RU202705U1 - ANION-SELECTIVE ION-EXCHANGE MEMBRANE - Google Patents

Abstract

The utility model relates to membrane technology, in particular to ion-exchange membranes, namely to anion-exchange membranes used to remove salt ions from solutions, and can find application in electrodialysis devices for selectively removing ions with varying degrees of charge from technological and food solutions. an ion-exchange membrane consisting of a heterogeneous strongly basic ion-exchange substrate membrane and a thin layer made in the form of a film of a homogeneous cation-exchange modifier layer having a thickness of 5-20 μm and made of sulfonated polyetheretherketone (SPEEK). The technical result is an expansion of the range of anion-exchange membranes by obtaining anion-selective ion-exchange membrane with selectivity to singly charged ions during the separation of anions in solutions containing ions with different degrees of charge and molecular weight. 3 tab.

Description

The useful model relates to membrane technology, in particular to ion-exchange membranes, namely to anion-exchange membranes used to remove salt ions from solutions, and can find application in electrodialysis devices for selective removal of ions with varying degrees of charge from technological and food solutions.

In recent years, interest in the study of the processes of electromembrane separation of electrolyte ions has sharply increased, which is due to the emergence of new areas of practical application of electromembrane technologies: reverse and metathesis electrodialysis, membrane-capacitive deionization. Ion separation processes play a key role in redox flow batteries, microbiological fuel cells, and in the creation of targeted drug delivery systems.

Known bilayer anion exchange membrane, consisting of a substrate membrane (MA-40) and a surface modifying layer, the basis of which is a copolymer of acrylonitrile and N, N-dimethyl-N, N-diallylammonium chloride (DMDAAC) [patent 2410147 RF Method for modifying anion exchange membranes, IPC B01D 71/06 (2006.01), B01D 71/82 (2006.01), B01D 71/60 (2006.01), B01D 61/44 (2006.01), C08J 5/22 (2006.01), publ. 27.01.2011]. It has an increased mass transfer of salt anions, in comparison with the original MA-40 membrane, and a high degree of chemical resistance in alkaline solutions. However, this membrane is not suitable for the electrodialysis separation of aqueous solutions of organic anions due to its high electrical resistance. In addition, the membrane cannot be used for electrodialysis desalination of food solutions, since a toxic monomer, acrylonitrile, is required for its production.

Known multilayer composite strongly basic membrane, including at least two polymer layers [patent 2559486 RF Multilayer composite polymer strongly basic membrane and a method for its production, IPC B01D 71/06 (2006.01), B01D 71/82 (2006.01), B01D 71/60 (2006.01) , B01D 61/44 (2006.01). C08J 5/22 (2006.01), publ. 08/10/2015]. This membrane has an increased mass transfer of salt anions, is stable in process solutions with a high pH value, and can be used for the electrodialysis separation of aqueous solutions of organic acids. However, this strongly basic membrane is not suitable for use in the food industry, since a highly toxic monomer, acrylonitrile, is used to manufacture the polymer modifier.

The closest analogue to the inventive membrane is an asymmetric bipolar membrane, consisting of a heterogeneous strongly basic ion-exchange membrane-substrate and a thin cation-exchange layer, of a homogeneous sulfonated perfluorocarbon polymer with a thickness of 5 to 20 micrometers, applied on a previously defatted and activated surface of a concentrated substrate at a concentrated acid for no more than 10 minutes [patent 120373 RF, IPC B01D 71/06 (2006.01)].

The disadvantages of the membrane include the low selective selectivity of the membrane to salt anions during electrodialysis, when processing dilute solutions (similar to natural water) and a drop in the limiting current value.

The technical result is to increase the selective selectivity of the heterogeneous anion-exchange membrane to singly charged anions in a mixture with two charged and (or) three charged anions, as well as organic anions when they are present together in solution.

The technical result is achieved by the fact that the proposed membrane consists of a heterogeneous strongly basic ion-exchange membrane-substrate and a thin layer made in the form of a film of a homogeneous cation-exchange modifier layer having a thickness of 5-20 microns and consisting of sulfonated polyetheretherketone (SPEEK). The modifier is applied to the activated surface of the substrate membrane after its treatment with concentrated acetic acid for no more than 10 minutes.

In contrast to the prototype, the claimed anion-selective ion-exchange membrane as a modifying layer has a film of sulfonated polyetheretherketone, 5-20 microns thick. The thickness of the modifying layer less than 5 micrometers does not provide the achievement of the technical result due to the unevenness of the applied modifying layer on the surface of the substrate membrane. It was experimentally revealed that an increase in the layer thickness of more than 20 μm leads to an increase in the surface resistance of the membrane and a decrease in the value of the limiting current.

Example 1. A heterogeneous strongly basic anion-exchange membrane MA-41 containing (in mass percent) 40% polyethylene and 60% styrene-divinylbenzene anion exchanger with quaternary ammonium bases was subjected to a standard conditioning procedure, including: surface treatment with carbon tetrachloride, keeping the membrane in ethyl alcohol for 6 hours, transfer to the salt (nitrate) form of ionogenic groups of the membrane [Polyansky NG, Gorbunov GV, Polyanskaya NL. Research methods of ion exchangers. M., 1976.]. After that, the membrane surface was dried and treated with concentrated acetic acid for 10 minutes. Thus, a pre-prepared strongly basic ion-exchange membrane without a modifier layer was obtained. To obtain an anion-selective ion-exchange membrane with a SPEEK modifying layer 5 micrometers thick, the surface of the substrate membrane was treated with a solution of 10% sulfonated polyetheretherketone in dimethylformamide in an amount of 0.02 ml / cm ² . For membrane samples with a SPEEK modifying layer thickness of 10 and 20 μm, a 10% solution of sulfonated polyetheretherketone in dimethylformamide was used in an amount of 0.04 and 0.08 ml / cm ^2, respectively.

The electrochemical characteristics of the proposed anion-selective ion-exchange membrane were investigated in an installation with a rotating membrane disc, at an angular speed of rotation of the disc of 100 rpm. The mass transfer coefficients were calculated according to the equation K _m = i _pr ⁰ / C ₀ vF, where i _pr is the limiting electrodiffusion current of the membrane under study, v is the kinematic viscosity of the solution, cm ² / s, C ₀ is the concentration of the solution, mol / cm ³ .

The table shows data on the coefficients of mass transfer of membranes depending on the thickness of the SPEEK modifying layer.

As can be seen from Table 1, the application of a modifying layer of SPEEK on the surface of the substrate membrane leads to an increase in the mass transfer coefficient of the proposed membrane by 18.2%, 22.7% and 18.2%, respectively. This effect is achieved due to the hydrophobization of the membrane surface, since there is an increase in the conductive sections.

The above information confirms the claimed technical result, namely, the proposed anion-selective ion-exchange membrane has a higher coefficient of mass transfer.

Example 2. Heterogeneous strongly basic anion-exchange membrane MA-41, containing (in mass percent) 40% polyethylene and 60% styrenedivinylbenzene anion exchanger with quaternary ammonium bases, was subjected to a standard conditioning procedure. After that, the membrane surface was dried and treated with concentrated acetic acid for 10 minutes. Thus, a pre-prepared strongly basic ion-exchange membrane without a modifier layer was obtained. To obtain an anion-selective ion-exchange membrane with a SPEEK modifying layer 10 micrometers thick, the surface of the substrate membrane was treated with a solution of 10% sulfonated polyetheretherketone in dimethylformamide in an amount of 0.04 ml / cm ² .

Some of the prepared and dried membranes were placed in a solution containing a mixture of sodium nitrate and sodium sulfate with a concentration of 0.015 mol мeq / l and 0.0075 mol⋅eq / l, respectively. And the other part of the membranes was placed in a mixed solution containing 0.1 mol / L sodium hydroxide and 0.05 mol / L sodium naphthenate.

и

. Расчеты избирательной селективности представлены в таблице 2 и 3.The selective selectivity of the proposed anion-selective ion-exchange membrane was investigated in a setup with a rotating membrane disc, at an angular speed of rotation of the disc of 100 rpm. On the obtained samples, the Hittorf transfer numbers of nitrate ions (t _NO3 ^- ) and sulfate (t _SO4 ^2- ) were measured at a constant current density of 5 mA / cm ² . The Hittorf transfer numbers of hydroxyl ions (t _OH ^- ) and naphthenate (t _Nf ^- ) were measured in a similar way. Based on the data obtained, the selectivity of the membrane for the nitrate / sulfate and hydroxyl / naphthenate systems was calculated as

and

... Selective selectivity calculations are presented in Tables 2 and 3.

Table 2 shows that the obtained anion-selective ion-exchange membrane with a modifying layer of SPEEK 10 μm thick has a pronounced selectivity to singly charged nitrate ions with respect to doubly charged sulfate ions taken in a 1: 1 ratio.

Table 3 shows that in a mixed system containing hydroxyl ions and naphthenate ions, the resulting membrane with a SPEEK modifying layer 10 μm thick has a pronounced selectivity to hydroxyl ions in relation to naphthenate ions taken in a 1: 1 ratio.

Thus, the proposed anion-selective ion-exchange membrane can be used for the selective separation of anions in solutions containing ions with different degrees of charge and molecular weight. It is new, industrially applicable, and therefore meets the criteria for utility models.

Claims (1)

Anion-selective ion-exchange membrane, consisting of a heterogeneous strongly basic ion-exchange substrate membrane and a thin homogeneous layer made in the form of a film formed on the previously defatted and activated surface of the substrate membrane when it is treated with concentrated acetic acid for no more than 10 minutes, characterized in that it is thin the layer is made in the form of a film of sulfonated polyetheretherketone with a thickness of 5-20 microns.