DE3731285A1 - Dimensionally stable anode, method for manufacturing it, and use thereof - Google Patents

Abstract

A dimensionally stable anode for the electrolytic extraction of metals from their aqueous solutions, with a titanium (alloy) body, an interlayer and an electrochemically active, iridium-containing layer situated thereon, the interlayer containing antimony or its oxides, and the electrochemically active layer being formed from iridium and/or its oxides doped with antimony or its oxides. The anode, whose manufacture is described, is notable, in the extraction of metals such as copper, zinc, cobalt, iron, nickel, manganese, cadmium and/or chromium, for a low overpotential and a long service life.

Description

The invention relates to a dimensionally stable anode for the electrolytic extraction of metals from their aqueous solutions with a titanium (alloy) base body, an intermediate layer and an electrochemically active, layer containing iridium, a process for their Manufacturing and their use.

In the electrolytic extraction of metals such as zinc, Cobalt, iron, nickel, manganese, cadmium and / or chromium, but especially of copper, from their aqueous, acidic Solutions are developed at the anode oxygen. The This makes the anode a constant oxidative attack exposed, which affects the lifespan and too leads to a gradual increase in the anode overvoltage. In extreme cases, the anode is passivated, so that it it is impossible to continue electrolysis.  

The phenomenon of passivation of the anodes can mainly through the formation of electrically non-conductive and non-stick titanium oxides by oxidation of the Titanium base material with oxygen, through which the Oxide substance building up the electrode coating itself, by the oxygen diffusion permeation through the Electrode coating through or through the electrolyte be conditional.

So far, attempts have been made to provide non-managerial and non-adherent titanium oxides in the interface gas-tight barrier layers, mostly made of platinum metal passed to prevent. On the one hand, this solution is very good expensive and not always effective because it is gas-tight Pt coatings are difficult to manufacture.

Furthermore, a variety of different ones Proposed compositions for an intermediate layer that either prevent the formation of titanium oxide or one should form an adhesive, electrically conductive layer that less sensitive to oxide formation in the subsurface responds.

From US-PS 37 75 284 an anode is known for anodic formation of oxygen is suitable. they contains a substrate that consists of a Platinum / iridium alloy or an oxide of a metal Platinum group exists, which continues to have a fixed Solution of a non-valve metal oxide with a valve metal is coated. This anode has a certain one Improve durability, but still not is satisfactory. In addition, the use of a expensive intermediate layer uneconomical.  

DE-Al-31 03 168 describes an anode with a Titanium substrate known that a first coating metallic bismuth or bismuth oxides on this substrate and a second coating of metallic iridium and Iridium dioxide applied to the first coating is. According to this disclosure can this anode with advantage in different Electrolysis environments, and particularly in such, at where oxygen is formed. The However, electrode still cannot regarding its industrial application with regard to their lifespan to satisfy. This seems to be partly due to this be that a connection of the iridium oxide with Bismuth occurs, leading to changes in structure and Adhesion of the active layer leads.

Finally, from DD 2 20 621 also dimensionally stable anodes for electrochemical processes, in particular for chlor-alkali electrolysis, are known, in which an intermediate layer is applied to a titanium base body, which consists of unreduced and with predominantly higher-quality oxides of one of the elements niobium, tantalum, tungsten , Antimony and cerium or mixtures thereof in a concentration range of 0.1 to 10 mol% of doped titanium oxide. An electrochemically active layer of ruthenium oxide in combination with stoichiometric titanium oxide is then located on this doped titanium oxide intermediate layer. This anode, which is intended in particular for chlor-alkali electrolysis, cannot satisfy the electrolytic extraction of metals from their aqueous solutions, such as zinc, cobalt and, above all, copper, with regard to the resistance of the anode, its service life and the surge voltages that build up. This can be attributed to various types of circumstances, but in particular also to the fact that coatings containing ruthenium in such electrolytes tend to form gaseous RuO ₄ with impairment of the electrode properties.

The present invention is based on the object to create a novel dimensionally stable anode that with long life and low overvoltage for the electrolytic extraction of metals from their aqueous Solutions can be used. According to another aspect of The object of the invention is also intended to be a method for Manufacture of such anodes and their use to be provided.

This task is accomplished by creating a Dimensionally stable anode of the type mentioned at the beginning solved, which is characterized in that the Intermediate layer contains antimony and / or its oxides and the electrochemically active layer of iridum and / or its oxides with a doping of antimony and / or whose oxides are formed.

In the context of the invention it was surprisingly found that a thin activation layer of antimony or its Oxides or mixtures thereof on the titanium substrate in Combination with an electrochemical on it active coating of iridium or iridium oxide or Mixtures of these with an antimony (oxide) doping is suitable to give anodes that have an improved  Adhesion and improved conductivity at high Life of the anode.

In the context of the invention it is preferred that the intermediate layer is free of precious metals or their oxides. Particularly favorable results are achieved in particular if the intermediate layer consists of antimony and / or its oxides. Sb ₂ O ₃ is particularly preferred among the antimony oxides, although other known oxides may also be present.

In the anode according to the invention, the surface of the Base body made of titanium or its alloys is formed, and the intermediate layer essentially of Titanium surface oxides free. It is therefore also in the Production of the anode according to the invention that the application of the intermediate layer and electrochemically active layer, drying it and their sintering or baking is carried out in this way will prevent oxidation of the titanium base body.

The iridium or its oxide is advantageously present in the active cover layer with a weight per unit area of 4 to 30 g Ir / m ² . Particularly favorable results can be achieved with basis weights in the range from 5 to 15 g Ir / m ² .

The electrode according to the invention does not only contain antimony or its oxides in the intermediate layer but also the electrochemically active layer is with antimony or its Oxide doped. Here, the antimony is opposite Iridium present in the deficit. According to the  Investigations carried out according to the invention are advantageous if the molar ratio of iridium: antimony in the active layer the ratio 100: 0.5-5 is sufficient. Values were particularly favorable with molar ratios of Ir: Sb = 100: 1-3 achieved.

The electrochemically active layer made of iridium or Iridium oxide or mixtures thereof is preferably from Valve metal oxides free. Aside from usual Auxiliaries such as adhesion promoters etc. exist after a particular embodiment of the invention the active Layer of iridium or oxide with the doping component Antimony or its respective oxides. As an adhesion promoter the usual for the volatile antimony oxides Find application, with the addition of copper as an oxide may be preferred.

According to a further aspect of the invention that is also Manufacturing process for the anode according to the invention includes. Usually one proceeds in such a way that one

• a) the anode substrate with a solution or dispersion of an antomony salt coated at least once,
• b) thereafter at temperatures below 400 ° C in an optionally oxidizing atmosphere, e.g. Air, heated,
• c) then with a solution or dispersion, the Ir and Sb compounds contains, coated and
• d) then dries and at temperatures in the range of 350 to 550 ° C heated.

Before applying the solution to form the  Intermediate layer usually makes the surface rough etched to increase the adhesion of the iridium coating favor.

The intermediate layer can advantageously be produced by applying a very dilute acidic paint which contains a small amount of a thermally decomposable antimony compound, for example in the form of inorganic or organic compounds of the antimony. Among the antimony compounds that can be used, antimony oxynitrate is particularly preferred, since it does not require any oxidizing conditions in order to form an oxide during thermal decomposition. The proportion of the thermally decomposable antimony compound is expediently in 0.1 to 0.5 molar solution, although proportions which differ from this may also be possible. The coating solution generally also contains a solvent, for example an organic solvent. Alcohols such as butanol, propanol etc. are particularly suitable as such. In addition, an acid is advantageously added to the solution, which precludes the formation of titanium oxide on the base body as much as possible during the coating. Such acids can be organic acids or, for example, hydrochloric acid. The coating solution leading to the intermediate layer can be baked at temperatures below 400 ° C., advantageously in the range between 350 to 390 ° C., since the formation of titanium surface oxides can be avoided or restricted under these conditions. Amounts of antimony in the range from 0.05 to 0.5 g / m ² and particularly preferably 0.1 to 0.2 g / m ^{2 should be} applied by the coating. These levels of antimony can normally be achieved with a single coating. In special cases, if, for example, the substrates cannot be dried horizontally and therefore the specified basis weights cannot be achieved, the antimony-containing solution can be applied a second or further time.

Because the antimony oxides during thermal treatment volatile, the color containing antimony can also small amounts of adhesion promoters, e.g. Copper. Therefore, the coating solutions for the Interlayer about 0.05 to 0.1 mol of copper in the form have its inorganic or organic solutions. A separate application of the Adhesion promoter, e.g. Cu compounds, after application of the solution containing antimony.

On the prepared surface, the electrocatalytically effective top layer applied, the Iridium and antimony as oxide and / or possibly also as Contains metal.

Iridium is usually applied in the form of 0.1 to 1 molar solutions of iridium salts or acids. In particular, hexachloroiridium (4) acid hydrate is advantageously used, the solution of which can be admixed with 0.01 to 0.1 mol of antimony (III) chloride. The molar ratio of iridium: antimony in these solutions is in the range from 100: 0.5-5, preferably 100: 1-3. These solutions can be applied several times and each baked at temperatures between 350 and 500 ° C. In the final baking process, temperatures of 500 to 550 ° C can finally be appropriate. The coating solutions are usually applied several times until a basis weight of 4 to 30 g Ir / m ² , preferably 5 to 15 g Ir / m ² , has been reached.

The anodes according to the invention are outstandingly suitable as oxygen-developing electrodes in electrolytic metal extraction processes. This makes them particularly suitable for the production of zinc, cobalt, iron, nickel, manganese, cadmium, copper and / or chromium from their aqueous acidic solutions. The anodes according to the invention have a longer service life and a lower overvoltage after longer running times than anodes according to the prior art. It is also possible to reduce the amount of iridium in the cover layer compared to conventional values in the anodes according to the invention. Finally, the anodes according to the invention survive switch-off processes or low-load times better in long-term operation without the coating becoming detached. In particular, it has been shown that the anode is particularly suitable for the production of copper, in which the electrolyte is obtained by solvent extraction of copper ores and has the usual level of organics, additives and impurities. The copper sulfate content of such solutions is usually 30 to 50 g Cu / l with a proportion of free sulfuric acid in the range from about 50 to 100 g / 1 and electrolyte temperatures of 40 to 60 ° C. At current densities between 200 and 1000 A / m ² at an anode potential of 1.4 to 1.6 V (against NHE), the wear of the anodes according to the invention is 1 to 1.5 mg Ir / kAh. Under favorable operating conditions, wear rates of even 0.5 mg Ir / kAh can be achieved.

The manufacture of the anode according to the invention is below in an advantageous embodiment further explained:

example 1

A titanium sheet measuring 100 × 10 × 1 mm was degreased and etched with 20% hydrochloric acid, rinsed and dried. The titanium substrate prepared in this way was coated with a 0.1 molar solution of SbCl ₁₃ in 20% hydrochloric acid which contains 8% by volume n-butanol, dried and heat-treated at 390 ° C. in a forced-air oven for 15 minutes. This coating with SbCl ₁₃ solution was repeated two more times.

The active top layer is applied to this intermediate layer by coating the substrate with a coating solution containing 0.5 Mo ¹ hexachloriridium (IV) acid hydrate and 0.005 mol antimony (III) chloride in 20% hydrochloric acid with 8 vol % n-butanol contains. After brushing the solution, the substrate is air-dried and then heat-treated in a forced air oven at 400 ° C for 20 minutes. This process is repeated 10 to 12 times until about 12 g of iridium, calculated as metal per m ^{2 of} anode surface, have been applied.

Then the anode is finished for 60 minutes at 500 ° C. The anode thus produced was under technical electrolysis conditions in an electrolyte for the copper recovery electrolysis, which contained 50 g copper / l as sulfate and 50 g free sulfuric acid / l as well as the additives and impurities usual in copper recovery electrolysis in the usual technical concentrations, with a current density of 1.2 kA / m ^{2 used} at a temperature of 40 to 50 ° C.

After 2000 hours of operation, the anode potential was 1.6 V / NHE and the wear rate was 1.0 mg / kAh.

Example 2

A titanium sheet measuring 100 × 10 × 1 mm was degreased and etched with 20% hydrochloric acid, rinsed and dried. The titanium substrate prepared in this way was coated with a 0.1 molar solution of SbCl ₁₃ in 20% hydrochloric acid and containing 8% by volume n-butanol and dried. A layer of a 0.1 molar aqueous solution of copper (II) acetate was then applied, air-dried until the solvent evaporated, and then heat-treated at 390 ° C. in a forced air oven for 15 minutes. This coating with SbCl ₁₃ solution and copper (II) acetate solution was repeated two more times.

The active cover layer is applied to this intermediate layer by coating the substrate with a coating solution containing 0.5 mol of hexachloriridium (IV) acid hydrate and 0.005 mol of antimony (III) chloride in 20% hydrochloric acid with 8 vol. % n-butanol contains. After brushing the solution, the substrate is air-dried and then heat-treated in a forced air oven at 390 ° C for 20 minutes. This process is repeated 10 to 12 times until about 12 g of iridium / m ² , calculated as metal, have been applied. In the first and second coating processes, an additional layer of copper acetate is applied as described above. Then the anode is finished for 60 minutes at 500 ° C.

The anode produced in this way showed an anode potential of 1.6 V / NHE under technical electrolysis conditions in a copper recovery electrolyte at a current density of 1.2 kA / m ² after 1000 hours of operation. The wear rate was 0.8 mg / kAh.

Claims (14)

1. Dimensionally stable anode for the electrolytic extraction of metals from their aqueous solutions with a titanium (alloy) base body, an intermediate layer and an electrochemically active, iridium-containing layer thereon, characterized in that the intermediate layer contains antimony and / or its oxides and the electrochemical active layer of iridum and / or its oxides is formed with a doping of antimony and / or its oxides. 2. Dimensionally stable anode according to claim 1, characterized characterized that the intermediate layer is free of precious metal. 3. Dimensionally stable anode according to claim 1, characterized characterized that the intermediate layer consists of antimony and / or its oxides. 4. Dimensionally stable anode according to one or more of the previous claims, thereby characterized in that the Titanium body essentially of Titanium surface oxides is free. 5. Dimensionally stable anode according to one or more of the preceding claims, characterized in that the iridium or iridium oxide is present in the active layer with a basis weight of 4 to 30 g Ir / m ² . 6. Dimensionally stable anode according to one or more of the previous claims, thereby characterized in that the molar ratio of iridium: antimony in the active layer Corresponds to a ratio of 100: 0.5-5. 7. Dimensionally stable anode according to one or more of the previous claims, thereby characterized that the active layer is free of valve metal oxides. 8. Dimensionally stable anode according to one or more of the previous claims, thereby  characterized that the active layer consists of iridium and antimony or their oxides. 9. A method for producing the anode according to one or more of the preceding claims by applying the intermediate layer on an anode substrate made of titanium or a titanium alloy and subsequently the iridium-containing active layer, characterized in that

• a) the anode substrate is coated at least once with a solution or dispersion of an antimony salt,
• b) subsequently heated at temperatures below 400 ° C. in an optionally oxidizing atmosphere,
• c) then coated with a solution or dispersion containing iridium and antimony compounds and
• d) then drying and heating at temperatures in the range of 350 to 550 ° C.

10. The method according to claim 9, characterized characterized that a hydrochloric acid Antimony chloride solution for the preparation of the Interlayer is used, which may be additional Contains adhesion promoter. 11. The method according to claim 9, characterized characterized that a hydrochloric acid Hexachloroiridium acid solution with an additive Antimony halide as a coating solution for Production of the active layer is used.   12. The method according to one or more of the preceding Claims, characterized in that the heating processes according to the order of the Intermediate layer and the active layer gently in in a mildly oxidizing atmosphere, essentially oxidation of the titanium surface to avoid. 13. Use of the anode according to one or more of the Claims 1 to 8 as an oxygen-developing electrode in electrolytic processes. 14. Use according to claim 13 for electrolytic Extraction of metals such as copper, zinc, cobalt, Iron, nickel, manganese, cadmium, and / or chrome their aqueous acidic solutions.