FI66095C - SAETT ATT I CEMENT BAEDDA IN BORSYRA ELLER BORATHALTIGT RADIOACTIVE AVFALL - Google Patents

Description

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Sweden-Sweden (SE) 7707770-9 (71) Aktiebolaget Asea-Atom, Box 53, 721 0A Västeräs 1, Sweden-Sverige (SE) (72) Hans Christensen, Västeräs, Sweden-Sverige (SE) (7 * 0 Berggren Oy Ab (5 * 0 Method for incorporating radioactive waste containing boron acid or borate into cement - Sätt att i cement bädda in borsyra eller borathaltlgt radioactive waste

In pressurized water reactors, boric acid or borate and primary circuits are normally added to control reactor power. The addition is based on the fact that boron acts as an absorber of neutrons. Power control is accomplished by increasing or decreasing the boric acid or borate content with one or more ion exchange masses connected to the primary circuit to which the boron-containing compounds can be adsorbed or desorbed. After some time of use, the used ion exchange masses must be replaced with new ion exchange masses. Spent boron and radioactive ion exchange masses must be treated as radioactive waste and stored under safe conditions. Similarly, radioactive material from boric acid or borate-containing pressurized water reactors by evaporation of concentrated material must be treated as radioactive waste.

One common way to treat boron- and borate-free ion exchange masses and, respectively, boric acid- and borate-free evaporation concentrates, which are strongly aqueous, is to mix them with cement in storage tanks, e.g. concrete molds or sheet metal containers. In this case, the cement solidifies by absorbing water. If this method is used for boric acid and borate-containing ion exchange masses or evaporation concentrates, it has been shown that the cement does not solidify into a durable product.

According to the present invention, it has proved possible to incorporate boric acid or borate-containing radioactive waste into the cement so that a very strong body is formed. According to the invention, this is achieved by treating the waste before mixing with the cement with a substance which neutralizes the retarding effect of boric acid and borates on the solidification of the cement.

More specifically, the present invention relates to a method for incorporating boric acid or borate-containing radioactive waste into cement, mixing the waste with the cement and solidifying the mixture in a tank, e.g. consists of an alkaline earth metal halide, an alkali metal fluoride or a polyvalent organic hydroxyl compound. This substance must be sufficiently soluble in water to react rapidly and effectively with boric acid or borate, and should preferably have a water solubility of at least 100 g per liter of water at room temperature. If the boric acid or borate is present adsorbed on the ion exchanger, it is preferable that the substance is further dissociated into ions in order to elute the boric acid or borate adsorbed on the anion exchanger efficiently. The anion of the substance must then have a higher affinity for the anion exchanger than that of boric acid or borate.

Said substance may preferably be calcium chloride, potassium fluoride or mannitol.

The substance is preferably added in solid form if the radioactive substance is aqueous, as is normally the case for ion exchange masses and evaporation concentrates.

The amount of substance added is preferably at least approximately stoichiometric with respect to the amount of boric acid or borate li 3 6 5095. At least excesses up to about 25% have no negative effect. If boric acid or borate is adsorbed to an ion exchanger having both an anionic moiety and a cationic moiety, the substance must be further added in an amount corresponding to any amount adsorbed by the cationic moiety.

Of these substances, alkaline earth metal chlorides give difficult to dissolve borates in the treatment of boric acid or borate-containing radioactive waste, alkali metal fluorides give sparingly soluble alkali metal fluoroborates and polyvalent hydroxyl compounds give didiol complexes.

Prior to mixing the treated radioactive waste with the cement, the pH is adjusted to about 11, and in other cases about 8 or more, preferably using alkaline earth metal chlorides.

A mixture of radioactive waste and cement is more suitably incorporated in a known manner with a water-sealing agent which prevents the transport of water within the solidified cement body. Examples of such substances are water glass, polymeric substances with the ability to prevent water from penetrating radioactive waste, and metal soaps of higher fatty acids. The amount of water-sealing agent is more suitably about 1 to 20 parts by weight per 100 parts by weight of cement.

The invention is further described in the following examples. Example 1

Styrene-divinylbenzine-type ion exchange pulp containing granules containing sulfonic acid groups and granules containing quaternary ammonium groups and used in the primary circuit of a pressurized water reactor in which it has absorbed 12% by weight of boric acid and sodium borates so that their concentration , contains 35% by weight of dry matter and 65% by weight of water. To 1000 parts by weight of this ion exchange mass is added 125 parts by weight of powdered calcium chloride. After mixing both components, the pH is raised to about 11 by the addition of sodium hydroxide. The mixture thus obtained, comprising about 1125 parts by weight, is mixed with 1600 parts by weight of cement and further with 32 parts by weight of water glass, the latter containing equal parts of silicate and water and forming water. relative to the sealing addition to the cement. After a few days, the mass has solidified and then remains intact.

The above-mentioned ion exchange mass has an equivalent ratio between the cation part and the anion part of 1: 1. About 35 parts by weight of calcium chloride is adsorbed on the ion exchange mass, the remaining part being sufficient for the reaction with boric acid and borates.

Example 2 1000 parts by weight of the same type of ion exchange compound as in Example 1 are mixed with 460 parts by weight of potassium fluoride powder, the pH of which will be about 8. After mixing the components, 1300 parts by weight of cement and a further 26 parts by weight of water sealant are added to the resulting mixture. formed by Silix GP (Ingenjörsfirman Per Engvall, Sweden). As in the previous case, a solidified durable product is obtained.

About 35% by weight of potassium fluoride is adsorbed on the ion exchange pulp, the remainder being sufficient for reaction with boric acid and borates.

Example 3 1000 parts by weight of an evaporation concentrate consisting of an aqueous solution containing 12% by weight of boric acid are mixed with 710 parts by weight of powdered mannitol. The pH is adjusted to 8 with sodium hydroxide. The mixture of about 1710 parts by weight is mixed with 2200 parts by weight of cement and further with 40 parts by weight of water glass consisting of equal parts of silicate and water. As in the previous case, a solidified product is obtained which is durable.

Example 4

A styrene-divinylbenzene-type ion-exchange mass containing granules containing quaternary ammonium groups and used in the primary circuit of a pressurized water reactor in which it has adsorbed boric acid and sodium borates to a content of 35% by weight, based on boric acid, and 14% by weight, substance and 65% by weight of water. To 1000 parts by weight of this ion exchange mass is added 130 parts by weight of powdered 63095 calcium chloride. After mixing the components, the pH is raised to about 11 by the addition of sodium hydroxide. The mixture thus obtained, which contains about 1130 parts by weight, is mixed with 1600 parts by weight of cement and further with 32 parts by weight of water glass, which consists of equal parts of silicate and water and acts as a water-sealing addition to the cement. After a few days, the mass has solidified and then remains intact.

Since the ion exchange mass has no cationic moiety, all of the calcium chloride is used for the reaction with boric acid and borates.

Claims (3)

1. The provisions of the cement tank in boron-containing radioactive waste, which may be mixed with cement and bleaching brakes, are also used, but also in concrete form, and in the case of radioactive waste, and the cement is treated with or in the form of a boron-resorient borate, and the water is a complex or complex compound and preferably an alkali metal halide, an alkane-metal fluoride or an organic hydroxyl fluoride. A method for incorporating radioactive waste containing boric acid or borate into cement, wherein the waste is mixed with cement and the mixture is solidified in a tank, e.g. concrete coil, characterized in that the radioactive waste is mixed with or a complexed compound, and consists of an alkaline earth metal halide, an alkali metal fluoride, or a polyvalent organic hydroxyl compound. 2. The composition according to claim 1, which comprises a temperature of at least 100 g per liter of wattage. Process according to Claim 1, characterized in that the solubility of the substance in water at room temperature is at least 100 g per liter of water. Process according to Claim 1 or 2, characterized in that calcium chloride is used as the alkaline earth metal halide. Process according to Claim 1 or 2, characterized in that potassium fluoride is used as the alkali metal fluoride. Process according to Claim 1 or 2, characterized in that mannitol is used as the polyvalent organic hydroxyl compound. 3. A composition according to claims 1 or 2, which comprises a solution of calcium alkali metal halides in calcium chloride.