RU2451350C2 - Method to immobilise nuclear waste - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: nuclear waste is mixed with a mineral composition and water, dried to form an immobilising matrix, differing by the fact that the mineral composition is produced by a manufacturing method, including stages that consist in preparing a base containing a certain amount of mineral material synthesised at least by a part of a live structure selected from flora or fauna and/or from a number of microorganisms; and in processing the specified base for its conversion into an inactivated substance of a certain texture.

EFFECT: invention makes it possible to immobilise nuclear waste, which may not be immobilised with classic cementing.

10 cl

Description

The present invention relates to a method for immobilizing nuclear waste with a matrix based on a mineral composition obtained by preparing a base containing a certain amount of mineral material synthesized by at least a part of a living structure selected from a plant, animal kingdom and / or from among microorganisms.

Radioactive or nuclear waste is radioactive material, the use of which is not provided and the dispersion of which in the environment is not permitted. Radioactive waste includes a huge number of substances that differ, in particular, in their activity and half-life, as well as in their state (solid, liquid, gaseous) and chemical composition.

Disposal of waste, more specifically, waste of radioactive origin, is a major environmental problem. Nuclear waste (liquid or solid) can be contaminated on the surface and / or in bulk.

Nuclear industry waste is specific. On the one hand, their activity decreases with time, and, on the other hand, their diversity requires different conditioning methods adapted to their volumes and activity. There are a number of ways to condition nuclear industry waste.

For nuclear waste, two main conditioning methods are used: pressing and insulation.

The primary conditioning method is pressing, in which the products to be sealed are placed in a container.

Isolation or immobilization of waste is a method that is often used in the nuclear industry when cement or polymer serves to immobilize nuclear waste inside containers, or when a conditioning matrix is used to fill nuclear waste.

In addition to the use for the isolation of solid massive waste in containers, cementing is also used to coat the waste in the form of solutions or powder, for example, evaporation residues, chemical sludge or ion-exchange resins.

Regardless of the degree of contamination of nuclear waste, they must be stored in reliable facilities for a sufficiently long time, for example, several centuries. During the storage period, it is necessary to ensure the integrity of the containers for storing, more specifically, the casing and contents consisting of waste and matrix.

These waste containers must meet strict criteria, in particular regarding the matrix. The contents should be sufficiently stable and not subject to dispersion depending on the storage conditions.

Insulation with cement is a cheap and easy to implement method, which is not without drawbacks. The interaction between the constituents of some nuclear waste and the cement matrix can lead to bloating and cracking of the container, reducing its durability.

Cementation is the most commonly used solid waste disposal method. The main reasons for this choice are the abundance of raw materials, the density of the material (biological protection), mechanical strength, the availability of knowledge about the behavior of an object over time, the reliability of the method and the simplicity of its implementation. The pre-compressed or mixed waste is usually placed in a basket, which, in turn, is placed in a metal or concrete container, after which they are immobilized with cement, designed to limit the risk of radioactive elements penetrating outside, and thus form a heterogeneous protective shell.

However, cementation does not guarantee the durability of containers for some nuclear waste with chemical contaminants (sulfates, ...) or reagents containing organic matter.

Indeed, the cementation process is an exothermic process that is dangerous because it can cause violent reactions when mixed with some reactive nuclear waste.

In addition, the cement medium has an alkaline pH of about 13-14, which may be incompatible with some nuclear waste.

Moreover, the isolation of radioactive materials generates gases, which does not guarantee the integrity of the containers for a long time, for example, for a period of at least 300 years.

Thus, one of the objectives of the present invention is to propose another solution that would allow the immobilization of nuclear waste and not have the disadvantages of the solutions of the prior art.

Thus, the invention provides a method for immobilizing nuclear waste, including:

- The mixing step, during which the nuclear waste is mixed with the mineral composition and water.

- A drying step, during which the mixture obtained in the mixing step is dried to form an immobilizing matrix,

in which the mineral composition is obtained by a manufacturing method, comprising the steps that consist of:

- preparing a base containing a certain amount of mineral material synthesized by at least a part of the living structure selected from the plant, animal kingdom and / or from among microorganisms; and

- processing said base to convert it into an inactivated substance of a certain texture.

Preferably, the immobilization method of the invention allows the immobilization of chemical contaminated nuclear waste and / or reactive metal nuclear waste and / or organic nuclear waste that cannot be immobilized by classical cementation.

In addition, the immobilization method according to the invention may include one or more of the following optional features, considered individually or in all possible combinations:

- the mineral composition is chosen so that it, when mixed with water, has a pH in the range from 11 to 12.5, for example, from 11 to 12;

- the mineral composition is chosen so that the reaction between the composition and water is substantially athermal;

- the ratio between the mass amount of the mineral composition and the mass amount of water was greater than or equal to 1, for example, greater than or equal to 1.5 and less than or equal to 85/15;

- the mineral composition is chosen so that the immobilizing matrix is resistant to compression above or equal to 8 MPa for 8 days;

- during the mixing step, sand may be added so that the ratio between the mass amount of the mineral composition and the mass amount of sand is greater than or equal to 1.5 and lower than or equal to 10;

- the mixing step includes:

a pre-mixing step during which the mineral composition and water are mixed,

a mixing step during which the mixture obtained in the preliminary mixing step is mixed, and

- the introduction stage, during which the mixed mixture is introduced into the shell containing waste intended for immobilization;

- the mixing step includes:

a pre-mixing step during which nuclear waste, mineral composition and water are mixed,

a mixing step during which the mixture obtained in the preliminary mixing step is mixed, and

- the introduction stage, during which the mixed mixture is introduced into the shell designed to accommodate nuclear waste;

- the mineral composition comprises at least 50% and at most 80% by weight of calcium carbonate;

- the mineral composition includes at least 10% and at most 30% by weight of silicon;

- the mass amount of nuclear waste in the immobilizing matrix depends on the shape and density and is greater than or equal to 10% and less than or equal to 80%.

The invention can be better understood by reading the description below, which is given only as an example.

The present invention relates to a method for immobilizing nuclear waste with chemical pollutants or reactive waste or containing organic matter, and more specifically, waste that cannot be isolated by classical hydraulic binders.

Preferably, the method according to the invention allows for the sealing of these wastes in a uniform and durable matrix that meets established storage criteria.

Among the nuclear waste that can be isolated by the method according to the invention can be listed without limitation mentioned: oils, resins, ion exchange resins, graphite, magnesium, uranium, aluminum, bitumen, sludge, glycol water, products based on borate and sulfate, sludge or concentrates containing organic matter, and mixtures thereof.

According to one embodiment of the invention, the immobilization method comprises:

- a mixing step during which the nuclear waste is mixed with the mineral composition and water,

- a drying step, during which the mixture obtained in the mixing step is dried to form an immobilizing matrix.

A mixture of the mineral composition and water allows the mineral composition to create a structure leading to the formation of a three-dimensional network. The formation of such a network leads to the setting of a mineral composition connected with water around nuclear waste, which after a certain drying time provides a compact mass consisting of waste and an immobilizing matrix.

The mineral composition used in the method according to the invention is obtained by a manufacturing method, comprising the steps, which consist of:

- preparing a base containing a certain amount of mineral material synthesized by at least a part of the living structure selected from the plant, animal kingdom and / or from among microorganisms; and

- processing said base to convert it into an inactivated substance of a certain texture.

Documents FR 9405013, FR 9504830, FR 9504831, FR 9504832 and WO 95/29250 describe examples of mineral compositions that can be used in the method of the invention.

According to one embodiment of the invention, the mineral composition used in the method according to the invention is a mineral composition obtained by a manufacturing method, comprising the steps that consist of:

- preparing a base containing a certain amount of mineral material synthesized by at least a part of the living structure selected from the plant, animal kingdom and / or from among microorganisms; and

- processing said base to convert it into an inactivated substance of a certain texture.

In the context of the invention, “living structure”, mineralizing, mineralized or mineralizable, is understood to mean any cellular structure or structure of cellular origin, plant, animal and / or microbiological, living and / or resulting from life and / or compounds of biological origin, crystalline or not in particular, enzymes, hormones, proteins, DNA.

By “inactivated substance” is meant a substance devoid of any biological and / or biomineralization activity, more specifically, any pathogenic microbiological activity.

In the context of the invention, the term "mineral" should be understood in a broad sense, that is, having a mineral in its composition.

The step of preparing the base may include a phase consisting in cultivating said living structure for such a period and in such an environment that this structure will produce or synthesize at least a portion of said material called “mineral biomass”.

The processing step may then include a phase of inactivation of the living structure. Inactivation should be understood to mean the production of an inactivated substance as defined above from a living structure as defined above.

The mixing phase can be performed during one of the steps of the cooking method.

Preferably, this mixing phase is carried out at least partially simultaneously with the other phase of the method according to the invention, for example, during inactivation or after the mixing step.

The manufacturing method can be implemented with microorganisms and / or cells of plant or animal origin, separately or in a symbiotic or other combination, saline, saline or saline.

Said living structure may be plant and / or animal or derived from a plant and / or animal, for example, a cell, tissue or organ.

In the plant kingdom, one can turn with equal success both to higher plants, dicotyledons, monocotyledons, and to lower plants, tallophytes or microorganisms.

Depending on the specific case, the selected structure is cultivated, in particular, in vivo, in the earth, on a layer rich in organic substances, hydroponic, in Petri dishes, in a reactor, for example in a fermenter, or grown in battery cells, on the root or by fish farming methods .

The structure can be cultured in an appropriate nutrient medium known to those skilled in the art, for example, Knopli liquid, Irle, Hanks solution, medium called “199”, Saburo medium, Eagle MEM medium, or the like.

The step of preparing the base may include the phase of obtaining and / or collecting said living structure and introducing it into the base in such proportions that this introduction forms at least part of the necessary mineral material.

The mineral material obtained and / or collected in this way can be of a different nature: carbonate, silicon, salt, fluoride, barite, carbon, glandular, in the form of, for example, sediments, modern and / or fossil nodules. Then it is introduced into the base either at the preparation stage or at the processing stage.

The composition of the final substance may include fossil sedimentary rocks and / or other rocks, such as granite, basalt, pumice or others.

During a possible phase of the manufacturing method, at least one of the aforementioned biomass, base, material and / or mineral substance is ground during the preparation step and / or the processing step.

Said grinding is at least partially carried out by ultrasonic grinding and / or physicochemical means, such as adding additives, irradiation, cryogenic and / or heat treatment, grinding or pressure change.

One of the phases of the method may be to prepare a suspension of said biomass, base or material in a liquid, preferably aqueous, for example, for spraying or brushing. This liquid may be included in the composition of one of the mentioned culture media.

During one of the phases of the method, it is possible to introduce a dye of a certain shade into at least one of the following components: culture medium, biomass, material, base and mineral substance.

A possible phase of the preparation and / or processing step is the incorporation of a binder and / or texturing agent into at least one of the following components: biomass, medium, material, base and mineral substance.

This binding and / or texturing agent is preferably a metal, for example calcium, magnesium, silicon, barium, sodium, fluorine, aluminum, iron, manganese, zinc or an organic substance, for example collagen, mucopolysaccharide and / or a polycellulose compound.

Preferably, the proportions and composition of said texturing agent are selected so that the final substance has a given strength and / or elasticity.

In addition, the manufacturing method may include the phase of full or partial dehydration of the inactivating salt or salts included in the composition of the aforementioned base and / or mineral.

This dehydration phase can be at least partially carried out by filtration, centrifugation, heat and / or cryogenic treatment.

According to the manufacturing method, it is envisaged that the phases of inactivation, dehydration and grinding can at least partially be carried out simultaneously.

During one of the phases or steps of the manufacturing method, an additive, for example, a foaming agent, a fibrous material, a binder, an insulating substance, a fire retardant or the like, may be added to the base and / or mineral.

The following classification gives non-limiting examples of structures that can be selected for use according to the invention:

a) From among dicotyledons:

- Plant cells of the order Daucales, the family Araliaceae (Araliaceae), the genus Hedera (ivy), in particular, Hedera helix (ivy ordinary);

- Plant cells of the order Arales (aralia), of the genus Rhaphidophora (rafidofora), of the species Syngonium podophyllum (pedigree syngonium) (Schott), Albolineatum, of the species Syhgonium auritum (syndium ear-shaped), another name of the Philodendron trifolium trifolium species (trifolium trifolium) ;

- Plant cells of the order of Solanales (nightshade), the Bignoniaceae family (Bignoniaceae), and the species Catalpa bignonioides (Catalpa bignoniform), when it comes to calcium oxalate in the octahedral form, “in the form of sea urchins”, present in abundance, for example, in petiole cells.

Any plant cell, even one that exhibits a weak tendency to symbiosis, can be mineralized and / or supermineralized in a way that we have discovered if it is brought into contact with such microorganisms.

This applies to the cells mentioned above, as well as to all plant cells obtained, for example, from shrubs in the form of shavings, sawdust and which are fossilized or converted into a tufa and / or travertine stone in this way.

b) From among monocotyledons:

- Plant cells of the order Pandarales (pandanaceae), in particular, the family Typhaceae (cattail);

- Herb cells, in particular the Lemnaceae family (duckweed)

c) Of the ferns:

The epidermis in Equisetum arvense (field horsetail) is the site of the formation of silicon mineral formations, which are sometimes considered calculi resulting from the secretion of epidermal membranes, while bacteria on the periphery and / or inside Equisetum arvense cells are involved. They explain the presence of silicon deposits inside and / or outside the cell. The accumulation of silicon in the sterile aerial shoots of Equisetum arvense and the reserves of opal silica, which have invaded the epidermis of its various aerial organs, are associated with the presence and symbiotic participation of bacteria. We are talking about rod-shaped bacteria from 0.4 to 0.7 microns in length and 0.1 microns in thickness. These rod-shaped bacteria cause gradual external swelling of the participating cells as the bacterial film develops. These successive films create a uniform and layered accumulation of silicon.

d) Of the algae

According to the invention, biomineral masses formed as a result of reproduction and accumulation of algae shells can be used in a natural or industrial way.

An example is:

- Rhodophyceae (red algae) mainly with the order of Nemalionales (non-metallic), Solenoporaceae (saline-pore) and Corallinaceae (coralline), including Lithothamnium (lithotamnion), Melobesia (melobesia);

- Chlorophyceae (green algae) with the order Siphonales (siphon) (including Codiaceae (codia), in particular Halimeda (halimeda) and Dacycladales (dasicladic) (including Dacycladaceae (dasicladic family), in particular Acetabularia (acetabulia);

- Charophyceae (char algae) with the family Characeae (char), in particular Cladophora (cladophore) and Vaucheria (vosheria);

- Schizophyceae with Porostromata and Spongiostroma, in particular Rivularia (rivulary), Oscillatoria (oscillatorium), Phormidium (formidium), Chroococcus (chroococcus) and Gleocapsa (gleocaps), which can be selected.

e) Lichens:

Biomineral mass may also be the result of a triple plant association of lichen type culture. Lichens are heterogeneous plant associations. The association, called mutually beneficial, consists of a fungus, algae and mineralizing bacteria, similar to those that we described above.

These bacteria contribute to the formation of complex and stained mineral inclusions within the mycelium.

The existence of lichen acid deposits in the form of extracellular hydrophobic crystals is due to the mineralization of lichens by the mentioned symbiotic bacteria. Symbiotic bacteria differ from the sometimes mentioned cyanobacteria in their small size and lack of pigment.

So, a living structure can simply be plant cells with such physiological equipment.

f) Among the mushrooms:

The structure of plant origin may be a lower plant selected from among the fungi and their spores.

g) Among the microorganisms:

The living structure can be a microorganism, for example a virus or bacterium, in particular Bacillus megatherium, Pseudomonas fluorescens, Pseudomonas maltophilia, Pseudomonas putida, Buttauxiella agrestis, Rhodococcus, Serratia marescens.

You can plan the use of the virus as a living structure.

The living structure may also be an animal or part of an animal, for example, a cell, tissue and / or organ selected from among the simplest or multicellular invertebrates, in particular spongiform, platelet-gill and echinoderms, or also from among vertebrates.

One or several compatible living structures, symbiotic or cooperating, can be cultured in one medium, regardless of whether they are of plant, animal or microbiological origin.

The purpose of the first stage of preparation is to obtain a mineral base, i.e. an intermediate product. Preferably, the step of preparing the base comprises a phase consisting in culturing said living structure for such a period and in such an environment that this structure will produce or synthesize at least a portion of said material referred to as “mineral biomass”.

The second stage consists in processing the aforementioned base after its super-mineralization in such a way as to turn it into a deactivated or inactivated mineral substance of a certain texture.

As an example, one or more correspondences between living structures and minerals and / or rocks listed below can be selected.

Hedera helix (ivy) cells correspond to calcium oxalate / limestone.

Ficus elastica cells (ficus elastic or rubbery) correspond to calcium carbonate / limestone.

Equisetum cells (horsetail) correspond to silicon / opal silica / silicified wood / sandstone.

Graminea (cereal) cells correspond to silicon / opal silica / silicified wood / sandstone.

Typhaceae (cattail) cells correspond to silicon / opal silica / silicified wood / sandstone.

Ascomycete (Ascomycete) corresponds to calcium dipicolinate / limestone.

Pectascinaceae cells correspond to calcium carbonate / limestone.

Pheophysea algae corresponds to silicon / diatomite.

Rhodophyceae algae (red algae) corresponds to calcium carbonate / limestone / travertine.

Chlorophycea algae (green algae) corresponds to calcium carbonate / limestone / travertine.

The algae Cyanophycea (blue-green algae) corresponds to calcium carbonate / limestone / travertine.

Lamellibranchea mollusk (Lamellar-gill) corresponds to calcium carbonate / limestone / limestone sandstone.

Biomass production is subject to the usual laws of growth of living structures: there is no need to accurately describe the phase of culture.

Depending on the living structure to be grown, the specialist will be able to determine which method and environment can be used with the greatest success.

So, depending on the type of structure chosen, one of the developed methods can be applied, in particular, in vivo culture, in the earth, on a layer rich in organic substances, hydroponic, in Petri dishes, in a reactor, for example, in a fermenter, or grown in battery cells, in the vine or by fish farming methods.

In the event that the plants maintain their integrity, traditional methods of culture are preferably used (in the ground, in the greenhouse, by the method of hydroponics and the like).

If the living structure mentioned is part of a plant, for example a cell, tissue or organ, the living structure can be derived from the so-called higher plants, monocotyledonous, such as duckweed, or dicotyledonous, and in particular from Daucales, vines, Bignoniaceae (bignoniaceae) , Moracaea (mulberry), Comrnaceae, Cactaceae (cactus).

For this type of structure, which, for example, produces a tuff and / or travertine substance, the following culture medium can be used:

Distilled water 1000 grams Calcium nitrate 0.71 Potassium nitrate 0.568 Magnesium sulfate 0.284 Ammonium phosphate 0.142 Ferric chloride 0,112 Potassium iodide 0.0028 Boric acid 0,0005 Zinc sulphate 0,0005 Manganese Sulfate 0,0005

In addition, the plant structure may be algae, in particular Rhodophyceae (red algae), Chlorophyceae (green algae), Charophyceae (char algae), Schyzophyceae, Cyanophycea (blue-green algae), Pheophyceae (brown algae) and / or also the simplest unicellular organism, and then other media should be considered.

The situation is also the case if the living structure is an animal or part of an animal, for example, a cell, tissue and / or organ, and more particularly the simplest one with a sandy, carbonate, silicon or chitinous shell, mesoglay of sponges with calcareous or silicon spicules, coral cells, epidermal cells mollusks or also cells originating from the bone structures of vertebrates. Mineral biomass can be obtained by in vitro culture of cells, tissues and / or organs of the animal kingdom involved in mineral biosynthesis.

For example, to obtain specific limestone, you can resort to modern and / or fossil coral products.

Microorganisms can also be cultivated in large quantities in commercial fermenters that are commercially available, and in particular in tangential filtration ultra-fermenters that allow for the organization of a continuous production process.

One or more compatible living structures can be cultured in one medium, if necessary, with at least one other compatible structure of plant, animal and / or microbiological origin.

The second stage consists in processing the aforementioned base after its super-mineralization in such a way as to turn it into an inactivated mineral substance of a certain texture.

So, in the production of biomass based on a living structure, the processing stage includes the inactivation phase of the living structure.

This inactivation phase can be carried out by adding at least one salt, such as, for example, magnesium oxide, magnesium sulfate, calcium chloride, barium chloride, preferably in anhydrous form.

Biomass is stabilized, that is, inactivated so that any cellular development is stopped. This result can be achieved by adding in the appropriate proportions one or more salts listed above, or substances that have a similar effect on the living structure contained in the mass.

When these compounds are used, the proportions (in mass units) corresponding to 1 part of magnesium sulfate, 0.5 part of calcium chloride, 0.5 part of barium chloride, 2 parts of magnesium oxide, preferably anhydrous, are acceptable. However, these proportions may vary, in particular in the range from 20% to 50%.

You can apply other methods of inactivation, individually or as a supplement, including the use of chemicals, in particular fluorosilicates, as well as irradiation and raising the temperature to a high level.

The mixing phase can be performed during one of the steps of the manufacturing method. Preferably, this mixing phase is carried out at least partially simultaneously with another phase of the process, and more particularly during inactivation.

You can resort to two phases of inactivation: one during the production of the product, and the other during application, for example, when the product is in a mixture state according to the method according to the invention.

So, the complete inactivation of living base structures is carried out by mixing the biomass and these salts with the addition of an equal amount of water, which ensures their good mixing. For example, you can add a base to the listed salts in a proportion of 0.5 parts of the base per 1 part of salts to 4 parts of the base per 1 part of salts.

One of the advantages of the manufacturing method is that the step of preparing the base can include a phase consisting in obtaining and / or collecting either said living structure or sedimentary mineral material and introducing it into the base in such proportions that this introduction forms at least part necessary mineral material.

You can collect mineral material in the form of, for example, sediments, modern and / or fossil nodules, and introduce it into the base either at the preparation stage or at the processing stage.

In addition, the living structure is chosen so that the associated mineral substance contains at least one carbonate, silicon, selenite mineralogical component or similar components. There are many other new mineral sources that can be used according to the invention. During pruning of shrubs or other agricultural operations (harvesting, including haying, reaping, harvesting grapes and others), a large number of mineralized or mineralized or mineralizing products are formed that are capable of supermineralization (hay, straw, stubble and the like).

During some industrial operations, waste products of plant origin are generated, for example sawdust, which can be mineralized. Plant cells are referred to as relatively rigid and, more specifically, creeper cells, such as, for example, Syngonium podophyllum (pedigree syngonium), Syngonium auritum (ear-shaped syngonium), another name Philodendron trifolium (three-leaf philodendron) and Syngonium hastifolium. Ivy, fig trees are a potential source of mineral substrates. Of course, this also applies to coastal seaweed deposits, such as sandy silt.

During a possible phase of the manufacturing method, at least one of the components: biomass, base, said mineral material and / or substance is ground during the preparation step and, if necessary, during the inactivating treatment step.

For example, if mineral and / or layered aggregates are obtained from a culture of a living structure, which can be crushed if necessary for their use in the bulk of the substrate. Also, if part or most of the mineral material is represented by fossil or solid waste as explained above, the blocks of the collected mass can be crushed or ground.

The grinding phase is performed until the desired texture or ductility is achieved. In other words, the purpose of grinding is to obtain a more or less friable substance, preferably a given particle size distribution.

Said grinding is at least partially carried out by ultrasonic crushing and / or physicochemical means, such as adding additives, cryogenic and / or heat treatment, grinding or changing the pressure.

In this case, one of the phases of the manufacturing method may consist in preparing a suspension of biomass or said ground material in a liquid, preferably aqueous. It is possible that during one of the phases of the method at least one of the following components is introduced into it: culture medium, biomass, base and mineral substance. Perhaps this substance is an element of biomass.

The stage of preparation and / or processing may consist in introducing at least one of the following components: biomass, medium, material, base and mineral substance, binding and / or texturing substances. This substance is preferably a binder, more specifically a metal, for example calcium, magnesium, silicon, barium, sodium, fluorine, aluminum, iron, manganese, zinc or an organic substance, for example, collagen, mucopolysaccharide and a polycellulose compound.

Obviously, this substance performs the function of an inactivating compound, if possible, if the base contains a living structure that has been cultivated or harvested.

Preferably, the proportions and composition of said binder and / or texturing agent are selected so that the final substance has a given strength or elasticity.

During one of the phases or steps of the method, an additive, for example, a foaming agent, a fibrous material, a binder, an insulating substance, a flame retardant or the like, may be added to the base and / or mineral.

In addition, the method may include a dehydration phase of at least partial one or more components of the aforementioned base and / or mineral.

This dehydration phase can be at least partially carried out by filtration, irradiation, centrifugation, heat and / or cryogenic treatment.

According to the method, it is provided that the phases of inactivation, dehydration and grinding are at least partially carried out simultaneously.

According to one embodiment of the invention, the mineral composition comprises at least 50% and at most 80% by weight of calcium carbonate and at least 10% and at most 30% by weight of silicon.

The mineral composition of the invention may take the form of a solid with separated components, which, after adding a certain amount of water and a thorough mixing step, gives a mass called a stone mixture.

The viscosity of the mass of the stone mixture is adjusted by changing the proportions of the mineral composition and water.

The manufacture of an insulating matrix is possible after thorough mixing of the mineral composition and water at ambient temperature. The fluidity of the mixture, mechanical properties and solidification time depend on the water content. It is adapted depending on the nature of the material and is used to isolate nuclear waste.

Drying the mass of the stone mixture gives a homogeneous matrix, the mechanical and chemical properties of which are compatible with the storage of nuclear waste.

For example, an immobilizing matrix has the following mechanical properties:

- resistance to compression above or equal to 8 MPa, usually 25 MPa after 30 days; and / or

- lack of gaseous discharge and sweating even under load; and / or

- shrinkage in size corresponding to cement matrices; and / or

- good radiation resistance; and / or

- the absence of changes in compression behavior after irradiation with a dose of 1300 kGy.

According to one of the methods of embodiment of the invention, the mixing step includes:

a pre-mixing step during which the mineral composition and water are mixed,

a mixing step during which the mixture obtained in the preliminary mixing step is mixed, and

- the introduction stage, during which the mixed mixture is introduced into the shell containing waste intended for immobilization.

According to one of the methods of embodiment of the invention, the mixing step includes:

a pre-mixing step during which nuclear waste, mineral composition and water are mixed,

a mixing step during which the mixture obtained in the preliminary mixing step is mixed, and

- the introduction stage, during which the mixed mixture is introduced into the shell designed to accommodate nuclear waste.

The invention is not limited to the described methods of embodiment and should not be construed restrictively, encompassing any equivalent method of embodiment.

Claims (10)

1. The method of immobilization of nuclear waste, including:
a mixing step during which the nuclear waste is mixed with the mineral composition and water,
a drying step, during which the mixture obtained in the mixing step is dried to form an immobilizing matrix,
characterized in that the mineral composition is obtained by a manufacturing method, comprising the steps that consist of:
preparing a base containing a certain amount of mineral material synthesized by at least a part of the living structure selected from the plant, animal world and / or from among microorganisms; and
processing said base to convert it into an inactivated substance of a specific texture. 2. The method according to claim 1, in which the mineral composition is chosen so that it, when mixed with water, has a pH value from 11 to 12.5. 3. The method according to claim 1 or 2, in which the mineral composition is chosen so that the reaction between the composition and water is substantially athermal. 4. The method according to claim 1 or 2, in which the ratio between the mass amount of the mineral composition and the mass amount of water is in the range from 1, for example, greater than or equal to 1.5, to 85/15. 5. The method according to claim 1 or 2, in which the mineral composition is chosen so that the immobilizing matrix has a resistance to compression greater than or equal to 8 MPa for 8 days. 6. The method according to claim 1 or 2, in which sand is added during the mixing step so that the ratio between the mass amount of the mineral composition and the mass amount of sand is greater than or equal to 1.5 and lower than or equal to 10. 7. The method according to claim 1 or 2, in which the mixing step includes:
pre-mixing step, during which the mineral composition and water are mixed,
a mixing step during which the mixture obtained in the pre-mixing step is mixed, and
the introduction stage, during which the mixed mixture is introduced into the shell containing waste intended for immobilization. 8. The method according to claim 1 or 2, in which the mixing step includes:
a pre-mixing step during which the nuclear waste, the mineral composition and the water are mixed,
a mixing step during which the mixture obtained in the pre-mixing step is mixed, and
the introduction stage, during which the mixed mixture is introduced into the shell designed to accommodate nuclear waste. 9. The method according to claim 1 or 2, in which the mineral composition comprises from 50 to 80% by weight of calcium carbonate and from 10 to 30% by weight of silicon. 10. The method according to claim 1 or 2, in which the mass amount of nuclear waste in the immobilizing matrix is from 10 to 80%.