DE3119641A1 - Ceramic building material having neutron-absorbing properties and use thereof - Google Patents

Abstract

A ceramic building material, which absorbs both thermal and epithermal neutrons even at elevated temperatures, is composed of a thermal-neutron-absorbing base material and 5 to 50 % by weight, based on the total weight of the building material, of at least one hydride, distributed therein, of zirconium, yttrium and/or of at least one of the rare earth elements and, if required, binders, and conventional fillers and auxiliaries.

Description

Ceramic building material with new

Tronen absorbent properties and its use The invention relates to a ceramic building material with neutron absorbing properties, which can be used as shielding material for nuclear power plants.

Ceramic building materials for the absorption of neutrons with low Energy, so-called thermal neutrons, are known. Such ceramic building materials contain known neutron absorbers with high neutron capture cross-sections, such as for example compounds of boron, cadmium, samarium, europium or gadolinium.

Such ceramic building materials have the disadvantage that they contain neutrons with a higher energy content (above 1000 eV) so-called epithermal neutrons, practically does not absorb. But since when operating nuclear power plants, but also bc in the operation of other systems in which high-energy particles or rays occur, thermal as well as epithermal neutrons occur, one was already in the past forced to construct bulkheads and shields that absorb both types of neutrons.

For this purpose, one currently uses a protective screen, the one Contains substance which reduces the rapid epithermal neutrons to a lower level Energy level slows down ..

The obtained in this way are then passed through a second protective screen thermal neutrons by known neutron absorbers, such as boron, absorbed. Attempts have also been made to use neutron absorbers for thermal neutrons to mix in a substance that slows down the epithermal neutrons.

As substances that retard epithermal neutrons to make them through neutron absorbers It is known to have compounds to make them absorbable for thermal neutrons of hydrogen, such as water, paraffin or water-containing materials such as cement, Concrete, etc., is used. However, such substances are only temperature resistant to a limited extent. Hydrocarbons such as paraffin decompose a little above 2000 C if they do then have not already been distilled off, water is distilled off at 1000 C, and also all minerals and building materials containing crystalline water give their water at the latest at 250 to 3000 C completely.

In addition, these substances all more or less quickly and intensive through ionizing radiation, as it occurs in a nuclear power plant, split and develop hydrogen, which mixes with oxygen and yields explosive oxyhydrogen.

The object on which the invention is based thus consisted in producing building materials to get that even at elevated temperatures, such as above 2500 C, in particular Above 3000 C, absorb both thermal and epithermal neutrons and can therefore be used as a uniform shielding material.

The ceramic building materials according to the invention with absorbing neutrons Properties are characterized in that they consist of a thermal neutron absorbent base material and 5 to 50% by weight, based on the total weight of the building material, at least one zirconium, yttrium and / or hydride distributed therein at least one element of the rare earths and optionally binding agents, common fillers and auxiliaries.

If ceramic building materials are mentioned here, it can be on the one hand plastic ceramic masses, such as water-containing ramming masses, and on the other hand to moldings made from such plastic masses in dried form Act. Such moldings can, for example, bricks, pipes or anything be molded parts that are dimensionally stable and normal strength requirements suffice and can also be burned.

The mentioned hydrides of zirconium, yttrium and the rare earths are excellent at decelerating epithermal neutrons, by themselves. at temperatures above 3000 C, since they are stable at these temperatures or only slowly begin to decompose.

For example, non-stoichiometric zirconium hydride starts at normal conditions only slowly above 3000 C; to give up its hydrogen to a limited extent and thereby to form metallic zirconium. Under hydrogen pressure it is even possible that the zirconium oxide still contains the hydrogen bonded at 5000 C. Something similar is to say about the hydrides of yttrium.

Preferred hydrides according to the invention are non-stoichiometric Hydrides of zirconium and yttrium of the formula ZrHx or YHX, where x is between 1.3 and 2 lies. The zirconium hydrides are most preferred.

Although under normal conditions zirconium hydride and yttrium hydride are present about 5500 C practically completely with the formation of metallic zirconium or yttrium decompose, it was surprisingly found that in the ceramic according to the invention Building materials these hydrides are so stable up to 5000 C and higher that they contain enough hydrogen to slow down epithermal neutrons sufficiently.

The ceramic building materials according to the invention expediently contain 5 to 30, preferably 10 to 25% by weight of the hydrides of zirconium and yttrium mentioned and / or rare earths, each based on the total weight of the building material.

As a thermal neutron absorbing base material, a known ceramic material used, the neutron absorber for thermal Contains neutrons. According to the invention, these are preferably boron, cadmium, europium, Gadolinium or samarium compounds alone or in conjunction with common ceramic ones Materials such as alkaline earth oxides, silicon dioxide, aluminum oxide or zirconium oxide. Examples of such thermal neutron absorbers contained in the base material Neutrons are boron oxide, boron carbide, cadmium oxide, europium oxide, or gadolinium oxide Samarium oxide and so-called boron frit. One good usable basic material consists of a ceramic mass made of boron oxide and alkaline earth oxides and / or SiO2.

Particularly useful base materials in which the hydrides mentioned are incorporated are obtained as follows. 40 to 50% by weight magnesium oxide become a plastic mass with 50 to 60% by weight of boron oxide and water mixed in a kneader.

30 to 60% by weight of this mass are then mixed with 15 to 30% by weight Zircon sand and 20 to 40% by weight of high-alumina cement and sufficient water mixed up.

After drying, the mass contains about 3 to 8 weight boron. Sie can be used directly as rammed earth or processed into granules and then further used according to the invention, i.e. mixed with the hydrides mentioned will.

Provided that the base material does not set as such and is stable Forms moldings or sufficiently stable linings or the like, it is expedient to add binders customary in ceramic masses, such as, for example Water glass.

A method for producing ceramic building materials according to the invention consists of dry mixing the granulated raw materials with one another, then to mix with a mineral binder and then the mixture in the desired Form to dry at elevated temperature, such as between 100 and 3000 C, whereby mechanical strength is achieved.

Europium, gadolinium or samarium hydride can be both epithermal Neutron absorbing material as well as thermal neutron absorbing Substance can be used in the base material. For example, europium hydride could be used alone or in a mixture with other substances, such as silica or aluminum oxide, by mixing be processed with water glass to the ceramic building materials according to the invention.

The ceramic building materials according to the invention have the advantage that they slow down epithermal neutrons due to the hydride content and in the thermal Then absorb the neutron absorbing base material. They practice this function even at relatively high temperatures, such as up to 5000 C, and are therefore the first High temperature materials for complete absorption of neutrons over the entire Energy range.

As mentioned, they can be used as plastic ramming masses, as dried ones or obtained and used as fired ceramic moldings.

The following examples serve to further illustrate the invention.

Example 1 75 g boron carbide, 25 g zirconium hydride and 50 g high alumina cement were dry mixed together. A plasticizer was then added, respectively based on the total amount of the above ingredients, from 7% Tylose, 16% water, 2 % Paraffin oil and 2 tons of pesticide added. The whole thing was mixed for 15 minutes, Pressing granules were produced by sieving, from which moldings were then pressed and dried. These were dried at 350 "C and some at 5000 Burned C. Stable ceramic stones with good mechanical resistance were obtained and excellent neutron absorption at temperatures up to at least 5000 C.

Example 2 For the production of granules from magnesium oxide and Boric acid became 43% by weight magnesium oxide and 57% by weight boric acid in one Mixer dry mixed together for 5 minutes. Then 18% water was added, the whole was further mixed for 15 minutes, dried, calcined at 12,600 ° C. and granulated.

To 225 g of these fired granules, 25 g of zirconium hydride, 125 g high-alumina cement was added, the whole was dry-mixed. Then were 90 cm3 of water are added and mixed with the other ingredients. The crowd were shaken in molds and dried at room temperature.

Example 3 To produce a ramming mass, 43% by weight Magnesium oxide and 57% by weight boric acid at 20% by weight, based on these solids, mixed with water in a kneader, whereupon left to stand overnight, through a Sieved a 2.5 mm sieve and let it dry.

500 g of this mixture were mixed with 100 g of zirconium sand and 300 g of high-alumina cement dry mixed, then 270 cc of water was added, followed by another 15 minutes was mixed. In the dried state, this mass contained about 4.9% by weight Boron and had a density of 1.80.

225 g of this moist rammed earth were mixed with 25 g of zirconium hydride, ZrH , where x was between 1.5 and 2, and 125 g of high-alumina cement mixed. the The plastic mass obtained in this way was used directly as a ramming mass.

Example 4 225 g of the ramming mass used in Example 3 were obtained mixed with 25 g of zirconium hydride, 125 g of HB acid cement and 125 g of water glass, to form moldings pressed and dried.

Example 5 50 g boron carbide, 50 g yttrium hydride and 50 g high alumina cement were dry mixed with one another and then as in Example 1 to form moldings processed.

Example 6 225 g of the ramming mass mentioned in Example 3 were added 25 g of yttrium hydride YHX, where x was between 1.3 and 2, and 125 g of high-alumina cement thoroughly mixed. The mixture was used as such as a ramming mass.

Claims (9)

Ceramic building material with neutron absorbing properties and its use claims Ceramic building material with absorbing neutrons Properties, characterized in that it consists of a thermal neutron absorbing Base material and 5 bis 50% by weight, based on the total weight of the building material, at least one zirconium, yttrium and / or hydride distributed therein at least one element of the rare earths and optionally binding agents, usual fillers and auxiliaries. 2. Ceramic building material according to claim 1, characterized in that it contains zirconium hydride of the general formula ZrHx, where x is between 1.3 and 2 lies. 3. Ceramic building material according to claim 1, characterized in that it contains yttrium hydride of the general formula flx, where x is between 1.3 and 2 lies. 4. Ceramic building material according to claim 1 to 3, characterized in that that it is the hydride of zirconium, yttrium and / or at least one rare element Earth in an amount of 5 to 30, preferably 10 to 25% by weight, based on the total weight of the building material. 5. Ceramic building material according to claim 1 to 4, characterized in that that it is a ceramic material as a thermal neutron absorbing base material contains, the at least one boron, cadmium, europium, gadolinium and / or samarium compound contains. 6. Ceramic building material according to claim 5, characterized in that he made a ceramic mass as a thermal neutron absorbing base material Contains boron oxide and alkaline earth oxides and / or silicon dioxide. 7. Ceramic building material according to claim 1 to 4, characterized in that that it is a ceramic material as a thermal neutron absorbing base material from 12 to 30% by weight magnesium oxide, 15 to 36% by weight boron oxide or boric acid, 15 to 30% by weight zircon sand, 20 to 40% by weight high-alumina cement and sufficient Contains water for a workable consistency. 8. Ceramic building material according to claim 1 to 7, characterized in that that it contains water glass as a binder. 9. Use of a ceramic building material according to claim 1 to 8 as Shielding of nuclear power plants.