NL1018720C2 - Electrochemical cell based on hollow-fiber membranes. - Google Patents

Description

Title: Electrochemical cell based on hollow fiber membranes

The invention relates to a method and device for carrying out electrochemical reactions in a gaseous or discharged state, and to a method for making such a device.

Liquid or gaseous electrolytes offer advantages over cells equipped with the fixed electrolytes, such as for example conventional batteries which are equipped with lead plates. US-A-5 759 711 describes a battery based on liquid electrolytes. In this known device the electrolytic solutions are circulated through the 10 chambers in which the electrodes (cathode and anode) are located. The chambers are separated by a membrane.

An advantage of using liquid or gaseous electrolytes is that the charged electrolyte can be stored outside the electrochemical cell, for example in a storage vessel. As a result, the energy content of the cell is in principle only limited by the volume of the storage vessel. It is also possible to switch between charging and producing electricity quickly and at a desired moment, without this being at the expense of the storage capacity of the cell; with fixed electrolytes, a so-called memory effect can occur if charging and production cycles are not fully performed.

The disadvantage of cells based on liquid or gaseous electrolytes is that they generally take up a lot of space due to the fact that the liquid electrolytes are relatively diluted compared to solid electrolytes (low electron density). As a result, quantities such as the specific power (for example expressed in W / kg), the power density (for example expressed in W per unit volume of the cell), the energy content (for example expressed in Wh / kg) or the energy density are 1018720 · 2 (for example expressed in Wh per volume unit) is generally low and could be improved.

Known cells based on liquid or gaseous electrolytes are also characterized by a relatively low efficiency due to heat production and / or short-circuit currents.

It is an object of the present invention to at least partially eliminate these disadvantages. It is intended to provide a more compact manner for conducting electrochemical reaction in gaseous or dissolved state. A cell for carrying out such reactions with an improved efficiency is also envisaged. It has been found that if this is based on a hollow-fiber membrane comprising ionic groups and an electron-conducting layer is covered on either side, this object can be achieved.

The present invention therefore relates to a method for carrying out an electrochemical reaction in a gaseous or dissolved state, wherein a gaseous or liquid phase is introduced on either side of a hollow-fiber membrane, each of which comprises reagents for and / or reaction products of said reaction, wherein the material of the walls of the hollow fiber membrane comprises ionic groups such that the phases on the inside and outside of said hollow fiber membrane do not at least substantially mix, and wherein the surface of the hollow fiber membrane on the inside and the outside is covered with an electrically conductive layer permeable to liquid or gas.

Because the material of the walls of the hollow-fiber membranes according to the present invention comprises ionic groups, it is achieved that the walls are ion-conducting. Ion transport can therefore take place through the wall. This ion transport is preferably selective, that is to say such that one type of ions can be transported more easily through the wall than the other type.

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The gaseous or liquid phases which each comprise reagents for and / or reaction products of said electrochemical reaction can be, for example, the electrolytes. The method and device according to the invention can also be used as a fuel cell. In that case the said phases comprise the reagents and reaction products for the conversion of, for example, hydrocarbons with oxygen.

The method according to the invention is preferably carried out such that one of said phases is introduced into a space, which space is defined by a container on the one hand and the outside of one or more of said hollow fiber membranes in said container on the other, and the another said phase into the space defined by the inner sides of said hollow fiber membranes, the layers on the outside being in electrical contact with each other and the layers on the inside being in electrical contact with each other.

Each of the layers on either side of the hollow fiber membrane serves as an electrode, for example one as a cathode and the other as an anode. Because the two electrodes are present as a layer on either side of the hollow-fiber membrane, a number of important advantages are obtained.

On the one hand, a simple and practical construction is obtained in that the electrodes can easily be applied as a layer on the surface of the hollow-fiber membrane, whereby a construction with sufficient mechanical strength can be realized.

On the other hand, by arranging the electrodes as a layer, the distance between the electrodes is minimal, namely approximately the wall thickness of the hollow-fiber membrane. Due to this minimum distance from the electrodes, the internal resistance for ion conduction is also minimal, which results in an electrochemical cell with a high efficiency (low heat losses). The resulting cell is also compact and high values for the aforementioned quantities (specific power, 1018720 · 4 power density, energy content and / or energy density) can be obtained.

Moreover, according to the invention there is no or hardly any liquid or gaseous reagents or reaction product (for example electrolyte) present between each of the electrodes on the one hand and the surface of the hollow fiber membrane on the other hand, whereby the dust transfer resistance is lower than if this were the case. . This also makes an additional contribution to the efficiency and / or the aforementioned quantities with regard to power and energy of the electrochemical cell.

The layers on the outside of the hollow membranes are in mutual electrical contact with each other and thus form, for example, the cathode of the cell. The layers on the inside are in another electrical contact with each other and form, for example, the anode. The contacts can be led outside in the usual manner such that connection points are obtained between which an electric current can flow.

Hollow fiber membranes are used according to the invention. Hollow fiber membranes are understood to be fibers known per se, which are usually manufactured by extrusion or spinning of a polymer. Hollow fiber membranes have a diameter of less than 1 mm. Suitable methods of manufacture are described, for example, in Kirk-Othmer's Encyclopedia of Chemical Technology, 3rd Edition, Band 12 (1984) pp. 492-517. In addition to polymeric materials, ceramic materials are also suitable for the manufacture of hollow-fiber membranes. Hollow fiber membranes have a high specific surface area. This makes it possible to manufacture modules according to the invention with an available surface area that can typically be up to 2000 to 4000 m2 / m3. Usually, hollow-fiber membranes have an outer diameter of a few tenths from mm to 30 at most 1 mm, the wall thickness usually being between the few tens of 1018720 · 5 μπι to hundreds of μιη. The length of the hollow-fiber membranes can in principle be chosen freely and amounts, for example, to a few cm to a few meters.

Suitable materials for the hollow-fiber membranes include nano- or ultra-filtration membranes made of polymeric material, such as polypropylene, with ionic groups on or in the polymer. Suitable ionic groups are, for example, sulfonic acid groups.

It is also possible to manufacture the hollow-fiber membrane from a microporous membrane, for example a polymer or ceramic material, the pores of which are filled with an ionic substance, for example a substance comprising sulphonic acid groups.

It is also possible to manufacture hollow fiber membranes by starting from a polymer matrix in which small ion exchange particles are arranged.

Nafion ™, a sulfonic acid-based perfluorinated polymer, is also a suitable material for the hollow-fiber membranes for use in the invention.

Combinations of the above materials are also possible. The above materials can be processed in a known manner into hollow-fiber membranes, for example by interfacial polymerization or phase inversion. Monomers from two sides are offered in interfacial polymerization. These come into contact with each other at an interface where the polymerization takes place. This technique is described, for example, in M.H.V. Mulder, "Basic Principles of Membrane Technology", Kluwer Academy Publishers, Dordrecht (NL) 2nd edition (1996), Chapter III.5.

For example, phase inversion can be applied to spiders. A solution of a polymer is assumed. A fiber is spun from this by passing the solution through a spinning head. In the spinning head 1018720 · 6, an agent is introduced into the lumen of the fiber in which the polymer does not dissolve or does not dissolve well (non-solvent). The outside may be contacted with the non-solvent by passing the fiber through a container with the non-solvent (see, for example, the above-mentioned publication of 5 M.H.V. Mulder, Chapter III.3).

The hollow fiber membranes according to the invention preferably have an outer diameter of 0.25 - 1 mm, preferably of 0.3 - 0.9 mm and a wall thickness of 0.04 mm - 1 mm, preferably of 0.05 - 0.2 mm. The number of hollow-fiber membranes that is used depends on the intended application and in particular on the intended performance, for example the intended electrical power. The electrical power of a cell is more or less proportional to the total available membrane area. Therefore, starting from a certain specification with regard to, for example, the desired power, a cell can easily be designed.

A cell can be formed by switching a plurality of modules, each module being, for example, in the form of a cube, a rib having a length of, for example, 5 cm to, for example, 1 m. The number of hollow-fiber membranes will then be a few tens to a few thousands or more.

The conductive layers which are applied on either side of the hollow-fiber membranes (on the inside and outside of the hollow-fiber membranes) comprise, for example, metals, graphite and / or electron-conducting polymers. In order to enable ion transport 25, the conductive layers must be permeable to ions (dissolved in a liquid or gas). This can for instance be realized by providing the conductive layers with perforations or by carrying them out in a fiber structure, for example by using graphite felt. The conditions during the application of the layer 30 can also be chosen such that this layer is built up intrinsically porous.

1018720 · 7

Moreover, the porous design of this conductive layer (for example through the perforations or through the fiber structure) has the effect of increasing the surface area of this layer, which acts as an electrode. This results in a larger effective surface on which or on which the electrode reactions can take place, whereby an additional contribution to the electrical power and power density of the cell is obtained.

It is also possible to design the electrically conductive layer in such a way that it comprises a material which, for example, has catalytic properties to accelerate certain electrode reactions. The electrically conductive layer can also be provided with materials which on the contrary have an inhibitory effect on certain, undesired reactions. These catalytic or inhibiting materials can be added to the starting material of the electrically conductive layer or applied separately thereto if the electrically conductive layer has already been applied.

Examples of suitable materials with catalytic properties for this purpose are Pt, Pd, an alloy of Cu and Pd. These can be used, for example, to catalyze the oxidation of nitrite to nitrate.

The electrically conductive layer can be applied on either side of the membrane (for example on the inside and outside of hollow fiber membranes) by using known techniques.

The layer or layers can for instance be applied by applying a conductive plate or foil on either side of the membrane (for example all around and / or in hollow fibers).

An electron-conducting material or a precursor thereof can also be vapor-deposited from the gas phase.

The electron-conducting material (or a precursor thereof) can also be applied to the membrane surface by precipitating this material from a liquid phase, for example by means of sol-gel methods or by means of wet impregnation.

If a precursor is used as a starting point, the precursor thus applied must be converted into the electrically conductive layer 5 by suitable physical and / or chemical treatment, for example by a temperature treatment or by bringing the precursor into contact with a reagent, such as a reducing agent. gas or a reducing solution or liquid (e.g. hydrazine).

It is preferred if the process according to the invention is carried out such that at least one of gaseous or liquid phase with reactants / reaction products (such as electrolytes) is allowed to flow through the space in which it is present. In this way it can be achieved that one of the phases flows from a storage vessel to the space, for example by circulating the electrolyte. When the system is operated as a battery, a certain capacity can be selected in this way due to the dimensions of, inter alia, the storage vessel.

When the system is used as a fuel cell, it is usually necessary, for example, to involve the gaseous reactants externally and to guide them through one of the spaces.

It is also possible that both phases (for example electrolytes) flow through their respective spaces. In this way a good electron transfer between the two electrolytes can be obtained. The directions of flow of the phases can be such that one phase flows into the other substantially transversely (substantially perpendicularly to each other), as is the case in the embodiment shown in FIG. 1. In this figure the arrows indicate the flow direction of the electrolytes. The first phase (Electrolyte 1) flows on the mantle side of a bundle of hollow-fiber membranes in a direction that is substantially perpendicular to the longitudinal direction of the hollow-fiber membranes in the bundle, so that the bundle is flowed transversely. The second phase 1018720 · 9 (Electrolyte 2) then flows through the lumen side of the individual hollow-fiber membranes.

Transversal inflow gives good dust transfer to the outer surface of the hollow membranes. As a result, the boundary layers on the surface become thinner, so that more ions can be supplied per unit of time. This results in an increased power density. On the lumen side, the dust transfer is not increased extra. For this reason, it is preferable that of the two electrode reactions that take place in the cell on either side of the membrane 10, the one that is most diffused is limited on the lateral side.

In order to obtain continuous flow, the container can be designed at suitable locations with supply and discharge points such that one or two separate circulation circuits of the phases (electrolytes 1 and 2) are obtained. A suitable module for carrying out this embodiment of the method according to the invention, wherein the direction of flow of the phases are directed substantially perpendicular to each other, is described in US-A-6 103 118. This publication also describes the manufacture of such modules described.

It is also possible to use the method according to the invention in modules with hollow-fiber membranes, the flow directions of the phases being substantially parallel. For this purpose, for example, a configuration can be chosen which is usually also used with heat exchangers of the so-called shell / tube type. This embodiment is preferably embodied such that the direction of flow of the two phases is opposite.

An apparatus for carrying out an electrochemical reaction in gaseous or dissolved state according to the invention comprises a container with hollow-fiber membranes therein, the material of the walls of the hollow membranes comprising ionic groups in which a first space becomes 1018720. defined by the container and the outside of the hollow fiber membranes, and a second space is defined by at least the inside of said hollow fiber membranes, wherein at least one of the hollow fiber membranes is covered on the inner and outer surface with a front ions or gas-permeable electron-conducting layer, such that said layers form a first electrical contact on one side of the hollow fiber membrane and the layers on the other side of the hollow fiber membrane form a second electrical contact.

The above-mentioned methods can be carried out with such a device. Such a device can be obtained by performing the following steps: - introducing hollow-fiber membranes into a container such that the above-mentioned spaces are created, each space having one or more gas and liquid supply and / or outlets, which spaces are substantially gas-tight or liquid-tightly separated from each other; - applying a gaseous, liquid or dissolved precursor for the electrically conductive layer in each of the spaces such that it covers the walls of the hollow membranes; - performing a chemical or physical conversion wherein said precursor is converted into the electrically conductive layer.

The first step, introducing hollow membranes, in particular hollow fiber membranes, into a container can suitably be carried out as described in US-A-6 103 118. A bundle of hollow fiber membranes is positioned in the container and a so-called potting is applied by casting a material using a mold of suitable shapes and then allowing the material to cure. The potting provides the seal between the two spaces, so that no mixing of the electrolytes can occur and should of course not be electrically conductive.

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11

By the above-mentioned method for manufacturing the cells according to the invention, the hollow-fiber membranes are provided with a uniform coating of precursor both on the inside and on the outside, which coatings are then each converted into the electrically conductive layer, without this electrical layers are in contact with each other, i.e. without the risk of a short circuit between the electrodes on the lumen side and the lateral side. Because the precursor layer is uniform, the resulting electrically conductive layer is present over almost the entire surface of the respective spaces (lumen side or the cladding side) and thus provides an electrical contact which extends over the entire inner surface and outer surface of the hollow The electrically conductive layer therefore also covers the portion of the potting and the portion of the inside of the container on the lumen side, as well as the portion of the potting and the portion of the inside of the container on the lateral side.

A metal salt that is in solution can be used as a precursor. The metal ion in this solution is then converted to the corresponding metal, so that the resulting electrically conductive layer comprises this metal.

The conversion of the precursor into the metal can be effected, for example, by using a reducing agent, such as, for example, hydrogen gas or hydrazine. Suitable precursor materials are, for example, palladium, platinum or silver salts, such as the chlorides of these metals.

The invention can be used for a variety of electrochemical reactions in gaseous or dissolved state. For example, for storing and subsequently producing electricity, for generating electricity from a fuel mixture (fuel cell), or for electrolysis (for example, the conversion of water into hydrogen and oxygen). The redox reactions that can be carried out can be for example (1018720 · 12 reactions where the first electrolyte / second electrolyte couple is selected from the redox couples: a couple formed by two solutions, each of which comprises cations with a difference in valence of at least 1, 5 wherein each of these solutions comprises the same or different cations, a couple formed by two solutions, each comprising anions with a difference in valence of at least 1, each of these solutions comprising the same or different anions, gaseous hydrocarbon / oxygen , gaseous hydrogen / oxygen.

If solutions of cations or anions are used, the said difference in valence is preferably at least 2, because a higher energy density can then be obtained.

The ions located on either side of the membrane (for example on the lumen and mantle side) can be the same (for example Fe2 + - »Fe3 + on the lumen side and the reverse reaction on the mantle side) or different (for example Fe2 + -» Fe3 + on the lumen side 20 and V5 + - »V4 + on the lateral side).

The invention can be applied to (large-scale) storage of electricity, for example for supporting the peak load of power plants. Electricity is stored during off-peak hours and produced during peak hours. This provides a substantial cost benefit. To support the peak load of power plants, the method or the device according to the invention can be used at the power plant site but also at the customers, for example households. The invention can also be applied in the automotive industry, wherein the device and method according to the invention is used, for example, instead of a conventional battery. It is also possible to refresh one or two of the electrolytes by "refueling" them at, for example, a gas station.

Another example is the application as an electrochemical oxygen pump, which can be used to create a low-oxygen environment (for example in the food industry). Hereby oxygen from the air which is to be depleted is converted at the cathode according to: 1/2 02 + 2e + 2H + -> H2 O, while oxygen is produced at the anode according to: H2 O -> 2H + + 1/2 02 + 2nd ~.

An important advantage is that, according to the invention, it is possible to switch quickly between storing and producing electricity. When used in means of transport this can be used, for example, to store braking energy, after which the system can immediately switch over if electricity is to be produced, for example for driving an electric motor in order to be able to accelerate better.

Another possible application is in the field of industrial processes, which often require a considerable peak load of electricity at start-up, while once in operation the load of the electricity grid is considerably lower. The device and method according to the invention can here also contribute to absorbing the peak load.

Because the method and device according to the invention are not dependent on solid electrolytes, a compact and flexible system is obtained, in particular when it is used for electricity storage. When used in batteries, according to the invention it is possible to switch quickly between charging and taking electricity, without this leading to, for example, the "memory effect", which problem is characteristic of batteries with fixed electrodes.

1018720e 14

According to the invention, a cell is obtained with a high efficiency. The table below shows a comparison between a number of relevant quantities that are obtained with a battery according to the invention and the same quantities that are obtained with a conventional battery with liquid electrolytes.

battery according to conventional invention battery specific power W / kg £ 400 <200 power density W / dm3> 600 <300 energy content Wh / kg> 200 ^ 100 energy density Wh / dm3 £ 400 <200 1018720 * 15 1. holder 2. potting 3 metal-coated membrane; jacket side 4. metal-coated membrane; lumen side 5. mantle side current collector 6. lumen side current collector 7. connector (+) 8. connector (-)

9. AV

10. electrolyte 1 IN

11. electrolyte 1 OFF

12. electrolyte 2 IN, 13. electrolyte 2 OFF

Claims (14)

A method for carrying out an electrochemical reaction in a gaseous or dissolved state, wherein a gaseous or liquid phase is introduced on either side of a hollow-fiber membrane, each of which comprises reagents for and / or reaction products of said reaction, wherein the material of the walls of the hollow fiber membrane comprises ionic groups such that the phases on the inside and outside of said hollow fiber membrane do not at least substantially mix, and wherein the surface of the hollow fiber membrane is covered on the inside and outside with an electrically conductive layer permeable to liquid or gas. 2. Method as claimed in claim 1, wherein one of said phases is introduced into a space, which space is defined by a container on the one hand and the outside of one or more of said hollow fiber membranes in said container on the other, and the other said phase into the space defined by the inner sides of said hollow fiber membranes, the layers on the outside being in electrical contact with each other and the layers on the inside being in another electrical contact with each other. Method according to claim 1 or 2, wherein at least one of the phases is allowed to flow through the space in which it is present. A method according to any one of the preceding claims, wherein both phases flow. The method of claim 4, wherein the flow directions of the phases are oriented substantially perpendicular to each other. 6. Method according to claim 4, wherein the directions of flow of the phases are substantially parallel and preferably opposite. A method according to any one of the preceding claims, wherein said hollow fiber membrane is a polymeric nano- or ultrafiltration membrane, wherein ion exchange groups are arranged on or in the polymer, and / or is a microporous membrane, the pores of which are filled with an ionic substance . A method according to any one of the preceding claims, wherein said electrically conductive layers each comprise a metal, graphite and / or a conductive polymer, the metal preferably comprising Pt, Pd and / or an alloy of Cu and Pd. 9. A method according to any one of the preceding claims, wherein the first electrolyte / second electrolyte couple is selected from the 10 redox couples: a couple formed by two solutions, each of which cations with a difference in valence of at least 1, preferably at least -2 , wherein each of these solutions comprises the same or different cations, 15. a couple formed by two solutions, each comprising anions with a difference in valence of at least 1, preferably at least 2, each of these solutions having the same or various anions, gaseous hydrocarbon / oxygen, 20. gaseous hydrogen / oxygen. 10. A method according to any one of the preceding claims, wherein the electrically conductive layer on the inside and / or outside of the hollow fiber membrane further comprises a catalyst for catalyzing desired electrode reactions and / or an inhibitor for inhibiting undesired electrode reactions. The use of a hollow-fiber membrane, the material of the walls of which comprises ionic groups and which is covered on both sides by an ion-conducting electron-conducting layer in electrochemical cells. 12. Device comprising a container with hollow fiber membranes therein, wherein the material of the walls of the hollow membranes comprises ionic groups, in which a first space is defined by the container and the outside of the hollow fiber membranes, and a second space becomes defined by at least the inside of said hollow fiber membranes, wherein at least one of the hollow fiber membranes is covered on the inside and outside surface with an ion or gas-permeable electron-conducting layer such that said layers on one side of the hollow -fibre membrane form a first electrical contact and the layers on the other side of the hollow fiber membrane form a second electrical contact. 13. Method for manufacturing a device according to claim 12, comprising the steps of: introducing hollow-fiber membranes into a container such that said spaces are created, wherein each space has one or more gas supply and / or outlets or has liquid, which spaces are substantially gas-tight and liquid-tightly separated from each other; providing a gaseous, liquid, or dissolved precursor for the electrically conductive layer in each of the spaces such that it covers the walls of the hollow fiber membranes; performing a chemical or physical conversion wherein said precursor is converted to the electrically conductive layer. The method of claim 13, wherein the metal precursor is a metal salt that is used in solution and wherein the electrically conductive layer comprises the metal. The method of claim 14, wherein the precursor is converted to a metal layer by using a reducing agent.