DD226547B1 - METHOD FOR RECOVERING COMPLEX-LINKED SILVERIONS, OF GROUNDED, WAFER, CYANIDOUS SOLUTIONS - Google Patents

Description

Field of application of the invention

The invention is applicable to electroplating and relates to the recovery of complex bonded silver ions from cyanide silver electrolytes which have a low silver concentration and, in contrast, have an excess of free alkali metal cyanide.

Characteristic of the known technical solutions

It is known that heavy metal complexes which are present as anion in the treatment solution can be bound to anion exchangers.

Particularly large capacities have strong base anion exchangers z. B. trimethylammonium groups. However, they have the disadvantage that the bound complexes, e.g. those of silver, can only be badly removed from the exchanger. It is sometimes more economical to incinerate the exchanger and recover the metal content from the combustion residues than to achieve desorption by chemical treatment. The chemicals used for desorption also partially damage the functional groups of the exchanger, which greatly reduces capacity and service life. The use of weakly basic or moderate strong anion exchangers has proved to be more favorable. They are easily regenerated by means of dilute sodium hydroxide solution and thereby easily release the bound heavy metal complexes. A corresponding method is known from DE-OS 2602441. However, this process has the disadvantage that the weakly basic or moderate-strong anion exchangers used make the process uneconomical. The heavy metals which enter the solution to be treated as an impurity accumulate in the electrolyte as a result of the direct recirculation in this process and spoil it in a short time, which means that the use of the process should only be possible for a short time. The claim that according to DE-OS 2,602,441 existing cyanides can be completely removed from the solutions to be treated, can not be fully followed, since the excess of free alkali metal azides is not bound by the proposed anion exchanger.

Furthermore, a method is known, after which silver is recovered from solutions of the film development institutions. Thus, according to DE-OS 2836160 a process for the recovery of silver in the range of 0.04 to 100mg / l metal content from solutions of anionic silver thiosulfate complexes is known, being used by this method strong base anion exchanger polystyrene-based with quaternary ammonium groups, which are in the chloride form. The regeneration is carried out with an alkaline 5 molar ammonium chloride solution of pH 8.5. It is also described here that a used solution enriched with thiosulfate has an approximately 25% greater efficiency in the regeneration, as an unused thiosulfatfreie solution, an explanation of which could not be found yet.

The used regeneration solution (5 molar ammonium chloride solution) is an almost saturated solution. To be able to use the treated filter again for wastewater treatment, therefore, a large amount of flushing water is required. On the other hand, the high concentration must be restored by adding salts in the used regeneration solution to compensate for the dilution effect of residual water in the exchangeable containers before regeneration and rinsing water after regeneration.

Object of the invention

The aim of the invention is to provide a more economical and environmentally friendly process for the recovery of complexed silver ions from dilute, aqueous, cyanide-containing solutions.

Explanation of the essence of the invention

The invention has for its object to provide a process for the recovery of complexed silver ions from dilute, aqueous, cyanide-containing solutions by ion exchange, which in a simple way by means Alkalkhydroxidlösung without the use of special additives and the recovery of silver from electroplating baths is possible in which the concentration is below 0.05 mg / l.

According to the invention the object is now achieved in that the dilute aqueous solution is passed in a closed circuit over a strongly acidic cation exchanger with sulfonic acid groups as a filling, a weakly basic anion exchanger with tertiary dimethylamino groups in hydroxide form as a filling and a strong base anion exchanger with quaternary trimethylammonium groups in hydroxide form as filling wherein until the full charge state of one of the ion exchangers, the silver complexes and free complexing agents are gradually bound to the weakly basic and strong base anion exchanger, after which regeneration of the anion exchangers by treatment with a 1 to 6 molar alkali hydroxide solution, associated with a release of the complex silver cyanides occurs and thereafter a per se known electrolytic deposition of the silver from the regeneration solution is performed.

In a further embodiment of the invention it is provided that the strongly acidic cation exchanger is additionally presented a weakly basic anion exchanger. In this case, complex-bonded cyanide anions can be bound already before the cation exchanger stage in order to ensure that any possible action of the cation exchanger on certain complexes is excluded.

In the context of the invention, it is provided that the dilute, aqueous bath solution to be treated contains an excess of complexing agents.

embodiment

The invention will be explained in more detail below by exemplary embodiments.

In the galvanic silvering of contact parts of the electrotechnical industry or of jewelry, a cyanide silver electrolyte was used in the invention, which had an excess of free alkali metal cyanide. The silver was present in the electrolyte as Na [Ag (CH) ₂ ]. By rinsing processes previously reached this silver complex together with the Alkalizyanidüberschuß in the wastewater, from which the silver should now be recovered as completely as possible. The wastewater was also treated so that it can be used again for the rinsing process. The concentration of silver ions in the effluent to be treated may vary between less than 0.05 mg / l and greater than 100 mg / l.

In the context of the invention now this silver-containing wastewater is passed through three successive ion exchangers, the first stage a strongly acidic cation exchanger with sulfonic acid groups as filling, the second stage a weakly basic anion exchanger with tertiary dimethylamino groups in the hydroxide as a filling and the third stage a strongly basic anion exchanger contains quaternary trimethylammonium groups in the hydroxide form as a filling. The flow rate is about 3 to 5m ³ / h with a filter diameter of 400mm. Before the first stage, this creates a pressure of about 1 kp / cm ² . The wastewater is now passed through the exchanger until cyanide levels of 0.05 mg / l occur at the end of the strongly basic anion exchanger. The content of silver cyanides is partially precipitated on the strongly acidic cation exchanger temporarily by removal of Na ⁺ ions. There is a deposition of AgCN with the release of hydrogen cyanide (HCN), which is bound to the strongly basic anion exchanger. Likewise, the content of excess alkali ynamide is split. The released hydrocyanic acid (HCN) is also bound to the strongly basic anion exchanger. The AgCN region on the strongly acidic cation exchanger migrates to nations as the loading of the exchange column progresses, along with the loading front. For the most part, the AgCN is present in a freely distributed form, so that it is mechanically filtered only in the following weakly basic anion exchange stage. There is a partially bond and occurs [Ag (CN) _2]. "- lon the silver but is mostly deposited as AgCN In the prevailing acidic environment by the simultaneous presence of copper in the wastewater part of the complexing agent (NaCN) is bound. The macroporous structure of the weakly basic anion exchanger favors good uptake of the precipitated, finely divided AgCN.

The strong base anion exchange stage predominantly reaches hydrocyanic acid (HCN) and other very weak acids. The anions are preferably bound in the upper region of the exchange column. At high loading rates, however, they disperse over a rather wide range of available exchange volume with greatly decreasing concentration, which must be taken into account during regeneration. After, as already mentioned, cyanide contents of about 0.05 mg / l occur at the outlet of the strongly basic anion exchanger, the anion exchanger stages in the sequence of strongly basic anion exchanger - weakly basic anion exchanger with sodium hydroxide solution of a concentration of 100g / l and a quantity of 60 to 300g / l ion exchanger volume (based on the strongly basic anion exchanger) regenerated. The flow rate is less than 2 m / h based on the free cross section of the exchange column. In this case, the existing loading water remains in the container above the exchanger bed of the strongly basic anion exchanger. As a result, a concentration gradient of the regeneration solution is produced, which causes a sharp delimitation of the elution fronts of the bound or filtered-off substances.

During regeneration, the bound hydrocyanic acid (HCN) is liberated from the strongly basic anion exchanger and combines with the regenerant to form NaCN. The strongly basic anion exchanger is thereby converted into the OH form. Due to the high concentration of the sodium hydroxide solution as a regenerating agent, the hydrolysis of the sodium cyanide, which normally takes place at low concentrations, takes place

Na ⁺ + CN "+ H ₂ O ^ HCN + Na ⁺ + OH" (1)

effectively prevented. The hydrocyanic acid is therefore present as an effective CN ~ ion, which causes the regeneration effect for bound silver complexes. In the strongly basic anion exchanger, the AgCN bound by precipitation is then dissolved, and the genuinely bound Ag [CN (CN) ₂ ] ion is detached from the ion exchanger.

AgCN + Na ⁺ + CN "- * Na [Ag (CN) ₂ ] (2)

R - Ag (CN) ₂ + Na ⁺ + OH "-» Na [Ag (CN) ₂ ] + R-OH (3)

(R here denotes the functional group of the ion exchanger)

The resulting Na [Ag (CN) ₂ ] is dissolved in the existing excess of NaCN and removed from the exchange bed.

After the regenerant has passed through the strong base anion exchanger, it is passed into the weakly basic anion exchanger where it releases the largely mechanically filtered AgCN (2). The genuinely bound portion of [Ag (CN) ₂ ] "ions is also dissolved (3) due to the better regenerability of the weakly basic anion exchangers, the exchanger being converted back into the OH form previously passed through the strong base anion exchanger, now contains the charged during loading anionic silver complexes in a form which allows an electrolytic recovery of the metal in a known manner.The solution remaining after the metal recovery solution can be used after correction of the alkali concentration for further regeneration, the high cyanide content of the solution, which remains after the demetallization, has a favorable effect and thus a considerable saving of chemicals in the regeneration is recorded.

With the beginning of the regeneration, the conductivity is measured in the running regeneration solution. After a first increase in conductivity from 1 ^ s cm " ¹ to about 100 ^ s cm" ¹ , the fractions are collected for silver recovery. Up to a conductivity of about 1000 Ω · cm · ¹ , the majority of the silver content has left the exchangers and the silver content of this solution, which, as already mentioned above, is subjected to electrolytic deposition, is 2 to 5 g / l or more.

Thereafter, the conductivity of the regeneration solution increases sharply and a high regenerant excess is present. This solution is collected for re-regeneration and the amount of regenerant consumed is added. Since this solution is used for a renewed regeneration, the silver content that it possesses (still about 0.1 to 1 g / l) is not lost.

As soon as the conductivity drops sharply and falls below 1 000 / xS cm ^-1 , the solution is no longer collected, as it no longer contains usable concentrations of silver and regenerant.

This is followed by rinsing with cation-free water until the conductivity has returned to the desired value in the pure water.

The strongly acidic cation exchanger is regenerated in a known manner with dilute mineral acid.

It is also possible to include the cation exchanger in the regeneration process of the anion exchanger. For this purpose, it is neutralized with solutions in which no complexing agents are contained (excess of nations) and the anion exchangers during their regeneration. The filtered silver compounds, such as. B.

AgCN also removed from the cation exchanger.

According to a further embodiment of the invention, the circuit of the ion exchanger can be carried out so that the strong acid cation exchanger is preceded by an additional weakly basic anion exchanger, wherein the strongly acidic cation exchanger is present in the neutral Sulfatfqrm. In this case, the advantage arises that complexed cyanide anions are already bound before the cation exchanger stage. A possible effect of the cation exchanger on certain complexes is thus excluded. The regeneration takes place here as already stated above. Thereafter, the sulphate form is to be restored by means of H ₂ SO 4.

Claims (3)

claims: 1. A process for the recovery of complexed silver ions, from dilute, aqueous, cyanide-containing solutions, which are passed through ion exchangers, bound here and released by regeneration of the ion exchangers in concentrated form, characterized in that the dilute aqueous solution in a closed circuit over a strongly acidic cation exchanger with sulfonic acid groups as filling, a weakly basic anion exchanger with tertiary dimethylamino groups in hydroxide form as filling and a strongly basic anion exchanger with quaternary trimethylammonium groups in hydroxide form as filling, wherein until reaching the full loading state of one of the ion exchangers, the silver complexes and free complexing agent gradually on the weakly anionic anion exchanger and a strongly basic anion exchanger are bound, after which a regeneration of the anion exchanger, in which the regeneration solution is fed in the same flow direction as in the loading, but first the strongly basic anion exchanger and then the weakly basic anion exchanger is flowed through by treatment with a 1 to 6 molar alkali hydroxide solution, associated with a release of the complex silver cyanides, and thereafter a per se known electrolytic Deposition of the silver is carried out from the regeneration solution. 2. The method according to claim 1, characterized in that the strongly acidic cation exchanger is additionally preceded by a weakly basic anion exchanger. 3. The method according to claim 1, characterized in that the dilute, aqueous solution to be treated contains an excess of complexing agents.