DE8032545U1 - STORAGE AND TRANSPORT CONTAINERS FOR AT LEAST ONE CHOCOLATE FILLED WITH RADIOACTIVE MOLDS MELTED IN GLASS - Google Patents

Description

Description ;

The present innovation relates to a storage and transport container preferably for at least one, Mold filled with radioactive waste melted in glass, consisting of several nested ones Containers made of concrete and steel and / or lead, which are each closed with lids, the the Inner sealed steel or cast iron container containing a mold in a pot-shaped concrete shielding container arranged and fixed in it by a casting filling reaching up to the concrete container opening.

The registration relates to storage containers for radioactive wastes that are mainly weak or low activity. Radioactive fission product solutions, which have higher activities and those in the operation of reprocessing plants, are, on the other hand, melted into certain types of glass according to the state of the art. This Glass is in a mold-like shape that is welded by shrinking after it has been filled is closed. This waste is highly radioactive waste with a very high spec-

specific activity up to Io Ci / 1. Equipment for manufacturing these molds have so far only existed as prototypes and test systems. Because of the high dose rate these containers must be handled in hot cells. Some of these give waste, in particular if the fission products are relatively fresh, they dissipate a considerable amount of heat. on the other hand

there are certainly fission product solutions that already exist

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have subsided in such a way that the heat generation
in the order of magnitude of Io to 20 watts per mold
lies. The storage of these molds has so far been largely unsolved.

So far, there have been more than one solution to this problem

rere suggestions. One of these suggestions sees the |

Storage of the molds in the salt of a mine. |

Further proposals are to put the molds in loading |

clay blocks drilled with holes and |

be ventilated to store. Another possibility f

is the storage of these molds in shielded f

Rooms with simultaneous ventilation and cooling |

of these rooms. $

The technical feasibility of the well-known Lö- |

sung has so far only been tried out on a trial basis. The- |

se solutions largely have the disadvantage that f

the waste is put in a transport container

the must and from this transport container then in g

the camp to be spent. Ie- ·· is an exception;

only the solution of a shielded bearing in p

Connection to a glazing system. With the type of |

Working in a hot vitrification cell is thus $

It is to be expected that the molds in these hot cells IS

become heavily contaminated. In order to have a flawless | j To be able to guarantee transport and safe storage .., these molds would have to be carefully outside can be decontaminated remotely.

The object of the present invention is now the
Glass canisters in one at the point of origin

safe transport container with low surface

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to pack dose rate, which can also serve as a storage container. The storage of these containers should, if possible, in simple buildings that can be built without great effort in terms of ventilation and cooling and do not have to be aircraft crash-proof or the like. The bin should be independent from the place where the waste is generated. In order to be able to use it economically, this container must be easy and cheap to manufacture and at the same time meet high strength requirements.

To solve this problem, the present innovation proposes in a container of the type described at the outset Kind before that between the whole, with one in the casting filling in the area of the concrete container opening anchored crossbar with a potted container arrangement attached to it and protruding from the container is introduced into an additional concrete shield, which consists of a base and cover with intermediate, consists of stacked, uniform, ring-shaped concrete modules without cladding, which are secured against displacement without special sealing, are placed on top of one another and that between the encapsulated container wall and the additional shielding there is an air gap. The invention further suggests that the horizontal parting lines are set off like a collar and act as ventilation slots are formed and that the elements or concrete modules with the cover and the bottom part by means such as Tie rods or the like are held together lengthways. Ultimately, the present innovation strikes in a particularly advantageous manner that the loading

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toninodulen or elements of the additional concrete shielding are designed as integral parts interchangeable that in addition in the ground or in the lid there is an angled vent opening and that the casting filling Made of a casting compound that conducts heat well, such as bearing metal based on copper or tin alloys or the like.

What is new is the storage of glass canisters in a combination of steel and concrete containers, with the Concrete tank is designed with two shells. The inner container, which consists of a steel and a concrete shell exists, designed as a tight storage and transport container. The second shell is made of concrete only a shield that is used for temporary or permanent above-ground storage. The usage transport bottles or the like is no longer necessary. A decontamination of the glass canisters can also be omitted. The tanks used, both made of steel and concrete, can be put in of any quality can be produced in a conventional manner and are therefore economical to manufacture. The storage in multi-shell containers made of steel and concrete avoids the creation of complex Storage buildings. For a possible removal of the containers to a later repository, no special Containers are procured. The inner container is both a storage and a transport container. The emerging Heat is either dissipated from the concrete in a suitable manner, this being done by highly conductive metallic materials Casting compounds or through ventilation slots in the shields can be reached.

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The innovation thus represents a much more economical and easy-to-use alternative to the previously known and planned solutions for the storage of vitrified fission products and solves the task set at the beginning in an optimal way. The containers outlined above are simple with conventional ones Funds to manufacture. The removal of waste from the hot cells is made much easier and entire work steps are saved. The inner containers for holding the glass canisters are standardized and can later serve as a transport container to a possible repository.

Further details are explained in more detail below with reference to the figure, which is a longitudinal section through show the new container schematically: The molds 1 contain radioactive fission product solutions, melted in glass. They are hermetically sealed and can on their surface be contaminated to some extent. In order to reduce the level of contamination of the molds this is first brought into the inner container made of steel or nodular cast iron by remote control. The introduction of the molds 1 in this container 2 can be done remotely via a kind of double lid, so that it is only slightly outside is contaminated. This steel container 2 is then closed by a lid 3 with a seal "4 is provided, which is already through the plug-like lid 3 is largely protected against the radiation of the molds 1. This container 2, which is very roughly machined can be and is therefore easy to manufacture,

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is now in a pot-shaped concrete shielding container 5, which is made of either normal or barite concrete, introduced. After the introduction is the Mold 1 already shielded by the steel 2 and by the concrete container 5, so that the dose rate on the outer wall of the container 5 is considerably reduced. The concrete container is now made with simpler means closed by a traverse 6, which is also used to hang up the container. This traverse 6 also prevents the steel container from falling out of the concrete shield, e.g. if the shield falls over, can fall out. The space 8 between the steel container and the concrete container is now covered with a suitable Potting compound filled up. The traverse 6 on the one hand via tension rods 7 anchored in the concrete container 5 firmly connected to this on the other hand, but also in the upper area 9 above the steel container 2, i.e. in the The opening area of the concrete container 9 is poured directly into the grouting filling in this. On the crossbar 6 a carrying eyelet Io is attached above, which over the grouting filling of the upper part 9 from the concrete container 5 protrudes. In the case of molds 1 with low heat emission, it is sufficient for the intermediate layer 8 to consist of a Kind of making mortar. In the case of molds 1 with a higher thermal output, it is advisable to use the intermediate layer made from a kind of bearing metal. These bearing metals, which in principle are alloys of copper, tin and the like have the advantage of great thermal conductivity. In this way the nascent Heat is dissipated from the concrete of the container 5 and via the metallic stopper in the upper area then brought to its top surface. That

The structure that has now arisen represents a tight and permanent envelope of the glass mold 1. The container arrangement can be stored in shielded rooms without the need for special ventilation. A Any slight pressure build-up in the mold 1 is easily absorbed by the thick-walled steel container 2.

Should, in addition, longer storage in simple above-ground buildings be planned and thus the Dose rate are reduced so that a control of the container is possible at any time, so will the inner container 5 with the molds 1 inserted into a second concrete container 11, the shielding strength of each can be varied according to the dose rate of the inner container 5. This exterior concrete container 11 is now only used nor shielding purposes. The container can therefore be provided with supply air ducts 12. Between the inner container 5 and the outer container 11, a corresponding air gap 13 is left. The outer container 11 is closed with a concrete cover 14 and a concrete floor 17, but with ventilation slots on the sides 15 has. These ventilation slots 15 have bends 18 so that there is no weakening the shielding effect.

Form the collar-like angled ventilation slots 15 Joints between individual, ring-shaped concrete modules or elements 16, which are placed on top of one another in height and be centered by the bends 18 or secured against displacement. Their thickness and height are different can be varied as required, with expedient

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a uniform size is assumed to simplify manufacturing. On the elements is the Concrete cover 14 is set, the floor is closed with the concrete floor part 17. The elements 16 with bottom 17 and cover 14 are held together by means of tie rods 19 axially inserted through the elements, which clamped on the bottom 17 and cover 14 by means of screws 2o are. The inner container 5 is now located in an outer container 11 that is easy to create, which, in addition to shielding, offers additional security, e.g. against plane crashes. the The heat generated in the inner container 5 is withdrawn from the container system by natural drafts. One This avoids excessive heating of the inner container. In this way, standard inner containers are used, which are used in the outer container 11 to be varied depending on the required shielding will. The inner containers 5 can be removed from the outer containers 11 at any time and the Outer container 11 can be used again. This arrangement has the consequence that the inner container 5 is economical can be created in a conventional manner. The outer container 11 can be made of relatively inexpensive material produced and adapted to the required shielding.

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■ List of Bezvias:

1 mold

2 inner steel or cast iron container

3 lids

4 seal

5 concrete shielding containers

6 traverse

7 tension bars

8 intermediate layer in the form of an annular gap

9 upper area

10 eyelets

11 second concrete tank

12 supply air ducts

13 air gap

14 concrete cover

15 ventilation slots

16 ring elements or concrete modules

17 concrete floor

18 bends

19 tie rods

20 screws

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Claims (6)

»Ί · ■ t I NUCLEAR RESEARCH CENTER Karlsruhe, March 11, 1981 KARLSRUHE GMBH PLA 8o61 Sdt / str ANR 1 002 597 Protection claims; 1. Storage and transport container, preferably for at least one, with radioactive melted in glass Waste-filled mold, consisting of ψ several nested containers jf concrete and steel and / or lead .naoh dor Patonrban "■■ % , each with a lid are closed, with the one containing the mold, % inner tight steel or cast iron container in one is arranged cup-shaped Betonabschirmbehälter and fixed in it by a container opening to the concrete casting filling pure% sponding, characterized gekennzeich- | i net that the whole, with one in the pouring filling p anchored in the area (9) of the concrete tank opening |: Cross member (6) with attached to it and from the Container (5) protruding eyelet (lo) encapsulated Be container assembly is introduced into an additional concrete shield (11), which consists of a bottom (17) .. and a cover (14) with interposed, stacked and uniform ring-shaped concrete modules (16) consists without cladding, which is secured against displacement without special sealing, are placed on top of one another and that between the encapsulated container wall (5) and the additional shield (11) an air gap (13) is present. 2. Container according to claim 1, characterized in that the horizontal parting lines are set off like a collar • · It · · are and are designed as ventilation slots (15). 3. Container according to claim 1 or claim 2, characterized in that that the elements or concrete modules (16) with the cover (14) and the bottom part (17) by means such as tie rods (19) or the like are held together lengthways. 4. Container according to claim 1 to 3, characterized in that the concrete modules (16) or elements of the additional Concrete shielding (11) are designed as uniform parts interchangeable with one another. 5. Container according to claim 1 to 4, characterized in that in addition in the bottom (17) or cover (14) a angled vent opening (12) is present. 6. Container according to Claims 1 to 5, characterized in that the casting filling (8) consists of a highly thermally conductive Potting compound, such as bearing metal based on copper, tin alloys or the like.