SYSTEM AND PROCESS FOR PRODUCTION AND COLLECTION OF RADIOISOTOPES

Abstract

A means for installing material, through a fuel assembly instrument thimble insert, into the existing instrument thimbles in nuclear fuel assemblies for the purpose of allowing the material to be converted to commercially valuable quantities of desired radioisotopes during reactor power operations during a remainder of a fuel cycle and removing the radioisotopes from the core through the reactor flange opening once the fuel assemblies have been removed for refueling. The invention also describes methods that can be used to harvest the irradiated material so it can be packaged for transportation from the reactor to a location where the desired radioisotope(s) can be extracted from the fuel assembly instrument thimble insert.

Claims

1-8. (canceled)

9. A method of irradiating an isotope that requires an extended exposure within a nuclear reactor lasting at least one fuel cycle, to achieve an intended target product, comprising the steps of: enclosing the isotope within an elongated tubular housing having an axis along its elongated dimension, the elongated tubular housing being closed at a forward end and capped at a rearward end to form a target specimen chamber therebetween within an interior of the elongated tubular housing, the elongated tubular housing being sized to slide within an instrument thimble of a nuclear fuel assembly, with the rearward end structured to be driven by a drive cable of an existing moveable in-core detector system; positioning the isotope at a preselected axial position within the elongated tubular housing; attaching the rearward end to the drive cable; driving the isotope within the elongated tubular housing into and at least partially through an instrument thimble of a selected nuclear fuel assembly within a core of a nuclear reactor; leaving the isotope within the instrument thimble for the remainder of a fuel cycle of the core; withdrawing the elongated tubular housing from the core at the end of the fuel cycle; removing the selected fuel assembly from the core; reinserting the elongated tubular housing at least partially into the core; and removing at least a portion of the elongated tubular housing that contains the isotope by dislodging the portion from the drive cable.

10. The method of claim 9 wherein the dislodging step cuts the elongated tubular housing around a circumference.

11. The method of claim 10 including the step of transferring the portion under water to a spent fuel pool.

12. The method of claim 11 transferring the portion in a building housing the spent fuel pool to a shielded package for shipment.

13. The method of claim 9, wherein positioning the isotope at a preselected axial position within the elongated tubular housing comprises positioning the isotope between a forward axial plug and a rear axial plug which extend across the interior of the elongated tubular housing.

14. The method of claim 9, wherein the irradiated isotope comprises one or more materials selected from the group consisting of: Co-60, W-188, Ni-63, Bi-213, and Ac-225.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] A further understanding of the invention can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:

[0012] FIG. 1 is a perspective view of a prior art in-core moveable detector arrangement that can be employed with this invention;

[0013] FIG. 2 is a schematic cross-sectional view of one embodiment of a target flux thimble of this invention; and

[0014] FIG. 3 is a schematic view of a reactor vessel and moveable in-core detector drive system showing the target flux thimble insertion and withdrawal positions of this invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0015] One preferred embodiment of the radioisotope production process of this invention utilizes the flux thimbles that provide the access conduit for the existing movable in-core detector fission chambers to the instrument thimble in the fuel assembly to periodically measure the reactor power distribution, to insert the target material to be transmuted into a desired radioisotope, into the fuel assembly instrument thimble. The flux thimble containing the target material, hereafter referred to as the target flux thimble 34, is shown schematically in FIG. 2 and takes the place of the miniature detector 12 shown in FIG. 1 as being inserted into the fuel assembly instrument thimble 50. The target flux thimble 34 is attached to the drive cable 48 in place of the miniature detector 12 and comprises an outer sheath 36 having an enclosed lead end 38 that is preferably rounded or beveled and an enclosed trailing end 40 that is enclosed by a cap 42 once the specimen or isotope target capsule 44 has been loaded within the chamber 45 within the outer sheath 36. The target material capsule 44 may have its own sheath (not shown) or if in solid self-standing form may be capped at either axial end by axial position end plugs 46 that position the target material capsule 44 in a desired axial position within the target flux thimble 34. The axial position end plugs may be held in position by friction or fit in slight recesses 52 in the inside surface of the target flux thimble sheath 36 preferably with the interfacing surface of the axial position end plugs beveled to assist movement of the axial position end plugs into the recesses when they are loaded into the target flux thimble sheath 36. The target flux thimble 34 remains in place within the fuel assembly instrument thimble 50 throughout the remainder of the reactor operating cycle after it is installed within the fuel assembly instrument thimble. When the reactor is refueled all the flux thimbles are withdrawn below the lower core plate inside the reactor vessel to allow the fuel assembly to be shuffled and/or removed from the vessel as part of the refueling process. If the amount of the desired radioisotope is expected to be sufficient inside a target flux thimble, the target flux thimble can be re-inserted into the empty reactor vessel location previously occupied by the removed fuel assembly to allow the portion of the target flux thimble containing the irradiated target material that was inside the fuel assembly instrument thimble to be cut off from the target flux thimble using existing tooling dedicated to flux thimble removal operations.

[0016] FIG. 3 provides an illustration of the positioning of the target flux thimble during the irradiation, refueling, and harvesting phases of production. Like reference characters are used among the several figures to represent corresponding components. Reference character 22 points to the guide conduits through which the target flux thimble 34 travels from the seal table 20. The guide conduits 22 are each aligned with a corresponding instrument column 56, which is aligned with a corresponding instrument thimble in one of the fuel assemblies in the core. Reference character 54 points to the fully inserted target flux thimble position in the corresponding fuel assembly in the core at which the target material capsule will be irradiated and reference character 58 refers to the fully withdrawn position that enables the corresponding fuel assembly to be withdrawn from the core, prior to harvesting the target material. Reference characters 68 and 70, respectively, show the difference of the fully withdrawn position and the fully inserted position at the seal table 20. After the fuel assembly is withdrawn from the core the target flux thimble 34 can be reinserted into the core area and severed at reference character 60 for removal from the reactor vessel. The irradiated target material can then be inserted into a container 62 that will allow the target material containing target flux thimble portion to be transferred via the fuel transfer system 66 to the spent fuel pool 64 where it can be packaged in a shielded shipping container 72 to ship to a processing facility. The remaining portion of the affected target flux thimble is removed using standard maintenance procedures and is replaced with a new target flux thimble. The process can be repeated as many times as desired, and simultaneously in as many different core locations as prudent to ensure that at least 75% of the fuel assembly locations hosting flux thimbles are available throughout the operating cycle.

[0017] The typical prior art method for producing commercially valuable radioisotopes that require long term irradiation inside commercial nuclear reactors involves inserting one or more fuel pin structures that contain the target material into one or more fuel assemblies. The process offered by this invention avoids the need to perform the very rigorous, time consuming and expensive analysis needed to support modifications to a licensed fuel assembly design to incorporate the modified fuel pin structures. The fuel assembly instrument thimbles that are accessed via the flux thimbles by the moveable in-core detector fission chambers do not require any modifications. Since there are no modifications to the fuel assembly design required by the approach documented herein, there is little cost associated with implementation of this process.

[0018] The irradiation of target materials to produce a desired radioisotope is the first step in the production of any commercially valuable radioisotope. Consequently, the potential business is the entire breadth of the longer lived radioisotope production market. Some notable highly desired (and priced) radioisotopes suitable for the production process addressed by this invention include Co-60, W-188, Ni-63, Bi-213, and Ac-225. The process described herein lends itself to the use of radioactive target material since the ability to shield the target material before it is irradiated is supported by the existing features of the moveable in-core detector architecture.

[0019] While specific embodiments of the invention have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular embodiments disclosed are meant to be illustrative only and not limiting as to the scope of the invention which is to be given the full breadth of the appended claims and any and all equivalents thereof