Patent Number: 
Section: claims

1. A process for the detritiation of radioactive waste containing tritium, comprising:carrying out a thermal desorption by subjecting said waste, placed in a detritiation reactor (RT), to a flow of moist gas and subsequently recovering tritium in the form of gas by means of a membrane reactor (RM) in order to valorize the tritium for re-use, the thermal desorption comprising the following sub-steps:A) shredding and uniformly mixing the waste to be detritiated;B) placing said waste in a detritiation reactor (RT);C) sending inert gas and demineralized water to an evaporation/mixing device;D) feeding a moist gaseous mixture, constituted by said inert gas and vapour formed from said demineralized water, to said detritiation reactor (RT) so that said moist gaseous mixture traverses all the waste, giving rise to a formation of a moist gaseous current containing tritium;E) sending said gaseous current containing tritium to a membrane reactor (RM); andF) feeding said membrane reactor (RM) with a swamping gas, thus obtaining exit from the membrane reactor (RM) itself, as end products, of a gaseous current of isotopes containing tritium extracted from the waste and of a gaseous current of detritiated gases. 2. The process according to claim 1, wherein, in order to facilitate thermal desorption, the detritiation reactor (RT) is introduced into an oven that controls and regulates a temperature of the detritiation reactor (RT) around a pre-defined set-point value. 3. The process according to claim 2, wherein the pre-defined set-point value is 120° C. 4. The process according to claim 1, wherein the swamping gas of step F) is pure hydrogen. 5. The process according to claim 1,wherein the detritiation reactor (RT) is operated at a pressure equal to or higher than atmospheric pressure, andwherein the membrane reactor (RM) is operated at a pressure lower than atmospheric pressure. 6. The process according to claim 1, wherein, in order to keep the concentration of tritium within the detritiation reactor (RT) very low, the moist gaseous mixture flows at a flow rate equal to approximately 30 or 50 times the internal volume of the detritiation reactor (RT) per hour. 7. The process according to claim 1,wherein the moist inert gas is kept within the detritiation reactor (RT) at a pressure slightly higher than atmospheric pressure, andwherein the membrane reactor (RM) operates at a pressure of 100 mbar on a swamping-gas side and at a pressure of 900 mbar on a side of feed of gases coming from the detritiation reactor (RT). 8. The process according to claim 1, wherein a time of stay of the moist gaseous mixture in the detritiation reactor (RT) is long enough to guarantee transfer of tritium and of hydrogen isotopes, without high values of tritium concentration being reached in the moist gaseous current leaving the detritiation reactor (RT). 9. The process according to claim 1, wherein a time of stay of the waste in the detritiation reactor (RT) is long enough to guarantee that required values of decontamination are reached. 10. The process according to claim 4, wherein, in order to keep the concentration of tritium within the detritiation reactor (RT) very low, the moist gaseous mixture flows at a flow rate equal to approximately 30 or 50 times the internal volume of the detritiation reactor (RT) per hour.