Nitrogen under cladding of fuel pins with mixed uranium-plutonium nitride
Authors/Creators
- 1. Proryv JSC, Moscow, Russia
- 2. IPPE JSC, Obninsk, Russia
- 3. NIIAR JSC, Dimitrovgrad, Russia
- 4. VNIINM JSC, Moscow, Russia
Description
In gas-bonded fuel pins the interior space is filled with helium in order to provide heat removal from the fuel. Under irradiation, as a result of gaseous fission products release, the initial gas composition under the fuel pin cladding changes, which leads to a change in its thermophysical characteristics. Post-irradiation examinations have shown that the partial pressure of nitrogen under the fuel pin cladding increases with fuel burn-up increase, since nitrogen atoms also release from uranium-plutonium nitride fuel under the cladding, in addition to the krypton, xenon and helium inert gases. The mechanisms of release of inert gases and nitrogen from nitride are different: the diffusion mechanism for inert gases and the knocking out of fission fragments for nitrogen. The difference in the gas release mechanisms leads to a significant quantitative difference in the gases release under the cladding. The specific nitrogen yield under the fuel pin cladding is significantly lower than the specific yield of other gases, but its presence is an important factor, since the dissociation temperature of the mixed nitride, as well as the nitriding of the inner surface of the cladding, depends on the nitrogen pressure under the fuel pin cladding. A generalization and analysis of the results of post-irradiation examinations of the nitrogen content in the gas mixture under the claddings of 87 investigated fuel pins after irradiation in the BN-600 reactor as part of 17 experimental fuel assemblies with mixed uranium-plutonium nitride fuel, irradiated to maximum fuel burn-up from 3 at. % to 9 at. % is carried out in the paper.
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Additional details
References
- Carvajal-Nunez U, Prieur D, Manara D (2014) Melting point determination of uranium nitride and uranium plutonium nitride: a laser heating study. Journal of Nuclear Materials 449(1–3): 1–8. https://doi.org/10.1016/j.jnucmat.2014.02.021
- Grachev AF, Zabudko LM, Skupov MV, Kryukov FN, Teplov VG, Marinenko EE, Porollo SI (2020) Fission gas release from irradiated uranium-plutonium nitride fuel. Atomic Energy 129(2): 103–107. https://doi.org/10.1007/s10512-021-00712-z
- Hayes SL, Thomas JK, Peddicord KL (1990) Material property correlation for uranium mononitride VI. thermodynamic properties. Journal of Nuclear Materials 171(2–3): 300–318. https://doi.org/10.1016/0022-3115(90)90377-y
- Lustman B (1985) Radiation Phenomena in Uranium Dioxide. Moscow, Atomizdat, 288 pp. [in Russian]
- Nekrasov BV (1957) Textbook of General Chemistry. Moscow, Goskhimizdat, 486 pp. [in Russian]
- Olander DR (1976) Fundamental Aspects of Nuclear Fuel Elements. TID-26711-P1. https://doi.org/10.2172/7343826
- Porollo SI, Ivanov SN, Marinenko EE, Zabudko LM (2017) Analysis of experimental data on gas release and swelling of uranium mononitride fuel irradiated in the BR-10 reactor. Atomic Energy 121(6): 415–423. https://doi.org/10.1007/s10512-017-0221-4
- Porollo SI, Marinenko EE, Kryukov FN, Nikitin ON, Gilmutdinov IF, Zabudko LM, Grachev AF, Tarasov BA (2022) Nitriding and carburization of mixed nitride uranium-plutonium fuel pin cladding. Atomic Energy 133(3): 92–97. https://doi.org/10.1007/s10512-023-00978-5
- Rogozkin BD, Stepennova NM, Bergman GA, Proshkin AA (2003) Thermochemical stability, radiation testing, fabrication, and reprocessing of mononitride fuel. Atomic Energy 95(6): 835–844. https://doi.org/10.1023/B:ATEN.0000018996.79185.bc