CH657471A5 - DEVICE FOR STORING HEAT-RELEASING RADIONUCLIDE CONFIGURATIONS. - Google Patents

Description

The invention relates to a device for storing heat-releasing radionuclide configurations, which are optionally enclosed in containers, with free cooling with ambient air, essentially consisting of a housing with a loading aisle, supply and exhaust air ducts and closed storage cells provided with ceilings, the storage racks or storage blocks with horizontal or inclined storage shafts as storage positions for the radionuclide configurations or the containers with radioactive substances, wherein the storage shafts are flowed through by cooling air in the axial direction.

Radioactive materials and radionuclide configurations, such as B. burned nuclear fuel elements or glazed highly radioactive waste, generate heat when decay, so that constant cooling is required for their storage. This presupposes that the constant presence of a cooling medium is ensured and that no inadmissible amounts of activity are derived with the cooling medium. These requirements are met, for example, by a bearing that is directly or indirectly cooled with ambient air.

Various concepts are proposed for the dry intermediate storage of heat-releasing radionuclide configurations.

It is proposed in DE-OS 2 730 729 to store the containers with the radioactive waste in vertical shafts, through which air flows axially from the bottom upwards, one or more times stacked one above the other. In DE-OS 2 906 629, the storage takes place in horizontal shafts, from which flow flows from outside in the vertical direction, the containers being arranged one after the other or several times. In both cases, direct as well as indirect cooling systems can be used.

DE-OS 2 837 839 describes the storage of containers in horizontal storage blocks with laterally arranged heat sinks which are flowed transversely in the vertical direction. Storage in vertical storage containers with a front-side shielding cover, which also serves as a heat sink, is also known (Nuclear Technology, Vol. 24, Dec. 1974), as is storage horizontally with cross-flow within a closed room and heat dissipation to the environment by means of heat pipes (atom and Strom, vol. 26 (1980) 4).

The main disadvantage of the storage described in DE-OS 2 730 729 is cooling with laterally arranged heat exchangers (walls) and the flow guidance required for this. The cell air escaping from the vertically arranged shafts with maximum temperature and flow velocity hits the flat ceiling and is then guided horizontally to the side heat exchangers.

Flow energy is destroyed by an impact flow on the flat ceiling. Furthermore, the horizontal flow to the heat exchangers is not favored by the external force field (gravitation), since the heated air tends to rise upwards.

Another disadvantage of the concept cited in DE-OS 2 730 729 is that it is not possible to clearly assign the heat to be removed from the storage rack area to one of the two heat exchangers.

The main disadvantage of the devices described in DE-OS 2 837 839 and in "Nuclear Technology" is that steep temperature gradients are required for the heat flow from the storage containers to the heat sink, which can lead to thermal loads on the stored goods. A particular disadvantage of the bearing design according to DE-OS 2 837 839 is that the heat sink consists of a solid, good heat-conducting material, usually of metal, which results in very high costs. In addition, the heavy weight of the bearing blocks with heat sinks means that special structural requirements must be placed on the storage racks.

2nd

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

The main disadvantages of the concept described in “Atom and Electricity” are that there is no clear assignment of the heat to be removed from the storage rack area to one of the two “heat pipe bundle heat exchangers” and that there is no practical experience regarding the behavior of heat pipes in the radiation field . In addition, the heat is also dissipated from the side, which means that the flow is not optimal.

In the device described in DE-OS 2 906 629, the fact that the ambient air is exposed to the radiation field of the radioactive substances without major shielding measures is also disadvantageous.

With all devices for the intermediate storage of heat-releasing radionuclide configurations with indirect cooling due to free convection flow, there have been significant disadvantages, above all with regard to optimal flow guidance and thus also optimal heat dissipation and shielding the ambient air against direct radiation from radioactive substances.

The present invention was therefore based on the object of providing a device for storing heat-releasing radionuclide configurations or containers with radioactive substances with free cooling with ambient air, essentially consisting of a housing with a feed passage, supply and exhaust air ducts and blankets which are closed Storage cells containing storage racks or storage blocks with horizontally or inclined storage shafts as storage positions for the radionuclide configurations or the containers with radioactive substances, with cooling air flowing through the storage shafts in the axial direction. This device was intended to improve the flow of cooling air and thus ensure reliable heat dissipation. In addition, the ambient air should be shielded against direct radiation from the radioactive substances stored.

This object was achieved according to the invention in that the ceilings of the storage cells are designed as heat exchangers and vertically, spatially and functionally separate lift and driven chimneys, which are open in the area of the storage racks, are arranged at the storage shaft openings within the storage cells.

It can be advantageous to arrange a separate lift and drive chimney for each storage rack, or to design the loading aisle as a common lift or drive chimney for two storage racks.

It is also advantageous to incline the bearing cell ceiling in the direction of the driven chimney, angles of <15 ° having proven to be favorable.

The arrangement of a separate buoyancy chimney via which the heated air is fed to the ceiling of the storage cell, which is designed as a heat exchanger, and a separate driven chimney provide a clear separation of functions between the buoyancy chimney for the heated coolant and the output chimney for the coolant cooled on the ceiling. Both the lift chimney and the chimney are in the direction of the earth's gravity field, i.e. aligned vertically, which is particularly favorable with regard to the size of the pressure losses and what thus has a favorable influence on the temperature level in the bearing.

Arranging the heat exchanger where the highest air temperature occurs within the cooling circuit, namely above the storage racks, proves to be particularly favorable from a thermodynamic point of view, since this results in the thermodynamic efficiency of the heat exchanger being the greatest.

657 471

In order to better protect the ambient air as it flows through the heat exchanger (ceiling) from exposure to direct radiation from the stored goods, internals can advantageously be arranged below and to the side of the ceiling to shield the radiation. Buoyancy and driven chimneys are preferably designed such that stray radiation effects are avoided.

The device according to the invention is explained in more detail below with reference to the schematic FIGS. 1 to 6. Show it:

1: schematic representation of the warehouse with a separate loading aisle and closable charging openings,

2: cross section through a storage cell, FIG. 3: cross section through a schematically illustrated storage shaft,

4: longitudinal section through a schematically illustrated storage shaft,

Fig. 5: schematic representation and flow principle, variant loading aisle = buoyancy chimney and

Fig. 6: schematic representation and flow principle, variant of separate loading aisle with closable charging openings.

The device consists of one or more storage cells (15), usually separated by loading passages (10), which are housed in a building. In these storage cells (15) there are storage racks (9) or storage blocks with storage shafts (2). The storage containers (1) filled with the stored goods are introduced into the preferably slightly inclined storage shafts (2) and, if necessary, pushed continuously through them. Spacers (12) are normally used to center the storage containers (1) in the storage shaft (2), which can simultaneously act as ribbing on the surface of the container. Storage containers (1) and storage shafts (2) form a free flow space through which the cooling air can flow in the axial direction. In the case of storage containers (1) which are circular in cross section and storage shafts (2) which are circular in cross section, an annular gap (17) results as the free flow cross section. Other suitable shaft cross sections, e.g. for rectangular storage containers are possible. The arrangement of the storage shafts (2) in the storage racks (9) is arbitrary, but mainly horizontal and square or hexagonal (Fig. 1). The cooling air heats up on its way through the free flow spaces (17) along the heated storage tanks and shaft surfaces. The inside surface of the shaft is heated secondarily by heat transfer due to heat radiation from the surfaces of the storage containers. The heated cooling air flows from the storage shaft (2) into the vertical lift chimney (3) and rises there.

The device according to the invention is an indirectly cooled bearing, in which the heated cooling air is guided to the ceiling (4), which is preferably slightly inclined in the direction of flow and is designed as a cooling surface and along which it cools down to the storage shaft inlet temperature. After exiting from the cooling channel (5) arranged along the ceiling (4) and formed by the ceiling (4) and the bearing block (9) or internals (21), the cooling air returns via the driven chimney (8) to the storage shafts (2 ). The ambient air, which sweeps over the ceiling (4) as external cooling air for the cooling surface, reaches the ceiling (4) via a supply air duct (7), where it is heated. The ambient air heated in this way is returned to the environment via an exhaust air duct (6).

Buoyancy chimney (3) and driven chimney (8) are thereby defined by limiting walls containing charging openings (13).

3rd

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

657 471

de (14) from the loading aisle (10) and possibly from a removal aisle (11).

If continuous storage operation is dispensed with, the removal aisle (11) and thus the charging openings on this boundary wall are dispensed with.

In addition, it is also possible to abolish the local separation between the buoyancy chimney (3) or the output chimney (8) and the loading aisle (10) and to design the loading aisle directly as a buoyancy chimney (3) or output chimney (FIG. 5). In this case, the boundary walls (14) with the charging openings (13) are also omitted here.

The inclination of the ceiling (4) and the storage shafts (2) ensures a clear direction of the circulating air flow.

The specification of a clear direction of the circulating air flow can also be achieved if the design of the individual storage shafts (2) in the storage rack (9) and the cooling channel (5) is such that the flow resistances are different for both flow directions. The flow resistance in the desired flow direction must be smaller than that for the opposite direction. This is achieved by means of appropriately shaped internals (20) at the storage shaft openings (18, 19).

The flow direction in the outer cooling circuit can also be selected by different heights of the supply air duct (7) and exhaust air duct (6) on the housing.

A ceiling slope angle of <15 ° has proven to be advantageous. It is also desirable for structural reasons so that the housing height is not higher than necessary.

Equipping the ceiling (4) designed as a heat exchanger with cooling fins (22) has proven to be recommendable from a thermodynamic point of view. By increasing the heat transfer area, the temperature level in the warehouse is reduced and, with a certain cooling capacity, the space required for the ceiling (4) is reduced.

The shielding of the ceiling (4) by means of internals (21) (e.g. a thick concrete ceiling that is pulled in) prevents direct radiation of the ambient air in the external cooling circuit. Dust activation and radiation of other substances that get into the heat exchanger with the environment is thus limited to minimum values.

Materials are used for the internals (21) which primarily weaken the radiation dose. Suitable materials are e.g. Concrete, iron or lead. The radiation-shielding internals (21) are designed, for example, as suspended concrete ceilings. This ceiling (21) can be arranged directly above the storage rack (9). It has openings (24) in the area of the upward (3) or downward chimneys (8), which allow the cooling air to flow in and out of the cooling channel (5).

Buoyancy (3) or driven chimneys (8) are designed in such a way that scattered radiation effects are avoided, i.e. An unimpeded radiation from the radioactive material into the up (3) or down chimney (8) and radiation propagation by scattering on the boundary walls is prevented.

Manufacturing the ceiling (4) from a metallic material (e.g. steel) has proven to be particularly advantageous, since metals generally have very good heat-conducting properties and thus the thermal resistance between the inner and outer cooling circuit is minimized. For the same reason, it is advisable to subject the surface of the metallic ceiling (4) to a treatment that promotes heat transport by radiation (e.g. anodizing, black painting).

Corrosion protection (e.g. galvanizing, anodizing) ensures that the ceiling (4) also meets the requirements for a longer period.

To make the storage shafts (2) and the storage containers (1) circular in cross-section proves to be inexpensive for reasons of cost. Other cross sections, e.g. square or hexagonal, are of course also applicable.

The closable charging openings (13) in the boundary walls (14) have proven to be particularly advantageous because they enable a local separation between the storage cell (15), the loading aisle (10) and the removal aisle (11), which in view of possible intervention measures is of great advantage.

Baffles (16) within the storage racks (9) that prevent cross flow can advantageously prevent the build-up of heat at the highest point of the storage rack and thus also prevent the possibility of local hot-spot formation.

By heating the shaft walls (2) as a result of the heat transport by radiation from the surface of the storage containers, the air in the spaces between the storage racks (9) is heated and rises to the top, where it collects in the upper area of the storage racks (9), thus there there is a possibility of heat accumulation.

In order to avoid this, for example, transversely arranged sheets (16) are arranged in the spaces between the storage racks (9) in order to prevent the air from flowing upwards.

Of course, the device according to the invention can also be designed with several heat exchangers connected in series as a multi-stage heat exchanger system (FIG. 6), the ceiling (4) being designed in multiple stages.

This means that the heat generated in the storage cell (15) is not released directly to the ambient air at the storage cell ceiling (4), but to a further closed circuit (23) which then releases the heat to the ambient air.

4th

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

S

3 sheets of drawings

Claims (13)

657 471 PATENT CLAIMS 1.Device for storing heat-releasing radio nuclide configurations or containers with radioactive substances, with free cooling with ambient air, essentially consisting of a housing with a loading aisle, supply and exhaust air ducts and closed storage cells with ceilings, the storage racks or storage blocks with horizontally or diagonally arranged Containing storage shafts as storage positions for the radionuclide configurations or the containers with radioactive substances, wherein the storage shafts are flowed through by cooling air in the axial direction, characterized in that the ceilings (4) of the storage cells (15) are designed as heat exchangers and within the storage cells (15) the chute openings (18, 19) are arranged vertically, spatially and functionally separate lift (3) and driven chimneys (8), which are open in the area of the storage racks (9). 2. Device according to claim 1, characterized in that the loading aisle (10) is designed as a lift (3) or driven chimney (8). 3. Device according to claim 1, characterized in that for each storage rack (9) a buoyancy (3) and an output chimney (8) is present. 4. Device according to one of claims 1 to 3, characterized in that the ceiling (4) of the bearing cell (15) is inclined in the direction of the driven chimney (8). 5. The device according to claim 4, characterized in that the angle of inclination of the ceiling (4) is <15 °. • 6. Device according to one of claims 1 to 5, characterized in that the ceiling (4) of the bearing cells (15) is provided with cooling fins (22). 7. Device according to one of claims 1 to 6, characterized in that the ceiling (4) with radiation-shielding internals (21) is provided within the storage cells (15). 8. Device according to one of claims 1 to 7, characterized in that the ceiling (4) consists of a metallic material. 9. The device according to claim 8, characterized in that the surface of the metallic ceiling (4) is subjected to a corrosion-inhibiting and / or a treatment which promotes heat emission by radiation. 10. Device according to one of claims 1 to 9, characterized in that the ceiling (4) of the storage cells (15) is designed in several stages. 11. Device according to one of claims 1 to 10, characterized in that at the inlet (18) or outlet openings (19) of the storage shafts (2) internals (20) are attached which have a lower flow resistance in the desired flow direction than in the opposite direction. 12. The device according to one of claims 1 to 11, characterized in that the free space between the stacking shafts (2) contains cross-flow-obstructing internals (16). 13. Device according to one of claims 1 to 12, characterized in that the buoyancy (3) or driven chimneys (8) are provided with closable charging openings (13) against the loading passage (10).