DE3102306A1 - Electrodes - Google Patents

Abstract

Electrodes comprising a carrier composed of an electrically conducting material and an active layer applied thereto contain nickel and/or cobalt in the active layer in addition to iron. The nickel and/or cobalt content should be 10 to 20 % by weight. The electrodes are suitable, in particular, as cathodes for alkali-chlorine (chlor-alkali) electrolysis cells.

Description

Electrodes

Technical electrolyses, especially chlor-alkali electrolyses using the diaphragm and membrane process, in which hydrogen is evolved at the cathode will require cathode materials with low hydrogen overvoltages in order to be inexpensive to be able to work.

At present, the diaphragm process is used for chlor-alkali electrolysis Iron cathodes, which overvoltages with technical current densities of 1 to 2.8 KA / m2 from 250 to 400 mV.

To reduce the overvoltage, especially during electrolysis aqueous hydrochloric acid, it is known to use the electrolyte when using graphite cathodes Adding salts of certain metals. These metals separate during electrolysis on the cathodes, whereby the hydrogen overvoltage is caused by the layers formed in this way is reduced. According to the French patent 1,208 508 this Purposes added copper, nickel, antimony, silver, gold, cobalt, iron and platinum salts (see also DL patent specification 3 725). According to DE-AS 12 16 852, the electrolyte a palladium salt was added during the electrolysis. However, to have sufficient effects To achieve, it is necessary to use considerable amounts of these salts. About that In addition, these additives have the further disadvantage that the hydrogen overvoltage is reduced only temporarily immediately after their addition, i.e. that one during the duration of the electrolysis must periodically or continuously add these additives, to keep the hydrogen overvoltage at a constantly lower value.

British patent specification 1 004 380 describes electrodes, which consist of a substrate made of a conductive material coated with an alloy is coated, which, in addition to molybdenum and tungsten, contains at least one of the elements iron, Contains cobalt and nickel. These layers, in the most varied of ways the substrate can be applied, have the disadvantage that they are in the cell are not corrosion-resistant to the electrolyte in an unloaded state and therefore leaching out the tungsten and molybdenum from the electrode surface crumble off. Apart from this disadvantage it is when using these electrodes it is also not possible to operate diaphragm and amalgam cells in combination, as that Molybdenum dissolved in the diaphragm cell and tungsten in the amalgam cell to disturbances by reducing the hydrogen overvoltage at the mercury cathode would lead.

DE-AS 12 73 498 discloses a method for producing electrodes for electrolytic water decomposers, in which one the overvoltage is reduced Activation layer on electrode surfaces by galvanic deposition of porous nickel containing embedded nickel compounds with the help of a Matt nickel bath at pH values above 5.8 and current densities from 10 to 40 A / dm2 is produced. The deposition of such nickel layers with targeted storage nickel hydroxide is difficult to control, so that high reject rates occur and such electrodes have not previously been used technically.

Finally, in US Pat. No. 4,049,841, cathodes are described which consist of a support made of iron on its surface by flame or plasma spraying a metal powder has been applied that has a lower hydrogen Overload than iron possesses. Such metals are, for example, cobalt, nickel, platinum, Molybdenum, tungsten, manganese, iron, tantalum, niobium, their carbides, nitrides or theirs Called alloys and mixtures. The disadvantage of this method is that the Carrier during the coating process is not dimensionally stable, that high powder losses up to occur to 65% and that the hydrogen overvoltages of these electrodes about 180 up to 200 mV. Similar electrodes are described in DE-AS 20 02 298, which also consist of a porous nickel layer, which is superficially on a metallic base are applied.

The present invention was based on the gift of specifying electrodes, which are used in particular as cathodes for chlor-alkali electrolysis cells and which are characterized by a low hydrogen overvoltage. Of the The present invention was based on the further object of a method for production to indicate such electrodes, which is reproducible at any time and according to which one Can produce electrodes without deformation of the carrier occurring.

It has now been found that this task with electrodes, in particular Cathodes for chlor-alkali electrolysis cells, consisting of a carrier of a electrically conductive material and active layers applied to it, in addition to Iron containing nickel and / or cobalt, can be dissolved in that the nickel and / or cobalt content 10 to.

20% by weight.

Surprisingly, electrodes whose active layers show nickel and cobalt in the specified range and although their iron content is very high is high, and 80% and above that, an extremely low one Hydrogen overvoltage.

Practically all electrically conductive materials are used as carriers, which are resistant to the appropriate electrolyte, but preferably iron into consideration.

The active layers according to the invention can be applied by cathode sputtering, vapor deposition, plasma coating, flame spray coating or by chemical reduction of compounds applied to the substrate metals mentioned.

However, the active layers are particularly advantageous electrolytically deposited from aqueous solutions, as this involves electrodes with particularly low Hydrogen overvoltages are obtained and compared to other processes, such as flame or plasma spraying, non-deformed electrodes are obtained. Have to do this especially acetate-buffered, acetic acid electrolytes have proven their worth. Suitable as acetate in particular ammonium acetate. The acetic acid content in the electrolyte should be 1.5 to 10 wt.%. The concentration of iron salts or nickel and cobalt salts should be roughly the ratio of iron: cobalt and / or nickel on the carrier to be applied active layer correspond. The total metal salt concentration in the electrolyte should be 0.5 to 20 g / l, preferably 4 to 10 g / l, based in each case on the metal content of the salt. The metal salts are those which are soluble in the areas mentioned Salts in question, e.g. the chlorides, nitrates, sulfates, acetates, citrates and tartrates.

The electrolytic deposition is expediently carried out at elevated temperatures from e.g. 500C, preferably 80 to 950C. In order to be able to work without pressure, the parting dung take place below the boiling point of the electrolyte.

When using elevated temperatures, they become particularly well-adhering Obtained active layers with particularly low hydrogen overvoltage. The electrolytic Deposition takes place at current densities of 10 to 2,500 mA / cm2, preferably 50 to 750 mA / cm2.

Example 1 An iron sheet with the dimensions of 20 x 150 x 2 mm is stripped in 10% strength by weight aqueous hydrochloric acid and treated with dist. Water washed. The cleaned iron sheet is then coated cathodically in an electrolyte bath, which contains 30 g of acetic acid, 38.5 g of ammonium acetate, 25.5 g of FeCl2. 4H20 and 4.5 g NiCl2 . 6H20 dissolved in 930 ml of water, 10 minutes at a current density of 300 mA / cm2 and temperature of + 820C. After the coating, the finished cathode, the active layer of which contains 86% by weight of iron and 13.8% by weight of nickel, in 13% by weight aqueous sodium hydroxide solution and the cathodic current voltage curve at + 800C added. The following overvoltages are generated depending on the current density determined: current density KA / m2 0.15 1.0 1.5 1.6 2.3 2.8 overvoltage mV 18. 21 22 23 26 27 If a bath is used for coating, which only contains 30 g NiCl2. 6H20 and does not contain any iron salt for the coating, the overvoltage is 1.5 KA / m2 all other things being equal, about 230 mV.

Example 2 An iron sheet is prepared as in Example 1 and shown in an electrolyte containing 32 g of acetic acid, 40 g of ammonium acetate, 24 g of FeC12. 4H20, 3 g NiCl2. 6H20 and 3 g CoCl2. Contains 6H20 dissolved in 930 ml of water, 3 minutes coated at +80 C and a cathodic current density of 300 mA / cm. The active layer the electrode contains 85.8% by weight of iron, 6.8% by weight of cobalt and 7.3% by weight of nickel. In 13% strength by weight aqueous sodium hydroxide solution, the following overvoltages are obtained at + 800C: Current density KA / m2 0.15 1.0 1.5 2.3 2.8 Overvoltage mV 5 12 20 23 25 Example 3 An iron sheet with the dimensions as in Example 1 is blasted with corundum cleaned superficially. Then you wear a with the help of the plasma torch about 60 / um thick layer of an iron-nickel alloy, the 83 wt.% iron and 17 Contains% nickel by weight. A nickel-iron powder of the grain size is used for the coating <40 / µm) 25 to be used. An argon-hydrogen mixture (70 Vol.% Hydrogen) is used.

The following are obtained in 13% strength by weight aqueous sodium hydroxide solution at + 800C cathodic overvoltage values: current density KA / m2 0.15 1.0 1.5 2.3 2.8 overvoltage mV 22 27 30 33 35 Example 4 t 4 9 iron sheets with the dimensions 150 × 20 × 2 mm are stripped in 10% strength by weight aqueous hydrochloric acid and distilled Water washed. The coating takes place in an acetate-buffered electrolysis bath (30 g / l acetic acid, 38.5 g / l ammonium acetate) with growing, in the following table specified metal salt concentrations at current densities of 3000 kA / m2 and temperatures of 800C (duration of the deposition in each case approx. 10 min).

The following table shows the hydrogen overvoltages measured in 13% strength by weight sodium hydroxide solution, depending on the respective composition of the coating tape and the resulting active layer.

Electrode electrolyte - active layer hydrogeng FeCl. g NiCl. % Ni overvoltage 4 H20 / i 6 H20 / i at 80 C mV at 2 1.5 1 26.0 4.0 13.4 20 2 25.0 5.0 14.2 22 a) - 30 100 230 b) 30 - O 220 c) 27.5 2.5 7.0 77 d) 20.0 10 29.7 50 e) 15 15 44.0 56 f) 10 20 62.8 86 g) 5 25 70.4 140 The table shows that active layers (electrodes 1 and 2) whose nickel content is within the claimed In the range from 10 to 20% by weight, there is a significantly lower hydrogen overvoltage exhibit as 'Active layers whose nickel content is outside this Range is (comparison electrodes c) -g) and a considerably lower hydrogen overvoltage compared to active layers, the active layer of which consists only of nickel or iron consists (comparison electrodes a) and b)).

Example 5 9 iron sheets are made under the conditions of the example 4 provided with an active layer that contains cobalt instead of nickel.

The following table shows the overvoltage values for each Electrodes specified.

Electrode Electrolyte Active Layer Hydrogen Coat2. g CoCl. % Co overvoltage 4 H20 '6 H20 / i at 80 C mV at 1.5 KA / m2 1 26.2 3.8 13 18 2 25 5 14.2 17 a) - 30 100 250 b) 30 - O 220 c) 27.5 2.5 7.0 60 d) 20 10 30.0 26 e) 15 15 44.2 38 f) 10 20 62.8 82 g) 5 25 69.3 138 The table shows that active layers, whose cobalt content is 10 to 20% by weight (electrodes 1 and 2), a significantly lower one Have hydrogen overvoltage compared to active layers, whose cobalt / iron content is outside this range (comparison electrodes c) -g)) and the hydrogen overvoltage is considerably below that of active layers which is pure iron or

Contain cobalt (comparison electrodes a) and b)).

Claims (3)

Claims 1. Electrodes, in particular cathodes for chlor-alkali electrolysis cells, consisting of a carrier made of an electrically conductive material and applied to it Active layers which contain nickel and / or cobalt in addition to iron, characterized in that that the nickel and / or cobalt content is 10 to 20 wt.%. 2. The method for applying the active layers according to claim 1, characterized characterized in that the layers are electrolytically polarized on the cathodically Carrier using an iron and nickel and / or cobalt salt containing acetate-buffered acetic acid electrolytes. 3. The method according to claim 2, characterized in that the acetic acid content in the electrolyte 1.5 to 10% by weight, the acetate content 1.0 to 12% by weight and the content of iron, cobalt and / or nickel salts 0.5 to 20 g / l, based on the metal content of the salts.