Patent Number: 039986934
Section: claims

1. In a thermal damage protection system for a nuclear steam supply system, said steam supply system including a reactor core having channels therein through which a coolant is circulated, said steam supply system further including sensors for generating signals commensurate with the coolant temperature and means for measuring and providing a signal commensurate with core power as a function of measured neutron flux, the nuclear steam supply system also including means for sensing and generating signals commensurate with neutron flux at a plurality of locations adjacent the core, the improvement comprising: means responsive to signals commensurate with coolant temperature upstream and downstream of the reactor core for generating a signal commensurate with core power as a function of the thermal energy added to the coolant;  first comparator means responsive to said signal commensurate with core power as a function of added thermal energy and to a signal commensurate with core power as a function of measured neutron flux for selecting the power signal commensurate with the higher power level;  means responsive to the power signal selected by said selecting means for generating a first compensation signal which varies as a function of core radial peaking factor;  means responsive to signals commensurate with neutron flux sensed at a plurality of locations adjacent the core for generating a second compensation signal which varies as a function of the axial distribution of power in the core;  means responsive to said selected power and first and second compensation signals for generating a core power signal compensated for axial and radial peaking factors; and  means responsive to said compensated power signal and to a signal commensurate with the coolant temperature upsteam of the reactor core for generating a signal commensurate with the core thermal limit as a function of a coolant pressure.  means responsive to said signal commensurate with power as a function of added thermal energy and to a signal commensurate with core downstream coolant temperature for generating a signal commensurate with the coolant pressure at which temperature saturation will occur; and  second comparator means responsive to said signal commensurate with saturation pressure and to said signal commensurate with core thermal limit as a function of coolant pressure for providing a pressure trip point signal commensurate with the instantaneously maximum one of the compared signals.  means for correcting the upstream coolant temperature signal to compensate for stratification effects before applying said temperature signal to said thermal limit signal generating means.  means for correcting the upstream coolant temperature signal to compensate for stratification effects before applying said temperature signal to said thermal limit signal generating means.  means responsive to said signal commensurate with power as a function of added thermal energy for generating a stratification compensation signal;  means responsive to said stratification compensation signal and a signal commensurate with core downstream coolant temperature for adjusting said temperature signal as a function of said stratification compensation signal; and  means for varying said adjusted downstream temperature signal in accordance with the relationship between temperature and the known reactor cooling system pressure at which temperature saturation occurs to generate a saturation pressure signal.  means third comparator responsive to a plurality of signals commensurate with coolant temperature downstream of the reactor core for selecting a signal commensurate with maximum coolant temperature for application to said stratification compensation signal generating means.  first function generator means; and  means for adjusting said first function generator means in accordance with the circulator pump operating configuration whereby a radial peaking factor signal which varies with coolant flow rate is generated.  means for generating a signal commensurate with average control rod position;  first function generator means responsive to said average rod position signal for generating a first variable bias signal; and  means responsive to said variable bias signal and to said selected power signal for generating said first compensation signal.  means responsive to signals commensurate with measured neutron flux for generating a signal commensurate with axial power offset;  function generator means, said function generator means being responsive to said axial power offset signal for generating said second compensation signal; and  means for adjusting the output of said function generator means in response to the circulator pump operating configuration.  means responsive to signals commensurate with measured neutron flux for generating a signal commensurate with axial power offset;  second function generator means, said second function generator means being responsive to said axial power offset signal for generating said second compensation signal; and  means for adjusting the output of said second function generator means in response to the circulator pump operating configuration.  means responsive to signals commensurate with measured neutron flux for generating a signal commensurate with axial power offset;  function generator means, said function generator means being responsive to said axial power offset signal for generating said second compensation signal; and  means for adjusting the output of said function generator means in response to the circulator pump operating configuration.  means responsive to said signal commensurate with power as a function of added thermal energy and to a signal commensurate with core downstream coolant temperature for generating a signal commensurate with the coolant pressure at which temperature saturation will occur; and  second comparator means responsive to said signal commensurate with saturation pressure and to said signal commensurate with core thermal limit as a function of coolant pressure for providing a pressre trip point signal commensurate with the instantaneously maximum one of the compared signals.  means responsive to said signal commensurate with power as a function of added thermal energy and to a signal commensurate with core downstream coolant temperature for generating a signal commensurate with the collant pressure at which temperature saturation will occur; and  second comparator means responsive to said signal commensurate with saturation pressure and to said signal commensurate with core thermal limit as a function of coolant pressure for providing a pressure trip point signal commensurate with the instantaneously maximum one of the compared signals.  means for modifying said signal commensurate with upstream coolant temperature in accordance with a constant which changes with the circulator pump configuration;  means for modifying said compensated core power signal in accordance with a constant which changes with the circulator pump configuration;  means for combining said modified upstream temperature and selected power signals to generate said core thermal limit signal.  means for modifying said signal commensurate with upstream coolant temperature in accordance with a coolant which changes with the circulator pump configuration;  means for modifying said compensated core power signal in accordance with a constant which changes with the circulator pump configuration;  means for combining said modified upstream temperature and selected power signals to generate said core thermal limit signal.  means for generating a minimum coolant pressure signal; and  means for applying said minimum coolant pressure signal as a third input to said second comparator means.  means for generating a minimum coolant pressure signal; and  means for applying said minimum coolant pressure signal as a third input to said second comparator means.  means for generating a minimum coolant pressure signal; and  means for applying said minimum coolant pressure signal as a third input to said second comparator means.  means for correcting the upstream coolant temperature signal to compensate for stratification effects before applying said temperature signal to said thermal limit signal generating means.  means for correcting the upstream coolant temperature signal to compensate for stratification effects before applying said temperature signal to said thermal limit signal generating means.  means for generating a signal commensurate with the thermal energy added to the circulating fluid in the system;  means responsive to said signal commensurate with added thermal energy for generating a variable stratification bias signal;  means for generating a signal commensurate with maximum system circulating fluid temperature;  means responsive to said generated bias and temperature signals for generating a temperature signal calibrated for stratification effects; and  means for varying said calibrated temperature signal in accordance with the relationship between temperature and the system pressure at whih temperature saturation occurs to provide a saturation pressure signal.  means for sensing and generating signals proportional to the temperature of the circulating fluid upstream and downstream of the heat source of the steam supply system; and  means responsive to said temperature signals for generating a signal commensurate with power as a function of added thermal energy.  means for varying said power signal as a function of the selected fluid flow rate prior to application to said bias signal generating means.  adjusting a measured value of core power to compensate for core radial peaking factor and the axial distribution of power in the core;  computing the thermal margin set point as a function of the temperature of a coolant circulated through the reactor core as measured upstream of the core and core power compensated for radial peaking factor and axial power distribution, the computed thermal margin set point being indicative of the core thermal limit as a function of coolant pressure; and  comparing the computed thermal margin set point with the actual coolant pressure.  adjusting a measure of core power in accordance with a known radial peaking factor versus power curve;  calculating an axial power off-set factor as a function of the power distribution in the upper and lower halves of the reactor core; and  further adjusting the measure of core power in accordance with a point on a known axial peaking factor versus axial off-set curve corresponding to the calculated axial off-set factor.  calculating the core power as a function of coolant temperature rise across the reactor core;  measuring core power as a function of neutron flux; and  selecting the measure of core power indicative of the highest power level for adjustment in accordance with radial peaking factor and axial power distribution.  choosing the radial peaking factor versus power and axial peaking factor versus axial off-set curves as a function of the instantaneous coolant mass flow conditions for the reactor core.  correcting the computed thermal margin set point for the effects of coolant stratification.  correcting the computed thermal margin set point for the effects of coolant stratification.  calculating the pressure at which core coolant temperature saturation will occur; and  selecting the maximum of the computed thermal margin set point and temperature saturation pressure signals for comparison with the actual coolant pressure.  calculating a stratification bias factor as a function of the thermal energy added to the coolant circulating through the reactor core;  adjusting a measured value of maximum coolant temperature in accordance with the stratification bias factor; and  determining an adjustable saturation pressure corresponding to the adjusted maximum temperature, said pressure being determined in accordance with a known relationship between temperature and the system pressure at which temperature saturation occurs.  adjusting a measure of core power in accordance with a known radial peaking factor versus power curve;  calculating an axial power off-set factor as a function of the power distribution in the upper and lower halves of the reactor core; and  further adjusting the measure of core power in accordance with a point on a known axial peaking factor versus axial off-set curve corresponding to the calculated axial off-set factor.  calculating the core powr as a function of coolant temperature rise across the reactor core;  measuring core power as a function of neutron flux; and  selecting the measure of core power indicative of the highest power level for adjustment in accordance with radial peaking factor and axial power distribution.  choosing the radial peaking factor versus power and axial peaking factor versus axial off-set curves as a function of the instantaneous coolant mass flow conditions for the reactor core.  correcting the computed thermal margin set point for the effects of coolant stratification.  calculating the pressure at which core coolant temperature saturation will occur; and  selecting the maximum of the computed thermal margin set point and temperature saturation pressure signals for comparison with the actual coolant pressure. 2. The apparatus of claim 1 further comprising: 3. The apparatus of claim 1 further comprising: 4. The apparatus of claim 2 further comprising: 5. The apparatus of claim 2 wherein said means for generating a signal commensurate with saturation pressure comprises: 6. The apparatus of claim 5 wherein said means for generating a signal commensurate with saturation pressure further comprises: 7. The apparatus of claim 1 wherein said reactor system includes a plurality of coolant circulator pumps and wherein said protection system further comprises: means for varying the signal commensurate with core power as a function of added thermal energy in accordance with the circulator pump operating configuration prior to application to said selecting means. 8. The apparatus of claim 7 wherein said first compensation signal generating means comprises: 9. The apparatus of claim 7 wherein said means for generating a first compensation signal comprises: 10. The apparatus of claim 7 wherein said means for generating a second compensation signal comprises: 11. The apparatus of claim 8 wherein said means for generating a second compensation signal comprises: 12. The apparatus of claim 9 wherein said means for generating a second compensation signal comprises: 13. The apparatus of claim 11 further comprising 14. The apparatus of claim 12 further comprising: 15. The apparatus of claim 13 wherein said core thermal limit signal generating means comprises: 16. The apparatus of claim 14 wherein said core thermal limit signal generating means comprises: 17. The apparatus of claim 2 further comprising: 18. The apparatus of claim 15 further comprising: 19. The apparatus of claim 16 further comprising: 20. The apparatus of claim 18 further comprising: 21. The apparatus of claim 19 further comprising: 22. Apparatus for generating a signal commensurate with the pressure at which temperature saturation will occur in a steam supply system comprising: 23. The apparatus of claim 22 wherein said means for generating a signal commensurate with added thermal energy comprises: 24. The apparatus of claim 23 wherein said means for generating a signal commensurate with added thermal energy further comprises: 25. A method for predicting whether the core thermal limits of a nuclear reactor are in danger of being violated comprising the steps of: 26. The method of claim 25 wherein the step of compensating a measured value of core power for radial peaking factor and axial power distribution includes: 27. The method of claim 26 wherein the step of compensating a measured value of core power for radial peaking factor and axial powr distribution further includes: 28. The method of claim 27 further comprising: 29. The method of claim 26 further comprising: 30. The method of claim 27 further comprising: 31. The method of claim 26 further comprising: 32. The method of claim 31 wherein the step of calculating the pressure at which temperature saturation will occur includes: 33. The method of claim 32 wherein the step of compensating a measured value of core power for radial peaking factor and axial power distribution includes: 34. The method of claim 33 wherein the step of compensating a measured value of core power for radial peaking factor and axial power distribution further includes: 35. The method of claim 34 further comprising: 36. The method of claim 35 further comprising: 37. The method of claim 36 further comprising: