EP2324143A1 - Cathode for the electrolytic deposition of zinc or the like from an electrolyte bath - Google Patents

Abstract

The invention relates to a cathode for the electrolytic deposition of zinc or the like, which comprises an electrolyte bath, which has a cathode sheet, a supporting and contact bar, which is attached to the upper edge of the plate-like cathode sheet and has a higher stability than the cathode sheet and has edge strips mounted at the lateral edges and possibly at the bottom edge of the cathode sheet. The edge strips are composed of an electrolyte-resistant metal, the electrical conductivity of which is lower than that of cathode sheet.

Description

 EMS Elektro Metal Schwanenmühle GmbH, D-66851 Schwanenmuehle

Cathode for the electrolytic deposition of zinc od, dal, from an electrolvt bath

The invention relates to a cathode for the electrolytic deposition of zinc, or the like, from an electrolyte bath, which comprises a cathode sheet, a support and contact rail attached to the upper edge of the plate-shaped cathode sheet, which has a higher stability than the cathode sheet, and at the side Has edges and possibly the bottom edge of the cathode sheet attached edge strips,

To obtain largely pure zinc, the known electrolytic deposition of metal ions at a cathode is suitable. Here, metal ions are dissolved in an acid bath of processed material, such as ore, electrolytically and deposited on a cathode, the transport of the metal ions through the acidic electrolyte takes place between Cathode and anode flowing DC,

Suitable cathodes for this purpose can generally be subdivided into two main components, namely the cathode plate or the cathode sheet, on which or on which the metal to be recovered is deposited, and the part called the contact, support or head rail, which belongs to the Introducing the electric current into the plate-shaped cathode sheet and for mechanically stabilizing and moving the cathode sheet, The electrolytic deposition of the zinc to be recovered on the surfaces of cathodes follows the current density distribution between anode and cathode and at the same time protects the cathode sheet from corrosion in the acid bath,

In order to obtain a uniform deposition or a metal structure as uniform as possible on the cathode, the most constant possible current density distribution over the cathode surface is sought. At the upper liquid level of the acid bath, the so-called liquid zone, there is normally no metal deposition, so that there is no protection against the cathode sheet Depending on the material used, the cathode sheet can therefore corrode and wear prematurely in the liquid zone, the acidic electrolyte being formed by the deposited zinc.

The deposited during the electrolytic deposition on the cathode and built there metal is stripped on both sides of the cathode outside the acid bath (stripping), it is a hindrance if the material to be recovered grows during deposition in the acid bath or electrolyte over the edges of the cathode sheet and thus Therefore, there is a requirement to keep the cathode edges in the electrolytic deposition of the zinc to be obtained free, For this purpose it is known on or on the cathode sheet to attach so-called edge strips, the previously from electrical The edge strips surround the edge regions or edge regions of the cathode, so that the direct current flowing through the cathode is not introduced into the electrolyte bath at the edges and thus no metal ions are deposited and deposited at these points,

The edge strips enclose either only the two vertically extending lateral edges of the cathode sheet or the lower, horizontally extending edge, There are many solutions with respect to the manner of attachment of the edge strips on the plαtteπformigen Kαthodenblαtt known, but all these solutions together is the use of an electrically insulating material such as plastic, rubber or wax for the edge strips,

These known cathodes with edge strips have some disadvantages, which in practice lead to additional operating costs,

The known edge strips are not mechanically strong and can be damaged in the processing of the cathode outside the electrolyte bath, this can lead to that at renewed

Use of the cathode in the region of the edge zone of the cathode sheet hindering metal deposits arise. In addition, it may also result in damage to the cathode sheet itself.

The known edge strips are not sufficiently strong with the

This leads to metal build-up in the edge zone region of the cathode sheet under the edge strips or also to the solution of the cathode material in the electrolyte. In both cases, the edge zone region of the cathode sheet is destroyed under the edge strips. The service life of the cathode sheet is thereby reduced. Under certain circumstances, the edge strips may lose their hold on the cathode sheet and remain in the electrolyte bath. This can cause significant interference during operation.

The edge strips change their chemical and physical properties when used in acidic electrolyte. As a result, the electrolyte is contaminated with foreign chemicals or other foreign substances. There is also the risk that the edge strips wear out prematurely,

The invention has for its object to avoid the above-mentioned disadvantages in the electrolytic deposition of metals from an electrolyte bath and, accordingly, to provide a cathode for the deposition of zinc or similar metals, which longer than known cathodes can be used and thus has a longer life,

This object is achieved according to the invention with a cathode, which has the features of claim 1, Advantageous embodiments and modifications of the invention are the subject of the dependent claim 1 dependent claims,

Notwithstanding the above-described prior art according to the present invention, the edge strips are not made of electrically insulating material, but of a resistant to the electrolyte metal, but which has a significantly and significantly lower electrical conductivity as the cathode sheet, the deposition of metal ions to the The thickness of the metal layer formed thereby on the edge strips is so small that the subsequent Abschalprozess of the recovered zinc or similar metal from the surfaces of the Cathode sheet is not affected,

For example, according to the invention, the edge strips made of stainless steel or titanium, while the cathode sheet may be an aluminum sheet,

The metallic edge strips can be securely and permanently attached to the cathode sheet in a suitable manner, for example by riveting, screwing, clamping or welding, so that the above-described disadvantages of the known non-metallic edge strips are avoided,

Due to the much higher mechanical stability of the present invention to be provided edge strips the risk of damage and loss is significantly reduced The inventively provided metallic edge strips can be connected to the cathode sheet with much higher support.

The metallic edge strips behave inertly with respect to the electrolyte. A change in the chemical or physical structure of the edge strips does not take place with a suitable choice of the metallic material,

To protect the region of the cathode sheet, which is located on the surface or, the mirror of the electrolyte bath, for example, a coating made of plastic, this is applied in a suitable manner to the cathode sheet and prevents corrosion, as long as the coating of plastic If this is not the case, the plastic can be undermined and the corrosion proceeds accordingly quickly,

In the liquid zone protected cathodes are known, these known cathodes in common is the use of a chemically resistant plastic, which, however, relatively easily dissolves from the cathode sheet and then its functions can no longer meet, Also provided with a plastic coating region of the cathode sheet by the peeling process mechanically stressed during the removal of the recovered metal, resulting in premature wear of the plastic coating,

Instead of plastic according to the invention a chemically resistant metal, such as stainless steel or titanium, used as protection for the cathode sheet, Derartiges metal can be very intimately connected to the cathode sheet, so that a Unterspülen the coating of the cathode sheet is prevented with electrolyte, as metals in general a have higher mechanical strength than plastics, the wear during peeling of the recovered zinc or other metal is reduced to a fraction compared to plastic, the durability and Lifespan of the protection of the cathode is therefore also significantly increased in the area of the liquid zone

In order to facilitate the process of Abschalenens attached to the cathode by the electrolysis zinc, it is known to use a so-called blade This pushes from the top between the cathode sheet and the metal layer deposited thereon As an approach for the blade are used in many cases approach discs made of plastic , which are provided on the cathode sheet in height of the liquid zone or the electrolyte surface on one or on both sides The known approach discs are made of plastic, since this is electrically non-conductive and therefore prevents the formation of a metal layer in this area The impact of the blade when stripping mechanically heavily stressed often the shoulder discs are therefore damaged or even knocked out their function is no longer given

According to the invention, the starting disks also consist of metals resistant to the acid bath or the electrolyte, such as, for example, stainless steel or titanium. The metal layer formed on the cathode during the electrolytic deposition takes place in proportion to the conductivities of the metals used for the contact disk and the cathode sheet The forming metal layer can be influenced by the electrical transition between the cathode blade and the contact disk. A correspondingly thin deposited metal layer on the contact disk does not hinder the function of the blade. The impact of the blade on the metal-made starting disks can not damage or destroy the contact disks a much longer service life than known shoulder plates made of plastic

Since the shoulder discs are arranged in the region of the electrolyte surface or liquid zone at the cathode, they can be combined with the above-described metallic liquid zone protection and in a Unit to be connected. Liquid zone protection with integrated suction disk also extends the service life of the cathode sheet

In the drawing, to further illustrate the invention, an embodiment of the cathode according to the invention is shown schematically in a view.

The cathode 1 has an existing example of aluminum sheet cathode sheet 2, which is fixed to a mounting rail 3. This cathode sheet 2 can be hung in the position shown in the drawing in an electrolyte bath, the surface of which is indicated by a dot-dash line 4.

The support rail 3 is provided with hooks 5 for handling and with contacts for the power input 6,

At the vertical edges 7 of the cathode sheet 2 edge strips 8 are permanently attached, which consist of metal whose electrical conductivity is much lower than that of the cathode sheet. At the lower edge of the cathode sheet 2 is shown in the

Embodiment, a further edge strip 9 attached, which consists of the same metal as the skirt 8, but this skirt 9 can also be omitted,

On the cathode sheet 2 are equal to the surface of the

Electrolyte bath (dash-dotted line 4) - one-sided or double-sided - shoulder discs 1 0 made of the same material as the edge strips 8 and 9 attached, which serve to facilitate the attachment of peeling knives,

In the area of the liquid zone of the electrolyte bath or whose surface (dash-dotted line 4) a protective layer 1 1 is arranged on the front and the back of the cathode sheet 2, which may consist of the same material as the edge strips 8 and 9 and the approach discs 1 0 Optionally, an electrical insulation, for example an insulating coating or an insulating intermediate layer, may be provided between the cathode sheet 2 and the edge conductors 8 and 9, which are made of poorly conductive metal and also likewise of poorly conductive starting disks 10 zinc or other metal on these accessories,

The ratio of the electrical conductivity between the existing of aluminum cathode sheet 2 and made of stainless steel

Skirting 8 and 9 is about 50; 1, When using titanium for the skirting and also the lugs, this ratio is much larger, because titanium is a very bad conductor,

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Claims

EMS Elektro Metal Schwanenmühle GmbH, D-66581 Schwanenmühle Patent claims:

1. Cathode for the electrolytic deposition of zinc od. Like., From an electrolyte bath, with an electrically conductive cathode sheet, at the top of a support and

Contact rail is attached, which has a higher stability than the cathode sheet, and attached to the other edges of the cathode sheet edge strips, characterized in that the edge strips (8; 9; 10) of the cathode sheet (2) consist of resistant to the electrolyte used metal, whose electrical conductivity is significantly lower than that of the cathode sheet,

2, cathode according to claim 1, characterized in that the

Cathode sheet made of aluminum,

3, cathode according to claim 1 or 2, characterized in that the edge strips (8; 9} are made of stainless steel,

4, cathode according to claim 1 or 2, characterized in that the edge strips (8; 9) consist of titanium,

5, cathode according to one of claims 1 to 4, characterized in that the cathode sheet (2) in the region of

Liquid zone (4) of the electrolyte bath is provided with a coating or, with a cover or, a protection of stainless steel or titanium,

6, cathode according to one of claims 1 to 5, characterized in that the cathode sheet (2) is provided with shoulder discs (1 0) for the attachment of a paring knife, which consist of metal with significantly lower electrical conductivity as the cathode sheet,

7. Cathode according to one of claims 1 to 6, characterized in that between the cathode sheet (2) and the edge strips (8; 9) and the shoulder discs (1 0) an electrical

Isolation is provided

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