EP0030334A1 - Electrolyzing apparatus for the galvanic reinforcement of web-shaped plastic foils precoated conductively - Google Patents

Abstract

For the galvanic reinforcement of conductively precoated band-shaped plastic foils, it is known to conduct them in a plurality of loops through an electrolysis bath. The belt is contacted with the aid of drive and contacting rollers arranged above the belt. To reduce the effort and improve the efficiency, it is proposed according to the invention that the conductively pre-coated plastic film strip (1) is only guided in a loop through the electrolysis bath (6) and immediately before immersion in the electrolysis bath by perpendicular to the direction of movement of the belt arranged grinding cathodes (26, 27) is contacted by contacting rollers (14, 15) known per se after they have left the electrolysis bath.

Description

The invention relates to an electrolysis system for the galvanic reinforcement of conductive pre-coated band-shaped plastic films which pass through the electrolysis belt in vertical loops, consisting of an electrolysis trough with vertical anode plates arranged parallel to the band course and drive and contacting rollers arranged at the top, and a washing and Drying plant.

DE-OS 15 21 076 describes a device for plating a strand of plastic, a metal layer of extremely small thickness being first produced on the plastic by chemical deposition, which is then electrolytically reinforced. For electrolytic reinforcement, the precoated strand is passed in a plurality of loops through an electrolysis bath, which has an electrolysis trough parallel to the course of the strand arranged vertical anode plates and above arranged drive and contacting rollers. Here, the first three loops are kept considerably shorter than the following ones and are at different voltages, so that they can be seen as independent electrolysis cells. A voltage of approximately 15 V is applied to the first drive and contacting rollers, a voltage of 5 V to the second and a voltage of 2 V to the other drive and contacting rollers. The reduction in loop length and gradation of the voltages in the first electrolytic cells occurred because it was not possible to maintain a voltage in the first loops that is necessary for the electroplating process of the strand. Because of the extremely small thickness of the chemically produced metal coating, a normal long loop would lead to such an increase in the resistance in this thin metal layer that electrolysis hardly takes place anymore.

The invention has for its object to provide an electrolysis system for the galvanic reinforcement of conductive pre-coated band-shaped plastic films, which manages to reduce the effort with significantly fewer loops, in particular with only one. This object is achieved according to the invention in that the conductively pre-coated plastic film strip immediately before immersing in the electrolysis bath by means of a grinding cathode arrangement arranged perpendicular to the direction of movement of the plastic film strip and after the outlet from the electrolysis bath in a manner known per se by drive and Contacting rollers can be contacted and that the grinding cathodes of the grinding cathode arrangement and the drive and contacting rollers are electrically isolated from each other and connected to their own power sources.

The fact that the conductive pre-coated plastic film strip is contacted immediately before immersion in the electrolysis bath, the length and thus the resistance of the current-carrying thin metal layer is limited to a minimum, so that the inlet circuit can be operated with a lower voltage and therefore higher currents than in the known device.

However, it has been shown that little current still flows into the inlet circuit if the cathodes of all current sources are connected to one another. However, if you connect the grinding cathodes and the contacting rollers galvanically separated from each other with your own power sources, the inlet current increases and you get a higher growth rate of the metal layer. The result of this is that after plunging, a reinforced plating can already take place, so that the subsequent drive and contacting rollers are inevitably more resilient. This in turn offers the advantage that the plastic film strip needs to be guided through the electrolysis bath in a single loop for certain applications, which considerably reduces the complexity and length of the system.

In order to achieve good contacting of a plastic film tape coated on both sides, rod-shaped grinding cathodes are arranged on both sides of the tape, which are arched on the side facing the plastic film tape and are arranged so that they are offset in the direction of movement of the plastic film tape and to one another Plastic foil tape passed between the two grinding cathodes successively spreads them over the entire area.

In the case of an existing system, an increase in the Throughput at a given layer thickness is practically only possible by increasing the current and the throughput speed accordingly. The maximum permissible current is limited by the resistance of the metal layer. However, since this resistance is temperature-dependent, according to a further proposal, the current can be increased further by cooling the plastic film strip or the metal layer on and immediately after the grinding cathode arrangement and on and in front of the drive and contacting rollers. The pre-coated or reinforced plastic film strip can preferably be cooled on and after the rod-shaped electrodes by compressed air and on and before the contacting rollers by bath liquid or water.

In order to achieve a uniform layer thickness over the entire width of the plastic film strip, plastic screens are provided in a manner known per se on both sides of the plastic film strip, which, according to the invention, can be adjusted perpendicular to the direction of movement of the plastic film strip in order to adapt to the bandwidth and current density distribution. Furthermore, it has been shown that if you introduce a panel over the entire width of the plastic film strip into the bathroom from above on the inlet and / or outlet side, the current on the inlet and outlet side can be increased without the Copper layer is damaged. This aperture ensures a uniform current density distribution on the inlet and outlet side.

If only plastic foil tapes coated on one side are to be galvanically reinforced, only the corresponding grinding cathodes or contacting rollers are connected to the corresponding power sources. For a better evaluation of the system, two plastic film strips coated on one side are used according to a further proposal treated simultaneously by bringing them together so that the coated sides are on the outside. This can be achieved with only a little additional effort in that a further unwinding and winding roll is provided for the second plastic film strip.

• Figur 1 eine Gesamtansicht einer Elektrolyseanlage in schaubildlicher Darstellung,
• Figur 2 eine vergrößerte Darstellung der stabförmigen Schleifkathoden,
• Figur 3 eine vergrößerte Darstellung des mit Kunststoffblenden versehenen Bandes in schaubildlicher Darstellung und
• Figur 4 eine schaubildliche Darstellung einer Elektrolyseanlage zum Plattieren von zwei einseitig beschichteten Kunststoff-Folienbändern.

The invention is explained in more detail with reference to the drawing, in which two exemplary embodiments are shown schematically. Show it:

• FIG. 1 shows an overall view of an electrolysis plant in a diagram,
• FIG. 2 shows an enlarged illustration of the rod-shaped grinding cathodes,
• Figure 3 is an enlarged view of the band provided with plastic panels in a graphical representation and
• Figure 4 is a diagrammatic representation of an electrolysis system for plating two plastic film strips coated on one side.

Figure 1 shows in principle an electrolysis system for the galvanic reinforcement of a conductive pre-coated band-shaped plastic film. A plastic film strip 1 is 2-pulled off an unwinding roller which is mounted in a wall-shaped housing part 3 and is in drive connection with a brake motor which is not visible in the drawing. The brake motor ensures that a constant tension is maintained in the plastic film strip 1. Via drive rollers 4 and 5, the plastic film strip 1 is fed to an electrolysis bath 6 which has a container 7 in which a pull roller 8 is rotatably accommodated with the aid of a frame 9 is. In the container 7 there are fixed anode plates 10 which rise and fall on both sides of the the plastic film strip 1 are arranged and are connected via lines 11 to anode connections 12 of individual power sources not visible in the drawing. A drive roller 13 is provided opposite the drive roller 5, via which the plastic film strip 1 emerging from the electrolysis bath 6 is fed to the drive and contacting rollers 14 and 15, which are located in a washing container 16. Two drive and contacting rollers are required if the plastic film strip is precoated on both sides and both sides are to be galvanically reinforced. Arrows 17 indicate spray nozzles for water for cleaning the plastic film strip 1 from any electrolyte still adhering to it. The plastic film strip 1 is fed via a further deflection roller 18 to a winding roller 22, which is likewise rotatably mounted in the wall-shaped housing part 3 and is provided with a drive motor which is not visible in the drawing. Both the unwinding roller 2 and the winding roller 22 are provided with pushbuttons 23 which are connected via control shafts 24 to potentiometers for speed control of the brake and drive motors. These potentiometers are not shown in the drawing, since they are located behind the wall-shaped housing part 3.

In the previously usual systems, provided that a conductive layer is applied to both sides of the plastic film strip, the two drive rollers 4 and 5 are also designed as contacting rollers. Since the metallic pre-coating of the plastic film strip 1 is usually applied by chemical deposition or by spraying, this metal layer has an extremely small thickness, which with normal loop length has such a high resistance that the inlet circuit is only able to carry very little current is so that hardly more electrolysis takes place, so the separation is extremely low. Any increase in voltage or current would, however, burn the precoat. For this reason, for example in the known electrolysis plant, the precoated plastic strand is passed through the electrolysis bath in a plurality of sometimes shortened loops. Since a drive and contacting roller must be assigned to each loop in this case, this known electrolysis system is very complex, especially if a thicker layer is to be applied galvanically. These difficulties are essentially eliminated in the system according to the invention by contacting the plastic film strip 1 immediately before immersing it in the electrolysis bath 6, with the aid of a grinding cathode arrangement 25 arranged perpendicular to the plastic film strip 1, as shown in FIG these two grinding cathodes 26 and 27, which are arranged on both sides of the plastic film strip 1. The grinding cathodes 26 and 27 are rod-shaped and are curved on the side facing the plastic film strip 1 and offset from one another in the direction of movement of the strip (arrow 28) such that the rod-shaped grinding cathodes 27 and 26 are coated over their entire area. This allows the current density at the grinding cathodes to be reduced. The arrangement of the S _c hleifkathoden 26 and 27 in the immediate vicinity of the mirror 29 of the electrolysis bath 6, which extends outside of the electrolysis bath 6, current-carrying part of the coating is extremely short, the resistance thus relatively low, in contrast to the known designs. Thus, a much higher galvanization current and thus a significantly higher deposition is possible, so that one can practically manage with a single loop, as shown in FIG. 1. The curved surfaces of the grinding cathodes are as smooth as possible in order to low frictional resistance and on the other hand to obtain a good current transfer.

An additional increase in the galvanization current is possible in that both the incoming and the outgoing current-carrying part of the plastic film strip 1 are cooled. In the exemplary embodiment shown in the drawing, air cooling is preferably used on the inlet side, which starts directly on the grinding cathode arrangement 25. The grinding cathodes 26 and 27 are inserted into the grooves 30 and 31, which are pressed against one another, for example, with the aid of magnetic means not shown in the drawing. Here, the grinding cathodes 26 and 27 are so far apart that the plastic film strip 1 can be moved easily in an S-shape. For air cooling, the two holders are provided with chambers 32 and 33, which are supplied with compressed air via channels 34 and 35, which then cools the strip in the chambers 32 and 33 and can escape in the direction of the arrow 36. This means that the current in the inlet circuit can also be increased.

The plastic film strip 1 emerging from the electrolysis bath 6 is also cooled, namely by spraying with washing water in the washing container 16 by means of the spray nozzles 17 and spraying with bath liquid by means of a spray nozzle indicated by an arrow 37 to close to it the vertex of the deflection roller 13. Immediately after the vertex of the deflection roller 13, spraying with washing water takes place through a further nozzle, which is symbolized by an arrow 38. The spraying is not only used for cooling, but also to avoid the formation of stains on the electrodeposited coating due to adhering electrolytes.

To achieve a uniform layer thickness over the entire width of the plastic film strip 1, plastic shields 40 and 41 are provided on both sides of the strip and on the side thereof, which shield the strip edges against the anode plates 10. They are arranged to be adjustable to the bandwidth and current density distribution transversely to the direction of movement of the belt. The plastic screens 40 and 41 cover the edges of the plastic film strip 1 against the anode plates 10 over the entire length. These plastic panels 40 and 41 are for clarity shown only for the expiring loop portion, as well as the anode plates 10. They are of course also provided in the anode plates of the incoming loop part _o

On the outlet side of the plastic film strip 1, further plastic screens 42 and 43 are preferably introduced into the bathroom from above to a depth of about 20 cm, namely between the strip and the anode plates. This achieves a better current density distribution on the anode plates 10 so that the current on the outlet side can be increased further without the layer being burned. 3 shows the arrangement of the plastic covers with respect to the plastic film strip 1. Such plastic covers can also be provided on the inlet side. In many cases, coating or reinforcement of the plastic film strip is only required on one side. In this case, either only the sliding cathode 26 and the contacting roller 15 or only the sliding cathode 27 and the contacting roller 14 need to be energized, depending on which side of the plastic film strip is precoated. With only: one-sided pre-coating of the plastic film strip, it is advantageous to increase the throughput if, according to a further embodiment, two plastic film strips coated on one side are brought together in such a way that is the metallic coating on the outside.

Figure 4 shows an exemplary embodiment of such an electrolysis plant. In this case, a further unwinding roller 45 is provided for a second plastic film strip 1 ', which is transferred to the drive roller 5 via a deflection roller 46. From there it is then carried on together with the plastic film strip 1 to the deflecting roller 20 and finally wound up again on a winding roller 47. The unwinding and winding rollers 45 and 47 are also provided with feelers 48 for detecting the diameter, so that the drive and brake motors, not shown in the drawing, can be regulated accordingly in terms of speed. The deflection rollers 18 to 21 are located in a drying container 49 in which the plastic film strips are dried on all sides with the aid of fans. Arrows 50 indicate the direction of action for the sake of clarity of fans which are not shown. The preferably electronic control of the electrolysis system is accommodated in a control cabinet 51.

Instead of or in addition to the anode plates 10, anode bodies can be used which can be used without interrupting the electrolysis process.

In an installed system for reinforcing a metal-coated plastic foil strip a polyimide film of 25 _/ um strip thickness and 120 mm width was used .. Prior to the galvanic reinforcement has been switched to this polyimide film or both sides of a CrNi and then again deposited a Cu layer, wherein the CrNi layer was 100 to 200 Å (Å = angstrom) and the Cu layer was 500 to 600 Å. The Cu layer could ver to 20 _/ um by the analysis system according to the invention be strengthened. An acidic copper bath was used as the electrolysis bath with a maximum deposition rate of 0.6 _/ μm per min. The inlet current was 3.5 A and the outlet current was 35 A. The plastic film strip was passed through the electrolysis bath 6 in only one loop, the length of the strip in the copper bath being 2 m. The belt speed was 0.05 m / min. Such plastic films are used to produce components integrated on plastic carriers, such as capacitors, crossovers, conductor tracks, resistors and plated-through holes.

If even greater layer thicknesses are to be achieved, the strip can be passed through the electrolysis bath again or several times, in which case the current strengths can be multiplied accordingly.

Claims (11)

1.Electrolysis plant for the galvanic reinforcement of conductive pre-coated band-shaped plastic films which pass through the electrolysis bath in vertical loops, consisting of an electrolysis tank with vertical _' anode plates arranged parallel to the course of the band and top-mounted drive and contacting rollers, as well as a washing and drying system characterized in that the conductively pre-coated plastic film strip (1) immediately before immersion in the electrolysis bath (6) by means of a grinding cathode arrangement (25) arranged perpendicular to the direction of movement of the plastic film strip (1) and after the outlet _/ outlet from the electrolysis bath ( 6) can be contacted by drive and / contacting rollers (14, 15) and that the grinding cathodes (26, 27) of the grinding cathode arrangement (25) and the driving and contacting rollers (14, 15) are electrically isolated from each other and connected to their own power sources. 2. Electrolysis plant according to claim 1, characterized in that on both sides of the plastic film strip (1) rod-shaped grinding cathodes (26, 27) are arranged, which are arched on the side facing the plastic film strip (1) and in the direction of movement of the plastic Foil tape (1) and offset from one another so that the plastic foil tape (1) passed between the two grinding cathodes (25, 26) covers them successively over their entire area. 3. Electrolysis plant according to claim 1 or 2, characterized in that the plastic film strip (1) on and immediately after the rod-shaped grinding cathodes (26, 27) and on and in front of the contacting rollers (14, 15) is cooled. 4. Electrolysis plant according to claim 3, characterized in that the pre-coated or reinforced plastic film strip (1) on and after the rod-shaped grinding cathodes (26, 27) by compressed air and on and in front of the contacting rollers (14, 15) by bath liquid or Water is coolable. 5. Electrolysis plant according to claim 4, characterized in that the holder (30, 31) for the rod-shaped grinding cathodes (26, 27) is provided with chambers (32, 33) and channels (34, 35) which contacted the cooling air along the Steer the plastic film tape (1) towards the electrolysis bath (6). 6. Electrolysis plant according to claim 5, characterized in that the holder for the rod-shaped electrodes consists of two parts (30 and 31), each part (20 or 31) having an electrode (26 or 27) and both parts (30 , 31) can be held together with the aid of holding magnets. 7. Electrolysis plant according to claim 3 or 4, characterized in that the running out of the electrolysis bath (6) and via a deflection roller (13) running plastic film strip (6) is cooled by rinsing, the plastic film strip (6) to close is cooled at the apex of the deflection roller (13) with bath liquid and after the apex with water. 8. Electrolysis plant according to one of claims 1 to 7, characterized in that to achieve a uniform layer thickness on both sides of the plastic film strip (6) are arranged arranged adjustable plastic screens (40, 41). 9. Electrolysis plant according to one of claims 1 to 8, characterized in that on the inlet and / or outlet side of the plastic film strip (1) a plastic screen (43) over the entire width of the plastic film strip (1) is immersed from above . 10. Electrolysis plant according to one of claims 1 to 9, characterized in that in the case of plastic film strips coated on one side, two strips (1, 1 ') are brought together in such a way that the coated sides are on the outside. 11. Electrolysis plant according to one of claims 1 to 10, characterized in that for drying the plastic film strips (1, 1 ') are arranged on both sides of the same fans. 1 plastic film tape 2 unwinding roll 3 wall-shaped housing part

6 electrolysis bath 7 containers 8 pull roller 9 frame 10 anode plates 11 lines 12 anode connections 13 pulley

16 washing containers 17 arrows (spray nozzles) 18 pulleys

23 touch device 24 control shaft 25 grinding cathode arrangement

28 arrow (direction of movement of the belt) 29 Electrolysis bath mirrors

36 arrow direction 37 arrow 38 arrow

45 unwinding roll 46 pulley 47 take-up roll 48 push button 49 drying container 50 arrows 51 control cabinet

Images