DE2234365C3 - Device for the continuous electrochemical treatment of a metal strip - Google Patents

Description

The invention relates to a device for the continuous electrochemical treatment of a metal strip.

An electrochemical treatment of metals can be carried out to remove metal and thereby to modify the surface, in particular to roughen it; to create an oxide layer or to to deposit a metal layer by electroplating.

If the metal is an endless molding, ζ. Β. in the form of wire or tape, the treatment is carried out preferably carried out by continuously passing the shaped body through the treatment bath.

From the German Offenlegungsschrift 16 21 115 it is z. B. known to lead an aluminum strip successively through a series of different electrochemical treatment baths, in which it is first ^br > electrolytically roughened and then anodically oxidized. The belt is conveyed through the various baths by means of pulleys.

In the French patent 14 24 643 is a Device for the anodic treatment of aluminum strips described in which the strip without Deflection rollers run horizontally through the treatment bath, whereby it is through a sealed input and Outlet opening is guided in the side walls of the bath tank. The bath liquid is by means of a Pump circulated in such a way that a strong turbulent flow between the belt and the Electrode is maintained. This results in a rapid exchange of electrolyte on the strip surface and rapid heat dissipation guaranteed. Under these conditions it is possible with high Current densities and thus high throughput speeds for the tape to work.

A disadvantage of this device is the use of abrasive rubber seals on the inlet and outlet Exit point of the tape. They can easily become scratched, especially those that are electrochemically treated Surface lead. Furthermore, the type of electrolyte circulation described there does not guarantee any optimal mixing of the entire bath liquid.

Although it is often desirable, because of the corrosive nature of many baths, not to use pulleys Having within the liquid is its use in those cases where there is no substantial corrosion is to be feared, but associated with considerable advantages. They allow the use essential shorter electrolyte troughs and thus space-saving devices. Besides, you don't need one here abrasive seals.

On the other hand, it is difficult to guide the belt around a deflection pulley in a simple manner to generate and maintain uniform turbulent bath flow along the strip surface.

In order to achieve the highest possible flow velocities, the liquid has mostly been placed underneath Pressure is pumped into the gap between the tape and the electrode, as in the French patent 14 24 643 and DE-OS 15 21 068 show.

It has now been found that in virtually every application of external pressure for this purpose Surfaces are obtained that are not free from flow patterns or other uneven surfaces Electrolyte flow-returning irregularities. Apparently it is, especially at larger bandwidths, not possible under such conditions, a completely rectified flow and to generate a completely uniform speed distribution over the entire width of the belt.

The object of the invention was to provide a device for the continuous electrochemical treatment of To propose metal bands in which the band runs through one or more pulleys through the electrolyte bath is performed and in which the electrolyte between the strip and the counter electrode with high, over the The entire width of the belt flows uniformly in one direction.

The invention is based on a device for the continuous electrochemical treatment of a Metal strip with an electrolyte trough, at least one pulley and at least one electrode in the Liquid space of the electrolyte trough, at least one flow channel between the electrode and its opposite part of the transport route and facilities for generating a rapid flow of Electrolyte liquid parallel to the direction of movement of the metal band through the channel.

The device is characterized in that the ends of the flow channel in separated parts of the Liquid space with different liquid level lie. The different fluid levels in the separated parts of the liquid space can be maintained by the fact that devices to suck the liquid out of one part and to pump it back into the other part are provided.

According to one embodiment of the device, the ends of the flow channel lie on different ones Height, d. h, the duct is inclined or, in extreme cases, vertically.This makes it possible to to use shorter electrolyte troughs and thus space-saving overall systems.

With particular advantage, two such flow channels above a deflection roller can be used in one device and are arranged in front of and behind this roller in the transport path of the belt. D? Bei will expediently the two channels with a common separated liquid chamber with a lower liquid level connected in such a way that this chamber is between them and that through both channels the Electrolyte liquid flows into this chamber from the outer main liquid space.

This embodiment can advantageously be designed so that the entire flow channels, separated liquid chamber and pulley consisting of the device part from the electrolyte trough can be extended upwards. In this way, the belt can be extended outside of the opening at the start of operation threading aggressive electrolytes or any malfunctions during operation easily and without Eliminate drainage of electrolyte fluid.

Another embodiment of the device has two pulleys in the electrolyte trough, between which the flow channel is arranged essentially horizontally. Ir. in this case the flow is through the channel forced by the fact that it is the only fluid connection between the severed Forms parts of the liquid space.

In the device according to the invention, the liquid flow comes through the alone in each case Gravity or by the difference in hydrostatic pressure between the beginning and the end of the flow channel conditions. In this way it is achieved with extremely simple means that between the surface of the tape to be treated and the electrode opposite it a strong, over the entire width of the chamber is maintained the same turbulent flow, which is so uniform that that it does not come to the mapping of flow structures on the treated surface. If that If the metal strip is only to be electrochemically treated on one side, it is expediently close to the the side wall of the channel opposite the electrode side escaped.

For optimal use of the transport path of the metal strip within the electrolyte liquid, how already mentioned, preferably one such channel with an electrode in front of and behind the f> o deflection roller The channels can be directed vertically or diagonally upwards, depending on how the Can be made the best way to guide the metal band.

In the device according to the invention, metal strips can be electrochemically processed in various ways treated weft. So z. B. a band by equal or Alternating current treatment superficially cleaned, descaled, roughened or the like. It is it is also possible to carry out an anodic oxidation or to galvanize the strip.

The tape can act as a counter electrode against the electrode or electrodes or as a central conductor be switched between two electrodes of different voltage.

The latter type of circuit is mainly used for alternating current treatment, but it can can also be used for direct current treatment. In this case the tape is opposite the one Electrode as anode, connected to the other as cathode

The device makes it possible to work with very high current densities which, depending on the type of treatment, can be between approximately 2 and 150 A / dm ² . In the case of electrochemical etching, the range from about 25 to 120 A / dm ² is preferred. Treatment times of about 10 seconds to 2 minutes are generally achieved.

The flow rate of the electrolyte liquid The desired current density is set in the gap between the strip and the electrode. The regulation the flow rate is achieved by changing the level difference in the electrolyte liquid between the separated parts of the liquid space and possibly the distance between the Wide walls of the flow channel, d. H. usually the distance between the tape and the electrode.

The device is essentially for the one-sided electrochemical treatment of metal strips provided and suitable In principle, a bilateral treatment is also possible by adding another Electrode is let into the wall of the flow channel opposite the back of the band and the tape is guided through the channel at a corresponding distance from this wall. With the special In the preferred unilateral treatment, the tape is generally as close as this to the back wall led so that it just no longer touches her. In this way of working, the back of the tape remains from The distance between the strip and the electrode is practically unchanged apart from the narrow edge zones usually on the order of 1 to 5 cm.

The device can advantageously consist of several of the basic units described above with an electrolyte trough be composed. Washing stations are expediently installed between these basic units, to free the tape from the adhering liquid of a treatment station. You can also chemical etching or pickling stages arranged behind or between the electrochemical treatment stations will. An example of the combination of several electrochemical treatment stages in one continuous plant is the electrochemical roughening and subsequent anodic oxidation of an aluminum tape. Etching and electroplating treatments for aluminum, copper, Steel or other metal strips in a device according to the invention in several successive ones Stations are carried out.

The following are embodiments of the device explained in detail with reference to the drawings.

Fig. 1 shows a section through the basic unit of an embodiment of the device.

F i g. 2 shows an embodiment with a horizontal

Arrangement of the channels.

In Fig. 1, the metal strip is denoted by 1, which passes through the electrolyte trough 2 via the rollers 9, 10 and II which contains the electrolyte liquid 3. The transport path of the belt is above the pulley 10 surrounded by two flow channels 5 'and 5 "with a flat rectangular cross-section, which are of the Outer walls 4 'and 4 "and the electrodes 7' and 7" designed as inner walls and not End walls shown are formed in front of and behind the plane of the drawing.

The electrodes T and 7 " together with the top and bottom adjoining non-conductive wall parts form the chamber 6, which is separated from the main liquid space of the electrolyte trough 2 and only connected to it through the slots 8 'and 8" below the electrodes T and 7 ", respectively.

The guide roller 9 for the tape 1 is connected to the cathode, and the electrodes T and 7 ″ are connected to the anode of a power source.

In the chamber 6, a suction tube 12 is guided up to the vicinity of the bottom of the chamber. The pipe ends in a suction pump 13, from which a line 16 via the throttle valve 15 into the main liquid space of the Electrolyte trough 2 returns. Near the inlet point of the line is a cooler 17 for discharging the excess heat attached.

During operation, the strip 1 is guided through the electrolyte liquid at the desired speed. The liquid flows continuously from top to bottom through the channels 5 'and 5 "between the surface of the belt and the electrodes T and 7", respectively. It flows through the slots 8 'and 8 "into the chamber 6 and is continuously sucked off there via the line 12 by the pump 13. The suction line is regulated by the throttle valve 15, which is controlled by the adjustable level probe 14.

The whole of pulleys 9, 10 and 11, the chamber 6, the flow channels 5 'and 5 "and the Existing suction devices device part is connected to a structural unit and can be removed from above the electrolyte trough 2 are lifted out.

F i g. 2 shows a simplified representation of another embodiment of the device according to the invention. Here the tape 1 is guided over two pulleys 10 and 10a, which are at the ends of an elongated Electrolyte trough 2 are arranged. The trough contains two basic units with two flow channels each. The main liquid space of the trough 2 is divided by an intermediate wall 18 which is only a narrow one Leaves gap open above the bottom of the trough through which the belt can pass. In the left half of the trough there is a separate chamber 6 with a lower liquid level than the main liquid space. The liquid level in the chamber 6 is maintained by the overflow 19 through which the Liquid drains through a drain (not shown) into a reserve tank, from which it flows into the electrolyte trough is pumped back.

The electrolyte liquid flows from the main liquid space through the flow channels 5 ′ and 5 ″ between the strip 1 and the electrodes T and 7 ″ into the chamber 6.

The basic unit located in the right half of the electrolyte trough 2 consists of the same elements like the left unit. The corresponding numbers are each marked with a to distinguish them small a provided.

The switching of the electrodes can be made depending on the desired result. In the drawing, the electrodes T and Ta "are at the negative pole, the electrodes 7" and 7a 'at the positive pole of a direct current source. In this case, the strip serves as a center conductor between the oppositely polarized electrodes T and 7 "or 7a 'and 7a".

For this 2; Sheet drawings

Claims (6)

Patent claims: 1. Device for the continuous electrochemical treatment of a metal strip with a Electrolyte trough, at least one pulley and at least one electrode in the liquid space of the Electrolyte trough, at least one flow channel between the electrode and the one opposite it Part of the transport route of the metal strip and facilities for generating a rapid flow of electrolyte liquid parallel to the direction of movement of the metal strip through the channel, thereby characterized in that the ends of the flow channel (5 ', 5 ") in separated parts of the Liquid space with different liquid level lie. 2. Apparatus according to claim 1, characterized in that to maintain the different Liquid levels in the separated parts, devices (12, 13, 15, 16) for suction the liquid from one part and intended for pumping back into the other part. 3. Apparatus according to claim 1, characterized in that the ends of the flow channel (5 ', 5 ") lie at different heights. 4. Apparatus according to claim 3, characterized in that it has two flow channels (5 ', 5 ") contains, the above a pulley (10) and in the transport path of the tape in front of and behind this role are arranged. 5. Apparatus according to claim 4, characterized in that there is a common separated one between the two flow channels (5 ', 5 ") Liquid chamber (6) is located at a lower level and that the entire flow channels, separated liquid chamber and pulley consisting of the device part from the electrolyte trough (2) can be extended upwards. 6. Apparatus according to claim 1 with two deflection rollers, characterized in that the flow channel or the flow channels (5 ', 5 ", 5a", 5a ") are essentially horizontal and between the two deflection rollers (10,1Oa ^ and that they form the only fluid communication between the separated parts of the fluid space.