RU2132096C1 - Method for burying radioactive compartments of recovered submarines and nuclear-powered vessels - Google Patents

Abstract

FIELD: disposal of radioactive wastes. SUBSTANCE: method for burying radioactive compartments in water area includes the following procedures. Reinforced-concrete cylindrical semi- containers with sealed end wall are made on separate floating platforms and then conveyed over water surface and coaxially installed with their open sides facing each other and reactor compartment placed in-between; then they are joined together. Reinforcement is then passed to through channels in semi-container end walls and tensioned by means of hydraulic jacks until both semi- containers are tightly joined together and reactor compartment is fully arranged within container with reinforcement pre-stressed to rated value, this procedure being followed by injection of grout into channels. Container holding the reactor compartment is conveyed over water surface to burial point. EFFECT: facilitated procedure. 6 cl

Description

 The invention relates to the problem of environmental protection, namely, to clean the area of radioactive waste, reactor compartments formed during the disposal of nuclear craft, submarines, ships, etc.

 A known method for the disposal of radioactive waste by placing them in metal sealed containers, for example, cylindrical, transporting them with a forklift in a vertical position, subsequent tipping in a horizontal position and stacking them in a box’s nests, several pieces, installing boxes on a ship, transporting to the place of disposal immersion of containers at the bottom of the water area [1].

 A known method for the disposal of radioactive and toxic waste in containers at the bottom of the sea, including the manufacture of a container with protective coatings, the placement of waste in it, sealing the container and its subsequent self-immersion at the bottom of the water [2].

 A known method for the disposal of radioactive and toxic waste in the area of the water area, including the manufacture of a container on a floating platform (ice cover of the water area) by enlarging the assembly of individual prestressed annular reinforced concrete elements in a volumetric prestressed tor container with filling the joints between the elements with a solution of cement on tension. A tor container with a temporarily open castle part is transported by swimming to the location of the waste, fix it. Waste is loaded into the cavity of the torus container through its castle part with the repetition of similar operations until the container is fully loaded and the castle part of the torus is monolithic. Then the torus tank laden with waste is sent to the burial place and immersed in a predetermined place at the bottom of the water area, sequentially forming an underwater, continuous torus storage [3].

 The disadvantages of the known methods are the lack of an initial domestic technical base, the complexity and length of the technological cycle, the need to transport containers using special vehicles to the disposal site and their chaotic spontaneous immersion at the bottom of the water area, which does not provide sufficient environmental safety and the ability to control the ecological situation in the region landfill. In addition, the known methods do not solve the problem of the burial of bulky radioactive waste, for example, the reactor compartments of utilized craft with nuclear power plants.

 The technical task is to simplify the method of disposal due to the possibility of loading the reactor compartment into the container at its location on the surface of the water area or at the bottom, sealing it and subsequent transportation to the place of disposal on the surface of the water area.

 The problem is solved in such a way that in the method of burial of the reactor compartments of utilized submarines and nuclear-powered ships in the water area, including the manufacture of a volumetric prestressed pipe-shaped reinforced concrete container, loading it with recyclable waste, sealing the container, transporting it over the surface of the water area and burial, according to the invention, first to separate floating platforms make cylindrical half-containers with end-face sealed on one side with a tenka, after which the semi-containers are moved along the surface of the water area, they are installed coaxially with open sides to each other, and the reactor compartment is coaxially placed between them and interlocked between them, then reinforcement is passed through the end channels in the cylinder walls through the end walls of the semi-containers, and it is pulled until it joins half-containers and placing the reactor compartment in the container cavity, and prestressing the valves to the calculated value, followed by injection of the solution into the channels. In addition, a roller conveyor track is mounted in the semi-container for loading the reactor compartment, and the container is loaded on the surface of the water area or at the bottom of the water area. Semicontainers are made by molding in a fixed metal formwork, or prestressed reinforced concrete rings.

 The proposed method differs from the known one in that first, on separate floating platforms, semi-containers of cylindrical shape with an end wall sealed on one side are made, which makes it possible to reduce the dimensions of the reinforced concrete structure of a cylindrical shape, which is determined by the format of the reactor compartment, in addition, their manufacture on floating platforms allows transport them to the location of the reactor compartment in the water area and the ability to balance their position when loading. Further, the proposed method is characterized in that the semi-containers on the floating platforms and the reactor compartment are installed coaxially and are loaded by docking them and placing the reactor compartment in the container cavity. Docking is carried out by tensioning the reinforcement, which is passed through the end walls of the semi-containers into the through channels made in the cylinder wall. At the same time, in a single cycle, the reinforcement is pulled up to the prestressing of the reinforcement to the calculated value, fixed by injecting the solution into the channels. This allows you to get a volumetric prestressed design of the packaging of the radioactive reactor compartment of increased tightness without additional costs.

 For convenience of loading, a roller conveyor track is mounted in the semi-containers. Moreover, taking into account the flooding of the platforms, loading is possible both on the surface of the water area and on the bottom. Further, the manufacture of semi-containers can be carried out by molding in a metal fixed formwork. Or semi-containers can be made from pre-loaded reinforced concrete rings, which simplifies the manufacturing process of semi-containers, especially in winter.

 The method is as follows.

 First, on separate floating platforms located on the surface of the water area (in its coastal zone), semi-containers of cylindrical shape are made.

 It is advisable to form prestressed reinforced concrete individual elements near a floating platform located on the surface of the water, i.e. on the coast of the water.

 The loading capacity of the platform is determined from the calculation of its general buoyancy and stability, as well as non-loadability on the coastal bottom with all combinations of possible loads, including storm loads. The manufacture of a semi-container is carried out by the layout and mutual docking of individual precast concrete rings, according to the cross section corresponding to the format of the packed cargo. In this case, a part of the container is formed in the form of a cylinder of the required length and cross-sectional shape, with an end wall sealed on one side, where a technological hatch with a sealed lid is integrated; the end wall is also made on the molding unit.

 Then, for the purpose of additional insulation, the inner cavity of each part of the container is lined closely or with a gap from it with a thin-sheet welded stainless steel jacket, with subsequent injection of the existing gap with a solution, for example, on tensile cement. A roller conveyor track is mounted on the lower inner part of the container, the design of which is designed for the least resistance when the reactor compartment is self-rolling.

 Or the manufacture of a semi-container is carried out by forming a prestressed reinforced concrete cylindrical element with an end wall in a metal fixed formwork, the inside of which serves as an anti-radiation insulating jacket during operation (storage of reactor compartments).

 In the manufacture of a semi-container in the cylinder wall, through channels are formed uniformly around the circumference to accommodate prestressed reinforcement.

 Manufactured semi-containers on floating platforms are transported along the surface of the water area to the location of the reactor compartment. Then they are centered, installed coaxially open sides to each other, and between them place the reactor compartment. After which their position is fixed. Then, reinforcement is passed through the end walls through all end channels of the half-containers and, using hydraulic jacks, the reinforcement is tensioned simultaneously: first, before joining the half-containers with simultaneous loading of the reactor compartment into the container cavity, and then to the calculated value of the prestressing reinforcement with subsequent injection of the solution into the channels.

 Equipping the semi-containers with a roll track ensures self-winding of the reactor compartments into the container cavity. The loading of the container can be performed both on the surface of the water area and at the bottom. For this platform equipped with ballast tanks for flooding. The loaded container on the platform is transported to the burial place. If necessary, for additional insulation, the space between the reactor compartment and the container is poured with concrete mixture through hatches located in the end walls of the container.

 As a result, the reactor compartment, reliably packed in a high-strength volumetric prestressed concrete container, is transported across the surface of the water area to the disposal site without additional overload costs, ensuring the environmental safety of the region.

Sources of information
1. Japanese application N 61-38439 B, publ. 8608.29 N 6-961, cl. G 21 F 9/34.

 2. SU, Copyright Certificate of the USSR N 1800483, Cl. G 21 F 9/24, publ. 03/07/93, bull. N 9.

 3. RF patent N 2077747, cl. G 21 F 9/24, BI N 11, 1997 - (prototype).

Claims (6)

 1. The method of burial of the reactor compartments of utilized submarines and nuclear-powered ships in the water area, including the manufacture of a volumetric prestressed tube-shaped reinforced concrete container, loading it with utilized compartments, sealing the container, transporting it over the surface of the water area and burial, characterized in that it is first produced on separate floating platforms half-containers of cylindrical shape with an end wall sealed on one side, after which half-containers are moved along the surface of the water area is installed coaxially open sides to each other, and between them the reactor compartment is located and coupled to each other, then reinforcement is passed through the end channels made in the cylinder walls through the end walls of the semi-containers and pulled until the semi-containers are joined, the reactor compartment is placed in the container cavity and prestressing the reinforcement to the calculated value, followed by injection into the channels of the solution fixing the reinforcement.  2. The method according to p. 1, characterized in that a roller conveyor is mounted in the semi-container for loading the reactor compartment.  3. The method according to claim 1, characterized in that the container is loaded on the surface of the water area.  4. The method according to claim 1, characterized in that the container is loaded at the bottom of the water area.  5. The method according to p. 1, characterized in that the semi-containers are made by molding in a fixed metal formwork.  6. The method according to claim 1, characterized in that the semi-containers are made of prestressed reinforced concrete rings.