Patent Number: 
Section: claims

1. A process for the chemical stabilization of a uranium carbide composite material corresponding to:UCx+yC with x≧1 and y>0, placed in a stabilization chamber, comprising the following stages:a stage of rise in temperature of the internal temperature of said chamber to a temperature of between approximately 380° C. and 550° C., said chamber being fed with an inert gas consisting of one or both of argon and nitrogen;a stage of isothermal oxidative treatment at said temperature of between approximately 380° C. and 550° C., said chamber being placed under O2 partial pressure; anda stage of controlling the completion of the stabilization of said composite material which comprises monitoring of the amount of molecular oxygen consumed and/or of carbon dioxide given off or of carbon dioxide and carbon monoxide given off, until at least the achievement of a value of an input set point for the molecular oxygen, of a minimum threshold value for said amount of carbon dioxide or of threshold values for the carbon dioxide and carbon monoxide. 2. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 1 wherein the stage of controlling the completion of the stabilization additionally comprises monitoring of variation in weight of the composite material based on carbon and uranium in the chamber, an increase in weight being correlated with the oxidation of uranium carbide in progress. 3. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 1, wherein the stage of controlling the completion of the stabilization is carried out with the application of a rise in temperature of the internal temperature of said chamber and the monitoring of CO2 given off. 4. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 1, comprising the introduction of a water vapor partial pressure into said chamber before and/or during and/or after the isothermal oxidative treatment stage. 5. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 4, wherein the stage of controlling the completion of the stabilization further comprises detection of H2 as marker for monitoring an end of oxidation in said chamber. 6. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 2, wherein the stage of controlling the completion of the stabilization comprises an operation of overpressurizing a plurality of reaction gases present in said chamber so as to accelerate the end of the oxidation of said composite material. 7. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 6, wherein the stage of controlling the completion of the stabilization additionally comprises a cycle of an operation of overpressurizing and an operation of underpressurizing the reaction gases present in said chamber. 8. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 2, in which said composite material exhibits a morphology of powder or of porous or dense pellet. 9. The process for the chemical stabilization of a uranium carbide composite material as claimed in claim 2, comprising a preliminary stage of determination of an optimum oxidation temperature by thermogravimetric analysis of a sample of UCx+yC composite material.