CS201370B1 - Sorbent on the basis of polymeres and method of making the same - Google Patents

Description

The present invention relates to a polymer-based sorbent and to a process for its preparation.

The use of sorbents in industrial practice is one of the oldest methods of separation or purification of substances. The process consists in passing a solution of substances through a sorbent layer from which one or more substances are sorbed onto the surface of the sorbent. Despite considerable progress in the methodology and technique of substance separation, resp. The cleaning process remains a very important way of cleaning substances and is still irreplaceable for some industries. For example, in brewing, distillery, wastewater treatment and many other industries.

Almost exclusively naturally treated natural inorganic materials such as diatomaceous earth, various types of lines, carboraffin and the like are used as sorbents in the past and present. Recently, polymeric sonbents have been prepared to replace naturally occurring resp. inorganic materials. Some polymeric sorbent materials are produced in limited amounts, especially for chromatographic purposes, by a suspension polymerization technique in the presence of an inert solvent, which is partially removed from the polymer after polymerization and which leaves fine holes in the polymer.

The direct, amphaphthal swbents are costly to modify and activate. In addition to high production costs, their disadvantage is their low sorption ability.

These drawbacks are eliminated by the polymer-based sorbent according to the invention, which is based on 1 wt. part of the polymer optionally ₍ blend of polymers from the group of poly-6-caprolactam, polyethylene terephthalate, polyethylene, polyphenylene oxide and polystyrene, contains 0.01 to 10 parts by weight of inorganic porous material, optionally a blend of porous materials selected from perlite, molecular sieve, active coal, diatomaceous earth and activated alumina with a specific surface area of 0.5 to 130 m ² / g, obtainable by mixing the above polymer with a corresponding amount of the above inorganic porous material with 0.5 to 100 parts by weight of a melting solvent, based on 1 part by weight of polymer, the polymer is dissolved in the solvent at a temperature of 50 to 260 ° C and, after solidification of the mixture, the melt solvent is extracted.

According to further features, the sorbent of the invention comprises 1 wt. % poly-6-caprolactam and 0.05 to 3 wt. parts of perlite, per 1 wt. % of polyethylene terephthalate 0.1 to 5 wt. parts of molecular sieve, per 1 wt. % of polyethylene 0.05 to 6 wt. parts of activated carbon, per 1 wt. % polyphenyloxide 0.08 to 8 wt. parts of infusior clay, per 1 wt. part polysty201370 rene 0.06 to 2 wt. parts of activated alumina powder. The process for the preparation of the sorbent according to the invention consists in dissolving the polymer in 0.5 to 100 wt. parts by weight of the fusion solvent based on 1 wt. An appropriate amount of inorganic porous material is added at 50 DEG to 260 DEG C. and the melt solvent is extracted after solidification of the mixture. The polymer is first dissolved in the melt solvent and then an inorganic porous material is introduced into the solution and finally the melt solvent is extracted with an extraction agent in which only the melt solvent is dissolved.

The polymers may furthermore be polyvinyl halide, silicones, polyacrylates, polymethacrylate, cellulose esters, polycarbonates and polyurethanes, or mixtures thereof.

Furthermore, diatomaceous earth, pumice, bentonite, talc, asbestos or mixtures thereof can be used as the inorganic porous material.

In particular, 6-caprolactam, diphenylamine, acetanilide, monochloroacetic acid, dichloroacetic acid, benzoic acid, naphthalene, 1-naphthol, 2-naphthol, dimethyl terephthalate, phenyl-5-naphthylamine, rosin, urea, and thiourea are used as fusible solvents according to the invention.

According to the invention, low boiling liquids are used as extraction agents for melt solvent extraction, in which the melt solvent is well dissolved and the polymer and the inorganic porous substance are not dissolved. Preferably, water, alcohols, ethers, hydrocarbons, ketones and the like are used.

The sorption properties of the sorbents of the invention depend on the type of polymer, its chemical structure, the type of inorganic porous material and its ratio to the polymer.

The combination of an inorganic porous material and a polymer yields a sorbent which has a high sorption capacity, a sufficiently rapid sedimentation rate compared to the prior art types, does not sinter and easily solubilizes, and well passes the filtered liquid in a thick layer and does not clog filters or columns. The sorption capacity of the polymeric sorbents of the present invention exceeds that of known sorbents, for example, carboraffins, diatomaceous earth and the like 10 to 15 times.

The sonbents of the invention are compact, homogeneous masses that do not separate into polymer and inorganic material. A further advantage of the preparation of the sorbents according to the invention is that, after extraction of the melt solvent, it is obtained in powder form, which does not need to be further processed, for example by grinding, as was the case with the known sorbents.

Certain types of polymers used in the preparation of the sorbents of the present invention are useful to stabilize against the effects of temperature. For example, polyvinyl chloride can be stabilized with organotin sulfide or sulfur free stabilizers. Polyvinyl and polydiene polymers are stabilized by phenolic antioxidants.

The sorbents consisting of the polymers and inorganic porous materials of the present invention, their production method and their effects are described in more detail in the following examples.

Example 1 wt. parts of poly-6-caprolactam are dissolved in 180 wt. of 6-caprolactam at 180 DEG C., 6 g of powdered perlite are added and mixed thoroughly. The liquid mixture is poured into a shallow dish and allowed to solidify into a plate about 0.5 cm thick. The mass is then broken and the 6-caprolactam is extracted with hot water and the powdery sorbent is dried. The sorbent is especially useful for treating ^one of the synthetic alcohol, i.e. to absorb aldehydes of alcohol due to its chemical structure, particle shape and a specific surface, which is 14.6 ^m2 / g.

Example 2 wt. parts of polyethylene terephthalate are dissolved in 240 wt. of rosin at ¹ temperature of 200 ° C, 20 wt. parts of the ground molecular sieve and the liquid is discharged into a shallow dish made of aluminum foil. After solidification, the fragile mass is poured into small pieces and the rosin is extracted with ethyl alcohol. The dried sorbent material is a fine, homogeneous powder that is easily wetted in both polar and non-polar solvents. The sorbent produced according to this example is suitable as a carrier for biologically active substances because its specific surface area is 60 m ² / g and the particle size is up to 30 nm.

Example 3 wt. parts of polyethylene are dissolved in 240 wt. of rosin at 160 ° C, 15 wt. parts of activated carbon and after thorough mixing, the liquid mass is allowed to solidify into a plate about 0.5 cm thick. The matter is broken and the rosin is extracted with ethyl alcohol. A fine gray powder is obtained. The sorbent produced by this process is suitable for trapping nonpolar substances dissolved in polar substances and further as a fragrance carrier and is therefore particularly suitable in the cosmetics and the like.

Example 4 wt. parts of polystyrene are dissolved in 140 wt. parts of naphthalene at 140 ° C and added 20 g of activated alumina powder. After mixing, the liquid mixture is poured into a bowl and allowed to solidify to form a plate which, after cooling, is broken and the naphthalene is extracted with diethyl ether. A white powder of homogeneous grain size is obtained. A sorbent of this type is preferably applicable to the purification of waste waters containing oil, oils and the like due to its relatively low cost and high sorption capacity.

Example 5 wt. parts of poly-6-caprolactam are dissolved in 180 wt. parts of 6-caprolactam at 180 ° C under a nitrogen atmosphere and 20 wt. parts of diatomaceous earth. After mixing, the liquid mixture is allowed to solidify and caprolactam is extracted from the mixture with hot water. A white, powdery mass of homogeneous grain size is obtained which is well wetted in water. This kind can be advantageously used for stabilizing beverages, for example beer. It is characterized in particular by its high sorption capacity to polyphenols.

Example 6 wt. parts of polyphenylene oxide were dissolved in 270 wt. 10 g of infusior clay was added to the solution, and the mixture was thoroughly mixed. The liquid mixture was allowed to solidify into a 0.5 cm plate. The brittle mass was then broken and the rosin extracted with ethyl alcohol. The sorbent obtained was in the form of a fine white powder. As such, it is particularly suitable as a filler for gas chromatograph columns because its surface area is up to 800 m ² / g and is thermally stable up to 200 ° C. Example 7 wt. parts of polyphenylmethylsiloxane were dissolved in 85 wt. of rosin at 125 ° C and 10 g of pumice stone were added to the solution. The mixture was thoroughly mixed and poured into a dish in a liquid state and allowed to solidify into a plate about 0.5 cm thick. The plate was broken into small pieces and the rosin was extracted with ethyl alcohol. Obvious bulk material was obtained. The sorbent obtained is suitable, for example, for trapping oily substances from an aqueous emulsion and the like.

Example 8 wt. parts of polypropylene were dissolved in 200 wt. of rosin at 140 ° C and 10 wt. parts of powdered bentonite. After cooling, the solid brittle mass was subjected to extraction with ethyl alcohol. A pulverulent material was obtained which was easy to handle. The sorbent obtained is suitable as a carrier of perfumes for their application in the cosmetic industry.

Example 9 wt. parts of poly-6-caprolactam prepared by activated anionic polymerization were dissolved in 170 wt. parts of 6-caprolactam at 180 ° C under an inert atmosphere. 10 g of talc was added to the solution. Allow the liquid mixture to solidify to a 0.5 cm plate. The plate was then broken into small pieces and 6-caprolactam was extracted with hot water. A homogeneous powdered sorbent was obtained. This sorbent is suitable for the stabilization of fruit juices, since it retains substances that are subject to chemical changes and are excreted and turbid over time.

Example 10 wt. 0.5 parts by weight of polyvinyl chloride were stabilized. parts of organotin stabilizer and dissolved in 180 wt. parts by weight of 6-caprolactam at 120 ° C and 12 wt. parts of asbestos powder. After cooling and solidification of the mixture, the 6-caprolactam was extracted with bitter water and dried to give a bulky powdered sorbent which is suitable for waste water treatment, especially for the capture of organic solvents, for example chlorinated.

Example 11 wt. parts of polycaprolactam were dissolved in 180 wt. 10 parts by weight of 6-caprolactam were added to the solution. parts of diatomaceous earth and 10 wt. parts of the ground molecular sieve. After cooling and solidifying the mixture, 6-caprolactam was extracted from the mixture with hot water. The powdered material obtained had very good stabilization in water and very good sorption properties. It is therefore particularly suitable for stabilizing wines.

Sorbents consisting of polymers and inorganic porous materials prepared according to the invention have particular application in the brewing industry for beer stabilization, in the distillery industry for separating undesirable flavorings, in the wine making industry for wine clarification, as well as for chromatography columns and for water treatment and purification. The sorbents of the invention in a number of applications can fulfill a dual function simultaneously, i.e. both as sorbents and as filter materials.

Claims (9)

OBJECT OF THE INVENTION Polymer-based sorbent, characterized in that, per 1 wt. from 1 to 10 parts by weight of polymer or a mixture of polymers selected from the group consisting of poly-6-caprolactam, polyethylene terephthalate, polyethylene, polyphenylene oxide and polystyrene. parts of inorganic porous material or a mixture of porous materials selected from the group consisting of perlite, molecular sieve, activated carbon, diatomaceous earth and activated alumina having a specific surface area of 0.5 to 130 m ² fe, such that the above polymer with the corresponding an amount of the above inorganic porous material is mixed with 0.5 to 100 wt. parts by weight of fusion solvent, based on 1 wt. % of the polymer, the polymer is dissolved in the solvent at a temperature of 50 to 260 ° C and, after the mixture has solidified, the melt solvent is extracted. 2. A sorbent according to claim 1, characterized in that, per 1 wt. % poly-6-caprolactam contains 0.05 to 3 wt. parts of perlite. 3. A sorbent according to claim 1, characterized in that, per 1 wt. part of polyethylene terephthalate contains 0.1 to 5 wt. parts of molecular sieve. A sorbent according to claim 1, characterized in that, per 1 wt. part of polyethylene contains 0.05 to 6 wt. parts of activated carbon. 5. A sorbent according to claim 1, characterized in that, per 1 wt. % polyphenylene oxide contains 0.08 to 8 wt. parts of infusior clay. 6. A sorbent according to claim 1, characterized in that, per 1 wt. the polystyrene part contains 0.06 to 2 wt. parts of activated alumina powder. 7. A process according to any one of claims 1 to 6, wherein the polymer is dissolved in 0.5 to 100 wt. parts by weight of the fusion solvent based on 1 wt. % of polymer at 50 DEG-260 DEG C., an appropriate amount of inorganic porous material is added, and after solidification of the mixture, the melt solvent is extracted. 8. The process of claim 7, wherein the polymer is first dissolved in the melting solvent and then the inorganic porous material is introduced into the solution. 9. A process according to claims 7 and 8, characterized in that the melt solvent is extracted with an extraction agent in which only the melt solvent is dissolved.