RU2694816C1 - Method of restoring safety barriers at a radioactive wastes disposal station - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to technology of improving or hardening soil using thermal, electrical or electrochemical means. Method of restoring safety barriers in a radioactive wastes disposal station includes immersing the electrodes in the area of formation of cracks and cavities in the barrier material, creation of electric field between electrodes, supply of carrier fluid to the area adjacent to electrode, transfer of carrier fluid from one electrode to another. Electrodes are immersed at the boundaries of the area of formation of a crack or cavity in a barrier material, which ensures safe burial of solid radioactive wastes. Barrier material mixed with the carrier fluid is fed into the first perforated electrode and injected into the anode area. Difference of potentials between electrodes is created, barrier material is pushed to area of formation of crack or cavity. Carrier fluid passed between electrodes and cleaned from barrier material is pumped through second perforated electrode. Dry barrier material is fed through perforation area.

EFFECT: invention makes it possible to remotely restore integrity of safety barriers at radioactive wastes disposal sites and to increase safety.

1 cl, 2 dwg

Description

The invention relates to the technology of improving or hardening the soil using thermal, electrical or electrochemical means and can be used to maintain the integrity of the clay-containing additional safety barriers at the points of storage and disposal of radioactive waste.

A known method of cleaning soil from hydrocarbons [RU 2132757, IPC WC09 1/02, B01D 61/56, publ. 10.07.1999], selected as an analogue. By this method, the central and peripheral electrodes are immersed in the soil. In the region adjacent to the central electrode, a heated carrier fluid with a pH of 5.5 is supplied, which is transferred under the action of an electroosmotic effect from the central electrode to the peripheral one. Hydrocarbons are squeezed out of the soil and removed from the peripheral electrodes.

The disadvantages of this method are:

- the need for heating and strict maintenance of the pH of the carrier fluid leads to a decrease in the efficiency of the process;

- when applying a heated carrier fluid to the region adjacent to the central electrode, its uneven distribution is created around the electrode, which leads to a weakening of the electroosmotic effect.

There is a method of recovery in place of contaminated heterogeneous soil [RU 2143954, IPC V09S 1/08, V09C 101/00, publ. 10.01.2000], selected as an analogue. According to this method, a constant electric current is passed through a region of low permeability soil within the region of contaminated heterogeneous soil between the first and second electrodes having opposite charges to cause an electroosmotic flow from the second electrode to the first electrode and / or electromigration movement of ionic pollutants towards the electrode opposite charge. The first electrode is placed at the first end of the area of contaminated heterogeneous soil, and the second electrode is placed at the opposite end of the area of contaminated heterogeneous soil. A hydraulic gradient is applied across the contaminated heterogeneous soil area to produce a hydraulic flow from the high pressure end of the contaminated heterogeneous soil area to the low pressure end of the contaminated heterogeneous soil area.

This method has disadvantages:

- for the implementation of the method it is necessary that the area of the soil between the electrodes was pre-moistened;

- the need for a hydraulic gradient for the emergence of a hydraulic flow increases the time of the process.

A known method of cleaning soil from hydrocarbons and pesticides and a device for its implementation [RU 2602615, IPC V09S 1/00, publ. 11/20/2016], selected as a prototype. By this method, the central and peripheral electrodes are immersed in the soil. Between the central and peripheral electrodes create an uneven electric field with a strength in the range of 50-110 kV / m. Soil is ground with a ripper to a particle size of 1.0 mm at a depth of 20-25 cm. The ground soil is mixed with a carrier liquid to a concentration of 1: 6. In the area adjacent to the Central electrode, serves the carrier fluid. They create a fluidized bed with a depth of 10-12 cm with a compressed air supply with a pressure of 1-2 atm. The carrier fluid is moved under the action of the electroosmotic effect from the central electrode to the peripheral one.

The disadvantages of this method are:

- the need for preliminary grinding of the soil to a particle size of 1.0 mm increases the time of the process and reduces the efficiency of the method;

- the complexity of the uniform arrangement of peripheral electrodes around the Central electrode to create an electroosmotic flow.

The technical result of the invention is the ability to remotely restore the integrity of the security barriers at the disposal sites of radioactive waste and improve the safety and efficiency of known methods.

The proposed method includes immersing the electrodes in the region of cracking and cavities in the barrier material, creating an electric field between the electrodes, supplying a carrier fluid to the region adjacent to the electrode, moving the carrier fluid from one electrode to another under the action of an electroosmotic effect. According to the invention, the perforated electrodes are immersed at the boundaries of the region of formation of a crack or cavity in the barrier material, which ensures the safe burial of solid radioactive waste. The barrier material displaced with the carrier fluid is fed directly to the first perforated electrode. Between the electrodes create a potential difference. Push the barrier material into the region of the formation of a crack or cavity. The carrier fluid, which passes between the electrodes and is cleaned from the barrier material, is pumped through the second perforated electrode. After the elimination of a crack or cavity, the electrodes are removed from the placement area, while simultaneously feeding dry barrier material through the perforation area.

The technical result is achieved due to the fact that to restore the integrity of safety barriers in the storage of radioactive waste of any geometry using perforated pipes from one end, which serve as electrodes simultaneously. Perforated pipes are positioned so that the crack or cavity in the barrier material is in the interelectrode space. In the upper part of one of the electrodes, which is the anode, a mixture of carrier fluid with a barrier material is injected under pressure, which is injected into the near-electrode region. Between the electrodes create a potential difference sufficient to start the electroosmotic movement of the carrier fluid. Due to the movement of the carrier fluid from the anode to the cathode, the barrier material is pushed to the crack or cavity. Restore the integrity of the safety barriers by filling them with an identical barrier material. The carrier fluid passing through the area between the electrodes is pumped through a perforated cathode connected to the pump. To prevent particles of the barrier material from entering the pipe, a metal filter located inside the cathode is used. After completing the process of restoring the integrity of the safety barriers, the electrodes are removed from the placement area, while simultaneously injecting dry barrier material to fill the resulting cavities.

FIG. 1 shows a scheme for restoring the integrity of safety barriers at a radioactive waste disposal facility.

FIG. 2 shows the process of extracting perforated electrodes.

To restore the integrity of safety barriers 1 in hard-to-reach places at the disposal site for radioactive waste 2, at least a pair of perforated pipes are used, which are hollow cathode 3 and anode 4 (Fig. 1). The cathode 3 is connected to a suction pump 5. Inside the cathode 3 is placed a metal filter 6, which transmits a carrier fluid and a barrier material. The anode 4 is connected to a pump 7 for supplying a mixture of a carrier fluid with a barrier material. The cathode 3 and the anode 4 are connected to a constant current source 8. Along the edges of the cavity 9 formed in the barrier material, perforated pipes are installed, which are the cathode 3 and the anode 4, for example, through concrete structures 10.

After completion of the restoration process of safety barriers 1, a filled cavity 11 and wells 12 from perforated pipes are formed, which are connected to a compressor for supplying dry barrier material 13.

The method is as follows.

When cavity 9 is formed in safety barriers 1 of radioactive waste disposal center 2, perforated pipes are used, which are hollow cathode 3 and anode 4, which are immersed parallel to each other as close as possible to the boundary of the region of formation of cavity 9 through holes in the storage elements, for example, concrete structures 10. The barrier material, identical to the barrier material at the disposal site of radioactive waste 2, is mixed with a carrier fluid that conducts electrical current, and under pressure iem via pump 7 is supplied to the first perforated electrode 4 is an anode.

Between the cathode 3 and the anode 4 create a potential difference using a constant current source 8. Push the barrier material coming from the perforated region of the pipe, which is the anode 4, into the region of the cavity 9 due to electroosmotic movement of the carrier fluid from the anode 4 to the cathode 3. Restore the integrity of safety barriers 1 by filling them with an identical barrier material.

The carrier fluid reaching the cathode 3 is pumped through the perforated area of the pipe. The dry barrier material is retained at the inlet to the cathode 3 by means of a metal filter 6. The carrier fluid entering the cathode 3 is removed from the pipe by means of a suction pump 5.

After completing the process of restoring the integrity of safety barriers 1, a filled cavity 11 is formed by filling the cavity 9 with the barrier material. The perforated pipes, which are the cathode 3 and the anode 4, are disconnected from pumps 5 and 7 and connected to a compressor to supply the dry barrier material 13. The cathode 3 and the anode 4 is gradually removed from the placement area, at the same time forcing the dry barrier material using a compressor 13 for filling the resulting cavities. The result is buried wells 12.

An example implementation of the invention is given below.

After detecting and determining the size of cavity 9, for example, according to RU 2579822, at least two perforated 57 mm diameter pipes made of GOST 9940-81 steel, which are cathode 3, were selected in clay-containing safety barriers 1 of the disposal point for graphite radioactive waste 2 anode 4. One of the ends of the selected perforated pipes was equipped with a metal cone-shaped tip to reduce resistance when moving in the barrier material. The cathode 3 and the anode 4 were immersed parallel to each other as close as possible to the boundary of the region of formation of the cavity 9 through the holes 10 present in the concrete structures. The distance between the cathode 3 and the anode 4 was ~ 1 m.

A barrier material was chosen that was identical to the barrier material at the point of disposal of graphite radioactive waste 2, containing a clay fraction from 18 to 28% by weight, and a fine silt fraction from 34 to 50% by weight. A significant part of the barrier material consisted of finely dispersed clay with a cation-exchange capacity of more than 30 mEq./100 g of rock. The selected barrier material was mixed with a carrier liquid. Distilled water with NaHCO ₃ dissolved in it - 318.3 mg / l was used as a carrier fluid; MgSO ₄ - 93.48 mg / l; CaCl ₂ - 192.7 mg / l. The barrier material mixed with the carrier fluid, under a pressure of ~ 1.5 kgf / cm ^{2, was} fed using a pump 7 into the first perforated tube, which is the anode 4.

Using a constant current source 8 between the cathode 3 and the anode 4 created a potential difference (100-150) V. The current density was (0.8-1.2) mA / cm ² . The barrier material mixed with the carrier fluid was pushed into the region of formation of the cavity 9 due to the electroosmotic movement of the carrier fluid from the anode 4 to the cathode 3. The velocity of the carrier fluid during electroosmosis was (2.5-3.0) mm / min. Restored the integrity of safety barriers 1 by filling them with an identical barrier material.

After 5.5 hours, the carrier fluid reaching the cathode 3 was pumped through the perforated area of the tube. The dry barrier material was retained at the entrance to the cathode 3 by means of a metal filter 6, which does not allow particles up to 0.045 mm in size. The carrier fluid entering the cathode 3 was removed from the pipe using a suction pump 5.

After the restoration of the safety barriers 1 was completed, a filled cavity 11 was formed by filling the cavity 9 with the barrier material 24 hours. The perforated pipes, which are the cathode 3 and the anode 4, were disconnected from the DC source 8 and from the pumps 5 and 7. Then the perforated pipes were connected to a compressor for supplying a dry barrier material 13. Dry barrier material using a compressor 13 under pressure (1.1-1.2) atm was fed into perforated pipes, which were simultaneously removed from the placement area with soon Tew 10 cm / min. After removal of the perforated pipes, filled wells were received 12. The total time to restore the integrity of the safety barriers at the graphite radioactive waste disposal site was 27 hours.

Thus, the safety of known methods is enhanced by the use of a remote non-destructive method of restoring safety barriers at radioactive waste disposal sites, excluding direct contact with radioactive materials. Efficiency is increased due to the implementation of the method in the repositories of almost any geometry and in hard-to-reach places.

Claims (1)

The method of restoring safety barriers at the point of placement of radioactive waste, including immersion of the electrodes in the area of formation of cracks and cavities in the barrier material, the creation of an electric field between the electrodes, the flow of carrier fluid in the region adjacent to the electrode, the transfer of carrier fluid from one electrode to another under the action of the electroosmotic effect, characterized in that the electrodes are immersed at the boundaries of the area of formation of cracks or cavities in the barrier material, ensuring safe burial of solid radioactive waste, and then the barrier material mixed with a carrier fluid, is fed into the first perforated electrode and injected into the near-anode region, creating a potential difference between the electrodes, pushing the barrier material into the region of the crack or cavity, and the carrier fluid passed between the electrodes and cleaned of the barrier material is pumped through the second perforated electrode, which, after the elimination of a crack or cavity together with the first perforated electro the house is removed from the regenerated area, while simultaneously feeding dry barrier material through the perforation area.

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