Patent Number: 
Section: claims

1. A method of calibrating exit thermocouples distributed over a plurality of fuel assemblies in a nuclear reactor comprising the steps of: repetitively recording temperatures measured by the thermocouples as reactor power increases during power ascension;  generating calibration factors from the temperatures measured during startup; and  applying the calibration factors to subsequent measurements of temperature taken by the thermocouples. 2. The method of  claim 1  wherein: claim 1 recording includes recording with each temperature measured for each thermocouple, the reactor power level at the time of the measurement and a predicted power at the thermocouple at the time of the temperature measurement using a three-dimensional nodal model of the reactor core;  generating calibration factors comprises generating a measured thermocouple power from each temperature measured for each thermocouple, generating a mixing factor for each temperature measured for each thermocouple by dividing the measured thermocouple power for each temperature measured for each thermocouple into the corresponding predicted power, and for each thermocouple fitting the mixing factors to a selected mixing factor function of reactor power; and  applying the calibration factors comprises, for each subsequent thermocouple temperature measurement, converting the temperature measurement to a measured thermocouple power and adjusting the measured thermocouple power by a mixing factor value determined from the selected mixing factor function of reactor power for that thermocouple. 3. The method of  claim 2  wherein the selected mixing factor function of reactor power is one of a linear function and a constant. claim 2 4. The method of  claim 2  wherein the selected mixing factor function of reactor power is a quadratic function. claim 2 5. The method of  claim 4  wherein the selected mixing factor function of reactor power is a linear function below a selected reactor power level and is then a said quadratic function. claim 4 6. The method of  claim 5  including periodically adjusting the selected mixing factor function of reactor power for each thermocouple. claim 5 7. The method of  claim 6  wherein adjusting the selected mixing factor function of reactor power comprises periodically generating a flux map of the reactor core at certain conditions, using the flux map and the three-dimensional nodal model at said certain conditions of the reactor core to generate a reference measured power distribution for the reactor core, generating a thermocouple measured temperature for each thermocouple at said certain conditions, converting each thermocouple measured temperature to a reference thermocouple power, establishing for each thermocouple an associated reference mixing factor by dividing a reference measured power for the thermocouple determined from the reference measured power distribution by the reference thermocouple power and adjusting the selected mixing factor function of reactor power for each thermocouple to pass through the associated thermocouple reference power. claim 6 8. The method of  claim 7  comprising periodically adjusting the selected mixing factor function of reactor power for each thermocouple. claim 7 9. The method of  claim 8  including periodically adjusting the selected mixing factor functions of reactor power for each thermocouple during startup. claim 8 10. The method of  claim 7  including periodically adjusting the selected mixing factor functions of reactor power multiple times during startup. claim 7 11. The method of  claim 7  comprising periodically adjusting the selected mixing factor functions of reactor power for the thermocouples after initial power ascension. claim 7 12. The method of  claim 2  further including generating standard deviations for each mixing factor for each thermocouple for each measured temperature, fitting all of the standard deviations to a single selected function of assembly power. claim 2 13. The method of  claim 10  wherein the selected function of assembly power is one of a quadratic function and a linear function of assembly power. claim 10 14. The method of  claim 1  wherein the step of repetitively recording temperatures measured by the thermocouples as power increases during power ascension comprises recording temperatures for discrete ranges of power during power ascension and limiting the number of measured temperatures recorded for each range of power. claim 1 15. The method of  claim 14  wherein recording temperatures for discrete ranges of power during power ascension comprise recording temperatures for ranges of about 5% power. claim 14 16. The method of  claim 12  including determining the quality of the thermocouple data by using the standard deviations. claim 12