Inner-side coatings have been proposed as a complementary solution within the accident tolerant fuel (ATF) framework, to provide enhanced protection for the nuclear fuel cladding. Unlike external surface, the degradation of irradiated internal cladding surface has not been studied extensively. Fission fragments produced during the fission of nuclear fuel is one of the key players in this degradation. This study aimed to estimate the minimum thickness of the thin chromium film, required to protect the inner side of the nuclear fuel cladding. The approach used is based on a set of calculations, of Ion ranges and damage profiles, for a group fission fragments, using the TRIM code. The calculation results were verified by comparison with the experimental data associated with the phenomena of the inner cladding degradation of thermo-releasing elements. The recommended minimum thickness for such a film was found to be 9 microns. Calculations also showed that chromium metal has a greater stopping power compared to the zirconium-based alloy E110, which indicates an increased ability of chromium to withstand exposure to energetic fission fragments during reactor operation.
The tragic events at Fukushima Daiichi nuclear power plants complex in 2011 have triggered a worldwide effort to implement numerous measures aimed at improving the safety of nuclear power plants. Protective coatings on Zr-based claddings were proposed within the frame of Accident Tolerant Fuel (ATF), a post Fukushima concept with the primary goal of improving nuclear fuel's tolerance for severe accident events. These coatings are being considered as short-term concepts to improve corrosion and high-temperature oxidation resistance, and reduce hydrogen absorption of Zr-based alloys, without introducing significant design modifications. Protective coatings were primarily evaluated as external coatings, however, the fact that inner-side of fuel cladding will remain un-protected is highlighted as a concern for the coatings approach. Hence, inner-side coatings as a complement to external coatings on nuclear fuel claddings were proposed. A numerical study (computer simulation) of the effect of the use of chromium carbide coatings was carried out to protect the inner shell on the characteristics of the reactor. Different thicknesses of these coatings were applied on the inner walls of nuclear fuel claddings using a single fuel assembly as a model. The impact of these coatings is evaluated through its induced effects on some reactor physics parameters such as the infinite multiplication factor, the flux, and the operating lifetime. Results were also compared with the case of using chromium coatings. Results showed that chromium carbide coatings will induce relatively small impacts on the studied parameters, when compared with the case of using pure metallic chromium coatings, however, many other factors need to be further studied, since chromium carbide coatings have a ceramic nature, therefore possible impacts on conductivity, adhesion, etc. would be expected.
Protective coatings were proposed as near-term concepts to enhance the Accident Tolerance of nuclear Fuel claddings, it's expected to improve corrosion resistance in severe events, and enhance cladding performance during normal operation, without introducing major design changes. Various aspects such as: corrosion resistance, thermal and Neutronic performances are being evaluated. However, the fact that, inner uncoated side of fuel cladding may expose to the oxidizing environment under some circumstances is still a concern. Thus, a complementary inner-side coating was proposed. Metallic Chromium is extensively studied as a potential coating material, and showed promising performance, Neutronic penalties are expected if chromium used as protective coating. In this study, reactor's inherent safety feedbacks, when chromium coatings used for fuel claddings inner-side protection, is evaluated, these parameters has not been studied before. Four different coating thicknesses were used in the evaluation. Results showed that, inner side coatings will induce less negative moderator temperature feed backs, while feedbacks to changes in fuel temperature will be more negative than the reference uncoated case. Boron coefficient was found to be less negative compared to the reference. It was found that each coating thickness will induce unique changes in neutrons flux; generally, there will be reduction in thermal portion of neutron flux, which will be less for the case of inner-side coatings, when compared to external coatings. The magnitude of feedbacks varies from thickness to another.
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