Patent Number: 
Section: claims

1. A nuclear power generating facility comprising:a containment building;an elongated reactor vessel housed within the containment building, the reactor vessel having a nuclear core having fissile material in which fission reactions take place and an open end axially spaced from the nuclear core, with the open end sealed by a head at a flange;a spent fuel pool supported outside the containment building at an elevation that extends substantially above the reactor vessel, the spent fuel pool having a pool of coolant in fluid communication with an interior of the reactor vessel through a first valve that is configured to automatically supply coolant from the pool of coolant to the interior of the reactor vessel when the reactor is depressurized and a level of coolant within the reactor vessel is below a given level; andan ultimate heat sink coolant reservoir whose upper coolant level under normal operation of the nuclear power generating facility is supported at an elevation substantially above the spent fuel pool, with a lower portion of the ultimate heat sink coolant reservoir in fluid communication with the spent fuel pool through a second valve whose operation is controlled by a level of coolant in the spent fuel pool to maintain the coolant in the spent fuel pool at approximately a preselected level. 2. The nuclear power generating facility of claim 1 wherein the first valve is either passively operated and/or designed to fail in an open position. 3. The nuclear power generating facility of claim 1 wherein the second. valve is either passively or manually operated. 4. The nuclear power generating facility of claim 3 wherein the second valve is a float valve. 5. The nuclear power generating facility of claim 1 including a passive safety system comprising a coolant reservoir supported within the containment building approximately at or above a first elevation of the reactor vessel flange and structured to maintain the given level of coolant within the reactor vessel for a first selected period of time when the coolant level in the reactor vessel during reactor operation unintentionally drops, the passive safety system being structured to be out of operation during a refueling of the nuclear core. 6. The nuclear power generating facility of claim 1 including:a refueling canal establishing a fluid communication path between an inside of the containment building at an elevation above the reactor vessel flange and the spent fuel pool, through which a fuel assembly can pass; andmeans for closing off the fluid communication path from the inside of the containment building to the refueling canal. 7. The nuclear power generating facility of claim 6 including:a branch coolant line connected to the reactor vessel; anda gauge on the branch coolant line having an output indicative of a coolant level within the reactor vessel, above the core, the gauge having an output that controls the first valve to adjust the coolant level to the given level when the reactor vessel is depressurized. 8. The nuclear power generating facility of Claim l including:a branch coolant line connected to the reactor vessel; anda gauge on the branch coolant line having an output indicative of a coolant level within the reactor vessel, above the nuclear core the gauge having an output which controls the first valve to adjust the coolant level when the reactor vessel is depressurized. 9. The nuclear power generating facility of claim 8 wherein the gauge is a pressure gauge. 10. A nuclear power generating facility comprising:a containment building;an elongated reactor vessel housed within the containment building, the reactor vessel having a nuclear core having fissile material in which fission reactions take place and an open end axially spaced from the nuclear core, with the open end sealed by a head at a flange;a spent fuel pool supported outside the containment building at an elevation that extends substantially above the reactor vessel, the spent fuel pool having a pool of coolant in fluid communication with an interior of the reactor vessel through a first valve that is configured to automatically supply coolant from the pool of coolant to the interior of the reactor vessel when the reactor is depressurized and a level of coolant within the reactor vessel is below a given level;an ultimate heat sink coolant reservoir whose upper coolant level under normal operation of the nuclear power generating facility is supported at an elevation substantially above the spent fuel pool, with a lower portion of the ultimate heat sink coolant reservoir in fluid communication with the spent fuel pool through a second valve whose operation is controlled by a level of coolant in the spent fuel pool to maintain the coolant in the spent fuel pool at approximately a preselected level;a refueling canal establishing a fluid communication path between an inside of the containment building at an elevation above the reactor vessel flange and the spent fuel pool, through which a fuel assembly can pass;means for closing off the fluid communication path from the inside of the containment building to the refueling canal;a branch coolant line connected to the reactor vessel; anda pressure gauge on the branch coolant line having an output indicative of the coolant level within the reactor vessel, the first valve being configured to automatically open responsive to the output of the pressure gauge indicative of the coolant level inside the reactor vessel above the core being below the given level, wherein the first valve opening causes coolant from the spent fuel pool to flow by gravity into the interior of the reactor vessel.