EP1013468A1 - Method and apparatus for roughening the surface of a support for light-sensistive coating - Google Patents

Abstract

Support, for radiation sensitive layers, is electrochemically roughened in an aqueous electrolyte bath, optionally after mechanical roughening, by three-phase or alternating current application to electrodes facing the support which travels continuously through the bath, a direct voltage being additionally applied to the support before or at the start of support passage in front of the electrodes. An Independent claim is also included for equipment for carrying out the above process, comprising (a) an electrolyte bath (1) containing three-phase current electrodes (4-6) connected to the secondary side of a three-phase current transformer (9), the primary side of which is connected via regulating transformers to a power transformer; and (b) a d.c. (direct current) source (8) with its poles connected to two d.c. electrodes or to a d.c. electrode (3) and the support (2). Preferred Features: The d.c. source (8) is connected with its minus pole to the support (2) and with its plus pole to the d.c. electrode (3) or vice-versa. The three-phase current electrodes (4-6) may be positioned upstream of the d.c. electrode (3), on either side of the d.c. electrode or downstream of two mutually isolated d.c. electrodes. When the support is anodized after passage through the bath, the direct voltage may be applied to a d.c. electrode upstream of the three-phase electrodes and to a current supply to the anodizing bath. A direct voltage may be applied to a d.c. electrode and to a three-phase or alternating current transformer, the d.c. electrode being positioned upstream of the three-phase current electrodes and being connected to the plus pole of the d.c. source, while the minus pole of the d.c. source is connected to the middle phase of the three-phase current transformer or to a center point of the alternating voltages of the two windings of the alternating current transformer. The direct voltage may be pulsed, (part of) the positive half waves of the pulsed direct voltage being applied to the support.

Description

The invention relates to a method and an apparatus for roughening a carrier for radiation sensitive layers, the surface of which is electrochemical or mechanical and then electrochemically in an aqueous electrolyte bath by applying a rotary or AC current is roughened on the carrier opposite electrodes, the carrier is continuously passed through the electrolyte bath.

Such carriers are used for the production of presensitized printing plates, wherein the material of the supports, which are processed in plate or tape form, is a metal, especially aluminum. The roughening of aluminum strips for example Printing plates are produced mechanically, chemically or electrochemically or in Combination of these roughening processes. The aim is that for the water supply and the adhesion of the radiation-sensitive layer used a certain aluminum surface Has structure and uniformity. When mechanically roughened, the surface structures have pyramid-like shapes and have different orientations Longitudinal and transverse direction on (anisotropy), while electrochemically roughened aluminum surfaces a spongy structure with many wells and depressions have uniform geometry in the longitudinal and transverse directions (isotropy).

Mechanical roughening has the advantage over purely electrochemical roughening of the smaller specific energy consumption per square meter surface of the carrier, however the disadvantage of a surface that is too coarse, on top of which, in addition to the pyramid-like structures crystalline structures are present. As a result of the anisotopy of the mechanical roughening it is not irrelevant to the printing process whether the printing plate is lengthwise or crosswise out of the belt was cut out.

Mechanical roughening processes are generally grain processes, such as wire or Brush grit, or sanding, while the electrochemical roughening in generally by electrolytic etching in an aqueous electrolyte solution.

In German patent 19 62 728 is a process for the continuous production of a lithographic surface on a metal belt by wet grinding and electrochemical Treatment described in an electrolyte, which involves wetting the metal surface used the electrolyte during the grinding and the electrochemical treatment in the direct connection to the grinding is carried out. For this there is a in the electrolyte fine-grained abrasive, and the abrasive suspension is in a over the entire width of the metal strip extending broad beam on the moving belt blasted. The electrolyte is, for example, an aqueous acidic or aqueous alkaline bath.

In the graining process described in DE-OS 21 30 391, the aluminum plate is first roughened by grinding with a moist emery compound, and after rinsing and optionally cleaning the plate, the grained surface of the aluminum plate is in sulfuric acid with direct current at a voltage in the range of about Anodized 10 to 20V and a current density in the range of about 1 to 2.2A / dm ² grained surface. Finally, the grained and anodized surface of the aluminum plate is treated with a primer to improve the bonding of the light-sensitive layer to be applied to the surface with the carrier material.

DE-AS 26 50 762 describes a process for the electrolytic graining of aluminum substrates for lithography using alternating current in an essentially hydrochloric acid or electrolytes containing nitric acid are known, with this method a AC voltage is applied, the anode voltage is greater than the cathode voltage and the ratio of the cathodic coulombic input to the anodic coulombic Input is less than 1. The anodic half period of the alternating current becomes equal to or set less than the cathodic half-period. The diameter and depth of the Pores or holes in the surface of the aluminum substrate can be set as desired be by an appropriate ratio of cathodic to anodic coulombic Input, determined by the voltage setting, is selected.

The frequency of the regulated alternating current is not within the usual alternating current frequency range, i.e. 50 to 60 Hz, limited. With higher frequencies, finer pores on the get grained surface.

German patent 30 12 135 describes a method for producing a support for lithographic printing plates, in which the surface of an aluminum plate is mechanically roughened by wet grinding, aluminum is chemically etched away from the surface of the plate and then an electric current with a waveform that by alternating polarity is applied to the plate in an acidic aqueous solution so that the ratio of the amount of charge formed with the plate as the anode to the amount of charge formed with the plate as the cathode is 0.5 / 1 to 1.0 / 1 lies. The electrolysis is carried out so that the current density, if the plate is the anode, is not less than 20 A / dm ² and the amount of charge formed with the plate as the anode is 200 coulombs / dm ² or less, and the anode and cathode voltages are between 1 and 50 V. Finally, the plate is subjected to anodic surface oxidation.

EP 0 390 033 B1 describes a method for roughening a carrier in which the Frequency of the three-phase or alternating current greater than or equal to 50 Hz to 300 Hz is selected and in the rest with increasing transport speed of the carrier through the electrolytic bath Frequency is set higher. For this purpose, the electrodes are in the electrolyte bath with the Secondary side of a first three-phase transformer connected, the primary side via a Three-phase frequency converter and via control transformers to a power transformer for Three-phase current is connected. The three-phase frequency converter sets the mains frequency of this Three-phase current in a range of greater than or equal to 50 to 300 Hz at a voltage between 1 up to 380 V for the individual phases of the three-phase current.

DE 39 10 450 C2 describes a method for producing a printing plate carrier, in which the printing plate support surface is electrochemically submerged in an acid electrolyte Using an alternating current is roughened, which has a frequency of 80 to 120 Hz and in which the ratio of anode time to period time is 0.25 to 0.20. On Such a method requires high circuit complexity because of the large implemented power output and creates problems in the distribution of electricity to the individual electrodes, since connecting a pole to the printing plate carrier is difficult designed.

DE 38 42 454 C2 relates to a method for electrolytic surface roughening Aluminum plate under the action of an alternating current, being in front of the electrolytic Surface roughening an electrically insulating organic or inorganic pre-coating is formed on the aluminum plate. Such a process does not only require an additional effort to form this layer but also corresponding technical Precautions for the action of non-sinusoidal alternating currents, such as those in the Procedures are applied. Even a very even pre-coating does not prevent it the formation of horizontal stripes, since these are essentially due to nonlinear electrical Properties of the surface of the printing plate carrier are conditional at the beginning of the roughening.

Roughening with alternating current of higher, variable frequency, as described in DE 39 10 213 A1 leads to a reduction in the intensity of the horizontal stripes, but requires one high expenditure on electrical equipment and limits the frequency range of the AC, which is for an optimal design of the surface of the printing plate carrier can be used.

A roughening of the printing plate carrier at certain transport speeds, like this Proposed in EP 0 585 586 B1 provides a constant application of each Part of the printing plate carrier with positive and negative half-waves of the alternating current, but does not take into account that transverse stripes essentially due to the upcoming half-waves be formed upon entry into the AC roughening zone.

The known methods and facilities take into account or reduce the education so-called horizontal stripes during the complete passage of the printing plate carrier the AC roughening zone, but do not prevent cross stripes already at Entry of the printing plate carrier into the effective range of the AC or three-phase electrodes form.

The combination of mechanical and electrochemical roughening is aimed at to combine the advantages of both methods. It is expected that the mechanically roughened surface of the metal carrier by cups and depressions through the electrochemical roughening, is superimposed. However, this shows in an undesirable way that in addition to the pyramid-like structures of mechanical Roughening relatively large holes occur due to the electrochemical roughening arise. The problem with electrochemical roughening using alternating current or when overlaying a mechanically roughened surface of a metal support with electrochemical roughening by means of alternating current at very high working speeds the occurrence of so-called electrical ricochets in time with the alternating voltage of the metal carrier, these cross-cuts in strip form visible on the surface of the metal support are. The cause of these disturbing cross-blows is the constant change in polarity of the AC voltage applied to electrodes.

The cross passages in the form of strips, generally also referred to as cross strips or stream strips, reduce the visual impression and, with a particularly strong expression, also the quality of the Product. The formation of these transverse or current strips usually increases with larger ones Transport speed of the printing plate carrier. These stripes are caused too Roughening begins with alternating or three-phase current. The electrical behavior of the Plate support and the electrolyte at the beginning of the roughening is not linear and changes with increasing roughening. This nonlinear behavior leads to the occurrence of Pressure plate carrier in the effective range of three-phase or alternating current electrodes embossing these horizontal stripes depending on whether they enter the roughening zone a positive or negative half wave of the AC voltage is effective.

The object of the invention is to improve a method of the type described in the introduction, that the formation of current stripes or transverse stripes on the surface of a through Electrolyte bath transported through the plate carrier at the beginning of the rotating or AC electrochemical roughening prevented or largely is minimized.

This object is achieved by a method according to the preamble of claim 1 Way solved that before or at the beginning of the transport of the carrier past the rotary or AC electrodes a DC voltage is additionally applied to the carrier.

According to the method, the negative pole of a direct current source is connected to the carrier and its positive pole connected to a DC electrode opposite the carrier. In a further embodiment becomes the negative pole of a direct current source with one opposite the carrier DC electrode and the positive pole connected to the carrier.

The further procedural embodiment of the invention results from the features of Claims 4 to 11.

Three-phase electrodes are in one in a device for carrying out the method Electrolytic bath connected to the secondary side of a three-phase transformer, the Primary side via control transformers to a power transformer for three-phase current is connected and there is also a direct current source, the poles of which have two Direct current electrodes or with a direct current electrode and the carrier which is connected to the rotary and DC electrodes passed, are connected. The device DC electrode in front of the first three-phase electrode in the direction of transport of the carrier Electrolyte bath arranged and connected to the positive pole of the direct current source, the The negative pole is in contact with the wearer.

Another AC device for carrying out the method includes two AC electrodes in an electrolytic bath with a primary and a secondary winding of an AC transformer connected and is a direct current source with the positive pole to one DC electrode and with its ground pole to a common connection of the primary and Secondary winding connected. The direct current electrode is expediently shown in Transport direction of the carrier arranged in front of the AC electrodes.

Figur 1

schematisch eine erste Ausführungsform einer erfindungsgemäßen Vorrichtung, deren mit Drehstrom beaufschlagten Elektroden eine Gleichstromelektrode vorgeschaltet ist,

Figur 2

schematisch eine zweite Ausführungform der Vorrichtung, bei der den Drehstromelektroden zwei Gleichstromelektroden vorgeschaltet sind,

Figur 3

schematisch eine dritte Ausführungsform der Vorrichtung, bei der den Drehstromelektroden eine Gleichstromelektrode vorgeschaltet ist, während eine weitere Gleichstromelektrode zwischen den Drehstromelektroden angeordnet ist,

Figur 4

schematisch eine vierte Ausführungsform, bei der den Drehstromelektroden eine Gleichstromelektrode vor- und nachgeschaltet ist,

Figur 5

eine fünfte Ausführungsform der Vorrichtung, bei der den Drehstromelektroden eine Gleichstromelektrode vorgeschaltet ist und eine Zuführung für elektrischen Strom eines Anodisierbades mit einem Pol einer Gleichstromquelle verbunden ist,

Figur 6

eine sechste Ausführungform einer erfindungsgemäßen Vorrichtung, bei der zwei Wechselstromelektroden mit einer Gleichstromelektrode zusammenwirken, und

Figuren 7a und 7b

schematisch die Diagramme von gepulsten Gleichströmen, die an Gleichstromelektroden angelegt werden.

The invention is explained below with reference to the drawing of some embodiments. Show it:

Figure 1

schematically shows a first embodiment of a device according to the invention, the electrodes of which are supplied with three-phase current, a DC electrode is connected upstream,

Figure 2

schematically shows a second embodiment of the device in which two direct current electrodes are connected upstream of the three-phase electrodes,

Figure 3

schematically a third embodiment of the device in which a direct current electrode is connected upstream of the three-phase electrodes, while a further direct current electrode is arranged between the three-phase electrodes,

Figure 4

schematically a fourth embodiment in which a direct current electrode is connected upstream and downstream of the three-phase electrodes,

Figure 5

A fifth embodiment of the device in which a direct current electrode is connected upstream of the three-phase current electrodes and a supply for electrical current of an anodizing bath is connected to a pole of a direct current source.

Figure 6

a sixth embodiment of a device according to the invention, in which two alternating current electrodes cooperate with a direct current electrode, and

Figures 7a and 7b

schematically the diagrams of pulsed direct currents which are applied to direct current electrodes.

Figure 1 shows schematically a device which consists of an electrolyte bath 1 through which a band-shaped carrier 2 is moved in the transport direction A. The electrolyte in the Electrolytic bath 1 can, for example, dilute aqueous nitric, sulfuric or hydrochloric acid his. A combination of two or three acids can also be used. Of course, other acid baths which are familiar to the person skilled in the art are also suitable for the Electrolyte bath 1 suitable. In addition to acids, the electrolyte bath can contain other chemicals, e.g. Contain salts or surfactants. The carrier 2 is in before it enters the electrolyte bath 1 suitable shape mechanically roughened or chemically pretreated. The facilities for mechanical roughening of the surface of the carrier 2 are not shown. Such facilities or device are among others in DE-OS 19 62 729 and the German patent 19 62 728 described and shown. There is only one electrochemical one in electrolyte bath 1 Roughening the surface of the carrier 2 instead.

Typically, the carrier is acid or roughened before electrochemical roughening Alkaline pretreatment pretreated to prevent rolling oil, impurities and air-formed to remove "natural" oxide. The device used for this is also not shown.

At a distance from the carrier 2, electrodes 4, 5, 6 are arranged in the electrolyte bath 1, which electrodes are connected to three windings of the secondary side of a three-phase transformer 9, which are not described in more detail. The corresponding three windings on the primary side of the three-phase transformer 9 are connected via lines L1, L2, L3 to regulating transformers, not shown, which are fed by a common power transformer for three-phase current. It is also possible that the lines L1, L2, L3 are connected directly to the power transformer, omitting the regulating transformers. If no further measures are taken, there are 2 electric shocks or electrical cross-shocks at high transport speeds of the carrier, which are caused by the applied three-phase current in accordance with the changes in polarity at the three-phase electrodes 4, 5, 6. To avoid these cross-shocks, a direct current electrode 3 arranged in the electrolyte bath 1 is connected upstream of the three-phase electrodes 4, 5, 6 in the transport direction A and connected to the positive pole of a direct current source 8. The ground pole or negative pole 7 of the direct current source 8 is in direct contact with the carrier 2, for example by means of a contact roller or a grinder. The carrier 2 is continuously moved past the electrodes 3, 4, 5 and 6 at a certain distance in the transport direction indicated by the arrow A; alternating current flows through the carrier 2. Direct current flows into the carrier 2 via the direct current electrode 3. By means of this direct current, the surface of the carrier is changed before it reaches the sphere of influence of the three-phase electrodes 4, 5, 6, to the extent that an impression of transverse stripes is not possible or only to a very small extent due to positive and negative half-waves of the three-phase current. The contact between the negative pole 7 and the carrier 2 takes place inside the electrolyte bath 1, but this contact could also be provided outside the electrolyte bath. It is also optionally possible that the negative pole 7 of the direct current source 8 is connected to the direct current electrode 3 and the positive pole to the carrier 2. The direct current electrode 3 is so close to the first three-phase electrode 4 that there can be no change in the electrical behavior of the surface of the carrier 2 achieved after the electrode 3 until the start of the action of the three-phase current or the alternating current. The current density of the three-phase electrodes 4, 5 and 6, which are operated with a selectable three-phase frequency for the purely electrochemical roughening, is in the range from 50 to 200 A / dm ² . After the electrochemical roughening in the electrolyte bath has ended, the carrier 2 is rinsed and electrochemically anodized. Rinsing takes place either with or without intermediate pickling. Insulation 14 is located between the direct current electrode 3 and the three-phase electrode 4.

The voltages applied to the electrodes 4, 5, 6 are 1 to 50 V, in particular 20 to 40 V.

The direct current applied to the electrode 3 is in the range from 0.1 to 10% of the Roughening current of all AC electrodes, and is in particular 2%. The tension of the applied direct current is 1 to 30 V, in particular 5 to 10 V. The current density of the Direct current is 3% to 300% of the roughening current of all roughening electrodes, in particular 100% of the roughening current.

A second embodiment of the device according to FIG. 2 also comprises an electrolyte bath 1, through which the carrier 2 is transported. The electrolytic bath 1 contains one Electrolytes of the same consistency as the electrolytic bath of the first embodiment Figure 1. In addition to the three-phase electrodes 4, 5 and 6, two are immersed in the electrolyte bath 1 DC electrodes 3a and 3b, both in the transport direction A of the carrier 2 in front of the Three-phase electrodes 4, 5 and 6 are arranged. Between the two direct current electrodes 3a and 3b on the one hand and the direct current electrode 3b and the three-phase electrode 4 on the other hand insulation 14 is attached. The DC electrode 3a is one with the positive pole DC source 8 connected, while the DC electrode 3b to the minus or Ground pole of the DC power source 8 is connected. The three-phase electrodes 4, 5 and 6 are connected to corresponding windings on the secondary side of a three-phase transformer 9, while the corresponding windings on the primary side of the three-phase transformer 9 over Regulator transformers, not shown, and a power transformer, not shown Three-phase current are connected. The three-phase transformer can be in star or delta connection be switched. The connection of the three-phase regulating transformers to the power transformer takes place via lines L1, L2 and L3. There is three-phase current on the lines L1, L2 and L3 fed.

The third embodiment of the device according to FIG The invention differs from the second embodiment according to FIG. 2 in that the two direct current electrodes 3a and 3b not next to each other but separately from each other are arranged in the electrolytic bath 1. As with the second embodiment according to the figure 2 in the third embodiment are the three-phase electrodes 4, 5 and 6 with the corresponding ones Windings of the secondary side of the three-phase transformer 9 connected. Corresponding windings on the primary side of the three-phase transformer are not Control transformers shown and a power transformer, not shown, to three-phase current connected. The control transformers and the power transformer are connected via lines L1, L2 and L3. There is three-phase current again via lines L1, L2 and L3 fed. The one DC electrode 3a is in front of the first three-phase electrode 4 Transport direction A of the carrier 2 arranged. The other direct current electrode 3b or 3 ' is located between the first and second three-phase electrodes 4, 5 and the second and third three-phase electrode 5, 6, as indicated by dashed lines in Figure 3. The DC electrode 3b is separated from the adjacent three-phase electrodes by insulation 14 Cut. The DC electrode 3a is with the positive pole of the DC source 8 and the DC electrode 3b or 3b 'connected to the negative pole.

In the fourth embodiment of the device shown schematically in FIG Three-phase electrodes 4, 5 and 6 connected in the same manner as in FIGS. 2 and 3, so that to avoid repetition reference to these figures or their description is taken. The one DC electrode 3a is before the first in this embodiment Three-phase electrode 4 and the other direct current electrode 3b after the third three-phase electrode 6, each seen in the transport direction A of the carrier 2, arranged in the electrolyte bath 1. The carrier 2 passes through an electrolyte bath 1, which has the same consistency as the electrolyte baths according to the embodiments according to FIGS. 1 to 3. The DC electrode 3a is with the positive pole and the direct current electrode 3b with the negative pole DC power source 8 connected. Between the direct current electrode 3 a and the three-phase electrode 4 an insulation 14 is attached, also between the three-phase electrode 6 and the DC electrode 3b.

A fifth embodiment of the device is shown schematically in FIG. The carrier 2 first passes through the electrolyte bath 1 in the transport direction A, in which the surface of the Carrier 2 is electrochemically roughened and then an anodizing bath 13, in which the carrier 2 is anodized or oxidized electrochemically. In the electrolyte bath 1 are in Transport direction A of the carrier 2 in succession a direct current electrode 3 and three-phase electrodes 4, 5 and 6 arranged. The three-phase electrodes 4, 5 and 6 are in the same Way, as described above with reference to Figures 1 to 4, to the secondary windings a three-phase transformer 9 connected. The DC electrode 3 is with the Positive pole of a DC voltage source 8 connected. There are two in the anodizing bath 13 electrodes with current. The minus pole of the direct current source is with one Electric power supply, not shown, to the anodizing bath 13 connected. Between the direct current electrode 3 and the three-phase electrode 4 is one Insulation 14 arranged. Between the electrodes of the anodizing bath, not specified 13 there is also insulation 14.

The distribution and size of the direct current applied to the carrier 2 depends on the Condition of the support 2 and the electrolyte of the electrolyte bath 1.

The second to fifth embodiment of the device according to the invention do not require that Compared to the first embodiment, complex contacting of the moving carrier 2 for the case that the negative pole 7 of the DC power source 8, as in the first embodiment of the Device provided according to the invention, associated with the moving carrier must become.

In a further, sixth embodiment of the device according to the invention in advance Direct current applied to the carrier 2 before it is still under the influence of alternating current is coming. There are two AC current electrodes 10 and 11 in the electrolyte bath 1, that with a primary and a secondary winding U1 and U2 of an AC transformer 12 are connected. In the transport direction A of the carrier 2 through the electrolyte bath 1 a DC electrode 3 is arranged in front of the AC electrodes 10, 11, which is connected to the Positive pole of a direct current source 8 is connected. Between the DC electrode 3 and there is insulation 14 in the alternating current electrode 10. The negative pole 7 of the direct current source 8 is on a common connection 15 of the primary and secondary winding of the AC transformer 12 connected. The connection 15 of the two windings U1 and U2 is at an average potential, the voltage in each case in one winding of the Transformer is half as large as the applied AC voltage. To the ripple of the like to reduce the direct current obtained, inductors, resistors, capacitances in the Output side of the AC transformer 12 are placed, then the negative pole 7th the DC power source 8 with the point of the output side of the AC transformer 12 is connected, which is at the medium potential. With a three-phase transformer the potential of the center conductor of the three-phase transformer corresponds to the middle one Potential.

Accumulators such as batteries, galvanic elements, Unipolar machines. DC generators, on the other hand, generate pulsating direct current, whose ripple is relatively low. Such pulsating direct currents are in and for mixed currents that consist of direct currents on which an alternating current is superimposed. On Instead of a direct DC voltage, such can be the case with the devices according to the invention pulsating DC voltages act on the carrier 2, as shown in Figures 7a and 7b are shown schematically. The pulsating DC voltage according to FIG. 7a is concerned is a voltage at which only half of the AC voltage is pulsating DC voltage flows. Such a pulsating DC voltage becomes when there is a resistance load obtained in the rectifier circuit of a transformer circuit. The pulsating DC voltage according to FIG. 7b, which has a significantly lower ripple than the DC voltage 7a, is by a so-called center or two-way circuit preserved in a bridge or Graetz circuit. Another decrease in Ripple can be generated by generating pulsating DC voltage with a so-called Three-phase star connection or three-phase bridge circuit can be obtained. Through the Action of the pulsating DC voltage right at the start of the transport movement of the Carrier 2 is achieved that the surface of the carrier 2 by the DC components changed so far that the subsequent alternating current or three-phase effect at the beginning of the Carrier movement is kept so small that streaks are not or only very weakly develop distinctly.

The DC electrodes are designed so that their electrically effective width can be changed is. The distance of the direct current electrodes from the carrier on the one hand and from the alternating current electrodes on the other hand, it is also changeable, as is that on the direct current electrodes applied voltage.

Comparative example

An aluminum strip (purity ≥ 99.5% A1) is degreased and cleaned in a 5% sodium hydroxide solution at room temperature, then rinsed with water and in 1% hydrochloric acid with an alternating current of 50 Hz and a current density of 100 A / dm ² treated at a belt speed of 1m / sec. After passing through the roughening station, clearly visible, alternating light and dark stripes alternating at a distance of 2 cm can be observed transversely to the tape running direction.

example 1

An aluminum strip (purity ≥ 99.5% A1) is cleaned in accordance with the comparative example with 5% sodium hydroxide solution and then rinsed. Immediately before the roughening with alternating current, the tape in the hydrochloric acid described in the comparative example is first treated under a direct voltage electrode, which is connected to the positive pole of a direct current source, with a current density of 80 A / dm ² (corresponding to FIG. 6). Then, as described in the comparative example, roughening with an alternating current of frequency 50 Hz and a current density of 100 A / dm ² at a belt speed of 1 m / sec. After passing through the roughening station, a uniformly light-colored carrier is obtained which has no alternating light and dark stripes transverse to the direction of the belt run.

Example 2

An aluminum strip (purity ≥ 99.5% A1) is cleaned in accordance with the comparative example with 5% sodium hydroxide solution and then rinsed. Immediately before the roughening with alternating current, the tape in the hydrochloric acid described in the comparative example is first treated with a current density of 80 A / dm ² under a direct voltage electrode which is connected to the negative pole of a direct current source. Then, as described in the comparative example, roughening with an alternating current of frequency 50 Hz and a current density of 100 A / dm ² at a belt speed of 1 m / sec. After passing the roughening station, barely visible, alternating light and dark stripes can be observed transversely to the tape running direction.

Claims (19)

Method for roughening a support for radiation-sensitive layers, the Surface electrochemically or mechanically and then electrochemically in an aqueous electrolyte bath by applying a three-phase or alternating current to the Carrier opposite electrodes is roughened, the carrier continuously is passed through the electrolytic bath, characterized in that before the or at the beginning of the transport of the carrier past the three-phase or alternating current electrodes a DC voltage is additionally applied to the carrier. Method according to claim 1, characterized in that the negative pole is a DC source with the carrier and its positive pole with an opposite one of the carrier DC electrode is connected. Method according to claim 1, characterized in that the negative pole is a Direct current source with a direct current electrode opposite the carrier and the positive pole is connected to the carrier. A method according to claim 1, characterized in that the DC voltage on two DC electrodes are applied, one of which is in the direction of passage of the carrier in front of the three-phase electrodes and the other between the three-phase electrodes is arranged. A method according to claim 1, characterized in that the DC voltage on two Direct current electrodes are present, one of which is in the direction of passage of the carrier the three-phase electrodes and the other after the three-phase electrodes. A method according to claim 1, characterized in that the DC voltage on two DC electrodes is applied, which is in the direction of passage of the carrier in front of the Three-phase electrodes are arranged side by side, and that the two direct current electrodes be separated from each other by insulation. A method according to claim 1, characterized in that the carrier after the Passing through the aqueous electrolyte bath in an anodizing bath by means of electrical Current is anodized and that the DC voltage on a DC electrode, the is arranged in the direction of passage of the carrier in front of the three-phase electrodes and on a supply for electrical current to the anodizing bath. A method according to claim 1, characterized in that a DC voltage on a DC electrode and on a three-phase or alternating current transformer, that the DC electrode in the direction of passage of the carrier before the three-phase or Alternating current electrodes and is connected to the positive pole of the direct current source and that the negative pole of the direct current source to the middle phase of the three-phase transformer or to a center point of the alternating voltages of the two windings of the AC transformer is connected. A method according to claim 8, characterized in that the AC transformer is switched so that a connection of the primary winding and a connection of the Secondary winding have a common connection and that to this connection the negative pole of the DC power source is connected. A method according to claim 1, characterized in that the DC voltage is pulsed and that the positive half-waves of the pulsed DC voltage to the carrier be created. A method according to claim 10, characterized in that only a part of the positive Half waves of the pulsed DC voltage is applied to the carrier. Device for performing the method according to one or more of the claims 1 to 11, characterized in that three-phase electrodes (4,5,6,) in an electrolyte bath (1) are connected to the secondary side of a three-phase transformer (9), whose primary side via control transformers to a power transformer for Three-phase current is connected and that a direct current source (8) is present, the Poles with two direct current electrodes (3a, 3b) or with one direct current electrode (3) and the carrier (2), which runs past the three-phase and direct current electrodes, are connected. Apparatus according to claim 12, characterized in that the direct current electrode (3) in front of the first three-phase electrode (4) in the transport direction of the carrier (2) Electrolyte bath (1) arranged and connected to the positive pole of the direct current source (8) whose negative pole (7) is in contact with the carrier (2). Apparatus according to claim 12, characterized in that both direct current electrodes (3a, 3b) in front of the first three-phase electrode (4) in the transport direction of the carrier (2) are arranged and that there is insulation (14) between the two direct current electrodes (3a, 3b). Apparatus according to claim 12, characterized in that the one DC electrode (3a) in front of the first three-phase electrode (4) in the transport direction of the carrier (2) is arranged and that the other DC electrode (3b, 3b ') between the first and second three-phase electrodes (4, 5) and the second and third three-phase electrodes (5, 6). Apparatus according to claim 12, characterized in that the one DC electrode (3a) in front of the first three-phase electrode (4) and the other direct current electrode (3b) after the third three-phase electrode (6), each in the transport direction of the carrier (2) is arranged. Apparatus according to claim 12, characterized in that the one DC electrode (3) in front of the first three-phase electrode (4) in the transport direction of the carrier (2) arranged and connected to the positive pole of the direct current source (8), the Negative pole (7) to a supply for electrical current to an anodizing bath (13) connected. Device for carrying out the method according to one or more claims 1 to 11, characterized in that two AC electrodes (10, 11) in one Electrolyte bath (1) with a primary and a secondary winding (U1, U2) AC transformers (12) are connected and that a DC power source (8) with the positive pole to a direct current electrode (3) and with its negative pole to one common connection (15) of the primary and secondary winding is connected. Apparatus according to claim 18, characterized in that the direct current electrode (3) in the direction of transport of the carrier (2) in front of the AC electrodes (10, 11) is arranged.

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