Patent Number: 056217765
Section: claims

1. A system for initiating safety action in response to monitoring of a critical parameter, comprising: first through fourth sensors for independently detecting the value of a critical parameter and outputting first through fourth sensor readings respectively;  first through fourth division electronics respectively connected to said sensors for processing said first through fourth sensor readings respectively; and  cross communication channels for interconnecting said first through fourth division electronics such that each one of said first through fourth division electronics receives the processed sensor readings from the other division electronics,  wherein said first division electronics comprises means for determining when its own sensor reading is not valid due to a fault, means for storing its own valid sensor reading as a spare, means for outputting a safety actuation inhibition signal, and means for terminating the output of said safety actuation inhibition signal in response to any two of three valid sensor readings communicated from said second, third and fourth division electronics being in excess of a set point, or in response to an invalid or missing sensor reading from one of said second, third and fourth division electronics and at least two of three valid sensor readings--consisting of the spare valid sensor reading and the two valid sensor readings from the remaining two of said second, third and fourth division electronics--being in excess of said set point.  a respective ac-powered battery charger for supplying dc power via respective isolation diodes to said corresponding division electronics and one other division electronics during normal operation, each battery charger receiving ac power from a respective ac power bus, each ac power bus in turn receiving ac power from dual ac power sources, and  a respective backup battery for supplying dc power to said corresponding division electronics and said one other division electronics via said isolation diodes in the event that ac power should fail, said respective battery being charged by said respective battery charger during normal operation.  first through fourth sensors for independently detecting the value of a critical parameter and outputting first through fourth sensor readings respectively;  first through fourth division electronics respectively connected to said sensors for processing said first through fourth sensor readings respectively, each of said first through fourth division electronics comprising means for determining when its own sensor reading is not valid due to a fault and means for outputting a safety actuation inhibition signal; and  cross communication channels for interconnecting said first through fourth division electronics such that each one of said first through fourth division electronics receives the processed sensor readings from the other division electronics,  wherein said first division electronics comprises means for terminating the output of a safety actuation inhibition signal in response to receipt from at least two of said second through fourth division electronics of sensor readings in excess of a set point when all of said first through fourth division electronics are in service; or in response to the following set of conditions: (a) one of said second through fourth division electronics is out of service; (b) the sensor readings from at least two of the remaining three division electronics are valid; and (c) at least two of said three valid sensor readings are in excess of said set point.  a respective ac-powered battery charger for supplying dc power via respective isolation diodes to said corresponding division electronics and one other division electronics during normal operation, each battery charger receiving ac power from a respective ac power bus, each ac power bus in turn receiving ac power from dual ac power sources, and  a respective backup battery for supplying dc power to said corresponding division electronics and said one other division electronics via said isolation diodes in the event that ac power should fail, said respective battery being charged by said respective battery charger during normal operation.  first through fourth sensors for independently detecting the value of a critical reactor parameter and outputting first through fourth sensor readings respectively;  first through fourth division electronics respectively connected to said sensors for processing said first through fourth sensor readings respectively, each of said first through fourth division electronics comprising means for determining when its own sensor reading is not valid due to a fault and means for outputting a scram inhibition signal; and  cross communication channels for interconnecting said first through fourth division electronics such that each one of said first through fourth division electronics receives the processed sensor readings from the other division electronics;  wherein each of said first through fourth division electronics further comprises means for selectively terminating the output of said scram inhibition signal in accordance with a first routine when all of said first through fourth division electronics are in service and in accordance with a second routine different than said first routine when only three of said first through fourth division electronics are in service, each of said first and second routines requiring the presence of at least two valid sensor readings in excess of a set point before terminating the output of said scram inhibition signal. 2. The system as defined in claim 1, wherein said safety actuation inhibition signal terminating means of said first division electronics alternatively terminates a safety actuation inhibition signal in response to an invalid or missing sensor reading from two of said second, third and fourth division electronics and either one of two valid sensor readings--consisting of the spare valid sensor reading and the valid sensor reading from the remaining one of said second, third and fourth division electronics--being in excess of said set point. 3. The system as defined in claim 1, further comprising a hardware logic circuit connected to receive an output from each of said first through fourth division electronics, wherein said hardware logic circuit changes from a normal state to a safety actuation state in response to discontinuance of receipt of safety actuation inhibition signals from at least two of said first through fourth division electronics. 4. The system as defined in claim 3, further comprising a safety actuator and redundant first and second actuator power supply circuits, wherein said safety actuator is coupled to said first and second actuator power supply circuits via said hardware logic circuit. 5. The system as defined in claim 4, wherein said hardware logic circuit comprises first through fourth sets of circuit breakers each having an open state and a closed state and electrical connections for connecting the circuit breakers within each of said first through fourth sets in series, the state of the circuit breakers of said first through fourth sets being respectively controlled as a function of the results of processing said first through fourth sensor readings by said first through fourth division electronics respectively. 6. The system as defined in claim 5, further comprising first through fourth instrumentation vaults for respectively housing said first through fourth division electronics and said first through fourth sets of circuit breakers, wherein said cross communication channels and said electrical connections penetrate the walls of said instrumentation vaults, and said first and second power supply circuits are respectively housed in said first and second instrumentation vaults. 7. The system as defined in claim 4, wherein said hardware logic circuit comprises first through fourth sets of circuit breakers having an open state and a closed state and electrical connections for connecting the circuit breakers within each of said first through fourth sets in series, the state of the circuit breakers of said first through fourth sets being respectively controlled as a function of the results of processing said first through fourth sensor readings by said first through fourth division electronics respectively. 8. The system as defined in claim 7, further comprising first through fourth instrumentation vaults for respectively housing said first through fourth division electronics and said first through fourth sets of circuit breakers, wherein said cross communication channels and said electrical connections penetrate the walls of said instrumentation vaults, and said first and second power supply circuits are respectively housed in said first and second instrumentation vaults. 9. The system as defined in claim 1, further comprising first through fourth dc electrical power supply circuits, and first through fourth instrumentation vaults for respectively housing said first through fourth division electronics and said first through fourth dc electrical power supply circuits, wherein said first division electronics receives dc electrical power from said first and fourth dc electrical power supply circuits, said second division electronics receives dc electrical power from said first and second dc electrical power supply circuits, said third division electronics receives dc electrical power from said second and third dc electrical power supply circuits, and said fourth division electronics receives dc electrical power from said third and fourth dc electrical power supply circuits. 10. The system as defined in claim 9, wherein each of said first through fourth dc electrical power supply circuits comprises: 11. A system for initiating safety action in response to monitoring of a critical parameter, comprising: 12. The system as defined in claim 11, further comprising a hardware logic circuit which changes from a normal state to a safety actuation state in response to discontinuance of receipt of safety actuation inhibition signals from at least two of said first through fourth division electronics. 13. The system as defined in claim 12, further comprising a safety actuator and redundant first and second actuator power supply circuits, wherein said safety actuator is coupled to said first and second actuator power supply circuits via said hardware logic circuit. 14. The system as defined in claim 11, further comprising first through fourth dc electrical power supply circuits, and first through fourth instrumentation vaults for respectively housing said first through fourth division electronics and said first through fourth dc electrical power supply circuits, wherein said first division electronics receives dc electrical power from said first and fourth dc electrical power supply circuits, said second division electronics receives dc electrical power from said first and second dc electrical power supply circuits, said third division electronics receives dc electrical power from said second and third dc electrical power supply circuits, and said fourth division electronics receives dc electrical power from said third and fourth dc electrical power supply circuits. 15. The system as defined in claim 14, wherein each of said first through fourth dc electrical power supply circuits comprises: 16. A reactor protection system for initiating a scram in a nuclear reactor in response to monitoring of a critical reactor parameter, comprising: 17. The reactor protection system as defined in claim 16, wherein said first division electronics further comprises means for storing its own valid sensor reading as a spare, and means for terminating the output of said scram inhibition signal in response to any two of three valid sensor readings communicated from said second, third and fourth division electronics being in excess of a set point, or in response to an invalid or missing sensor reading from one of said second, third and fourth division electronics and at least two of three valid sensor readings--consisting of the spare valid sensor reading and any valid sensor reading from said second, third and fourth division electronics being in excess of said set point. 18. The reactor protection system as defined in claim 17, wherein said scram inhibition signal terminating means of said first division electronics alternatively terminates a scram inhibition signal in response to an invalid or missing sensor reading from two of said second, third and fourth division electronics and either one of two valid sensor readings consisting of the spare valid sensor reading and the valid sensor reading from the remaining one of said second, third and fourth division electronics--being in excess of said set point. 19. The reactor protection system as defined in claim 16, further comprising a hardware logic circuit connected to receive an output from each of said first through fourth division electronics, wherein said hardware logic circuit changes from a normal state to a scram state in response to discontinuance of receipt of scram inhibition signals from at least two of said first through fourth division electronics. 20. The reactor protection system as defined in claim 19, further comprising a safety actuator and an actuator power supply circuit, wherein said safety actuator is coupled to said actuator power supply circuit via said first hardware logic circuit, and said first hardware logic circuit comprises circuit breakers for selectively making or breaking the electrical connection between said safety actuator and said actuator power supply circuit in response to receipt of scram signals from at least two of said first through fourth division electronics.