DE4227179C1 - Platinum@ electrolysis recovery - has cation exchange membrane separating anode and cathode zones to give metal powder without producing chlorine@ gas - Google Patents

Abstract

In the recovery of platinum metals from watery acid salt solutions of their chloro compounds, in an electrolytic action, a cation exchange membrane separates the anode and cathode zones. The solution in the anode zone containes acid ions with an electrochemical anion potential finer than water. The electrolysis is effected at a temp. of 10-18 deg. C with a current density of 1-100 A/dm2. The electrolysis is pref. at temp. of 20-60 deg. C, with a current density of 5-50 A/dm2. A solution used in the cathode zone has a start concentration of 1-50 g/litre of platinum metal as a chloro compound. The solution in the cathode zone has a pH value of 0-2. Diluted sulphuric acid is in the anode zone, or a sodium sulphate solution is used. The cation exchange membrane is based on an organic synthetic resin, containing sulphonato groups. USE/ADVANTAGE - The technique is for the recovery of platinum metals in powder form such as ruthenium, rhodium, osmium, iridium, platinum and their alloys. It delivers a loose powder material, with good working qualities, without producing chlorine gas.

Description

The invention relates to a method for the electrolytic production of Platinum metals from aqueous hydrochloric acid solution of their chlorine compounds in one through an ion exchange membrane in the anode compartment and cathode compartment separate electrolysis cell, with an aqueous solution in the anode compartment and the solution of the chloro compounds is in the cathode compartment. The invention relates particularly to the electrolytic extraction of the platinum metals in Powder form.

From DD 1 39 605 it is known to electrolytically powder platinum metals to separate aqueous solutions. Solutions of their chloro complexes, after excess acid has been evaporated at a concentration of 5 to 50 g / l platinum metal, a pH between 0.3 and 1.0 and a current density from 10 to 150 mA / cm² at 20 ° C and a residence time of 5 to 10 min treated electrolytically. The powders deposit on the cathode and are by stripping or by rhythmic movements of the Cathode removed. They are pourable and screenable; their particle size is between 0 and 1 mm and can be achieved by varying concentration, temperature and pH value can be influenced.

According to EP 0 249 316 B1, metals can be obtained from aqueous solutions of their compounds, such as gold from potassium gold cyanide and platinum from chloroplatinic acid, by electrolysis in an electrolysis cell separated by a fluorinated anion exchange membrane with quaternary ammonium groups as a diaphragm in the anode compartment and cathode compartment . The metals are deposited on the cathode from the solution of the metal compounds in the cathode compartment, while oxygen (for gold deposition) or chlorine (for platinum deposition) is formed on the anode from the metal-free aqueous solution filling the anode compartment. The electrolysis can take place at temperatures from room temperature to 100 ° C and with current densities of 10 ^-2 to 50 A / dm².

The invention has for its object a method of the beginning characterized way to find with which platinum metals from the aqueous Solutions of their chlorine compounds electrolytically, without developed chlorine gas, let it win. The procedure is particularly designed to Extraction of the platinum metals in the form of loose powder with good processing properties from those resulting from the platinum group metal divorce Enable solutions. Platinum metals in the sense of the invention are ruthenium, rhodium, palladium, Osmium, iridium, platinum and alloys thereof.

This task is - based on a procedure according to the generic term - Solved with the characterizing features of claim 1.

Sub-claims 2 to 9 contain further refinements of the method.

The process has proven particularly useful when the electrolysis at a Temperature of 20 to 60 ° C with a current density of 5 to 50 A / dm² and the solution in the cathode compartment has a maximum initial concentration 100 g / l platinum metal, preferably 1 to 50 g / l platinum metal, as a chloro compound and has a pH of 0 to 2.

Dilute sulfuric acid and aqueous have been used as the anode compartment liquid Sodium sulfate solutions have proven to be particularly suitable. The use of others Liquids, such as dilute phosphoric acid and phosphate solutions, is also possible.  

The anodic method is characteristic of the method according to the invention Oxygen development - chlorine gas does not form - and the high Current efficiency that u. a. is based on the fact that - in contrast to the known Process - a reoxidation of as intermediate stages of the cathodic Reduction occurring, not yet completely reduced to the metal Platinum metal ions from chlorine dissolved in the electrolyte cannot enter.

With the help of the process, the chlorine compounds can be used in powder form Extract platinum metals with good to very good yields. The loose, light to dark gray powder are characterized by high purity and good flowability.

The platinum metal chloro compounds suitable for the process are the chlorides and chloro complexes of platinum metals, such as RhCl₃, H₂PdCl₄, H₂PtCl₆, K₂PtCl₆ and RuCl₃.

Because solutions of chloro compounds of this kind in precious metal sheaths and -Refining processes arise, it lends itself to the inventive Combine processes with these processes, giving the opportunity to Anode compartment fluid in the circuit and the cathode compartment fluid in the circuit or pass through the cell proves to be particularly advantageous.

The platinum metals separate in the cathode compartment as loose on the cathode adhering powder, which, as far as it is not at the bottom of the cathode compartment collect, allow to be easily stripped from the cathode. The powders fall all the more more finely divided, the lower the platinum metal concentration, the temperature and the movement of the solution of the chloro compounds filling the cathode compartment and the higher the cathodic current density.

As the cation exchange membrane separating the cathode compartment from the anode compartment any membrane of this type is suitable, provided that it is sufficiently chemical and  is thermally stable. Cation exchange membranes have proven particularly useful based on organic synthetic resins, preferably strongly acidic cation exchange membranes, especially those with sulfonato groups.

The cathodes can be made of any known cathode material, if it is is stable in hydrochloric acid solution. Have particularly proven themselves in Metals in plate or sheet form, preferably tantalum, titanium and the platinum metals. The anodes are, for example, from the German Patents 14 67 221 and 15 71 721 known electrodes from film-forming Metal, such as titanium, tantalum, zirconium and niobium, with a platinum metal or Platinum metal oxide coating preferred.

To explain the method according to the invention in more detail, the following Examples are the production of platinum, rhodium, palladium and ruthenium powder from aqueous solutions of potassium hexachloroplatinate (IV), K₂PtCl₆, Rhodium (III) chloride, RhCl₃, tetrachloropalladic acid, H₂PdCl₄, and Ruthenium (III) chloride, RuCl₃, described.

example 1

The cathode compartment of a through the Thomapor® cation exchange membrane MC 3470 in the cathode and anode compartment separate electrolysis cell Glass is with 1 l aqueous K₂PtCl₆ solution, platinum content 4.8 g / l, and the anode compartment filled with 0.2 l of 10% sulfuric acid. The electrolysis of the Cycle K₂PtCl₆ solution is carried out at about 50 ° C using a titanium sheet with a surface of 0.2 dm² as cathode and one platinized titanium expanded metal with a surface of 0.2 dm² as well as an anode. The cathodic and the anodic current density are in each case 5 A / dm². After 250 ampere minutes - corresponding to a current yield from 63.3% - 4.8 g of platinum as a gray, loose powder that pours well and seven leaves. The cathode compartment liquid still contains 0.005 g / l Platinum.  

Example 2

The cathode compartment of a through the cation exchange membrane Nafion® 417 in Electrode cell made of glass, separated from the cathode and anode, is filled with 1 l aqueous RhCl₃ solution, rhodium content 15 g / l, and the anode compartment with 0.2 l 10% sulfuric acid filled. The electrolysis of the circulated RhCl₃ solution is carried out at room temperature using a titanium sheet with a surface area of 0.2 dm² as cathode and a platinized one Expanded titanium with a surface of 0.2 dm² as an anode. the cathodic and the anodic current density are each 10 A / dm². After 840 ampere minutes, corresponding to a cathodic current yield from 83.8% - 15 g rhodium as a gray, loose powder that pours well and seven leaves. The cathode compartment liquid still contains 0.006 g / l Rhodium.

Example 3

The anode compartment of a through the cation exchange membrane Nafion® 417 in The cathode and anode compartment separate electrolysis cell made of glass with 0.2 l 10% sulfuric acid filled. 1 l aqueous H₂PdCl₄ solution, palladium content 15 g / l, is circulated through the cathode compartment of the electrolytic cell guided. The electrolysis is carried out at room temperature using a Titanium sheet with a surface of 0.2 dm² as cathode and a platinized Expanded titanium with a surface area of 0.2 dm² as well Anode. The cathodic and the anodic current density are in each case 15 A / dm². After 700 ampere minutes - corresponding to a cathodic one Current efficiency of 64.7% - 14.99 g palladium as a gray, loose powder receive. The palladium content of the cathode compartment liquid is 0.007 g / l sunk.

Example 4

The anode compartment of a through the cation exchange membrane Nafion® 417 in The cathode and anode compartment separated glass electrolysis cell with 0.2 l 10% sulfuric acid filled. 1 l aqueous RuCl₃ solution, ruthenium content  15 g / l, is circulated through the cathode compartment of the electrolytic cell. The electrolysis is carried out at room temperature using a titanium sheet with a surface of 0.2 dm² as cathode and a platinum-coated titanium expanded metal with a surface of also 0.2 dm² as an anode. The cathodic and anodic current densities are 10 A / dm². To 3200 ampere minutes are - corresponding to a cathodic current efficiency of 22.1% - 14.8 g of ruthenium obtained as a loose gray powder. The Ruthenium concentration in the cathode compartment liquid is 0.19 g / l.

Claims (9)

1. A process for the electrolytic production of platinum metals from aqueous hydrochloric acid solution of their chloro compounds in an electrolysis cell separated by an ion exchange membrane in the anode compartment and cathode compartment, an aqueous solution containing acid anions being present in the anode compartment and the solution of the chloro compounds in the cathode compartment, characterized in that Anode and cathode compartments are separated from each other by a cation exchange membrane that contains aqueous solutions in the anode compartment as acid anions, the electrochemical anion potential of which is nobler than that of water, and the electrolysis at a temperature of 10 to 80 ° C with a current density of 1 up to 100 A / dm². 2. The method according to claim 1, characterized in that the electrolysis at a temperature of 20 to 60 ° C with a current density of 5 to 50 A / dm² is carried out. 3. The method according to claim 1 or 2, characterized in that in A solution is used that has an initial concentration of has a maximum of 100 g / l of platinum metal as a chloro compound. 4. The method according to claim 3, characterized in that in the cathode compartment a solution is used which has an initial concentration of 1 to 50 g / l Has platinum metal as a chloro compound.   5. The method according to any one of claims 1 to 4, characterized in that the solution in the cathode compartment has a pH of 0 to 2. 6. The method according to any one of claims 1 to 5, characterized in that in Dilute sulfuric acid is used in the anode compartment. 7. The method according to any one of claims 1 to 5, characterized in that in Anode compartment aqueous sodium sulfate solution is used. 8. The method according to any one of claims 1 to 7, characterized in that a cation exchange membrane based on an organic synthetic resin is used. 9. The method according to claim 8, characterized in that a cation exchange membrane based on an organic synthetic resin, the sulfonato groups contains, is used.