DE1154921B - Radiation protection wall and procedure for pretreating building blocks for it - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 37 a 7/01

INTERNATIONAL KL.

E 04b; B 63h

D 26349 V / 37a

REGISTRATION DATE: AU G U S T 1957

NOTICE THE REGISTRATION AND ISSUE OF THE EDITORIAL: SEPTEMBER 26, 1963

The invention relates as an addition to the invention according to patent 1057 770 to a Radiation protection wall at least partly made of basalt, gabbro or diabase. This affects the Invention a particularly advantageous and at the same time economical embodiment of the radiation protection wall and a method for pretreating building blocks therefor.

The radiation protection walls known to date have a heating effect when they are exposed to radiation experienced the disadvantage that they must have a special heat shield because the actual Radiation protection materials cannot withstand the temperatures they would otherwise assume, without being damaged. Radiation protection walls according to the main patent usually have these disadvantages not on, but radiation protection walls that are only built according to the teachings of the main patent are still too expensive compared to the proposal of the present invention. This is particularly the case with reactors for energy production, which in contrast to smaller breeder reactors at least in part of the the side of the radiation protection wall facing the reactor core allows temperatures to arise that are above 100 ° C and are often even higher. The modern development of reactors for power generation even reveals that thermal economic needs regarding conversion the heat generated in the reactor into usable energy, e.g. B. in electricity, more and more lead to reactor types which operate at the highest possible temperatures of the reactor core be, d. H. at temperatures that are several to many hundreds of degrees above 100 ° C. For Such reactors with very strong heat generation are the radiation protection walls known up to now so still disadvantageous. The invention is based on this disadvantage to overcome.

According to the invention, the object is achieved in that the basalt according to the main patent, Gabbro or diabase existing radiation protection wall measured from the irradiated side at least in such depth consists of building blocks made of basalt, gabbro or diabase, up to which - z. B. as a result of radiation absorption - Temperatures above 100 ° C of the radiation protection wall occur.

If it is not made of heat-resistant stone, the radiation protection wall is also expediently made of stone with a water content of more than 0.5%, because this water content does not cause cracks in the radiation protection wall ^{where the temperatures are below 100 ° C}

and methods of pretreatment

of building blocks for this

Addendum to patent 1057 770

Applicant:

Dolerit Basalt Aktiengesellschaft,
Cologne, Mittelstr. 20-24

Werner Gottschalk, Cologne-Marienburg,
has been named as the inventor

of the star and is desirable as a good neutron catcher.
Further features of the invention relate to methods for producing particularly heat-resistant building blocks from basalt, gabbro or diabase. Typically, diabase with a water content of less than 0.5% can withstand temperatures of up to 300 ° C and more, while basalt can usually withstand temperatures up to around 250 ° C.

Reactors that are equipped with a radiation protection wall according to the invention are lighter and cheaper than the known reactors because the additional heat protection made of steel that was previously necessary is no longer necessary. When using the radiation protection wall according to the invention, the reactors can also be operated at those high temperatures which are aimed for for thermal reasons, but which have so far not been economically feasible because of the unacceptably high costs for thermal protection. In particular, the reactors for mobile systems, e.g. B. ships, vehicles or the like., Can only be formed by using the radiation protection wall according to the invention so that they are light, space-saving and cheap, technically better because of the higher permissible operating temperatures, so overall more economical.
Some exemplary embodiments of the invention are described in more detail with reference to drawings.

1 shows a nuclear reactor with a radiation protection wall according to the invention in section; is there

309 689/30

the reactor core is only shown schematically, omitting the other associated facilities, than it is necessary to understand the invention,

Fig. 2 shows in the diagram an example of the temperature distribution in the radiation protection wall according to Fig. 1;

FIG. 3 shows a perspective view of a detail from a radiation protection wall according to FIG. 1, and

Fig. 4 shows schematically a continuous furnace for using the method according to the invention for Manufacture of building blocks that are sure to be highly heat-resistant.

In Fig. 1, 1 denotes the reactor core, which can be of any design and in which one of the known nuclear reactions takes place in a known manner and is controlled and economically used via suitable systems, which are not shown in FIG. 1. The harmful rays radiating outwards from the reactor core 1 are rendered harmless in the radiation protection wall 2, 3. The wall part 2 on the inside of the reactor, ie towards the reactor core 1, consists of basalt, gabbro or diabase and is therefore heat-resistant up to well over 100.degree. Natural stone or artificial stone can be used for this. The outer wall part 3 consists of another radiation protection material, e.g. B. barite concrete. Fig. 2 shows the temperature distribution in the radiation protection wall. From Figs. 1 and 2 it can be seen that the radiation protection wall is measured in such a depth of refractory stone 1 from the reactor core forth, until the reactor occur when operating temperatures above 100 ^ö C. jStraMenschutzwand 2, 3. The heat-resistant wall part 2 does not suffer any cracks during operation of the reactor. The wall part 3 made of barite concrete also does not suffer any cracks because it is not ^{heated above 100 °} C., so that the water contained in it not only cannot cause any damage, but is also effective as a desired neutron catcher. It is advantageous if the water content is greater than 0.5%.

3 shows that the heat-resistant wall part 2 has been made from building blocks 4. The direction of the incidence of rays is indicated by an arrow.

The building blocks are expediently manufactured according to claim 7 of the main patent in such a way that that larger stone blocks by blasting or the like. Are broken in the quarry, but the Use of mechanical striking tools, e.g. hammers, chopping, pneumatic hammers, etc., is avoided.

The best results can be achieved using building blocks made from basalt rock, the is composed according to claim 6 of the main patent.

If the operating temperatures of a reactor are so that temperatures in the radiation protection wall above 250 or 300 ° C, building blocks are used according to the invention, which one Have been exposed to temperatures of at least about 400 ° C. This is recommended for security reasons even if diabase is used, which itself can withstand temperatures above 300 ° C, if its water content is below 0.5%.

A continuous furnace designed according to FIG. 4 is expediently used for this pretreatment of the building blocks 5. The furnace has an inlet opening 6 and an outlet opening 7. The furnace 5 runs in Conveyor belt 8 through it, which protrudes from the inlet opening 6 and the outlet opening 7. Of the Oven 5 is in the direction of the conveyor belt movement in several chambers or heating zones 9 to 13 divided. In the chambers 9 to 13 there are heating elements 14 to 18, which each chamber on heat up to a higher temperature than that of the previous chamber. The last chamber has one Temperature of about 400 ° C. The length of the chambers measured in the direction of the conveyor belt movement 9 to 13 each corresponds to the time for which a building block 4 is the temperature of a specific chamber should be exposed. It is advantageous to choose the arrangement so that the building blocks by minute to be heated by about 10 ° C until it reaches a temperature of about 400 ° C to have. The stones are then kept at this temperature for about 30 minutes. For this Grande, the chamber 13 in FIG. 4 is longer than the preceding chambers 9 to 12. However the number and length of the chambers do not correspond to the advantageous ones mentioned above Data, otherwise the drawing would be confusing.

The broken and mechanically processed building blocks 4 are placed on the inlet opening 6 Conveyor belt 8 is placed and on this conveyor belt 8, which is driven by the motor 19 via the transmission 20 is driven, passed through the continuous furnace 5. After leaving the outlet opening 7 one lets the building blocks 4 slowly cool down, for which purpose a device similar to that under certain circumstances Continuous furnace can be provided.

Such building blocks 4, which show cracks when leaving the outlet opening 7 or after cooling, what z. B. can be determined by a simple sound test, are sorted out and can be used as Scrap cannot be built into the radiation protection wall according to the invention. Those stones 4 that do not have to be sorted out for this reason, can be used for radiation protection. at These stones are guaranteed that they will work even with long-term high thermal loads show no cracks.

Whether the above-described heat treatment is used for those blocks that are after already mentioned method according to claim 7 of the main patent with special technical care broken and machined, or in the case of building blocks, which have been made according to the previously usual process broken and worked is in itself indifferent. However, the reject is broken at usual and processed building blocks much larger, because all the building blocks that have already broken or broken contain cracks during machining, cracks during heat treatment. It is therefore more economical breaking and processing according to the main patent.

In any case, it has been shown that those stones which leave the furnace S without cracks or cracks, even later, when the reactor is heated, no more cracks appear. The special one The importance of heat pretreatment becomes clear when one looks at what is unknown in the prior art and takes into account the tremendous difficulties, costs and dangers that arise when doing so in the case of an operating reactor

shows that the radiation protection wall or a building block of the same shows a crack.

According to the invention, radiation protection walls can thus be produced in which a special and there is no need for expensive thermal protection in addition to biological protection.

Claims (4)

PATENT CLAIMS: 1. Radiation protection wall, according to patent 1,057,770 at least partially consisting of basalt, gabbro or diabase, characterized in that it consists of building blocks of basalt, gabbro or diabase, measured from the irradiated side, at least to such a depth as to which - z . B. as a result of radiation absorption - temperatures above 100 ° C occur in the radiation protection wall. 2. Radiation protection wall according to spoke 1, characterized in that it, insofar as it does not consists of basalt, gabbro or diabase, stone with a water content of more than 0.5% consists. 3. Radiation protection wall according to claim 1 or 2, characterized by the use of building blocks, that have been exposed to a temperature of at least about 400 ° C. 4. A method for pretreating building blocks according to claim 3, characterized in that that the building blocks slowly heated to at least 400 ° C, then about 30 minutes on this Maintained temperature and then slowly cooled. Considered publications:
Nuclear Engineering, 1956, p. 270. For this purpose, 1 sheet of drawings © 309 689/30 9.63