EP0283785B1 - Process for recovering mercury by electrolysis - Google Patents

Abstract

A process for recovering metallic mercury by electrolysis from an electrolyte containing Hg2Cl2 in suspension by cathodic reduction.

Description

The invention relates to a method for the deposition of metallic mercury from an electrolyte by means of electrolysis, wherein the mercury-I-chloride (Hg₂Cl₂) in suspension-containing electrolyte reacts with chlorine, which the mercury-I-chloride to soluble mercury-II-chloride (HgCl₂ ) oxidized, which is reduced cathodically to liquid mercury by electrolysis under the influence of chlorine at the anode.

The process according to the invention is advantageously used whenever mercury-I chloride present as a suspension is to be separated off and recovered as metallic mercury. Mercury-I-chloride, for example, often occurs during the purification of gases, which is obtained in a reactor with a solution of mercury-II-chloride.

Such a process is described in European laid-open specification 179 040. The chlorine gas generated there during the electrolysis is discharged from the electrolysis vessel and fed to a reactor in which the oxidation has taken place. This has the advantage that the chlorine gas required in the process is generated by the process itself, but a special chlorine gas line is required between the electrolysis cell and the oxidation reactor. Special precautions must be taken to ensure that the toxic chlorine gas does not get into the environment. The chlorine gas must also be taken by appropriate measures in the in the reactor existing suspension can be finely divided so that the oxidation reaction can be carried out there.

This publication does not describe the exact design of the electrolysis cell used there. However, it must be assumed that the electrolysis cell is divided by means of a membrane, because the state of the art according to German patent specification 20 11 610 generally advises to keep chlorine away from the cathode during an electrolysis cycle, since chlorine is reduced at the cathode and thus reduces the current efficiency of the metal deposition taking place there (cf. in particular column 8, lines 63 ff of DE-AS 20 11 610).

The invention avoids these disadvantages. It is based on the object of proposing a method for the deposition of metallic mercury from an electrolyte by means of electrolysis with the features mentioned at the outset, which is distinguished by a noticeably simplified procedure, combined with a noticeably increased yield of deposited metallic mercury.

To achieve this object, the invention is characterized in that by using an electrolysis cell in which the chlorine developed during oxidation at the anode can migrate unhindered into the cathode region of the cell, the chlorine formed in the electrolysis cell during electrolysis in situ for the oxidation the mercury-I chloride contained in the electrolyte as a suspension is used to form soluble mercury-II chloride.

The separate conduction of the chlorine gas evolving during electrolysis to the oxidation reactor is therefore dispensed with. Rather, the oxidation and the electrolysis are carried out in one and the same electrolysis cell, so that the chlorine gas generated during the electrolysis can also migrate directly and unhindered into the cathode region of the cell. The gaseous chlorine formed in the electrolysis is therefore generally dissolved in the electrolyte and transported with the electrolyte, possibly supported by a pump or the like. The entire volume of the electrolyte is thus available for the oxidation of the mercury I chloride to mercury II chloride by means of the (gaseous or dissolved) chlorine.

A fixed bed electrolysis cell is preferably used for the process described, without a separate anolyte circuit and with a diaphragm which prevents direct contact with the counterelectrode but does not hinder the mass transfer. It has become known in a basic embodiment by the German patent specification 26 22 497 and in an improved embodiment by the applicant's DE-PS 29 04 539. A further improved embodiment describes the applicant's DE-PS 35 32 573. All of these embodiments can be used for carrying out the method according to the invention.

The process according to the invention is carried out in such a way that the electrolyte is used at least initially in such a concentration of mercury-I chloride and / or that the electrolysis voltage and thus the electrolysis current are used at least initially at such a level that metallic mercury is used deposits on the cathode and drips from there. It can then be withdrawn from the bottom of the electrolytic cell. Iron, silver, nickel, copper, cadmium, aluminum, zinc, tin or an alloy of these metals is particularly suitable as the material for the cathode.

Deviating from the proposal of the already mentioned German specification 20 11 610, anodically formed chlorine is thus used in the process according to the invention to oxidize the poorly soluble mercury-I chloride, which then dissolves this salt, whereby the initial suspension is only made accessible to electrolysis.

Experiments have shown that it can suffice if the electrolysis voltage and thus the electrolysis current are only initially applied in a voltage spike for a relatively short time, namely until a first mercury film has formed on the surface of the amalgam cathode. The voltage can then be reduced to normal values again and the mercury continues to deposit in metallic form on the surface of the amalgam cathode. The same applies to the concentration of Hg₂Cl₂ in the electrolyte.

The inventive method is based on the theory that at the anode of the electrolysis device Cl⁻ in Cl₂ passes. The Cl₂ reacts with the Hg₂Cl₂ in suspension form and gives 2HgCl₂, which is dissolved in the electrolyte.

At the cathode, the HgCl₂ is reduced to Hg ^o + 2Cl⁻. This Cl⁻ is then available for the oxidation of the cathode.

• (A) Hg^o (gasförmig) + HgCl₂ (löslich) = Hg₂Cl₂ (schwerlöslich)
  Oxidation:
• (B) Hg₂Cl₂ (schwerlöslich) + Cl₂ (gasförmig) = 2HgCl₂ (löslich)
  Elektrolyse:
• (C) HgCl₂ (löslich) + elektr. Energie = Hg^o (flüssig) + Cl₂ (gasförmig)
  Ergebnis: Aus Hg^o (gasförmig) + Energie erhält man also Hg^o (flüssig)

Das in Stufe C entstehende Cl₂ (gasförmig) wird als solches und in situ in Stufe B verwendet.Written as an electrochemical equation, the following results:
Initial reaction (only as an example) of how Hg₂Cl₂ can form as a suspension in an electrolyte:

• (A) Hg ^o (gaseous) + HgCl₂ (soluble) = Hg₂Cl₂ (hardly soluble)
  Oxidation:
• (B) Hg₂Cl₂ (hardly soluble) + Cl₂ (gaseous) = 2HgCl₂ (soluble)
  Electrolysis:
• (C) HgCl₂ (soluble) + electr. Energy = Hg ^o (liquid) + Cl₂ (gaseous)
  Result: Hg ^o (gaseous) + energy gives Hg ^o (liquid)

The Cl₂ (gaseous) formed in stage C is used as such and in situ in stage B.

These electrochemical reactions are at least a rough picture of the processes actually taking place during the electrolysis. In reality, these processes can be more complicated, for example via corresponding complexes or multiple reactions.

In one embodiment, using copper as the cathode material, the electrolyte used had the following composition:
45 g / l Hg₂Cl₂ as a suspension
30 g / l sulfuric acid
10 g / l chloride.

The anodic current density was 300 A / m². It was expanded metal, so that this value relates to the entire area including the gaps. The cathodic current density was also 300 A / m².

The initial content of water-insoluble Hg₂Cl₂ was equal to the above-mentioned concentration of the suspension of 45 g / l. The initial current density was 600 A / m².

Claims (3)

1. Process for refining of metallic mercury from an electrolyte by means of electrolysis, wherein the mercury-I-chloride (Hg₂Cl₂) in suspension containing the electrolyte is reacting with chlorine which is oxidating the mercury-I-chloride to a soluble mercury-II-chloride (HgCl₂) which by means of the electrolysis under development of chlorine at the anode is reduced cathodically to liquid mercury, wherein by utilization of an electrolysis cell in which the chlorine developed in the oxidation at the anode, can freely move to the cathode area of the cell wherein the chlorine is developed in the electrolysis cell at the electrolysis is utilized in situ for the oxidation of the mercury-I-chloride to soluble mercury-II-chloride.
2. Process according to claim 1, characterized in that a packed bed electrolysis is utilized.
3. Process according to claim 1 or 2, characterized in that as a material for the cathode iron, silver, nickel, copper, cadmium, aluminium, zinc, tin or an alloy of these metals is utilized.