Patent Number: 051587416
Section: claims

1. A passive cooling system for liquid metal cooled nuclear fission reactors comprising the combination of: a liquid metal cooled nuclear reactor plant comprising a satellite assembly with a reactor vessel component containing a heat producing core of fissionable fuel submerged in a pool of liquid metal coolant and having at least one primary heat transferring liquid metal coolant loop circuit including a pump component housed in a vessel paired with a heat exchanger component housed in a vessel, said components being connected in series by means of top entry loop conduits extending down into the component Vessels to provide for circulating liquid metal coolant in series from the reactor component vessel through the pump component vessel and the heat exchanger component vessel then back to the actor component vessel; and  a passive cooling system including a series of spaced apart side-by-side partitions in generally concentric arrangement surrounding each component of the reactor satellite assembly forming a sequence of adjoining fluid flow space enclosures for the circulation of cooling fluid intermediate the partitions and heat transfer cooling through said space enclosures, the respective space enclosures around each assembly component being connected in fluid communication with the corresponding space enclosures of the other assembly components, said passive cooling system including a containment vessel substantially surrounding each of the vessels housing an assembly component in spaced apart relation, a cylindrical baffle wall substantially encircling each containment vessel of the assembly in spaced apart relation, a guard vessel substantially surrounding each containment vessel and cylindrical baffle wall of the assembly in spaced apart relation, a concrete silo substantially surrounding the guard vessels of the assembly in spaced apart relation, a fluid flow heat transferring circuit for the passage of air coolant extending downward from the ambient atmosphere above the reactor vessel and concrete silo into the space intermediate the guard vessel and cylindrical baffle wall of each assembly component and around the bottom edge of the cylindrical baffle wall and upward through the space intermediate the cylindrical baffle wall and the containment vessel of each assembly component and returning back out into the ambient atmosphere above the reactor vessel and concrete silo.  a liquid metal cooled nuclear reactor plant including a satellite assembly with a reactor component comprising a primary vessel containing a heat producing core of fissionable fuel submerged in a pool of liquid metal coolant and having at least one primary heat transferring liquid metal coolant top entry loop circuit including a pump component housed in a primary vessel paired with a heat exchanger component housed in a primary vessel, said components being connected in series with top entry loop conduits providing for circulating liquid metal coolant in series from the primary vessel of the reactor component through the primary vessel of the pump component and the primary vessel of the heat exchanger component then back to the vessel of the reactor component: and  a passive cooling system including a series of spaced apart side-by-side partitions in generally concentric arrangement surrounding each component of the reactor satellite assembly forming a sequence of adjoining fluid flow space enclosures for the circulation of fluid intermediate the partitions and heat transfer cooling through said space enclosures, the respective space enclosures around each satellite assembly component being connected in series fluid communication with the corresponding space enclosures of the other assembly paired component vessels, said passive cooling system including a containment vessel substantially surrounding each of the primary vessels housing an assembly component in spaced apart arrangement, a cylindrical baffle wall substantially encircling each containment vessel of the satellite assembly in spaced apart relation, a guard vessel having a cylindrical support substantially surrounding each containment vessel and cylindrical baffle wall of the reactor satellite assembly in spaced apart relation said guard vessel supports resting on a reactor base, a concrete silo substantially surrounding the satellite assembly of reactor components, and a reactor shield deck bridging overhead substantially across the concrete silo and each primary vessel and its surrounding containment vessel closing off the upper ends of each of said primary and containment vessels, the cylindrical supports of the guard vessels providing support and reinforcement to the overhead reactor shield deck, a fluid flow heat transferring circuit for the passage of air coolant through a duct extending downward from the ambient atmosphere above the reactor primary vessel and surrounding concrete silo into the space intermediate the guard vessel and cylindrical baffle wall of each assembly component and around a bottom edge of the cylindrical baffle wall and upward through the space intermediate the cylindrical baffle wall and the containment vessel of each assembly component for cooling the surface of the containment vessels by absorbing heat and returning air upward through a duct and out into the ambient atmosphere above the reactor vessel and concrete silo carrying the absorbed heat from reactor components.  a liquid metal cooled nuclear reactor plant including a satellite assembly with a reactor component comprising a primary vessel containing a heat producing core of fissionable fuel submerged in a pool of liquid metal coolant and having at least one primary heat transferring liquid metal coolant top entry loop circuit including a pump component housed within a primary vessel paired with a heat exchanger component housed within a primary vessel, said components being connected in series with top entry loop conduits extending down into the component primary vessels from above to provide for circulating liquid metal coolant in series from the primary vessel of the reactor component through the primary vessel of the pump component and the primary vessel of the heat exchanger component then back to the vessel of the reactor component  a passive cooling system including a series of spaced apart side-by-side partitions in generally concentric arrangement surrounding the primary vessel of each component of the reactor satellite assembly forming a sequence of adjoining fluid flow space enclosures, said respective space enclosures around each satellite assembly component primary vessel being connected in series fluid communication with corresponding space enclosures of the other assembly paired component vessels, the passive cooling system including containment vessel substantially surrounding each of the primary vessels housing an assembly component in spaced apart arrangement, a cylindrical baffle wall substantially encircling each containment vessel of the satellite assembly in spaced apart relation extending down substantially the length of the containment vessels, a guard vessel having underlying supports substantially surrounding each containment vessel and cylindrical baffle wall of the reactor satellite assembly in spaced apart relation, said guard vessel supports resting on a reactor base, a concrete silo substantially surrounding the satellite assembly of reactor components in spaced apart relation, and a reactor shield deck bridging overhead across the satellite assembly of reactor components closing off the upper ends of each of said primary and containment vessel sealing the space therebetween from retaining a gas therein, a fluid flow heat transferring circuit for the passage of air coolant through a passive cooling system comprising at least one duct extending downward from opening to the ambient atmosphere above the reactor satellite assembly into the space intermediate the guard vessel and cylindrical baffle wall of each assembly component and around a bottom edge of the cylindrical baffle wall and upward through the space intermediate the cylindrical baffle wall and the containment vessel of each assembly component and out into the atmosphere through at least one duct extending upward from said space intermediate the cylindrical baffle wall and containment vessel of each assembly component and opening into the atmosphere for cooling the surface of the containment vessels; and  a secondary passive cooling system including at least one opening to the atmosphere between the concrete silo and the reactor satellite assembly and openings in the guard vessel supports whereby heating of the guard vessel will induce a cooling and heat carrying flow of air from the atmosphere into the concrete silo space surrounding the guard vessels through the opening and over the guard vessels and back out into the atmosphere through at least one air return opening to the atmosphere. 2. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 1, wherein the satellite assembly comprising the reactor vessel component and the primary heat transferring liquid metal coolant loop pump and heat exchanger components are located substantially buried below ground level. 3. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 1, wherein the liquid metal cooled nuclear reactor plant comprising a satellite assembly including a reactor component connected in fluid communication by means of top entry conduits in multiple primary heat transferring liquid metal coolant loop circuits each having a paired pump component housed in a vessel and heat exchanger component housed in a vessel. 4. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 1, wherein the reactor vessel, containment vessel, cylindrical baffle and guard vessel are each circular in cross-section of respectively increasing diameter and concentrically arranged with their side walls providing spaced apart portions forming annular intermediate areas therebetween. 5. A passive cooling system for liquid metal cooled, top entry loop nuclear fission reactors comprising the combination of: 6. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 5, wherein the satellite assembly comprising the reactor vessel component, and the primary heat transferring liquid metal coolant loop pump and heat exchanger components and housing vessels therefor are located substantially buried below ground level. 7. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 5, wherein the primary vessel, the containment vessel, the cylindrical baffle and the guard vessel of each component of the satellite assembly ar circular in cross-section, sequentially of respectively increasing diameter and concentrically arranged with their side walls providing spaced apart partitions forming a series of annular intermediate areas therebetween. 8. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 5, wherein the cylindrical supports of the guard vessels are resting upon a floor comprising the base for the reactor plant satellite assembly. 9. The passive cooling system for liquid metal cooled nuclear fission reactors of claim 5, wherein the cylindrical supports of the guard vessels are provided with openings in each cylinder below the bottom of the guard vessels to enable cooling fluid to flow through the cylinder supports across the bottom of the guard vessel. 10. A passive cooling system for liquid metal cooled, top entry loop nuclear fission reactors comprising the combination of: