DE2603874B2 - METHOD OF REMOVING ARSENIC FROM A SOLUTION CONTAINING ARSENIC TOGETHER WITH COPPER - Google Patents

Description

The invention relates to a method for removing arsenic from an arsenic together with copper containing solution; in particular, it relates to a method for removing arsenic from copper electrolyte solutions or the like

The invention relates generally to a hydrometallurgical process in which arsenic is removed from a solution containing arsenic. Such solutions, which as a rule originate from large-scale processes for the production of copper, are usually obtained in a copper electrolysis process or in a process for purifying a copper electrolyte solution (hereinafter referred to as "copper electrolyte solution & ₅ and the like"), e.g. . B. a copper electrolyte solution, a solution obtained by concentrating the liquid effluent from the electrolysis of a copper electrolysis solution until the arsenic begins to precipitate (hereinafter referred to as "decuppered electrolyte solution") or a solution obtained during decuppering electrolysis of the above-mentioned solution until the beginning of the electrolytic deposition of arsenic . The invention particularly relates to a method for extracting arsenic using an organic solvent, in which the above-mentioned copper electrolyte solution and the like are brought into contact with an organic phase to convert the arsenic into the organic phase.

In ore materials used in non-ferrous metallurgy processed, especially in copper ores Contains some arsenic. Most of the arsenic found in copper refining is in the form of dust from smelting, for example in a direct smelting furnace, or in a copper production process, for example in a converter or refining furnace, recovered and recycled However, some of the arsenic accumulates in the sulfuric acid waste solution that comes from the gas scrubbing stage when collecting the sulfur dioxide is obtained. Another part of the arsenic enriches in a copper electrolyte solution and the like in a copper electrolysis stage. Hence that accumulates Arsenic accumulates within the copper refining system if it is not removed from the system.

In order to remove arsenic from a copper electrolyte solution and the like, a decoppering electrolysis has hitherto been carried out as a cleaning step in order to remove the arsenic in the form of an electrolytic sludge together with the copper. In copper-removing electrolysis, which is used to remove arsenic from a copper electrolyte solution and the like or from a solution that is carried out when an electrolyte solution containing arsenic is concentrated until the arsenic begins to precipitate (such a solution is hereinafter referred to as "copper-free electrolyte solution") , it is difficult to separate the arsenic from the copper, especially considering that the arsenic is generally in an earlier stage (e.g. in a converter or in a refining furnace) in the form of a sludge mixture of copper and arsenic for the further use of the copper is recycled. Such a process cannot be considered a basic process for removing arsenic. In addition, toxic gases such as arsine (AsH ₃ ) are formed in the later stages of the copper-removing electrolysis, and high costs are required to render the arsine harmless. At the same time, the current yield decreases, since the copper concentration drops. The process is therefore uneconomical or ineffective.

Another known method is to remove arsenic in the form of a sulphide Arsenic by adding hydrogen sulfide gas to a copper electrolyte solution or to a decoppering electrolyte solution is added for the purpose of cleaning, the conversion efficiency of the hydrogen sulfide is low and at the same time can coprecipitation of copper cannot be avoided. Therefore, an additional stage is required to remove copper and arsenic from a precipitate mixture separated from arsenic sulphide and copper sulphide.

The methods described above can be such as can be summarized as follows: if one assumes that the first stage is a copper

electrolysis, a copper electrolyte solution is used as the starting material the production of additional copper electrolyte solution is fed back into the cycle and the smaller portion is concentrated, whereby arsenic is eliminated by concentration and CuSO ₄ · nH ₂ 0 can be recovered with the formation of a decoppered electrolyte solution. The copper-removed electrolyte solution is usually subjected to a copper-removal electrolysis, which results in substantial proportions of Cu and a copper-removed solution with the formation of additional copper electrolyte solution.

On the other hand, in a smelting process, the raw copper is usually first introduced into a direct smelting furnace in the form of a sheet Copper receives the discharge; from the converter is transferred into a refining furnace, in which some of the Cu and other materials, such as. B. Zn, removed and returned to the direct smelting furnace in the circuit and waste products such. B. SO ₂ , can be removed by washing. The product of the refining furnace is formed into a semi-raw copper anode and subjected to copper electrolysis, with arsenic contained therein

It has now been found that by mixing a copper electrolyte solution and the like with a tributyl phosphate Bringing containing organic solvent phase into contact, the arsenic in the electrolyte solution Od. The like. Can extract selectively into the organic phase.

The invention therefore relates to a method for removing arsenic from a copper electrolyte solution and the like, which is characterized in that the copper electrolyte solution and the like are mixed with an organic solvent phase containing butyl phosphate brings in contact, in order to do this in this Extract solution containing arsenic into the organic solvent phase.

The invention relates generally to the removal of arsenic from a copper electrolyte solution and the like Use of a liquid-liquid extraction process instead of the conventional processes where Hydrogen sulphide gas is added or an electrolysis is carried out is carried out.

The copper electrolyte solution and the like treated by the method according to the invention generally contain at least copper ions, arsenic ions and sulfuric acid. On a typical industrial scale, the copper ions are present in an amount of more than about 30 g / l, the arsenic ions are: "ninnr Mgr>c> £ yr> n rncb.!" than about 1 g / l vorhsn'Jpi and the sulfuric acid (here and below in the meaning of H ₂ SO ₄ ) is present in an amount of more than about 150 g / l. Of course, other conventional components can also be present, e.g. B. nickel ions in an amount of more than about 1 g / i are usually found in Kxipfereiektrolytlösurigen and the like on an industrial scale sinq \ It is self-evident for the expert (let the copper electrolyte solutions used according to the invention and the like, such. the copper-plated electrolyte solutions and the copper-plated solutions are not particularly limited and that these solutions may have different compositions depending on the exact commercial reaction scheme that occurs, but as with any invention which is in the field of large-scale process It is possible to indicate certain solutions that are usually, but not exclusively, found in this field and these are explained in more detail below in order to facilitate the general understanding of the present invention for those skilled in the art; however, the following description of various solutions is by no means intended Limitation of the invention to this L to understand solutions.

A common copper electrolyte solution contains about 30 to about 60 g / l Cu, about 150 to about 250 g / l H ₂ SO ₄ , about 1 to about 7 g / l As and usually smaller amounts of Sb (on the order of about 0.1 to about 0.7 g / l) and Ni in an amount of about 1 to about 20 g / l. Typical decoppered electrolyte solutions resulting therefrom contain Cu in an amount of about 15 to about 30 g / L, H ₂ SO ₄ in an amount of about 200 to about 350 g / L, and As in an amount of about 3 to about 10 g / l, with Sb being usually present in an amount from about 0.2 to about 1.0 g / l and Ni in an amount from about 1 to about 30 g / l. .

On the other hand, a copper-removed solution obtained from the copper-removing electrolysis of such a copper-removed electrolyte solution usually contains about 0.01 to about 5 g / l copper, about 270 to about 600 g / l H ₂ SO ₄ and about 3 to about 10 g / L As, with Sb and Ni usually being present in amounts on the order of from about 0.2 to about 1.0 g / L and from about 1 to about 30 g / L, respectively. The tributyl phosphate (hereinafter abbreviated to TBP) used as an extractant according to the invention has the structure [CH ₁ (CH ₂ ) JO] ₃ P = O. TBP is usually used in a suitable organic solvent, since it has a specific gravity that is in is close to that of water and has a high viscosity. The organic solvent, which acts essentially as a diluent, can for example be a hydrocarbon, in particular kerosene (a C ^ -C ^ paraffin). The degree of dilution is arbitrary, but in general the TBP is diluted so that it is contained in the finished organic phase in an amount of about 50 to about 75% by volume. If TBP se is diluted so that the finished organic phase contains a larger amount of TBP, the specific gravity and the viscosity of the organic phase ar increase and, after contact with the aqueous phase, the organic phase and the aqueous phase tend to form an emulsion . If the dilution leads to the fact that the finished organic phase contains too little TBP, that is to say substantially less than about 50% by volume, the phase separation is / was good;

However, the extracted arsenic decreases and the efficiency becomes low.

Sometimes a good phase separation is obtained by adding a higher alcohol, such as 2-ethyl-hexanol, Dodecyl alcohol and the like, to the organic phase in an amount of about 5% by volume or less. The higher alcohol has the effect of separating the organic phase into two phases, which is common occurs when the arsenic concentration in the -organic Phase increases, to prevent and to ensure an extraction with a good efficiency.

Contacting the organic phase with the aqueous solution phase is conventional carried out, most expediently simply by that the two phases are mixed together with stirring.If ideal mixing is carried out, a contact time of 5 to 10 seconds is sufficient, with the usual working method the contact time is but preferably about 30 seconds.

There is no particular limitation on the temperature of the extraction system that arsenic becomes however, more easily extracted into the organic phase when the temperature is lower, therefore the temperature e.g. B. preferably about 10 to about 20 c.

The volume ratio between the organic phase and the aqueous phase (hereinafter referred to as “O / A ratio”) at the time of contact is not subject to any particular limitation. The arsenic content of the aqueous phase with the extraction however, it decreases with increasing O / A ratios. Based on the explanations above it is easy for a person skilled in the art to find the optimal O / A ratios for the respective processing stage sequence to determine. As a general rule, an O / A ratio on the order of about 1: 1 from the standpoint of carrying out the process on a large scale, generally on is most preferred

If an organic phase containing TBP is used, the arsenic can be obtained from a copper electrolyte solution or the like are extracted without being influenced (disrupted) by other metal elements contained therein, such as Sb, Cu, Ni and the like. However, the sulfuric acid concentration of the aqueous phase has an influence the arsenic concentration, and the extraction results will be better if the sulfuric acid concentration increases, for example to about 300 to about 400 g / l. The organic containing TBP However, phase extracted to a certain extent sulfuric acid, and when the sulfuric acid concentration of the treated aqueous phase increases, the amount of extracted sulfuric acid also increases greater.

The large-scale implementation of the extraction process according to the invention can be carried out using a discontinuous (batch) extraction or a continuous extraction, z. B. in the form of a countercurrent extraction in several. Stages, are carried out, the optimal number of stages is determined according to conventional chemotechnical processes. In order to extract the arsenic with a good efficiency, the countercurrent extraction is in several ways Most Preferred Steps The extraction device may be among those known in the art commonly used such as B. a mixer-settling device, a rotating disk contactor, an impulse device (a pulse device) or a centrifuge extractor, to be chosen freely.

If desired, stripping can be carried out to remove the arsenic from the organic phase will. The aqueous phase that can be used for this stripping can, for example, be an alkaline one Solution, such as an aqueous solution of sodium hydroxide, an aqueous solution of sodium carbonate or an aqueous ammonia solution, be best however, water is suitable because it is easily accessible if one has such an aqueous phase with the Brings arsenic-containing organic phase into contact, it is possible to remove the arsenic (by stripping) to be transferred into the aqueous phase. During stripping, the organic phase is regenerated and it can be used in Circulation can be returned to the extraction stage. The large-scale implementation is in the Typically performed using an alkali solution in an amount equal to about 1.2 to about 1.5 times the equivalent of the arsenic present and the sulfuric acid present (molar equivalents; Moles of alkali per mole of arsenic and sulfuric acid) corresponds, however, to the invention in no way limited

The optimal contact ratio of the organic Phase with the aqueous phase in the stripping procedure given above is using the conventional chemotechnical principles established; on an industrial scale the contacting ratio is generally about 3: 1 to about 10: 1 with particularly good results can be obtained when the contact ratio is about 5: 1. The stripping time depends primarily Line from the total volumes of the aqueous phase and the organic phase and their concentrations away; on an industrial scale using systems such as are commonly used, however, stripping can be successful for about 30 seconds at a temperature of about 20 to about 30 ° C be performed.

The arsenic can be obtained in a simple manner from the aqueous solution after stripping Reduce, d. H. by introducing sulfur dioxide into the aqueous solution, before or after the concentration the aqueous solution to crystallize the arsenic as arsenic trioxide. To increase the yield (Recovery rate) of arsenic trioxide, sulfur dioxide is preferably introduced into the aqueous solution thereby reducing the arsenic in the aqueous solution to the trivalent state. The optimal one The ratio of sulfur dioxide to the aqueous solution can be made using conventional chemotechnical Principles are laid down, but in general the sulfur dioxide is in one such amount introduced into the aqueous solution as about 2 to about 10 times the equivalent of Arsenic in the solution (molar equivalents) corresponds to for a period of about 10 to about 30 minutes under a pressure slightly above atmospheric pressure. The temperature will be in any Wise chosen and the temperature is usually the own temperature of the aqueous solution, as obtained from the previous process stage.

After the above-described process of this invention can arsenic from copper electrolyte solution and. The like. Are removed and the resulting

removed arsenic can be obtained, for example, in the form of arsenic trioxide.

Another method for recovering (separating) the arsenic from the aqueous solution after Stripping consists in adding a sulphidating agent, such as hydrogen sulfide, sodium sulfide or sodium hydrogen sulfide, to the system arsenic trisulfide to fail.

The main object of the present invention is to remove arsenic from a copper electrolyte solution or the like. to be extracted by means of TBP with a high degree of efficiency. The procedure according to the invention can also be applied to other aqueous sulfuric acid solutions containing arsenic. if however, the arsenic acid is contained therein in the trivalent state, e.g. B. in the case of a sulfuric acid waste solution in a gas scrubbing process of a sulfuric acid plant, the one achievable according to the invention takes Extraction efficiency was found to decrease. A copper electrolyte solution or the like is characterized by that they contain the arsenic in an amount of about 50% by weight or more in a higher valence state than in the trivalent state, i.e. H. in the pentavalent state

Since no hydrogen sulfide gas is used in the process of the invention, none occur Pollution and no bad smells. Since the result of the extraction of arsenic is better, if the sulfuric acid concentration is higher, the arsenic can be extracted with good efficiency even from a Copper electrolyte solution, a solution before copper removal electrolysis, or a solution that has been subjected to electrolysis of copper, all of them have a high sulfuric acid concentration of, for example, about 320 to about 390 g / l, removed will.

When the method of the present invention is applied to a copper electrolyte solution and the like, extracted the organic phase containing TBP selectively arsenic and some sulfuric acid, but it extracts

Table I.

not copper, nickel, antimony, chlorine and the like, which are contained in the copper electrolyte solution in a similar amount are. Therefore it is possible to remove arsenic from the other elements, especially from arsenic Copper, to separate. Therefore, no arsenic-copper separation step is required.

While conventional copper removal electrolysis produces toxic gases, the present invention significantly improves the working environment. This is a major benefit in the practical implementation of the procedure.

The invention is illustrated in more detail by the following examples, without, however, being restricted thereto. All examples described below were made at atmospheric pressure unless otherwise specified and carried out at normal fluff temperature. It should be noted in particular that the operating pressure for the present invention is not important and that usually atmospheric pressure is applied. But one can also use underpressure or overpressure, albeit in the sense of Effectiveness of the process obtained no benefit by moving to such more complicated systems will.

example 1

In this example! the arsenic was made from a copper electrolyte solution, obtained from a copper electrolysis system and from a decoppering electrolyte solution extracted in a discontinuous (batchwise) way

100 ecm each of these solutions and 100 ecm one Kerosene TBP phase containing 50% by volume of TBP, were placed in a separatory funnel using a shaker for 5 minutes at room temperature shaken and then left to stand, the mixture separating into two phases. the Concentrations of the components in the aqueous phase were analyzed and those obtained thereby Results are given in Table I below.

Components

Analysis of the aqueous phase (g / l)

As Sb Cu

H ₂ SO ₄

At the start

Copper electrolyte solution 5.18

(before extraction)

At the end

Copper electrolyte solution 4.53

(after extraction)

At the start

Solution before the copper removal electrolysis 8,10

(before extraction)

At the end

Solution before the copper removal electrolysis 5.24

(after extraction)

0.52

46.8

0.72

0.72

26.3

26.3

215

348

348

329

Example 2

4.091 of a solution which had been prepared by cooling a copper electrolyte solution from a copper electrolysis system to room temperature and then filtering it to remove the precipitated Sb ₂ O ₅ , Sb ₂ O ₃ - As ₂ O ₅ (aqueous

709 524/463

Phase), and 9.64 l kerosene containing 50% by volume of TBP and 5% by weight of 2-ethylhexanol (organic phase),

produced and subjected to continuous overextraction.

The device used for the extraction was a rotating disk contactor with an inner diameter of 50 mm, a column length of 600 mm, the 22 partition walls and rotating disks included. The flow rate of the organic phase was 121 ecm / Min. And the flow rate of the filtered docking electrolyte solution was 51 ccm / min. The extraction was performed for 80 minutes at room temperature, with the disks at a speed were rotated at about 500 rpm.

In addition, continuous stripping was carried out using 9.66 liters of the organic Phase into which the arsenic had been extracted and 8.28 l of water. It became the same Rotary disk contactor as used above to perform stripping. The flow rate the organic phase was 60 ccm / min. and the flow rate of the aqueous phase was 52 cc / min. The stripping was performed for 160 minutes at room temperature, with the disks at a speed were rotated at 400 rpm.

The results obtained in these experiments are given in Table II below.

Table II Example 3

Copper electrolyte solution
before extraction

Organic solvent before extraction Continuous extraction was carried out using 5.0 L of copper electrolyte solution from a copper electrolysis system « obtained before decoppering wa (aqueous phase), and using 11.2 Kerosene containing 50% by volume of TBP and 5% by volume of 2-ethylhexanol (organic phase). It became the the same device as used in Example 2 for the extraction. The flow velocity dei organic phase was 112 ccm / min. and the flow rate the aqueous phase was 50 ccm / min. The extraction was carried out for 100 minutes at room temperature with the disks rotated at a speed of about 500 rpm.

Using 11.5 l of the organic phase, into which arsenic had been extracted and using continuous stripping was carried out from 10.9 l of water. It became the same device as used for performing the stripping in Example 2. The flow rate of the organic phase was 58 cc / min., and the flow rate of the aqueous phase was ^> ccm / min. The extraction was carried out for 200 minutes carried out at room temperature while the wafers at a speed of about 400 rpm were shot. The results obtained are given in Table III below.

Table III

4.09 1

Cu 46.8 g / l
H ₂ SO ^ 236 g / l (965 g)
As 4.72 g / l (19.3 g)
Sb 0.52 g / l

extraction

9.64

35 copper electrolyte solution
before extraction

Organic solvent before extraction

Solution after the
extraction

Organic solvent
after extraction 5.0 1

Cu 26.8 g / l
H ₂ SO ₄ 348 g / l
^As 7.8 g / l (39.0 g)
Sb 0.72 g / l
extraction

11.2 1

45 solution after the
extraction

4.07 1

Cu 46.9 g / l
H ₂ SO ₄ 223 g / l (908 g)
As 2.18 g / l (8.9 g)
Sb 0.52 g / l

Stripping
Water 8.28 1

9.66 1

Cu traces
H ₂ SO ₄ 5.9 g / l (57 g)
As 1.08 g / l (10.4 g)
Sb traces of organic solvents after extraction

Water (aqueous phase) after stripping

Organic solvent after stripping 4.7 1

Cu 28.1 g / l
H ₂ SO ₄ 325 g / l
As 0.55 g / l (2.59 g)
Sb 0.75 g / l

Stripping
Water 10.9 1

Water (aqueous phase) after stripping

55 11.5 1

Cu traces H ₂ SO ₄ 16 g / I As 3.17 g / l (36.4 ig) Sb traces

Organic solvent after stripping

8.301

Cu traces
H ₂ SO ₄ 6.9 g / l (57 g)
As 1.25 g / I (10.4 g)
Sb traces

9,641

Cu traces
H ₂ SO ₄ <0.01 g / l
As <30.01 g / l
Sb lanes 11.21

Cu traces
H ₂ SO ₄ 16.4 g / l
As 3.25 g / l (36.41 g)
Sb traces

11.2 1

Cu traces H ₂ SO ₄ <0.01 g / l As <ö.01 g / l Sb traces

2 (5 03

1 l of the extract obtained during stripping was heated to boiling and concentrated to 107 ecm. Thereafter the concentrated extract was cooled to room temperature for about 15 minutes for about 8 liters Sulfur dioxide were introduced, with 2.5 g of arsenic trioxide crystals crystallized out. The crystals contained after washing with water 75.6% As.

Claims (10)

Patent claims: 1. Procedure for removing arsenic from a solution containing arsenic together with copper, see chap characterized in that: that the solution with a tributyl phosphate containing brings organic phase into contact and thereby the arsenic contained in this solution into the organic Phase extracted 2. The method according to claim 1, characterized in that the organic phase with your into this, extracted ep ν'Arsen, then with Water or an "aqueous alkaline solution" brings the arsenic into contact with the aqueous Transfer phase. 3. The method according to claim 1 and / or 2, characterized in that the organic phase used as the extractant is about 50 to contains about 75% by volume of tributyl phosphate 4. The method according to at least one of claims 1 to 3, characterized in that the The organic phase used as the extractant also contains a higher alcohol 5. The method according to claim 4, characterized in that that the organic phase contains 2-ethylhexanol or dodecyl alcohol as the higher alcohol 6. The method according to claim 2, characterized in that that the aqueous phase is concentrated to obtain the arsenic 7. The method according to claim 6, characterized in that before or after the concentration the aqueous phase introduces sulfurous acid gas into the water or into the aqueous alkaline solution 8. The method according to claim 2, characterized in that the aqueous phase after Stripping a sulfiding agent adds to the precipitation of arsenic in the form of arsenic sulfide. 9. The method according to claim 8, characterized in that the sulfiding agent used is hydrogen sulfide, Sodium sulfide or sodium hydrogen sulfide is used 10. The method according to at least one of claims 2 to 9, characterized in that one an aqueous sodium hydroxide, sodium carbonate or ammonia solution as the aqueous alkaline solution used