DE1565926C3 - Device for the electrochemical processing of cutting edges - Google Patents

Description

The invention relates to a device for the electrochemical machining of cutting edges on continuous ones Metal strips, especially on razor blade strips, the metal strip over the electrolyte in a first electrolyte-filled chamber with a cathode and in a second electrolyte-filled chamber Chamber communicates with an anode

It is known to use electrolytic cells for removing metal from continuous workpieces, wherein anodes and cathodes are arranged along the workpiece and an electrolyte over the Workpiece surface and in contact with the electrodes flows so that between workpiece and electrodes there is no physical contact

This known arrangement has the disadvantage that only the parts of the opposite cathode Workpiece are treated while facing the anodes or as spacers between anodes and cathode-serving insulators no processing takes place. Furthermore, the electrolyte, through the the current flows from the anode to the workpiece, dirty because this electrolyte also removes the electrolysis products from the workpiece at the same time There is also some current loss when the current is direct from the anode through the electrolyte flows to the cathode

In another type of embodiment of a previously known cell for surface treatment, in particular of anodizing, continuous workpieces are anodes in one or more of an electrolyte arranged leading chambers, so that the current pass through the electrolyte in the workpiece can. The workpiece is then transferred to the main treatment chamber, in which the cathode is located The arrangement is chosen so that the entire surface of the workpiece is electrolytically treated will. It is not possible to treat selected parts of the surfaces in places. Also can high current densities result at the points where the current flows into the workpiece, wel the current over only a relatively short workpiece length can occur. Also known is an electrolytic cell for the treatment of a continuous strip with two chambers for receiving an electrolyte, wherein each chamber contains a cathode and each edge of the strip with that in the chamber Electrolyte is in contact. This arrangement has the disadvantage that the contact between the anode and Strip is produced over a sliding contact, which leads to sparking and consequently to damage of the strip can lead.

The invention is based on the object of a device for the electrochemical processing of cutting edges on continuous metal strips, in particular on razor blade strips, which provide a cheap power supply to the workpiece, short Current paths in the workpiece and low current losses guaranteed.

This object is achieved with a device of the type mentioned at the outset in that the chambers and the electrodes are elongated and arranged approximately concurrently with the metal strip, that the cathode runs the entire length of the first chamber next to an edge of the metal strip and that the second chamber with the anode therein is adjacent to the central portion of the metal strip extends along the first chamber.

The device is preferably provided with a shielding mask which is used for delimitation and separation of the two chambers and as a guide for the razor blade as it passes through the cell serves.

The walls of the first chamber can be formed by the elongated cathode and the shielding mask be the walls of the second chamber from the elongated anode, the shielding mask and the central section of the razor strip.

With the device according to the invention, the aforementioned disadvantages of the prior art are thereby eliminated turned off that the surface of the workpiece to be electrolytically treated are selected can, because the entire surface is not exposed, and that the surface selected in this way as a whole at the same time is exposed to treatment. Further

there is no sliding contact on the workpiece, but the electrical contact is made via the unpolluted Electrolyte causes the anode to be placed next to the central portion of the razor strip is, over the entire length, high current densities are avoided and it is ensured that the strip is not damaged by excessive local heating and the efficiency of the process is increased will.

In the drawing, an embodiment of the electrolytic cell according to the invention is in one Cross-section and shown in perspective.

The drawing shows an embodiment of the cell, as already described in the earlier patent application DT-OS 1 565 925 is shown and described. The cell has a metal housing 10 which is the cathode of the cell represents. Within the metal housing 10, two shielding masks 12 made of ceramic material are arranged, whose opposite end faces are at a sufficient distance to allow the passage of a metal strip 13 to enable the razor blade blanks lying one behind the other with already punched out recesses is formed. The razor blade strip 13 forms a sliding fit with the End faces of the shielding masks 12. Each of the shielding masks 12 has a central groove in which one elongated anode 14 is angeodnet to an electrolyte receiving anode chamber 12a between the razor blade strip 13 and the respective anode 14. The shielding masks 12 continue to form Cathode chambers 126.

For further details on cell construction and electroforming process or For electrofinish, reference is made to the description and drawing of the earlier patent application already mentioned.

The current travels from each anode 14 through the electrolyte in the corresponding anode compartment 12a to the central portion of the blade strip 13, through the blade strip 13 to the exposed surface of each Edge of the blade strip 13 and then through the electrolyte in the appropriate cathode chamber 126 to the housing 10 forming the cathode.

Such a construction of the electrolytic cell has the great advantage that it is not necessary is to make immediate physical contact between the anode and the blade strip. Such direct physical contact shows the arcing tendency that occurs between the anode (or the anodic contact strip) and the moving blade strip can occur and inevitably the anode (or the contact strip) or the blade strip will wear.

In order to prevent metal from settling on the central part of the blade strip, it is expedient selected as the anode a material that is not in the

dissolves required type to form a coating; Examples of this are anodes coated with rhodium, such as rhodium-plated copper, lead anodes, and graphite anodes. On the other hand, the anodes can also consist of a coating of noble metal on a base metal of anodically polizable material. While platinum-coated titanium is preferably used for this purpose, it is also possible as Plating other precious metals such as rhodium, gold or iridium to be used. These metals are good conductors and have the advantage that they do not dissolve in the electrolyte. It is desirable here as a base material to use a material that can be anodically polished so that the base material is not dissolved, when there are some pinholes in the coating. Tungsten can also be used as the base material will; however, this material is more difficult to machine than titanium and also more expensive.

It should also be stated that only one anode is necessary that the effectiveness by the However, effectiveness can be increased through the use of two anodes. The anodes don't have to be formed with flat surfaces but can be of any suitable shape that allows good current flow guaranteed. For example, instead of anodes in the form of a strip or tape Anodes in the form of rods are used, the circular cross-section of which has the advantage of the largest Surface area per given cross-sectional area.

1 sheet of drawings

Claims (7)

Patent claims: 1. Device for the electrochemical processing of cutting edges on continuous metal strips, in particular on razor blade strips, wherein the metal strip is connected via the electrolyte in a first electrolyte-filled chamber with a cathode and in a second electrolyte-filled chamber with an anode, characterized in that the chambers ( 12a, 126) and the electrodes (10, 14) are elongated and are arranged approximately parallel to the metal strip (13), so that the cathode (10) runs next to an edge of the metal strip over the entire length of the first chamber (12 /?) And that the second chamber (12a) with the anode (14) located therein extends alongside the central section of the metal strip (13) along the first chamber. 2. Device according to claim 1, characterized by a shielding mask (12) which serves to limit and separate the two chambers (12a, 12b) and to guide the razor blade strip (13) as it passes through the cell. 3. Apparatus according to claim 2, characterized in that the walls of the first chamber (126) are formed by the elongated cathode (10) and the shielding mask (12). 4. Apparatus according to claim 2 or 3, characterized in that the walls of the second chamber (12a) are formed by the elongated anode (14), the shielding mask (12) and the central portion of the razor blade strip (13). 5. Device according to one of claims 1 to 3, characterized by a third elongated electrolyte-filled chamber (126) with a second elongated cathode (iQ), a second edge of the razor blade strip (13) being arranged in this third chamber. 6. Device according to one of claims 1 to 5, characterized in that the anode has a has a circular cross-section. 7. Device according to one of claims 1 to 6, characterized in that the anode (14) from consists of a base metal provided with a precious metal coating or plating, which polarizes, if it were anodically connected in an electrolytic cell.