Patent Number: 
Section: claims

1. A method for selecting and disposing remaining spent nuclear fuel bundles for casks comprising the steps of:numbering spent nuclear fuel bundles in order based on their values of decay heat so that the spent nuclear fuel bundles with lower values of decay heat are given smaller numbers;removing any spent nuclear fuel bundles with values of decay heat higher than a limit of decay heat for the casks to define remaining spent nuclear fuel bundles;calculating the mean value of decay heat of the remaining spent nuclear fuel bundles;evaluating one or more casks, wherein each cask comprises a number of cells to hold the remaining nuclear fuel bundles and determining if the number of cells of each cask is odd or even;reserving a number of the remaining spent nuclear fuel bundles with values of decay heat closest to the calculated mean value of decay heat of the remaining spent nuclear fuel bundles so that the number of reserved remaining spent nuclear fuel bundles is equal to the number of the casks and to redefine the remaining spent nuclear fuel bundles, when the number of the cells of each cask is odd;determining if the number of the remaining spent nuclear fuel bundles is odd or even;removing the remaining spent nuclear fuel bundle with the highest value of decay heat and redefining the remaining spent nuclear fuel bundles, when the number of the remaining spent nuclear fuel bundles is odd;matching the remaining spent nuclear fuel bundles so that the remaining spent nuclear fuel bundle with the highest value of decay heat is matched with the remaining spent nuclear fuel bundle with the lowest value decay heat, and that the remaining spent nuclear fuel bundle with the second highest value of decay heat is matched with the remaining spent nuclear fuel bundle with the second lowest value of decay heat, and that the remaining spent nuclear fuel bundle with the third highest value of decay heat is matched with the remaining spent nuclear fuel bundle with the third lowest value of decay heat, and so on so as to match the remaining spent nuclear fuel bundles in pairs;calculating a mean value of decay heat of each remaining spent nuclear fuel bundle pair;arranging the remaining spent nuclear fuel bundle pairs in order based on their mean value of decay heat;calculating the difference between the mean value of decay heat of each remaining spent nuclear fuel bundle pair and the previously calculated mean value of decay heat of the remaining spent nuclear fuel bundles;determining if the number of the cells of each cask is odd or even;if the number of the cells of each cask is odd, disposing the remaining spent nuclear fuel bundles in the casks in a first way;if the number of the cells of each cask is even; disposing the remaining spent nuclear fuel bundles in the casks in a second way; anddetermining if the heat load on each cask is smaller than a limit of heat load and reducing the limit of decay heat for the casks and returning to the step of removing any remaining spent nuclear fuel bundles with values of decay heat higher than the limit of decay heat for the casks, when the heat load on each cask is not smaller than the limit of heat load for the casks. 2. The method according to claim 1, wherein the first way of selecting the remaining spent nuclear fuel bundles comprises the steps of:disposing each reserved spent fuel bundle in a related cask;calculating the difference between the value of decay heat of each reserved spent nuclear bundle and the mean value of decay heat of the remaining spent nuclear fuel bundles; andsubtracting 1 from the number of the cells of each cask before dividing it by 2, thus providing the number of the spent nuclear fuel bundle pairs for each cask so that the total of the difference between the mean value of decay heat of each selected spent nuclear fuel bundle pair and the mean value of decay heat of the remaining spent nuclear fuel bundles plus the difference between the value of decay heat of the only reserved spent nuclear fuel bundle and the mean value of decay heat of the remaining spent nuclear spent nuclear fuel bundles is close to zero. 3. The method according to claim 1, wherein the second way of selecting the remaining spent nuclear fuel bundles comprises the step of dividing the number of the cells of each cask by 2, thus providing the number of the remaining fuel bundle pairs for each cask so that the total of the difference between the mean value of decay heat of each selected spent nuclear fuel bundle pair and the mean value of decay heat of the remaining spent nuclear fuel bundles is close to zero. 4. The method according to claim 1, wherein disposing the remaining spent nuclear fuel bundles in the casks in the first or in the second way comprises the steps of:arranging the remaining spent nuclear fuel bundles for each cask in order based on their values of decay heat; anddisposing the remaining spent nuclear fuel bundles in each cask so that the remaining spent nuclear fuel bundles with higher values of decay heat are located closer to each center of the cask. 5. The method according to claim 4, wherein the value of decay heat of each remaining spent nuclear fuel bundle is closest to the value of decay heat of another remaining spent nuclear fuel bundle at a same distance to the center of each cask in a diagonal line. 6. The method according to claim 5, wherein the sum of decay heat of the remaining spent nuclear fuel bundles in each quadrant of each cask is close to the sum of decay heat of the remaining spent nuclear fuel bundles in any other quadrant of each cask.