ES2976760A1 - Procedure for obtaining a membrane-electrode assembly unit (MEA) in electrochemical devices - Google Patents

Abstract

Method for obtaining a membrane-electrode assembly unit (MEA) in electrochemical devices. The present invention relates to a method for obtaining a membrane-electrode assembly unit (MEA) for electrochemical devices such as fuel cells, ion exchange electrolysers, redox flow batteries and other energy generation or storage systems, which allows assembly when the membrane used is not purely polymeric in nature (non-commercial) and improves assembly when it is. This new procedure comprises a stage prior to pressing that facilitates assembly between the components and improves the interfaces, facilitating their handling, improving their efficiency in the cell and their post-mortem analysis. The invention can be framed in the area of materials science and energy, and is of interest to industries that manufacture electrochemical components, as well as small electronic devices or biomaterials.

Description

DESCRIPTION

Procedure for obtaining a membrane-electrode assembly unit (MEA) in electrochemical devices

The present invention relates to a method for obtaining a membrane electrode assembly (MEA) unit for electrochemical devices such as fuel cells, ion exchange electrolysers, redox flow batteries and other energy generation or storage systems, which allows assembly when the membrane used is not purely polymeric in nature (non-commercial) and improves assembly when it is. This new method comprises a stage prior to pressing that facilitates assembly between the components and improves the interfaces, facilitating their handling, improving their efficiency in the cell and their post-mortem analysis. The invention can be framed in the area of materials science and energy, and is of interest to industries that manufacture electrochemical components, as well as small electronic devices or biomaterials.

BACKGROUND OF THE INVENTION

Optimization of the processing stage of the membrane-electrode assembly (MEA) unit is necessary especially when non-commercial components, new gas diffusion layers (GDL), new catalytic layers or new membranes are used. However, the most determining factor in this assembly is the nature of the membrane used in the MEA unit.

In the specific case of proton exchange membrane fuel cells (PEMFC), the proton exchange membrane acts as an electrolyte, transporting the protons generated in the anode to the cathode, and also as a separator between the two electrodes. In the case of anion exchange fuel cells (AEMFC), the membrane is a conductor of hydroxyl anions. Therefore, the requirements that the membrane must have in these devices are: it must have high ionic conductivity, be an electronic insulator and be impermeable to both fuel and oxygen. It must also be chemically and mechanically resistant under the operating conditions of the cell and, finally, it must be able to be obtained at low cost in the form of thin films.

Most commercial PEMFCs use the Nafion® polymer electrolyte, developed by DuPont in the late 1960s. Its chemical structure consists of a main polymer chain of polytetrafluoroethylene of a hydrophobic nature responsible for its mechanical stability and side chains terminated with sulfonic groups that are hydrophilic in nature and are responsible for ionic transport. Under suitable hydration conditions, these sulfonic groups dissociate, providing the polymer with ionic conductivity. Nafion® has been and is an extensively studied material and, in principle, has the electrical, chemical and mechanical properties necessary to function correctly as an electrolyte in PEMFCs. However, experience has helped to determine the disadvantages of its use, which are, firstly, its high price; secondly, the fact that its ionic conductivity decreases significantly with temperature due to dehydration problems; and finally, its high permeability to methanol, which in the case of direct methanol fuel cells (DMFC) is a serious and important problem. For all these reasons, different lines of research have emerged over the last few decades that aim to improve the characteristics of Nafion® or to replace it with new materials with better performance. Among others, there are proton exchange membranes based on polymers with sulfonated styrene groups that improve the dimensional and oxidative stability of sulfonated polystyrene itself at high levels of humidity, for example, sulfonated styrene-ethylene-butylene-styrene (sSEBS). However, sSEBS membranes with high conductivity values absorb a lot of water and at the same time experience a significant loss of dimensional stability that compromises their lifetime.

Other membranes with styrene groups are graft polymers based on a stable hydrophobic main chain to which sulfonated polystyrene chains are grafted, and, on the other hand, there are membranes based on polymers with aromatic groups in the main chain such as polysulfones and polyetheretherketones; other membranes are based on sulfonated polyphosphazenes, sulfonated polyimides, especially naphthalene ones, as well as polybenzimidazole membranes doped with phosphoric acid. However, all of them have different limitations and problems: they have lower conductivities than Nafion®, excessive swelling and loss of mechanical stability, limited mechanical properties due to their low glass transition temperature that improve at the expense of operating in hydrated atmospheres, dimensional instability in the hydrated state that leads to chain splits and low durability, as well as low solubility that makes membrane preparation difficult or problems with diffusion of phosphoric acid out of the membrane after long operating times that cause a sudden drop in conductivity, respectively.

Finally, another possibility is the formation of flexible ionomeric networks from mixtures of acidic polymers such as sulfonated polysulfones and basic polymers such as polybenzimidazole. These networks contain ionic bonds formed from a proton transfer from the acidic group to the basic group, which when dry are less fragile than their individual components, probably due to the flexibility of the ionic bonds [M. Walter, K. -M. Baumgartner, M. Kaiser, J. Kerres, A. Ullrich, E. Rauchle, Proton-Conducting Polymers with Reduced Methanol Permeation, J. Appl. Polym. Sci. 74 (1999) 67].

In order to function correctly as electrolytes in PEMFC and DMFC, both Nafion® type perfluorosulfonated membranes and the new developments described (except in the particular case of phosphoric acid doped polybenzimidazole membranes) require the absorption of a large amount of water, which in many cases leads to a loss of dimensional stability. On the other hand, increasing the working temperature above 80°C causes very significant losses of proton conductivity due to dehydration problems. The development of organic-inorganic hybrid membranes is shown to be the most suitable approach to solve these problems since they combine the thin film forming properties and low temperature proton conductivity of the organic component with the thermal and chemical stability and the possibility of obtaining high temperature proton conductivity provided by the inorganic component, in addition to a decrease in methanol crossover [D. Dhanapal, M. Xiao, S. Wang Y. Meng, A Review on Sulfonated Polymer Composite/Organic-Inorganic Hybrid Membranes to Address Methanol Barrier Issue for Methanol Fuel Cells, Nanomaterials 9(5) (2019) 668].

Hybrid membranes can be classified into two main groups based on the nature and strength of the interaction between both components. Class I membranes (which consist of an ionomeric matrix in which inorganic particles, generally of nanometric size, are dispersed) in which weak bonds are established, such as hydrogen bonds, van der Waals or electrostatic forces, and Class II membranes (where the interaction between the components is at a molecular level, so both must include functional groups in their structure capable of reacting with each other to form chemical bonds, usually synthesized by sol-gel) whose bonds are covalent or ionic-covalent. Sometimes the border between both classes is diffuse and there may be systems with characteristics of both groups.

The MEA unit is the central component of an ion exchange membrane fuel cell (or electrolyzer). To improve the efficiency of processing and manufacturing such an assembly, different strategies have been designed, such as improving the fragility of the gas diffusion layer through the addition of polymers such as Teflon® or the use of fabrics instead of carbon paper; also through new processes such as roll to roll or other industrial processes commonly used in the polymer materials industry. Much research has also been carried out on improving the catalytic ink that is deposited on the gas diffusion layer, both in the synthesis of the ink itself and in the method used for its deposition. On the other hand, various temperature and pressure parameters have been described for the hot pressing assembly stage of the components.

The limiting factor in most hot-pressed membrane-electrode assemblies is the ease with which stresses can be created, especially at the edges of the active area and even more so at the points where the gases are fed, facilitating the formation of microcracks that lead to lower cell performance and may even end up short-circuiting the system.

The preparation methods of MEA units are grouped into two techniques [J. Zhao; S. Shahgaldi; A. OzdenIbrahim; E. Alaefour; X. Li; F. Hamdullahpu, Effect of catalyst deposition on electrode structure, mass transport andperformance of polymer electrolyte membrane fuel cells, Applied Energy 255 (2019) 113802], depending on the substrate on which the catalytic layer is deposited. 1) When the catalytic layer is deposited on the gas diffusion layer GDL (Gas Diffusion Layer), the method is called CCS (Catalyst Coated on Substrate) or also GDE method (Gas Diffusion Electrode) [E. López-Fernández; C. Gómez Sacedón; J. Gil-Rostra; F. Yubero; A. R. González-Elipe; A. de Lucas-Consuegra, Recent Advances in Alkaline Exchange Membrane Water Electrolysis and Electrode Manufacturing, Molecules 26 (2021) 6326]; and 2) when the catalytic layer is deposited directly on the membrane, called the CCM method (Catalyst Coated on Membrane) [JP2006260909A, 2006-09-28]. In the CCS method, the most commonly used technique to deposit the catalytic layer is airbrushing (screen printing, painting, collage, etc.), with different modifications. For the CCM technique, which is widely used in recent years, airbrushing (screen printing, painting, collage, etc.) is also used directly on the membrane, as well as the so-called decal transfer method. In both techniques, a “sandwich” is prepared between the electrodes and the membrane; In CCS, the corresponding electrolyte (membrane) is placed between the prepared electrodes, and in the CCM method, a GDL is used since the catalytic layers have already been deposited on both sides of the membrane. They are then hot-pressed from room temperature to temperatures of 200°C [K. Talukdar; S. Delgado; T. Lagarteira; P. Gazdzicki; A. K. Friedrich, Minimizing mass-transport loss in proton exchange membrane fuel cell by freeze-drying of cathode catalyst layers, Journal of Power Sources 427 (2019)] using a hydraulic press. The MEA is usually placed in the measuring cell between two seals to prevent gas leaks and short circuits between bipolar plates and/or terminals.

However, to date, no MEA unit assemblies have been reported that improve mechanical properties, improve the diffusion of external gases, or improve the electrode-electrolyte interfaces. Nor have MEA unit assemblies been reported to date that allow the use of purely inorganic membranes or organic-inorganic hybrids with a high non-polymeric component content.

DESCRIPTION OF THE INVENTION

The present invention relates to a method for obtaining a key component in fuel cells and low-temperature electrolysers, such as the membrane-electrode assembly, the MEA unit. The new method is particularly advantageous when the membrane is of an inorganic or organic-inorganic hybrid nature with a high content of non-polymeric components, which are more fragile, making their assembly and handling difficult.

The process described in the present invention is of particular interest to the end user, to industries that manufacture fuel cells and/or electrolysers, energy storage devices and transport industries (both domestic and aeronautical, naval, railway) as well as small electronic devices. It may also be useful in the manufacture of redox flow batteries and in their different applications. On the other hand, it may be of interest to companies that manufacture gas diffusion layers or catalysts.

In a first aspect, the present invention relates to a method of obtaining a MEA unit (membrane-electrode assembly) through the processes of lamination and pressing (hereinafter "process of the invention") comprising the following steps:

a) preheating a laminator having a roller release system for at least 4 minutes at a temperature between 75 °C and 125 °C; b) perforating a plasticizing sleeve (1) at its midpoint making a window (2) with the measurement of the active area desired for the MEA unit; c) placing a membrane (3) inside the plasticizing sleeve from step (b), constituting the sleeve-membrane assembly;

d) cover the membrane-sheath assembly obtained in (c) with onion skin protective paper;

e) using the preheated laminator from step (a) to laminate the membrane-covering assembly obtained in (d) at a temperature between 75 and 125 °C; f) manually removing the onion skin protective paper from the laminated product obtained in (e), leaving the laminated membrane;

g) placing two electrodes (4a and 4b) in the form of a sandwich on the laminated membrane obtained in step (f) facing the gap in the window free of plastic wrap created in (b), where the size of the perimeter of said electrodes is greater in perimeter than that of the window of the plastic wrap;

h) pressing the laminate obtained in (g) at a temperature between 100 °C and 160 °C, at a pressure of between 8 bar and 20 bar for at least 3 min. i) cooling the assembly obtained in (h) to a temperature between 20 °C and 30 °C by applying a pressure of between 8 bar and 20 bar for at least 3 minutes.

The laminator must have a roller release system (two or four) to avoid possible jams that could damage the membrane-sheath assembly. In addition, the use of onion skin paper or similar is intended to cover the membrane-sheath assembly to facilitate passage through the laminator rollers without jams, thus avoiding damage during laminating. Once the membrane-sheath assembly to be obtained has been properly arranged, the lamination must seal the membrane respecting its dimensions with respect to the laminating sheath used. Likewise, the process temperature can vary depending on the thickness of the assembly, where for thicknesses of 80 ^m the temperature is 75 °C and for greater thicknesses it can reach up to 125 °C. The electrode must always slightly overlap the laminate window, thus reducing the active area of the MEA by 3 to 8%, compared to the assembly process without a lamination stage. For example, if the electrode size is 2.24 x 2.24 cm2, the size of the active area (laminate window) has to be slightly smaller, in this preferred example 2.15 x 2.15 cm2, reducing the active area by 7.8%.

The method of the present invention offers numerous advantages, such as that the MEA unit obtained is well assembled, with all the components joined together and its dimensionality does not change after the test in the cell, thus allowing post-mortem tests to be carried out that can help to understand the operation of the MEA unit or to repeat the electrochemical characterisation later if necessary. Another advantage of the method of the invention would be that the experimental pressing conditions can be lowered in step (h) regardless of the nature of the membrane used, both temperature and pressure and time, avoiding processes of softening and fluidity of the membrane, as well as structural damage. Another additional advantage is that both with 100% polymeric membranes (whether commercial Nafion® type or other non-commercial compositions) and with organic-inorganic hybrid membranes, step (e) facilitates contact between the membrane-electrode interfaces, improving the efficiency in the cell compared to membranes assembled by the conventional hot pressing method. In the case of organic-inorganic hybrid membranes with a high content of inorganic components that contribute to fragility, step (e) allows the manufacturing of the MEA unit, its handling, as well as successive assembly and disassembly processes for the repetition of electrochemical tests. This processing method facilitates the incorporation of up to 50% inorganic content into the hybrid membrane. The process of the invention increases the electrochemical performance in the cell, regardless of the nature of the membrane and the electrodes used in the assembly, thanks to the improvement of the electrode-electrolyte interfaces and the better diffusion of gases at the ends of the active area of the MEA unit.

In the present invention, "onion paper" means any vegetal paper that, like tissue paper, is exceptionally light and thin; translucent and flexible with a satin texture. Although thin, it is extremely resistant due to its uniform fiber formation and 25% cotton fiber content, which allows for high folding properties.

It is also known as greaseproof paper, baking paper, butter paper, tissue paper or vegetable paper. It is chemically treated (it is given a bath in sulfuric acid, hence the name) to cover the pores of the cellulose and thus make it impermeable, translucent and also resistant to high temperatures. In the case of this procedure, it is used for its main characteristics of non-stick and thermal resistance to withstand temperatures of up to approximately 220 °C and is selected without being limited to Parafilm vegetable paper, with a weight that ranges between 40 and 100 g/m2.

In a preferred embodiment, before step (a), a previous step of preparing the components of the MEA unit, the membrane (3) and the electrodes (4a and 4b), is carried out at the desired size, and by means of a CCS method or a CCM method.

In the present invention "the preparation of the components of the MEA unit" is understood because the membrane can be commercial or non-commercial, both of polymeric nature and organic-inorganic hybrid, with regard to the electrodes, these can be of any nature and prepared by any processing method, where the components must have the size of the desired MEA without this being limited by the assembly method of the present invention and the deposition of the catalytic layer can be carried out both by the CCS method and the CCM method. When the catalytic layer is deposited on the membrane (CCM) it is included in the plasticizing sheath and after plasticizing the electrodes are faced with a gas diffusion layer (GDL) to subsequently press everything. In this case, during the MEA component preparation stage, the catalytic layer is deposited on both sides of the membrane, allowing for a wide range of processing methods, with spraying being preferred, where the CCM unit would be placed inside the plastic sleeve (c), to subsequently cover the components with onion skin paper (d) and proceed to lamination (e). This processing method allows up to 50% inorganic content to be incorporated into the membrane.

In the CCS method, only the membrane without a catalytic layer is included in the sheath since the catalytic layer is deposited directly on the electrodes with a gas diffusion layer (GDL).

In another preferred embodiment the membrane is selected from among commercial ionomeric membranes (3) based on perfluorosulfonated polymers, ionomeric membranes based on hydrocarbon chain polymers, organic-inorganic hybrid membranes based on perfluorosulfonated polymers, organic-inorganic hybrid membranes based on hydrocarbon chain ionomeric polymers, ionomeric membranes based on block copolymers with sulfonated styrene groups and organic-inorganic hybrid membranes based on block copolymers with sulfonated styrene groups. In another more preferred embodiment the above membrane has a catalytic layer deposited by the CCM method using a chemical or physical deposition method, preferably airbrushing, screen printing, decal transfer, electrodeposition, ion beam sputtering or magnetic sputtering.

Another advantage of the procedure is that with organic-inorganic hybrid membranes, those that are known to have a high inorganic component content and high fragility, step (e) allows the manufacturing of the MEA unit as well as its handling, when until now it was impossible due to its fragility. These hybrid membranes can be class I hybrids with the organic and inorganic components linked by weak ionic bonds, electrostatic or Van der Waals forces (known as composites) or type II with covalent bonds between components (hybrid materials on the nanometric scale). The inorganic component can be Si, Zr, P, Al, Ti among others, or a combination of them in binary or ternary systems, for example, TiO2-P2O5 or SiO2-P2O5-ZrO2, with a maximum content of 50% in the hybrid. Alkoxides, chlorides, nitrates, acetates or citrates among others can be used as precursors. The incorporation of the inorganic component into the hybrid can be carried out by any liquid deposition method, the most preferred embodiment being sol-gel synthesis. The organic component can be a monomer, polymer, block copolymer or a polymerizable alkyl alkoxide. In a preferred embodiment, aromatic monomers or polymers that are susceptible to sulfonation or any other monomer or polymer. The organic component is incorporated into the hybrid by organic polymerization of its functional groups that will vary depending on the nature of the monomer, polymer or alkyl alkoxide used. In addition, step (e) allows the MEA unit to be assembled and disassembled for the repetition of electrochemical tests. This processing method facilitates the incorporation into the membrane of up to 50% inorganic content.

In another preferred embodiment, the electrodes (4a and 4b) are selected from electrodes with a gas diffusion layer (GDL) made of paper, felt, carbon fibres or fabrics with (or without) a microporous layer (MPL); the catalytic layer being deposited by a chemical or physical deposition method, preferably airbrushing, screen printing, electrodeposition, chemical vapour deposition, ion beam sputtering or magnetic sputtering. Among the different commercial brands are GDL Toray, Sigracet, Freudenberg or ELAT E-Tek.

In another preferred embodiment of the process, the plasticizing pouches (1) of step (b) are selected from bioriented polypropylene (BOPP), polycarbonates, polyurethanes or polyamides. In a more preferred embodiment, the plasticizing pouch is made of bioriented polypropylene. In an even more preferred embodiment, the bioriented polypropylene plasticizing pouch comprises a coating of a layer of ethylene-vinyl acetate copolymer (EVA), with total thicknesses between 80 and 125 µm.

In another preferred embodiment, the onion skin protective paper selected from step (d) is a Parafilm vegetable paper, with a weight ranging between 40 and 100 g/m2 containing 25% cotton fibers by weight and resistance to temperatures up to 220 °C.

In another preferred embodiment, the plasticizing of step (e) is carried out at a speed between 20 cm/min and 40 cm/min.

In another preferred embodiment, during laminating, a pressure is applied in step (e) which reduces the thickness of the sheath-membrane assembly obtained by between 3 and 7% with respect to the ratio between the thickness of the sheath-membrane assembly at the inlet and outlet of the laminator.

In another preferred embodiment if the size of the electrodes is 2.24 x 2.24 cm2, the size of the active area or window of the laminate has to be slightly smaller, in this preferred example 2.15 x 2.15 cm2, reducing the active area by 7.8%.

In another preferred embodiment, the pressing in step (h) is carried out at a temperature between 100 °C and 160 °C, at a pressure between 8 bar and 20 bar for at least 3 min. An advantage of the method of the invention would be that in step (h) the pressing conditions can be lowered, regardless of the nature of the membrane and the electrodes used, both in temperature and pressure and time, compared to conventional assembly. These milder experimental conditions avoid membrane softening and fluidity processes, as well as structural damage during assembly caused by high temperature and pressure conditions.

In another preferred embodiment, the cooling of step (i) is carried out with the cooling cartridges of the hydraulic press for a time of at least 3 minutes maintaining a pressure of between 8 bar and 20 bar.

An advantage of the method of the invention is that in step (i) the pressing conditions can be lowered, regardless of the nature of the membrane used, both temperature and pressure and time, compared to conventional assembly. These milder experimental conditions prevent membrane softening and fluidity processes, as well as structural damage during assembly caused by high temperature and pressure conditions.

Another aspect of the invention is a membrane-electrode assembly unit comprising a membrane comprising an ion exchange membrane (3) and a catalytic layer, and two electrodes on both sides of the membrane (4a and 4b) characterized in that the membrane also comprises a plasticized sheath (1) that covers it with a material selected from bioriented polypropylene (BOPP), polycarbonates, polyurethanes or polyamides, where the sheath also has a hole in its midpoint making a window (2) with the measurement of the active area desired for the MEA to connect the electrodes and said membrane.

In another preferred embodiment, the plasticizing sheath is made of bioriented polypropylene. In an even more preferred embodiment, the plasticizing sheath (1) is made of bioriented polypropylene and comprises a coating of an ethylene-vinyl acetate copolymer (EVA), with total thicknesses between 80 and 125 ^m.

In a preferred embodiment of the device the membranes are selected from commercial ionomeric membranes based on perfluorosulfonated polymers, ionomeric membranes based on hydrocarbon chain polymers, organic-inorganic hybrid membranes based on perfluorosulfonated polymers, organic-inorganic hybrid membranes based on hydrocarbon chain ionomeric polymers, ionomeric membranes based on block copolymers with sulfonated styrene groups and organic-inorganic hybrid membranes based on block copolymers with sulfonated styrene groups. In another more preferred embodiment the above membranes have a catalytic layer deposited by the CCM method. In another preferred embodiment, commercial ionomer membranes are based on perfluorosulfonated polymers or organic-inorganic hybrid membranes based on perfluorosulfonated polymers, which have improved stack efficiency compared to membranes assembled by the conventional hot pressing method, which represents another additional advantage.

In another preferred embodiment, the electrodes are selected from electrodes with a gas diffusion layer (GDL) made of paper, felt, carbon fibers or fabrics with (or without) a microporous layer (MPL), the catalytic layer being deposited by any deposition method, whether chemical or physical, such as airbrushing, screen printing, electrodeposition, chemical vapor deposition, ion beam sputtering or magnetic sputtering.

In another preferred embodiment if the size of the electrodes is 2.24 x 2.24 cm, the size of the active area or window of the laminate has to be slightly smaller, in this preferred example 2.15 x 2.15 cm.

Throughout the description and claims the word "comprises" and its variants are not intended to exclude other technical features, additives, components or steps. For those skilled in the art, other objects, advantages and features of the invention will become apparent partly from the description and partly from the practice of the invention. The following examples and figures are provided by way of illustration, and are not intended to be limiting of the present invention.

BRIEF DESCRIPTION OF THE FIGURES

Fig. 1. Diagram showing the laminating sleeve with the central window of the active area size of the MEA unit to be prepared. Step (b) of the process of the invention.

Fig. 2. Diagram of the sheath-membrane assembly that constitutes stage (c) of the invention process.

Fig. 3. Diagram of the different stages of the invention process: A. Side view of the laminated membrane (after step e). B. Side view of the electrodes placed on both sides and with a surface slightly larger than that of the laminate-free window (step g). C. Side view of the MEA once hot-pressed (step h) and after the cooling process (step i). The diagram is valid for both CCS (Catalyst Coated on Substrate) and CCM (Catalyst Coated on Memory) configurations.

Fig. 4. Diagram corresponding to step (g) described in the invention process, showing the top view after placing and facing the electrodes on each side of the laminated membrane. The bottom view is identical to the top view (not shown).

Fig. 5. PEMFC H2/O2 single cell test at 80°C, 100% relative humidity and atmospheric pressure of a Nafion® N112 membrane with conventional hot-press MEA processing and with processing described in this invention with lamination and subsequent hot pressing.

Fig. 6. Tests in a PEMFC H2/O2 monocell at a temperature of 60°C, 100% relative humidity and atmospheric pressure of an inorganic and organic-inorganic hybrid polymeric membrane (A) with conventional hot-pressing MEA processing and (B) with processing described in this invention with lamination and subsequent hot pressing.

Fig. 7. PEMFC H2/O2 monocell test at 60°C, 100% relative humidity and atmospheric pressure of an organic-inorganic hybrid membrane with conventional hot-press MEA processing and processing described in this invention with lamination and subsequent hot pressing.

EXAMPLES

The invention will now be illustrated by means of tests carried out by the inventors, which demonstrate the effectiveness of the product of the invention.

Example 1: Nature of the membranes used for the assembly of the MEA unit

Membranes of polymeric, inorganic and organic-inorganic hybrid nature are prepared.

(1) Commercial membranes based on perfluorosulfonated polymers (Nafion® type) or hydrocarbon chain ionomer polymers are purchased from a supplier and used according to the product data sheet without any additional modification.

(2) Ionomeric polymeric membranes based on block copolymers with sulfonated styrene groups are prepared from a triblock copolymer of styrene-ethylene-butylene-styrene (SEBS) with 32% by weight of styrene units, which is purchased from Repsol under the trade name Calprene CH-6120. SEBS polymeric membranes are prepared by tape casting from chloroform solutions using the Dr Blade technique (BYK Instruments). The heterogeneous sulfonation reaction of SEBS (s-SEBS) is carried out by immersing the polymeric membranes in a 0.3 M solution of trimethylsilyl chlorosulfonate in dichloroethane (DCE) for 2 hours.3

(3) Inorganic sol-gel solutions precursors of inorganic membranes are prepared using trimethyl phosphate (PO(OCH3)3, TMP), zirconium tetrapropoxide (Zr(OC3H7)4, TPZr) from Aldrich, tetraethyl orthosilicate (SKOC2H5K TEOS) from Merck and acetylacetone (C5H8O2, acac) from Fluka. Other chemicals used were propanol as sol-gel solution solvent (C3H8O) and acidified water (0.1N HCl) as sol-gel reaction catalyst. Membranes are prepared by casting in Teflon (PTFE) molds and allowing to gel at 50 °C for several days depending on the desired final thickness. Different compositions have been tested, the preferred composition being the one that maintains the molar ratio 40SiO2-40P2O5-20ZrO2. A molar proportion of P2O5 of 25-60%, ZrO2 between 25-30% and SiO2 between 50-10% can be used.

(4) Organic-inorganic hybrid membranes based on s-SEBS and modified with inorganic sol-gel solutions of the ternary oxide system SiO2-P2O5-ZrO2. The membranes are prepared by the infiltration process. The s-SEBS membranes are pre-swollen in H2SO41N at 80 °C for 2 h and then immersed in the 40SiO2-40P2O5-20ZrO2 solution at 80 °C for different times. The preferable infiltration time is 10 min. At the end of the treatment, the membranes are cleaned with ethanol and dried at 50 °C for 1 h and at 120 °C for 2 h to ensure the formation of gels. Finally, the hybrid membranes are cleaned with ethanol at 80 °C for 2 h and dried at 80 °C for 1 h. The infiltrated dry samples show an area increase between 42% and 117%, and thicknesses of around 45-55 ^m depending on the infiltration time.

All membranes are cut to a size slightly larger than the active area of the electrode to be used in the MEA. For example, if the active area is 5 cm2, the electrodes will be 2.24 x 2.24 cm2 and the minimum membrane dimensions 3 x 3 cm2. Polymeric and hybrid membranes are homogeneous, transparent without cracks or defects.

Example 2: Obtaining the MEA unit in CCS (Catalyst Coated on Substrate) conformation

Membrane-electrode assemblies are prepared using ionomeric membranes of any nature (both pure polymeric and organic-inorganic hybrids) and electrodes in the CCS configuration:

1. The electrodes (4a and 4b) in this example are composed of a commercial GDL gas diffusion layer (Sigracet BC39 from SGL) and a catalytic layer deposited by sputtering on the GDL. The catalytic layer contains between 0.9 and 1.0 mg Pt/cm2 and symmetrical electrodes have been used at the anode and cathode.

2. The assembly is carried out by preparing the plastic sleeve (1) (biaxially oriented polypropylene (BOPP) with a layer of ethylene-vinyl acetate copolymer (EVA)), making a central window (2) the size of the active area that the MEA unit will have (Figure 1).

3. The membrane (3) is placed inside the plastic sleeve (1) as shown in Figure 2. It must be centered well with respect to the window of the sleeve, avoiding wrinkles so that the lamination is adequate and no errors occur in the process.

4. The cover-membrane assembly is covered with onion skin paper or similar so that it absorbs the pressure of the laminating, also avoiding problems of obstruction and jamming in the laminator.

5. The laminating stage is carried out by introducing the membrane-sheath assembly covered with the protective paper into the laminator previously heated to 80 °C. The laminating must seal the membrane respecting its dimensions with respect to the laminating sheath used (Figure 3.A).

6. Figure 3.B shows how the electrodes (4a and 4b) are placed on both sides of the plasticized membrane, perfectly facing the active area window and taking into account that each electrode always has to be slightly larger than the window (2) of the plasticized membrane (1), that is, each electrode (4) must always slightly overlap the window (2) of the plasticization, thus reducing the active area of the MEA by between 3 and 8%, compared to the assembly process without a lamination stage.

7. Figure 3.C shows the side view of the final MEA, after the hot pressing and cooling processes. Figure 4 shows a top view of the final MEA. Pressing is performed at a temperature of 100 °C at a pressure of 15 bar for 3 min in a Collin P200 hydraulic press. The cooling process is performed using the cooling cartridges of the Collin P200 hydraulic press at a pressure of 15 bar for 3 min.

Example 3: Improvements in stack efficiency (I-V curves and power density curves) in MEA units assembled with the process described in this invention.

It is demonstrated how the use of the present invention improves the electrochemical performance in the cell independently of the nature of the membrane and the electrodes used in the assembly. To this end, the polarization and power density curves of different MEA units assembled in one case by the traditional hot pressing method and in another, using the present invention process of lamination and subsequent pressing are determined in order to compare the results.

The tests were carried out in commercial ElectroChem® 5 cm2 monocells with graphite bipolar plates with serpentine flow channels; Scribner 850e test station, H2/O2 gas flow of 200 mL/min, 100% relative humidity and atmospheric pressure.

In the case of Nafion® (N112), using 1.0 mg Pt/cm2 on each electrode and 80°C cell temperature, the maximum current density increases from 2700 mA/cm2 to 2900 mA/cm2 in the laminated MEAs, as seen in Figure 5. The maximum power density also improves slightly from 922 mW/cm2 to 923 mW/cm2.

Figure 6 compares the performance of the pure s-SEBS polymeric membrane with the organic-inorganic hybrid membrane sSEBS-(40SiO2-40P2O5-20ZrO2) with both assembly procedures: traditional hot pressing procedure (Figure 6.A) and procedure of the present invention (Figure 6.B). For the s-SEBS polymeric membrane, the maximum power density obtained is 300 mW/cm2 in the conventional MEA, however, in the MEA laminated using the procedure described in the present invention a maximum power density of 400 mW/cm2 is obtained (corresponding to a 33% improvement). The same occurs for the hybrid membranes sSEBS-(40SiO2-40P2O5-20ZrO2) infiltrated for 5 minutes and sSEBS-(40SiO2-40P2O5-20ZrO2) infiltrated for 10 minutes, where its maximum power density goes from 316 and 412 mW/cm2 with the conventional hot pressing method to 430 and 504 mW/cm2 with the processing described in this invention, which represents improvements of 36 and 22%, respectively. This higher performance is directly related to the assembly method used and the improvement of the interfaces when using the processing described in the present invention. In Figure 7, this improvement in electrochemical performance when using the combination of lamination and hot pressing in the MEA processing can be directly compared, for the preferred example of a sSEBS-(40SiO2-40P2O5-20ZrO2) hybrid membrane infiltrated for 10 minutes resulting in a 22% improvement in power density.

Example 4: Post-mortem evaluation of the MEA unit after electrochemical testing in the cell.

The use of the processing described in this invention combining lamination with hot pressing allows for “repetitive characterization” and post-mortem study of the MEAs after their electrochemical evaluation. With a common hot pressing process, once the electrochemical test was performed and the single cell or stack was disassembled, the MEAs were usually detached and damaged for testing, especially when testing membranes that are not 100% polymeric. This caused a drop in performance during the tested cycles and made it impossible to reuse these MEAs in other tests (by varying temperature or relative humidity). However, using the processing method described in this present invention, the laminated MEAs remain unchanged after being tested, which means an improvement in the electrochemical performance, they can be reassembled and tested to complete the electrochemical study, and a post-mortem study of the MEA is also allowed.

Claims (15)

1. Procedure for obtaining a membrane-electrode assembly unit (MEA) for a fuel cell, characterized in that it comprises the following stages: a) preheating a laminator having a roller release system for at least 4 minutes at a temperature between 75 °C and 125 °C; b) perforating a plasticizing sleeve (1) at its midpoint making a window (2) with the measurement of the active area desired for the MEA unit; c) placing a membrane (3) inside the plasticizing sleeve from step (b), constituting the sleeve-membrane assembly; d) cover the membrane-sheath assembly obtained in (c) with onion skin protective paper; e) using the preheated laminator from step (a) to laminate the membrane-covering assembly obtained in (d) at a temperature between 75 and 125 °C; f) manually removing the onion skin protective paper from the laminated product obtained in (e), leaving the laminated membrane; g) placing two electrodes (4a and 4b) in the form of a sandwich on the laminated membrane obtained in step (f) facing the gap in the window free of plastic wrap created in (b), where the size of the perimeter of said electrodes is greater in perimeter than that of the window of the plastic wrap; (h) pressing the laminate obtained in (g) at a temperature between 100 °C and 160 °C, at a pressure of between 8 bar and 20 bar for at least 3 min; and (i) cooling to a temperature between 20 °C and 30 °C, the assembly obtained in (h) by applying a pressure between 8 bar and 20 bar for at least 3 minutes. 2. Method according to claim 1, where before step (a), a previous step of preparation of the components of the MEA unit is carried out: the membrane (3) and the electrodes (4a and 4b), to the desired size, and by means of a CCS method or a CCM method.3 3. Method according to any of claims 1 or 2, wherein the membrane (3) is selected from ionomeric membranes based on perfluorosulfonated polymers, ionomeric membranes based on hydrocarbon chain polymers, organic-inorganic hybrid membranes based on perfluorosulfonated polymers, organic-inorganic hybrid membranes based on hydrocarbon chain ionomeric polymers, ionomeric membranes based on block copolymers with sulfonated styrene groups and organic-inorganic hybrid membranes based on block copolymers with sulfonated styrene groups. 4. Method according to claim 3, wherein the membrane (3) has a catalytic layer deposited by the CCM method using a deposition method, chemical or physical, preferably airbrushing, screen printing, decal transfer, electrodeposition, ion beam spraying or magnetic sputtering. 5. Method according to any of claims 1 to 4, wherein the electrodes (4a and 4b) are selected from electrodes with a gas diffusion layer (GDL) made of paper, felt, carbon fibers or fabrics with or without a microporous layer (MPL), the catalytic layer being deposited by a deposition method, whether chemical or physical, preferably airbrushing, screen printing, electrodeposition, chemical vapor deposition, ion beam sputtering or magnetic sputtering. 6. Method according to any of claims 1 to 5, wherein the plasticizing sleeve (1) of step (b) is selected from bioriented polypropylene (BOPP), polycarbonates, polyurethanes or polyamides. 7. Method according to claim 6, wherein the plastic sleeve (1) is made of bioriented polypropylene. 8. Method according to claim 7, wherein the plasticized sheath (1) of bioriented polypropylene comprises a coating of an ethylene vinyl acetate copolymer (EVA), with total thicknesses between 80 and 125 ^m.9 9. Method according to any of claims 1 to 8, wherein the onion skin protective paper of step (d) is Parafilm tracing paper with a weight ranging between 40 and 100 g/m2, cotton fiber content of 25% by weight and resistance to temperatures up to 220 °C. 10. Method according to any of claims 1 to 9, wherein the plasticizing of step (e) is carried out at a speed between 20 cm/min and 40 cm/min. 11. Method according to any of claims 1 to 10, wherein during laminating a pressure is applied in step (e) which reduces the thickness of the sheath-membrane assembly obtained by between 3 and 7% with respect to the ratio between the thickness of the sheath-membrane assembly at the inlet and outlet of the laminator. 12. Method according to any of claims 1 to 11, wherein the pressing of step (h) is carried out between a temperature of 100 °C and 160 °C, at a pressure of between 8 bar and 20 bar for at least 3 min. 13. Method according to any of claims 1 to 12, wherein the cooling of step (i) is carried out with the cooling cartridges of the hydraulic press for a time of at least 3 minutes maintaining a pressure of between 8 bar and 20 bar. 14. A membrane-electrode assembly unit comprising a membrane comprising an ion exchange membrane (3) and a catalytic layer, and two electrodes on both sides of the membrane (4a and 4b) characterized in that the membrane also comprises a plasticized sheath (1) that covers it with a material selected from bioriented polypropylene (BOPP), polycarbonates, polyurethanes or polyamides, where the sheath also has a hole at its midpoint making a window (2) with the measurement of the active area desired for the MEA to connect the electrodes and said membrane. 15. Membrane-electrode assembly unit according to claim 14, wherein the plastic sheath (1) is made of bioriented polypropylene and comprises a coating of an ethylene-vinyl acetate copolymer (EVA), with total thicknesses between 80 and 125 ^m.