DE1048887B - Method of replacing the exchangeable cations of a clay with a stretchable lattice - Google Patents

Description

Method of replacing the exchangeable cations of a clay with Extensible Lattice This invention relates to the treatment of clays having an expandable lattice. Clays of this type consist of particles which in turn are layered on top of each other Plates of the mineral in question and the metallic ions in between exist. It - consists z. B. each particle of a bentonite or hectorite clay a multitude of montmorillonite plates with cations between them. In the natural state these ions are sodium and / or calcium ions. By attraction of these metal ions, water and other polar molecules penetrate the particles and cause swelling of the same as the plates by the compared to the Metal ions large polar molecules are pushed apart. This appearance it is also written that bentonite and hectorite produce plastic gels can.

The cations between the plates are like the cations of a cation exchanger, and it is sometimes desirable to have this Replace cations with others. It can e.g. B. the swelling capacity of these clays reduced by replacing the natural cations with larger, organic cations will. This could e.g. B. in clay used as a thickener or for production of a dielectric film is used. For making dielectric Films, an aqueous clay dispersion is applied to a smooth surface and drains. The dielectric properties of these films are increased by substitution the natural cations are significantly improved by larger cations. Are these Cations can also be polymerized, which also improves the mechanical ones and electrical properties of the film.

Until now, the cation exchange has been achieved through the treatment of clay with a solution that contained the other cations, that is, in one stage carried out. This does not replace all exchangeable cations, and you had to come up with a clay that still contained some of its natural cations, content. According to the invention, a two-stage exchange process reduces the proportion of the original cations in the final clay.

According to the invention, the exchangeable cations are initially through Intermediate cations to be eliminated in gaseous form are replaced by an aqueous clay dispersion is treated with the cation exchange material containing the intermediate cations; the intermediate cations then become the other by treating the clay with one Solution containing cations eliminated and replaced by others. The invention applies in particular to raw clays, but can also be used on pretreated clays will.

The two-stage treatment according to the present invention is the proportion of the original cations is significantly reduced. For example was the sodium content of a raw bentonite, which was originally 0.70 to 0.80 meq / g sodium contained, only reduced to 0.05 to 0.1 meq / g by one-stage treatment. After the two-stage treatment according to the invention, it was only 0.02 to 0.003 mval / g. Even a dielectric film made from such clay has far more favorable improved properties Properties on. Cheat the power factor of a film from a single-stage treated Clay, the dispersion of which is made with an impregnating agent before film production the reaction product of diethylenetriamine was treated with phthalic anhydride, It was 0.5 to 0.80 / 0 or 0.3 to 0.40 / 0 with subsequent impregnation with a two-stage treated sound film 0.3 to 0.40 / 0 or 0.2 to 0.30 / 0, respectively after when the impregnation was carried out. A film of two-stage treated Clay also exhibits a smaller increase in power factor with increasing temperature on.

The elimination of the intermediate cations differs significantly from replacing original toning cations. While in the second case the exchanged Cations are still in the conversion system, leaving them first said the reaction mixture in the gaseous state. The elimination can go on two ways are effected: either in such a way that the intermediate cations are ions a base weaker than that of the desired cations, or that the Intermediate cations in the gaseous state at a certain temperature of the Eliminate tone, with the second level at an equally high or higher level Temperature is made.

In the first case, the implementation results in a stronger with a weaker Base the gaseous displacement of the latter, and in the second case the intermediate cations also eliminated as a gas, which is achieved by treating the clay with the solution and increasing it the temperature is caused during the second stage. As intermediate cations ammonium ions are suitable, which can be eliminated in both types of clay. Should the final cations z. B. Diethylenetriamine, so will be the elimination applied the first method; on the other hand, if they are to be derived from lead acrylate, see above use the second method. Ammonia has a very low boiling point and can be easily eliminated as a gas. Furthermore, as intermediate cations Substituted ammonium ions are useful, which differ from low molecular weight compounds and boiling point, such as B. methylamine and diethylamine, can be derived.

The final cations can be organic, some larger are as natural. They also tend to be the original ones that still exist To displace cations, whereby the proportion of the latter is further reduced. They are preferably obtained from amines with a high molecular weight and boiling point, so z. B. diethylenetriamine, triethanolamine, p entamethylene hexamine, p-diisobutylphenoxyäthoxyäthyldimethylbenzylammoniumchlorid or dimethyloctadecylamine. These amines can practically be used in aqueous solution Amine hydroxides are considered. Advantageously, those introduced into the clay can be used organic cations be polymerizable or hardenable, and the clay is used for Polymerization treated. This is especially valuable when making clay dielectric films are used; the clay is polymerized after the film is made or hardened, the physical and electrical properties are improved same. The polymerizable or curable cations are obtained from the reaction product of a polyamine with a polycarboxylic acid, preferably from the reaction product of diethylenetriamine with phthalic anhydride. Such reaction products can are considered to be polyfunctional amine salts. These cations from the reaction product Diethylenetriamine with phthalic anhydride can be obtained by heating to 240 to 2500 C can be polymerized or hardened.

The final cations can also be metallic in nature, which are larger than the natural ones, e.g. B. lead ions. Furthermore, the cations derived from lead acrylate, the final cation is partially polymerizable, which in turn improves the properties of the clay through subsequent polymerization can be.

The first stage of the invention should be by treating an aqueous Clay dispersion with a cation exchanger containing the intermediate cations causes will. This stage ultimately consists of mixing two ion exchangers for the purpose Exchange of their cations. An aqueous clay dispersion can be made by mixing the clay generated with water; Impurities such as calcium carbonate and sand, will be by means of centrifugation, such as silicates, sulfates and chlorides, with low Molecular weight, by reaction with a strongly basic anion exchange resin be eliminated. Since the cation exchanger is the calcium carbonate present in the water Removing calcium is done in order to maintain the effectiveness of the ion exchanger as much of the calcium carbonate as possible out of the dispersion before the first stage removed. The anion exchange treatment can be carried out before or after the treatment with the cation exchanger, or both exchangers in Form of a so-called mixed bed come into effect at the same time. The treatment with the cation exchanger containing the intermediate cations can proceed so that the clay dispersion is passed through a bed of the cation exchanger. as Cation exchangers find sulfonated phenol-formaldehyde resins and sulfonated, crosslinked ones Polystyrene resins use. The resin is enriched with intermediate cations and regenerated by treatment with solutions, as is customary in ion exchange processes, when it is saturated with natural cations.

In the second stage of the process, the clay can either be used as an aqueous one Dispersion or as a film consisting of a layer of the dehydrated dispersion are treated with a solution containing the final cations. The invention is particularly valuable for the production of a dielectric film, which preferably by treating a sound film with a solution of the final Cations is produced.

Here are a few examples.

Example 1 Hectorite clay was dispersed in distilled water, to form a dispersion containing 3.5 weight percent clay, which in some Days hydrated to a gel. The gel was used to remove sand and calcium carbonate Centrifuged twice, after which the gel turned into a 2.5 weight percent clay containing Dispersion was diluted.

450 kg of the dispersion were crosslinked with 0.056 m3 of a sulfonated Polystyrene cation exchange resin in the ammonium form and mixed for 30 minutes touched. The ion exchange resin in question had already been used for gel treatment without being regenerated afterwards. The gel was then made from resin separated and mixed again with 0.056 m3 of regenerated ion exchange resin, wherein this time was stirred for 4 hours.

The gel was then for 45 minutes at an absolute pressure of 10 mm of mercury evacuated with slow stirring to remove all gases. The dispersion was applied in a 2 mm thick layer on glass plates, which were heated to 660 ° C. in a drying oven for 3 hours. The resulting movie was then dry and 1 mm thick, whereupon it was separated from the plates. Thereafter it was immersed for 24 hours in a solution consisting of 12.8 kg of water and 460 g a solution of 23.7 percent by weight diethylenetriamine and 28.4 percent by weight Phthalic anhydride in water. After that he was again for the same Time dipped in an identical, fresh solution. Then stacked place it between sheets of blotting paper at room temperature for 14 days. The stacks were between ten and twelve arches high. Then the sheets were placed in an oven and the temperature thereof increased by 5 ° C / hour until a temperature of between 60 and 700 C was reached, which was maintained for 5 days. The film was cured by heating it at 85 to 950 C for 5 hours, the temperature then increased by 5 ° C / hour to 240 to 2500 C, and this was maintained for 2 to 3 days.

The film was then examined and a reduction in sodium content from 0.75 meq / g in the original clay to 0.035 meq / g. The power factor the film was 0.270 / 0 at room temperature. A similar film made of sound that doesn't treated with a cation exchange resin had a sodium content of 0.0625 mval / g and a power factor of 0.380 / 0.

Example 2 4 weight percent hectorite clay was distilled in Water dispersed and allowed to hydrate for a few days, followed by a homogeneous gel formed. The hectorite gel was used to remove sand and calcium carbonate centrifuged twice, after which it was mixed with deionized water to form a dispersion above has been diluted.

A 0.028 m3 bed of sulfonated, crosslinked polystyrene cation exchange resin was made and, in order for the resin to transform itself into its ammonium form, with treated with a 1 normal ammonium chloride solution. The hectorite dispersion was then passed through the ion exchange bed at a rate of 54 kg / hour. It was found that at this rate of flow the sodium ions of the clay have been replaced by the ammonium ions of the resin, resulting in an ammonium clay dispersion formed.

23.7 percent by weight diethylenetriamine and 28.4 percent by weight phthalic anhydride were dissolved in water. 54 kg of the 20% clay dispersion were removed after treatment diluted with the ion exchanger in a stirred tank with 5.4 kg of water. A diluted one Solution of 460 g of the diethylenetriamine-phthalic anhydride solution and 12.8 kg of water slowly became the clay dispersion in the kettle with vigorous stirring given. This addition took 1 hour. An additional 480 g of the undiluted Diethylenetriamine phthalic anhydride solution were then taken within 1 to 2 minutes added continued stirring.

After this solution was added to the dispersion, the mixture became under slow stirring for 45 minutes at reduced pressure of 10 mm of mercury evacuated to remove gases from it. Then a 2 mm thick was placed on glass plates Film poured out of her. The plates were at a humidity of 25% Maintained in a drying oven at 55 to 650 C for 2 hours, after which the film is dry and was 0.025 mm thick.

After drying, the film was separated from the glass plates Cut right size and stacked in stacks of ten to twelve sheets. These Stacks were stored between sheets of removable paper for 14 days at room temperature. The sheets were then heated in an oven at 50 C / hour to 60 to 700 C and kept at this temperature for 5 days.

After this pre-curing stage, the film was heated to 85 to - 950 C, held there for 5 hours and then heated at 50 C / hour to 240 to 2500 C. After two to three days of heating at 240 to 2500 C, the polymerization was des resinable component, d. H. of the ion from diethylenetriamine and phthalic anhydride closed.

The film was then examined and had a loss factor at 250.degree of 0.003 and a specific inductive capacity of 3.7; at 1000 C.

Loss factor of 0.006. Increased in the range of 25 to 1000C the specific inductive capacity increases by 0.015 ovo per degree C. These numerical values were obtained on the basis of individual sheets of film which were fastened in a holder and with 1000 hearts / sec. investigated on mercury electrodes.

Example 3 A 20 / above hectorite dispersion purified according to Example 1 was passed through a mixed bed.

The latter consisted of 500 cc of a sulfonated, crosslinked polystyrene cation exchange resin in the ammonium form and from 175 cc of a strongly basic anion exchange resin in the OH form.

The ion exchange resin mixture was made into a stainless steel Pipe 10 to 12.5 cm in diameter, through which mixed bed then the Dispersion was passed.

54 kg of the hectorite dispersion flowed through the bed to Throughput rate of 400 ccm / minute to remove the sodium and a To produce ammonium clay.

461 g of a diethylenetriamine-phthalic anhydride solution prepared according to Example 1 were diluted with 12.9 l of water and the diluted solution inside the dispersion dropped in for an hour.

After that, 461 g of undiluted solution quickly became available with constant stirring added.

The dispersion prepared in this way was spread out according to Example 1, dried and hardened.

Investigations on the cured film showed a power factor of 0.610 / 0 and a dielectric constant of 3.7 at 250 C.

Example 4 500 g of a 20% dispersion were mixed through a Ion exchange bed, each consisting of 150 g of the same ion exchange resins as in Example 3. The throughput rate was 200 to 300 cc / hour. The demetallized dispersion was mixed according to Example 1 with a solution cast into film, dried and hardened.

The resulting film was analyzed and found to be 0.03% found as Na2 0.

Example 5 A 20% aqueous hectorite dispersion was through a 75 cm high column of 5 cm diameter passed; the column consisted of previously through Reaction with an excess n-NH4 Cl solution converted into its ammonium form, sulfonated, crosslinked polystyrene resin. The resulting clay dispersion contained 2 meq sodium ions / 100 g clay. The ammonium clay dispersion was made with an amine high molecular weight solution mixed.

The latter was prepared as follows: 250 cc of a molar solution from p-Diisobutylphenoxyäthoxyäthyldimethylbenzylammoniumchlorid with a p-value of 8 were made from strongly basic through a 45 cm high column 1.9 cm in diameter Amine anion exchange resin conducted in the 0 OH form - to the Cl ions of the amine to be replaced by OH ions of the resin. The pE value of the resulting Amine solution in OH form was 11.

4.5 cc of the modified amine solution were diluted with 28 cc of water and while continuously shaking the reaction vessel to 200 cc of the ammonium clay dispersion given. The clay flaked immediately and ammonia fumes were evolved.

Moistened litmus paper stained blue over the jar, probably because NH2 converted to NH4 0 H on litmus paper.

The flakes were separated from the solution by vacuum filtration and then oven-dried the solution at 500 ° C. for 24 hours. The modified in this way Tone looked a little darker than the original hectorite tone.

Example 6 A 50% aqueous Wyoming bentonite dispersion with a basic exchange capacity of 100 meq cation / 100 g dry clay was achieved a 75 cm high column of 5 cm diameter made previously by treatment with excess N H4 Cl solution, sulfonated, crosslinked polystyrene resin converted into its ammonium form directed. The resulting clay dispersion, the 0.22 meq sodium ions / 100 g clay was made with the high molecular weight amine solution prepared as follows mixed: In a weight ratio of 1: 2, dimethyloctadecylamine in Dissolved diethyl ether. The solution was heated to 450 ° C. and removed from methyl bromide gas bubbled through, whereby a salt insoluble in ether, trimethyloctadecylammonium bromide, originated. The salt was then washed with fresh ether and filtered. Thereafter it was dried by evaporation of the ether. An analysis of the salt after the Parr bomb method showed that the bromine ion content of the salt was within 1 ll / o of the theoretical amount for trimethyloctadecylammonium bromide. 100 cc of an aqueous Normal solutions of the salt were passed through a 45 cm high column 1.9 cm in diameter directed; the column contained in order to replace the bromine ions of the salt with the OH ions of the resin form a strongly basic amine anion exchanger. The resulting The amine hydroxide solution was strongly basic and free of bromine ions.

To saturate the basic cation exchange capacity of the clay a certain amount of the 50 / above bentonite dispersion in the N H + 4 form is sufficient Amount of the amine hydroxide solution was added dropwise with continued stirring.

While the amine cations of the hydroxide die N H + 4 ions of bentonite replaced, the mixture flocculated. Ammonia odor was clearly noticeable, and Litmus paper placed above the vessel changed color (gaseous base). The clay flakes were filtered off and the excess water was removed. To wash was unnecessary. After air drying, the modified clay exhibited swelling properties in non-polar, organic solvents, such as. B. gasoline and toluene.

PTETN LANGUAGES: 1. Procedure for replacing the exchangeable cations of a clay with a stretchable lattice by other cations, characterized in that First the exchangeable cations by intermediate cations, which are in gaseous form Let the condition be removed from the clay, replaced by an aqueous dispersion of the clay with a cation exchange material that contains the intermediate cations, is treated and that ~ then the intermediate cations are removed and replaced by other cations by treating the clay with a solution containing the other cations will.

Claims (1)

2. The method according to claim 1, characterized in that the natural exchangeable cations in the clay by larger cations of an organic base and that the intermediate cations are cations of a weaker base than the organic base. 3. The method according to claim 1, characterized in that the exchangeable Cations are replaced by cations of an amine, the intermediate cations in a certain temperature to be removed from the clay as a gas and that the treatment of the clay with a solution of the amine at or above this predetermined temperature is carried out. 4. The method according to any one of the preceding claims, characterized in that that the clay containing the intermediate cations is formed into a film by the water is removed from a layer of the dispersion and the film with a solution of the amine is treated. 5. The method according to any one of claims 2 to 4, characterized in that that the organic cations are polymerizable or hardenable and that these ions containing clay is treated for the purpose of polymerizing or hardening. 6. The method according to claim 5, characterized in that the organic Cations from the reaction product of diethylenetriamine with phthalic anhydride are formed.