This invention relates to systems for treating materials, especially waste materials, with liquid reactant metals. The invention encompasses both methods for treating materials in a liquid reactant metal and treatment systems for performing the treatment operations.
It is known that certain chemically active metals or reactant metals held as a liquid at elevated temperatures have the ability to chemically reduce organic compounds. Suitable reactant metals include aluminum, magnesium, lithium, and alloys of these metals as described in U.S. Pat. Nos. 5,000,101, 6,069,290, and 6,355,857 to Wagner. The entire content of each of these prior patents is hereby incorporated in this disclosure by this reference. These liquid reactant metals chemically reduce organic molecules to produce mostly hydrogen and nitrogen gas, elemental carbon, char, and metal salts. Most metals mixed with the organic materials or bound up in organic molecules in the waste materials dissolve or melt into the liquid reactant metal. Low boiling point metals such as Mercury may go to a gaseous state and separate from the liquid reactant metal along with other gases. Other metals alloy with the liquid reactant metal or separate from the liquid reactant metal by gravity separation. Liquid reactant metals are also useful in treating radioactive wastes and mixed radioactive and nonradioactive wastes. U.S. Pat. No. 6,355,857 discloses processes for treating radioactive and mixed radioactive and nonradioactive wastes in a liquid reactant metal reactor. Many of the materials in the waste are chemically reduced to produce relatively innocuous compounds or constituent elements. Radioactive metals such as Uranium and transuranic metals are dissolved or otherwise dispersed into the liquid reactant metal. As shown in U.S. Pat. No. 6,355,857 and U.S. patent application Ser. No. 10/059,808, the entire content of which is incorporated by reference, radiation absorbing metals and radiation moderating metals may be included in the liquid reactant metal. The liquid reactant metal, trapped radioactive isotopes, and radiation absorbing or moderating materials may be solidified to form an ingot. In the resulting ingot the radiation absorbing materials absorb radioactive emissions from the trapped radioactive isotopes and greatly reduce the amount of radiation escaping from the ingot. Thus, the ingot provides a good vehicle for the relatively safe, long-term storage of radioactive isotopes.
The liquid reactant metal treatment processes described above and in U.S. Pat. No. 6,355,857 and application Ser. No. 10/059,808 provide ways to effectively isolate radioactive isotopes from mixed non-radioactive and radioactive wastes and effectively store radioactive materials. There remains a need, however, for improved systems for providing the necessary contact between the material to be treated and the reactant metal, and for handling the resulting reaction products. The need is particularly acute for high-level nuclear waste materials such as spent nuclear fuel rods.
The present invention provides treatment methods and devices for treating various types of materials with liquid reactant metals. Although the invention is applicable for treating many types of materials, the present treatment system is especially suited for treating articles such as spent nuclear fuel rods or similar articles that include high-level radioactive materials. The invention places the radioactive elements from the radioactive material in a storage mixture that includes the liquid reactant metal and radioactive emission control materials. This storage mixture can be cooled to form ingots in which the radioactive elements may be stored in relative safety over long periods of time.
As used in this disclosure and the accompanying claims, the radioactive atoms dissolved or otherwise liberated from the target material being treated will be referred to as “radioactive material decomposition constituents.” The term “decomposition” is not used here to imply that the atoms dispersed into the reactant metal from the target material change from one isotope to another by radioactive emission. Rather the term “decomposition” is used to describe the fact that the respective atoms were once part of the article made up of the target material being treated or were once included in the physical structure of the target material, and have been released from the target material into the liquid reactant metal. This release into the liquid reactant metal at least partially, and preferably completely, eliminates the original article or physical structure of the target material.
The materials included in a storage mixture according to the invention to absorb or moderate radioactive emissions from the radioactive material decomposition constituents in the storage mixture will be referred to in this disclosure and the accompanying claims as “radioactive emission control materials.” The word “control” in this phrase is not intended to imply that the materials prevent radioactive emissions from the radioactive isotopes in the storage mixture. It will be appreciated that the “control” provided by the radioactive emission control material is in absorbing the radioactive emissions that inevitably occur, either producing a stable isotope or one that degrades further by radioactive emission. The phrase radioactive emission control materials also encompasses moderating materials that absorb high energy particles or radiation and produce lower energy emissions in response.
According to the invention, material to be treated, that is, the target material, is placed or loaded into a containment area defined within a liquid reactant metal treatment vessel. The containment area is then placed below the level of the liquid reactant metal in the treatment vessel. This places the target material in contact with the liquid reactant metal and allows the desired reactions to occur. Reaction products are then removed from the treatment vessel.
In one form of the invention the treatment vessel is held in a first position to load the target material into the vessel. The treatment vessel is then tilted to a treatment position in order to place the containment area, and thus the target material, below the level of liquid reactant metal in the vessel. In other forms of the invention, liquid reactant metal is poured or otherwise transferred from a separate vessel into the treatment vessel to place the containment area below the liquid reactant metal level in the treatment vessel.
The manner in which reaction products are removed from the treatment vessel depends upon the nature of the target materials being treated. Where the target material is a spent nuclear fuel rod for example, the reaction products comprise decomposition constituents made up of radioactive materials and other materials from the spent fuel rods dissolved or otherwise dispersed in the liquid reactant metal. In this case, the reaction products are removed from the treatment vessel by transferring the entire melt including the reactant metal, decomposition constituents, and radioactive emission control materials into ingots for cooling. In forms of the invention in which the material to be treated includes hydrocarbons or other materials that are chemically reduced by the liquid reactant metal, the reaction products include products from the chemical reduction reaction. These reaction products are removed from the treatment vessel in gaseous, liquid, or solid form as is known in the art of liquid reactant metal reactors.
The present invention provides a relatively simple arrangement for placing materials to be treated in contact with a liquid reactant metal. The invention is particularly advantageous for treating spent nuclear fuel rods because the system allows the rods to be treated in a single vessel which may be loaded easily in an automated fashion necessary for handling such radioactive materials. The resulting storage mixture may then be poured off into molds in an automated fashion to form the desired long-term storage products.
These and other objects, advantages, and features of the invention will be apparent from the following description of the preferred embodiments, considered along with the accompanying drawings.
Referring to the schematic representation shown in
One preferred treatment vessel 11 will be discussed in detail below with reference to
In some forms of the invention, a heating device 20 will be associated with treatment vessel 11. Heating device 20 might be used for maintaining the liquid reactant metal in treatment vessel 11 at the desired temperature for performing the process or for melting an initial charge of metals in addition to maintaining the reactant metal temperature. Heating device 20 may include a fossil fuel burning system or an electrical induction heating system, or any other heating system suitable for use in liquid reactant metal reactors. A circulating arrangement 21 may also be associated with treatment vessel 11 for circulating the liquid reactant metal within the vessel. Some forms of the invention may also include a tilting mechanism or arrangement 22 for tilting treatment vessel 11 from one position to another in the course of the treatment process. Tilting arrangement 22 will be described in further detail with reference to
Target material loading arrangement 12 is included in system 10 for loading the material to be treated, that is, the target material, into treatment vessel 11. Target material loading arrangement 12 may be any of a number of different structures or devices depending upon the particular target material. For example, where the target material is comprised of spent nuclear fuel rods or portions of such fuel rods, loading arrangement 12 may comprise a remotely operated robotic arm or other structure for picking up one or more of the highly radioactive spent fuel rods and placing the rod or rods into a target material containment structure within treatment vessel 11. This target material containment structure is not shown in the schematic diagram of
Reaction product removal arrangement 14 may include a number of different elements depending upon the nature of the target material. Again using the example of a target material comprising a spent nuclear fuel rod, reaction product removal arrangement 14 will comprise a structure associated with treatment vessel 11 for pouring or otherwise physically removing the storage mixture and directing the storage mixture to molds (not shown in
Where the target material includes materials such as hydrocarbons or other materials that are chemically reduced by the liquid reactant metal, the reaction product removal arrangement may include a gaseous reaction product removal component and a solid/liquid reaction product removal component. Examples of these gaseous liquid/solid reaction product removal components are described in U.S. Pat. No. 6,227,126, the entire content of which is hereby incorporated herein by reference.
The reactant metal conditioning vessel 15 shown in
In forms of the invention in which the target material includes radioactive constituents to be captured in the liquid reactant metal, the treatment process will include adding radioactive emission control material to the liquid reactant metal to ultimately produce a storage mixture. The emission control materials may be added to the liquid reactant metal in any of a number of different ways within the scope of the invention. In one form of the invention, the emission control materials are included with the original materials making up the liquid reactant metal. In this form of the invention the emission control material is already in the liquid reactant metal at the time the target material is added to treatment vessel 11. In other forms of the invention, the emission control materials may be added to the treatment vessel after the target materials are contacted with the liquid reactant metal. In these forms of the invention, emission control material vessel 16 shown in
Regardless of the manner in which vessel 16 is employed according to the invention, where the vessel is present in the system, it will commonly include its own heating arrangement and circulating arrangement 31. Transfer of the storage mixture to the ingots may be accomplished by physically tilting vessel 16 to pour the mixture or by a suitable pumping arrangement. Where materials from vessel 16 are added to treatment vessel 11, the transfer may similarly be accomplished by pouring the liquid metals from vessel 16 or by pumping the liquid metals.
The nature of containment structure 18 will depend upon the nature of the target material being treated in system 10. Where high-level radioactive materials such as spent nuclear fuel rods are being treated, containment structure 18 may comprise a lead lined, reinforced concrete structure. Where no radioactive materials are being treated in system 10, the containment structure may comprise any suitable structure for containing untreated materials, reaction product gases, or molten metals that may inadvertently escape from the various vessels or containers in the system.
An example treatment vessel 11 is shown in
In the side view of treatment vessel 11 provided in
A number of fossil fuel burners 34 are mounted on a top enclosure 35 of vessel 11. These burners 34 form part of the heating system 20 shown schematically in
Circulation within vessel 11 is provided by a number of circulating devices 40 mounted on vessel top 35. These circulating devices 40 correspond to the circulating arrangement 21 shown schematically in
As shown in
Referring to
The vessel top 35 also includes a target material loading door or hatch 54. This loading door 54 may be opened to expose a loading access opening in vessel top 35 which provides access to containment structure 45 to facilitate loading a target material into the containment structure. In the form of the invention shown in
As shown in
The operation of the tilting treatment vessel 11 shown
Once the target material (rod 60) is loaded through loading door 54 and vessel 11 contains the desired quantity of liquid reactant metal, the vessel is tilted by the tilting mechanism 22 to the treating position shown in
The particular containment structure 45 shown in
It will be appreciated that containment structure 45 made up of overlapping components 48 and 49 is preferred for its simplicity. However, numerous other types of containment arrangements may be used with in the scope of the invention. For example, alternative containment structures may include a cage fixed within vessel 11 having a separate cage door or closure. Also, some forms of the invention may include a removable cage or containment structure that may be removed from vessel 11, loaded with target material, and then placed back in the vessel and fixed in the desired position within the vessel. All of these alternatives are encompassed within the scope of the accompanying claims.
Once the target material, in this case spent fuel rod 60, is totally dissolved or otherwise dispersed in the liquid reactant metal below level L in
In any event, the storage mixture received in an ingot forming mold may be allowed to cool and solidify to produce a storage product for the radioactive material decomposition constituents. The ingot may then be encapsulated in a suitable radiation shielding material.
The above described preferred embodiments are intended to illustrate the principles of the invention, but not to limit the scope of the invention. Various other embodiments and modifications to these preferred embodiments may be made by those skilled in the art without departing from the scope of the following claims.
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