EP1293005A1 - Dimensionally stable gas diffusion electrode - Google Patents

Abstract

The invention relates to a dimensionally stable gas diffusion electrode and to a method for producing the same. The inventive electrode comprises at least one electroconducting catalyst substrate for receiving a coating mass that contains a catalyst material, and one electrical connection. The catalyst substrate (4; 11) may be a tissue, a nonwoven, a foam, a sintered metal body or felt from a electroconducting material, an expanded metal plate or a metal plate that is provided with a multitude of openings (2, 8), on which the coating material (5) that contains the catalyst material is applied. The catalyst substrate, if not sufficiently rigid itself, is firmly linked with a gas-permeable, alkali-resistant metal base plate (1; 7), especially produced from nickel or one of its alloys in a mechanical and electroconducting manner.

Description

Dimensionally stable gas diffusion electrode

The invention relates to a dimensionally stable gas diffusion electrode consisting of at least one electrically conductive catalyst support material for receiving the coating material containing catalyst material and an electrical connection, and a method for producing the electrode. The catalyst support material is a woven fabric, fleece, sintered metal, foam or felt made of electrically conductive material, an expanded metal plate or a metal plate provided with a plurality of openings, on which the catalyst material contains

Coating composition is applied, and which is mechanically and electrically conductively connected to a gas-permeable metallic base plate, in particular made of nickel or a nickel / silver alloy or an alkali-resistant metal alloy. If the catalyst support material has sufficient inherent rigidity, the use of a base plate can be dispensed with and the catalyst support material provided with coating material containing catalyst material can be installed directly in an electrochemical reaction apparatus.

Gas diffusion electrodes are used in different arrangements for electrochemical processes. For fuel cells with a solid electrolyte polymer membrane e.g. the gas diffusion electrodes as hydrogen consumption anode and oxygen consumption cathode (SVK) are placed directly on the membrane. In the case of HC1 electrolysis with an oxygen consumable cathode, this also lies directly on the membrane.

For NaCl electrolysis with SVK e.g. On the other hand, it has proven to be advantageous to operate the SVK separately from the membrane with a gap that is a few mm wide and through which alkali flows. With a conventional technical height of more than one meter, the SVK can advantageously only be operated with so-called pressure compensation according to the gas pocket principle, as described in US Pat. No. 5,693,202. The

Electrode is free with a usual gas pocket height of 15 - 35 cm between caustic soda and oxygen. Since a limited, but still present, height-dependent differential pressure is applied via the SVK, which is relatively elastic, similar to a membrane, it must be supported with spacers against bulging in the direction of the membrane or on the other side in the direction of the gas pocket. Uncontrolled bulging of the SVK in the direction of the membrane causes a reduction in the catholyte gap up to the contact between the SVK and the membrane. This results in a disturbance in the flow of lye, combined with an uneven concentration distribution and possible damage to the membrane. Possibly through the SVK passing oxygen gas bubbles can not withdraw unhindered and collect in places with a greatly reduced

Electrolyte gap on. This leads to the membrane and electrode being bent and thus to an increase in the local current density in the remaining electrode area. The effects described result in an increased k-factor, i.e. an excessive increase in the operating voltage depending on the increase in the current density and thus an excessive specific energy consumption.

The spacer between the electrode and membrane in particular has repeatedly led to problems. Local contact points combined with structural movements in the electrolysis cell occasionally lead to chafing points on the membrane, which can lead to leakage over a long period of operation. Accordingly, the SVK was also burdened with pressure points, which could certainly lead to damage if it were to operate for years. In addition, the spacers shield both electrode and membrane surfaces, which also leads to high current densities and thus to high voltages and high specific energy consumption. A solution was therefore sought to be able to dispense with such spacers.

In the past, many attempts to apply the soft SVK to a rigid support failed due to the problem of having to sinter and press the electrode first in order to give it the necessary tightness with targeted porosity and then the fluoropolymer-containing electrode structure metallic, ie by means of Welding or soldering, to connect to the rigid support. Such a connection is practically unsustainable and, because of the fluorides released, is also very susceptible to corrosion. The object of the invention is to provide a stable gas diffusion electrode and a method for its production which does not have the disadvantages mentioned.

The solution is to apply the coating material containing catalyst material according to the basically known wet or dry calendering process to a metallic, single or multi-layer scrap structure with the structure described below.

The invention relates to a dimensionally stable gas diffusion electrode consisting of at least one electrically conductive catalyst support material for receiving a coating material containing catalyst material, in particular mixtures of finely divided silver or finely divided silver oxide or mixtures of silver and silver oxide and Teflon powder or of mixtures of finely divided Silver or silver oxide or mixtures of silver and silver oxide, carbon and Teflon powder, and an electrical connection, characterized in that the catalyst support material is a fabric, fleece, sintered metal, foam or felt made of electrically conductive material, an expanded metal plate or is provided with a plurality of openings metal plate on which the coating material containing the catalyst material is applied, and which has a sufficient flexural strength, so that an additional stiffening by using an additional base plate can be dispensed with, or with a gas-permeable rigid metallic base plate or a rigid fabric or expanded metal, in particular made of nickel or its alloys or alkali-resistant

Metal alloys, mechanically and electrically conductive is firmly connected.

The open structure serving as catalyst support material consists in particular of a fine wire mesh or a corresponding fine expanded metal, filter screen, felt, foam or sintered material, into which the coating material containing the catalyst material is clamped during rolling. This open structure is in In one embodiment, before the coating material containing catalyst material is pressed in or rolled in, it is already connected to the entirely open, but more compact and rigid substructure in a metallic manner, for example by sintering.

The function of this substructure is that of an abutment when the coating material containing the catalyst material is pressed in, which in this case can also spread into structure-related gaps between the two layers and thus clamp together even better.

The metal for the base plate is preferably selected from the series nickel or an alkali-resistant nickel alloy, in particular nickel with silver, or nickel, which is coated with silver, or from an alkali-resistant metal alloy.

Alternatively, in special cases, a rigid foam or a rigid sintered structure or a perforated or slotted plate made of a material can be used as the base plate

Series of nickel, alkali-resistant nickel alloy or alkali-resistant metal alloy, in particular nickel with silver, or nickel, which is coated with silver, can be used. In this case, the coating material which has been rolled out into a fur and contains catalyst material is rolled directly into the basic structure, which at the same time has the function of a catalyst support material. An additional catalyst support material is therefore not used.

The catalyst support material preferably consists of carbon, metal, in particular nickel or nickel alloys or an alkali-resistant metal alloy.

The base plate preferably has a plurality of openings, in particular slots or bores, for improved passage of reaction gas.

The openings are preferably at most 2 mm, in particular at most 1.5 mm wide. The slots can have a length of up to 30 mm. When using a foam or a porous sintered structure, the pores have an average diameter of preferably at most 2 mm. The structure is characterized by high rigidity and bending strength.

In a special embodiment of the gas diffusion electrode, a foam or sintered metal body is used as the catalyst support material, an edge provided for connecting the electrode to an electrochemical reaction apparatus being pressed together in order to achieve the required gas / liquid tightness.

A preferred variant of the gas diffusion electrode is characterized in that the base plate has an opening-free peripheral edge of at least 5 mm, which is used to attach the electrode, in particular by welding or soldering, or with screws or rivets or clamps or by using electrically conductive adhesive to the Edge of the one to be connected to the electrode

Serves gas bag.

A selected form of the gas diffusion electrode is characterized in that the catalyst support material and the coating material containing the catalyst material are connected to one another by dry calendering.

A preferred variant of the gas diffusion electrode is designed in such a way that the catalyst support material and the coating material containing the catalyst material are applied to the catalyst support material by pouring or wet rolling the coating material containing water and possibly organic solvents (for example alcohol) and are connected by subsequent drying, sintering and possibly compacting is.

In order to improve the uniform gassing of the gas diffusion electrode, an additional electrically conductive gas distributor fabric, in particular made of carbon, is provided between the base plate and the catalyst support material or metal, in particular nickel, or an alkali-resistant nickel alloy, in particular with silver or made of nickel, which is coated with silver, or an alkali-resistant metal alloy.

In a special embodiment of this gas diffusion electrode, the

Base plate on a flat recess for receiving the gas distribution fabric.

An embodiment of the gas diffusion electrode has proven to be particularly suitable in which the layer of catalyst support material and coating material containing catalyst material in the edge region of the electrode is connected to the edge of the base plate in a gas-tight manner all around.

The gas-tight connection can be made, for example, by sealing or, if necessary, ultrasonically supported, rolling down.

When using a foam or a porous sintered structure as catalyst support material or base plate, after coating the structure with coating material containing catalyst material, a peripheral edge zone is strongly pressed in order to obtain a gas-tight edge area.

The gas diffusion electrode preferably has an edge without openings or an edge sealed by pressing a porous structure and is gas-tight and electrically conductive at this opening-free edge with an electrochemical reaction apparatus, for example by means of welding, soldering, screwing, riveting, clamping or using alkali-resistant, electrical conductive adhesive bonded.

If the gas diffusion electrode is connected to the electrochemical reaction apparatus by means of welding or soldering, the opening-free edge is preferably silver-free. If, however, the gas diffusion electrode is connected to the electrochemical reaction apparatus by means of screws, rivets, clamps or the use of electrically conductive adhesive, the opening-free edge is preferably silver-containing.

When integrating the gas diffusion electrode into the electrochemical reaction apparatus by screwing, riveting, clamping, it is advantageous to seal the edge zone of the base plate against the installation surface of the electrochemical apparatus by means of an elastic insert.

Another object of the invention is a method for producing the gas diffusion electrode according to the invention, by sintering the catalyst support material with a base plate which is provided with a multiplicity of openings, applying the powdery or fibrous coating composition which may contain rolled catalyst material in a previous work step

Roll on at a pressure of at least 3-10 ^ Pascal (dry calendering).

The invention also relates to an alternative method for producing a gas diffusion electrode by applying a thin to dough-like mixture of catalyst with water and possibly an organic solvent, for example alcohol, with a solvent content between 0 to 100% and a solids content between 5 to 95% with rolling or spatulas or pouring the mixture, drying and sintering at a higher temperature, in particular at least 100 ° C. and at most 400 ° C., under protective gas, in particular nitrogen, carbon dioxide, noble gas or a reducing medium, particularly preferably argon, neon, krypton, Butane and possibly further rolling the sintered composite at a pressure of at least 3-10 ^ Pascal.

After the catalyst support material has been sintered to the base plate, the surface of the catalyst support material is preferably provided with a silver layer, in particular by electrodeposition or electroless plating. In a special form of the method, a gas distributor fabric is applied to the base plate and sintered to the base plate before the catalyst support material is applied.

A particularly preferred method is characterized in that the catalyst carrier material, gas distributor and base plate are sintered simultaneously.

In order to avoid inadmissible deformation of the upper structure into the lower structure during the rolling process, the opening division of the two layers should be suitably matched to one another. Adequate drainage of condensate or caustic soda must also be ensured to prevent the gas transport channels from being blinded.

During the operation of the gas diffusion electrode according to the invention as an oxygen consumable cathode (SVK), this structure supplies the catalytically active layer with oxygen through its openings and forms the rigid substructure which makes this gas diffusion electrode dimensionally and deformably stable.

However, the simultaneous use of an upper and lower structure is not absolutely necessary; a direct coating of the base plate is also conceivable.

The application of a catalyst mass in the form of a thin liquid mass or a dough by the wet rolling method by pouring or spatula, then drying, sintering and possibly compacting by rolling is a further variant of the method.

For the installation of the electrode by means of screw, rivet, clamp, solder, weld or adhesive connection in a gas pocket structure, the slightly protruding edge of the base structure, which is preferably deeper than the catalyst support material structure and during rolling, can be used. the catalyst material contains tendency coating composition can be protected in a suitable manner from the fluoropolymers, are used. It is particularly advantageous if this part is left open during the stamping of the openings in the form of holes, slots, etc., ie remains massive and lateral escape of the oxygen can thus be prevented. An escape of oxygen from the boundary between the two

Layers can be avoided by suitably rolling down a narrow, catalyst-filled edge strip of the top layer onto the substructure, which should no longer be slotted here or should otherwise be covered with metal and sealed. For rolling down the edge strip, for example, the use of an ultrasonically excited, rotating roller head has proven successful. The

Transmission of the pressure-vibration forces causes the gaps to be completely filled with coating material containing catalyst material.

If a foam or an open-pore sintered structure is used as the base body, the porous structure is strongly compressed in a peripheral edge area to prevent the escape of oxygen in the edge area. The strong compacting causes the formation of a gas-tight structure.

The type of catalyst applied, in particular after the dry calendering process, but also after the wet calendering process and the spatula process, allows used catalyst layers to be removed by vigorous blowing or spraying, so that the metallic support structure can be coated again.

Depending on the type of introduction of the gas diffusion electrode, for example as an SVK, into a gas pocket or attachment to the gas pocket, it is entirely conceivable that this double structure can be reused several times and thus considerable costs can be saved. The catalyst, on the other hand, can be recovered chemically and / or electrochemically from the extracted mass using simple means, so that the recycling requirement can also be taken into account here. Another object of the invention is an electrochemical gas diffusion cell having a gas diffusion electrode according to the invention as described above.

The electrochemical gas diffusion cell can be designed with permanently installed but also with removable gas pockets.

The invention is explained in more detail below with reference to the figures.

Show it:

Fig. 1 is a diagram of the structure of a gas diffusion electrode according to the invention

Fig. 2 shows the cross section through the electrode of FIG. 1 along line A-A

3 shows a diagram of a variant of the electrode according to FIG. 1 with an additional gas distribution fabric 10

Fig. 4 shows the cross section through the electrode of Fig. 3 along line B-B

5 shows a diagram of an electrolysis cell with the gas diffusion electrode

Examples

Unless otherwise stated, percentages are percentages by weight.

Example 1 (Fig. 1 + 2)

Production of a two-layer dimensionally stable gas diffusion electrode: The base plate (1) consists of 1.5 mm thick nickel sheet with openings (slots) (2) 1.5 mm wide and 15 mm long (from Fiedler / D). The distribution of the slots is chosen so that their distance from each other is 5 mm in the longitudinal direction and 2 mm in the transverse direction. The adjacent longitudinal rows of the slots are shifted against each other by half a period, so that the slot is adjacent to the distance.

This basic structure has an unslit edge (3). A nickel wire mesh (4) with a wire diameter of 0.14 mm and a mesh size of 0.5 mm (Haver and Boecker / D) acts as a support structure for the activation. The wire mesh is flush with the edge zone. This arrangement is sintered at temperatures between 800-1200 ° C; you get a coherent structure.

The side carrying the wire is silver-plated. To apply the activation, the unslit edge zone (3) is covered with a suitable material such as wax, lacquer, adhesive tape or the like. The complete electrode structure is then coated with a coating material (5) which has previously been rolled into a film (“fur”) and consists of 85% carbon black (Vulcan XC-72, 10% Ag), 15% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 500 g / m ² , which is connected to the wire mesh (4) by rolling, pressing or the like. After removal of the layer covering the edge area, the edge area (6) is used to achieve a sufficient level

Gastightness using an ultrasonic welding machine with roller seam head (Fa. Stapla / D) - the electrode is now ready for installation. The integration into the electrochemical reaction apparatus takes place, for example, by welding, soldering, screwing, clamping, riveting or using electrically conductive adhesive or the like in the solid edge zone (3).

When the gas diffusion electrode and the electrochemical reaction apparatus are connected by means of clamping, riveting or screwing, an elastic seal is applied between the gas diffusion electrode and the contact surface of the electrochemical reaction apparatus in order to prevent the gas and liquid phases from mixing.

Example 2

Production of a two-layer dimensionally stable gas diffusion electrode: The structure is similar to that of Example 1 except for the use of a different application method for the coating material containing catalyst material and the application of an additional uncatalyzed gas diffusion layer:

The side carrying the wire is silvered without current. To apply the activation or the gas diffusion layer, the unslit edge zone is covered on both sides by means of a suitable material such as wax, lacquer, adhesive tape or the like. The electrode structure is then coated on the non-wire-bearing side with a gas diffusion layer previously rolled out to form a fur, consisting of 70% carbon black (Vulcan XC-72, uncatalyzed), 30% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 750 g / m ² , which is connected to the slotted sheet structure by rolling, pressing or the like.

To apply the catalyst layer, the wire-bearing side of the electrode structure is mixed with a mixture of 70% carbon black (Vulcan XC-72, 10% Ag / PTFE mixture (85% / 15%)) and 30% previously mixed to a pasty mass.

Spread isopropanol ("spatula"), dry at 65 ° C and to achieve sufficient gas tightness compacted by rolling. A tempering step at 250 ° C / lh follows to solidify the electrode. The electrode is integrated into the electrochemical reaction apparatus as in Example 1.

Example 3

Production of a two-layer dimensionally stable gas diffusion electrode: The structure is similar to that of Example 1 except for the use of a different support material for the catalyst: a fine expanded metal of the type 5-M-5-050 Pulled (thickness of the starting material: 0.127 mm, web width: 0.127 mm, LWD: 1.27 mm, from DELKER / USA). The use of expanded metal results in particularly strong interlocking between the coating material containing catalyst material and catalyst support material.

Example 4 3 + 4)

Production of a three-layer dimensionally stable gas diffusion electrode: The base plate of the electrode consists of a 2 mm thick slotted plate (7) with openings (slits) (8) 1.5 mm wide and 25 mm long (from Fiedler / D). The

The distribution of the slots is selected so that their distance from each other is 5 mm in the longitudinal direction and 2 mm in the transverse direction. The adjacent longitudinal rows of the slots are shifted against each other by half a period, so that the slot is adjacent to the distance.

This basic structure has an unslit edge (9) which does not have to be at the same height as the slotted contact surface - the use of a higher edge has proven to be advantageous for the sealing. An inserted wire mesh (10) with a 0.5 mm wire diameter and 0.8 mm mesh size (Haver and Boecker / D) acts as a gas distributor. A fine nickel wire mesh with 0.14 mm wire diameter and 0.5 mm mesh size is placed on this structure (Fa. Haver and Boecker / D) (11), which is flush with the edge zone in the case outlined in FIG. 3.

The use of a further layer in comparison to Examples 1 to 3 serves to improve the gas and liquid transport or to additionally clamp the catalyst mass.

This arrangement is sintered at temperatures between 800-1200 ° C; you get a coherent structure. The side carrying the wire is silvered without current.

To apply the activation, the higher, unslit edge zone (9) is made using a suitable material such as e.g. Wax, varnish, adhesive tape etc. covered. The complete electrode structure is then coated with a coating material which has previously been rolled out to form a film (“fur”)

(5) made of 85% carbon black (Vulcan XC-72, 10% Ag) and 15% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 500 g / m ² , which is achieved by rolling, pressing or the like with the fine wire mesh (11) is connected. After removal of the layer covering the edge area, the edge area (13) is rolled down to achieve sufficient gas tightness using an ultrasonic welding device (Stapla / D); the electrode is now ready for installation. The integration into the electrochemical reaction apparatus takes place, for example, by welding, soldering, screwing, clamping, riveting or using electrically conductive adhesive or the like in the solid edge zone (9).

When connecting the gas diffusion electrode and the electrochemical reaction apparatus by means of a clamping, riveting or screwing process, an elastic seal is applied between the edge (13) of the gas diffusion electrode and the contact surface of the electrochemical reaction apparatus in order to prevent the gas and liquid phases from mixing. Example 5

Production of a three-layer dimensionally stable gas diffusion electrode: The structure is similar to that of Example 4 except for the use of a different support material for the catalyst: it is a fine expanded metal of type 5-

Ni-5-050 Pulled (thickness of the starting material: 0.127 mm, web width: 0.127 mm, LWD: 1.27 mm, from DELKER / USA). The use of expanded metal results in a particularly intensive interlocking between the catalyst support material and the coating material containing catalyst material.

Example 6

Production of a three-layer dimensionally stable gas diffusion electrode: The structure is similar to that of Example 4 except for the use of a different support material for the catalyst: it becomes a fine perforated plate with one

Opening diameter of 0.3 mm and a triangular division of 0.6 mm related (from Fiedler / D).

Example 7

Production of a three-layer dimensionally stable gas diffusion electrode: The structure is similar to that of Example 4 except for the use of a different catalyst support material and application method for the coating material containing the catalyst material: it becomes an opaque, sintered nickel felt with a thickness of 0.3 mm (from Nitech / F) used as catalyst support material. This absorbent structure is coated with a pourable mixture of 36% carbon black (Vulcan XC-72, 10% Ag), 64% HOSTAFLON TF 5033 suspension (10% PTFE) in a coating thickness of 250 g / m ² , at 95 ° C dried and compacted by rolling to achieve sufficient gas tightness. A tempering step at 250 ° C / lh follows to solidify the electrode. The integration of the electrode in the electrochemical reaction apparatus takes place as described in Ex. 4.

Example 8

Manufacture of a single-layer dimensionally stable gas diffusion electrode: The base plate consists of 5 mm thick nickel foam (Dunlop / USA). The average pore diameter is 1 mm, the gap volume is 80%.

This basic structure has a non-porous edge before the coating process is completed; a support structure is not used.

The side intended for a later coating is silver-plated. To apply the activation, the edge zone is covered with a suitable material such as e.g. Wax, varnish, adhesive tape etc. covered. The complete electrode structure is then coated with a coating material which has previously been rolled out to form a film (“fur”) and consists of 85% carbon black (Vulcan XC-72, 10% Ag), 15% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 500 g / m occupied, which by rolling, pressing or the like is connected to the foam structure. After removing those covering the edge area

The edge area is pressed together to achieve a sufficient gas tightness to a thickness of 1 mm - the electrode is now ready for installation. The integration into the electrochemical reaction apparatus takes place, for example, by welding, soldering, screwing, clamping, riveting or using electrically conductive adhesive or the like. in the massive edge zone.

When connecting the gas diffusion electrode and the electrochemical reaction apparatus by means of a clamping, riveting or screwing process, an elastic seal is applied between the edge of the gas diffusion electrode and the contact surface of the electrochemical reaction apparatus in order to prevent mixing of the gas and liquid phases. Example 9

Manufacture of a single-layer dimensionally stable gas diffusion electrode: The base plate consists of 1.5 mm thick nickel sheet with slots 1.5 mm wide and 15 mm long (from Fiedler / D). The distribution of the slots is chosen so that their distance from each other is 5 mm in the longitudinal direction and 2 mm in the transverse direction. The adjacent longitudinal rows of the slots are shifted against each other by half a period, so that the slot is adjacent to the distance.

This basic structure has an unslit edge; a support structure is not used. The side intended for a later coating is silver-plated. To apply the activation, the unprotected edge zone is covered with a suitable material such as wax, lacquer, adhesive tape or the like. The complete electrode structure is then coated with a coating composition which has previously been rolled out to form a catalyst material and consists of 85% carbon black (Vulcan XC-72, 10% Ag), 15% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 500 g / m ² , which is connected to the slotted plate by rolling, pressing or the like. After removing the layer covering the edge area, the electrode is ready for installation. The integration into the electrochemical reaction apparatus takes place, for example, by welding, soldering, screwing, clamping, riveting or using electrically conductive adhesive or the like in the solid edge zone.

When connecting the gas diffusion electrode and the electrochemical reaction apparatus by means of a clamping, riveting or screwing process, an elastic seal is applied between the edge of the gas diffusion electrode and the contact surface of the electrochemical reaction apparatus in order to prevent mixing of the gas and liquid phases. Example 10

Production of a single-layer gas diffusion electrode: The structure is similar to that of Example 9 except for the application of an additional uncatalyzed gas diffusion layer:

The side intended for the subsequent coating is silvered without current. To apply the activation or the gas diffusion layer, the unslit edge zone is covered on both sides by means of a suitable material such as wax, lacquer, adhesive tape or the like. The Eleldroden structure is then coated on the non-silvered side with a gas diffusion layer previously rolled out to form a fur, consisting of 70% carbon black (Vulcan XC-72, uncatalyzed), 30% HOSTAFLON TF 2053 (PTFE) in a coating thickness of 750 g / m ² , which by

Rolling in, pressing etc. is connected to the perforated plate structure.

The application of the coating material containing the catalyst material and integration of the electrode into the electrochemical reaction apparatus is carried out as in Example 9.

Example 11 (Electrode Test)

The gas diffusion electrode described in Example 1 was installed in an electrolysis cell (see FIG. 5) which has a conventional anode half-cell (18) with a membrane (14). The design of the cathode half-cell differs significantly from the structure used in conventional cells - it consists of

Catholyte gap (15), oxygen consumption cathode (SVK) (16) and gas space (17).

The catholyte gap (15) has a conventional function; the, opposite the

Hydrogen development, oxygen reduction associated with great energy savings takes place at the SVK (16). There is a gas room behind the SVK (16) (17), which serves the supply of oxygen and the discharge of water of reaction or dilute sodium hydroxide solution.

The SVK (16) has a size of 18 cm x 18 cm and was operated over a period of 100 days at a stable cell voltage of 1.98 volts; the maximum deflection measured under operating conditions was 0.5 mm.

The following process parameters were set:

• current density: 3 kA / m ² , • cell temperature: 85 ° C,

Sodium hydroxide solution concentration: 32% by weight,

• Brine concentration: 210 g sodium chloride / 1

• maximum differential pressure: 24 cm water column

Claims

Patentansprfiche

1. Dimensionally stable gas diffusion electrode consisting of at least one electrically conductive catalyst support material for receiving a coating material containing catalyst material, in particular mixtures of finely divided silver or finely divided silver oxide or mixtures of silver and silver oxide and Teflon powder or of mixtures of finely divided silver - Or silver oxide or mixtures of silver and silver oxide, carbon and Teflon powder, and an electrical connection, characterized in that the catalyst support material

Fabric, fleece, foam, sintered metal body or felt made of electrically conductive material, an expanded metal plate or a metal plate provided with a plurality of openings, on which the coating material containing catalyst material is applied, and which has a sufficient flexural strength, so that additional stiffening by Use of an additional base plate can be dispensed with, or is mechanically and electrically conductively connected to a gas-permeable, rigid metallic base plate, or a rigid fabric or expanded metal, in particular made of nickel or its alloys or alkali-resistant metal alloys.

2. Gas diffusion electrode according to claim 1, characterized in that the metal for the base plate from the series: nickel or an alkali-resistant nickel alloy, in particular nickel with silver, or nickel which is coated with silver or an alkali-resistant metal alloy is selected.

3. Gas diffusion electrode according to claim 1 or 2, characterized in that the catalyst support material made of carbon, metal, in particular of nickel or an alkali-resistant nickel alloy, in particular nickel with silver, or nickel, which is coated with silver, or an alkali-resistant

Metal alloy is made. Gas diffusion electrode according to one of claims 1 to 3, characterized in that the base plate has a plurality of openings, in particular slots or bores.

Gas diffusion electrode according to one of claims 1 to 4, characterized in that the base plate has an opening-free peripheral edge of at least 5 mm.

Gas diffusion electrode according to one of claims 1 to 5, characterized in that a foam or sintered metal body is used as the catalyst support material and the edge provided for connecting the electrode to an electrochemical reaction apparatus is pressed together.

Gas diffusion electrode according to one of claims 1 to 6, characterized in that the catalyst support material and the coating material containing catalyst material are connected to one another by dry calendering.

Gas diffusion electrode according to any one of claims 1 to 7, characterized in that a coating material containing water and possibly organic solvent, preferably an alcohol, containing catalyst material is applied to the catalyst support material by pouring or wet rolling and then by drying, sintering and optionally compressing with the Catalyst support material is connected.

Gas diffusion electrode according to one of claims 1 to 8, characterized in that between the base plate and the catalyst support material, an additional electrically conductive gas distribution fabric, in particular

Carbon, metal, nickel, an alkali-resistant nickel alloy, in particular Nickel with silver, or nickel coated with silver or a leach-proof metal alloy is provided.

10. Gas diffusion electrode according to one of claims 1 to 9, characterized in that the base plate has a raised edge region for receiving the gas distributor fabric.

11. Gas diffusion electrode according to one of claims 1 to 10, characterized in that the layer of catalyst support material and catalyst material-containing coating material in the edge region in the

Electrode is connected gas-tight all around to the edge of the base plate.

12. Gas diffusion electrode according to claim 11, characterized in that the gas tightness in the edge region is achieved by sealing, pure or ultrasound-assisted rolling down.

13. Gas diffusion electrode according to one of claims 1 to 12, characterized in that an open-pore structure, in particular a foam, fabric, fleece or a sintered structure is used as the catalyst support material or base plate and the edge region is gusseted together to achieve a gas tightness.

14. Gas diffusion electrode according to one of claims 1 to 13, characterized in that the gas diffusion electrode has an edge without openings and on this opening-free edge gas-tight and electrically conductive with an electrochemical reaction apparatus by means of welding, soldering, screwing, riveting, clamping or using alkali-resistant, electrically conductive adhesive is connected.

15. Gas diffusion electrode according to claim 14, characterized in that the connection of the gas diffusion electrode with the electrochemical reac- tion apparatus by welding or soldering, the opening-free edge is silver-free.

16. Gas diffusion electrode according to claim 14, characterized in that the gas diffusion electrode is connected to the electrochemical reaction apparatus by means of screws, rivets, clamps or the use of electrically conductive adhesive, the opening-free edge containing silver.

17. Gas diffusion electrode according to one of claims 14 to 16, characterized in that when the gas diffusion electrode is integrated into the electrochemical reaction apparatus, the edge zone of the base plate is sealed against the installation surface of the electrochemical apparatus by means of an elastic insert.

18. A method for producing a gas diffusion electrode according to claim 1 by sintering the catalyst support material with a base plate which is provided with a plurality of openings, applying the powdery or fibrous, optionally in a separate step to a fur-rolled catalyst material with rolling at one

Pressure of at least 3-10 ^ Pascal (dry calendering).

19. A method for producing a gas diffusion electrode according to claim 1 by applying a thin to dough-like mixture of coating material containing catalyst material with water and possibly an organic solvent, for example alcohol, with a solvent content between 0 to 100% and a solids content between 5 to 95% on a catalyst support material with rolling, spatula or pouring the mixture, drying and sintering at a higher temperature, in particular at least 100 ° C and at most 400 ° C, under

Shielding gas, especially nitrogen, carbon dioxide, inert gas or a reducing medium, particularly preferably argon, neon, krypton, butane and possibly further rolling the sintered composite at a pressure of at least 3-10 ^ Pascal.

20. The method according to claim 18 or 19, characterized in that after the sintering of the catalyst support material with a base plate, the surface of the catalyst support material is provided with a silver layer, in particular by galvanic or electroless plating.

21. The method according to any one of claims 18 to 20, characterized in that before the catalyst support material is applied to a base plate, a gas distributor fabric is applied and sintered with the base plate.

22. The method according to claim 21, characterized in that the sintering of catalyst support material, gas distributor and base plate takes place simultaneously.

23. Electrochemical gas diffusion cell comprising a gas diffusion electrode according to one of claims 1 to 17.