SE461621B - Storage arrangement for storing environmentally dangerous substances - Google Patents

Abstract

The present invention relates to a storage arrangement 1 for storing environmentally dangerous substances 2 such as, for example, of the stable toxic compound type or of the long-lived nuclear substance type etc., and which comprises a number of cavities 6 in a rock, which are intended for receiving the substances 2 in question, with a roof 8 over said cavities, the cavities 6 in question being surrounded by a hydraulic barrier 7. The invention makes it possible inter alia to obtain a passive dry store. Receiving cavities for storage are formed by drilled vertical holes 6 which extend to a level 10 lying above an underlying drainage and ventilation zone 11. The hydraulic barrier 7, which is displaced laterally in relation to the storage boreholes 6, and laterally located ventilation holes 12 are connected to the underlying drainage and ventilation zone 9. <IMAGE>

Description

461 621 and ventilation zone, and that the hydraulic barrier displaced laterally in relation to the storage borehole or lateral ventilation holes is adjacent to the underlying drainage and ventilation zone.

The invention is described below as a preferred embodiment, reference being made to the accompanying drawings, in which Fig. 1 schematically shows a first embodiment of a bearing according to the invention, Fig. 2 schematically shows a second example of a bearing, Fig. 3 shows a preferred capsule for containment of environmentally hazardous substances, Fig. 4 shows a layer in sectional view, Fig. 5 shows a part of the intended production pattern of the layer, and Fig. 6 shows a further example of a layer in section.

The present invention relates to a layer 1 in which hazardous substances 2 of the type stable toxic or long-lived nuclear substances can be stored. The storage layer, which comprises a repository 3, 31, 32, is preferably enclosed by a rock formation 4, which rises above an adjacent valley depression. From the valley depression, an outlet tunnel 5 with a slope of a few degrees X, suitably exceeding 3 °, is blasted upwards into the rock formation 4. The height and plane of the repository can be adapted to the height of the rock formation above the valley depression and distribution horizontally. above the tunnel level in the rock, the repository is constructed in the form of drilled vertical holes 6. Around the repository 3, 31, one or more rows of boreholes 7 are constructed, which are connected to the outlet tunnel 5 below the repository 3. a watertight roof 8 is cast over the repository 3 ; 82.

The layer 1, 11, 12 can be constructed in a rock formation 4, which has completely or cracked rock, but that rocks with wide unwanted crush zones are avoided.

In the first exemplary embodiments of layer 1, 1, tunnels 9, which are suitably inclined> 3 ° in the direction from the repository 3, 31 towards the outlet tunnel 5, are constructed below it and these underlying tunnels 9 are intended to function as drainage and ventilation tunnels. The function of the drainage and ventilation tunnels l 461 621 is to try to keep the repository 3, 31 dry and ventilate away any heat, if the storage substances 2 emit heat while the outlet tunnel 5 has the task of carrying penetrating groundwater away towards the repository 3, 31.

The rows drilled around and at a suitable distance from the repository 3, 31 with holes 7, 71 are arranged to function as drainage holes and extend from the surface of the rock down to the said tunnels 9 which act as drainage. These surrounding rows of vertical outer boreholes 7, 71 can be described as a "hydraulic barrier", the function of which is to divert the groundwater penetrating towards the repository 3, 31 and the drainage from the roof 8, 82.

The drilled receiving hole 6 of the repository extends down to a level 10, which is located above the zone 11 in which the drainage and ventilation tunnels 9 are arranged.

In order to dissipate heat from the receiving boreholes 6 to the underlying drainage and ventilation tunnels 9, if necessary, vertical ventilation boreholes 12, 122 are drilled in the rock 4 and said repositories 3, 31, 32 and which are connected to the said drainage and ventilation tunnels 9. Blanks 2 such as fuel rods can be immersed to the bottom 6A of the receiving boreholes and be encapsulated efficiently and securely in containers 13 of a certain type. For example, said container 13 may be formed by an outer casing 14 in the form of a steel tube with inner pellet 15 of bentonite and pellet 16 of sintered steel or glazed with the storage material 2 in question received in its inner space 13A. The container 13 can be closed by means of a sintered lid of stainless steel. While a bentonite pellet 18 may be arranged to switch off between storage blanks 2.

Roof 8; 82 may consist of different layers of concrete 19 and of bentonite or other sealing material layer 20 as well as a draining material 21, such as macadam between each concrete layer 19 covered by a soil layer 22.

In the repository drained from water 3; 31 a dry repository is obtained. There is no water that spreads the dangerous substances 2 in the groundwater. Corrosion on the containers or capsules 13, where the hazardous substances 2 are stored is minimized or ceases completely, where no stress corrosion occurs in a dry storage.

In the embodiment according to Figs. 1 and 4, the precondition for storage is that fuel elements are torn down and that four fuel rods "are placed in a container 13 with a diameter of, for example, 60 mr th which is immersed in boreholes 6 with a diameter of for example .0 mm in a layer 1, which can be limited by a total horizontal surface of about 110,000 m2 and with a total depth of about 300 m, while in the embodiment according to Fig. 2 the precondition for dry storage is that fuel elements are placed intact in boreholes with a diameter for example 250 mm (BWR) or 350 mm (PWR) within a horizontal surface of approx. 27,000 m2 but with the same drilling depth B as as above.

Fig. 6 shows a further exemplary embodiment, which differs from the said previous layer in a number of points. The hydraulic barrier can alternatively be made in the form of an artificial crushing zone 200 of any width, i.e. the solid rock 4 is blasted to fragment 4A, whereby the efficiency of the hydraulic barrier is considerably better than with the presence of only drill heels. Boreholes can be drilled according to the previously stated proposal, but used as loading holes. The blasting can take the form of inverted benching, or more generally 'Sub level stoping' or vertical crater retreat (VCR). The advantage of this is that any rock stresses are neutralized. Movements outside the bearing 12, which are triggered for one reason or another, such as an earthquake, land uplift, land subsidence, do not primarily propagate to the bearing 12 itself, depending on the width of the crushing zone and the size of the movement. If blasting of crushing zone 201 is also carried out under the bearing 12, as shown in Fig. 6, the damping of movements in the rock 4 can be further increased. In addition, it will be very difficult to access the nuclear waste etc 2 from below. Another advantage of crushing zone 200 instead of boreholes, as a hydraulic barrier, is that the ventilating boreholes 122 can be connected to the crushing zone 200, 201. The residual heat emitted by the waste capsules 2 can then be dissipated to the crushing zone 200, 201, by convection, without to enter the biosphere and could be recycled through, for example, a heat pump system. Any moisture that may arise in the bearing 12 then condenses on the cold outer walls of the crushing zone and is diverted.

A water trap 202 can be arranged in the drainage tunnel 5 partly to prevent unauthorized persons and animals from approaching the warehouse 12, partly to prevent air supply to the warehouse 12. 461 621 The essential thing about the invention is that the receiving cavities for storing the blanks 2 are formed by drilled vertical holes 6, any width being selected as needed, and these deposition holes 6 reaching down to a level so that its bottom 6A is located clearly above the underlying drainage and ventilation zone 9; 201, for example 10-25 m, and that the hydraulic barrier 7, 200 or laterally displaced ventilation holes 12, 122 displaced laterally relative to the storage bore holes 6 are connected to the underlying drainage and ventilation zone 9, 201. This makes it possible to obtain a simple, safe and well-functioning storage for passive dry storage of hazardous substances, without requirements for the presence of fans or pumps to cool or dewater the storage.

The said underlying drainage and ventilation zone 201 can then preferably be formed by a crushing zone, i.e. a space in the rock, which contains rock fragments 4A, for example shattered rock 4.

The laterally displaced hydraulic barrier 200 may conveniently be formed by a crushing zone of the type indicated above.

Conveniently, a crushing zone 200 may extend around the entire storage layer 12 at, for example, about 25 meters distance from the repository 32, in the form of a square, and at least also along its underside, whereby connection of the crushing zones 200, 201 to each other is present.

The storage drill heels 6 are arranged to be closed by means of plugs, which can be formed by alternating layers of concrete and bentonite, for example with a thickness of 50-100 m.

The invention is not limited to the embodiments of bearings described above and shown in the drawings, but can be varied within the scope of the claims without departing from the spirit of the invention.

Claims (10)

461 621 P a t e n t k r a v Warehouses (1; 11; 12) for the storage of environmentally hazardous substances (2), such as stable toxic compounds, long-lived nuclear substances, etc., and comprising a number of cavities intended for receiving the substances in question (2). 6) in a rock (4) with a roof (8; 82) over said cavities (6), and that the cavity (6) in question is surrounded by a hydraulic barrier (7; 200), characterized in that receiving cavities for storage are formed by drilled vertical holes (6), which reach a level (10), which exceeds an underlying drainage and ventilation zone (9: 201), and that it is displaced laterally relative to the storage boreholes (6). the hydraulic lock (7; 200) or lateral ventilation holes (12; 122) are adjacent to the underlying drainage and ventilation zone (9; 201). Bearing according to claim 1, characterized in that said underlying drainage and ventilation zone (201) is formed by a crushing zone, i.e. a space in the rock (4), which contains rock fragments (4A), for example blasted. Mountain. Bearing according to one of the preceding claims, characterized in that the laterally displaced hydraulic barrier (200) is formed by a crushing zone, i.e. a space in the rock (4), which contains rock fragments (4A), for example crushed rock. . A bearing according to any one of the preceding claims, characterized in that said underlying drainage and ventilation zone (9; 201) is inclined in the direction of the storage bore (6). A bearing according to claim 4, characterized in that an outlet tunnel (5) sloping from the storage borehole (6) connects to said drainage and ventilation zone (9: 201). A bearing according to claim 5, characterized in that a water trap (202) is present in the outlet tunnel (5). A bearing according to any one of claims 3-6, characterized in that a crushing zone (200: 201) extends around the entire storage layer (32) and at least also along its underside with connection of the crossing zones (200, 201). 201) to each other. Bearing according to one of the preceding claims, characterized in that in the upward direction the storage layer (1, 12) is delimited by a roof (8; 82), which is formed by concrete (19) and bentonite (20) in several stock. Bearing according to one of the preceding claims, characterized in that the storage boreholes (6) are located with their bottom (6A) clearly above the underlying crushing zone (201), for example 10-25 m. Bearing according to one of the preceding claims, characterized in that the storage boreholes (6) are arranged to be closed by means of plugs formed by alternating layers of concrete and bentonite, for example with a thickness of 50-100 m.