DE1042236B - Process for the preparation of bisquaternary polymers of a vinyl aromatic hydrocarbon - Google Patents

Description

Process for the preparation of bisquaternary polymers of a vinyl aromatic Hydrocarbon This invention relates to anion exchange resins which are incorporated in a Side chain two quaternary ammonium groups as functional anion-adsorbing Containing groups that have strong anion-adsorbing properties of very high Moles and which can be regenerated easily and effectively at the same time.

The resins prepared according to the invention are insoluble, crosslinked polymers of a vinyl aromatic hydrocarbon, the aromatic nuclei of which are functional anion-adsorbing groups of the general formula have, in which Y is an anion in both cases, A is an alkylene group of 2 to 6 carbon atoms - preferably an ethylene group or the group represents and in which R, R 'and R2 represent methyl or ethyl or p-hydroxyethyl radicals.

The resins are usually made in the chloride form; in this Trap Y is a chloride residue. However, they can easily be converted into other forms of salt transferred by treatment with other mineral acids, such as. B.

Sulfuric acid, or with inorganic salts, such as. B.

Sodium, potassium or ammonium sulphate; in these cases Y represents the anion of the related acid or salt.

The products of the process can be produced in two ways. In one process, an amine of the general formula in which X is an anion and the letters A, R, R 'and R2 have the meaning given above, reacted with a chloromethylated, insoluble, crosslinked polymer of a monovinyl hydrocarbon, preferably of styrene.

The amine that contains the quaternary ammonium group is quaternized an amine, such as N, N'-tetramethylethylenediamine, with reagents such as methyl chloride, Methyl iodide, ethylene oxide, dimethyl sulfate and diethyl sulfate, prepared in a known manner.

The chloromethylated resin with which the amine is reacted to form the product of this invention is made by known methods as described in U.S. Patent 2,591,573. So is made by emulsion or suspension polymerization in the presence of a radical-forming agent Catalyst, such as an organic peroxide compound, the polymer of a monovinyl hydrocarbon manufactured. The preferred vinyl hydrocarbon is styrene; but others can Compounds such as vinyl toluene, vinyl naphthalene, ethyl styrene, vinyl anthracene and their homologues, as well as mixtures thereof, may be related.

Usually a substance suitable for interpolymerization is used with the Monovinyl hydrocarbon polymerizes to the insolubility of the resin in ordinary organic solvents and in aqueous solutions of acids, bases and salts to ensure. Divinylbenzene is used as a copolymerizable crosslinking compound preferred. Other known crosslinking monomers that contain two or more groupings the formula CH2 = C <can also be related, such as. B. trivinylbenzene, Divinyltoluenes, divinylnaphthalenes, divinylethylbenzene, divinylxylenes, ethylene glycol dimethacrylate, Ethylene glycol diacrylate, diallyl maleate, divinyl ether or divinyl glycol ether. Approximately 1% of the crosslinking monomer is preferred.

The crosslinked polymer is chloromethylated in a known manner, z. B. by means of paraformaldehyde and hydrochloric acid or by means of chloromethyl methyl ether and aluminum chloride.

The inventive reaction of the amine with the chloromethylated crosslinked polymer is preferably carried out at the highest possible temperature, wherein the particles of the chloromethylated resin in a.

Liquid, e.g. B. water or an organic liquid suspended containing toluene or ethylene dichloride. An aqueous medium is preferred and the reaction is preferably carried out at the boiling point of the reaction mixture. The best results are achieved when the resin particles by means of an organic Liquid, such as B. ethylene dichloride, were swollen prior to amination.

A second method to produce the products according to the invention is that, for. B. quaternized by means of methyl chloride, methyl iodide, ethylene oxide or methyl or ethyl sulfate an anion exchange resin which contains anion-adsorbing groups of the general formula on its aromatic nuclei wherein A and Y have the meaning described above and R5 and R6 represent hydrogen atoms or methyl or ethyl groups. These intermediates are prepared in a manner not claimed here by adding an amine of the formula in which the letters A, R5 and R6 have the meaning described above, reacts in the manner also described above, as is the case with the reaction of the amine has been described.

The quaternization of these intermediates is easy to carry out. In the preferred method, the particles are made of this ion exchange resin which has the terminal amino group contains, poured into water. While the resin sludge is being stirred, ZIethylchloridgas is passed in until the adsorption of the gas ceases, preferably in the presence of a soluble iodine salt which serves as an activator. The resin particles are then thoroughly washed. This quaternization is successfully carried out at room temperatures and at higher temperatures.

Best results are achieved when the temperature is 25 to around 950C and the methyl chloride is under a pressure of 0.35 to 6 atmospheres. The procedure is advantageous through the use of lime, calcium carbonate or calcium hydroxide, Modified zinc oxide and sodium hydroxide, all of which bind hydrochloric acid and sodium iodide.

The resins made by this process are in salt form received, d. i.e., Y in the above general formula is a halogen atom or a Sulfuric acid residue. Since they are usually applied as a free base, they will converted into this by treating it with an aqueous solution of a base, about caustic soda, washes.

Methyl bromide and methyl iodide are used with success in the same way applied like the methyl chloride described above. Methyl iodide is particularly effective. But it is uneconomical to use. Also higher alkyl halides such as butyl chloride or butyl sulfate, can be used with the disadvantage that the absorption capacity of the resins is necessarily reduced as the molecular size of the Substituents on the nitrogen atoms increases. Methyl or ethyl sulfates are also already been used as quaternizing reagents. They naturally store methyl respectively.

Ethyl groups on the amino nitrogen atom. When ethylene oxide is used it yields ß-hydroxyethyl groups.

If the first or second method described above is followed, an anion-exchanging resin is obtained which, because of the presence of the bisquaternary ammonium groups has a very high ion absorption capacity on the aromatic nuclei of the insoluble, crosslinked resin. The resins that appeal most are those in which all of the alkyl substituents on the 2 nitrogen atoms are methyl groups and the alkylene group between the nitrogen atoms is ethylene.

From British patent specification 652 830 a method is known that from. expensive, soluble and not readily available bromine compounds goes out and reacts it with a polyfunctional amine to form an insoluble end product to obtain, which is however in large pieces and requires grinding and sieving, also has a strong tendency to swell and its insolubility is difficult to control is. The method according to the invention, however, is based on solid starting materials, is easier to carry out operationally and leads to smoother and more pleasant to more manageable products.

The following examples illustrate. the presentation of the products according to this invention.

Example 1 Production of the synthetic resin used as the starting material In a vessel with a thermometer, mechanical stirrer and reflux condenser, 41 Brought water and 0.341 of a 1.50 / 0 strength solution of magnesium silicate.

The stirrer was turned on and a mixture of 975 g of styrene and 25 g commercial divinylbenzene (consisting of 10 g divinylbenzene and 15 g ethyl styrene) and 10 g of benzoyl peroxide added. The stirred mixture was brought to the reflux temperature heated and held on this for about 3 hours. The cooled mixture was then filtered and the resin beads dried.

The dried product was then chloromethylated.

2000 g of chloromethyl ether (C H3 OCH2 Cl) were added to the resin and the mixture was allowed to stand at room temperature for 1/2 hour. During this time the resin particles swelled. The mixture was 2.3 l Petroleum ether (Kp. 30 to 600C) added and the agitator turned on. The mixture was cooled to 0 ° C and 600 g of anhydrous powdered aluminum chloride in the course of about Added slowly for 1 hour. Stirring was continued for about 2 hours, while maintaining the mixture at 0 ° C. Then 101 ice water was slowly added and stirring continued for 1/2 hour. The resin beads were filtered off. That The chloromethylated product contained 18.9% chlorine.

According to the invention, the resin beads were then covered with ethylene dichloride and swollen. They contained 49,5010 solids. The rest was water and ethylene dichloride. A mixture of 700 g of the moist resin, 0.81 of water and 225 g of N, N'-tetramethylethylenediamine (CHS) 2NC2H4N (CH3) 2 was placed in a vessel equipped with a thermometer, stirrer and reflux condenser. The mixture was brought to reflux temperature and held for 2 hours. Then 0.5 l of water was added and distilled off. The distillation was continued until no more ethylene dichloride appeared in the distillate. In the meantime, the water removed by distillation has been replaced. After cooling to room temperature, the resin, which was still present in spherical form, was washed with water until neutral. It contained groups of the formula as substituents on the aromatic nuclei The product was an ion exchange resin with a base exchange capacity of 5.24 milliequivalences (meq.) Per dry substance or 1.93 milliequivalences per gram wet. Its quaternary ammonium capacity was 2.84 milliequivalences per gram dry and 1.04 milliequivalences per cubic centimeter wet. The capacity, based on quaternary ammonium, is a measure of the ability of the resin to absorb neutral salts such as e.g. B. sodium chloride, and exchange its anion for the anions of the salt, while the total base exchange capacity is a measure of the ability of the resin to remove acids from solution by adsorption to the weakly basic amine groups (in this case the terminal - N (CH3) 2 groups) and by ion exchange on the quaternary ammonium groups.

Hundred grams of the moist, obtained in the manner indicated above Resin (50.7 01o solids) and 0.1 l of water were placed in a container, the one with a stirring device, a gas supply pipe, thermometer and a mercury manometer was provided. The air was purged from the container by a stream of methyl chloride, then the system sealed, the stirrer turned on and methyl chloride initiated at a constant pressure of 30 cm Hg. The reaction mixture was gradually heated to 45 ° C and at this temperature for 4 hours under pressure held. The vessel and its contents were cooled to room temperature, the resin was separated off, washed and then washed by washing with a 5% solution of sodium hydroxide in transforms the hydroxyl form.

The product had a total base capacity of 4.87 milliequivalents per g dry or 1.83 milliequivalences per cc wet. Its base exchange capacity, based on quaternary ammonium, was 3.45 milliequivalences per gram dry or 1.30 milliequivalences per cc wet. Thus the latter is related to the total Basic capacity 71: 100.

Example 2 In a vessel with a thermometer, stirrer and reflux condenser was a mixture of 50 g of technically pure 2-dimethylaminoethyltrimethylammonium iodide, (CH,), - N-C, H, -N (CH,), I, 80ccm water and 66 g of the chloromethylated resin beads brought, the production of which is described as a starting material in Example 1.

The resin beads were swollen with ethylene dichloride, with water moisturized and contained solid resin components. The mixture was at reflux temperature Heated for 8 hours. Otherwise, the amination was carried out in the same way as described in example 1. The product was first treated with a 10% solution of Hydrochloric acid and then washed thoroughly with water. The result was 122 g of moist Resin (48.5% solid resin components) with a density of 0.72. The entire basic capacities of the resin was 4.74 meq per gram dry and 1.67 meq per cc wet. Its capacity, based on quaternary ammonium, was 3.96 milliequivalents per g dry and 1.39 milliequivalences per cc wet.

This resin, like all products of this invention, is easy to apply from the salt form to the hydroxyl form by treatment with a solution a base, such as B. of sodium hydroxide.

Recovery of uranium from sulfuric acid solutions Among the same Test conditions are compared: A strongly basic quaternary ammonium exchange resin in the hydroxyl form prepared by reaction according to U.S. Patent 2,591,573 of trimethylamine with a chloromethylated copolymer of styrene and divinylbenzene (Resin A), and a tertiary basic anion exchange resin based on crosslinked Polystyrene with dimethylamino groups, described in »Chemical Trade Journal at Chemical Engineer from Sept. August 1955 (HarzB) and a bis-quaternary anion exchange resin according to the present invention.

The solution to be treated contains 1 g uranium per liter in the form of UO2SO4 3 H2 0, 2 g of trivalent iron in the form of Fe2 (SO4) 3 9H2O, 0.2 g of divalent iron in the form of Fe 504 7 7H2O and 30 to 40 g sulfate ions in the form of Na2 SO4. The pn value is adjusted to 1.8 with concentrated sulfuric acid.

40 cc of the resin to be tested is poured into a 50 cc burette. The above-mentioned treatment solution is then allowed to run through the bed of resin until the effluent contains 20% uranium. The flow rate is 1 cc per minute. At this point in time, which is the breakthrough point, the liquid that has flowed out is collected and the capacities of the resins to be compared are determined. The test results are compiled in the table below resin according to resin B resin A invention Flow rate until through breaking point 201,. . . . . . . . . . 3.481 1.441 2.681 Adsorbed Uranium ........ 87 g uranium 36 g uranium 87 g uranium Adsorbed Uranium Saturation .... 99.7g uranium 41.1g uranium 71.4g uranium The data in the second and third columns are calculated for 1000 ccm of resin.

Each of the resins to be tested is rinsed with 40 cc of water and with a solution leached the one-third gray equivalent of H N 0 and two-thirds Contains gray equivalents of STH4N-O3 per liter. Complete removal, dissolving and regeneration of the resin is achieved with resin A with 136 ccm, with the resin according to the invention with 200 cc of this solution.

The comparison shows that the resins according to the invention are different of the known commercially available resins and are surprisingly superior to them. The new bisquaternary ammonium anion exchange resins have at least a 30 or 400 / o greater capacity for uranium than resin A or resin B. Adsorb when saturated the new resins have about 400Io more uranium than the known resins. Finally is too their ability to regenerate is superior to that of other quaternary ammonine resins.

The superiority of those made by the process of the invention bisquaternary ammonium resins over known quaternary ammonium resins is significant Among other things, in the recovery of valuable substances, such as uranium, on an industrial scale Scale.

Claims (6)

PATENT CLAIMS: 1. Process for the preparation of bisquaternary polymers of a vinyl aromatic hydrocarbon, characterized in that either an insoluble, crosslinked, chloromethylated polymer of an aromatic monovinyl hydrocarbon is mixed with a quaternary amine of the general formula brings to reaction or such a chloromethylated polymer which, as a result of reaction with an amine, such as tetramethylethylenediamine, already has groups of the general formula on its aromatic nuclei bears, quaternized with methyl chloride, methyl iodide, ethylene oxide or methyl or ethyl sulfate, where A is an alkylene chain with 2 to 6 carbon atoms, optionally interrupted by a methylamino radical, X and Y anions, R, R ', R2 are methyl, ethyl or ß-oxyethyl radicals , R5 and R6 hydrogen atom represent methyl or ethyl groups. 2. The method according to claim 1, characterized in that the starting product Mixed polymers of the aromatic monovinyl hydrocarbon with a polymerizable, compound containing more than one vinyl group can be used. 3. The method according to claim 2, characterized in that copolymers from 98 to 99.90 / 0 styrene and 2 to 0.1 0 / o divinylbenzene used as starting material will. 4. The method according to claim 1 to 3, characterized in that the Reaction of the amine with the chloromethylated polymer or mixed polymer in one running liquid medium and the reaction mixture approximately up to its boiling point is heated. 5. The method according to claim 4, characterized in that the polymer particles be preswollen in the liquid medium prior to amination. 6. The method according to claim 1 or 2, characterized in that to quaternize the particles of the polymer or mixed polymer in water in Presence of a soluble iodide as an activator at temperatures from 25 to about 95 "C treated with gaseous methyl chloride introduced under pressure for so long until no more gases are absorbed, where appropriate lime, zinc oxide or sodium hydroxide can be added. Documents considered: British Patent No. 652 830; U.S. Patent Nos. 2591 573, 2597494, 2614099