EP1451885A2 - Gas diffusion electrode support structure - Google Patents

Abstract

The invention relates to a gas diffusion electrode support structure that receives a gas diffusion electrode (10) for an electrochemical reactor. Said support structure has a base structure (8) to whose fin (11) a connecting element is connected via a weld seam (20) in an electrically conductive way. The connecting element is configured as a bent structure and encloses an edge area (15) of the gas diffusion electrode (10). The edge area (15) of the gas diffusion electrode (10), in an external section (32), is not coated, and in an interior section (33) is provided with an electrochemically active coating.

Description

Gas diffusion electrode support structure

The invention relates to a carrier structure for a gas diffusion electrode. The support structure serves to receive a gas diffusion electrode for an electrochemical reaction apparatus. In particular, the invention relates to a gas diffusion electrode

Support structure for an electrolysis or fuel cell.

One method of integrating gas diffusion electrodes into their electrical contact with the basic structure of an electrochemical reaction apparatus is to form a press contact, such as in DE-A-4444 114. at

The use of press contacts, however, has shown that their electrical contact resistance often deteriorates during operation of the arrangement - this results in an undesirable increase in the consumption of electrical energy.

A more permanent electrical connection between the gas diffusion electrodes and the electrochemical reaction apparatus can be achieved with the aid of welding processes, such as those e.g. in EP-A-1 041 176. If a gas diffusion electrode with a non-perforated, circumferential, metallic edge is used, direct welding can be carried out with the basic structure of the electrode. The continuous edge of the basic electrode structure mentioned in EP-A-1 041 176 requires a perforated or slotted plate as the support structure. The electrodes to be integrated therefore often consist of a metallically conductive basic structure which is open-pored over the entire area and in whose cavities the electrochemically active composition, hereinafter referred to as coating, is embedded. Attempts to weld the coated electrode directly failed due to the frequent decomposition of the coating compound at high joining temperatures.

Furthermore, the use of a mass which has become plastic by heating and which solidifies again on cooling as a sealing material is described in EP-A-1 029 946. wrote. Chemically inert substances such as PTFE can be used here. However, a high temperature of 200 to 400 ° C must be used to permanently bond this substance to the basic structure. The implementation of the processes as described in EP-A-1 029 946 therefore requires extensive devices / machines.

The invention has for its object to provide a gas diffusion support structure in which the gas diffusion electrode is permanently and sealingly held.

The object is achieved according to the invention by the features of

Claim 1.

The carrier structure according to the invention for receiving a gas diffusion electrode for an electrochemical reaction apparatus, such as an electrolysis or fuel cell, has a basic structure. The basic structure is, for example, a half-shaped housing or the like of an electrolysis cell. The basic structure carries the gas diffusion electrode. For this purpose, according to the invention, an electrically conductive connecting element is provided between the basic structure and the gas diffusion electrode, the connecting element preferably being of low-ohmic electrical conductivity. The provision of a connecting element makes it possible, on the one hand, to establish a permanent and electrically conductive connection to the basic structure and, on the other hand, to the gas diffusion electrode.

It is particularly preferred to design the connecting element such that it surrounds the gas diffusion electrode in the edge region. This makes it possible to

Gas diffusion electrode in the edge area should not be provided with coating material, so that only an exposed metallic grid or the like is present. A good electrically conductive connection can be realized for the metallic grid or a metallic support structure or the like. It is particularly preferred here, in an outer part of the edge area, such as a narrow, strip-shaped outer frame-like area, the gas diffusion electrode at least partially, preferably to be completely coating-free and also to provide an electrochemically active coating in an inner part of the edge region. This coating otherwise corresponds to the entire coating provided on the gas diffusion electrode. This means that only a part of the edge area, which is enclosed by the connecting element, is coating-free and thus good electrical contact can be achieved in this area. The part of the edge area at which the transition between the area of the gas diffusion electrode covered by the connecting element to the free gas diffusion electrode is preferably coated with electrochemically active material.

The lack of coating material in the welding zone allows a qualitatively perfect connection. The open-pore catalyst carrier of the gas diffusion electrode is therefore free of coating material in this area and would, when operated in the electrochemical reaction apparatus, without measures to achieve a sealing effect, a mixture of those on both sides of the electrode

Media, namely gas and liquid electrolyte, enable. For this, in processes such as To counteract the chlor-alkali electrolysis with an oxygen consumable cathode, undesirable circumstances, the uncoated welding zone could be provided with liquid or pasty materials which solidify after some time and which seal the open-pored structure at this point. The sealing materials could be solidified, for example, by chemically curing a liquid or paste-like substance. Due to the chemically usually very aggressive conditions present in the electrochemical reaction apparatus, the service life of such seals has proven to be very short - it was in the range of weeks or a few months and thus stands in the way of an efficient continuous use of the electrochemical reaction apparatus.

In particular, by providing a connecting element which folds around the edge area of the gas diffusion electrode and that in a preferred development only part of the edge area is coating-free, good sealing is achieved possible at the edge of the connecting element. This can be done by pressing the connecting element, which is preferably a plastically deformable material, in particular sheet metal. Here, a circumferential approach can be provided, which enables a relatively good sealing on the gas diffusion electrode. However, it is particularly preferred to provide a seal between the connection element and the edge region of the gas diffusion electrode, in particular the inner part of the edge region, ie the edge region provided with a coating, in the connection region of the electrode and connection element the media located on both sides are sealed , which can be an elastic or plastic seal, reliably separated.

The seal is preferably resistant to the liquids and gases present in the reaction apparatus, in particular alkali-resistant. It is particularly preferred to use an elastic seal made of ethylene-propylene-diene terpolymers

(EPDM) or a plastic seal made of polytetrafluoroethylene (PTFE) or seals that contain these components.

The connecting element preferably has a fold-like configuration in the region of the seal. This fold, in particular, can be used to achieve a tight seal by plastically deforming the connecting element. If such a fold is provided, it is particularly advantageous to provide a sealing compound, which is preferably viscous, instead of one of the above seals or in addition.

The force with which the connecting element is deformed and presses against the seal is preferably carried out with a line force of at least 10 kg / cm, preferably at least 50 kg / cm and particularly preferably at least 100 kg / cm.

The frame surrounding the gas diffusion electrode is made by welding two pairs, preferably of different lengths, of open metal profiles manufactured. The ends of the shorter profiles advantageously have an identical shape over the entire length; the long profiles are notched in the edge area - they only have the appearance of a flat sheet in this area. This different shape enables rapid entry and exit from the welding area when using an automated welding process in which a continuous movement of the welding head has an advantageous effect on the time required for welding the electrode.

The connecting element preferably consists of several connecting parts or profiles. Likewise, the seal can consist of several sealing parts. In this case, the connection points between connection parts are arranged offset with respect to one another with respect to the connection points between sealing parts, so that the connection points do not touch or at most only touch or cross slightly. The connection of the connecting parts or profiles can be made both at a joint (90 °) and at a miter (45 °).

The finished frame consists of an outer flat and an open, inner area. The level area is used to connect the frame to the basic structure of the electrochemical reaction apparatus, the open area to accommodate the electrode.

The frame preferably consists of nickel or an alkali-resistant nickel alloy, in particular a nickel-silver alloy or of nickel that is coated with silver, or another alkali-resistant metal alloy.

When the electrode is integrated into the frame according to the invention, it is welded at its coating-free edge into the open, metallic area of the frame with the formation of a continuous or discontinuous seam. Then the elastic or plastic seal is inserted and the frame structure is closed by pressing. After closing the structure, the sealing force is thus determined by the elastic tension of the bent sheet metal fold applied. The completely framed and sealed electrode is integrated into the electrochemical reaction apparatus with a continuous weld.

The material of the basic structure, like the frame structure according to the invention, preferably consists of nickel or an alkali-resistant nickel alloy, in particular a nickel-silver alloy or of nickel that is coated with silver, or another alkali-resistant metal alloy. The thickness of the sheets from which the frame structure according to the invention is made is a maximum of 1 mm, preferably 0.1 to 1 mm, particularly preferably 0.2 to 1 mm.

The electrochemically active coating of the gas diffusion electrode contains a compound of the catalyst material, e.g. silver (I) oxide and a binder, e.g. a polymer such as polytetrafluoroethylene (PTFE). Furthermore, the coating material can be carbon or a carbon-containing compound as well as additives, e.g. Ammonium bicarbonate, which among other things act as pore formers.

The catalyst carrier is a mesh, fabric, braid, fleece or foam made of nickel, optionally silver-plated, or a nickel alloy, in particular nickel-silver alloy.

For welding the gas diffusion electrode onto an open frame structure using common methods such as. B. laser, resistance, metal reactive gas, metal inert gas, fuel gas, tungsten inert gas, plasma, ultrasonic welding processes can be a continuous seam as well as welding spots or

Quilting seams are used. Alternatively, the gas diffusion electrode can also be connected to the frame structure by means of a soldering process.

For the welding of the frame, which has already been provided with an electrode, into the basic structure of the electrochemical reaction apparatus, leakages must be avoided due to the necessity, especially those welding processes drive suitable, which allow the creation of a continuous seam. For example, laser, metal reactive gas, metal inert gas, fuel gas, tungsten inert gas and plasma welding processes are particularly suitable for this. Alternatively, a soldering process can also be used.

When using the above-described procedures, it was found that when using a frame for the electrode, the force exerted by the fold on the seal is sufficient to reliably seal the electrode from the frame. This could even be demonstrated when using a soft construction material for the frame structure, such as nickel.

The electrode integrated into an electrochemical reaction apparatus according to the method according to the invention can preferably, but not exclusively, be used in the following processes:

- Chlor-alkali electrolysis with oxygen depletion cathode

- Hydrochloric acid electrolysis with oxygen depletion cathode

- Electrochemical recycling of waste materials - Electrosynthesis of organic or inorganic substances

- Energy generation using fuel cell processes

Furthermore, the invention relates to a gas diffusion electrode with a connecting element which is electrically conductively connected in the edge region of the gas diffusion electrode. The gas diffusion electrode according to the invention is particularly suitable for connection to a basic structure, as described above. The configuration and connection of the connecting element with the gas diffusion electrode is also preferably configured as described above.

The invention is described below on the basis of preferred embodiments

Reference to the accompanying drawings explained in more detail. Show it: 1 shows a connecting element in combination with a seal,

2-5 different process steps for producing the gas diffusion electrode support structure according to the invention,

6 shows a first embodiment of the gas diffusion electrode support structure and

7 shows a second embodiment of the gas diffusion electrode support structure according to the invention.

Examples

The connection of a gas diffusion electrode with a gas pocket using the support structure according to the invention is described with the aid of the examples below. The gas pocket has a semi-solid basic structure 8 (FIG. 1) with a

Length of 1800 mm and a width of 250 mm. The gas diffusion electrode 10 (FIG. 2) is first inserted into a connecting element 12 (FIG. 3), here a self-supporting frame made of nickel, which is then connected to a web 11 (FIGS. 6, 7) of the basic structure 8. Such a gas pocket was used in a chlor-alkali electrolysis cell. The gas diffusion electrode was operated as an oxygen consumption cathode.

example 1

To produce the frame which forms the connecting element 12 between the gas diffusion electrode 10 and the basic structure 8, four linear, miter-made profiles made of nickel sheet (thickness: 1 mm) are cut, as shown in FIG. 1 in the enlargement 25, and by means of Tungsten inert gas (TIG) welding process in the corner areas 29 joined to a rectangular frame. The gas diffusion electrode 10 was inserted into the open profile 13 (FIG. 2) of the connecting element 12. The edge region 15 of the gas diffusion electrode is inserted into the open connecting element 12. The edge region 15 running along the four sides of the gas diffusion electrode 10 is formed by an outer part 32 without an electrochemically active coating and an inner part 33 with a coating. The gas diffusion electrode 10 is welded to the frame 12 along a line 16 (FIG. 3), for example by means of ultrasonic welding.

The sealing effect for separating the different media located on both sides of the electrode, namely oxygen and electrolyte, is achieved through the use of an elastic seal 17 made of alkali-resistant EPDM.

The seal 17 is made of four parts cut on joint 24 (FIG. 1) assembled and inserted into the open profile 13 (Fig. 4). The profile 13 is closed by pressing with a line force of 200 kg / cm (Fig. 5). The combination of a miter-cut basic structure 8 with a seal 17 cut not at miter but at a right-angled joint also causes the seal in the corners.

In a first embodiment, the framed electrode 10 is positioned on the web 11 of the basic structure in such a way that the entire frame 12 sits on the web with the folded-over part of the gas diffusion electrode 10 (FIG. 6). This type of integration has the advantage of a minimal dead area of the gas diffusion electrode 10, since the electrochemically inactive part of the framed electrode 10 overlaps with the web of the basic structure 8. The frame is connected to the base structure 8 in the edge area by means of laser weld seam 20. The use of this welding process has the advantage of a high joining speed and a low heat input into the structure, so that thermal damage to the seal or the electrode coating can be avoided.

Example 2

In a second preferred embodiment, the integration of the electrode into the basic structure of the gas pocket of the chlor-alkali electrolysis cell is similar to the embodiment described in Example 1, the production being identical to the production described with reference to FIGS. 2-5. The difference between the two embodiments lies in the seal and its geometry and in the connection of the frame 12 to the web 11 of the basic structure 8.

The seal 17, which in the exemplary embodiment shown consists of four sealing parts 34, is connected to one another in the corner region at joint 26 (FIG. 1). The four profiles 35 of the connecting element 12 are, as shown in FIG. 1 in the enlargement 28, also connected to one another in a butt joint. The butt lines of seal

17 and connecting element 12 are arranged at a right angle to one another and therefore do not overlap. A plastic seal made of polytetrafluoroethylene (PTFE) is used. The corners of the connecting element 12 are welded along the edge 30 by means of a tungsten inert gas (TIG) process; after welding the electrode 10 (see example 1), it is closed with a line force of 400 kg / cm.

The fully framed electrode 10 is positioned on the web 11 of the basic structure 8 such that only an edge region 19 of the connecting element 12 rests on the web, while the folded part of the gas diffusion electrode projects into the gas pocket (FIG. 7). The connecting element 12 is welded to the web 11 along a weld seam 18. This type of alignment can reliably avoid contact between the frame structure and the ion exchange membrane separating the cathode half cell from the anode half cell.

Example 3

In a third embodiment, similar to the embodiment described in Example 1, an elastic seal made of EPDM is used, with the difference that the four parts of the seal are mitered (see FIG. 1: 27), while the four parts of the frame are butted are cut.

After welding the electrode (see Example 1) into the open profile 13, the profile 12 is closed with a line force of 250 kg / cm.

The integration of the electrode in the basic structure of the chlor-alkali electrolysis cell is identical to the variant carried out in Example 2 (see FIG. 7).

Claims

claims

1. Gas diffusion electrode support structure for receiving a gas diffusion electrode (10) for an electrochemical reaction apparatus, with

a basic structure (8) and

a gas diffusion electrode (10) carried by the basic structure (8)

marked by

an electrically conductive connecting element (12) arranged between the basic structure (8) and the gas diffusion electrode (10).

2. Gas diffusion electrode support structure according to claim 1, characterized in that a connecting element (12) encloses an edge region (15) of the gas diffusion electrode (10).

3. Gas diffusion electrode support structure according to claim 2, characterized in that an outer part (32) of the edge region (15) of the gas diffusion electrode is at least partially coating-free and an inner part (33) of the edge region (15) with an electrochemically active coating (14 ) is provided.

4. Gas diffusion electrode support structure according to one of claims 1-3, characterized by a between the connecting element (12) and the edge region (15), in particular the inner part (33) of the edge region (15), provided seal (17).

5. gas diffusion electrode support structure according to claim 4, characterized in that to achieve the sealing effect, the connecting element (12) in the region of the seal (17) is plastically deformed.

6. Gas diffusion electrode support structure according to one of claims 1-5, characterized in that the connecting element (12) surrounds the gas diffusion electrode (10) in the form of a frame.

7. Gas diffusion electrode support structure according to one of claims 1-6, characterized in that the connecting element (12) from several

Connecting parts (35), the seal (17) consists of several sealing parts (34) and the connection points of the connecting parts (35) or

Sealing parts (34) are offset from one another.