Patent Number: 
Section: claims

1. A method for controlling reactivity of a fast reactor under conditions of uncertainty, wherein the fast reactor includes a reactor core, comprising the steps of:conducting physical measurements of reactor core subcriticality;after assembly of the reactor core, comparing obtained values with design values of neutron-physical characteristics of the reactor core;wherein, if there is a discrepancy between the obtained values with the design values of the neutron-physical characteristics of the reactor core, installing adjustable reactivity rods in the fast reactor at a level of a fuel portion of the reactor core;wherein a level of boron-B10 isotope enrichment of the adjustable reactivity rods is selected to be higher than the level of boron-B10 isotope enrichment of compensating rods of the reactor core;wherein the adjustable reactivity rods are located in one or more replaceable core reflector modules;wherein the adjustable reactivity rods are inserted in core reflector slots formed in the replaceable core reflector modules; andwherein after installation of the adjustable reactivity rods at the core fuel portion level, additional physical measurements of the core subcriticality are performed, and in the event of a discrepancy between the obtained and design values, the adjustable reactivity rods with an insufficient enrichment are replaced with adjustable reactivity rods with an enrichment ensuring subcriticality of the reactor core, wherein the adjustable reactivity rods are replaced by removal of one or more of the replaceable core reflector modules and replacing the replaceable core reflector modules with the adjustable reactivity rods of a required enrichment. 2. A method for controlling reactivity of a fast reactor under conditions of uncertainty, wherein the fast reactor includes a reactor core, comprising the steps of:conducting physical measurements of reactor core subcriticality;after assembly of the reactor core, comparing obtained values with design values of neutron-physical characteristics of the reactor core;wherein, if there is a discrepancy between the obtained values with the design values of the neutron-physical characteristics of the reactor core, installing adjustable reactivity rods in the fast reactor at a level of a fuel portion of the reactor core;wherein a level of boron-B10 isotope enrichment of the adjustable reactivity rods is selected to be higher than the level of boron-B10 isotope enrichment of compensating rods of the reactor core;wherein the adjustable reactivity rods are located in one or more replaceable core reflector modules; andwherein the adjustable reactivity rods are inserted in core reflector slots formed in the replaceable core reflector modules; andwherein after installation of the adjustable reactivity rods at the core fuel portion level, additional physical measurements of the core subcriticality are performed, and in the event of a discrepancy between the obtained and design values, the adjustable reactivity rods with an insufficient enrichment are replaced with adjustable reactivity rods with an enrichment ensuring subcriticality of the reactor core, wherein the adjustable reactivity rods are replaced by removal of adjustable reactivity rods from the core reflector slots and their replacement with other adjustable reactivity rods of a required enrichment.