The disclosure relates to radioisotope production, and more particularly to methods and apparatus for assembling annular radioisotope targets.
Among the problems of fabrication of annular composite radioisotope targets 10 (
Another problem associated with the conventional method of assembling radioisotope targets is that the C-shaped foil 12 must be compressed against the inner cladding tube 14 while disposing the outer cladding tube 16 over the foil 12 and inner cladding tube 14. During the assembly process, it is difficult to prevent the C-shaped foil 12 from buckling as the outer cladding tube 16 is slipped over the foil 12. Thus, much care and time are needed to assemble radioisotope targets using the conventional flat C-shaped foil 12.
In view of the foregoing problems associated with conventional radioisotope targets and the assembly thereof, an embodiment of the disclosure provides an annular radioisotope target that includes an inner cladding tube and a helical coil-shaped foil ribbon disposed over the inner cladding tube. The helical coil-shaped foil ribbon has a first end, a second end, a first edge and a second edge. An outer cladding tube is disposed over the helical coil-shaped foil ribbon and inner cladding tube, and end caps are attached to the outer cladding tube and the inner cladding tube.
In another embodiment there is provided a method for making an annular radioisotope target. The method includes, providing an inner cladding tube and sliding a helical coil-shaped foil ribbon over the inner cladding tube. The helical coil-shaped foil ribbon has a first end, a second end, a first edge and a second edge. An outer cladding tube is disposed over the helical coil-shaped foil ribbon and inner cladding tube. End caps are attached to the outer cladding tube and inner cladding tube to seal the foil between the outer cladding tube and inner cladding tube.
In some embodiments, the cladding and end caps are made of an aluminum alloy. In other embodiments, the helical coil-shaped foil ribbon is made of a material selected from the group consisting of uranium, molybdenum, and an alloy thereof.
In some embodiments, the first edge and second edge of the helical coil-shaped foil ribbon are beveled. In other embodiments, the first edge of the helical coil-shaped foil ribbon and the second edge of the helical coil-shaped foil ribbon comprise tongue and groove edges.
In some embodiments, each of the inner cladding tube and outer cladding tube has a thickness ranging from about 1 to about 5 millimeters in thickness. In other embodiments, the foil has a thickness ranging from about 0.5 to about 2 millimeters. However, the cladding tubes and foil for the target are scalable, thus the foregoing ranges are used for illustration purposes and are adaptable to a particular size radioisotope target configuration.
In some embodiments, the helical coil-shaped foil ribbon has a diameter that is 5% to 20% less than an outside diameter of the inner cladding tube.
In some embodiments, the helical coil-shaped foil ribbon is devoid of gaps between the first edge of the helical coil-shaped foil ribbon and the second edge of the helical coil-shaped foil ribbon.
In some embodiments, the helical coil-shaped foil ribbon is compressed by the endcaps to eliminate gaps between the first edge and the second edge of the helical coil-shaped foil ribbon.
An advantage of making and using radioisotope targets made with a helical coil-shaped foil ribbon is that the target may be assembled much more easily and quickly with less interference between the helical coil-shaped foil ribbon and the outer cladding tube. The use of the helical coil-shaped foil ribbon is also effective to eliminate gaps between edges of the foil ribbon during the assembly and dimensioning process. Other features and advantages of the embodiments of the disclosure may be evident with reference to the attached drawings and following description.
An important feature of the disclosed embodiments is the use of a helical coil-shaped foil ribbon in the manufacture of radioisotope targets. With reference to
It will be appreciated that the helical-coil shaped foil ribbon 30 can be made with a wide range of ribbon widths, lengths, thicknesses and IDs to accommodate different size target manufacturing capabilities. For example a 2.54 cm wide foil ribbon would be wound around an inner cladding tube of a selected diameter twice as many times as a 5.08 cm wide ribbon, and the 2.54 cm foil ribbon would be twice as long as the 5.08 cm foil ribbon. Thus, the length and width of the foil ribbon 30 are not particularly critical to provide the features and advantages of use of a foil ribbon 30 rather than a flat sheet foil that is bent into a “C-shaped” radioisotope target 28.
In order to fit the foil ribbon 30 tightly against a raised edge 34 of end cap 36a and 36b (
After the foil ribbon 30 is disposed over the inner cladding tube 32, the outer cladding tube 44 may be slid over the foil ribbon 30 and inner cladding tube 32. Then a second end cap 36b having an outside diameter smaller than an inside diameter of the outer cladding tube 44 and the second end cap 36b having a larger inside diameter than the OD of the inner cladding tube 32 is slid onto the inner cladding tube 32 to contact the second end 38b of the foil ribbon 30 to compress the first end 38a of the foil ribbon 30 against end cap 36a and close up any gaps in the helical coil-shaped foil ribbon 30.
When the outer cladding tube 44 is disposed over the foil ribbon 30 and the second end cap 36b is put in place inside the outer cladding tube 44 and adjacent to second end 38b of the foil ribbon 30, pressure is applied to end caps 36a and 36b to cause gaps in the helical coil-shaped ribbon 30 to close. The end caps 36a and 36b are secured, optionally by welding, to the outer cladding tube 44 and then whether the target 28 assembly is stretched or swaged any remaining gaps simply get tighter/narrower, and do not open or cause overlap as in the case of the flat C-shaped foil 12 (
The use of a helical coil-shaped foil ribbon 30 in a radioisotope target 28 is novel and solves many of the manufacturing issues associated with using a flat C-shaped foil 12. Advantages of the helical coil-shaped foil ribbon 30 include, but are not limited to, ease of assembly and manufacture, ability to consolidate the spiral rings of the foil ribbon 30 by swaging or expansion without opening gaps or overlapping the edges of the foil ribbon 30. Accordingly, the helical coil-shaped foil ribbon 30 provides a more uniform target 28 for irradiation, and allows for ease of both assembly prior to exposure, and disassembly after exposure.
After the helical coil-shaped foil ribbon 30 is irradiated, the outer cladding 44 is removed from the structure by one of a number of methods. One method of removal is where the end caps 36a and 36b are cut off and the outer cladding tube 44 is scored deeply along the length of the outer cladding tube 44. Using the score line as a weak point, the outer cladding tube 44 may be peeled away from the helical coil-shaped foil ribbon 30 and removed. The peeling away of the outer cladding tube 44 has minimal impact on harvesting the foil ribbon 30 and subsequent isotope production steps. It decreases the total time to manufacture, and allows for higher production rates.
A wide variety of materials may be used as the radioisotope target 28 materials for the above-described embodiments. For example, nonfissionable metal materials selected from the group consisting of steel, stainless steel, nickel, nickel alloy, zirconium, zircaloy, aluminum, or zinc coated aluminum may be used for the end caps 36a and 36b and for the inner and outer cladding tubes 32 and 44, respectively. In one embodiment, the inner and outer cladding tubes 32 and 44 and the end caps 36a and 36b are made of aluminum or an aluminum alloy.
The overall dimensions of the radioisotope target 28 are limited only by the reactor design used to irradiate the foil ribbon 30. Accordingly, the cylinder-shaped tubes 44 may have lengths ranging from about 30 cm to about 60 cm. Outer diameters of the cylindrical cladding tubes 44 may range from about 2.0 cm to about 6.0 cm. Inner and outer cladding tube wall thicknesses may vary and may range from about 0.6 to 1.6 mm. Generally, the wall thicknesses are not critical, provided that radiation may easily penetrate the walls of the tubes to irradiate the target material and that proper heat conductance is achieved during the irradiation process. A typical irradiation process may include temperatures in the range of from about 500 to about 600° C.
The inner and outer cladding tubes 32 and 44 may be treated to improve the assembly and disassembly process. For example, the surfaces in contact with the foil ribbon 30 may be oxidized or nitrided to reduce bonding between the foil ribbon 30 and the inner and outer cladding tubes 32 and 44. In some embodiments, aluminum cladding tubes are used and are naturally oxidized by exposure to ambient atmosphere. In other embodiments, the inner and outer cladding tubes 32 and 44 are cleaned thoroughly to provide a smooth, clean surface for sliding over the foil ribbon 30.
The material of the helical coil-shaped foil ribbon 30 is not particularly critical to the disclosed embodiments provided it is a material that can be activated with neutrons. Accordingly, the foil ribbon 30 may be made of low enriched uranium metal, plutonium metal, or an alloy of uranium and molybdenum, such as 90 mol % uranium and 10 mol % molybdenum.
The thickness of the foil ribbon 30 may depend on the diameter of the inner and outer cladding tubes 32 and 44. In some embodiments, the foil ribbon may have a thickness ranging from about 0.02 mm to about 0.2 mm.
In some embodiments, a barrier material may be used to reduce or eliminate bonding between the foil ribbon 30 and the inner and outer cladding tubes 32 and 44. Radiation (recoil) enhanced diffusion can cause the foil ribbon 30 to bond with the inner and outer cladding tubes 32 and 44 making disassembly difficult. Recoil atom absorbing barriers may be used to prevent such recoil enhanced diffusion, and thus bonding. A number of metals have been found effective for use as recoil barriers, including, but not limited to, copper, nickel, iron and zinc. A primary target using one barrier may have the barrier disposed between the outer surface of the foil ribbon and the inner surface of the outer cladding tube, or between the foil ribbon and the outer surface of the inner cladding tube. In some embodiments, two barriers between the foil ribbon and the inner and outer cladding tubes, may be used. When one barrier is used, the barrier may be comprised of nickel metal. However, when two barriers are used, nickel, copper, iron or zinc may be used but it is preferred that the two barriers be selected from the same metal.
Barrier thickness, if used, may vary, depending upon the target configuration and the application. Such thickness may range from about 10 micrometers to 100 micrometers. However, since the recoil range for copper and nickel is approximately 7 micrometers, a copper or nickel barrier having a predetermined thickness of approximately 10 micrometers is desirably used. Additionally the manner in which the barrier is applied to the cladding tubes may vary. It is contemplated that the metal recoil barriers could exist as separate foils similar to that of the foil ribbon of fissionable material or applied to the foil ribbon of fissionable material by electrodeposition, ion implantation, electroplating, spraying or other similar methods.
After the radioisotope target 23 is irradiated, the outer cladding tube 44 is removed and the toil ribbon 30 is peeled from the inner cladding tube 32 and the irradiated foil ribbon 30 is dissolved in a chemical bath to extract isotopes.
A particular advantage of the disclosed embodiments is that the foil ribbon greatly reduces the time and complexity required to assemble the radioisotope targets. Accordingly, mass production of radioisotope targets is possible since gaps and overlaps of the foil are avoided by using the above described foil ribbon target. Also, the foil ribbon target avoids interference with the outer cladding tube 44 during the target assembly process since the foil ribbon can be made to tightly adhere to the inner cladding tube 30 by the resilience of the foil ribbon.
The foregoing descriptions of embodiments have been presented for purposes of illustration and exposition. They are not intended to be exhaustive or to limit the embodiments to the precise forms disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments are chosen and described in an effort to provide the best illustrations of principles and practical applications, and to thereby enable one of ordinary skill in the art to utilize the various embodiments as described and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.
The U.S. Government has rights to this invention pursuant to contract number DE-NA0001942 between the U.S. Department of Energy and Consolidated Nuclear Security, LLC.
Number | Name | Date | Kind |
---|---|---|---|
3594275 | Ransohoff | Jul 1971 | A |
3860041 | Leiter | Jan 1975 | A |
6160862 | Wiencek et al. | Dec 2000 | A |
10109383 | Pärnaste | Oct 2018 | B1 |
20110255646 | Eriksson et al. | Oct 2011 | A1 |
20140226773 | Toth et al. | Aug 2014 | A1 |
20180166179 | Piefer | Jun 2018 | A1 |
Number | Date | Country |
---|---|---|
106851957 | Jun 2017 | CN |
0115176 | Mar 2001 | WO |
2018106681 | Jun 2018 | WO |