DE2501869A1 - NUCLEAR FUEL PARTICLES FOR USE IN THE MANUFACTURE OF NUCLEAR FUEL BODIES - Google Patents

Description

1 BERUIN-DAHLEM 33 PODBIELSKIALLEE 68 β MUNICH 22. WIDENMAYERSTRASSE 49

European Atomic Energy Community Berlin: dipl.-i.ng. r. müller-börner (EURATOM)

MUNICH: DIPL.-ING. HANS-H. WEY

25 733 Berlin, January 15, 1975

Nuclear fuel particles for use in the manufacture of nuclear fuel bodies

The present invention relates to nuclear fuel particles for use in the manufacture of nuclear fuel bodies and their subsequent treatment in a nuclear fuel processing plant.

In a high temperature thorium cycle reactor, i.e. In a high temperature reactor (HTR) that _{uses both fissile (e.g. U 335} ) and incubable (e.g. ^T ^ 232 ^ materials, some of the incubable material is converted into incubated fissile material by neutron absorption, and then the two materials are absorbed during the fuel processing separately. It has been found to be advantageous to separate the spent fissionable materials (U ₃₃₅ and U ₃₃₆₎ from the fertile material. and the hatched U ₃₃₃ at the beginning of the work-up phase. this is intended a production of U ₃₃₆ in the from the ■ Processing of recovered uranium can be avoided.

One known method of carrying out this separation is to form nuclear fuel bodies containing separate particles of "fissile" and "breeding" material, each

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The present invention enables a nuclear fuel body which meets a requirement for heavy metal density without requiring high packing density is.

According to the present invention, a nuclear fuel particle is proposed in which within the particle both fissile and incubable material is included and the two materials are physically arranged in this way and mounted around an internal barrier so that they can be separated from one another subsequent to irradiation.

A nuclear fuel particle for use in the manufacture of nuclear fuel bodies can advantageously be made from a core contain fissile material, with an inner relatively thin coating of barrier material, which is an inner Barrier forms, with a relatively thick intermediate layer of incubable material and a relatively thin outer layer Coating made of fission product-retaining material.

Furthermore, the invention also comprises a method for production of a nuclear fuel particle that allows for the incorporation of both fissile and breeding material into the Particles comprised in that the core is formed from one of the materials and a coating is made on this core Barrier material is applied to form an inner barrier and by subsequently using the coated core the other of the materials is coated and a coating of fission products is retained on the other material Material is applied.

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Particle has its own coating of layered fission product retaining material, e.g. Contains pyrocarbon or pyrocarbon and silicon carbide *

There is a further development of this known method therein, one or more layers of silicon carbide into the To incorporate coatings of "fissile" particles, but not to do so in the case of "breeding" particles. Through this a separation is to be made possible through the use of chemicals that remove the pyrocarbon coatings of the "breeding" Particles dissolve while the "fissile" particles pass through their insoluble silicon carbide layers are protected.

However, the lack of silicon carbide layers in the coatings of the "breeding" particles has a destructive effect Influence on their ability to retain fission products, as certain important fission products (primarily cesium) are under Operating conditions of the H.T.R. ^ in which they are used can wander through even pyrocarbon coatings very quickly.

In addition, the demands according to the one just described known methods used incorporation of two different particle shapes into the fuel body one very much careful control during manufacture to achieve homogeneity and requires in some types of H-T.R. one extraordinarily close packing of particles. This extremely tight packing requirement makes it difficult to obtain the To compress the fuel body so that it is on the one side under radiation and when subjected to high burning conditions and rapid neutron dosing behave satisfactorily, and that on the other hand their coatings does not break when the particles are compacted.

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Furthermore, the invention also comprises a method for producing a nuclear fuel particle which is used for Formation of an internal barrier in the application of a relatively thin coating of barrier material to one Core consists of fissile material, with a relatively thick intermediate layer of incubable material on the barrier Material and then a relatively thin outer coating of fission product-retaining material is applied will.

As used herein, the term "coating" is intended to mean that there is more than one layer may be comprised of one or more materials, and "inner barrier" means a refractory Coating that is able to a significant degree to withstand mechanical loads and chemical conditions to withstand in a nuclear fuel processing plant without their effectiveness as an internal barrier lose. Of course, barrier materials that are used to form an inner barrier must also be suitable for use in a nuclear reactor, and in this regard are used as barrier materials Pyrocarbon and Silicon Carbide, which are used to form fission product-retaining coatings on nuclear fuel particles are preferred to form internal barriers, although other barrier materials are also used that have suitable properties.

An embodiment of the invention and its inclusion in a nuclear fuel body are explained in more detail below with reference to a drawing. This drawing shows a cross section through a nuclear fuel particle.

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A nuclear fuel particle 1 of spherical shape for use in the production of a nuclear fuel body has a core 4 made of fissile material (U ₃₃₅ ) with an inner, relatively thin coating 3 of barrier material (pyrocarbon and silicon carbide), a relatively thick intermediate coating 5 from Breedable material (Th_) and an outer, relatively thin coating 6 of fission product-retaining material is coated. It is clear that the barrier material coating 3 forms the inner barrier around which the fissile material and the incubatable material are arranged and attached.

In detail, the inner coating 3 consists of a coating 3b made of silicon carbide, which is between coatings 3a and 3c. Similarly, the outer coating 6 consists of a coating 6b Silicon carbide lying between coatings 6a and 6c.

In a specific form of use, the core 4 can consist of fissile material have a diameter of 250 μm, the coatings 3a and 3c made of pyrocarbon can each be 30 μm thick and a 40 μm thick layer 3b made of Silicon carbide lying around; the thick coating 5 of incubable material can be 150 μm thick and the outer Coating 6 can consist of a coating 6a from 40

thick pyrocarbon consist of a coating of 40 thick 6b Aim silicon carbide and a coating 6c yam 70 · thick "pyrocarbon.

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Using known methods, the particles can after manufacture with a mixture of graphite powder and resin binders are "overlaid" and compacted in molds to form nuclear fuel bodies of any desired shape, which can be cylindrical, ring-shaped or spherical, for example.

After irradiation, the spent fissile material from the fertile material bodies nuclear fuel may After making the in known manner dedensification of the particles of d ^en separated / by the particles are passed between the spaced rolls or panels with their outer coatings 6 are broken, without to damage a substantial proportion of the inner coatings 3. Although a small part of the inner coatings 3 can be broken up during the passage through the rolls or plates, this small amount of spent fissile material, thereby contaminating the freshly hatched fissile material, can be tolerated during the chemical solution treatment; however, this depends on the intended uses of the incubated fissile material.

The incubable material can then be dissolved by chemicals, while the fissile cores 4 through the inner Chemical attack resistant silicon carbide coatings 3b remain protected.

The particles 1 are produced in that U_ seeds are prepared in oxide or carbide form which contain U_ _g (oxide or carbide) powder mixed with a small percentage by weight of stearic acid binder. the

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Mixture is then agglomerated and brought into spherical shape, by feeding the powder into a rapidly rotating bowl until "fissile" cores of the desired diameter can be obtained.

After heat treatment to remove the binder and make the cores porous, the cores are placed in a fluidized bed furnace to obtain their coatings 3. The coated "fissile" particles are then removed from the oven and used as "seeds" for a further agglomeration process in which they are coated with a mixture of Th___ in oxide or carbide form and a binder to form the relatively thick coatings 5. After further heat treatment to remove the binder and make the coatings 5 porous, the particles are returned to the fluidized bed furnace, where they receive their pyrocarbon / silicon carbide / pyrocarbon coatings 6. It is clear that incubated U ₃₃₃ * ^ ^as ^ is obtained by irradiating Th ₃₃₂ , instead of the U ₃₃₅ according to the method described above for the preparation of particles 1 can be taken if the desired amount of U _{333 is} available.

Although the invention has been described in the preferred arrangement has been, in which the fissile material forms the core 4, the position of the fissile and the incubatable material can be reversed if this is necessary for certain types of use.

Nuclear fuel can be "overlaid" by the body Particles 1 are formed by agglomeration using a mixture of graphite powder and resin binder and the parts are then compacted in a mold under moderate pressure

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with the soft coatings deforming.

The "overcoat" can be binders such as silicon carbide contain.

The invention provides composite nuclear fuel particles, which contain fissile and incubable materials, with internal barriers (the coatings 3) separating the materials from one another keep separate. The invention further provides such particles in which the use of silicon carbide coatings (3b, 6b) ensures good retention of fission products, although the coating 3b does not the same degree of impermeability is required for fission product traversal as is required for the outer coating 6b is required.

The invention also enables "heavy" metal densities to be achieved in the manufacture of nuclear fuel bodies and with a relatively modest packing density. reason this is that the number of separated and packaged particles is reduced, while the thickness of the required Coatings 3 and 6 remain essentially constant regardless of particle diameter. The volume of space that occupied in the coated particle by the layer material

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is proportional to 'r', where 'r' is the radius of the fuel particles.

On the other hand, the volume of heavy metal in the particle is proportional to 'r', so the larger the total radius of the Particle, the greater the ratio of the volume occupied by the metal (in oxide or carbide form). There the amount of heavy metal required in a body of fuel by the physical characteristics of the Nuclear reactor in which it is used is determined

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clear that for the larger particles created by the invention can be produced, a smaller volume of sheet material and a smaller number of particles for one certain amount of heavy metal is required than would be the case with a nuclear fuel body that is completely consists of coated particles that separately contain fissile or incubatable material, thereby creating greater volume for pressed "overlay" material is available to separate and protect the particles during compaction of the nuclear fuel body. One Consideration limiting the size of the particle is the temperature differential that occurs during irradiation between the inner barrier and outer coating of the fission product retaining material is created; but this may be considered when designing specific nuclear fuel particles in accordance with the invention will.

The fissile and incubable regions of the nuclear fuel particles of the invention can also be prepared by other methods used for the production of nuclear fuel particle cores can be used, e.g. according to the sol-gel process.

Another fissile material, for example P ^u ₂ 39, such as another incubable material, for example U ₃₃₈ , can also be used.

Of course, a variety of internal barriers can be formed that separate fissile and breeding materials within a nuclear fuel particle.

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Claims (11)

Claims 1.) Nuclear fuel particles, characterized in that within the particle (1) both it contains both fissile and incubable material and that the two materials are surrounded by an inner barrier (3) are physically arranged and attached in such a way that they are separated from one another after an irradiation can be. 2. Nuclear fuel particles according to claim 1 for use in the production of nuclear fuel bodies, characterized by a core (4) made of fissile Material that is used to form an inner barrier from an inner relatively thin coating (3) of barrier material, from a relatively thick intermediate coating (5) made of incubable material and from an outer, relatively thin one Coating (6) is covered from fission product-retaining material. 3. Nuclear fuel particles according to claim 2, characterized characterized in that the barrier material consists of material retaining fission products. 4. Nuclear fuel particles according to one of claims 1 to 3, characterized in that the fissile material consists of U ₃₃₅ or incubated U2 ₃₃ and that the incubable material consists of Th ₂₃ . - 11 - 509831 / 0S65 5. nuclear fuel particles according to claim 3, characterized ' characterized in that the fission products are restrained Material (3) consists of a coating (3b) made of silicon carbide, which between PyrocarbonbeSchierungen (3a, 3c) lies. 6. Process for producing a nuclear fuel particle according to claim 1 or 2, characterized in that within the particle both Fissile as well as incubable material is included, in that the core (4) is formed from one of the materials is> and that a coating (3) made of barrier material is applied to it to form an inner barrier that subsequently the coated core is coated with the other of the materials (5) and that then a coating (6) made of material retaining fission products is applied to the other material will. 7. Process for producing a nuclear fuel particle according to claim 1, characterized in that an inner barrier is used to form an inner barrier A relatively thin coating (3) made of barrier material is applied to a core (4) made of fissile material that then a relatively thick intermediate coating (5) made of incubable material is applied, on which an outer, relatively thin coating (6) made of fission products restrained material follows. 8. The method according to claim 7, characterized in that the inner barrier from SpaIt products retentive material is formed. - 12 - 509831/0565 9. The method according to any one of claims 6 to 8, characterized in that U ₃₃₅ or incubated U ₉₃₃ seeds are mixed in oxidic form with a small percentage by weight of stearic acid binder, that the mixture is then agglomerated and brought into spherical shape by the mixture for Forming fissile cores is filled in a rapidly rotating shell, after heat treatment to remove the binder and to make the core porous, the core is placed in a fluidized bed furnace, where it contains a relatively thin coating of pyrocarbon and silicon carbide to form an internal barrier that the coated Cores are then agglomerated with Th «_2 and stearic acid as a binder, creating a relatively thick envelope around the coated core and then, after the heat treatment to remove the binder and make the coating porous, the cores are coated with pyrocarbon and silicon carbide. 10. Nuclear fuel body characterized by nuclear fuel particles according to one of the claims 1 to 5 in close packed relationship within a graphite matrix. 11. A method for separating fissile and incubable material from nuclear fuel particles, which are arranged according to one of claims 1 to 5 or 10, characterized in that the particles are passed between spaced rollers or plates, their outer SpaItprodukte-inhibiting coatings are broken, without damaging a substantial portion of the internal barriers in the particles Se / MP - 25 733 509831/0565