Patent Number: 053435079
Section: claims

1. An integrated emergency shutdown power and cooling system for maintaining cooling functions in a nuclear reactor during power failure conditions, the reactor having residual heat removal means normally operated during shutdown, the system comprising: a first pump in fluid communication with a reactor coolant pump seal, the first pump being operable to pump coolant to the reactor coolant pump seal;  a coolant storage tank containing coolant and being in fluid communication with the first pump such that coolant is pumped form the storage tank to the reactor coolant pump seal, thereby cooling the reactor coolant pump seal;  a second pump in fluid communication with a residual heat removal system, the second pump being operable to pump coolant from the residual heat removal system;  a heat transfer means in fluid communication with the second pump and an existing reactor coolant system such that coolant circulated by the second pump is cooled by the heat transfer means before being circulated to the existing reactor coolant system;  an independent power source coupled to the first pump and the second pump such that power is supplied from the independent power source to the first pump and the second pump when other sources of power are lost;  whereby during a power fail condition disabling the residual heat removal means normally operated during shutdown, the first pump, in combination with the coolant in the coolant storage tank, pumps coolant to the reactor coolant pump seal when the reactor is hot and pressurized and the second pump, in combination with the heat transfer means, pumps coolant to the heat transfer means, thereby reducing the temperature of teh coolant when the reactor core is shut down.  a high pressure pump in fluid communication with a reactor coolant pump seal, the high pressure pump being operable to pump water to the reactor coolant pump seal;  a water storage tank containing water and being in fluid communication with the high pressure pump such that water is pumped from the tank to the reactor coolant pump seal, thereby cooling the reactor coolant pump seal;  a low pressure pump in fluid communication with a residual heat removal system, the low pressure pump being operable to pump water from the residual heat removal system;  a cooling water pump in fluid communication with the existing cooling water system, the cooling water pump being operable to pump water from the existing cooling water system;  a water to water heat exchanger having a primary circuit and a secondary circuit, the primary circuit being in fluid communication with the low pressure pump and an existing reactor coolant system, the low pressure pump being operable to pump water from the residual heat removal system through the primary circuit to the reactor coolant system, the secondary circuit being in fluid communication with the cooling water pump and the existing cooling water system, the cooling water pump being operable to pump waer from the existing cooling water system though the secondary circuit such that heat from water circulated though the primary circuit is transferred to the water circulated though the secondary circuit, thereby reducing the temperature of the cooling water circulated through the primary circuit;  an independent power source controllably coupleable to the high pressure pump and the low pressure pump such that power is supplied from the independent power source to the high pressure pump and the low pressure pump when regular and emergency power are lost, the independent power source, high pressure pump and low pressure pump being provided in addition to cooling means operative from said regular and emergency power;  whereby during a power fail condition the high pressure pump, in combination with the water in the water storage tank, cools the reactor coolant pump seal when the reactor is hot and pressurized, and the low pressure pump, in combination with with the heat exchanger, cools the reactor coolant system when the reactor is shut down.  a high pressure pump in fluid communication with a reactor coolant pump seal, the high pressure pump being operable to pump water to the reactor coolant pump seal;  a water storage tank containing water, in fluid communication with the high pressure pump such that water is pumped from the tank to the reactor coolant pump seal, for cooling the reactor coolant pump seal;  a low presure pump in fluid communication with a residual heat removal system, the low pressure pump being operable to pump water from the residual heat removal system;  a cooling water pump in fluid communication with an existing cooling water system, the cooling water pump being operable to pump water from the existing cooling water system;  a air to water heat exchanger having a primary circuit and a secondary circuit, the primary circuit being in fluid communication with the low pressure pump and an existing reactor coolant system, the low pressure pump being operable to pump water from the residual heat removal system through the primary circuit to the reactor coolant system, the secondary circuit being air cooled by a blower, the blower being operable to blow air though the secondary circuit, the heat exchanger being operable to transfer heat from the primary circuit to the air blown though the secondary circuit, thereby reducing the temperature of the primary circuit;  an independent power source coupled to the high pressure pump and the low pressure pump such that power is supplied from the independent power source to the high pressure pump and the low pressure pump when regular and emergency power are lost, the independent power source, high pressure pump and low pressure pump being provided in addition to cooling means operative from said regular and emergency power;  whereby during a power fail condition the high pressure pump, in combination with the water in the water storage tank, cools the reactor coolant pump seal when the reactor is hot and pressurized, and the low pressure pump, in combination with the heat exchanger, cools the reactor coolant system when the reactor is shut down.  a high pressure pump in fluid communication with a reactor coolant pump seal, the high pressure pump being operable to pump water to the reactor coolant pump seal;  a water storage tank containing water, in fluid communication with the high pressure pump such that water is pumped from the water tank to the reactor coolant pump seal, thereby cooling the reactor coolant pump seal;  a low pressure pump in fluid communication with a residual heat removal system, the low pressure pump being operable to pump water from the residual heat removal system;  a cooling water pump in fluid communication with the existing cooling water system, the cooling water pump being operable to pump water from the existing cooling water system;  a water to water heat exchanger having a primary circuit and a secondary circuit, the primary circuit being in fluid communication with the low pressure pump and an existing reactor coolant system, the low pressure pump being operable to pump water from the residual heat removal system through the primary circuit to the reactor coolant system, the secondary circuit being in fluid communication with the water storage tank and the high pressure pump, the high pressure pump being operable to pump water from the water storage tank though the secondary circuit such that heat from water circulated though the primary circuit is transferred to the water circulated though the secondary circuit thereby reducing the temperature of the cooling water circulated through the primary circuit;  an independent power source coupled to the high pressure pump and the low pressure pump such that power is supplied from the independent power source to the high pressure pump and the low pressure pump when regular and emergency power are lost, the independent power source, high pressure pump and low pressure pump being provided in addition to cooling means operative from said regular and emergency power;  whereby during a power fail condition the high pressure pump, in combination with the water in the water storage tank, cools the reactor coolant pump seal when the reactor is hot and pressurized, and the low pressure pump, in combination with the heat exchanger, cools the reactor coolant system when the reactor is shut down.  delivering a coolant from a coolant to a reactor coolant pump seal, at least during a pressurized state of the power plant, thereby cooling the reactor cooling pump seal;  circulating a coolant through a residual heat removal system, at least during a depressurized state of the power plant, said delivering and said circulating including pumping the coolant via powered means;  coupling to the powered means an independent backup power supply upon loss of power;  transferring the heat away from at least one of the coolant circulating through the residual heat removal system and the coolant pump seal;  wherein delivering the coolant to the reactor coolant pump seal and circulating the coolant through the residual heat removal system are carried out under said loss of power. 2. The system of claim 1, wherein the coolant comprises water. 3. The system of claim 1, wherein the first pump is a high pressure pump. 4. The system of claim 1, wherein the second pump is a low pressure pump. 5. The system of claim 2, wherein heat transfer means comprises a water to water heat exchanger and a cooling water pump in fluid communication with a supply of cooling water, the cooling water pump being powered by the independent power source, the heat exchanger having a primary circuit and a secondary circuit, the primary circuit being in fluid communication wih the second pump and the existing reactor coolant system, the secondary circuit being in fluid communication with the cooling water pump and an existing cooling water supply system, the heat exchanger being operable to transfer heat from the primary circuit to cooling water in the secondary circuit, thereby reducing the temperature of the primary circuit. 6. The system of claim 2, wherein the heat transfer means comprises an air to water heta exchanger and a blower, the heat exchanger having a primary circuit in fluid connection with the second pump and the existing reactor coolant system, and a secondary circuit cooled by air flow, the air flow being generated by the blower, the blower being powered by the independent power source, the heat exchanger being operable to transfer heat from the primary circuit to the air flow over the secondary circuit, thereby reducing the temperature of the primary circuit. 7. The system of claim 2, wherein heat transfer means comprises a water to water heat exchanger, the heat exchanger having a primary circuit and a secondary circuit, the primary circuit being in fluid communication with the second pump and the existing reactor coolant system, the secondary circuit being in fluid communication with the coolant storage tank and the first pump, the heat exchanger being operable to transfer heat from the primary circuit to the secondary circuit, thereby reducing the temperature of the primary circuit. 8. An integrated emergency shutdown power and cooling system for maintaining cooling functions in a nuclear reactor during power failure conditions, comprising: 9. An integrated emergency shutdown power and cooling system for maintaining cooling functions in a nuclear reactor during power failure conditions, comprising: 10. An integrated emergency shutdown power and cooling system for maintaining cooling functions in a nuclear reactor during power failure conditions, comprising: 11. A method of cooling a nuclear power plant in power fail conditions comprising: 12. The method of claim 11, wherein said delivering a coolant is done using a high pressure pumping apparatus. 13. The method of claim 12, wherein said circulating a coolant is done using a low pressure pumping apparatus. 14. The method of claim 13, wherein said delivering a coolant from a coolant source is done by pumping coolant from a coolant storage receptacle. 15. The method of claim 14, wherein said transferring the heat away from the coolant is done using a water to water heat exchanger apparatus. 16. The method of claim 14, wherein said transferrring the heat the away from the coolant is done using an air to water heat exchanger apparatus.