DD285127A5 - Electrode element of an electrode for gas-developing electrolytic processes - Google Patents

Abstract

The invention relates to electrode elements which are suitable for the production of electrodes for gas-producing electrolytic processes. The electrodes of electrode elements arranged parallel to one another are characterized in that the electrode elements (1) are lamellae, tapes, foils or the like having a thickness (6) of up to 3 times the mean bubble discharge diameter, in that the surfaces of the electrode elements (1) have profilings (2 3, 4) whose height fixes a capillary-effect gap (4) between adjacent electrode elements (1) and that the width (5) of the electrode elements (1) is at least 10 times that of the gap (4). Fig. 3 {electrode element; Electrolysis; Gas development; parallel elements; Gap; capillary; profiling}

Description

For this 1 page drawings

Field of application of the invention

The invention relates to electrode elements which are suitable for the production of electrodes for gas-developing electrolytic processes.

Characteristic of the known state of the art

For the production of various important basic chemicals, such as sodium hydroxide, chlorine, hydrogen or hydrogen peroxide, gas-producing electrolytic processes are of paramount importance. The electrodes to be used in the electrolysis of alkaline solutions, water, hydrochloric acid or sulfuric acid must correspond to a large number of partly conflicting use parameters. A very important requirement is the rapid removal of the evolved gas from the space between the anode and cathode beyond these electrodes in order to avoid a large proportion of gas which increases the electrical resistance of the electrolyte. However, this is contrary to the endeavor to use the available construction surface for a maximum effective for an electrochemically acting electrode surface. It is further desired to realize a uniform and finely structured electrode surface, so that the conditions for a homogeneous electric field are given. Discontinuities, such. B. edges, lead to field strength increases and thus to a non-uniform electrode load, which causes not only energy losses, but also premature wear of the electrode material or the electro-catalytic coating (so-called coating).

Essential for ensuring an optimal process is also the realization of a uniform, small electrode gap, without the use of membranes this mechanically strong stress or even damage. It should also be avoided that electrode elements with a large thickness exert a high contact pressure on the membrane and thus hinder the flow of electrolyte, or the ion transport through the pore system of the membrane markedly. Two important basic types of gas-generating metallic electrodes are known: On the one hand used by power distributors, parallel arranged profile bars whose cross-section is circular, elliptical, teardrop or rectangular (DE-OS 3008116, DE-OS 3325187, DE-PS 3519272, DE-OS 3519573). But also U-shaped in spaced juxtaposed rails are known according to DE-AS 1271093.

On the other hand perforated sheets with vertical and horizontal slits, with respect to the electrode plane angled or deep-drawn segments, perforated hole electrodes and grid metal electrodes are known (DD-PS 250026, DE-OS 3625506, DE-OS 2735238).

Representatives of the former basic type use parallel elements that are firmly connected to power distribution rails and a teardrop-shaped cross section (DE-OS 3325187) or an approximately circular cross-section (DE-OS 3008116). The circular cross section was modified by separating segments lying in the electrode plane. Both electrodes should preferably be used for the chloralkali electrolysis in amalgam cells. The disadvantage is that the electrodes have no significantly reduced Gasblasenbedeckungsgiad. The removal of the gas takes place exclusively by the fluid flow and the buoyancy. The particular cross-sectional geometries are not suitable for assuming an active role in gas transport through the electrode. Although they prevent the catalytic coating by avoiding points of discontinuity or overstressing, this is done by accepting the disadvantages due to the radiused nonuniform distances of the electrode surface.

DE-OS 3519272 discloses an electrode structure using a plurality of parallel elements of rectangular cross-section. A plate-shaped support with bulges on both sides serves to fasten the electrode elements and as a current distributor. The cross section of the rectangular electrode elements should have a ratio of 1: 5. Thus, the gas exhaust tabs in the region of the gap do not come into contact and swirl, a relatively large gap between adjacent elements is provided. This leads to a relatively low utilization of the available construction surface and to an uneven electrode load, in particular in the area of

Edges of rectangular profiles, where increased wear of the catalytic coating is expected. The selected shape of the carrier of the electrode elements, which is at the same time current distributor, prevents the concentration of the gas in the space beyond the reactive electrode surface. As a result, there is a high proportion of gas in the reaction area associated with increased electrical losses.

One of the above-described electrode structure is very similar to the disclosed in DE-OS 3519 573 electrode. It also consists of parallel arranged on a power distribution elements rectangular cross-section whose distance from each other is a few millimeters. In addition, the membrane facing the end faces of the elements on a plurality of recesses. The webs between them are not electrocatalytically coated and lie on the membrane. Thus, the available reactive surface is only about 10% of the membrane area. Due to relative movements between the electrode and the membrane, the webs can cause local damage to the membrane.

As a representative of the second basic type of gas-generating metallic electrodes is described in DE-OS 2735238 an electrode with vertical louver-like elements that were produced by pressing out of a sheet. This electrode structure causes considerable field strength differences and thus greatly different loads on the electrode surface. At the edges of the louver-like elements facing the membrane, increased wear of the electrolytic layer is to be expected.

Venetian blind elements in predominantly horizontal arrangement have been described in DD-PS 250026. The very sharp-edged jalousie end causes a strong field strength increase and a considerable mechanical and thermal loads on the membrane.

DE-OS 3625 506 discloses an electrode having a number of substantially horizontal, rectangular openings, which bridge or flag parts are assigned.

This electrode too can not prevent the formation of a relatively large proportion of gas bubbles in the space between the electrode and the membrane.

Object of the invention

The object of the invention is the development of electrode elements for electrodes in gas-producing electrolytic cells, which ensure a cost-effective production and improved performance parameters of the electrodes.

Explanation of the essence of the invention

The invention has for its object to develop electrode elements for electrodes gas-producing electrolytic processes, which allow the production of uniformly delicate electrode structures. A directed gas bubble transport of the electrode structure is intended to significantly reduce the gas bubble loading in the electrolyte of the reaction space. The electrode elements should allow a simple and variable positioning to each other.

According to the invention the object is achieved in that are used as electrode elements lamellae, tapes, foils or the like with a thickness of up to 3 times the average bladder removal diameter. Between the electrode elements arranged parallel to one another there is a gap which causes the capillary effect. It is fixed by profiles of appropriate height, which are supported by the surfaces of the electrode elements. The width of the electrode elements is at least 10 times the realized capillary gap width.

To ensure a directed removal of gas from the reaction space into the degassing space, the electrode elements have profiles with preferably a structure extending transversely to the plane of the electrode. They ensure that the gas can get into the degassing space by the shortest route and thus does not cause any appreciable increase in the ohmic resistance of the electrolyte -m reaction space.

The electrode elements can carry the profiling according to the invention on one or both sides. In the case of the first-mentioned variant, the electrode electrodes lie in the same direction with respect to their profiles. In the other case, the alternate arrangement of prorated and smooth, d. H. not profiled, electrode elements useful. However, in order to obtain a capillary gap which is wider than the height of the web-like profilings, it may be necessary to use only electrode elements profiled on both sides. In order for the profilings to rest on one another, they are to be designed with respect to the surfaces of an electrode element with a different inclination relative to the longitudinal axis.

The profiles may also have structures that are to be regarded as local, non-directional surveys and z. B. knob or are formed like a wart.

embodiment

The invention will be explained in more detail with reference to an embodiment and the figures. It represents

Fig. 1: two Kapillarspaltelektroden with intermediate separator

2: true-to-scale enlargement of a section of a capillary gap electrode (M: approximately 10: 1)

3: electrode element with horizontally extending web-like profiles (one-sided)

4: electrode element with substantially horizontally extending web-like profiles (on both sides)

Fig.5: Electrode element with local (directionally indifferent) profilings.

The electrode elements 1 according to the invention comprise not only the variants of unilateral or bilateral, directional or directionally indifferent profile structure illustrated in FIGS. 3 to 5. They comprise all profiled electrode elements 1 made of thin lamellae, tapes, foils or the like, which are in an orderly packaged to the electrode 8

between adjacent electrode elements 1 to fix a capillary effect causing gap 4 and enable or ensure the gas transport transversely to the electrode plane. In this case, the electrode elements 1 have a thickness 6 up to 3 times the bubble detachment diameter and a width 5 of at least 10 times the capillary gap 4.

1 shows two capillary gap electrodes 8 as the cathode and anode with an interposed separating element 7 (eg membrane) in the so-called zero distance. The electrode structure of the invention allows a large and constant electrode spacing, which corresponds to the thickness of the separating element 7 over a large area. The conformability of the capillary gap electrode moreover ensures a uniform pressure distribution over the separating element 7, which not only prevents its damage, but also does not impair the ion current or the electrolyte current. The space, which adjoins the electrode surface, which faces away from the separating element 7, serves as a degassing space for the electrolyte.

FIG. 2 shows a scale-enlarged detail of the capillary gap electrode.

While the electrode element 1 depicted in FIG. 3 has horizontally extending web-like profilings 2 on only one side, stag-like profiles 3 are arranged on both sides on the electrode element 1 according to FIG. The profilings 3 with the axis 9 of the one side do not run parallel to the profilings 3 with the axis 10 of the other side of the same electrode element 1. This makes it possible to double the capillary gap 4 between adjacent electrode elements 1. The intersecting profiles 3 have point contact. But it is also an alternate arrangement of both sides profiled electrode elements 1 with smooth, non-profiled electrode elements possible. FIG. 5 shows directionally different, wart-like profiles 4, which can be arranged on one or both sides of the electrode element.

The generation of the profiles 2,3,4 can be done by embossing tools. The production of electrode elements 1 by the melt spinning method into glass-metallic foil tapes is particularly economical. They usually have a thickness 6 of 20pm to 100μιη and a width of about 5mm. To produce the desired profiles 2,4, the surface of the roller is prepared accordingly.

Electrodes of the electrode elements according to the invention form in a dense packing a gas- and liquid-permeable, mechanically highly resilient and yet completely conformable to a flat surface structure. At this surface no high requirements with regard to evenness, warp o.a. be put.

The advantages of the electrode elements according to the invention are that they can be assembled without separate spacers to dense, fine and uniformly structured packings. The capillary gap between adjacent electrode elements, fixed by their profiles, ensures a directed gas transport and an intensive exchange of electrolytes.

Claims (4)

Electrode elements of an electrode for gas-producing electrolytic processes arranged parallel to each other, characterized in that the electrode elements (1) are lameilers, tapes, foils or the like having a thickness (6) up to 3 times the mean bubble peeling diameter the electrode elements (1) carry profiles (2,3,4) whose height between adjacent Elektrodanelementen (1) causes a capillary effect causing gap (4), and that the width (5) of the electrode elements (1) at least 10 times the gap (4). 2. electrode elements according to claim 1, characterized in that the profilings (2,3) have a web-like, transverse to the plane of the electrode (8) extending structure. 3. electrode elements according to claim 1, characterized in that the profiling (4) has a knobbed or wart-like structure. 4. electrode elements according to claim 1 to 3, characterized in that the profilings (2, 3, 4) on both sides of the electrode elements (1) are arranged.