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Fracture mechanics analysis of Zircaloy-4 tubular samples after laboratory simulated LOCA transient
•Steam oxidation and hydrogen embrittlement during a LOCA was studied.•Axial tensile cladding samples were analyzed using LEFM.•Stress intensity factors were evaluated using finite elements.•The fracture toughness is shown to be a relevant parameter for LOCA embrittlement. This paper investigates th...
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Published in: | Engineering fracture mechanics 2018-04, Vol.193, p.96-107 |
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Main Authors: | , , , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
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Summary: | •Steam oxidation and hydrogen embrittlement during a LOCA was studied.•Axial tensile cladding samples were analyzed using LEFM.•Stress intensity factors were evaluated using finite elements.•The fracture toughness is shown to be a relevant parameter for LOCA embrittlement.
This paper investigates the room temperature cladding embrittlement of Stress Relieved Annealed (SRA) Zircaloy-4 fuel cladding samples subjected to laboratory steam oxidation tests simulating Loss of Coolant Accident (LOCA) transients at 1200 °C followed by water quenching. These high temperature oxidized tubes are mechanically tested using axial tensile samples with machined gage sections. Formerly performed studies suggested that Linear Elastic Fracture Mechanics (LEFM) could provide a good understanding of the sample failure process, including crack nucleation close to the oxidized surfaces followed by crack instability and sample failure at higher applied loads. However, it was found that when the applied stress intensity was calculated using solutions for plate material given in the Tada and Paris Handbook, with the cracks in the plate corresponding to a crack formed only on the cladding’s outer surface – produced by oxidation on this surface alone – versus two opposing cracks formed on the cladding’s inner and outer surfaces – produced by oxidation on both of these surfaces – the critical stress intensity was different between these two cases. It is shown here that for both of the foregoing configurations the same critical crack intensity values are obtained when the applied LEFM stress intensity values are calculated using three dimensional finite element modeling of the axial tensile samples. The critical stress intensity factors determined by this more accurate method – and calculated as a function of degree of surface oxidation and hydrogen content in the prior-β phase – could, thus be considered to be a true materials parameter correlating well with the experimentally determined effect of hydrogen content on the failure strength of the samples. |
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ISSN: | 0013-7944 1873-7315 |
DOI: | 10.1016/j.engfracmech.2018.03.005 |