. The models for the evolution of bubble volume fract...
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2019-09-01
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| Series: | Nuclear Engineering and Technology |
| Online Access: | http://www.sciencedirect.com/science/article/pii/S173857331930066X |
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doaj-4b0d442690c945e08a7617c5f28273d32020-11-25T02:23:39ZengElsevierNuclear Engineering and Technology1738-57332019-09-0151615751588A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubblesXiaobin Jian0Xiangzhe Kong1Shurong Ding2Institute of Mechanics and Computational Engineering, Department of Aeronautics and Astronautics, Fudan University, Shanghai 200433, ChinaInstitute of Mechanics and Computational Engineering, Department of Aeronautics and Astronautics, Fudan University, Shanghai 200433, ChinaCorresponding author.; Institute of Mechanics and Computational Engineering, Department of Aeronautics and Astronautics, Fudan University, Shanghai 200433, ChinaFracture near the U10Mo/cladding material interface impacts fuel service life. In this work, a mesoscale stress model is developed with the fuel foil considered as a porous medium having gas bubbles and bearing bubble pressure and surface tension. The models for the evolution of bubble volume fraction, size and internal pressure are also obtained. For a U10Mo/Al monolithic fuel plate under location-dependent irradiation, the finite element simulation of the thermo-mechanical coupling behavior is implemented to obtain the bubble distribution and evolution behavior together with their effects on the mesoscale stresses. The numerical simulation results indicate that higher macroscale tensile stresses appear close to the locations with the maximum increments of fuel foil thickness, which is intensively related to irradiation creep deformations. The maximum mesoscale tensile stress is more than 2 times of the macroscale one on the irradiation time of 98 days, which results from the contributions of considerable volume fraction and internal pressure of bubbles. This study lays a foundation for the fracture mechanism analysis and development of a fracture criterion for U10Mo monolithic fuels. Keywords: Bubble volume fraction, Bubble pressure, Bubble size, Mesoscale stress, Fuel fracture mechanismhttp://www.sciencedirect.com/science/article/pii/S173857331930066X |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Xiaobin Jian Xiangzhe Kong Shurong Ding |
| spellingShingle |
Xiaobin Jian Xiangzhe Kong Shurong Ding A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles Nuclear Engineering and Technology |
| author_facet |
Xiaobin Jian Xiangzhe Kong Shurong Ding |
| author_sort |
Xiaobin Jian |
| title |
A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| title_short |
A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| title_full |
A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| title_fullStr |
A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| title_full_unstemmed |
A mesoscale stress model for irradiated U10Mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| title_sort |
mesoscale stress model for irradiated u10mo monolithic fuels based on evolution of volume fraction/radius/internal pressure of bubbles |
| publisher |
Elsevier |
| series |
Nuclear Engineering and Technology |
| issn |
1738-5733 |
| publishDate |
2019-09-01 |
| description |
Fracture near the U10Mo/cladding material interface impacts fuel service life. In this work, a mesoscale stress model is developed with the fuel foil considered as a porous medium having gas bubbles and bearing bubble pressure and surface tension. The models for the evolution of bubble volume fraction, size and internal pressure are also obtained. For a U10Mo/Al monolithic fuel plate under location-dependent irradiation, the finite element simulation of the thermo-mechanical coupling behavior is implemented to obtain the bubble distribution and evolution behavior together with their effects on the mesoscale stresses. The numerical simulation results indicate that higher macroscale tensile stresses appear close to the locations with the maximum increments of fuel foil thickness, which is intensively related to irradiation creep deformations. The maximum mesoscale tensile stress is more than 2 times of the macroscale one on the irradiation time of 98 days, which results from the contributions of considerable volume fraction and internal pressure of bubbles. This study lays a foundation for the fracture mechanism analysis and development of a fracture criterion for U10Mo monolithic fuels. Keywords: Bubble volume fraction, Bubble pressure, Bubble size, Mesoscale stress, Fuel fracture mechanism |
| url |
http://www.sciencedirect.com/science/article/pii/S173857331930066X |
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