Patent Number: 044915403
Section: summary

TECHNICAL FIELD In a proposed method for preparing radioactive waste from nuclear reactors for long-term disposal, spent nuclear fuel rods from nuclear reactors are enclosed directly, i.e. without fuel reprocessing, in gas-tight containers of a corrosion-resistant material. This invention relates to an improved method of such preparation. BACKGROUND ART According to one known method, spent fuel rods are placed in a container of copper and embedded in lead in the container by pouring molten lead into the container and allowing it to solidify in the container. After that, the container is provided with a lid of copper which is welded to the container to form a gas-tight joint. The present invention is based on the realization that considerable advantages can be gained if a copper powder is used instead of lead for embedding the spent fuel rods in the container and if the sealing of the container and the lid is carried out by means of isostatic compression. One advantage is that the resistance to corrosion attack is increased by the fact that the coherent mass of copper, formed from the copper powder, the container and the lid, is more resistant to corrosion than a container of copper and a body of lead within the copper container. This is due, on the one hand, to copper in itself being more resistant than lead and, on the other hand, to the protection afforded by having a coherent mass of a single material. Another advantage is that the interior of the container can be made free from cavities, which is hardly possibly when casting lead into the container and subsequently welding a lid onto the container. A further advantage is that the joint between the container and the lid after the isostatic compression is absolutely tight and completely reliable. This is because the container and the lid become a single entity without any joint, or any transition area of a different material composition existing between them. Welding together copper parts having substantial wall thicknesses, as in the known case, involves considerable difficulties and results in a joint in which the copper has a structure different from that of the adjacent material. The joint can therefore represent a weak part in the sealed container. DISCLOSURE OF THE INVENTION According to the invention there is provided a method of preparing spent nuclear fuel rods from a nuclear reactor for long-term storage in a copper container, which method comprises the steps of embedding the fuel rods in copper powder within the container, closing the container with a copper lid, and subjecting the closed container to hot isostatic compression at a pressure and a temperature sufficient to form the container, the powder and the lid into a coherent mass in which the spent fuel rods are embedded. Suitably, the lidded container is enclosed in a capsule which is evacuated and sealed prior to effecting the isostatic compression. Normally, the gas-tight capsule is allowed to remain when the container is deposited for long-term storage. This capsule can be made of sheet metal and may be of the same quality copper as the container, which reduces the probability that a coherent material fault or defect in the copper material will occur. The capsule can, however, also be made of some other material, which may supplement copper for corrosion protection purposes. Stainless steel or titanium are particularly suitable examples. The container, the lid and the copper powder are advantageously manufactured from a highly pure quality of copper with low oxygen content, such as the so-called OFHC (Oxygen Free High Conductivity) type which contains at least 99.95% Cu (including small amounts of Ag). Such a quality is assumed to give a good corrosion resistance in the finished product. Alternatively, highly pure copper which has been deoxidized with small amounts of phosphorus (max. 0.015% P) may be used. The particles in the copper powder are preferably spherical, or at least to a major extent spherical. Particles of substantially spherical shape have good free flowing properties and therefore give a high fill factor. The fill factor may be improved by using spherical powders of at least two different grain sizes. A suitable grain size for one of two fractions is 0.5-1.5 mm and for the other of the fractions 0.1-0.2 mm. Alternatively, the latter fraction may constitute a graded fraction with a grain size of a maximum of 0.2 mm. By subjecting the container and/or fuel elements to light impacts or vibrations during filling, the fill factor for the applied copper powder may be further improved. For the same purpose, it may be desirable to temporarily locate a vibrating packing device on or in the filled copper powder. The isostatic pressing for forming the coherent dense mass of the container, lid and powder is suitably carried out at a pressure of at least 10 MPa and at a temperature in the range of 600.degree.-800.degree. C., or at a temperature in the range of 500.degree.-800.degree. C. In order to achieve a tight and permanent joining of the lid to the container in a rapid and reliable manner, during the isostatic pressing, without having to employ high temperatures and long treatment times, it is important that the joining surfaces, prior to being applied against each other, are freed from foreign substances by some suitable treatment, for example scraping, shot blasting, abrading with metal brushes, washing or etching. It is particularly important that the joining surfaces are freed from oxide depositions, which may be done by washing with acid or by reduction of the oxide coating with hydrogen gas at elevated temperature. By giving the joining faces a certain texture such as grooves, scratches or an embossed pattern, parts of the contact surfaces are subjected, during the pressure application, to a strong plastic deformation while at the same time fresh and clean metal surfaces are generated. This causes the joint region to become more reactive, which facilitates the formation of a tight joint between the lid and the container during the isostatic pressing. Further, by said texturing of the joining surfaces and by giving contact portions between lid and container, on at least one of these, stepped or conical shape, or by constructing the lid with a central stud passing into the container with a close fit within the container, it is possible to extend the actual length of the joint, relative to that obtained with a plane and smooth lid by a factor of 2-3, which additionally ensures the formation of a coherent dense mass from the lid and container during the subsequent hot isostatic pressing. In addition, the accurate fitting of the lid on the container is facilitated by the mechanical guidance provided with a stepped design of the contact portions or a central stud, while at the same time displacements of the positions of the parts during pressure application and compaction are prevented. In order to embed the fuel rods separately and in predetermined relative positions within the container, they may be held in desired spaced-apart positions within the container during the feeding in of the copper powder and during the sealing of the container, by suitable spacing elements. According to an advantageous embodiment, the spacing elements are the spacers, normally of stainless steel, used in the nuclear reactor to support the fuel rods in bundles during operation of the nuclear reactor. After the fuel rods have been exhausted in the reactor, the complete fuel rod bundles can then, without any further assembly work, be removed from the reactor and placed in the copper container for treatment according to the present invention whenever containment and long-term storage of them is necessary. According to another advantageous embodiment of the invention, the spacing elements are made of copper. This embodiment is particularly suitable if the fuel rod bundles are to be partially dismantled. After the isostatic pressing, spacing elements of copper with a surrounding copper powder give rise to a more homogeneous unit with fewer transition areas between different materials. Before carrying out the isostatic pressing of the filled and lidded container to form a coherent dense mass of the copper components, the filled and lidded container can be subjected to a creep deformation by subjecting it to isostatic compression at a lower temperature than that which is to be used during the final pressing. For example, the container can be arranged in the sealed gas-tight capsule which is used in the final pressing, or the lid can be gas-tightly joined to the container if the capsule is dispensed with. For the creep deformation a pressure of at least 10 MPa and a temperature in the range of 300.degree.-500.degree. C. are preferably employed. By subjecting the copper parts to isostatic compression at a lower temperature than that which is used during the final joining together of the parts, an efficient supporting pressure on the cladding tubes of the fuel rods during continued heating is obtained. In this way it is possible to eliminate, or at any rate considerably reduce, the risk that gas present in the cladding tubes will generate a pressure sufficient to cause creep rupture in the tubes when heating them to the temperature necessary to form a coherent unit of copper powder, container and lid. The spent fuel rods contain gases, among others of helium and fission gases, which even at room temperature may provide a pressure of 50-80 bar within the fuel rod cladding tube.