KR101279352B1 - Porous substrate with enhanced strength, reinforced composite electrolyte membrane using the same, membrane-electrode assembly having the same and fuel cell having them - Google Patents

Abstract

The present invention relates to a porous support having improved strength, a reinforced composite electrolyte membrane using the membrane, and a membrane-electrode assembly and a fuel cell having the membrane.

The porous support of the present invention is a porous support with improved mechanical strength after electrospinning by introduction of a heat treatment means or a crosslinking agent, and can provide a porous support made of various polymer materials applied to electrospinning. It is possible to provide a reinforced composite electrolyte membrane prepared by impregnating a hydrogen ion conductive polymer. Thus, the reinforced composite electrolyte membrane of the present invention can improve the mechanical strength, electrochemical properties and durability while maintaining high porosity, thereby improving the performance of the membrane-electrode assembly and the fuel cell employing the membrane.

Reinforced composite electrolyte membrane, electrospinning, porous support, conductive polymer electrolyte, fuel cell.

Description

POROUS SUBSTRATE WITH ENHANCED STRENGTH, REINFORCED COMPOSITE ELECTROLYTE MEMBRANE USING THE SAME, MEMBRANE-ELECTRODE ASSEMBLY HAVING THE SAME AND FUEL CELL HAVING THEM}

The present invention relates to a porous support having improved strength, a reinforced composite electrolyte membrane using the same, a membrane-electrode assembly having a reinforced composite electrolyte membrane thereof, and a fuel cell, and more particularly, after the electrospinning, the strength is achieved by introducing heat treatment means or a crosslinking agent. -Impregnated with a hydrogen ion conductive polymer inside the porous support having a high porosity of the polymer material, and improved mechanical strength, electrochemical properties and durability, membrane-electrode assembly equipped with the reinforced composite electrolyte membrane And a fuel cell.

Unlike general batteries, fuel cells do not require battery replacement or charging, and are fuel cells that supply fuel such as hydrogen or methanol to convert chemical energy into electrical energy during combustion.

The fuel cell is a high efficiency power generation device with energy conversion efficiency of about 60%. It is more efficient than existing internal combustion engines, so it uses less fuel and is a pollution-free energy source that does not generate environmental pollutants such as SO _x , NO _x , and VOC. There is an advantage.

In addition, there are additional advantages, such as a variety of raw materials can be used for production, a small area required for production facilities, and a short construction period. Accordingly, fuel cells have a variety of applications ranging from mobile power supplies for portable devices, transport power supplies for automobiles, and the like to distributed generation available for home and power projects. In particular, when the operation of a fuel cell vehicle, a next-generation transportation device, becomes practical, the potential market size is expected to be wide.

There are five types of fuel cells according to operating temperature and electrolyte. Specifically, alkaline fuel cells (AFC), phosphoric acid fuel cells (PAFC), molten carbonate fuel cells (MCFC), and solid oxide fuel cells (SOFC) ), Polymer electrolyte fuel cells (PEMFC) and direct methanol fuel cells (DMFC). Among them, polymer electrolyte fuel cells and direct methanol fuel cells excellent in mobility have attracted great attention as future power sources.

Electrolyte membranes, which are key components of polymer electrolyte fuel cells and direct methanol fuel cells, must play a role in preventing fuel from moving from the anode to the cathode, in addition to the basic function as a membrane for hydrogen ion transfer. Therefore, the electrolyte membrane is a cation exchange membrane and must have chemical, thermal, mechanical and electrochemical stability at the same time as the hydrogen ion conductivity.

A representative example of the ion conductive polymer electrolyte membrane is Nafion, a perfluorine-based hydrogen ion exchange membrane developed by DuPont in the early 1960's. In addition to Nafion, as a similar perfluorinated polymer electrolyte membrane, Asahi Chemicals' Aciplex-S membrane, Dow Chemical's Dow membrane, Asahi Glass Flemion membrane of the company.

However, the conventional commercially available perfluorinated polymer electrolyte membrane has chemical resistance, oxidation resistance, and excellent ion conductivity, but environmental problems are pointed out due to high price and toxicity of intermediate products produced during manufacturing.

Accordingly, such perfluorinated subtotal and film polymer electrolyte have been studied introducing such group a carboxyl group, a sulfonic acid on the aromatic ring polymer in order to compensate for the polymer electrolyte membrane defect, an example of a sulfonated polyaryl ether sulfone [Journal of Membrane Science, 1993, 83 , 211], sulfonated polyether ether ketones [Japanese Patent Laid-Open No. Hei 6-93114, US Pat. No. 5,438,082], Sulfonated polyimide [US Pat. No. 6,245,881] and the like are known. However, the known polymer electrolyte membrane is prone to dehydration by acid or heat in the process of introducing sulfonic acid groups into the aromatic ring, and hydrogen ion conductivity is greatly affected by water molecules.

In addition, the above-mentioned perfluorine-based and hydrocarbon-based polymer electrolyte membranes face great limitations in the commercialization of fuel cells due to a sudden decrease in hydrogen ion conductivity and softening of the membrane and high methanol permeability due to a decrease in moisture content at 100 ° C. or higher. As a method to solve this problem, hydrocarbon polymers such as polyether (ether keton), polysulfone, polyimide, etc., which are relatively inexpensive and have various commercial applications, are available. Research is actively underway.

However, the alternative polymer electrolyte membrane having low fuel permeability also has a problem in that it is difficult to realize excellent performance of a polymer electrolyte fuel cell due to a decrease in dimensional stability as well as high water content when hydrating.

Therefore, in order to obtain improved cell performance of fuel cells, new materials excellent in dimensional stability and mechanical properties due to hydration of these alternative electrolyte membranes are urgently required.

As a prior art progressed in accordance with such a requirement, US Patent No. 5,547,551 manufactures a composite membrane in which Nafion solution (5 wt%) is introduced into e-PTFE, and Korean Patent No.746339 has excellent dimensional stability in sulfonated polymers. A blend composite film prepared by introducing is disclosed.

In addition, in order to improve oxidation resistance and thermal mechanical stability, which is the biggest disadvantage of the hydrocarbon-based polymer, and to overcome the low adhesion of the electrode caused by excessive swelling during the manufacture of the membrane electrode assembly (MEA), the reinforced composite electrolyte Research on reinforced composite electrolyte membranes is being actively conducted, such as reinforced composite electrolyte membranes marketed under the trade name Gore Select by WL Goore & Associates.

In general, the reinforced composite electrolyte membrane is determined by the chemical structure, pore size, porosity, and mechanical properties of the porous support employed to impart mechanical properties and dimensional stability, the performance of the final reinforced composite electrolyte membrane is determined. Therefore, since the porous support must have excellent hydrogen ion conductivity characteristics in the reinforced composite electrolyte membrane, high porosity, in particular, high porosity of 70% or more is required.

However, since having a high porosity shows a problem that the mechanical properties are lowered, the development of a porous support and an ion conductor having excellent mechanical properties, dimensional stability, and durability while maintaining high porosity is urgently required.

It is an object of the present invention to provide a porous support with improved strength while maintaining high porosity.

Another object of the present invention is to provide a reinforced composite electrolyte membrane impregnated with a hydrogen ion conductive polymer inside the porous support and a method of manufacturing the same.

It is another object of the present invention to provide a membrane-electrode assembly and a fuel cell, each having a high porosity and having a reinforced composite electrolyte membrane having excellent mechanical properties, dimensional stability, and durability.

In order to achieve the above object, the present invention provides a porous support of a polymer material having improved strength by the heat treatment means or cross-linking agent after the electrospinning.

The porous support of the present invention is selected from the group consisting of polyethylene, polypropylene, polyester, polyamide, cellulose, polysulfone, polyethersulfone, polyimide polyvinylidene fluoride, polyacrylonitrile and polyamideimide, or It consists of a polymer material of two or more mixed forms.

In the porous support of the present invention, the strength is improved by the ion crosslinking of 30 to 50% by the crosslinking agent introduced.

In addition, the porosity of the porous support of the present invention meets 20 to 80%.

The present invention provides a reinforced composite electrolyte membrane impregnated with a hydrogen ion conductive polymer inside a porous support having high porosity and excellent mechanical properties, dimensional stability, and durability.

In this case, the hydrogen ion conductive polymer may be used if it is a sulfonated hydrocarbon-based ion conductor, more preferably sulfonated polysulfone, sulfonated polyether sulfone, sulfonated polyether ketone, sulfonated polyarylene ether One or more selected from the group consisting of sulfones, polyaryletherbenzimidazoles and partially fluorine-introduced ion conductors are used.

The present invention 1) a first step of preparing a reinforced porous support of a polymer material having improved strength by electrospinning the polymer-containing spinning solution, heat treatment or introduction of a crosslinking agent; 2) preparing a polymer electrolyte solution in which a hydrogen ion conductive polymer is dissolved in a polar solvent, and impregnating the porous electrolyte with the polymer electrolyte solution; 3) after the impregnation process, a third step of forming a composite electrolyte membrane by forming a membrane by pressing the rolls by passing through the preheated metal rolls and 4) a fourth step of acid treating the composite electrolyte membrane. It provides a manufacturing method.

At this time, the porous support of step 1) is heat treatment is performed for 6 to 12 hours at a temperature of 250 to 350 ℃, more preferably 280 to 310 ℃ after electrospinning.

In addition, in step 1), the crosslinking agent is selected from the group consisting of divinylbenzene, methylenebisacrylamide and tetramethylene bis acrylamide for the purpose of improving the strength, and thus the crosslinking degree satisfies 30 to 50%. do.

The material of the porous support of the present invention is selected from the group consisting of polyethylene, polypropylene, polyester, polyamide, cellulose, polysulfone, polyethersulfone, polyimide, polyvinylidene fluoride, polyacrylonitrile and polyamideimide If it is a single or mixed polymer of two or more types can be used. In addition, it is formed by the electrospinning method using a spinning solution in which 10 to 50% by weight of the polymer is dissolved.

The porosity of the porous support of the present invention meets 20 to 80%.

In step 2) of the method for preparing a reinforced composite electrolyte membrane of the present invention, preferably, a sulfonated polysulfone, sulfonated polyethersulfone, sulfonated polyetherketone, sulfonated polyarylene ether sulfone And polyaryletherbenzimidazole and at least one selected from the group consisting of partially fluorine-containing ion conductors.

In step 3) of the method for producing a reinforced composite electrolyte membrane of the present invention, the dried membrane thickness is 1 to 10000 µm before the acid treatment.

Furthermore, the present invention provides a membrane-electrode assembly employing a reinforced composite electrolyte membrane having high porosity and excellent mechanical properties, dimensional stability, and durability at the same time, and a fuel cell having the same.

According to the present invention, after the electrospinning, it is possible to provide a porous support made of a polymer material having improved strength by introducing heat treatment means or a crosslinking agent.

In particular, the present invention is an invention devised from the fact that it is possible to prepare a porous support made of a polymer material having a significantly improved strength by introducing a heat treatment or crosslinking agent in the form of a nonwoven web formed by electrospinning, which can be applied to electrospinning. It is possible to provide a porous support made of various polymers.

In addition, it is possible to provide a reinforced composite electrolyte membrane impregnated with a hydrogen ion conductive polymer inside the porous support.

Furthermore, the performance improvement of the membrane-electrode assembly and fuel cell provided with the reinforced composite electrolyte membrane of the present invention can be expected.

Hereinafter, the present invention will be described in detail.

The present invention provides a porous support having a tensile strength of up to 25 MPa as a porous support of a polymer material having improved strength by introducing heat treatment means or a crosslinking agent after electrospinning.

1 is a surface photograph before heat treatment performed on the porous support of the present invention, Figure 2 is a surface photograph after heat treatment performed on the porous support of the present invention, Figure 3 is the result of measuring the change in tensile strength before and after heat treatment. From the above, the porous support of the polymer material of the present invention entails a significant improvement in mechanical strength by heat treatment means after electrospinning.

In addition, the porous support of the present invention may be implemented by ion crosslinking, as well as crosslinking by the heat treatment, for the purpose of strength improvement.

At this time, the preferred crosslinking agent may be any one selected from the group consisting of divinylbenzene, methylenebisacrylamide and tetramethylene bis acrylamide, but is not limited thereto.

30-50% of the crosslinking degree by the crosslinking degree introduction of this invention is preferable. At this time, if the degree of crosslinking is less than 30%, the porous support is dissolved in a solvent and difficult to use. If the crosslinking degree is greater than 50%, flexibility is reduced and brittleness is generated, which is not preferable.

Accordingly, the present invention may provide various porous supports made of various polymer materials that can be applied to electrospinning.

Thus, the porous support of the present invention is to be used for the purpose of improving the durability, and thus performs a function of improving chemical resistance, oxidation resistance and thermal / mechanical stability. Preferred materials for the porous support used for this purpose include polyethylene, polypropylene, polyester, polyamide, cellulose, polysulfone, polyethersulfone, polyimide polyvinylidene fluoride, polyacrylonitrile and polyamideimide Single or mixed forms of two or more selected from the group can be used.

Among the above, more preferably single or two or more kinds selected from polyethylene, polypropylene, polyester, polyamide, polyimide, polybenzimidazole and polyamideimide which are excellent in chemical resistance, oxidation resistance and thermal / mechanical stability It is to use the material of the form.

It is preferable that the porosity of the porous support is 20 to 80%. If the porosity is less than 20%, a drastic reduction of the hydrogen ion conductivity property occurs, and if it exceeds 80%, the mechanical and chemical resistance or thermal properties Falls out.

On the other hand, in the form of the support, it is possible to form a pore, a nonwoven fabric, and the like, but considering the uniform impregnation of the ion conductor and the resulting ion conduction characteristics, the nonwoven fabric is preferable. Thus, in the embodiment of the present invention, the nonwoven fabric is described as a preferred embodiment, but is not limited thereto.

The present invention provides a reinforced composite electrolyte membrane impregnated with a hydrogen ion conductive polymer inside a porous support having improved strength while maintaining the high porosity.

Figure 4a shows the surface of the reinforced composite electrolyte membrane according to the present invention, while the pores due to the porous support is not observed, showing a dense structure, Figure 4b is a cross-section of the reinforced composite electrolyte membrane, the porous support is confirmed inside the membrane As a result, good mechanical strength results will be supported.

In this case, various hydrogen ion conductive polymers that can be impregnated into various porous supports used in the reinforced composite electrolyte membrane of the present invention can be applied, and by applying a known sulfonated hydrocarbon-based ion conductor, high porosity can be maintained. At the same time, it is possible to provide various types of reinforced composite electrolyte membranes having mechanical properties and dimensional stability.

Examples of hydrogen ion conductive polymer electrolytes that can be used in the reinforced composite electrolyte membrane of the present invention include sulfonated polysulfone, sulfonated poly (ether sulfone), and sulfonated polyether ketone. (sulfonated poly (ether ketone)), sulfonated poly (arylene ether sulfone), SPAES, poly (arylether benzimidazole) and partially fluorinated ion conductors One or more ion conductors selected from the group consisting of More preferably sulfonated polyaryleneethersulfone or polyaryletherbenzimidazoles having excellent ion conductivity and thermal / mechanical stability are used.

In addition, the present invention 1) the first step of preparing a reinforced porous support of a polymer material having improved strength by the heat treatment or introduction of a crosslinking agent after the electrospinning of the polymer-containing spinning solution,

2) preparing a polymer electrolyte solution in which a hydrogen ion conductive polymer is dissolved in a polar solvent and impregnating the polymer electrolyte solution in the porous support;

3) after the impregnation process, a third process of forming a composite electrolyte membrane by forming a composite electrolyte membrane by pressing the roll through the pre-heated metal roll to form a film;

4) Provided is a method for producing a reinforced composite electrolyte membrane comprising a fourth step of acid treating the composite electrolyte membrane.

Step 1) in the manufacturing method of the present invention to prepare a high molecular weight polymer spinning solution with an intrinsic viscosity of 0.4 dL / g or more, the polymer spinning solution to control the nozzle and the spinning distance of various diameters, applying a high voltage Spinning produces a porous support.

In this case, the polymer-containing spinning solution is selected from the group consisting of polyethylene, polypropylene, polyester, polyamide, cellulose, polysulfone, polyethersulfone, polyimide, polyvinylidene fluoride, polyacrylonitrile and polyamideimide 10 to 50% by weight of the solid content of the polymer alone or in combination of two or more thereof is dissolved. At this time, when the concentration of the polymer spinning solution of the present invention is less than 10% by weight, a short circuit phenomenon in which the spun fibers are broken is observed. A problem arises.

At this time, the spinning nozzle and the spinning distance to be carried out during the electrospinning can be adjusted, the spinning nozzle of the preferred embodiment can be carried out using a stainless steel tube having a diameter of 0.25mm or 0.42mm, but is not limited thereto. The discharge speed may be adjusted according to the spinning nozzle.

The collector used during the electrospinning is made of an electrically conductive metal plate or a metal mesh, and the shape thereof is not particularly limited, but a circular plate or a rectangular plate is a plate-type collector. The size of the plate-shaped collector may vary depending on the viscosity of the polymer solution and the threshold voltage (Vc) accordingly, but is preferably more than the trapping area of the nanofibers produced by spinning from the spinning nozzle. In addition, the distance between the spinneret and the collector may be adjusted within a range in which the spun fiber is not shorted, preferably 5 to 20 cm, but is not limited thereto.

In the manufacturing method of the present invention, the heat treatment in step 1) may be carried out within 250 to 350 ° C., more preferably at 280 to 310 ° C., for 6 to 12 hours to perform ion crosslinking to prepare a porous support having excellent mechanical strength. At this time, if the heat treatment temperature is less than 250 ℃, the heat treatment is not sufficiently heat-treated to the inside of the support can not obtain a high strength porous support, there is a disadvantage that takes a long heat treatment time in terms of efficiency. In addition, if the temperature exceeds 350 ° C., the high thermal strain produces non-uniform strength of the support, and due to the rapid increase in strength, the ductility disappears and cracks and fractures occur in the support.

In addition, in order to improve the strength in step 1), there is a method of ion crosslinking by introducing a crosslinking agent in parallel with the heat treatment process. In this case, the crosslinking agent is any one selected from divinylbenzene, methylenebisacrylamide or tetramethylene bis acrylamide, and preferably divinylbenzene is used. In order to promote the crosslinking reaction, it may be carried out by adding an initiator selected from N, N'-azobisisobutyronitrile (AIBN), benzoyl peroxide (BPO) or dicumyl peroxide.

The degree of crosslinking by the crosslinking agent may be implemented in 30 to 50% to prepare a porous support having excellent strength.

In the manufacturing method of the present invention, when the heat treatment process or the crosslinking agent is not introduced in step 1), a phenomenon in which the porous support is dissolved in a polar solvent used in the preparation of the hydrogen-ion conductive polymer electrolyte solution occurs, so that the durability and mechanical properties of the porous support are generated. This results in a decrease in strength.

Step 2) in the manufacturing method of the present invention is a process of impregnating the porous support with a polymer electrolyte solution in which a hydrogen ion conductive polymer is dissolved in a polar solvent.

In this case, the hydrogen ion conductive polymer to be used may be used if it is a sulfonated hydrocarbon-based ion conductor, preferred examples thereof are sulfonated polysulfone, sulfonated polyether sulfone, sulfonated polyether ketone, sulfonated polyaryl One or more selected from the group consisting of eneethersulfones, polyaryletherbenzimidazoles, and partial fluorine-containing ion conductors is used.

In addition, the solvent for dissolving the hydrogen ion conductive polymer is not particularly limited in view of the purpose of the invention, it may be appropriately selected according to the type of the selected hydrogen ion conductive polymer. That is, there is no particular limitation as long as it is a polar solvent as the solvent used for the above purpose, preferably N, N-dimethylacetamide, N-methyl-α-pyrrolidone, N-methyl-2-pyrrolidone, dimethyl sulfo One or two or more mixed solvents selected from oxides may be used.

In addition, the step of impregnating the porous support is also not particularly limited, and may be any method in which the polymer electrolyte solution in which the hydrogen ion conductive polymer is dissolved is uniformly applied to the porous support.

Examples thereof include a casting method, a melting method, a roll pressing method, and the like, and preferably, the casting process is performed with a uniform coating thickness when the porous support is impregnated.

In the manufacturing method of the present invention, step 3) is a step of forming a composite electrolyte membrane by forming a composite electrolyte film by forming a film by compressing a roll by passing through the preheated metal rolls after the impregnation process of step 2).

At this time, by using a roll pressing method that passes through a preheated roll at 120 ° C. for uniform surface and uniform impregnation of the cast membrane, a reinforced composite electrolyte membrane uniformly impregnated due to the remaining trace amount of polar solvent can be prepared.

In addition, in order to prevent expansion and contraction of the prepared composite electrolyte membrane, the membrane is fixed in a rectangular frame, and then slowly dried in an inert atmosphere of 40 ° C. to 60 ° C. to prevent the formation of pinholes, and then to 120 ° C. Dry for 3 hours in a reduced pressure drier to completely remove the remaining solvent.

In the drying step, when initially dried at a temperature exceeding 60 ° C., many pinholes are formed, and the thickness of the composite membrane becomes uneven due to uneven drying, and wrinkles and cracks occur due to rapid shrinkage and expansion of the membrane. On the other hand, when slowly drying at a temperature of less than 40 ℃ does not cause a special problem, but there is a problem that unnecessarily long drying time.

In this case, the thickness of the electrolyte membrane prepared by the above method is preferably 1-10000 μm before the drying.

Thereafter, step 4) in the manufacturing method of the present invention is an acid treatment of the prepared composite electrolyte membrane, and acid treatment is an acid (SO ³ -H) capable of transferring hydrogen ions in a sodium salt (SO ^3- Na ⁺ ) state. ⁺ ) To complete conversion to form. At this time, the acid treatment is carried out under 80 to 120 ℃ and acid solution conditions for 2 to 3 hours, and is not particularly limited to the type of acid used, sulfuric acid (H ₂ SO ₄ ), nitric acid (HNO ₃ ), phosphoric acid (H It is preferable to select one of strong acids such as ₃ PO ₄ ), hydrochloric acid (HCl) and the like.

Furthermore, the present invention provides a membrane-electrode assembly employing the reinforced composite electrolyte membrane and a fuel cell provided with the membrane-electrode assembly.

In other words, by employing a reinforced composite electrolyte membrane having high ion conductivity, low water content and excellent dimensional stability, it is expected to improve the performance of the membrane-electrode assembly and the fuel cell.

Hereinafter, the present invention will be described in more detail with reference to Examples.

This embodiment is intended to illustrate the present invention in more detail, and the scope of the present invention is not limited to these examples.

Example 1 Preparation of a Porous Support in the Form of Polyamide-imide (PAI) Nonwoven Fabric

An acyl halide such as thionyl chloride is dissolved in a polar solvent such as 1-methyl-2-pyrrolidinone (NMP, NMP), cooled to 5 ° C or lower, and then prepared at a room temperature. Aromatic tricarboxylic acid anhydride is added and stirred at room temperature within 1 hour, continuously adding aromatic diamine and reacting at 50-130 ° C. for 5 hours or less, intrinsic viscosity (solvent: DMAc, temperature: 30 ° C., concentration 0.5 g) / dL) was polymerized with a PAI resin of 0.4 dL / g or less. Subsequently, the phosphorus compound of triphenylphosphite (hereinafter referred to as TPP) was continuously reacted using 50 mol% or less of the monomer to prepare a PAI having a high molecular weight of 0.4 dL / g or more.

The prepared PAI polymer was prepared in a polymer spinning solution at a concentration of 10% by weight on a polar solvent DMAc, and the polymer spinning solution was electrospun onto a collector through a nozzle having a diameter of 0.25 mm under a voltage of 15 kV and a spinning distance of 10 cm. Thereafter, the PAI fiber web electrospun on the collector was separated to prepare a porous support of PAI material in the form of a nonwoven fabric.

In order to improve the mechanical strength of the porous support of the PAI material prepared above, the PAI porous support was heat-treated for 12 hours at a temperature range of 280 ~ 310 ℃ of the high temperature dryer.

In addition, PAI (TORLON 4000T), which is a powder state produced by SOLVAY SOLEXIS, was purchased and carried out in the same manner as the electrospinning method to prepare a porous support of PAI material.

Example 2 Preparation of a Reinforced Composite Electrolyte Membrane 1

Step 1: preparation of sulfonated polyarylene ether sulfone copolymer having a sulfonation degree of 50%

A 100 ml branched round flask was fitted with a gas inlet, thermometer, Dean-Stark trap, cooler and stirrer, removed air and impurities for several minutes in a nitrogen atmosphere, and then 4,4'dichlorodiphenylsulfone 3.4460 g, 4.4 ' 3.7242 g of biphenol (hereinafter referred to as "BP"), 3.9301 g of disulfonated dichlorodiphenyl sulfone, 3.1787 g of potassium carbonate, 44.4 ml of NMP, and 22.2 ml of toluene (NMP / toluene = 2/1 V / V) were added thereto. The monomer was dissolved while stirring at 80 ° C. or higher for 1 hour.

Then, after raising the temperature of the reaction solution to 160 ℃, refluxed with toluene for 4 hours to remove the water of the reaction product, and then heated to 190 ℃ again to remove residual toluene from the Dean-Stark trap completely for 24 hours I was. After the reaction was completed, the reaction solution was diluted with NMP, filtered, poured into water, precipitated in the form of swollen fibers, and filtered. Thereafter, the obtained reaction product was dried in a vacuum dryer at 120 ° C. for 24 hours to obtain a sulfonated polyarylene ether sulfone (SPAES-50), which is a sulfonated polymer copolymer.

Step 2: Preparation of Reinforced Composite Electrolyte Membrane

5% by weight of sulfonated polyarylene ether sulfone (SPAES) copolymer prepared in step 1 having a degree of sulfonation degree of 50% in N-methyl-2-pyrrolidone (NMP) at 80 ° C. After dissolving at a concentration of and impregnated in the porous support prepared in Example 1 and after the first drying process in the temperature range of 40 ℃ ~ 60 ℃ passed through two metal rolls heated to 120 ℃ and compression and After the heat treatment process, a reinforced composite electrolyte membrane having a thickness of 50 ㎛ was prepared through a vacuum drying process of 60 ~ 120 ℃.

Since the prepared composite electrolyte membrane is in the form of sodium salt (SO ^3- Na ⁺ ), 0.5 mole of sulfuric acid (H ₂₎ at 100 ° C. for the purpose of completely converting to a form of acid (SO ³ -H ⁺ ) capable of hydrogen ion transfer. SO ₄ ) After the acid treatment for 2 hours in the solution to remove the residual acid after washing for 2 hours or more in a third distilled water of 100 ℃ repeated washing several times to prepare a reinforced composite electrolyte membrane.

Example 3 Preparation of Reinforced Porous Support Using Crosslinking Agent

In the solution containing N, N'-azobisisobutyronitrile (AIBN) using divinylbenzene (DVB) as a crosslinking agent, a nonwoven fabric of PAI material prepared in Example 1 was used as a crosslinking agent. After immersion, the reaction was carried out at 80 to 120 ° C. for 30 minutes to 12 hours, followed by repeated washing several times at 60 ° C. using ethanol to remove residual DVB, and having a porosity of 30% through ionic crosslinking. The support was prepared.

Comparative Example 1 Preparation of Electrolyte Membrane

The sulfonated polyarylene ether sulfone (SPAES) copolymer having a level of degree of sulfonation of 50% prepared in step 1 of Example 2 was dissolved in N-methyl-2-pyrrolidone (NMP). After filtering, the resultant was filtered using a 0.45 μm pore size PTFE syringe filter and poured directly onto a clean glass plate without surface scratches. The solvent used in the preparation of the casting solution was slowly dried in an inert atmosphere at 60 ° C., and then dried in a reduced pressure dryer at 100 ° C. for 3 hours or more to completely remove the solvent, thereby preparing an electrolyte membrane having a thickness of 50 μm. After the preparation was carried out in the same manner as the acid treatment of step 2 of Example 2 above.

Comparative Example 2

Nafion ™ 115 (US Dupont) was commercialized by removing impurities with 3% hydrogen peroxide, followed by washing for 2 hours in 0.5M sulfuric acid, and then washing in tertiary distilled water several times.

Experimental Example 1 Structure Analysis of the Reinforced Composite Electrolyte Membrane

1 is a scanning electron microscope (FE-SEM) result before heat treatment of a polyamideimide (PAI) nonwoven fabric used as a porous support of the reinforced composite electrolyte membrane of the present invention, Figure 2 is a scanning electron microscope (FE-SEM) after heat treatment It is a result of comparing the results, Figure 3 shows the results of the change in tensile strength of the polyamideimide (PAI) nonwoven fabric before and after heat treatment.

From the above, it was confirmed that in the reinforced composite electrolyte membrane of the present invention, the porous support significantly increased the mechanical strength after the heat treatment process.

4A shows the porosity of the porous support before impregnation of the sulfonated polyarylene ether sulfone (SPAES) copolymer, a hydrogen ion conductive polymer, as a result of scanning electron microscopy (FE-SEM) on the surface of the reinforced composite electrolyte membrane of the present invention. No structure was observed, and the surface of the reinforced composite electrolyte membrane after impregnation confirmed a dense structure in which no pores were observed. On the other hand, Figure 4b is to observe the cross-section of the reinforced composite electrolyte membrane, by confirming the porous support structure inside the membrane, to support the mechanical strength improvement.

Experimental Example 2 Evaluation of Properties of Reinforced Composite Electrolyte Membrane

1. Water absorption rate measurement

In order to measure the water absorption rate of the prepared electrolyte membrane, the electrolyte membranes prepared in Example 2, Comparative Example 1 and Comparative Example 2 were washed several times with deionized water, and the washed polymer electrolyte membrane was immersed in deionized water for 24 hours. After removing and removing the water present on the surface was weighed (W _wet ). The same membrane was then again dried for 24 hours in a reduced pressure dryer at 120 ° C. and again weighed (W _dry ). The water absorption was calculated by the following equation .

2. Dimensional stability measurement

Dimensional stability of the electrolyte membrane prepared above was performed in the same manner as the water absorption rate measurement method, but instead of measuring the weight, after measuring the area (A) change of the membrane, it was calculated by the following equation (2 ).

3. Ionic Conductivity Measurement

In order to measure the ionic conductivity of the electrolyte membrane prepared above, for the electrolyte membrane prepared in Example 2, Comparative Example 1 and Comparative Example 2, the measuring equipment in the measurement temperature range 25 ℃ [Solatron-1280Impedance / Gain from Solartron -Phase analyzer] was used to measure the ion conductivity. At this time, the impedance spectrum was recorded from 10MHz to 10Hz, the ion conductivity was calculated by the following equation (3 ).

(Wherein, R is the measurement resistance (길이), L is the length (cm) between the measurement electrodes, A is the cross-sectional area (cm 2) of the prepared electrolyte membrane).)

4. Methanol Permeability Measurement

Methanol permeability was calculated by Equation 4 by mounting an electrolyte membrane between a constant concentration of methanol and water, and measuring the concentration of methanol over time with a refractive index detector (R1750F Younglin instrument). .

(In the above, a is the slope in the time-concentration graph, V _B is the volume of permeated methanol (cm 3), L is the thickness of the electrolyte membrane (cm), A is the area of the electrolyte membrane (cm 2), and C _A is used. Shows the concentration of methanol.)

Table 1 shows the results of evaluating the properties of the fuel cell reinforced composite electrolyte membrane.

From Table 1, the dimensional stability and the water absorption rate of the important area in the membrane-electrode assembly were observed, and in the case of the reinforced composite electrolyte membrane prepared in Example 2 of the present invention, it was confirmed that there is almost no change. Accordingly, it was confirmed that physical properties such as dimensional stability and water absorption rate, which are suitable for fuel cell applications, were compared with those of a polymer electrolyte membrane composed of sulfonated polyarylene ether sulfone (SPAES) copolymer only (Comparative Example 1).

That is, in the case of the reinforced composite electrolyte membrane of the present invention, the water absorption rate was reduced to less than half as compared to the polymer electrolyte membrane (Comparative Example 1) consisting of only sulfonated polyarylene ether sulfone (SPAES) copolymer, and the comparative example Compared to 1 and commercial electrolyte membrane (Comparative Example 3), similar levels of hydrogen ion conductivity were shown.

However, the reinforced composite electrolyte membrane of the present invention was compared with a polymer electrolyte membrane composed of only sulfonated polyarylene ether sulfone (SPAES) copolymer (Comparative Example 1) as a result of comparing hydrogen ion conductivity and membrane resistance, and hydrogen ion conductivity. Due to the free porous support, the hydrogen ion conductivity was somewhat reduced, but the actual membrane resistance considering the thickness of the sulfonated polyarylene ether may be considerably lowered due to the excellent mechanical strength of the reinforced composite electrolyte membrane of the present invention. It can be controlled to an equivalent level or higher than a polymer electrolyte membrane made of a sulfone (SPAES) copolymer.

In addition, as a result of measuring methanol permeation characteristics, Example 2 showed much lower 5.25 × 10 ⁻⁷ cm 2 / s as compared to the 1.65 × 10 ⁻⁶ cm 2 / s result for the commercialized Nafion 115 (Comparative Example 2). Therefore, it was confirmed that the reinforced composite electrolyte membrane of the present invention lowered methanol permeability and improved methanol permeation characteristics.

From the above results, when applying the reinforced composite electrolyte membrane of the present invention to the membrane-electrode assembly in the future, it can be expected that fuel cell characteristics equal to or higher than the polymer electrolyte membrane composed of sulfonated polyarylene ether sulfone (SPAES) copolymer alone. have.

As described above, the present invention provides a reinforced composite electrolyte membrane in which a hydrogen ion conductive polymer is impregnated into a porous support whose strength is improved by heat treatment or crosslinking agent after electrospinning, thereby providing a polymer electrolyte composed of only a conventional hydrogen ion conductive polymer. Compared to the membrane, the dimensional stability, water absorption rate and methanol permeability are improved, so that it can be applied as an electrolyte membrane for fuel cells or polymer electrolyte fuel cells and direct methanol fuel cells.

Although the present invention has been described in detail only with respect to the embodiments described, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and such modifications and modifications belong to the appended claims. .

1 is a scanning electron microscope (FE-SEM) photograph before heat treatment of a polyamideimide (PAI) nonwoven fabric used as a porous support in the present invention,

2 is a scanning electron microscope (FE-SEM) photograph after heat treatment of the polyamideimide (PAI) nonwoven fabric used as the porous support in the present invention,

Figure 3 is a photograph measuring the change in tensile strength before and after heat treatment of the polyamideimide (PAI) nonwoven fabric used as a porous support in the present invention,

4A is a scanning electron microscope (FE-SEM) photograph of the surface of the reinforced composite electrolyte membrane according to the present invention;

4B is a scanning electron microscope (FE-SEM) photograph of the cross-section of the reinforced composite electrolyte membrane of FIG. 4A.

Claims (17)

delete delete delete delete The non-woven web made of a polymer material is crosslinked by heat treatment or introduction of a crosslinking agent, so that the crosslinking degree is 30 to 50%, the porosity is 20 to 80%, and the hydrogen ion conductive polymer is inside the porous support having a tensile strength of up to 25 MPa. Reinforced composite electrolyte membrane. 6. The reinforced composite electrolyte membrane according to claim 5, wherein the hydrogen ion conductive polymer is a sulfonated hydrocarbon-based ion conductor. 7. The sulfonated hydrocarbon-based ion conductor according to claim 6, wherein the sulfonated hydrocarbon-based ion conductor is sulfonated polysulfone, sulfonated polyether sulfone, sulfonated polyether ketone, sulfonated polyarylene ether sulfone, sulfonated polyaryl ether Said reinforced composite electrolyte membrane, characterized in that at least one selected from the group consisting of benzimidazole and partially fluorine-containing ion conductor. 1) a first step of preparing a non-woven web type reinforced porous support made of a polymer material by electrospinning a polymer-containing spinning solution to form a nonwoven web, and then improving the strength of the nonwoven web by heat treatment or introducing a crosslinking agent; 2) preparing a polymer electrolyte solution in which a hydrogen ion conductive polymer is dissolved in a polar solvent and impregnating the polymer electrolyte solution in the porous support; 3) after the impregnation process, a third process of forming a composite electrolyte membrane by forming a composite electrolyte membrane by pressing the roll through the pre-heated metal roll to form a film; 4) A method for producing a reinforced composite electrolyte membrane comprising a fourth step of acid treating the composite electrolyte membrane. The method of claim 8, wherein the heat treatment is performed at a temperature of 250 to 350 ° C. for 6 to 12 hours. The method for producing the reinforced composite electrolyte membrane according to claim 8, wherein any one selected from the group consisting of divinylbenzene, methylenebisacrylamide and tetramethylene bis acrylamide is introduced. The method of claim 8, wherein the crosslinking degree by introducing the crosslinking agent is 30 to 50%. The group of claim 8, wherein the porous support is made of polyethylene, polypropylene, polyester, polyamide, cellulose, polysulfone, polyethersulfone, polyimide, polyvinylidene fluoride, polyacrylonitrile and polyamideimide Method for producing a reinforced composite electrolyte membrane, characterized in that 10 to 50% by weight of the polymer selected solely or in a mixture of two or more selected from the prepared in the spinning solution dissolved in a polar solvent. The method of claim 8, wherein the porosity of the porous support is 20 to 80%. The method of claim 8, wherein the hydrogen ion conductive polymer is sulfonated polysulfone, sulfonated polyether sulfone, sulfonated polyether ketone, sulfonated polyarylene ether sulfone, sulfonated polyaryletherbenzimidazole And at least one selected from the group consisting of ion conductors into which partial fluorine has been introduced. The method for producing the reinforced composite electrolyte membrane according to claim 8, wherein the dried film thickness is 1 to 10000 µm before the acid treatment. A membrane-electrode assembly employing the reinforced composite electrolyte membrane of claim 5. A fuel cell employing the membrane-electrode assembly of claim 16.

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