Patent Number: 043354661
Section: claims

1. A method of substantially instantaneously measuring the axial gross gamma activity profile of a irradiated fuel assembly, said method comprising: using a multielement detector requiring no collimator and requiring no scanning, said detector comprising a plurality of spaced apart substantially identical individual current-measuring (as opposed to pulse-measuring) detectors to measure substantially instantaneously a profile of gross gamma activity as a function of axial position along said fuel assembly.  measuring substantially instantaneously the axial gross gamma activity profile of said particular fuel assembly according to the method of claim 1 both (a) at some initial time t.sub.o, so as to obtain an initial axial gross gamma activity profile, and then (b) at some later time t.sub.1, so as to obtain a final axial gross gamma activity profile; and then  comparing said initial axial gross gamma activity profile with said final axial gross gamma activity profile so as to determine whether any significant differences in said profiles exist.  (a) substantially instantaneously measuring the gross gamma activity profile of a fuel assembly according to the method of claim 1, wherein said gross gamma activity profile is measured with said multielement detector located out-of-core and after a cooling time which is at least about 9 months;  (b) normalizing said gross gamma activity profile obtained in step (a) so as to obtain a normalized gross gamma activity profile having a peak value which is equal to 1.0; and  (c) using a previously determined calibration curve of a burnup monitor and using one measurement of the burnup monitor by a gamma spectrometer to convert the normalized profile to the true burnup profile.  (1) integrating said normalized gross gamma activity profile so as to obtain an integrated value G;  (2) measuring the intensity I, of a particular gamma ray of a burnup monitor with a germanium detector at one axial position along said fuel assembly and determining therefrom the corresponding intensity I.sub.o at the center of said fuel assembly;  (3) multiplying I.sub.o .times.G so as to obtain a monitor-calibrated total intensity I.sub.T ; and  (4) locating I.sub.T on a previously obtained calibration curve of total intensity of said particular gamma ray of said monitor vs. declared burnup, so as to obtain a value of burnup corresponding to I.sub.T.  (a) integrating said profile of gross gamma activity as a function of axial position along said fuel assembly so as to obtain an integrated detector response, R, for said cooling time T.sub.1 ;  (b) locating T.sub.1 on a previously experimentally determined graph of (R/declared burnup) vs. cooling time, so as to obtain a corresponding value of burnup. 2. A method according to claim 1, wherein said current-measuring detectors are selected from the group of detectors consisting of gamma-measuring ionization chambers and gamma-measuring proportional chambers. 3. A method according to claim 2, wherein said object is a spent fuel assembly. 4. A method according to claim 3, wherein said individual current-measuring detectors are ionization chambers, wherein said ionization chambers are located along a straight line and are all spaced an equal distance apart, and wherein the distance between the two outermost individual detectors is equal to the length of said fuel assembly. 5. A method of determining whether a particular fuel assembly has been tampered with, said method requiring less than 10 seconds of total measurement time and comprising: 6. A method according to claim 5 wherein (t.sub.1 -t.sub.o) is less than about 2 months and wherein the cooling time is less than 9 months. 7. A method of determining burnup of an object, said method requiring less than 10 minutes of total measurement time, said method comprising: 8. A method according to claim 7 wherein said burnup monitor is Cs-137. 9. A method according to claim 8, wherein said fuel assembly has a burnup within the range from about 0 to about 40,000 MWD/MTU. 10. A method according to claim 9, wherein said fuel assembly is selected from the group consisting of BWR, PWR, and MTR fuel assemblies. 11. A method according to claim 7 or claim 10 wherein said cooling time is about 9 months and wherein step 7(c) consists of the following steps: 12. A method of determining burnup to within 10% of the declared burnup of a particular object having a known cooling time T.sub.1, using a multielement ionization chamber detector as a stand-alone device, said method comprising the method according to claim 1 and including also the following steps: 13. A method according to claim 12 wherein T.sub.1 is greater than about 9 months. 14. An apparatus requiring no collimator and no scanning and being suitable for substantially instantaneously measuring the axial gross gamma activity profile of a irradiated fuel assembly, said apparatus comprising a plurality of variably spaced apart substantially identical individual current-measuring (as opposed to pulse-measuring) detectors selected from the group of detectors consisting of gamma-measuring ionization chambers and gamma-measuring proportional chambers operable in cooperation with an electronics system which converts the multiple detector signals into an observable profile. 15. An apparatus according to claim 14, wherein said individual detectors are located along a straight line, are spaced apart equidistantly, and wherein said individual detectors occupy a total length equal to or greater than the length of an object being measured. 16. An apparatus according to claim 15, wherein said detectors are adjustably mounted on a base and wherein said individual detectors occupy a total length equal to the length of an object being measured.