ES2609602T3 - Storage well system for the storage of spent nuclear fuel and a method for storage thereof - Google Patents

Abstract

A storage well system for the storage of spent nuclear fuel, consisting of at least one horizontal corridor (3) from which at least one storage system characterized by consisting of an inclined characterization guide well (1) and a well of inclined storage of greater diameter (2), excavated in the central line of said characterization guide well (1), with an identical inclination angle below the horizontal level, in which the length of the characterization guide well (1) exceeds that of the storage well (2), and in which said well is placed at least one storage tank (6) to receive the spent nuclear fuel.

Description

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Investigation Camp

The invention is directed to the system of wells for the storage of spent nuclear fuel, or of highly radioactive waste, and a method for its storage.

Background of the invention

According to the most advanced techniques for the treatment of spent nuclear fuel or highly radioactive waste (hereinafter, "spent nuclear fuel"), the materials intended for dumping are stored in so-called deep repositories. Before storing them in such repositories, spent nuclear fuel is placed in special storage containers. Currently, two basic principles of deep repositories are used: vertical or horizontal storage wells, and eventually a combination of both.

The storage method in vertical storage wells is based on the assumption of the storage of spent nuclear fuel in storage containers located in the wells, and that the space between the containers and the rock is filled with an intermediate barrier of bentonite.

Vertical wells are described in international patent application WO 2008032018, according to which spent nuclear fuel is stored in solid barrels within a vertical well 3-5 km deep.

Chinese patent CN 101971268 describes the storage of spent nuclear fuel in a vertical well by means of cables that reach the bottom of it. Storage containers are stored in the space surrounded by these cables.

Russian patent RU 2212720 describes the storage of spent nuclear fuel in vertical wells 100 m deep, inside special repositories equipped with a steel lining and a concrete filling, which includes concentric steel shells. Among the disadvantages of these solutions, it is worth mentioning the impossibility, or difficulty, of removing spent nuclear fuel and large volumes of excavated rock.

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The method of storage of spent nuclear fuel in a horizontal storage pit is described in Canadian patent CA 1106626, according to which the fuel is stored in the longitudinal groove at the bottom of a horizontal tunnel.

Another known method is described in US patent application US 2010/0234663, according to which, at the base of a vertical well, several horizontal horizontal wells are drilled, in which the radioactive fuel is stored inside special containers. The removal of the containers is carried out by means of secondary longitudinal wells, using a special mechanism that includes a connector of the container, the extraction mechanism connectable to the container, and a perforation pipe.

Japanese patent JP 2008073572 describes a method of storage of spent nuclear fuel in a horizontal well, and its withdrawal by a parallel horizontal well located below the level of the storage well. Both parallel wells are connected to each other by perpendicular extraction openings.

Some of the disadvantages of horizontal wells are their inadequacy for the withdrawal of already stored fuel, and the financial and mechanical requirements of eventual extraction. Another disadvantage is that it is not appropriate to excavate these wells in masses of heterogeneous rock due to the stability of the well from the moment of construction to the end of the storage hole.

The disadvantages of both methods are the difficulties of handling in storage, complicated surface requirements and characteristics of the rock mass, and inadequate methods of extracting the stored fuel.

Description of the invention

One of the objects of this invention is the storage well system, in accordance with patent claim 1, for 3DD (three-dimensional dumping) of spent nuclear fuel storage), and another the storage method, according to the claim. of patent 7, of the nuclear fuel spent in storage wells, which eliminates the aforementioned disadvantage of current techniques.

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The storage well system for storing spent nuclear fuel consists of at least one horizontal corridor, in which at least one storage system is installed, a system consisting of a characterization well and an inclined storage well practiced on its line. central, where storage containers are located.

The gufa characterization well and the inclined storage well are wells with an identical inclination angle, between 20 and 30 degrees. The guide well of characterization exceeds the storage well in length. The diameter of the large well of characterization varies between 0.1 and 0.2 m (preferably 0.12 m), and that of the inclined storage well is between 0.5 and 2 m (preferably 1.3 m). The large characterization well can be filled with a marker material, such as a mixture of sand with a red or green pigment, to facilitate its location in case it is necessary to remove the spent spent nuclear fuel. The process of construction of the system foresees that the first guide well of characterization is first excavated, which will serve for a detailed verification of the quality of the rock. Next, the storage well will be drilled in the central line of the characterization well.

For the removal of storage containers, it is possible to build a working access, such as a handling galena that intersects with the other sections of the characterization wells, along which the well will be excavated for the removal of the spent nuclear fuel containers. Work access can also be built after a long time from the moment the spent nuclear fuel is stored in the storage wells. The guide well of characterization serves for the location of the storage well, and for the subsequent excavation of the well to remove the spent spent fuel containers. Preferably, the system will include more horizontal corridors, arranged in parallel, with a separation of 40 to 60 m (preferably, 55 m), in which storage systems will be constructed in regular systems of 20 to 40 m (preferably, 30 m ), which will consist of a gufa characterization well and an inclined storage well.

The spent nuclear fuel storage method consists of storing at least one container in the inclined storage pit (preferably several containers) by means of a handling mechanism. Said mechanism, by which

the individual components of the system are transported to the bottom of the well,

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it can be a material handling car that moves by gravity or by a rope.

The storage container can be placed inside a supercontainer, which will include an external envelope with engineering barriers, such as a barrier. The cohesion of the supercontainer is secured by an external basket with a lid, which is a cylindrical vessel of perforated sheet, whose perforation openings constitute 60% of the surface of the supercontainer shell. In the outer basket of the supercontainer, located vertically on the surface of the individual components of the barrier are blocks (molds) of bentonite, and the storage container is located in the center.

According to another variant, the storage container can be placed in a storage pit on a segment of the support barrier. In this case, the segment of the support barrier is first located by means of a hydraulic device at the bottom of the well, and then the container with the spent nuclear fuel is placed on it. The segment of the support barrier will preferably be formed by a block of bentonite. Its section will have the shape of an annular space limited by the section of a circle with an angle between 110 and 130 degrees (preferably 120 degrees). The process concludes by the displacement, and consequent installation, of the hydraulic storage of two filler barrier segments at the storage location, and / or by spraying the free space around the storage container with a projected barrier that will then gradually be compacted by a special compaction mechanism. The segments of the filling barrier will preferably be formed with bentonite blocks and will have the shape of a limited annular space with a circular section at an angle of 110 to 120 degrees. The sum of the angles of the sections of a circle of the barrier holder segment and the filling segments shall be <360 degrees. The barrier material will be compacted clay and bentonite, capable of absorbing heat from radioactive waste and transferring it to the surrounding rocks, inhibiting the attenuation of radionuclides and, at the same time, protecting the storage container from the influence of mechanical pressures The remaining free space between the segments, the storage container and the wall of the storage pit will be filled with a projected barrier of compacted clay and bentonite.

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Behind the storage container there will be a separator block, consisting of a barrier located behind another storage container stored in the same way. Preferably, the separator block will be a circular bentonite block.

For the removal of storage containers, it is possible to build a work access (handling galena), independently of the side corridors and storage systems. Work access can also be built after a long time from the moment the spent nuclear fuel is stored in the storage wells. Once the marking material of the characterization guide well is installed in the handling galena, an access well will be built therein for the extraction of the lowest storage container. The withdrawal will then consist of depressurization around the storage container; for example, by digging or extracting, and consequently collecting the storage container with a suitable device, and removing it to the handling galena to place it in a transport medium that removes it from the mine.

The advantages of this method are the minor difficulties in the underground area of the deep repository, the easiest handling taking advantage of the gravity forces in the well structure and the storage of spent nuclear fuel, but also the possibility of its withdrawal. The selected inclination will be sufficient for the movement of the storage mechanism by actuating the horizontal component of the gravity force. At the same time, it reduces the load on the handling rope by the transmission of the vertical component on the underlying rock.

The advantage of the storage well system according to the invention is that the inclination of the storage pit guarantees a stable position of the containers even if they have to be removed by depressurizing the barrier. Another advantage is the possibility of building a work access in the heterogeneous rock mass, and the possibility of withdrawing the fuel long after closing the deep repository.

Brief description of the diagrams

The preferred versions of the invention are described below, taking as reference the attached diagrams, in which:

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Fig. 1 shows the cross section of a horizontal corridor with a manipulation mechanism, and a longitudinal section of the characterization well and the inclined storage well, in which the storage containers are placed and the separation block is located , including work access.

Fig. 2 shows the cross-section of the inclined storage pit, in which the storage container is placed on the support barrier segment, and the space between the storage container and the pit wall is filled with two segments. of filling.

Fig. 3 shows the cross-section of an inclined storage pit, in which the storage container is placed on the support barrier segment, and the space between the storage container and the pit wall is filled with barrier. projected.

Fig. 4 shows the plane of the spatial arrangement of the system, with parallel horizontal corridors and storage systems.

Examples

Example 1

The storage well system for the storage of spent nuclear fuel of Fig. 1 consists of a horizontal corridor 3, from which a storage system consisting of a guide pit of inclined characterization 1, and an inclined storage pit 2 begins. , with an identical inclination angle of 30 degrees. The large well of characterization 1 has a diameter of 0.12 m, its length exceeds storage well 2, and is filled with a marking material, in this case a mixture of sand with red pigment.

The storage pit 2 has a diameter of 1.3 m, and inside it are placed the storage containers 6. Between them a separation block 7 is placed. The storage system includes a working access, which is the galena of handling 10. In this version, the storage container 6 is located inside a supercontainer.

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Example 2

The storage well system for the storage of spent nuclear fuel is like that of Example 1, with the difference that the storage container 6 is located on the support barrier segment 5. The space between the storage container 6 and the wall of the storage pit 2 is filled with two filler barrier segments 8a and 8b, as can be seen in Fig. 2

Example 3

In this variant, the storage container is located on the segment of the support barrier 5, and the space between the storage container 6 and the wall of the storage well is filled with projected barrier 9, as can be seen in Fig. 3. The projected barrier (9) will be gradually compacted by a special compaction mechanism.

Example 4

In the spatial scheme of the system, according to the invention, as can be seen in Fig. 4, the horizontal corridors 3 are arranged in parallel, with a separation of 55 m from each other, in regular sections every 30 m. In this case, the storage systems consist of a guiding well of characterization 1 and an inclined storage well 2, built on its central line.

Industrial utility

The method of storage of spent nuclear fuel in the storage well system of the invention allows long-term storage of this material or highly radioactive waste. It allows easy handling, does not require a complex structure of underlying rock, and allows easy removal of fuel.

Claims (12)

5 10 2. fifteen 3. twenty Four. 25 5. 30 A storage well system for the storage of spent nuclear fuel, consisting of at least one horizontal corridor (3) from which at least one storage system characterized by consisting of a guide pit of inclined characterization (1) and a well of inclined storage of greater diameter (2), excavated in the central line of the aforementioned guide well of characterization (1), with an identical inclination angle below the horizontal level, in which the length of the guide well of characterization (1) exceeds that of the storage well (2), and in which said well is placed at least one storage tank (6) to receive spent nuclear fuel. The system of Claim 1 characterized by angles of inclination between 20 and 30 degrees. The system of Claims 1 to 2, characterized in that the guide well of characterization (1) has a diameter between 0.1 and 0.2 m (preferably 0.12 m), and that the storage well (2) has a diameter between 0.5 and 2 m (preferably 1.3 m). The system of Claims 1 to 3 characterized in that the guide well of characterization (1) is filled with marking material, preferably a mixture of sand with a red or green pigment. The system of Claim 1 characterized in that the storage systems, from the horizontal corridor (3) are separated from each other at regular distances of 20 to 40 m (preferably, 30 m), and that the horizontal corridors are arranged in parallel with separations of 40 to 60 m (preferably 55 m). The system of Claims 1 to 5 characterized in that it includes a working access that intersects with the other sections of the characterization wells (1), which is the handling galena (10). 5 10 fifteen twenty 25 30 7. The method of storage of spent nuclear fuel in the storage wells of Claim 1 characterized in that, within the inclined storage pit (2) at least one storage container (6) will be located by a handling mechanism. 8. The method of claim 7 characterized in that the manipulation mechanism (4) is a material handling car that moves by gravity on a rope. 9. The method of Claim 7 characterized in that at least one separation block (7) is placed between each adjacent storage container. 10. The method of claims 7 to 9 characterized in that the storage container (6) goes inside a supercontainer. 11. The method of Claim 7 characterized in that the storage container (6) is located on a segment of the support barrier (5), previously placed at the bottom of the storage pit (2), while the space between the storage container (6) and the wall of the storage pit (2) will be subsequently filled with two filler barrier segments (8a, 8b) and / or with a projected barrier (9). 12. The method of Claim 11 characterized in that the support barrier segment (5), the filler barrier segments (8a, 8b) and the projected barrier (9) are made of compacted clay and bentonite. 13. The method of Claim 11 characterized in that the segment of the support barrier (5) has in its cross section the shape of part of an annular space, limited by the section of a circle with an angle of 110 to 130 degrees ( preferably 120 degrees). 14. The method of claims 11 and 12 characterized in that the segments of the filling barrier (8a, 8b) have in the section a form of part of an annular space, 9 limited by the section of a circle with an angle of 110 to 120 degrees, in which the sum of the angles of the circle sections of the filler barrier segment (5) and the filler barrier segments (8a, 8b) is <Sprava_