SE433150B - FINAL DISPOSAL DEPOSIT FOR RADIOACTIVE WASTE - Google Patents

Description

10 l5 20 25 30 315 40 ? 81.1-942-7 materials such as glass, ceramics, bitumen, plastics and hydraulics binder. In addition, the storage chambers are closed with salt and hydraulic adhesives and the gaps between fall barrels with crushed salt. Waste placed in boreholes shall be protected by bodies of different materials such as salt, cement or bitumen. In all these cases, however, one counts at the as "assumed maximum breakdown" (AMH), i.e. dimensioning accident, assumed the water intrusion with the occurrence of a direct contact between some or all of the stored waste and intrusion aqueous solutions. It is estimated that a fraction of the stored the radioactivity is leached and by convection and diffusion distributed over a more or less large area in the cavities underground. Under unfavorable conditions can not be excluded that some of the contaminated saline solutions after more or less long time comes into contact with that at less depth the groundwater. In this case, the purpose of the final disposal questioned and jeopardized namely that the radioactivity for a long time to come will be reliably terminated from the biosphere.

For storage of highly radioactive, heat-generating waste has arranged for the purpose of final disposal depots, which in their form are in principle similar to conventional ones mines. The highly radioactive waste comprises about 99% of it activity for final disposal. That in a glass matrix fused waste must be packed in stainless steel containers and disposed of in boreholes.

So far, however, no measures have been known, which during or after the operational phase can safely protect the waste against contact with water. In the proposals presented so far the disposal of the final disposal level horizontally and directly to the vertical shafts from the ground surface via a field location at the same depth. \ Furthermore, the possibility of a final disposal depot is expected or after the operating phase is filled with water, even if this event assumed with a very low probability. The one so far proposed direct horizontal connection of the final the location of vertical shafts from the ground surface would facilitate spread of radioactivity by convection.

It can be assumed that water penetration - if at all - takes place in groundwater-bearing cover layers via a shaft pipe. This shaft pipes are generally considered to be the most exposed of the final disposal depot 10 15 20 25 30 35 40 3 '78119142-7 part, because here in the shortest way groundwater conductor and the geological layer formation, e.g. rock salt, permeated by shaft shaft, why even in the future one under the longest possible time completely waterproof shaft design 1 this area should pay the utmost attention. Should still arise water- penetration, the water would flow to the deepest point of the shaft and from there spread to the horizontally branched storage the localities or the stockpiles. Through the highly radioactive waste heat generation, the rock is heated locally. The under hydrostatic pressurized saline solution could penetrate the bearing boreholes, attack the hot waste molds and leach radioactivity.

Due to the high temperatures, even very strong convections would currents can occur in the vertical boreholes.

Due to density differences, the leachable then spreads activity within a short period of time over the entire disposal sontella del. Due to the higher temperature of the brines in the lowest part of the final disposal depot, a transport of radio active nuclides also to be able to take place in the vertical direction in the shaft pipe of the final disposal depot. Thus, it must be feared that the spread finally takes place all the way to the water penetration point level and thus to the groundwater. Active countermeasures to protect the stored waste from contact with saline solutions according to the development so far not yet proposed and are also not conceivable in the design of the final disposal depot in conventional form.

The object of the invention is to carry out one in such a manner final disposal depot for high, medium or low level waste, that this waste is safe, long-term and automatically protected against contact with water, in which case there should also be a possibility to stop or shut off the spread of water from above ground to areas outside the direct water penetration point.

This object is solved according to the invention by: the final disposal site for the final disposal of the waste is located at a level with sufficient distance above one leading to the shaft level of the place of connection and that the place of final bound with the connection point to it via at least one from the place of connection to the place of final disposal ascending, not water-filled blind shaft or an ascending riser.

A further development of the invention proposes that The location between two shafts is designed as a depression. Especially advantageous is that in the bearing section via pressure lines be able to initiate gas in the event of a risk incident. 10 15 20 25 3o_ ss' 40 7211942-7 The invention thus allows by a suitable design of final disposal a safe shielding of the stored waste against contact with water or saline solutions. In addition is extra active countermeasures possible, which prevent the spread of the liquid from the shaft area to the cavities underground and you can t.o.m. get out any water that has penetrated again. Should a water intrusion occur from mountain areas other than directly in the shaft, which at corresponding, crack-free safety zones around the actual final disposal can be assumed with a significantly lower probability than water penetration through the shaft pipe, it is according to the invention possible even in this case to shut down large parts of final disposal depot against penetrating liquids. This happens on it the way that the entire final storage field is divided into separate ones sub-bearings, which are not interconnected through horizontal localities of the same level.

The invention will now be explained in more detail in connection with a schematic embodiment shown in the accompanying drawing.

As shown in the figure extends for communication with final disposal depot 10 required vertical shafts 4, 7 significantly deeper than the storage level ll in the actual final storage location 2 and has a sufficient safety distance from the 2 final disposal holes of the storage location. In case of assumed maximum failure (AMH) can in the for the final disposal of high-speed radio active waste use the final disposal part 1 of the final disposal the depot 10 generates an air cushion which is below the water column hydrostatic pressures. This ensures that the water masses l2, l3, 14 do not have direct access to the storage part ll According to experience, rock salt formations are underground impermeable to gases.

The verticals required for the final disposal depot 10 shafts 4, 7 are driven a certain distance (approx. 200 m) further down than the actual final disposal site 2 of the "highly radioactive, 'heat generating waste. After these vertical shafts 4, 7 driven down to about l0G0 meters depth, operated pocket resorts and horizontal connecting distances 3. The actual final disposal part l is constructed approximately 200-300 meters above level l5 and is only through risers and / or blind shafts 5.6 connected with the lower connecting lines 3 or 16. In the case of water penetration rises the water 12, 13, 14 first in the mine lower parts and compresses the existing ones in places 1, 5 and 6 10 15 20 25 30 35 40 '7811942-7 the air to the hydrostatic pressure of the water column.

The one required for the prevention of ingress of water 12, 13, 14 additional amount of air can via via shafts 4 and 7 or pipelines 9 located at locations 3 and 16 via above ground (not shown) Compressor stations are pressed in the final fern part 1.

By introducing a gas, direct contact between i the final disposal depot 10 penetrated water 12 - 14 and the radioactive the waste. The possibility of leaching and subsequent spread of radioactivity is reliably and for a long time prevented ahead.

As shown in dashed lines in the figure, the connection locations can 3 is designed so that one or more thereof forms a connection point 16 with a slash 8. This design has the advantage that with security is prevented that e.g. in case of heavy water penetration the water immediately rises in the riser 5 resp. blind shaft 6.

By means of the gap 8 it is thus achieved that this is filled first and that the air (gas) in the final storage part 1 resp. stigorten 5 och the blind shaft 6 remains for a certain time before the water 13 also blocks these.

In the meantime, underground workers can always leave the final disposal depot via one of the horizontal ones the connecting distances.

As shown by dashed lines in the figure, can from the riser 5 or the blind shaft 6 are provided with additional cavities 17, which in the case of very rapid water penetration first occupy the water masses. The air displaced from these extra rooms folds away to the final disposal part 1 and is compressed there. Pâ This way comes even if all the compressors are above ground lacks, the storage part l not to be filled with water.

In addition to this advantage, there are also other technical ones possibilities for long-term securing of the final disposal depot 10, which in hitherto discussed embodiments of final disposal depot not been possible. Through thoughtfully built-in pipelines 9, which in normal operation can be used as cooling, fresh air and material transport lines, can in the below elevated pressure standing air volume is pumped in viscous filling masses, which eventually solidify and eventually lead to a solid material tightly sealed final disposal depot 10 as well after unforeseen water penetration. avs119u2-7 6 To reduce the air volume in the final disposal level ll can the final disposal part 1 is further filled, if applicable with weak or medium radioactive waste, e.g. and fat.

Claims (4)

10 l5 20 25 7 78119112-7 PATENT REQUIREMENTS A final disposal depot (10) for radioactive waste in a salt stack or any equivalent geological formation, the waste being placed in storage-capable screening containers and stored in a final disposal site (1) in the salt stack or formation, whereby the final storage site (1) can be reached via at least one shaft (4, 7), characterized in that the final disposal site (1) for final disposal of the waste is at a level (11) with a sufficient distance above a connection site leading to the shaft (4, 7). (15) and that the final storage location (1) is connected to the connection location (3) to this via at least one ascending, non-water-filled blind shaft (6) or an ascending riser (5) ascending from the connection location (1) to the final storage location (1). . The final storage depot according to claim 1, characterized in that between two shafts (4 and 7) leading to the ground surface is such that the connection point (3) is designed as a depression (8). Final disposal depot according to claims 1 and 2, characterized in that the final disposal site (1) for receiving the waste (2) can be supplied with a gas via pressure solders (9). Final disposal depot according to Claim 1, 2 or 3, characterized in that the final disposal site (1), the ascending ridge (5) and / or the blind shaft (6) are wholly or partly in the event of downtime or water intrusion. securely sealable with suitable material through pre-laid pipelines (9).