Experimental and numerical study of fracture mechanisms in UO2 nuclear fuel

Gatt, Jean-Marie; Sercombe, J.; Aubrun, I.; Ménard, J.C

doi:10.1016/j.engfailanal.2014.07.019

Cited by 22 publications

(14 citation statements)

References 13 publications

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“…The advantage of this approach is that CZM eliminates singularity of stress at the crack tip. This approach has been used for nuclear fuels and implemented into fuel performance codes [33,34]. The pick stress on the cohesive law is the cohesive strength of the material, σ c , and corresponds to the point at which the crack initiates for a critical separation, λ f .…”

Section: Traction-separation Curvesmentioning

confidence: 99%

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Balboa

Brutzel

Chartier

et al. 2018

Journal of Nuclear Materials

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Molecular dynamics simulations using two empirical potentials: Cooper and MOX-07 are carried out to assess the mechanical properties of U x Pu 1−x O 2 solid solution as a function of irradiation dose. The structural damage evolution with dose is modelled with the accumulation of Frenkel pairs method. The structural change follows classical steps with increasing dose: first accumulation of point defects that cluster and form dislocation loops which transform in turn to dislocation lines. Elastic properties such as the bulk modulus and the anisotropic factor via the Zener's ratio are evaluated for each steps. Overall, bulk moduli decrease with increasing dose while anisotropic factor behaviour depends on the potential used. It is also found that point defects play a major role in these evolution. Traction-separation curves used in cohesive zone models are also calculated for different irradiation doses. From these curves we extract the tensile strengths and the energy release rates as well as the fracture toughness. Fracture toughness is found to increase steadily with dose whereas tensile strengths displays v-shape curves which decreases for low doses and raises for high doses. For all these mechanical properties, point defects seem to play a major role while the impact of the dislocations is rather minor.

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Section: Traction-separation Curvesmentioning

confidence: 99%

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Balboa

Brutzel

Chartier

et al. 2018

Journal of Nuclear Materials

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“…However, the fracture properties are not correlated to the porosity, pore and grain size distributions in the underlying microstructure. Similar correlations are missing in the fracture studies made in [12][13][14]. In the present work, a multi-scale method is pursued to obtain the microstructural dependent fracture parameters of a smeared crack model [14,15] at the engineering scale.…”

Section: Introductionmentioning

confidence: 72%

“…The fracture modeling of UO 2 fuel pellets have primarily focused on thermo-mechanical fragmentation process during power cycles. Numerical techniques like discrete element method (DEM) [11], or finite element method (FEM) with cohesive zone [12] or smeared crack models [13,14] have been employed in these investigations. In DEM [11], the fracture properties are randomly distributed in the pellet to obtain the fragmentation behavior.…”

Section: Introductionmentioning

confidence: 99%

Multi-scale modeling of inter-granular fracture in UO2

Chakraborty¹,

Zhang²,

Tonks³

et al. 2015

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The brittle fracture behavior of UO 2 fuels is strongly influenced by the porosity and grain size distributions in the underlying microstructure. In service, there is significant evolution of these microstructural features, which can alter the fracture properties and subsequently the thermo-physical-mechanical behavior of the nuclear fuels. To incorporate these microstructural effects on the fracture behavior, a multi-scale modeling framework is developed in the present work. Within this framework, the grain-boundary fracture properties obtained from molecular dynamics simulations are utilized in a phase-field model to investigate the intergranular brittle crack propagation in this material. A sensitivity study with varying porosity, pore and grain size is performed to investigate their influence on the fracture properties. Subsequently, the parameters of an engineering scale fracture model are obtained by fitting the stress-strain evolution obtained from the phase-field simulations. This framework provides a hierarchical coupling of properties evaluated at the atomistic scale to perform more realistic engineering level predictions of fracture in nuclear fuel pellets.

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“…As a first approximation, we have treated these local material properties as constants in the calculations and neglected any dependence on temperature or other parameters. The best-estimate value for G gb is 4 × 10 −3 Jm −2 , which is more than two orders of magnitude lower than the measured macroscopic (bulk) fracture energy of unirradiated polycrystalline UO 2 [147][148][149]. No measured data are available for the local fracture energy of grain boundaries, but molecular dynamics simulations indicate that it is comparable to that of bulk polycrystalline UO 2 in unirradiated conditions [150,151].…”

Section: Summary Of Main Findingsmentioning

confidence: 78%

Modelling of fine fragmentation and fission gas release of UO₂ fuel in accident conditions

Jernkvist

2019

EPJ Nuclear Sci. Technol.

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In reactor accidents that involve rapid overheating of oxide fuel, overpressurization of gas-filled bubbles and pores may lead to rupture of these cavities, fine fragmentation of the fuel material, and burst-type release of the cavity gas. Analytical rupture criteria for various types of cavities exist, but application of these criteria requires that microstructural characteristics of the fuel, such as cavity size, shape and number density, are known together with the gas content of the cavities. In this paper, we integrate rupture criteria for two kinds of cavities with models that calculate the aforementioned parameters in UO2 LWR fuel for a given operating history. The models are intended for implementation in engineering type computer programs for thermal-mechanical analyses of LWR fuel rods. Here, they have been implemented in the FRAPCON and FRAPTRAN programs and validated against experiments that simulate LOCA and RIA conditions. The capabilities and shortcomings of the proposed models are discussed in light of selected results from this validation. Calculated results suggest that the extent of fuel fragmentation and transient fission gas release depends strongly on the pre-accident fuel microstructure and fission gas distribution, but also on rapid changes in the external pressure exerted on the fuel pellets during the accident.

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Experimental and numerical study of fracture mechanisms in UO2 nuclear fuel

Cited by 22 publications

References 13 publications

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Multi-scale modeling of inter-granular fracture in UO2

Modelling of fine fragmentation and fission gas release of UO₂ fuel in accident conditions

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Experimental and numerical study of fracture mechanisms in UO2 nuclear fuel

Cited by 22 publications

References 13 publications

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Damage characterization of (U,Pu)O2 under irradiation by molecular dynamics simulations

Multi-scale modeling of inter-granular fracture in UO2

Modelling of fine fragmentation and fission gas release of UO2 fuel in accident conditions

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Product

Resources

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Modelling of fine fragmentation and fission gas release of UO₂ fuel in accident conditions