DE2622643A1 - PROCESS FOR EXTRACTION OF GOLD, SILVER AND TELLURA - Google Patents

Description

PATENT LAWYERS

PROF. DR. DR. J. REITSTÖTTER

DR.-ING. WOLFRAM BUNTE

DR. WERNER KINZEBACH

D-BOOO MUNICH 4O. BAUERSTRASSE 22 FERNRUF (O89) 37 63 83 TELEX 0218208 ISAR D POSTAL ADDRESS: D-80OO MUNICH 43. POST BOX 780

Munich, May 21, 1976 M / 17 127

EMPEROR MINES LIMITED

88 Richardson Street, Albert Park, Melbourne, Australia

Process for the extraction of gold, silver and tellurium

The present invention relates to extraction processes, particularly for the extraction of gold, silver and tellurium from ores containing tellurium.

Tellurium, gold and silver often come together in different forms Products such as telluride flotation concentrates and ores. So far have been used in the extraction of gold, silver and Tellurium from such concentrates and ores mostly the concentrates are roasted and by subsequent cyanidation gold and silver were then extracted. The cyanidation residues were then converted into various Processes such as sodium hydroxide leaching, tellurium extracts.

609850/0706

ORIGINAL ISSiSPECTEO

However, these processes were unsatisfactory in terms of high yields of gold, silver and tellurium.

The object of the present invention is therefore to create an extraction process that eliminates these disadvantages in a simple manner and effectively circumvents or diminishes ·.

The invention thus relates to an extraction process which is characterized in that a tellurium product is used wins, oxidizes this tellurium product, extracts gold and silver from it, dissolves the oxidized tellurium product and Tellurium precipitates from the dissolved tellurium product.

A preferred embodiment is explained with reference to the drawings, wherein

Fig. 1 is a flow diagram of an embodiment of the invention, and

Figure 2 is a flow diagram of another embodiment of the present invention.

According to a preferred embodiment, the tellurium products, which contain the starting materials, including, for example, telluride flotation concentrates which Gold, silver, and tellurium and sometimes other metals, such as selenium, contain, oxidized with an oxidizing agent, and the subsequent process stages and intermediate stages between the stages of oxidation and the dissolution of gold, silver and tellurium, to a certain degree of depend on the oxidizing agent used.

60 9 850/0706

According to another embodiment, the material containing gold, silver and tellurium, for example a telluride flotation concentrate, is oxidized in basic hypochlorite solution in the presence of an alkaline earth metal salt, preferably a calcium salt, and the tellurium remains in the insoluble residue. The flotation concentrate can be filtered as shown in the flow diagram according to FIG. 1 and the oxidation can then be carried out in the presence of NaOH and Ca (OCl) ₂ . The filtrate is returned to the oxidation stage.

On the other hand, when the oxidation occurs in the absence of an alkaline earth metal salt is carried out, the tellurium goes into solution and can by separately stirring with an alkaline earth metal salt be precipitated. Of these two alternatives, however, the former is preferable.

Gold and silver are obtained from the insoluble oxidation residue by cyanidation. The cyanidation residue is then preferably treated with a sodium sulfide solution in order to dissolve the tellurium compounds from which elementary Tellurium precipitated by using reducing agents such as sodium sulfite, sodium bisulfite or sulfur dioxide can be.

According to a second embodiment, material containing gold, silver and tellurium is oxidized under acidic conditions oxidized, sulfuric acid / potassium chlorate or sulfuric acid / potassium permanganate mixtures are suitable for this purpose. In this case the oxidation products are filtered off and the filtrate is preferred with a reducing agent Sulfur dioxide, treated to precipitate the tellurium. In this process, gold and silver are cyanidated extracted from the oxidation residue.

609850/0706

In the third process, the material containing gold, silver and tellurium is mixed with ferric chloride solution, which is a contains solid oxidizing agent, preferably manganese dioxide, oxidizes. Then the oxidized solids can with an alkali metal hydroxide solution to the To effect solution of the tellurium compound. The tellurium containing solution is then neutralized and the resulting precipitate is dissolved in a sodium sulfide solution. Then the tellurium is made using a reducing agent, such as sodium sulfite, sodium bisulfite or sulfur dioxide precipitated. In this process, gold and Silver extracted from the alkali metal hydroxide leach residue by cyanidation.

The methods according to the invention can be carried out, for example, as follows.

According to the flow diagram in FIG. 1, telluride flotation concentrates, for example about 227 kg (500 lbs) telluride flotation concentrate, are placed in a stirrer and stirred with water to a density of 15 to 20% solids.

The alkalinity is adjusted to about 5% with sodium hydroxide. After calculating the telluride in the batch, add a calcium hypochlorite slurry. Add enough chlorine to add 2.5 lbs. (1.134 kg) of available chlorine to one pound (0.454 kg) of tellurium in the batch. The alkaninity is readjusted so that it does not drop below 0.5% NaOH. The oxidation time is normally 4 hours.

609850/0706

M / 17 127 - 5 -

When the oxidation is complete, the whole is filtered and the filtrate is returned to the process in order to reduce the consumption of reagents. The oxidized solids are transferred to another stirrer and slurried again, there sodium cyanide is added, the content is adjusted to 0.5 to 1% sodium cyanide and the slurry is aerated. Periodically, solid samples are examined for gold and silver to determine when cyanidation is complete. After the cyanidation is complete, the slurry is placed in a decanting kettle where the soluble gold and silver components are separated by repeated washing and decanting.

The washing liquids are transferred to another stirred vessel, where the tellurium is dissolved in about 10% sodium sulfide solution. To facilitate this solution, the slurry temperature is raised to 95 ⁰ C. It usually takes 3 to 5 hours to dissolve, after which the slurry is filtered. The tellurium is then precipitated from the filtrate by adding sodium sulfite. The consumption of sodium sulfite is about three times the amount of tellurium contained. After filtering, the tellurium precipitate is dried and melted.

According to another example, shown in the flow sheet of Figure, refinery anode slurries are treated.

The anode slurries are mixed with a solution containing sodium hydroxide, sodium hypochlorite and a calcium salt. After a reaction time of 2 to 4 hours, the slurry is filtered, the selenium contained in the filtrate is recovered in a known manner, and the tellurium remaining as CaTeO ^ in the residue is purified by stirring with 10% -lger

609850/0706

Hydrochloric or sulfuric acid extracted. The copper that dissolves together with the tellurium is called oxalate precipitated and the tellurium is either by reduction with sulfur dioxide, or by neutralization, addition of S and precipitation obtained with sodium sulfide.

Gold and silver are then extracted from the acid leach residue by cyanidation.

Other metals, such as selenium, are also at the appropriate stage of the process extracted by appropriate procedures.

Thus, an extraction process for tellurium has been created which is relatively simple to perform and which is satisfactory brings high yields of gold, silver and tellurium. The method is advantageous because the base material does not have to be roasted.

The process according to the invention is thus an improved process for the separation of essentially pure tellurium from materials containing tellurium and also creates a new and improved process for separating gold and silver and tellurium from tellurium flotation concentrates and is therefore extremely beneficial.

609850/0706

Claims (11)

Claims 1. Process for the extraction of gold, silver and tellurium, characterized in that a telluride product is oxidized, gold and silver extracted, which oxidized Tellurium product dissolves and tellurium precipitates from the dissolved tellurium product. 2. The method according to claim 1, characterized in that the oxidized tellurium products are cyanidated, Gold and silver extracted and the tellurium extracted from the cyanidation residue. 3. The method according to claim 1 or 2, characterized in that the oxidized products are treated with sodium sulfide, to solve the tellurium products. 4. The method according to any one of the preceding claims, characterized in that the product with basic Hypochlorite solution oxidizes. 5. The method according to any one of the preceding claims, characterized in that the oxidized tellurium compounds dissolves from the cyanidation residue and tellurium precipitates out of solution with sodium sulfite. 6. The method according to claim 1, characterized in that the oxidized products are filtered, the filtrate reduced with sulfur dioxide or neutralized and precipitated, the precipitate dissolves in sodium sulfide and elemental tellurium precipitates with sodium sulfite. 6,99850 / 0706 7. The method according to claim 6, characterized in that moreover gold and silver by cyanidation extracted from the oxidation residue. 8. The method according to claim 6 or 7, characterized in that the concentrates with H ^ SO ^ / KCIO ^ or
HpSO./KMnO- oxidized. Process according to Claim 1, characterized in that the oxidized products are dissolved in order to dissolve the tellurium products Products with sodium hydroxide leaches the leaching liquid neutralized to precipitate telluric acid, which dissolves telluric acid in sodium sulfide and is elemental Tellurium precipitates with sodium sulfite. 10. The method according to claim 9, characterized in that the solids leached with sodium hydroxide cyanidated to produce gold and silver. 11. The method according to claim 9 or 10, characterized in that the products are in the oxidation stage with ferric chloride solution in combination with manganese dioxide oxidized. 609850/0706 • J. Read more