RU2090943C1 - Method for decontaminating hydrogeological structures - Google Patents

Abstract

FIELD: physical and engineering decontamination and recovery processes for hydrogeological structures contaminated with radioactive wastes. SUBSTANCE: method involves building of shield made of hydroradionuclide insulating material under contaminated structure, its surface being inclined to center of working area. Boundaries of working area are insulated by vertical hydroradionuclide walls and joined with shield. Tank is made in center of shield below its surface. Workings from soil surface are brought to tank, their walls are reinforced and covered with electricity conducting net and draining material. Holes intended to pass leaching agents to structure are cased by electricity conducting pipes; positive potential is applied to walls of these pipes and negative potential, to walls of workings. Sealing dome is mounted above working area. EFFECT: facilitated procedure. 3 cl, 1 dwg

Description

 The invention relates to physicotechnological processes for the decontamination and reclamation of hydrogeological structures and is intended for use in the decontamination of moistened and waterlogged soils susceptible to infection by radioactive waste (RAW).

At present, there are known directions for the development of this technological process, the most representative of which are decontamination methods, including partial or complete removal of soil contaminated with radioactive waste, the processing of it with an acid solution, backfilling of part of the treated soil [1, 3, 4]
Obvious and significant disadvantages of this technology are significant costs for removal, transportation, processing in stationary installations, return delivery and bookmark; however, a more significant drawback is the low efficiency of the process of separation of radioactive waste from water-saturated soil, which necessitates the burial of significant volumes of contaminated soil and negatively affects the environmental indicators of the entire process of soil decontamination and remediation.

Closest to the technological essence is a method for deactivating hydrogeological structures, including drilling a well in an infected area for supplying leaching agents to the soil, collecting liquid phases including radionuclides, containerizing them and burial (in allotted burial grounds) [4]
Significant disadvantages of this method are the high specific costs of leaching agents with low decontamination efficiency of moistened to waterlogged soil (for example, in the North-West zone of the Russian Federation), the duration of the process leading to the alienation of territories and their irrational use, lack of guarantees for the release of radioactive gases into the atmosphere, as well as uncontrolled erosion of soils and the spread of radionuclides by their migration with moisture.

 The proposed method eliminates these disadvantages, and also more efficiently uses the physico-mechanical and physico-chemical characteristics of the treated soil for the decontamination process, which significantly intensifies the process and makes it environmentally friendly.

 However, the practical use of the proposed method does not force to comply with special rules around the decontamination site.

 This efficiency of the proposed method of decontamination of hydrogeological structures, including the drilling of wells for the supply of leaching agents, the collection of liquid phases containing radionuclides, the removal, containerization and disposal of radioactive waste, due to the preliminary execution of the screen from the radioactive waste geohydrostructures of the hydroradionuclide insulation material with slopes from its periphery to the center of the site , the boundaries of the site are isolated by vertical hydroradionuclide-resistant walls, connect them to the screen, in the middle of the site , below the screen, a reservoir is made, the latter is connected by a hole with the soil surface, the walls of the hole are strengthened by a draining microporous material, the walls of the wells and the holes are connected to different poles of the current source, the area is closed with an air-tight dome protection with forced illumination from above, and spores are cultivated in the spores mushrooms and mushrooms are grown in the natural infected phase.

 This implementation of the method allows for efficient and intensive outflow of liquid phases with radioactive waste, which leads to operational decontamination and remediation of soils with a return to general use.

 The set of essential technological features (techniques) of the proposed method was investigated for compliance with the criteria of the invention, including the criterion of the inventive step of the solved technical problem. At the same time, the sources of information that are closest in essence [1–10 applications] and the condition that all the signs are in a single connection and aimed at achieving a single result were taken into account.

 In these sources, well-known techniques that are separately used for particular tasks are identified: tank performance; the implementation of a protective casing for the removal of dust fractions from the working platform.

 In a detailed analysis of the separately known signs and the totality of the signs of the applicant’s proposal, it is determined that none of the known signs solves either the particular or the general task of the applicant, while even the artificial combination of known signs also does not solve the technical problem and is not aimed at achieving a single technical and economic and social (environmental) result.

 This allows the applicant to conclude that the developed method for the decontamination of hydrogeological structures meets the criteria of the invention.

 The essence of the proposal is disclosed further in the description of the drawing and methods of implementing the method.

 Under the infected section 1 of the hydrogeological structures, a hydroradionuclide-impervious screen 2 is made with a slope towards the middle part of the site, this section 1 along its perimeter / with a margin from the site for the possible spread of liquid phases is protected by a hydroradionuclide-impervious sheet pile wall 3, which is dipped in the lower part 4 through screen 2 for the formation of a hydro-sealed fence section 1. Then perform one or more workings 5, the perforated walls 6 of which are reinforced with microporous material with electric ovodyaschey mesh / waste of the manufacturing and production of the rolling /, the bottom of the production of complete development in a subterranean reservoir 7, wherein the additional container 3 operate with perforated walls; a pipe 9 with a perforation and a mesh at its base 10 to the bottom of the tank 8 is defined in a working 5, the cavity of the pipe 9 is connected to a vacuum pump / not shown /.

 After such equipment of the working platform, inclined 11 and / or vertical 12 wells pass with their perforated electrically conductive pipes casing, the cavities of which are connected to the injection pump / not shown /.

 To prevent possible releases of vapors into the atmosphere above the working platform, a protective sealing dome 13 is made from under which gases are exhausted. The dome is made of translucent material, and over the output 5 in the dome overlap, windows are made to allow direct solar radiation to be supplied to the output (in the absence of vapor under the dome), the walls 6 inside are covered with microporous material 14.

 Such arrangement of the infected area 1 allows efficiently, observing the rules and norms of radiation safety, to implement the technology of decontamination of the area infected with waste / waste.

 The method of deactivating the hydrological structures of section 1 is as follows. The walls 6 of the mine 5 are connected with the negative plus of the electric potential, and the pipes of the wells 11 and 12 are connected with the positive pole of the electric potential. The cavity of the pipes 9 are connected to a vacuum pump, and the cavity of the pipes 11-12 with a discharge pump; gases are pumped out from under the dome 13, keeping the pressure below atmospheric by 5 10 The flocculant supplied through the pipes 11, 12 enters through the perforations into the soils of section 1 and, leaching radionuclides from it, move / the liquid phase / by the directed movement of charged particles to the perforated walls 6 of generation 5, while part of the radioactive material settles on the microporous material 14 of the wall 6, part flows down into the containers 8 and 7, where a radioactive deposit settles down in the container 8 on its bottom. The pulp and the liquid phase from the tank 8 and the tank 7 are pumped out through the pipe 9 and taken for further using flocculants for enrichment and disposal / recycling; burial.

 If there is no water-resistant layer under the lower boundary of the geological structure of section 1, then part of the liquid phase goes to the screen 2 and due to its inclination towards the tank 7, flows towards the tank 7, flows into the tank 8 and is discharged through the pipe 9.

 The presence of microporous material 14 on the walls 6 can significantly intensify the decontamination process by applying fungal cultures spores to the material (for example, fungal spores: pigs, mushrooms, toadstools, etc.), this leads to faster and cleaner removal of RW from the walls 6 , and when the mushrooms are saturated with radionuclides / which is controlled by the instrument remote method; devices, as a trivial solution, are not shown in the drawing / last / mushrooms / are removed instead with material 14, replacing it with a new one for the second and subsequent bioactive decontamination cycles. At the same time, it is possible to use stimulating artificial lighting in UV and IR, helium-neon lamps.

 The decontamination technology is carried out until the maximum concentration limit for the content of radioactive waste is established in the soils of section 1. After this, the pipes 9, 11 and 12, as well as the walls 6, are removed from the ground, the structures are dismantled; the tank 8 and the tank 9 are filled with cementing hydroradionuclide insulating material; the site is leased for use by the environmental passport to the Gosatomnadzor / radiation safety service.

 If possible, the hydroradionuclide-impermeable screen 2 and the tongue 3 are kept for operation, to prevent the spread of those radioactive waste that could still remain in the soil sections 1 and were not detected during the control examinations during the commissioning of the site.

When implementing this decontamination technology, due to the specified arrangement and technological equipment of section 1, it is possible to use electric potential of various capacities, as well as different-temperature injection focuses, when the use of liquid and gaseous phases heated to 150 250 ^° C and cooled to 30 50 ^° C leads to more intense release of radionuclides at the boundaries of the interaction of these two phases introduced into the soil.

 Data on the specific composition of flocculants, their consumption per unit of treated soil volume can be given by the developer for a specific area infected with a specific radionuclide, as examples of the method for the given boundary conditions of this technology for deactivation of hydrogeological structures.

 Thus, the technical characteristics of the developed method consists in the high manufacturability of its operations, the simplicity and reliability of the entire cycle of work from the arrangement to the end of the decontamination process and the commissioning of the site by environmental protection is environmentally friendly.

 The mobility and versatility of the method allows you to use it when deactivating soils of different composition, structure, humidity, acidity, physico-chemical characteristics in open and cramped work conditions.

Sources of information taken into account:
1. Feasibility study for decontamination and reclamation of the Skipper Canal. With St. Petersburg, A / O "Vasilyevsky Island", 1992, v. 1, p. 10 - 26.

 2. Ampelogova H. I. et al. Decontamination in nuclear energy. M. Energy Publishing, 1982, p. 138 142.

 3. A. Plugin, A. p. USSR N 1604067, class G 21 F 9/34, 1982.

 4. Description of the Shelter object and requirements for its transformation. Kiev, Naukova Dumka, 1992, p. 19 28, p. 8, f. 12. The prototype.

 5. US Pat. N 4693833, class C 02 F 1/58, 1987.

 6. Germany of the district N 3615513, class G 21 F 9/28, 1987 decontamination of products from radioactive waste.

 7. United Kingdom, n-ka N 2092362, cl. G 21 F 9/28, 1982, radioactive waste containers.

 8. France, n-ka N 2562311, cl. G 21 F 9/10, 1985, RAO, purification.

 9.Pat. USA N 4724853, CL 08 V 3/12, 1985 cleaning of surfaces from radioactive waste.

 10. Japan, n-ka N 59 232300, cl. C 25 F 7/02, 1984, metal decontamination.

Claims (3)

 1. A method of deactivating hydrogeological structures, including drilling wells in an infected area, supplying leaching agents to the structure, collecting liquid radioactive phases, their subsequent containerization and disposal, characterized in that under the contaminated radioactive waste structures a screen is preliminarily made of hydroradionuclide insulating material with a slope of its surface to the center of the site, the boundaries of the infected area are isolated by vertical hydroradionuclide-resistant walls, connect them to the screen, in days, part of the site runs a reservoir below the screen surface, excavations from the soil surface pass to the reservoir, strengthen and cover their walls with an electrically conductive mesh and a drainage material with a microporous outer surface, wells are cased with perforated electrically conductive pipes, a positive electric current potential is applied to the walls of these pipes, and the walls of the workings have a negative potential, the area from above is aero-sealed with a dome, create under the dome lowered atmospheric gas pressure, and from The tank is discharging liquid radioactive waste for its containerization and disposal.  2. The method according to claim 1, characterized in that spores of fungal cultures are applied to the drainage material with a microporous outer surface, which are periodically removed for enrichment and disposal.  3. The method according to PP. 1 and 2, characterized in that the dome above the development is made of translucent material and helium-neon lamps are placed under it.