Patent Number: 
Section: claims

1. A separable multi-component cask for spent nuclear fuel transport and storage comprising:a vertical longitudinal axis;a vertically elongated first cylinder having a neutron radiation shielding composition, the first cylinder defining a first cavity extending along the longitudinal axis;a vertically elongated second cylinder having a gamma radiation blocking composition, the second cylinder defining a second cavity extending along the longitudinal axis and configured to hold a cylindrical spent nuclear fuel canister containing a plurality of fuel assemblies;the second cylinder detachably mounted inside the first cavity of the first cylinder; andan air ventilation annulus formed between the first and second cylinders, the air ventilation annulus defining a heat removal passage to remove heat emitted by the canister when placed inside the second cylinder. 2. The cask according to claim 1, wherein the second cylinder has a higher thermal conductivity than the first second cylinder. 3. The cask according to claim 1, wherein the second cylinder includes a bottom lid attached to a bottom end of the second cylinder, and a radially protruding top mounting flange extending circumferentially around a top end of the second cylinder. 4. The cask according to claim 3, wherein the top mounting flange is received at east partially with an upwardly open annular recess formed in a top end of the first cylinder. 5. The cask according to claim 4, wherein the annular recess is formed by an angle ring having an L-shaped cross section. 6. The cask according to claim 4, wherein the annular recess comprises a plurality of raised spacer blocks, the top mounting flange of the second cylinder being seated on the spacer blocks to form a plurality of upper air outlet openings between the top flange and the first cylinder within the recess which is in fluid communication with the air ventilation annulus between the first and second cylinders. 7. The cask according to claim 6, wherein the top mounting flange is coupled directly to the spacer blocks by threaded fasteners. 8. The cask according to claim 3, wherein the first cylinder includes a castellated top end, the top mounting flange of the second cylinder being supported on the castellated top end forming a plurality of upper air openings in fluid communication with the air ventilation annulus. 9. The cask according to claim 3, wherein the bottom lid is comprised of a gamma blocking material and a neutron absorbing material. 10. The cask according to claim 9, wherein the bottom lid comprises a hydrogenous material. 11. The cask according to claim 1, further comprising a bottom lid attached to a bottom end of the second cylinder, wherein the bottom lid extends downwards below an annular support flange at a bottom end of the first cylinder forming a lower air inlet to the air ventilation annulus. 12. The cask according to claim 1, further comprising a bottom lid attached to a bottom end of the second cylinder, wherein the bottom lid does not protrude radially outwards between a sidewall of the second cylinder. 13. The cask according to claim 12, wherein an interior surface of the first shell includes a plurality of vertical longitudinal splines arranged in the air ventilation annulus which center the second cylinder in the first cylinder, a plurality of longitudinally-extending air passages of the air ventilation annulus being formed between the splines. 14. The cask according to claim 3, further comprising a plurality of lifting lugs detachably mounted to the top mounting flange of the second cylinder for lifting and moving the second cylinder. 15. The cask according to claim 14, wherein the top mounting flange of the second cylinder is coupled to the first cylinder by a plurality of threaded fasteners engaging a top flange of the first cylinder, the first and second cylinders being liftable as a unit by lifting the second shell via the lifting lugs. 16. The cask according to claim 1, wherein the first and second cylinders each have a cylindrical body with circular transverse cross-sectional shape. 17. A multi-component transfer cask system for storage and transport of spent nuclear fuel comprising:a vertical longitudinal axis;a vertically elongated outer container having a neutron radiation shielding composition, the outer container comprising a top end including an annular top flange, a bottom end, and a cylindrical sidewall extending between the ends and defining a first cavity;a vertically elongated inner container having a gamma radiation blocking composition, the inner container comprising a top end including an annular mounting flange, a bottom end, and a sidewall extending between the ends and defining a second cavity configured to hold a spent nuclear fuel canister;the mounting flange of the inner container detachably coupled to the top flange of the outer the outer container such that the inner container is suspended and supported via the coupled flanges in a cantilevered manner;a spent nuclear fuel canister disposed in the second cavity of the inner container and heating the inner container;an air ventilation annulus formed between the inner and outer containers along the longitudinal axis, wherein air within the annulus is heated by the inner shell inducing an upward flow of cooling air through the annulus;an interface between the mounting flange of the inner container and the top flange of outer container being configured to define a plurality of upper cooling air outlet openings in fluid communication with the air ventilation annulus for rejecting the heated air to an ambient environment;wherein the inner container is axially and slideably separable from the outer container. 18. The cask according to claim 17, wherein the top flange of the outer container is castellated forming a plurality of circumferentially spaced apart vertical gaps between top flange and the mounting flange of the inner container which define the upper cooling air outlet openings. 19. The cask according to claim 17, further comprising a bottom lid attached to the bottom end of the inner shell, wherein the bottom lid extends downwards below the bottom end of the outer shell and defines a downwardly open annular lower cooling air inlet opening between the inner and outer containers to introduce ambient cooling air into the air ventilation annulus. 20. The cask according to claim 17, wherein the mounting flange of the inner container is coupled to the top flange of the outer container by a plurality of threaded fasteners. 21. A method for transferring and transporting spent nuclear fuel comprising:providing a nuclear fuel transport cask comprising an outer neutron shield cylinder having an internal first cavity and an inner gamma block cylinder having an internal second cavity, the gamma block cylinder detachably coupled to and nested inside the first cavity of the neutron shield cylinder;separating the gamma block cylinder from the neutron shield cylinder;placing the gamma block cylinder on a support surface;loading a plurality of spent nuclear fuel assembles into the second cavity of the gamma block cylinder;lifting the gamma block cylinder over the neutron shield cylinder; andinserting the gamma block cylinder and fuel canister assembly into the neutron shield cylinder; andseating a top mounting flange of the gamma block cylinder on a plurality of spacer blocks arranged circumferentially around the neutron shield cylinder. 22. The method according to claim 21, further comprising before or after the step of placing the gamma block cylinder, a step of inserting a fuel canister into the gamma block cylinder before the loading step, wherein the fuel assembly are loaded into the canister. 23. The method according to claim 21, further comprising after the step of inserting the gamma block cylinder into the neutron shield cylinder, bolting a top mounting flange of the gamma block cylinder to a top flange of the neutron shield cylinder.