SU1163808A3 - Underground storehouse for radioactive and other material - Google Patents

Description

The invention relates to systems for storing radioactive material in underground storage facilities, namely, storage facilities for the long-term storage of spent fuel from nuclear reactors and radioactive waste, which are obtained from the processing of said nuclear fuel. The purpose of the invention is to ensure reliable storage. FIG. 1 shows the first storage variant, vertical section; Fig. 2 shows a second storage variant in which the internal cavity of the body of bedrock extends to the level of the surface of the bedrock, is a vertical section; on fig.Z - the third option with more efficient heat removal, vertical section; and FIG. 4 shows one of the spherical bodies made of concrete and filling the inside of the hollow body. In the rock monolith 1 there is a vault located at a certain depth from the surface 2 of the earth. Half a mouth and a half 3 are pulled out of the rock, inside which is placed a hollow body 4 made of concrete, the internal cavity of which contains sufficient space for the placement of radioactive material, at. at any point, the outer surface of the hollow body 4 is spatially removed from the walls of cavity 3, the space between the wall of cavity 3 and the hollow body 4 is filled with clay 5. The cavity 3 is completely surrounded by the shell 6 of the bedrock, which in turn is separated from all sides a gap of 7 from the monolith of a bedrock 1. The gap 7 is also filled with clay 8. The cavity 3 and the shell 6 are preferably round. A hollow body made of concrete 4, which has an ellipsoidal shape, is provided with a hole located in its upper part, which communicates via trunk 9 with a horizontal tunnel 10. Through tunnel 10 and trunk 9 radioactive material can be transferred into the hollow body 4. Barrel 1I is directed upwards to the horizontal line 10 and is intended for inspection of the storage. Personnel exercising control over the storage can be lowered down through the barrel 11 for visual inspection of the internal cavity of the hollow body 4. The observation can also be carried out using the Television system. The vertical shaft 12 passes through the bedrock 6 up to the horizontal tunnel 10. In the shaft 12, measuring instruments (not shown) are installed to determine temperature, humidity and radioactive radiation. These gauges can be connected with wires running along the trunk 9 and tunnel 10, showing them with devices located at the observation and monitoring point. Drainage tunnels 13 can be provided in the bedrock monolith -1, located around the circumference of the repository. The purpose of these drainage tunnels 13 is to divert groundwater, which may be located in the bedrock outside the HtmHuia temple. A well 14 runs from drainage tunnels 13 to surface 2 of the earth. . . The horizontal tunnel 10 can communicate directly with the plant, which impacted the regeneration of spent nuclear fuel, therefore, the risk of radioactive contamination that occurs during transportation of radioactive waste is reduced in this case. The system is equipped with appropriate lifting and transport means for transporting radioactive waste through the trunk 9 and distributing the waste in the space inside the hollow body 4 made of concrete. The creation of the system can be accomplished by using known methods of excavating the earth. First of all, the workers and transport tunnels are drilled in the rock to the place where cavity 3 and sheath 6 are to be placed. The cavities are excavated from bottom to top. Gap 7 is filled with clay immediately after the rock has been removed from it. Clay is supplied under pressure, so that no voids remain in it. In the region (Fig. 1, dashed lines 15), which approaches the bottom of the gap 7, it is necessary to stabilize the head by adding

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in her suitable stabilizing. reagent, it is necessary so that it can withstand more firmly. pressure shell 6 of bedrock. When cavity 3 is dug, its bottom is filled with clay to a certain height. The hollow body 4 is then made of concrete and connecting trunks 9 and 11. After the concrete has hardened and an insulating plastic layer is placed on the outer surface of the hollow body 4 of concrete, the space between the hollow body 4 of concrete and the walls of cavity 3 is filled with clay. When the storage structure is complete, the aforementioned work and transport tunnels can be filled with concrete.

Cracks and cracks that may occur in the bedrock near the location of the two cavities are closed by feeding concrete into them.

If there are places of displacement or lowering of the rock outside the storage, then ... these movements previously cause deformation of the clay 8 in the gap 7. If the thickness of this clay shell is sufficient, then the deformation is not transmitted to the following shells. If the deformation is of such a force that it captures even the shell 6 of bedrock, then the forces causing the deformation are absorbed by a layer of clay 5 into the spaces between the wall of the cavity 3 and the hollow body 4. The hollow concrete body 4 located inside the entire system preferably has an ellipsoid or spherical shape that provides a very high resistance to stresses acting on it from the outside; therefore, even deformations of very strong amplitude, for example, deformations caused by earthquake, cannot affect the bnau system in such a way as to destroy the hollow body 4 of concrete.

In the second version of the repository. (FIG. 2) the gap 7 reaches the surface of the earth 2. The horizontal cross section of the gap 7 preferably has the shape of a tube.

On the surface of the earth, a gap of 7 zy.- dug. a layer of concrete 16 that prevents

squeezing onto the surface of clay 8 ,.

A layer of concrete 16 is made quite thick in order to prevent also

chance of intentional damage

system.

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The second option (figure 2) is especially preferable for those cases when the groundwater level in the rock surrounding the reservoir is very high, - Shell 6, consisting of bedrock, located inside the gap 7, filled with clay 8, can have a system there is no drainage of water from the groundwater, and the clay of the fender 8 made of clay 8 effectively prevents the penetration of groundwater from the bedrock monogram 1 outside of it into the system.

In the third storage variant (Figs. 3 and 4tesh1O, which is formed under the influence of the stored radioactive material, it is distributed and dispersed in a simple and effective way.

The storage (Figures 3–4) may be located in the monolith of the core port 1 at a certain depth below the level of the earth's surface 2. This depth

can match. eg. 300-600 m. A cavity is selected in the bedrock monolith 1, and the shell 6 of the bedrock remains in this cavity g. The gap 7 between the shell 6 and the monolith of the bedrock 1 is filled with clay B, which forms the shell covering the bed 6 of the bedrock. The casing 6 of a bedrock is placed in a certain position with respect to. to the bedrock monolith 1 outside by means of support members 17, which may consist of either augmented concrete or the remaining rock.

The bedrock casing 6 comprises a cavity 3 having a spherical shape and communicating via a vertical shaft 9 with a horizontal tunnel 10, which is located. near ground level 2. Cavity 3 and barrel 9 are bordered with reinforced concrete 18.

Cavity 3 contains the space in which the radioactive material is located. Inside the cavity 3, a vertically cylindrical element 19 is installed, made of reinforced concrete. At the lower end of the shchindric element 19 there are two rows of air vents 20. made around the periphery. Near the top of the cylindrical element 19, a number of holes 21 are provided,

also applied along the periphery of the wall. The cylindrical element 19 is supported at its bottom end to the bottom of cavity 3, while its upper end is set at a distance from its upper part. Thus, the cylindrical element 19 divides the cavity 3 into the outer space between the outer surface of the cylindrical element 19 and the wall of the cavity Z. and into the inner space formed by the inner cavity of the cylindrical element 19. These spaces communicate with each other through ventilation holes 20 at the lower end and through the open upper end of the cylindrical element 19 and the return 21.

The space in the cavity 3, which is occupied by the cylindrical element 19, is filled with spherical bodies 22. (FIG. 4) made in the form of balls and made of concrete, all of which have the same diameters. The spherical body is provided with a number of through holes 23 (in this case, three). The through holes 23 are in the form of straight cylinders, and they are positioned in such a way that the lines passing through their centers are at the vertices of an equilateral triangle. Each spherical body 22 is provided with a hook or protrusion 24 that is attached to the ball.

and with which the ball can be raised or lowered. The spherical bodies 22 are placed in the cavities 3 in such a way that the through holes 23 made in them are located at a certain angle to the horizontal plane. This angle is chosen in such a way that the through holes 23 end in the spaces between the spherical bodies 22, the hook or the protrusion 24 is set relative to the through holes 23 so that when the spherical body 22 is lowered into the cavity 3, hook it to the hook or protrusion 24 The through holes 23 are automatically set in the desired direction.

Radioactive material intended for storage is solid and in the form of rods. Thus, spent cells and fuel cell cartridges removed from a nuclear reactor can be stored without

subsequent processing in the proposed woundship.

The rods of radioactive material are supplied to the through holes 23 for placement in some Spherical bodies 22, namely, those that are located inside the cylindrical element 19, and preferably only those that are located in the lower part of the internal space of the cylindrical element 19. It is advisable a cylindrical element 19 is filled with spherical bodies 22 containing radioactive material, only one third of its height. The rods of radioactive material are placed in the through holes 23 in the spherical bodies 22 in such a way that the rods are spatially separated from the inner surface of the through holes 23, which allows free air circulation through the through holes 23 along the rods of the radioactive material. In Fig. 4, some rods of the fuel cells 25 are placed into the through holes 23 of the spherical bodies 22. The rods of the fuel cells 25 are laid inside the holes 23 with the help of suitable supporting devices (not shown).

The construction of the repository can be carried out by blasting Hbix works according to a known method. The internal cavity 3 must be faced inside with significantly reinforced concrete. Concrete cylindrical element 19 is made by pouring concrete into the place where it should be located inside cavity 3. The space outside the cylindrical element 19 is filled with concrete spherical bodies 22, which descend through barrel 9. Concrete spherical bodies 22 containing radioactive material are placed at the bottom of the cylindrical element 19, and above them are spherical bodies 22 that do not contain radioactive material.

The barrel 9 emerges with its lower end directly above the upper opening of the cylindrical element 19. If necessary, the spherical bodies 22 can be easily removed from the internal space of the cylindrical element 19, which may be desirable, for example, in the case when radioactive material is stored in them. remove for regeneration l. In the storage (FIGS. 3 and 4), the air in the lower part of the cylindrical element 19 is heated by the heat emitted by the radioactive material, and rises inside this element to the very top, and there it is directed through the holes 21 in the upper part side of the wall of cavity 3, where it cools and flows down into the space located between the cylindrical element 19 and the wall of cavity 3. After that, the air re-enters the cylinder element 19 through the vent holes 20 in its lower part, in contact It eats with radioactive material, is reheated, and then the cycle is repeated. Air flows through the space between the spherical 808, 8 bodies 22 and through the through holes 23 in these bodies. Thus, the spherical bodies 22 act as a porous mass, which provides relatively free and rapid movement of air and at the same time prevents the possibility of compression and collapse of the cavity under the influence of significant external forces. Thus, the proposed repository can ensure the safe distribution of radioactive waste over a period of time long enough for the level of these materials to be reduced to a safe level. In addition, the repository can also be used to house it .. and other materials He didn’t have any radioactive waste.

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Claims (5)

1. UNDERGROUND STORAGE FOR PLACING A RADIOACTIVE AND OTHER MATERIAL A cavity containing a hollow body of concrete, separated from all sides by a gap from the cavity wall and connected to a vertical trunk passing through the bedrock, characterized in that, for the purpose of to ensure storage reliability, the cavity in the bedrock is limited by a shell of the same bedrock, which in turn is separated from all sides by a gap from the bedrock monolith, while the bedrock shell is made with spherical or ellipsoidal, and the gap between the hollow body of concrete and the wall of the cavity and the gap between the wall of the shell of bedrock and the bedrock are filled with clay. 2. Storage according to claim 1 of m and n sistent in that the sheath extends up to the bedrock levels nya ^g bedrock surface. 3. Storage according to paragraphs. 1 and 2, which is characterized in that a cylindrical element with open ends is placed inside the hollow body, containing spherical bodies and made of reinforced concrete, the axis of which mainly extends vertically, so that it divides the internal space of the hollow body into the internal compartment, covered by a cylindrical element, and the outer compartment between the outer side of the cylindrical element and the wall of the inner cavity, while the inner and outer compartments communicate with each other from both ends, with spherical bodies, made of concrete, made to fill both the internal and external compartments, have through holes for receiving radioactive material and are located only in the lower part of the cylindrical element. 4. Storage facility I and 3, about t ~. which means that the cylindrical element is divided. · On the periphery of the gap between the holes made adjacent to both of its ends. 5. Storage facility 1, 3 and 4, characterized in that the spherical bodies made of concrete are made with connecting means for connecting them to the device for lifting and processing. Priority on points: ¹ 13.12.76 according to claim 1; . 01/19/77 according to claim 2; 06/30/77 in claims 3-5. SU .... 1163808 1163808 2