Patent Number: 046474200
Section: claims

1. A nuclear fuel pin scanner system for inspecting nuclear fuel pins at a throughput rate to determine the uniformity and amount of fissile material contained in the fuel pin, comprising: a rotary irradiator having a source of activating radiation located centrally thereof, said irradiator having a plurality of circumferentially spaced positions thereabout for supporting fuel pins in radially spaced relation to said source of activating radiation;  means for feeding and discharging said fuel pins singly into and from said irradiator at said throughput rate;  means for rotating said irradiator and fuel pins contained therein about the source of activating radiation whereby each fuel pin is irradiated for an extended period of time relative to the throughput rate;  detector means downstream of said irradiator comprising an array of axially spaced radiation detectors for detecting radiation from segments, respectively, of each fuel pin during oscillatory movement of said fuel pin relative to said detector means to achieve an effective total scanning time for said pin equal to a detection period times the number of segments;  fuel pin outfeed means for receiving fuel pins from the detector and for transferring the fuel pins from the system; and  wherein the irradiator comprises a cylindrical magazine having a plurality of fuel pin receiving tubes therein for holding fuel pins during activation; the cylindrical magazine being adapted to turn about a longitudinal axis extending therethrough with the fuel pin receiving tubes being arranged in a circular arrangement approximately centered on said longitudinal axis;  the source of activating radiation being positioned at approximately the longitudinal axis of the cylindrical magazine and adapted to be oscillated along said longitudinal axis to provide oscillatory axial relative motion between the fuel pins contained in the magazine and the source of activating radiation.  an infeed bank for holding at least one fuel pin to be inspected;  a transfer shuttle for removing fuel pins from the infeed bank;  an infeed conveyor means for receiving fuel pins from the transfer shuttle and for moving the fuel pins to the irradiator.  a background detector, americium gauge and gamma transmission gauge for measuring background radiation, americium radiation levels, and gamma ray transmissiveness, respectively, of fuel pins at a time prior to when the fuel pin enters the irradiator.  a frame;  a magazine rotatably mounted upon the frame; the magazine having a longitudinal axis about which it rotates;  a plurality of fuel pin receiving tubes extending longitudinally within the magazine; the fuel pin receiving tubes being arranged in an approximately circular arrangement so that each receiving tube is at approximately an equally spaced radius from the longitudinal axis of the magazine;  means for holding a source of activating radiation centered approximately along the longitudinal axis of the magazine;  means for rotating the magazine; and  means for rotating fuel pins held within the fuel pin receiving tubes as the magazine rotates.  arranging a plurality of nuclear fuel pins in an arrangement about a longitudinal axis of rotation with each fuel pin approximately an equal radial distance therefrom;  rotating the nuclear fuel pins about said longitudinal axis of rotation;  activating the fuel pins by exposing the fuel pins to a source of activating radiation lying along said longitudinal axis of rotation;  removing activated fuel pins from the arrangement;  positioning an activated fuel pin within a detector means having a plurality of detector elements arranged in an axial array;  oscillating the activated fuel pin positioned within the axial array over a distance approximately equal to the spacing of adjacent detector elements to thereby multiply the effective time available for detection by the number of detector elements; and  detecting the emission of radiation by the activated fuel pin being oscillated within said detector means. 2. The nuclear fuel pin scanner of claim 1 wherein the irradiator further comprises fuel pin rotation means for rotating fuel pins held within the fuel pin receiving tubes as the cylindrical magazine rotates. 3. The nuclear fuel pin scanner of claim 2 wherein the fuel pins are held within the fuel pin receiving tubes by releasable collets. 4. The nuclear fuel pin scanner of claim 2 wherein the fuel pin rotation means comprises collets which releasably hold the fuel pin; the collets being provided with exterior geared surfaces which engage with a stationary sun gear thereby causing the collets and attached fuel pins to rotate in the receiving tubes as the magazine is rotated. 5. The nuclear fuel pin scanner of claim 1 wherein the source of activating radiation is a supply of neutron emitting radioactive material contained within a radiation source tube; the radiation source tube being oscillated within an activation passageway existing in the irradiator along approximately the longitudinal rotational axis of the cylindrical magazine. 6. The nuclear fuel pin scanner of claim 1 wherein the fuel pin infeed means comprises: 7. The nuclear fuel pin scanner of claim 1 further comprising: 8. A nuclear fuel pin irradiator for providing extended irradiation times compared to the throughput rate of the irradiator, comprising: 9. The nuclear fuel pin irradiator of claim 8 wherein the magazine is cylindrically shaped. 10. The nuclear fuel pin irradiator of claim 8 further comprising releasable collets for holding fuel pins in the receiving tubes; the collets forming a part of fuel pin rotation means which rotate fuel pins held in the receiving tubes by the collets. 11. The nuclear fuel pin irradiator of claim 8 further comprising means for longitudinally oscillating the source of activating radiation. 12. A method for inspecting nuclear fuel pins to accurately determine uniformity and total amount of fissile material contained therein, comprising: 13. The method of claim 12 wherein the source of activating radiation is oscillated longitudinally along the axis of rotation during the step of activating the fuel pins. 14. The method of claim 12 further comprising rotating the individual fuel pins about fuel pin longitudinal axes while the arrangement is rotated and activated.