Patent Number: 047073241
Section: claims

1. Apparatus for controlling the response to a load signal of a pressurized water reactor having a plurality of controlled process variables, said apparatus comprising: a control system for effecting control actions to regulate a selected process variable to a value called for by a setpoint reference signal; and  means responsive only to rapid fluctuations in said load signal above a predetermined frequency for adjusting the value of said setpoint reference signal by an amount which substantially matches the variation in the value of the selected process variable expected as a result of said rapid fluctuations in the load signal without control action, and taking into account any time delay in the affect of the rapid fluctuations on the selected process variable, whereby control actions effected by said control system are substantially reduced.  generating setpoint signals for said control systems;  operating said control system to effect control actions which regulate the associated process variables to the value called for by the associated setpoint signal;  generating a load signal representative of the load imposed on the reactor;  generating from said load signal a rapid fluctuation signal representative of the magnitude of fluctuations in the load signal above a predetermined frequency; and  adjusting the magnitude of at least one of said setpoint signals in response to said rapid fluctuation signal by an amount which substantially matches the change in the value of the associated process variable expected as a result of said rapid fluctuations in the load signal without control action, taking into account any time delay in the affect of the load change on the value of the associated process variable, whereby the control actions required by the associated control system are significantly reduced.  generating a transfer function representative of the change required in at least one setpoint signal to effect a change in the value of the associated process variable which substantially matches the expected change in the process variable resulting from the changes in load above said predetermined frequency;  applying said transfer function to said rapid fluctuation signal to generate an adjustment signal; and  summing said adjustment signal with said at least one setpoint signal.  rod control means responsive to the load signal for positioning the control rods to regulate the power level of the reactor to the power level called for by the load signal, and including means for generating a deadband in the response of the control rods to changes in the magnitude of the load control signal by inhibiting repositioning of the control rods when the change in magnitude of the load signal is smaller than a selected change in magnitude such that the reactor adjusts to such small changes in load imposed thereon through changes in operating temperature; and  deadband adjusting means for varying the value of said selected change in magnitude of the load signal defining said deadband as a function of the magnitude of fluctuations in the load signal above a predetermined frequency, whereby the width of the deadband in the rod control means is varied with the magnitude of the rapid power changes resulting in a significant reduction in the control actions required by the rod control means.  deadband signal generating means responsive to said load signal for generating a deadband control signal as a function of the magnitude of fluctuations in the load signal above a predetermined frequency;  reference means for generating a temperature reference signal from said load signal; and  rod control means response to the magnitude of the temperature reference signal (T.sub.REF) for positioning said control rods and including deadband control means responsive to said deadband control signal for inhibiting the response of the control rods to the temperature reference signal (T.sub.REF) when the difference between actual temperature and the temperature called for by the temperature reference signal is less than said deadband control signal, whereby the deadband in the response of the control rods to changes in the load signal varies as a function of the magnitude of rapid load changes resulting in a significant reduction in the control actions required by the rod control means.  positioning the control rods as a function of the change in magnitude of the load signal when the magnitude of such change exceeds a selected value, such than there is a deadband in the response of the control rods to changes in magnitude of the load signal which causes the reactor to respond to changes in magnitude smaller than the selected value through a change in reactor operating temperature; and  varying said selected value as a function of the magnitude of fluctuations in the magnitude of the load signal above a predetermined frequency whereby positioning of the control rods is substantially reduced. 2. The apparatus of claim 1 wherein said setpoint reference signal adjusting means includes means for limiting the amount by which said setpoint signal is adjusted to a predetermined value whereby control actions are effected by said control system in response to rapid fluctuations in said load signal which are of large magnitude. 3. The apparatus of claim 2 wherein said pressurized water reactor supplies steam to a turbine-generator set having an impulse chamber, wherein said apparatus includes means for generating said load signal as a function of the steam pressure in said impulse chamber and wherein the setpoint reference signal adjusting means adjusts the amount by which the setpoint signal is adjusted as a function of time taking into account the lag in time in the response of the selected variable to a change in impulse chamber steam pressure. 4. The apparatus of claim 1 wherein said pressurized water reactor includes control rods, wherein said control system positions the control rods to regulate the reactor power level in response to a temperature reference setpoint signal and includes means for generating said temperature reference setpoint signal as a function of said load signal, and wherein said setpoint signal adjusting means adjusts said temperature reference setpoint signal by an amount which results in a change in reactor power level through a change in reactor temperature rather through repositioning of the control rods. 5. The apparatus of claim 4 wherein said rod control system includes means for generating a deadband in the response of the control rods to said temperature reference setpoint signal by inhibiting repositioning of the control rods in response to changes in the temperature reference setpoint signal below a predetermined magnitude. 6. The apparatus of claim 5 wherein said deadband generating means comprises means for varying the width of said deadband as a function of the magnitude of the changes in the temperature reference setpoint signal above said predetermined frequency. 7. The apparatus of claim 1 wherein said pressurized water reactor includes a primary coolant loop and a pressurizer for maintaining a programmed pressure in the primary coolant loop, and wherein said control system includes means responsive to a pressure reference setpoint signal for regulating pressurizer pressure and said adjusting means is responsive to fluctuations in said load signal above said predetermined frequency to adjust the pressure reference setpoint signal by an amount which corresponds to the expected variation in pressurizer pressure as a result of the rapid fluctuations in the load signal. 8. The apparatus of claim 7 wherein said adjusting means includes means for adjustment of the pressure reference setpoint signal in response to rapid fluctuations in the load signal when the pressurizer pressure is above a predetermined magnitude. 9. The apparatus of claim 8 wherein said adjusting means includes means for limiting the amount by which the pressure setpoint signal is adjusted to a predetermined value. 10. A method of operating a pressurized water reactor having a plurality of control systems controlling a plurality of process variables, said method comprising the steps of: 11. The method of claim 10 wherein said adjusting step comprises the steps of: 12. The method of claim 11 including the step of limiting the magnitude of the correction signal to a preselected value. 13. The method of claim 12 including the steps of measuring the selected process variable and applying said correction signal to the setpoint signal only when said selected process variable is below a preselected value. 14. The method of claim 12 including the steps of operating said control system so that control action is only effected when the change in magnitude of the setpoint signal exceeds a preset value so that there is a deadband in the response of the control system. 15. The method of claim 14 including the step of adjusting the width of said deadband as a function of the magnitude of the fluctuations in said load signal above said predetermined frequency. 16. The method of claim 15 wherein said pressurized water reactor includes a reactor coolant loop, wherein said selected process variable is coolant temperature, wherein said control system effects changes in coolant temperature by repositioning control rods in the reactor and wherein said setpoint signal is a temperature reference signal generated as a function of said load signal. 17. The method of claim 13 wherein said pressurized water reactor includes a reactor coolant loop and a pressurizer controlled by said at least one control system to regulate the pressure in the reactor coolant loop, and wherein the setpoint signal represents a programmed value for the pressurizer pressure. 18. Apparatus for controlling the response of a pressurized water nuclear reactor, having control rods for controlling the reactor power level, to rapid fluctuations in a load signal representative of the load imposed on the reactor, said apparatus comprising: 19. The apparatus of claim 18 wherein said means for varying the value of said selected change in magnitude of the load signal defining the deadband includes means for increasing the value of the selected change as the magnitude of the fluctuations in the load signal above the predetermined frequency increases. 20. The apparatus of claim 19 including means for generating a temperature reference signal (T.sub.REF) from said load signal and wherein said rod control means positions the control rods in response to said temperature reference signal, said apparatus also including protection means for generating temperature limits for operation of the reactor and limit means responsive to the deadband adjusting means and the protection means for maintaining the temperature reference signal (T.sub.REF) at a value which prevents the reactor operating temperature from exceeding said temperature limits despite the variations in the width of said deadband. 21. Apparatus for controlling the response to a load signal of a pressurized water nuclear reactor having control rods for regulating the power level of the reactor said apparatus comprising: 22. The apparatus of claim 21 including protection means responsive to the operating conditions of the reactor for generating a temperature limit signal representative of the maximum operating temperature of the reactor for existing conditions and limit means for generating a maximum temperature reference signal by substracting the deadband control signal from the temperature limit signal and wherein said reference means includes means responsive to said load signal for generating a load temperature reference signal and means for selecting the smaller of said load temperature reference signal and the maximum temperature reference signal as said temperature reference signal. 23. The apparatus of claim 22 wherein said deadband signal generating means includes high pass filter means for extracting from the load signal a signal representative of the magnitude of fluctuations in the load signal above said predetermined frequency, means for generating a signal representative of the average squared value of said extracted signal and means for generating therefrom a temperature related deadband control signal which varies in magnitude in terms of degrees of operating temperature as a function of the magnitude in said fluctuations in said load signal. 24. The apparatus of claim 23 including means for generating a deadband control signal of fixed magnitude, and selection means responsive to the magnitude of the fluctuation of said load signal above a preset level for selecting said signal of fixed magnitude for said deadband control signal in place of said variable deadband control signal. 25. The apparatus of claim 24 wherein said selection means includes switch means response to said average squared value signal for selecting said signal of fixed magnitude as said deadband control signal when said average squared value signal exceeds a preset level. 26. A method of operating a pressurized water nuclear reactor having control rods for regulating reactor power in response to a load signal representative of the load imposed on the reactor including the steps of: 27. The method of claim 26 wherein the step of positioning the control rods comprises the steps of: generating a temperature reference signal from the load signal, measuring the reactor temperature, comparing the temperature reference signal to the measured signal and positioning the control rods as a function of the difference therebetween when said difference exceeds said selected value. 28. The method of claim 27 wherein the step of varying the selected value of said difference between the temperature reference signal and the measured temperature signal which defines said deadband comprises: extracting the fluctuations in the load signal above said predetermined frequency from said load signal, generating a signal representative of an average squared value of the magnitude of said fluctuations and varying the selected value defining said deadband as a temperature function of said average squared value signal. 29. The method of claim 28 including monitoring the operation of the reactor and generating a signal representative of a limiting value for the reactor temperature as a function of existing conditions, and wherein the step of generating said temperature reference signal includes limiting the magnitude thereof to a value which will maintain the reactor temperature below said reactor temperature limit taking into account the width of said deadband as represented by said selected value of the difference between the temperature reference signal and the reactor measured temperature. 30. The method of claim 29 wherein the step of generating the temperature reference signal includes generating a load derived temperature reference signal from the load signal and wherein said step of limiting the temperature reference signal includes the steps of: subtracting the temperature function of the average squared value signal from the reactor temperature limit signal to generate a maximum temperature reference signal and selecting the smaller of the load derived temperature reference signal and the maximum temperature reference signal as the temperature reference signal. 31. The method of claim 30 including the step of monitoring the magnitude of the average squared value signal and substituting a deadband signal of fixed magnitude for said temperature function of the average squared value signal as the selected value defining said deadband when the magnitude of the average squared value signal exceeds a prechosen level.