RU30210U1 - Reinforced concrete container for transportation and / or long-term storage of radioactive and toxic waste from various industries - Google Patents

Abstract

1. A reinforced concrete container for transporting and / or long-term storage of radioactive and toxic waste of various industries, comprising a housing with a hermetically sealed lid, a container with a lid for packaging waste located inside the housing with the formation of a spacing cavity between them, in which the lower container holding elements are placed, characterized in that heat-insulating material is introduced into the spacing cavity filling it, as well as lateral capacity-fixing elements, the lower ones being fixed s capacity elements are arranged at its bottom and formed as damper and the housing bottom adapted to support dempferami.2. Reinforced concrete container according to claim 1, characterized in that the side container-fixing elements are mounted on the side walls of the container. Reinforced concrete container according to claim 1 or 2, characterized in that perlite sand with a filling width of the spacing cavity from 25 to 35 mm is used as the heat-insulating material. Reinforced concrete container according to claim 1, or 2, or 3, characterized in that the supporting dampers are located along the forming contour of the bottom and are made in the form of alternating protrusions and grooves with a width equal to the thickness of the corresponding wall of the housing. Reinforced concrete container according to claim 1, or 2, or 3, or 4, characterized in that the lower capacity-fixing elements are made of corners radiating from the center of the bottom of the container.

Description

The utility model relates to the field of radioactive and other toxic waste management, namely to reinforced concrete containers intended for transporting and / or long-term storage of solid, liquid, solidified radioactive waste from nuclear power plants, civil and military vessels with nuclear reactors, and may used for transportation and disposal of toxic waste from chemical and other industries in liquid and hot conditions.

An analysis of the state of the art in this field showed that a container for transporting radioactive materials is known, containing a concrete case with a lid, a sealed container for packing materials, located inside the case with the formation of a lateral spacing cavity with fixing the bottom of the tank and the cover of the case (Japanese Patent No. 2907690 B2 7027897 A, MKI: G 21 F 5/10, publ. 06/21/99).

To prevent cracking of the walls of the case from the influence of a significant temperature gradient arising from the radioactive decay of waste in the tank, shielding partitions are additionally placed in the spanning cavity and a natural convention is implemented, which entails the presence of additional structural elements, which complicates and increases the cost of the analog design.

heat sink due to the fact that the bottom of the tank is installed without any clearance directly on the bottom of the case, and above it is close to the cover of the case, which will lead to their cracking and, as a result, reduce radiation safety.

And finally, the design does not provide for dampers, which, if a container falls during transportation, reduces the reliability of the structure and, therefore, radiation safety.

Of the known devices, the closest to the claimed one is a reinforced concrete container for storing heat-generating materials, comprising a housing with a hermetically sealed lid, a container with a screwdriver for packaging waste located inside the housing with the formation of a spacing cavity between them, in which the lower locking elements are placed (UK Patent No. 2337722A1 , MKH: G 21F5 / 10 publ. 12/11/99).

The impossibility of achieving the result by the said device, provided by the claimed design of the container, is due to the fact that, firstly, the container is placed in an additional steel chamber, which fulfills the shielding function and divides the spacing cavity into two cavities through which cooling air is passed that enters them from the atmosphere through the lower channels in the housing and the chamber with the air exhaust system in the upper part.

Such a constructive study of the container complicates the product, which leads to its significant cost, and in addition, the presence of channels reduces reliability due to the lack of tightness of the housing.

Secondly, due to the installation of a container in a metal chamber with side gaps, conditions are created within the gap, its roll with a possible tilt of the case during transportation of the container, and the higher the gap, the less stable the capacitance, which will lead to areas with significant heat transfer to concrete and, consequently, to the possible appearance of cracks in it.

product and fall protection measures.

In developing the claimed design, the task was to increase radiation safety by reducing heat transfer from heat-generating materials poured into a reinforced concrete casing, while reducing the cost of the product. In addition, it was necessary to protect the product in case of its fall.

In solving the aforementioned problem, a technical result was achieved, consisting in increasing the reliability of the device by reducing the thermal conductivity by significantly reducing the local heat transfer from the tank to the housing, without the use of an expensive structural cooling and heat removal system to the outside, which allowed to maintain tightness container, simplify the design and increase its radiation characteristics.

In addition, to protect the container from cracks when the product falls, damping elements were introduced into its design, and the introduction of lateral fixing elements made it possible to maintain a stable position of the tank and ensure uniform heat transfer to the reinforced concrete wall.

The technical result is achieved in that the reinforced concrete container comprises a housing with a hermetically stocked lid, a container with a lid for packaging waste located inside the housing with the formation of a spacing cavity between them in which the lower container-fixing elements are placed.

New in the device is that heat-insulating material is introduced into the spacing cavity, which contains it, as well as lateral capacity-fixing elements, the lower capacity-fixing elements are located on its bottom and are made in the form of dampers, and the bottom of the body is made with supporting dampers.

In addition, the side container-fixing elements can be mounted on the side walls of the container, and perlite sand with a filling distance of the spacing cavity of 25 to 35 mm can be used as heat-insulating material.

In addition, onoric dampers can be located but forming the contour of the bottom of the container and made in the form of alternating protrusions and grooves with a width equal to the thickness of the corresponding wall of the housing.

In addition, the elements that fix the capacity of the vessel can be filled from the corners radially emanating from the center of the bottom of the container.

The container is presented in the drawings, which depict in figure 1 - a nodal section of the device; Figure 2 is a top view; Fig.Z is a bottom view; Figure 4 - section aa in figure 1; 5 is a bottom view of the container.

The container contains a reinforced concrete casing 1, made in the form, for example. polygonal parallelepiped with side walls 2, bottom 3 and screw 4 mounted on recesses 5. A through hole is made in the central part of the cover b. Inside the casing is a container 7 made of sheet metal. The bottom 8 of the tank 7 is made with the lower capacity-fixing elements 9 fixed to them and made from angles arranged in the form of beams emanating from the point O of the center of the bottom of the tank. At the same time, the elements 9 fulfill the function of dampers.

The side walls 10 of the container 7 are made with lateral container-fixing elements 11. Both the side 11 and lower 9 locking elements are rigidly fixed to the container. A fastener 12 with a mounting hole 13 is mounted in the upper part of the tank. The tank 7 is located in the housing 1 so that a distance cavity 14 is formed between them, which is filled with heat-insulating material - a layer 15, for example, of perlite sand. The dimensions of the container and the housing are designed so that the width of the stripes. / ,.

TI, filled with non-Nert sand, between them was from 25 to 35 mm. which is associated with optimal absorption of heat, causing a limitation of the limiting temperature on the heating of the casing wall, and thereby preventing the occurrence of cracks in reinforced concrete.

In the case of the use of other heat-insulating materials, for example, polymers, the dimensions of the cindery of the cavity 14c with the filling layer may be different, which will entail a change in the overall dimensions of the container.

The value of the lateral locking elements 11 corresponds to the width of the cavity 14 with a small gap, which is incommensurably smaller than the distance between the container and the camera in the prototype device, which eliminates the roll of the container.

Along the generatrix of the contour of the bottom of the casing 3, there are supporting dampers made in the form of alternating protrusions 16 and grooves 17 of the width ni of which corresponds to the thickness H ;, side walls 2 of the casing located above the corresponding protrusions, to prevent cracks in the weakest point of the structure - in the interface between the bottom and the corresponding inner side wall of the housing. The protrusions of the damper are made of, for example, concrete or other energy-intensive material.

It is also possible to perform other supporting dampers.

Installation of the device is as follows.

In the factory or, if necessary, in the territory of the NPP, a container body brought from the manufacturer is installed, on the bottom of which the required amount of pearlite sand is poured, and then a container 7 is placed inside it on the lower and side fixing elements 9 and 11.

If necessary, packaging of solid radioactive waste Krippsi 4 and 12 previously removed for mounting holes 6 and 13 are removed. In the case of packing liquid salt melts, the frappings are left in place, and the melts are poured through a pshang sleeve located in the holes of both covers.

-S,

Then perlite sand is poured into the spacer cavity 14 in a number of steps.

Upon the completion of filling the cavity with sand, the opening 6 of the housing 4 of the housing is sealed with a stopper and, in addition, the opening and the edges of the cover are filled with a sealant mixture.

After the operations performed, the container is ready for transportation to the place of its storage or burial. In the event of an emergency - container falling, the latter falls on the supporting damper protrusions 16, which are destroyed, perceiving the shock load on themselves and thereby protecting the walls and bottom of the body from destruction, especially the interface between the bottom and the steaks. Similarly, the lower damper elements 9 are destroyed, protecting the thin metal sheets of the tank from cracks.

The device operates as follows.

The heat emitted, for example, when pouring hot liquid waste, is transferred from the tank 7 through its metal walls to the space of the spacer cavity 14. If it were empty, then under the influence of a significant temperature, stresses would appear in the walls, bottom and hull of the housing , exceeding the tensile strength of concrete, which could lead to the formation of trembling and a violation of the sealing of the container and, consequently, to environmental contamination.

In the case of dense filling of the cavity with pearlite sand, its layer dampens the temperature effect as heat passes to the walls of the casing and, passing the layer, for example (depending on the overall dimensions of the container and its wall thickness), from 25 to 35 mm, the heat decreases and the temperature reaches an acceptable value at which cracking of reinforced concrete does not occur. When the cavity 14 is filled with other heat-insulating material, for example, polymer (plastic) and with other overall dimensions of the container, the engineering calculation of the required optimal thicknesses of the heat-insulating material and the overall dimensions of the container is performed.

The ability to implement the inventive device of the container is confirmed by using known means and non-deficient materials, including signs presented at the level of functional generalization, with the achievement of technical results consisting in increasing the radiation safety of the product by eliminating the appearance of cracks in the reinforced concrete of the case due to the damping of the effects of high heat temperatures through the use of heat-insulating material, as well as due to the presence of a precaution itelnyh measures providing for introduction into the structure of the damper elements, and finally by eliminating the banks that have occurred in the prior art, by introducing the lower side together with the fixing elements. In addition, the cost of the claimed product is significantly lower than the cost of the prototype, due to the lack of an expensive cooling system in the claimed container.

Claims (5)

1. Reinforced concrete container for transporting and / or long-term storage of radioactive and toxic waste of various industries, comprising a housing with a hermetically sealed lid, a container with a lid for packaging waste located inside the housing with the formation of a spacing cavity between them, in which the lower container-fixing elements are placed, characterized in that heat-insulating material is introduced into the spacing cavity filling it, as well as lateral capacity-fixing elements, the lower ones being fixed s capacity elements are arranged at its bottom and formed as damper and the housing bottom adapted to support the damper. 2. The reinforced concrete container according to claim 1, characterized in that the side container-fixing elements are mounted on the side walls of the container. 3. The reinforced concrete container according to claim 1 or 2, characterized in that perlite sand with a filling width of the spacing cavity of 25 to 35 mm is used as the heat-insulating material. 4. The reinforced concrete container according to claim 1, or 2, or 3, characterized in that the supporting dampers are located along the forming contour of the bottom and are made in the form of alternating protrusions and grooves with a width equal to the thickness of the corresponding wall of the housing. 5. The reinforced concrete container according to claim 1, or 2, or 3, or 4, characterized in that the lower container-fixing elements are made of corners radiating from the center of the tank bottom.