Patent Number: 047388188
Section: claims

1. A method of operating a PWR comprising the steps of: generating a main feedwater flow control signal as a function of steam generator level;  generating an alternative main feedwater flow control signal as a function of reactor coolant T.sub.avg ;  controlling main feedwater flow with the flow control signal generated as a function of steam generator level with the PWR at power; and  controlling main feedwater flow with the alternate flow control signal generated as a function of T.sub.avg following a reactor trip in a manner which avoids isolating main feedwater flow and activating an auxiliary feedwater system.  monitoring steam generator level;  controlling feedwater flow to the steam generator from a main feedwater system as a programmed function of water level;  monitoring reactor coolant T.sub.avg, isolating the main feedwater system when T.sub.avg falls to a Low T.sub.avg set point value, and actuating an auxiliary feedwater system when the steam generator level falls to a low low level set point level;  the improvement comprising:  monitoring reactor operation for a reactor trip and in response thereto;  terminating control of feedwater flow as a programmed function of steam generator level; and instead,  controlling the flow of feedwater to the steam generator from the main feedwater system as a programmed function of T.sub.avg in a manner which avoids isolating the main feedwater system and activating the auxiliary feedwater system.  maintaining control of feedwater flow as a programmed function of T.sub.avg while attempting to restart the tripped reactor, and following restart, continuing control of feedwater flow as a programmed function of T.sub.avg until the steam generator level reaches a predetermined level, and transferring back to controlling main feedwater flow as a programmed function of steam generator level when said predetermined steam generator level is reached.  a steam generator;  a main feedwater system for supplying feedwater to the steam generator;  a reactor which heats reactor coolant for circulatin through the steam generator to convert the feedwater to steam;  means for monitoring reactor coolant temperature and determining a T.sub.avg ;  means responsive to reactor coolant T.sub.avg for isolating the main feedwater system from the steam generator when reactor coolant temperature decreases to a selected Low T.sub.avg set poit value;  an auxiliary feedwater system;  means for monitoring steam generator level;  means responsive to steam generator level for activating said auxiliary feedwater system when steam generator level decreases to a low-low level set point value; and  flow control means for controlling flow of feedwater from the main feedwater system to the steam generator as a programmed function of the monitored steam generator level and responsive to a reactor trip for controlling main feedwater flow instead as a programmed function of reactor coolant T.sub.avg which function decreases flow as T.sub.avg decreases, and terminates flow before T.sub.avg decreases to the Low T.sub.avg set point value, whereby activation of the main feedwater system isolation means and of the auxiliary feedwater system are avoided. 2. The method of claim 1 wherein the step of generating a flow control signal as a function of reactor coolant T.sub.avg comprises generating a signal which decreases with decreasing T.sub.avg and terminates flow at a T.sub.avg which is above a selected Low T.sub.avg value at which the main feedwater system is isolated. 3. The method of claim 1 wherein the step of generating a main feedwater flow control signal as a function of steam generator level includes applying integral control action thereto, said method including the additional steps of transferring control back to control of main feedwater flow with said signal generated as a function of steam generator level when said steam generator level reaches a predetermined level with flow controlled with said alternate flow control signal, and slaving the signal generated as a function of steam generator level to the alternate signal while said latter signal is being used to control main feedwater flow, whereby a bumpless transfer is effected upon transfer from said alternate signal to the signal generated as a function of steam generator level. 4. In a method of controlling the flow of feedwater to a steam generator in a pressurized water reactor comprising the steps Of: 5. The method of claim 1 wherein the step of controlling the flow of feedwater to the steam generator from the main feedwater system as a programmed function of T.sub.avg comprises reducing the flow with decreasing T.sub.avg below a preselected value of T.sub.avg and terminating flow at a value of T.sub.avg which is above said Low T.sub.avg set point. 6. The method of claim 5 including the step of reducing the Low T.sub.avg set point to a value which is below a preselected no load T.sub.avg value. 7. The method of claim 6 wherein the step of terminating flow at a value of T.sub.avg which is above said Low T.sub.avg set point includes selecting a value of T.sub.avg for termination of flow which is below the preselected no load T.sub.avg value. 8. The method of claim 5 including the step of: 9. The method of claim 8 wherein said predetermined steam generator level is a preselected no load level. 10. The method of claim 5 including the step of lowering the low-low level set point below the lowest level reached by a dip in steam generator level when steam flow is terminated following a reactor trip and before a steam dump system is activated to reestablish steam flow, in order to avoid actuation of said auxiliary feedwater system on said dip. 11. The method of claim 5 wherein the step of monitoring steam generator level includes providing a level signal filtered to prevent a dip in steam generator level from reaching the low-low level set point when steam flow is terminated following a reactor trip and before a steam dump system is activated to reestablish steam flow, to avoid activating the auxiliary feedwater system on said dip. 12. The method of claim 5 including the step of delaying activating of the auxiliary feedwater system on a low-low level signal for an interval following a reactor trip sufficient in duration to allow the steam generator level to recover from an initial dip in level resulting from termination of steam flow through reestablishment of steam flow by operation of a steam dump. 13. Apparatus comprising; 14. The apparatus of claim 13 wherein said flow control includes means for generating a flow control signal programmed as a function of steam generator level, means for generating a flow control signal programmed as a function of reactor coolant T.sub.avg, and means responsive to a reactor trip for comparing the level programmed and T.sub.avg programmed flow control signal and for controlling flow with the programmed signal having the lowest magnitude. 15. The apparatus of claim 13 wherein said means for monitoring steam generator level generates a steam generator level signal and wherein said means for activating the auxiliary feedwater system includes means for comparing the level signal with a low-low set point signal and for activating the auxiliary feedwater system when the level signal falls to the value of the set point signal, and further including means for delaying the level signal for a duration which exceeds the duration of an initial dip in steam generator level following the reactor trip. 16. The apparatus of claim 13 wherein said means for monitoring steam generator level generates a steam generator level signal and wherein said means for activating the auxiliary feedwater system includes means for comparing the steam generator level signal with a low-low set point signal and for activating the auxiliary feedwater system when the level signal, falls to the value of the low-low set point signal, and further including means for filtering the steam generator level signal such that it does not fall to the value of the set point signal in response to an initial dip in steam generator flow following a reactor trip resulting from the termination of steam flow and before steam flow is reestablished by the dumping of steam.