FR2556370A1 - Process for the recovery of silver, especially from the residues from leaching of zinc ores - Google Patents

Abstract

Recovery of silver from ore residues. The invention relates to a process according to which, during the operation of leaching of zinc sulphide ores, chemical zinc sulphide is added in order that the silver salts should preferably be bound to this zinc sulphide. The latter is then separated by flotation of the zinc-poor residue. In this way, the flotation froth is rich in silver, which can be easily recovered. Application to the treatment of the residues from the leaching of zinc sulphide ores.

Description

 The present invention relates to the recovery of silver, in particular leaching residues of zinc ores, formed for example during a process for extracting zinc electrolytically.

 We know that silver is present in many ores, but generally in small quantities. However, about three-quarters of the money produced comes from the recovery of silver during the metallurgy of different metals that are essentially lead, copper and zinc. For example, in an electrolytic zinc extraction process, the ores are leached so that the zinc goes into solution and forms a crude solution of zinc sulphate as well as a zinc-poor residue. The silver dissolves as well and the silver sulphate passes into the crude solution which has to be purified. It is at this stage that the money is generally recovered.

 Very often, the zinc-poor residue formed during leaching of zinc ore is not mined, although it contains elements such as lead, silver, iron, copper, and so on. So we have already tried to recover these elements including the money from this residue. For example, methods are known in which the residue undergoes a hot acid attack and the silver is selectively separated during complex operations.

 The invention allows the recovery of silver by a very simple operation, and it is based on the discovery that, when silver compounds are present in solution, for example during the leaching of sulphide ores. In the case of zinc, these compounds tend to bind to the zinc sulphide present in the solid state, this zinc sulphide being either of the initially or newly formed blende or of the intentionally added zinc sulphide.

 Thus, the invention relates to a process which allows the recovery of silver by separation of zinc sulfide, since the silver compounds are attached to this compound. The process applies both to specially prepared materials, i.e. in which zinc sulphide has been intentionally added, and to materials in which zinc sulphide already present has naturally been a carrier for fixing silver compounds.

More specifically, the invention relates to a method for recovering silver by separating a silver-rich fraction, comprising
contacting a liquid phase containing dissolved silver compounds with zinc sulphide particles under conditions which favor the binding of the silver compounds to the sulphide particles of zinc, and
- the separation of silver-enriched zinc sulphide.

 In a particularly important case from an economic point of view, the contacting operation is simultaneous with the operation of dissolving the zinc sulphide ores of an electrolytic zinc extraction process. The zinc sulphide particles may be blende present in the ore or neoformed during leaching. The zinc particles may also be particles of chemical zinc sulphide or blende intentionally added during leaching of sulphide ores of zinc. This chemical zinc sulfide or blende is preferably activated by milling to a small particle size.

 The conditions which favor the fixing of the silver compounds preferably comprise a heating at a temperature higher than 50 ° C.

 It is desirable that the separation of the silver-enriched zinc sulphide comprises, after the separation of the solid phase and the liquid phase, the fractionation of the solid phase by flotation. Such a flotation advantageously comprises grinding preferably at a particle size of less than 100 microns and advantageously of about 40 microns.

 Flotation advantageously involves the activation of the blende by initial addition of lime and then by addition of copper sulphate.

 It is also desirable that the flotation comprises a rough flotation and at least one rewashing.

Rough flotation advantageously has a duration of the order of 30 minutes and the restoring a duration of the order of 15 minutes.

 Thus, the invention implements only a very simple operation. Indeed, the possible addition of zinc sulphide, when zinc sulphide of suitable quality is not present, is carried out without any particular additional treatment. Only an additional flotation operation is necessary compared to conventional operations carried out during electrolytic zinc extraction. This flotation is carried out under the specific conditions of the separation of blende and is therefore well known to those skilled in the art.

 Other characteristics and advantages of the invention will emerge more clearly from the following detailed description of an embodiment of the invention applied to the zinc extraction electrolytically.

Although the invention is described with reference to this example, the silver enrichment process can be applied to the treatment of other ores and solutions.

 During the zinc extraction electrolytically, the zinc sulphide ores, suitably roasted, are first subjected to dissolution to solubilize the largest possible amount of zinc, while curbing the dissolution of impurities. This dissolution in solution is carried out in two stages. In the first stage, sulfuric acid, recovered in the zinc sulfate electrolysis tanks, acts on an excess of roasted ore. It is already known to add manganese dioxide and iron sulfate in the reaction medium so that iron, arsenic, antimony and germanium preferentially precipitate and spend as little as possible in solution. At this point, a lot of the money is in solution. This first leaching dissolves only a part of the zinc. As a result, its residue, after decantation, is subjected to a more vigorous leaching which dissolves most of the remaining zinc. The formed solution then contains a large number of impurities including silver, and is returned to the first leaching so that a large part of the impurities is removed.

 It is therefore at this stage, ie in the first leaching or neutral leaching, that it is desirable for activated zinc sulphide particles to be present so that the silver compounds preferentially settle thereon. .

 Thus, since only a part of the ore is attacked during the first leaching, only a portion of the zinc sulphide reacts and so there remains a significant amount of zinc sulphide on which the silver compounds can bind and concentrate. However, the zinc sulphide present in the initial ore in the medium has an activity which is limited, and it is therefore desirable that added active zinc sulphide or neoform present in the reaction medium. Such active zinc sulfide may be formed by chemical zinc sulfide or finely ground blende. The amount of zinc sulphide or blende added is preferably such that the amount of zinc added is between 2 and 10 times the amount of silver present in the reaction medium.

In general, the amount of silver present in the reaction medium is of the order of one hundred grams per tonne. The quantity of zinc sulphide to be added is therefore of the order of 3 to 15 times 1, a quantity of silver weighing 300 to 1500 grammes per ton.

 The conditions which favor the fixation of the silver compounds on the zinc sulphide particles are a relatively high temperature, preferably greater than 500C, and a large surface area of the zinc sulphide. It is therefore desirable that it, whether chemical or in the form of blende, is activated by extensive grinding.

 The leaching residue thus obtained thus contains the silver compounds preferably fixed on zinc sulphide. The mineralogical study of this residue indicates that zinc sulphide is essentially present as a residual, from the ore, containing only little silver, in the form of zinc sulphide added and containing a significant amount of silver and in the form of of zinc sulphide neoformed also containing a significant amount of silver.

 The zinc-poor residue is normally separated by decantation from the solution which, after purification, is electrolyzed. According to the invention the separation comprises, after the settling, a flotation. Since the silver compounds are attached to zinc sulphide, the latter is the object of the separation by flotation.

Consequently, the conditions of flotation are those used for the enrichment of the blende.

 This flotation is well known to specialists.

Thus, the residue is advantageously initially subjected to grinding, preferably to a size less than 100 microns and advantageously of the order of 40 microns.

Blende is activated by the addition of lime and copper sulphate so that it floats. The foam is collected and transmitted to a thickener. The collected pulp is then transmitted for example to a rotary filter.

EXAMPLE
The silver-enriched zinc sulphide is separated from a zinc-poor sample called "ferrite" because it contains a lot of iron. This residue contains 100 g / t silver, 19.6% zinc, 26.7% iron, 80 g / t germanium, and 255 g / t indium.

The processing of the residue includes the following operations
grinding the residue to a particle size of 40 microns,
conditioning at 16% solids for 19 minutes, with addition of lime, the pH obtained being equal to 12,
second conditioning of 10 minutes with addition of copper sulphate at a rate of approximately 800 g / t,
- rough flotation for 30 minutes,
- two lettings, with a flotation time of 15 minutes each.

The results obtained are shown in the following table.

Contents
<tb> Recovery <SEP>%
<tb> g / t <SEP>%
<tb> Product <SEP>% <SEP> P
<tb> Ag <SEP> Zn <SEP> Fe <SEP> Ag <SEP> Zn <SEP> Fe
<tb> Concentrate <SEP> 8.35 <SEP> 1037 <SEP> 33 <SEP> 16.4 <SEP> 72.8 <SEP> @ <SEP> 14.1 <SEP> 5.1
<tb> Rejection <SEP> 91.65 <SEP> 35.3 <SEP> 18.4 <SEP> 27.7 <SEP> 27.2 <SEP> @ <SEP> 85.9 <SEP> 94.9
<tb> Food <SEP> 100 <SEP> 119 <SEP> 19.6 <SEP> 26.7 <SEP> 100 <SEP> @ <SEP> @ <SEP> 100 <SEP> 100
<Tb>

 These results indicate a significant recovery of silver, with significant concentration. In addition, the zinc is enriched but the recovery is low @ar the float phase @ is not important.

 The method according to the invention therefore requires, compared to the conventional method of electrolytic zinc extraction, only additional flotation and this operation is simple and not very telling. The process is therefore much more interesting than the known processes for treating these residues, which generally comprise hot acid etching before separation by flotation.

Given the low content and the large volume of the residue, such hot acid attack is very storytelling not only in chemicals but especially in thermal energy
Although the invention has been described with reference to the recovery of silver from the zinc-poor residue formed by the leaching of zinc sulphide ores, it applies to other processes in which the silver may be found. the state of a solution. The addition of zinc sulphide, which is an inexpensive product, allows the separation of silver by a simple operation, requiring only basic equipment and can be practically implemented in any metallurgical plant.

Claims (10)

A method for recovering silver from solutions containing dissolved silver compounds, by separating a silver-rich fraction, characterized in that it comprises  contacting a liquid phase containing dissolved silver compounds with zinc sulphide particles under conditions which favor the binding of the silver compounds to the sulphide particles of zinc and then  - the separation of silver-enriched zinc sulphide. 2. Method according to claim 1, characterized in that the contacting of the liquid phase and the zinc sulphide particles is carried out in an operation for dissolving zinc sulphide ores during a process. zinc extraction electrolytically. 3. Method according to one of claims 1 and 2, characterized in that zinc sulfide particles in contact with which is put the liquid phase comprise blende particles already present or neoformed. 4. Method according to any one of claims 1 to 3, characterized in that zinc sulphide particles are added in the form of chemical zinc sulphide or activated blende. 5. Method according to any one of the preceding claims, characterized in that the contacting conditions which promote the fixing of the silver compounds on the zinc sulphide particles comprise the use of a temperature greater than or equal to at 500C. 6. Process according to any one of the preceding claims, characterized in that the separation of the silver-enriched zinc sulphide comprises the separation of the solid phase, and then the flotation thereof. 7. Method according to claim 6, characterized in that the flotation is performed under the conditions normally used for the separation of the zinc ore blende.  8. Process according to claims 2 and 7 taken together, characterized in that it comprises, before flotation, grinding so that the material has a particle size less than 100 microns. 9. Method according to one of claims 7 and 8, characterized in that it comprises, before flotation, the activation of the blende by adding lime and then adding copper sulfate. 10. Method according to any one of claims 7 to 10, characterized in that the flotation comprises a rough flotation and at least one rewash.