Patent Number: 047770090
Section: claims

1. In a pressurized water nuclear reactor steam supply system having a recirculation type steam generator including a variable speed feedwater pump, a main feedwater valve and a bypass feedwater valve, a method for controlling the water level in the steam generator comprising: measuring the steam flow out of the steam generator and generating a steam flow signal commensurate with the steam flow;  measuring the feedwater flow into the steam generator and generating a feedwater flow signal commensurate with the feedwater flow;  measuring the water level in the steam generator and generating a water level signal commensurate with the water level;  measuring the reactor power and generating a power signal commensurate with the reactor power;  passing the water level signal through a a first adaptive network, wherein the control coefficients in said first network have a functional form dependent on said power signal, the output of said first network representing a dynamically compensated level signal;  comprising the steam flow signal with the feedwater flow signal and passing the difference through a first proportional/integral circuit to generate a compensated flow error signal;  comparing the compensated level signal with the compensated flow error signal to generate a flow demand signal;  controlling the steam generator water level as a function of said flow demand signal, through a logic scheme including three power regimes corresponding to low, intermediate, and high power levels, wherein,  whereby the operation of said feedwater pump, bypass valve and main valve determine the water level in the steam generators during operation of the nuclear steam supply system.  measuring the average temperature of the primary side water and generating a temperature signal commensurate with the average temperature;  setting a flat when the reactor has been tripped; and  refilling the steam generator after a reactor trip to a threshold normal water level by controlling the feedwater flow rate only as a function of the primary side water temperature signal, and after the threshold water level is reached, controlling the feedwater flow rate on said flow demand signal. 2. The control method of claim 1 wherein the flow demand signal is passed through a second adaptive network in which the control coefficient are functions of said power signal to generate a compensated flow demand signal for delivery to said logic scheme. 3. The control method of claim 1 wherein said system includes a primary side water volume having a hot leg through which water exits the reactor and enters the steam generator and a cold leg through which water exits the steam generator and enters the reactor, further including the steps of 4. The control method of claim 1, wherein the step of passing the water level signal through said first adaptive network includes passing the water level signal through a lead/lag circuit. 5. The control method of claim 1, wherein the step of passing the water level signal through a first adaptive network includes passing the signal through a circuit in which at least one of the control coefficients has a non-linear dependence on said power signal. 6. The control method of claim 4, wherein the flow demand signal is passed through a second proportional integral circuit in which the gain and reset rate are functions of said power signal. 7. The control method of claim 2, wherein the step of passing the flow demand signal through a second adaptive network includes passing the flow demand signal through a second proportional/integral circuit and wherein the gain and reset rate of said second proportional/integral circuit are functions of said power level. 8. The control method of claim 1 wherein each of the feedwater pump, bypass valve, and main valve are modulated by a functional dependence on said flow demand signal. 9. The control method of claim 8, wherein the step of controlling the steam generator water level through a logic scheme includes the step of opening or closing the main valve in accordance with a switchover circuit responsive to said power signal. 10. The control method of claim 9, wherein the step of controlling the steam generator water level through said logic scheme includes the step of closing or opening the bypass valve in accordance with a second switchover circuit responsive to said power signal. 11. The control method of claim 1 further including the step of passing the compensated flow error signal through a switchover circuit responsive to said power signal, wherein the compensated flow error signal is omitted from the step of comparing the compensated level signal with the compensated flow error signal, when the power signal is in said low power regime. 12. The control method of claim 4, wherein the step of passing said water level signal through a first adaptive network includes passing the level signal through a circuit having an output defined by a LaPlace transform that has the form (T.sub.3 S+1)/(T.sub.4 S+1), and, T.sub.3, T.sub.4 are the control coefficients that are functions of said power signal. 13. The control method of claim 6, wherein the step of passing the flow demand signal through a second proportional/integral circuit includes passing the flow demand signal through a circuit having an output defined by a LaPlace transform that has the form K[1+1/T.sub.8 S], where S is LaPlace's function and K and, T.sub.8 are functions of said power signal. 14. The control method of claim 5 wherein the flow demand signal is passed through a second adaptive network comprising a second proportional/integral circuit in which the gain and reset rate are nonlinear functions of said power level, to generate a compensated flow demand signal for delivery to said logic scheme. 15. The control method of claim 14 wherein each of the feed water pump, bypass valve, and main valve are modulated by a functional dependence on said compensated flow demand signal. 16. The control method of claim 15, wherein the step of controlling the steam generator water level through a logic scheme includes the step of opening or closing the main valve in accordance with a switchover circuit responsive to said power signal. 17. The control method of claim 6, wherein the step of controlling the steam generator water level through said logic scheme includes the step of closing or opening the bypass valve in accordance with a second switchover circuit responsive to said power signal.