Patent Number: 048184756
Section: claims

1. In a nuclear reactor having a water coolant with said water coolant being heated in said reactor to drive a turbine and coupled main generator for supplying output power, an improved emergency coolant injection system for supplying water coolant to said reactor during a loss-of-coolant inventory accident, said system comprising:  a second generator mechanically coupled to said main generator and turbine, said second generator converting rotational energy of said turbine and coupled main generator into electric power, including converting the spindown momentum of said turbine and said coupled main generator to electric power;  a reactor coolant injection pump, said pump having an inlet coupled to a source of coolant for said reactor and an outlet for providing said coolant to the interior of said reactor;  an electric pump motor directly coupled to said reactor coolant injection pump for driving said reactor coolant injection pump; and  a dedicated power supply, said dedicated power supply originating at said second generator and supplying power to said electric pump motor coupled to said reactor coolant injection pump,  whereby core coolant can be supplied to said reactor during a loss-of-coolant inventory accident using the spindown momentum of said turbine and said coupled main generator.  a reactor;  a steam outlet from said reactor to a main turbine;  a turbine and coupled main generator for supplying electric power to a power grid;  a condenser for receiving steam from said turbine and for producing condensate; and  a condensate/feedwater system for supplying condensate from said condenser into the interior of said reactor;  the improvement to said condensate/feedwater system comprising:  a reactor coolant injection pump, said pump having an inlet coupled to said condenser for obtaining coolant and an outlet for communicating coolant to the interior of said reactor;  a second generator mechanically coupled to said turbine and coupled main generator, said second generator converting rotational energy of said turbine and said coupled main generator into electric power, including converting the spindown momentum of said main turbine and coupled generator into electric power;  a condensate pump electric motor for driving said reactor coolant injection pump; and  a dedicated power supply, said dedicated power supply originating at said second generator and supplying power to said condensate pump electric motor coupled to said reactor coolant injection pump;  whereby emergency core coolant can be supplied to said reactor during a loss-of-coolant inventory accident using the spindown momentum of said main turbine and coupled generator.  a condensate pump having a suction on said condenser and an outlet, said condensate pump comprising said reactor coolant injection pump;  a feedwater pump, said feedwater pump connected in series to said condensate pump having an inlet on the outlet of said condensate pump and a feedwater outlet to provide feedwater to said reactor during normal operation;  said condensate pump having an outlet bypassing said feedwater pump; and  means in said condensate pump outlet for preventing backflow from said reactor and the outlet of said feedwater pump to said condensate pump,  whereby said condensate pump provides coolant to said reactor bypassing said feedwater pump during a loss-of-coolant inventory accident using the spindown momentum of said turbine and said coupled main generator.  providing a second generator;  mechanically coupling said second generator to said turbine and said coupled main generator:  converting rotational energy of said turbine and said coupled main generator into electric power using said mechanical coupled second generator comprising converting the spindown momentum of said turbine and said coupled main generator to electric power through said mechanically coupled second generator;  providing a reactor coolant injection pump having an inlet and an outlet;  coupling said inlet to a source of coolant;  coupling said outlet to the interior of said reactor;  providing an electric motor to drive said reactor coolant injection pump; and  supplying power from said second generator to said motor during operation of said plant, whereby power to said reactor coolant injection pump includes said power generated from the spindown momentum of said turbine and said coupled main generator.  providing water coolant in said reactor;  heating portions of said water coolant to steam in said reactor;  providing a turbine for receiving steam and driving a coupled main generator for supplying power output to a grid;  providing a condenser for receiving steam from said turbine and generating coolant for return to said reactor;  providing a condensate pump having an inlet for receiving coolant from said condenser and an outlet;  providing a feedwater pump for receiving coolant from the outlet of said condensate pump and for reintroducing coolant into said reactor,  a process for controlling a loss-of-coolant inventory accident including the steps of:  depressurizing said reactor when a loss-of-coolant inventory accident occurs;  providing a bypass line from the outlet of said condensate pump to the interior of said reactor, said bypass line having a one-way flow to prevent backflow into said condensate pump;  providing a second generator mechanically coupled to said turbine and said coupled main generator having a power output separate from said coupled main generator;  converting the spindown momentum of said turbine and said coupled main generator into electric power using said second generator;  supplying electric power from said seoond generator to said condensate pump;  driving said condensate pump by said supplied power during a loss-of-coolant inventory accident; and  injecting coolant into said reactor using said condensate pump when said reactor pressure falls below the shutoff head for said condensate pump.  said reactor normally cooled by a forced circulation cooling system which includes a plurality of pumps and said reactor cooled during a loss-of-coolant inventory accident by an emergency core cooling system,  an emergency core cooling power supply comprising:  an auxiliary generator coupled to said shafting of said turbine and main generator for converting spindown momentum of said turbine and coupled main generator to electric power; and  dedicated power supply means for supplying power from said auxiliary generator to said emergency core cooling system,  whereby emergency coolant injection can be provided to said reactor during a loss-of-coolant inventory accident using the spindown momentum of said turbine and coupled main generator. 2. The invention of claim 1 wherein said reactor coolant injection pump is a condensate pump. 3. The invention of claim 2 and wherein said outlet for said reactor coolant injection pump includes a line for bypassing a downstream feedwater pump. 4. The invention of claim 1 and wherein said dedicated power supply includes a direct electrical connection from said second generator to said electric pump motor. 5. In a nuclear reactor power plant system for supplying power to a main grid, said power plant system including: 6. The invention of claim 5 and wherein said condensate/feedwater system includes: 7. In a nuclear reactor having water coolant heated to steam to drive a turbine, said turbine having a coupled main generator for supplying power output to a grid, said reactor further including a reactor core cooled by a water coolant injection system, an improved process for operating said water coolant injection system during a loss-of-coolant inventory accident including the steps of: 8. In a nuclear reactor of the type having a reactor core cooled by a process including the steps of: 9. In a nuclear power system of the type having a boiling water reactor for providing steam to a turbine, said turbine coupled to a main generator on common shafting for providing electric power output,