FR3001829A1 - Method for storing radiferous waste in geological layer to extract e.g. uranium, involves gradually saturating water to limit water movement to maintain waste in anoxic condition to avoid oxidation of waste and migration of radio elements - Google Patents

Abstract

The method involves placing radiferous waste in storage cells located at lower part of a water table in saturable ground water, and covering the waste. The ground water is gradually saturated to limit circulation and movement of water around waste in order to maintain the waste in anoxic condition to avoid or delay oxidation and to avoid migration of the radio elements in the radiferous waste and to fix the radon exhaled by waste, where time of radioactive decay of the wastes lasts approximately 3.8 days.

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to the storage of radiferous waste originating mainly from the exploitation of ores for the extraction of rare earths, zirconium or uranium, as well as depollution of ancient sites that have historically housed activities using radium or thorium.

The radium-containing waste contains radium, uranium and thorium and exhales radon-222, which is a radioactive gas of 3.8 days, due to the radioactive decay of radium-226. Background and problem The concepts of Storage of radiferous waste is based on the principle of avoiding any intrusion of water in the place where they are stored. Thus, the cells or cells in which these radiferous waste are stored are generally placed in relatively dry environments and away from any circulation or water runoff.

The object of the invention is to propose a different concept of the long-term storage of radiferous waste. OBJECT OF THE INVENTION The main object of the invention is therefore a method for storing radiferous waste consisting in successively: placing said waste products in at least one disposal cell situated below the level of a groundwater table in a saturable soil in water; - cover said waste, and - saturate the soil with water to limit the circulation and movements of water around the waste, in order to maintain the waste in an anoxic condition to prevent or delay oxidation and on the other hand to avoid the migration of radioelements found in radium waste and in particular to fix the radon exhaled by the waste the time of its radioactive decay which lasts approximately 3.8 days. Preferably, the method according to the invention comprises the following steps: - digging the at least one storage cell in said soil, below the level of said water table to a depth of 15 to 30 meters; filling the at least one waste disposal cell; - cover the whole with a confinement layer up to the level of the water table, surmounted by a layer of embankment itself surmounted by a vegetal layer resulting from the reworking of the initially excavated lands; ensure the saturation of the soil with water, around the waste and in the confinement layer. In this case, the confinement layer is preferably made of clay of low permeability, compacted and has a thickness of 3 to 5 meters.

In this case, the backfill layer is clayey and has a thickness of 6 to 10 meters. The method according to the invention is preferably used in a clay soil. List of Figures The invention and its technical characteristics will be better understood on reading the following description which is accompanied by four figures representing respectively: FIG. 1: in section, the preparation of the storage site according to the method of the invention; Figure 2: in top view, the same site at the same time; Figure 3: in section, the same site during the filling of the storage cells, and Figure 4: in section, the same site, once the process steps completed. In fact, the principle of the concept according to the invention consists in storing radiferous waste in a geological layer of low permeability with a dominant clay or marly component and at a depth of about ten at about thirty meters. With reference to FIG. 1, an open-air excavation 1 is first carried out, up to the level of storage envisaged, below the so-called "secular" piezometric level of the water table 2, at the bottom of which cavities are created. storage 3. These are dug on the ground, preferably clay. In Figure 2, we see the storage area 11 storage cells 3. A storm basin 12 is provided at a level slightly lower than that of the base of the storage cells 3, the ground base being slightly sloping . This storm basin 12 makes it possible to recover the water during the operating or filling phase of the disposal cells by waste packages. Then, with reference to FIG. 3, a platform 4 for operating and filling the storage cells 3 is constituted. The waste is packaged in containers 5 and stored in each storage cell 3, on several levels. Residual voids between the containers 5 are filled with a granular or cementitious material. As shown in Figure 3, during the formation and filling of cells, the latter are protected from run-off water and weather by temporary shelter, then by a building 9 for the operation and filling phase. During the operation and filling phase, radon management is based on natural ventilation of the cells, through the building in which they are located, the building remaining open on its side blanks. Until all the storage cells 3 are filled, they are covered with a temporary protective layer 10 made of clay. With reference to FIG. 4, once filled, the storage cells 3 are covered with a low-permeability, extremely compacted clay-containing confinement layer 6 3 to 5 meters thick, followed by a clay layer. embankment 7 from 6 to 10 meters thick, then a layer of plant protection 8 restoring the natural level of the site and resulting from the reworking of the lands initially present before excavation. After closure, a fundamental objective is to protect people and the environment from the risks associated with the release of radioactive substances contained in the waste, as well as external exposure.

The process according to the invention is intended to contain radiferous waste effectively for a few tens of thousands of years. The device implemented by this method, to ensure these functions, must remain available passively. Thus, it is planned to isolate waste natural phenomena, as well as ordinary human activities.

Below groundwater level 2, the soil must be saturated with water, similar to a sponge filled with water. In other words, we can consider that we drown radiferous waste. With respect to water transfers, the safety of the storage depends on the flow of water through it, the kinetics of the release of the elements by the waste and the interaction mechanisms that slow down the movements. The circulation of water is limited to limit the release of radionuclides and chemical toxins, as close as possible to radiferous waste. The installation of such an installation in a clay layer of low permeability therefore limits the flow of water. This promotes the establishment of chemical equilibrium and contributes to the control of transport or migration of solutes. In order to limit the oxidation of materials such as uranium, the storage and the confining part of the cover, namely the confinement layer 6, will be implanted under the water table, to promote the maintenance of anoxic conditions.

In general, the more the poral space of the materials crossed is saturated with water, the slower the rate of propagation of radon. It is thus possible to trap the radon and avoid its rise to the surface the time of its estimated radioactive decay to about 3.8 days.

Claims (4)

CLAIMS1) A method for storing radiferous waste consisting in successively: - placing said waste in at least one storage cell (3) located below the level of a water table (2) in a saturable soil water; - cover said waste, and - gradually saturate the soil with water to limit the circulation and movements of water around the waste, in order to maintain the waste in an anoxic condition to prevent or delay oxidation and on the other hand to prevent the migration of radioelements in radiferous waste and in particular to fix radon exhaled by the waste the time of its radioactive decay which lasts about 3.8 days 2) Method according to claim 1, characterized in that it comprises the following steps: - digging the at least one storage cell (3) in said soil, at a depth of 15 to 30 meters, below the level of said sheet phreatic (2); - Fill the at least one storage cell (3) of waste; - cover the assembly with a confinement layer (6) up to the so-called "secular" piezometric level of the water table (2), surmounted by a layer of embankments (7); - ensure the saturation of the soil in water, around the waste and in the confinement layer (6). 3) Process according to claim 2, characterized in that the confinement layer (6) is clay low compacted permeability and has a thickness of 3 to 5 meters. 4) Method according to one of claims 2 or 3, characterized in that the backfill layer (7) is clay and has a thickness of 6 to 10 meters.