EP1891191A1 - Fast-dissolving bentonite granulate - Google Patents

Abstract

A process is disclosed for preparing fast-dissolving bentonite granulates, as well as a bentonite granulate prepared by this process. To prepare the bentonite granulate, an overactivated bentonite overactivated with at least 110 % of its cation exchange capacity with alkali metal ions is preferably used as starting material, and is preferably granulated with a water glass solution having a SiO<SUB>2</SUB>:X<SUB>2</SUB>O modulus of more than 3.2, X being selected from sodium and potassium.

Description

 QUICKLY CRUMPING BENTON I TGRANULATE

The invention relates to a process for the production of rapidly disintegrating bentonite granules and bentonite granules which can be obtained by this process.

Detergent formulations use bentonites to create a built-in soft-grip effect. These bentonites have a high swelling capacity, especially when activated as sodium bentonite. In the application, however, difficulties arise because on the surface of the bentonite particles on contact with water rapidly forms a gel layer, which hinders the further access of water. After a rapid initial formation of the gel layer, therefore, the decay of the bentonite granules slows down in the water, because the core of the particles remains stable for a long time and is only very slowly swollen by the penetrating water and thus decays. Ultimately, this means that a significant portion of the bentonite granules is discharged with the wash liquor or that larger bentonite particles remain on the fibers of the washed fabrics. In both cases, therefore, go considerable Shares of bentonite used lost and can not contribute to the soft grip effect.

Highly swelling bentonites can also potentially be used in detergent tablets, where they can also act as tablet disintegrants. However, this is only possible if the disintegration of the bentonite particles takes place rapidly. Detergent tablets have even higher requirements for disintegration compared to normal powder detergents to ensure that no coarser particles remain on the washed laundry. So here it is particularly important that the detergent tablets disintegrate as quickly as possible in the wash liquor.

In EP 1 102 729 B1, the problem of defective disintegration of the bentonite granules is attempted to be solved by reducing the swelling capacity of the bentonite granules without disturbing the disintegration of the bentonite into individual lamellae, so that the bentonite present in the wash liquor is dissolved in the leachate considerable extent to the formation of a soft grip effect is available. In the process, a bentonite having a montmorillonite content of at least 85% by weight is first dried to a moisture content of from 25 to 35% by weight. The dried bentonite is then comminuted and processed by adding water to an extrudable paste having a moisture content of 25 to 40 wt .-%. This paste is then extruded through a 4 to 10 mm diameter orifice and the extrudate is dried to a moisture content of 10 to 14% by weight. After drying, the extrudates are calcined at 120 to 250 ⁰ C until they have an ignition loss of less than 4% at 190 ⁰ C. The bentonite extrudates are then comminuted again. For the production of this bentonite with a low swelling capacity, a bentonite is already used as starting material, which after activation with sodium ions in contact with water only in relative moderately small extent swells or shows only a slight tendency to form a gel.

No. 4,746,445 describes bentonite agglomerates which are prepared by spraying finely divided bentonite with sodium silicate as binder. The agglomerates contain 1 to 5% binder. Although they have a different bulk density, the agglomerates do not separate from the other detergent ingredients after incorporation into detergent powder because they have an irregular surface. The agglomerates have an increased stability, so that they do not disintegrate in the further production steps of the detergent production. Nevertheless, they dissolve easily on contact with water. For the production of the bentonite agglomerates, a clay is used which has large proportions of montmorillonite. Particular preference is given to using a sodium bentonite. This can be obtained from natural sources, such as a Wyoming or Western bentonite. However, it is also possible to use a calcium bentonite which has been activated with alkali compounds, such as sodium carbonate. The Na ₂ O content of the agglomerates should be at least 0.5%, preferably at least 1%, particularly preferably at least 2%. For binding the bentonite agglomerates, a water glass with a Na ₂ OiSiO ₂ module of 1: 1.6 to 1: 3.2, preferably 1: 2 to 1: 2.8 or 1: 3.0 is used. The bentonite agglomerates are prepared by spraying an aqueous solution of the binder onto finely divided bentonite while it is being agitated. In the examples, the binder used is a water glass solution having a solids content of 7% and a Na ₂ OiSiO ₂ module of about 1: 2.4. Furthermore, it is described that when using water glass solutions with another module Na ₂ O: SiO ₂ , which is chosen within a range of 1: 2 to 1: 3, a good agglomeration can be achieved, non-dusting agglomerates are obtained. Similar bentonite agglomerates are described in US 4,767,546, US 4,851,137, and US 4,488,972, the examples are each selected identically. The bentonite agglomerates contain 1 to 5% sodium silicate as binder. To produce the agglomerates, a water glass solution having a solids content of from 2 to 4% by weight and a modulus of Na ₂ OrSiO _{2 of} from 1: 2 to 1: 3 is used in each case. The content of sodium oxide in the bentonite can be selected in the range of 0.5 to 10 wt .-%. However, detailed data is not executed in the examples. Here in each case commercially available sodium bentonites are used. However, exact details of the degree of activation are missing.

In DE 33 11 568 C2, a particulate and softening coarse detergent for textiles is described which contains, inter alia, sodium bentonite. The sodium bentonite is present as an agglomerate of smaller particles of ground sodium bentonite from which the concomitant grus has been removed after milling and before agglomeration. The bentonite agglomerates are coated with a silicate or partially coated to prevent the bentonite agglomerates from sticking to surfaces. The agglomeration of the bentonite takes place with the addition of dilute sodium silicate solution. In the example Bentonitte ^' ilchen are described which from 82.3 parts by weight of anhydrous bentonite, 16.1 parts by weight of water, 1.5 parts by weight of sodium silicate and 0.06 parts by weight of a blue dye, the is applied to the surface of the particles exist. The bentonite used is a sodium carbonate-treated bentonite which, after the sodium carbonate treatment, is freed of its coagulum parts by centrifuging.

US 4,699,729 describes a process for preparing a detergent composition which contains a small proportion of finely divided bentonite powder. The bentonite is agglomerated on the surface of a particulate granulate. meriert. The binder used is a sodium silicate solution which has a modulus Na ₂ O = SiO ₂ of 1: 2.4. Generally, sodium silicate solutions having a modulus of Na ₂ OiSiO _{2 of} from 1: 1.6 to 1: 3.2, preferably 1: 2 to 1: 3, more preferably 1: 2.35 or 1: 2.4, may be used.

As bentonite sodium bentonite is preferably used, wherein both a natural sodium bentonite as well as a Na ₂ CO ₃ activated calcium bentonite can be used. Typically, the bentonite has a content of Na ₂ O of 0.8 to 2.8%.

In US 4,609,473 agglomerates of bentonite and sodium sulfate are described which textiles can give a soft touch effect. The agglomerates are prepared by agglomerating the finely divided bentonite and the sodium sulfate with the aid of a binder. In the simplest case, moisture can be used for this purpose. However, it is also possible to use sodium silicate as an inorganic binder, but more accurate values for amount and modulus are not specified. As bentonite, preferably natural sodium bentonites are used. It is also possible to use calcium bentonites which have been activated with sodium carbonate. In Example 1, an agglomerate of finely divided sodium bentonite and sodium sulfate is prepared using water as the binder. If the resulting agglomerates are compared in their softening properties with agglomerates obtained by agglomeration of the same bentonite with dilute sodium silicate solution, the agglomerates described first have much better properties.

In DE 39 42 066 Al a process for the preparation of a granular, avivierend acting detergent additive is described. The detergent additive contains (A) from 30 to 90% by weight of a layered silicate, (B) from 1 to 40% by weight of finely crystalline, synthetic see zeolite NaA, (C) 0 to 30 wt .-% of water-soluble salts from the class of sulfates, carbonates, silicates and phosphates of sodium or potassium, and (D) the rest to 100 wt .-% water. Preferably, however, the detergent additives are free of phosphates and alkali silicates. Preferred components of group (C) are sodium sulfate and sodium carbonate, both of which are used as anhydrous salts individually or in admixture. The components are dry blended, then mixed with an aqueous component containing a portion of the zeolite. Granulate formation thus takes place without the addition of water glass.

DE 34 19 571 describes a textile softening mixture which can be used as an additive to a particulate detergent. The softener mixture contains discrete softening particles containing at least about 75% by weight of a smectite-type clay and less than about 5% by weight of anionic, nonionic, ampholytic, and zwitterionic surfactants. The plasticizer particles are prepared by spraying the smectite clay with a solution containing a quaternary ammonium compound. Since there is no exchange reaction with the clay, as long as the ammonium compound is adsorbed only on the surface of the clay, the amount of the ammonium compound can be remarkably reduced. The clays used are preferably sodium benzonites. However, it is also possible to use calcium bentonites which have been activated by treatment with sodium carbonate. The plasticizer particles may optionally contain, in addition to the smectite-type clay, substances which soften the desired fabric or do not adversely affect washing, examples of suitable materials being binder or agglomerating agents, e.g. For example sodium silicate. A suitable sodium silicate has a module Na ₂ O: SiO ₂ of, for example, 1: 2.4. EP 0 387 426 A2 describes a detergent additive for producing a soft-grip effect which contains a natural hectorite of specific composition. The agglomeration of the natural hectorite is carried out in Example 1 with water as the agglomerating agent. The wet agglomerates are dried and sieved to the desired particle size.

In DE 42 43 389 Al a process for the preparation of sorbents is described, which are used for example as animal litter. For this purpose, a weakly swelling bentonite, preferably a calcium bentonite, with a Montmorrilonitgehalt of about 40 to 65 wt .-% with a basic reacting alkali metal compound homogenized by intimate kneading and transferred under ion exchange in a swellable bentonite. The alkali metal compound, preferably the corresponding sodium compound, is used in an amount of from 0.1 to 1.5% by weight, preferably from 0.25 to 1.5% by weight, based on the dried crude bentonite. In the examples, as the alkali metal compound, among others, a water glass solution is used. The added amounts correspond to a Na ₂ O content of 0.5%, 1.0% and 1.5%. In this process, however, the crude calcium bentonite is not first activated with an alkali metal compound, and then the activated bentonite is granulated.

The use of water glass as a binder for the production of bentonite agglomerates, as are customary in detergent additives, has been known for some time. Usually, water glasses with a Na ₂ OiSiO ₂ module of about 2.4 are used. The water glasses must be strongly alkaline to prevent premature polymerization of the water glass. This would lead to a solidification of the granules and thus to a poor disintegration in the wash liquor. The bentonite granules become detergent compositions further processed, for which the bentonite granules must first be packaged after production and then, for example, transported to the detergent producer. In the process, workers come into contact with the bentonite granules or the dust they produce. Because of the highly alkaline properties of the water glass, especially when used in higher amounts, the bentonite granules are irritating, ie when handling the bentonite granules appropriate safety precautions must be taken.

The invention was based on the object to provide a process for the production of bentonite granules are available, which are obtained with which bentonite granules that can be handled without major safety precautions. The granules should be able to be stored for a long time and show rapid disintegration in the wash liquor.

The object is achieved by a method having the feature of patent claim 1. Advantageous developments of the method are the subject of the dependent claims.

Surprisingly, it has been found that when using bentonite which has been overactivated with alkali metal ions, it is possible to obtain granules which show a very rapid decomposition in water. The bentonite introduced into the water or a wash liquor can therefore dissolve completely during periods of time available in a washing machine at the end of a normal washing cycle and is therefore completely available for the production of a good softening effect when applied to textiles. The losses due to the discharge of undissolved bentonite particles with the wash water can be minimized and no residues of larger bentonite agglomerates remain on the washed textiles. The best swelling properties of bentonites in water are achieved per se with stoichiometrically activated with alkali metal ions bentonite. If the amount of alkali used to activate the bentonite is further increased, the volume of the source decreases again. Therefore, one expects the best swelling properties and thus a rapid disintegration of the granules when using a stoichiometrically activated bentonite. Surprisingly, however, it has been shown that in the granulation with waterglass, the granules containing a more than stoichiometrically activated with alkali metal ions bentonite, show a faster disintegration, than granules, which were prepared from a stoichiometrically activated bentonite.

Without wishing to be bound by this theory, the inventors believe that addition of ions beyond the amount needed for activation results in electrostatic shielding of the bentonite plate negative charges.

In the production of rapidly disintegrating bentonite granules, the procedure is such that

provided with alkali metal ions overactivated bentonite which is overactivated with at least 110% of its cation exchange capacity with alkali metal ions; and

the over-activated with alkali metal ions bentonite is granulated with a water glass solution.

By a bentonite overactivated with alkali metal ions is meant a bentonite which has been reacted with a larger amount of an alkali metal compound, for example soda or potassium oxalate, than corresponds to its cation exchange capacity. The cation exchange capacity is determined on the starting material, ie the non-activated bentonite, by first exchanging the exchangeable cations for ammonium ions and then the nitrogen content of the washed and dried bentonite is determined by elemental analysis. From the found amount of exchangeable cations then the amount of alkali metal compounds to be used can be calculated. The molar excess of the amount of alkali metal ions used amounts to at least 110%, preferably at least 120%, particularly preferably at least 140%, based on the cation exchange capacity of the bentonite. Preferably, the excess is selected in the range of 140% to 200%, more preferably in the range of 150% to 180% of the cation exchange capacity.

The activation of the bentonite used as starting material takes place in a manner known per se. The wet bentonite, which usually has a water content of 20 to 40 wt .-%, is kneaded with a suitable alkali metal compound, for example. Soda or potassium oxalate, and then dried. The resulting over-activated bentonite with alkali metal ions can optionally be ground again. Usually, the bentonite overactivated with alkali metal ions before granulation has a dry sieve residue on a sieve with a mesh size of 75 μm, preferably less than 15% of the weighed amount.

In addition to the described activation method, other conventional methods can be used. For example. the activation can also be carried out by first slurrying the bentonite used as starting material in water and then activating it by adding a solid or dissolved in water alkali metal compound. The concentration of the reaction components is chosen so that an activated with alkali metal ions bentonite is obtained, which has the required overactivation. For the granulation of the over-activated bentonite with alkali metal ions, preferably a water glass solution is used, which has a modulus SiO ₂ : Na ₂ O of more than 3.2. Preferably, the water glass solution has a modulus SiO ₂ = Na ₂ O of more than 3.3, particularly preferably a modulus in the range of 3.3 to 4.0. In the production of the granules, therefore, it is advantageous to use a water glass which has a higher modulus SiO ₂ : Na ₂ O than that of the water glasses conventionally used. This means that the alkali content of the water glass, and thus also the bentonite granules, can be significantly reduced in comparison to the previously available bentonite granules. When using a water glass with a modulus SiO ₂ : Na ₂ O of more than 3.2, the irritant effect of the granules decreases significantly, which is why the granules are easier to transport and handle. For example, the granules no longer have to be classified as "irritating". In addition to the sodium water glass solution described above, a potassium water glass solution or a sodium / potassium water glass solution having the above-mentioned modulus can be used in the same manner. The modulus here is based on potassium oxide or the mixture of potassium oxide and sodium oxide, but has the abovementioned range of values.

The granulation preferably uses a water glass solution which has a solids content of at least 10% by weight, preferably at least 15% by weight, particularly preferably at least 30% by weight, particularly preferably at least 40% by weight, particularly preferably at least 50 % By weight.

Another advantage of the use of bentonite overactivated with alkali metal ions is that very small amounts of waterglass can be used, yet granules are obtained showing on the one hand high mechanical stability and on the other hand rapid disintegration. Preferably the water glass solution is added in such an amount to the over-activated sodium bentonite that the bentonite granules at a water content of 8 wt .-% of alkali metal silicate, preferably sodium silicate, of less than 4.0 wt .-%, preferably less than 3, 5 wt .-%, particularly preferably less than 3.0 wt .-%, preferably less than 2.6 wt .-%, in particular less than 2.0 wt .-%.

Preferably, the bentonite overactivated with alkali metal ions is prepared from a bentonite having a pH of more than 7, preferably a pH of more than 8, more preferably a pH of more than 9 in an aqueous slurry containing 2% by weight of bentonite , in particular has a pH in the range of 8-10.

Preferably, the over-activated with alkali metal ions bentonite has a swelling capacity in water of at least 15 ml / 2 g. Due to the high swelling capacity of the rapid disintegration of the granules is supported. In spite of the high swelling capacity of the bentonite overactivated with alkali metal ions, no delay in the disintegration of the granules due to gelation on the bentonite grains is observed.

The over-activated alkali metal ion bentonite is preferably prepared by activation of a calcium bentonite. Common calcium bentonites can be used. Such calcium bentonites usually have cation exchange capacities in the range of 50 meq / 100 g to 120 meq / 100 g. However, it is also possible to use a sodium bentonite for overactivation.

The alkali metal ions with which the bentonite is overactivated are preferably selected from the group of sodium ions and Selected potassium ions, with sodium ions being particularly preferred.

When activated with sodium ions, the bentonite used as starting material, in particular calcium bentonite, is preferably activated with a compound from the group of sodium carbonate, sodium bicarbonate, sodium phosphate, sodium oxalate and sodium citrate. Suitable sodium phosphates are, for example, trisodium monophosphate and trisodium polyphosphate. When activated with potassium ions, the potassium compound is preferably selected from the group of potassium carbonate, potassium bicarbonate, potassium phosphate, potassium citrate and potassium oxalate. The activation of the bentonite, in particular calcium bentonite, is carried out in a conventional manner. For this purpose, the bentonite, which may have a moisture in the range of 20 to 40 wt .-%, is kneaded with the calculated amount of the alkali metal compound. Subsequently, the over-activated with alkali metal ions bentonite can be dried, ground and optionally sifted to adjust the desired grain size.

The granulation of the over-activated with alkali metal bentonite, particularly preferably sodium bentonite, takes place per se by conventional methods. For example. the waterglass solution can be sprayed onto the agitated bentonite which has been overactivated with alkali metal ions. For this purpose, for example, free-fall mixers can be used, in which a curtain of falling particles of the overactivated bentonite is formed, on which the water glass solution is then sprayed.

After granulation, the water content of the granules can be lowered, for example, by introducing heated air to the desired value. Usually, the water content of the finished bentonite granules is 6 to 14 wt .-%, preferably 7 to 12 wt .-%, particularly preferably 8 to 10 wt .-%. Preferably, however, the granulation of the over-activated alkali metal ion bentonite, in particular sodium bentonite, but in such a way that the overactivated bentonite is placed in a high-speed mixer and the water glass is added within a short period of time in its entirety. The granulation can be carried out both in a batch process and in a continuous process. For granulation in the batch process, a so-called Eirich mixer and for continuous granulation, for example, a continuously operating ploughshare mixer, as offered for example by the company Lödige, or a ring layer mixer, such as a Lödige CB mixer, can be used.

Another object of the invention is a bentonite granules, as it can be obtained, for example, with the method described above. Such Bentonitgranulat is characterized by the fact that it dissolves very quickly in water or disintegrates very quickly.

The bentonite granules according to the invention have the following properties:

a swelling volume of at least 15 ml / 2g a decomposition in water after 30 seconds of at least 80%.

The bentonite granules preferably have a decomposition in water after 90 seconds of at least 90%, particularly preferably of at least 95% and especially preferably of at least 99%.

The granulated overactivated bentonite preferably has a pH of more than 10 in an aqueous slurry containing 2% by weight of granules. The invention will be explained in more detail by means of examples.

Used measuring methods

Cation exchange capacity

Principle: The clay is treated with a large excess of aqueous NH ₄ Cl solution, washed out and the amount of NH ₄ ⁺ left on the clay determined by elemental analysis.

Me ⁺ (clay) ^" + NH ₄ ⁺ NH ₄ ⁺ (clay) ^" + Me ⁺

(Me ⁺ = H ⁺ , K ⁺ , Na ⁺ , 1/2 Ca ²⁺ , 1/2 Mg ²⁺ ....)

Equipment: sieve, 63 μm; Erlenmeyer grinding flasks, 300 ml; Analytical balance; Membrane filter chute, 400 ml; Cellulose nitrate filter, 0.15 μm (Sartorius); Drying oven; Reflux condenser; hot plate; Distillation unit, VAPODEST-5 (Gerhardt, No. 6550); Volumetric flask, 250 ml; Flame AAS.

Chemicals: 2N NH ₄ Cl solution Nessler's reagent (Merck, Art. No. 9028); Boric acid solution, 2%; Caustic soda, 32%; 0.1 N hydrochloric acid; NaCl solution, 0.1%; KCl solution, 0.1%.

Procedure: 5 g of clay are sieved through a 63 μm sieve and dried at H ² O. Then weigh exactly 2 g on the analytical balance in differential weighing into the Erlenmeyer grinding flask and add 100 ml of 2N NH ₄ Cl solution. The suspension is boiled under reflux for one hour. In the case of strongly CaCO ₃ -containing bentonites, ammonia development may occur. In these cases, it is necessary to add NH ₄ Cl solution until no ammonia odor is discernible. Additional control can be done with a wet indicator paper. After a service life of about 16 h, the NH ₄ ⁺ bentonite is filtered through a membrane filter and until For extensive freedom from ions washed with demineralized water (about 800 ml). Detection of the ionic freedom of the wash water is performed on NH, j ⁺ ions with the sensitive Nessler's reagent. The washing time can vary between 30 minutes and 3 days, depending on the key. The leached NH ₄ ⁺ -TOn is removed from the filter, dried at HO ⁰ C for 2 h, ground, sieved (63 micron sieve) and dried again at 110 ⁰ C for 2 h. Thereafter, the NH ₄ ⁺ content of the clay is determined by elemental analysis.

Calculation of the CEC: The CEC (cation exchange capacity) of the clay is conventionally determined by the NH ₄ ⁺ content of the NH ₄ ⁺ clay determined by elementary analysis of the N content. For this purpose, the device Vario EL 3 of the company Elementar-Heraeus, Hanau, DE, according to the instructions of the manufacturer was used. The data are given in mval / 100 g clay (meq / 100g).

Example: nitrogen content = 0.93%; Molecular weight: N = 14.0067 g / mol

0.93x1000

CEC = = 66.4 mVal / 100g

14.0067

CEC = 66.4 meq / 100 g NH ₄ ⁺ bentonite

Determination of water content

The water content of the products at 105 ⁰ C is determined using the method DIN / ISO-787/2.

Determination of the pH of a bentonite sample

2 g of the sample are dispersed in 98 ml of distilled water. Thereafter, the pH is determined with a calibrated glass electrode. Determination of the dissolution rates of granules

The dissolution rate of the granules is investigated by a method as described in WO 99/32591.

The granules are first screened with a sieve of mesh size 200 microns. 8 g of the sieved material is placed in one liter of water, which is heated to 3O ⁰ C and comprising 21 ° German hardness. With a paddle stirrer for 90 sec. At 800 revolutions / min, stirred. The remaining residue of the granules is sieved with a sieve of mesh size 0.2 mm and then dried at 40 ⁰ C to constant weight. The residue is weighed and the solubility determined as the difference to the weighed-in amount of granules.

Determination of mechanical stability

105 to 115 g of the granules are placed on a sieve of mesh size 0.15 mm and sieved finely divided portions of the granules.

100 g of the freed of fines granules are placed on a sieve of mesh size 0.15 mm, which is mounted on a drip tray. On the granules 3 rubber balls are given, which have a diameter of 2.9 mm. The sieve is covered with a lid, with a distance of 25 mm between sieve and lid. The device composed of drip tray, sieve and lid is placed on a rotary shaker and shaken there for 15 min. Subsequently, the collected in the drip tray granules is weighed. This number corresponds to the refractive index for 15 min. Shaking time.

The sieve is shaken again for 15 minutes and the material which has accumulated in the drip tray is weighed again. has melted. The sum of the sieve passes results in a refractoriness number of 30 min.

Determination of the source volume

A graduated 100 ml graduated cylinder is filled with 100 ml of distilled water or an aqueous solution of 1% soda and 2% trisodium polyphosphate. 2 g of bentonite are added slowly and in portions, each about 0.1 to 0.2 g, with a spatula on the surface of the water. After a drop of added portion, the next portion is added. After the 2 g of bentonite have been added and dropped to the bottom of the graduated cylinder, the cylinder is allowed to stand for one hour at room temperature. Then the height of the swollen substance in ml / 2g is read on the graduation of the measuring cylinder.

Determination of dry residue

About 50 g of the air-dry clay material to be examined are weighed out on a sieve of the corresponding mesh size. The sieve is connected to a vacuum cleaner, which sucks all parts, which are finer than the sieve through the sieve through a suction slot circulating under the sieve bottom. The strainer is covered with a plastic lid and the vacuum cleaner is switched on. After 5 minutes, the vacuum cleaner is switched off and the amount of remaining on the screen coarser fractions determined by differential weighing.

X-ray diffractometry:

The X-ray images are taken on a Philips high-resolution powder diffractometer (X '-Pert-MPD (PW3040)) equipped with a CO anode. Determination of montmorillonite content via methylene blue adsorption

The methylene blue value is a measure of the inner surface of the clay materials.

a) Preparation of a tetrasodium diphosphate solution

5.41 g tetrasodium diphosphate are weighed to 0.001 g exactly in a 1000 ml volumetric flask and shaking to the mark with dist. Water filled up.

b) Preparation of a 0.5% methylene blue solution

In a 2000 ml beaker, 125 g of methylene blue in about 1500 ml dest. Water dissolved. The solution is decanted off and distilled to 25 l with dist. Water filled up.

0.5 g of wet test bentonite with a known internal surface are weighed to the nearest 0.001 g in an Erlenmeyer flask. Add 50 ml of tetrasodium diphosphate solution and heat the mixture to boiling for 5 minutes. After cooling to room temperature, 10 ml of 0.5 molar H ₂ SO _{4 are} added and 80 to 95% of the expected final consumption of methylene blue solution is added. With the glass rod, a drop of the suspension is taken and placed on a filter paper. It forms a blue-black spot with a colorless yard. It is then added in portions of 1 ml more Methylenblaulösung and repeated the dot sample. The addition takes place until the yard turns slightly light blue, so that the added Methylenblaumenge is no longer absorbed by the test bentonite. c) Testing of clay materials

The test of the clay material is carried out in the same way as for the test bentonite. From the used amount of methylene blue solution, the inner surface of the clay material can be calculated.

381 mg methylene blue / g clay correspond to a content of 100% montmorillonite according to this method.

Example 1:

The bentonite used was a natural Ca bentonite which has the following properties:

Table 1: Properties of the bentonite

This bentonite was activated with different proportions of soda. As a comparison, a sample of the bentonite which had not been subjected to activation. The bentonite samples obtained are summarized in Table 2. Table 2: degree of activation of the bentonites used

The bentonites listed in Table 2 were each granulated with water glass using two grades of waterglass that differed in modulus. The data of the water glass used are summarized in Table 3.

Table 3: Properties of those used for granulation

glasses of water

Activation of the bentonite

Each 350 g of bentonite, which had been dried to a water content of about 30%, is placed in a Werner & Pfleiderer mixer type LUK 050 T and kneaded for 1 min. Thereafter, while continuing to run the mixer, the appropriate amount of soda is added and the mixture is kneaded for a further 10 minutes. The dough is crushed by hand into small pieces and dried in a convection oven at about 75 ⁰ C for 2 to 4 hours to a water content of 10 ± 2%. The dry goods is then ground in a rotary rotor mill Retsch type SR 3 with a 0.12 mm sieve.

Production of granules

In each case 1000 g of the characterized in Table 2 bentonite were placed in an Eirich Intensive Mixer R02E and metered via a funnel as an agglomerating agent water or water glass solution (water glass A or B). Each of water glass solutions having a solids content of 10%, 20% and 40% was used. The low setting for the rotational speed of the plate as well as the maximum rotational speed for the whirl beer were chosen. Unless otherwise indicated, the agglomeration parameters were each chosen below such that more than 50% of the granules were in a particle size range of 0.4 to 1.4 mm. For this purpose, the granules were sieved off appropriately after granulation and drying.

Investigation of the dispersion rate

The granules were examined for their dispersion rate in the manner described above. The data obtained are summarized in Table 4 for a granulation with a water glass with a modulus SiO ₂ : Na ₂ O of 2.65 and in Table 5 for a granulation with a water glass with a modulus SiO ₂ : Na ₂ O of 3.2 , In addition to the data on the disintegration of the granules, the swelling volumes of the granules obtained and the pH during dissolution of the granules in water are also included in Tables 4 and 5. Table 4: Properties of granules granulated with different amounts of water glass modulus SiO ₂ : Na ₂ O of 2.65

Bento-Agglomerati- QuellvoLoslichkeit pH- Wasserglas- nit onsmittel lumen Value proportion ml / 2 mg 90 s 30 s (%)

1 water 12 70 52 9, 5 -

1 296 g A (10%) 12 75 61 1.2

1 313 g A (20%) 18 91 83 2.6

1 426 g A (40%) 18 99 98 10, 6 7.2

2 314 g of water 20 66 30 10, 7 -

2 352 g A (10%) 14 63 44 10, 7 1.5

2 364 g A (20%) 14 98 91 10, 6 3.1

2 430 g A (40%) 14> 99.5> 99.5 10, 6 7.3

3 450 g of water 15 90 74 10, 5 -

3 284 g A (10%) 20 100 100 10, 5 1.2

3 330 g A (20%) 19 100 99.5 10, 6 2.8

3 352 g A (40%) 17> 99.5> 99.5 10, 5 6.0

Considering first the granules, which were granulated only with water, it can be seen that the swelling volume of the unactivated bentonite is 12 ml / 2 mg, the stoichiometrically activated bentonite increases to 20 ml / 2 g, and then again to overactivated bentonite to 15 ml / 2 g to fall off.

Considering the solubility, in the case of the overactivated bentonite 3, a complete dissolution is achieved even after a water glass content of 1.2% after 30 s, whereas for the stoichiometrically activated bentonite 2 a significantly higher water glass content of 7.3% is required within 30 s to achieve a complete dissolution of the granules. All granules showed a high mechanical stability and the abrasion according to the previously described test method was <2%. Even at low concentrations of waterglass granules were obtained, which had sufficient mechanical stability for technical use.

Table 5: Properties of granules which were granulated with different amounts of water glass modulus SiO ₂ : Na ₂ O of 3.2

Bento-agglomerate source Solubility pH- water glass nitrate lumen Value share ml / 2 mg 90 s 30 s (%)

1 water 12 70 52 9.5 -

1 252 g B (10%) 11 77 62 0.9

1 275 g B (20%) 13 96 84 1.9

1 341 g B (40%) 16 97 93 4.8

2 314 g water 20 66 30 10.7 -

2 519 g B (10%) 13 99 94 10,4 1,5

2 410 g B (20%) 13 98 94 10.4 3.0

2 457 g B (40%) 18> 99, 5> 99.5 10.1 6.6

3 258 g of water 15 90 74 10.5 -

3,305 g B (10%) 16.5> 99.0 97.0 10.7 0.85

3 330 g B (20%) 17.0> 99.5> 99.5 10.6 1.8

3 352 g B (40%) 19.0> 99.5> 99.5 10.5 3.9

If one uses a water glass with a modulus SiO ₂ : Na ₂ <3 of 3.2, which thus has a lower proportion of strong bases, a water glass content of only 1.8% is sufficient to produce an overactivated bentonite 3 within 30 s to achieve virtually complete dissolution of the granules. The stoichiometrically activated bentonite in turn has higher contents Water glass required to achieve a quick dissolution of the granules.

All granules showed a high mechanical stability and the abrasion according to the previously described test method was <2%. Even at low concentrations of waterglass granules were obtained, which had sufficient mechanical stability for technical use.

Claims

claims

1. A process for the preparation of rapidly disintegrating bentonite granules, wherein:

provided with alkali metal ions overactivated bentonite which is overactivated with at least 110% of its cation exchange capacity with alkali metal ions; and

the over-activated with alkali metal ions bentonite is granulated with a water glass solution.

The method of claim 1, wherein the waterglass solution has a modulus SiO ₂ IX ₂ O greater than 3.2, wherein X is selected from sodium and potassium.

3. The method of claim 1 or 2, wherein the water glass solution has a solids content of at least 10 wt .-%.

4. The method according to any one of the preceding claims, wherein the alkali metal ion is selected from the group of sodium ions and potassium ions.

5. The method according to any one of the preceding claims, wherein the water glass solution is added in such an amount to over-activated alkali metal ions bentonite that the bentonite granules at a water content of 8 wt .-% of alkali metal silicate, in particular sodium silicate, of less than 3.0 Wt .-% contains.

A process according to any one of the preceding claims, wherein the bentonite overactivated with alkali metal ions is prepared from a bentonite having a pH of greater than 8 in an aqueous slurry containing 2% by weight of bentonite.

A process according to any one of the preceding claims, wherein the over-activated bentonite having alkali metal ions has a water swellability of at least 15 ml / 2 g.

A process according to any one of the preceding claims wherein the over-activated bentonite is made by activating a calcium bentonite.

9. The method of claim 8, wherein the calcium bentonite is activated with a compound from the group of sodium carbonate, sodium citrate, sodium bicarbonate and the sodium phosphates.

10. The method according to any one of the preceding claims, wherein the bentonite granules are dried to a water content in the range of 6 to 14 wt .-%.

A rapidly disintegrating bentonite granule obtained by a process according to any one of claims 1 to 10, which has the following properties:

a swelling volume of at least 15 ml / 2g; a decay in water after 30 seconds of at least 80%.

12. Rapidly disintegrating bentonite granules according to claim 11, wherein the bentonite granules have a decomposition in water after 90 seconds of at least 90%.

13. rapidly disintegrating bentonite granules according to claim 11 or 12, wherein the bentonite granules in an aqueous Aufschläiraτiung having a content of 2 wt .-% granules has a pH of more than 10.

14. Rapid disintegrating bentonite granules according to any one of claims 11 to 13, wherein the granules have an abrasion of <2%.

15. Fast disintegrating bentonite granules according to any one of claims 11 to 14, wherein the granules at a water content of 8 wt .-% has a content of sodium silicate of less than 3 wt .-%.