Patent Number: 050858254
Section: claims

1. A multiple liquid standby safety injection system for nuclear reactor plants, comprising the combination of: a nuclear reactor plant including a reactor pressure vessel containing a core of fissionable nuclear fuel:  a first water tank for containing cooling water and gas under pressure for propelling the water through an injection system including a valve controlled conduit making fluid communication from said first tank to the nuclear reactor pressure vessel above the fuel core for supplying cooling water to the fissionable fuel during an emergency;  a second solution tank for containing a water solution of a soluble neutron absorbent compound and gas under high pressure for propelling the neutron absorbent water solution through an injection system including a valve controlled conduit making fluid communication from said second tank to the nuclear reactor pressure vessel for supplying neutron absorbent solution to the core of fissionable fuel during an emergency;  a source of high pressure compressed propelling gas having a valve controlled conduit making fluid communication therefrom to each the first water tank and the second solution tank to provide pressurized gas to the tanks for propelling their contents through their respective injection systems into the nuclear reactor pressure vessel by means of their respective valve controlled conduits;  sensing means monitoring the nuclear reactor pressure vessel operating the valves controlling flow in the conduits making fluid communication between the first water tank and the pressure vessel, and between the second solution tank and the pressure vessel; and  a propellant pressurized gas supply and distribution system comprising a fluid conveying conduit having a flow controlling valve making fluid communication between the first water tank and the second solution tank and having pressure monitoring and sensing means in both the first water tank and second solution tank for regulating an actuating mechanism operating the flow controlling valve whereby fluid flow of pressurized gas between the first water tank and the second solution tank is determined by their relative pressures.  a nuclear reactor plant including a reactor pressure vessel containing a core of fissionable nuclear fuel;  a first water tank for containing cooling water and gas under pressure for propelling the cooling water through an injection system including a valve controlled conduit making fluid communication from said first tank to the nuclear reactor pressure vessel above the fuel core contained therein for supplying supplemental cooling water to the fissionable fuel during an emergency;  a second solution tank for containing a water solution of a soluble neutron absorbent compound and a gas under high pressure for propelling water solution through an injection system including a valve controlled conduit making fluid communication from said second tank to the nuclear reactor pressure vessel adjacent to the fuel core for supplying neutron absorbent solution to the core of fissionable fuel during a emergency;  a source of high pressure compressed propelling gas having a valve controlled conduit making fluid communication therefrom to each the first water tank and the second solution tank for providing pressurized gas to each tank for propelling their liquid contents through their respective injection systems into the nuclear reactor pressure vessel by means of their respective valve controlled conduits;  sensing means monitoring conditions in the nuclear reactor pressure vessel for operating the valves controlling flow through the conduits making fluid communication between the first water tank and the pressure vessel;  a propellant pressurized gas supply and distribution system comprising a fluid conveying conduit having a flow controlling valve making fluid communication between the first water tank and the second solution tank and having pressure monitoring and sensing means in both the first water tank and second solution tank for regulating an actuating mechanism operating the flow controlling valve in the fluid conveying conduit making fluid communication between the first water tank and the second solution tank whereby fluid flow of pressurized gas between the first water tank and the second solution tank is determined by their relative pressures; and  liquid level measuring means for monitoring the level of a liquid within each the first water tank and the second solution tank and regulating valve activating mechanisms operating a first flow control valve in the conduit making fluid communication from said first tank to the nuclear reactor pressure vessel, and a second flow control valve in the conduit making fluid communication from said second solution tank to the nuclear reactor pressure vessel, said first and second flow control valves terminating fluid flow from said tanks to the pressure vessel when a predetermined low level of liquid within the respective tank occurs.  a nuclear reactor plant including a reactor pressure vessel containing a core of fissionable nuclear fuel;  a first water tank for containing cooling water and gas under pressure for propelling the water through an injection system including a valve controlled conduit making fluid communication from said first water tank to the nuclear reactor pressure vessel above the fuel core for supplying cooling water to the fissionable fuel during an emergency;  a second solution tank for containing a water solution of a soluble neutron absorbent comprised compound and gas under high pressure for propelling the neutron absorbent water solution through an injection system including a valve controlled conduit making fluid communication from said second solution tank to the nuclear reactor pressure vessel for supplying neutron absorbent solution to the core of fissionable fuel during an emergency;  a source of high pressure compressed propelling gas having a valve controlled conduit making fluid communication therefrom to each the first water tank and the second solution tank to provide pressurized gas to the tanks for propelling their contents through their respective injection system into the reactor pressure vessel by means of their respective valve controlled conduits;  sensing means monitoring the nuclear reactor pressure vessel and operating the valves controlling fluid flow in the conduits making fluid communication between the first water tank and the reactor pressure vessel, and between the second solution tank and the reactor pressure vessel;  a propellant pressurized gas supply and distribution system comprising a fluid conveying conduit having a flow controlling valve making fluid communication between the first water tank and the second solution tank and having pressure monitoring and sensing means in both the first water tank and second solution tank for regulating an actuating mechanism operating the flow controlling valve in the fluid conveying conduit making fluid communication between said first and second tanks whereby fluid flow of pressurized gas between the first water tank and the second solution tank can be determined by their relative pressure;  liquid level measuring means for monitoring the level of a liquid within each of the first water tank and the second solution tank, a regulating valve activating mechanism operating a flow control valve in the conduit making fluid communication from said first water tank to the reactor pressure vessel, and a regulating valve activating mechanism operating a flow control valve in the conduit making fluid communication from said second solution vessel to the reactor pressure vessel for selectively terminating fluid flow from said tanks to the pressure vessel when a predetermined low level of liquid occurs within a tank; and,  said first water tank and second solution tank each being provided with a liquid level measuring float valve for closing off the respective conduits making fluid communication from each tank to the nuclear reactor pressure vessel when a predetermined low level of liquid occurs within each tank. 2. A multiple liquid standby safety injection system for nuclear reactor plants of claim 1, wherein the first water tank is provided with a liquid level measuring means for monitoring the level of a liquid within the tank and regulating a valve activating mechanism operating a flow control valve in the conduit making fluid communication from said first tank to the nuclear reactor pressure vessel for terminating fluid flow from the first water tank to the pressure vessel. 3. A multiple liquid standby safety injection system for nuclear reactor plants of claim 1, wherein the second solution tank is provided with a liquid level measuring means for monitoring the level of a liquid within the tank and which regulates a valve actuating mechanism operating a flow control valve in the conduit making fluid communication from said second tank to the nuclear reactor pressure vessel for terminating fluid flow from the second solution tank to the pressure vessel. 4. A multiple liquid standby safety injection system for nuclear reactor plants of claim 1, wherein the terminal end of the conduit making fluid communication from the first water tank to the nuclear reactor pressure vessel is provided with a flow check valve in a normally closed state thereby preventing back-flow. 5. A multiple liquid standby safety injection system for nuclear reactor plants, comprising the combination of: 6. The multiple liquid standby safety injection system for nuclear reactor plants of claim 5, wherein the terminal end of the conduit making fluid communication from the first water tank to the nuclear reactor pressure vessel is provided with a flow check valve in a normally closed state thereby preventing back-flow of fluid from the nuclear reactor pressure vessel into the conduit. 7. A multiple liquid standby safety injection system for nuclear reactor plants of claim 5, wherein the first water tank is provided with a liquid level measuring float valve for closing off the conduit making fluid communication from said first water tank to the nuclear reactor pressure vessel. 8. A multiple liquid standby safety injection system for nuclear reactor plants of claim 5, wherein the second solution tank is provided with a liquid level measuring float valve for closing off the conduit from said second solution tank to the nuclear reactor pressure vessel. 9. A multiple liquid standby safety injection system for nuclear reactor plants of claim 5, wherein the valve controlled conduits making fluid communication respectively from the first and second tanks to the nuclear reactor pressure vessel each include dual parallel control valves. 10. A multiple liquid standby safety injection system for nuclear reactor plants, comprising the combination of: 11. A multiple liquid standby safety injection system for nuclear reactor plants of claim 10, wherein the valve controlled conduits making fluid communication respectively from the first water tank and the second solution tank to the reactor pressure vessel each include dual parallel control valves. 12. A multiple liquid standby safety injection system for nuclear reactor plants of claim 10, wherein the terminal end of the conduit making fluid communication from the first water tank to the nuclear reactor pressure vessel is provided with a flow check valve located entirely within said reactor vessel and which prevents back-flow of fluid from the nuclear reactor pressure vessel into the conduit. 13. A multiple liquid standby safety injection system for nuclear reactor plants of claim 10, wherein the valve controlled conduit making fluid communication from the first water tank and the second solution tank includes a squib-type valve. 14. A multiple liquid standby safety injection system for nuclear reactor plants of claim 10, wherein the conduit making fluid communication from the first water tank and the second solution tank comprises at least one squib-type flow controlling valve operated by a logic system signal. 15. A multiple liquid standby safety injection system for nuclear reactor plants of claim 10, where the conduit making fluid communication from the first water tank to the second solution tank comprises multiple flow control valves with at least one explosive operated valve. 16. A multiple liquid standby safety injection system for nuclear reactor plants of claim 12, wherein the flow check valve in the terminal end of the conduit making fluid communication from the first water tank to the nuclear reactor pressure vessel is in a normally closed state.