EP0132549A1 - Process and apparatus for the continuous one-sided anodisation of aluminium strips, and their use in the manufacture of printing plates - Google Patents

Abstract

In the process for the continuous one-sided anodic oxidation of strips made of aluminum or one of its alloys, the direct current comes into play through at least one anode and one cathode arranged in an aqueous electrolyte. The anode (s) and cathode (s) act from opposite sides and at the same time electrochemically on the strip moving past them, which in particular is guided essentially horizontally past the essentially horizontally arranged electrodes. A device for carrying out such a method contains a) at least one treatment bath (2) which is filled with an aqueous electrolyte (3), b) at least one anode (5) each, which underneath and c) at least one cathode (4) each , which are arranged above the band to be treated (1) in the electrolyte. A tape treated in this way is preferably used as a carrier material in the production of offset printing plates bearing a radiation-sensitive layer.

Description

Process and device for the continuous one-sided anodic oxidation of aluminum strips and their use in the production of offset printing plates

The invention relates to a method and a device for the continuous one-sided anodic oxidation of aluminum or one of its alloys in strip form, which can be used in particular as a carrier material for offset printing plates.

Ribbon-shaped, roughened and anodized aluminum is required, for example, for the production of electrolytic capacitors, in construction, for packaging materials or in the production of carrier materials for offset printing plates. The band-shaped material is generally divided into smaller formats.

Carrier materials for offset printing plates are provided either by the consumer directly or by the manufacturer of pre-coated printing plates on one or both sides with a radiation (light) sensitive layer (reproduction layer), with the help of which a printing image of a template is generated by photomechanical means. After this printing form has been produced from the printing plate, the support carries the image areas which will guide the color during later printing and at the same time forms the hydrophilic image background for the lithographic printing process at the areas which are free of image (non-image areas) during later printing.

• - Die nach der Belichtung relativ löslicheren Teile der strahlungsempfindlichen Schicht müssen durch eine Entwicklung leicht zur Erzeugung der hydrophilen Nichtbildstellen rückstandsfrei vom Träger zu entfernen sein, ohne daß der Entwickler dabei in größerem Ausmaß das Trägermaterial angreift.
• - Der in den Nichtbildstellen freigelegte Träger muß eine große Affinität zu Wasser besitzen, d. h. stark hydrophil sein, um beim lithographischen Druckvorgang schnell und dauerhaft Wasser aufzunehmen und gegenüber der fetten Druckfarbe ausreichend abstoßend zu wirken.
• - Die Haftung der strahlungsempfindlichen Schicht vor bzw. der druckenden Teile der Schicht nach der Belichtung muß in einem ausreichenden Maß gegeben sein.
• - Das Trägermaterial soll eine gute mechanische Beständigkeit z. B. gegen Abrieb und eine gute chemische Resistenz, insbesondere gegenüber alkalischen Medien besitzen.

The following requirements must be met for a layer support for reproduction layers for the production of offset printing plates:

• - The parts of the radiation-sensitive layer which are relatively more soluble after exposure must be easy to remove from the support without residues by development in order to produce the hydrophilic non-image areas, without the developer attacking the support material to a greater extent.
• - The carrier exposed in the non-image areas must have a great affinity for water, ie be highly hydrophilic, in order to absorb water quickly and permanently during the lithographic printing process and to be sufficiently repellent to the bold printing ink.
• - The adhesion of the radiation-sensitive layer before or the printing parts of the layer after exposure must be sufficient.
• - The carrier material should have good mechanical resistance, for. B. against abrasion and good chemical resistance, especially against alkaline media.

Aluminum is used particularly frequently as the base material for such layer supports, which by known methods by dry brushing, wet brushing, sandblasting, chemical and / or electrochemical treatment is roughened superficially. To increase the abrasion resistance, electrochemically roughened substrates in particular are subjected to an anodization step to build up a thin oxide layer. These anodic oxidation processes are usually carried out in aqueous electrolytes containing H ₂ S0 ₄ , H ₃ P0 ₄₁ H ₂ C ₂ O ₄ , H ₃ BO ₃ , amidosulfonic acid, sulfosuccinic acid, sulfosalicylic acid or mixtures thereof. The oxide layers built up in these aqueous electrolytes or electrolyte mixtures differ in structure, layer thickness and resistance to chemicals. As already mentioned, such roughened and anodized materials also play a certain role in other technical fields. In the production of offset printing plate supports, in particular aqueous H ₂ S0 ₄ and / or H ₃ P0 ₄ solutions are used.

• 1 Die Schaltung des Aluminiumbandes als Anode wird durch eine Kontaktwalze (-rolle, -stange) bewirkt, die sich außerhalb des Anodisierelektrolyten befindet und die mit dem positiven Pol einer Gleichstromquelle verbunden ist; im Elektrolyten ist mindestens eine Kathode angeordnet, wobei das Aluminiumband auf der dieser Elektrode zugewandten Seite anodisch oxidiert wird (siehe auch Fig. 3 in der anliegenden Zeichnung).
• 2 Die Schaltung des Aluminiumbandes als Anode wird durch eine elektrolytgefüllte Kontaktzelle (Kontaktzone) bewirkt, in der sich mindestens eine Anode befindet. Das Band selbst wird dann als Mittelleiter in eine zweite elektrolytgefüllte Zelle (Zone) geführt, in der mindestens eine Kathode angeordnet ist (siehe auch Fig. 4 in der anliegenden Zeichnung). In verschiedenen Variationen dieser Anordnung kann die Reihenfolge der Zellen (Zonen) vertauscht werden und ist auch der Einsatz unterschiedlicher Elektrolyte möglich. Das Aluminiumband wird auf der der Kathode zugewandten Seite anodisch oxidiert.

The following devices and / or methods for the practical implementation of a continuous anodic oxidation of aluminum strips are known from the prior art, which can essentially be divided into two groups:

• 1 The switching of the aluminum strip as anode is effected by a contact roller (roller, rod) which is located outside the anodizing electrolyte and which is connected to the positive pole of a direct current source; At least one cathode is arranged in the electrolyte, with the aluminum strip on the side facing this electrode is anodized (see also FIG. 3 in the attached drawing).
• 2 The switching of the aluminum strip as an anode is effected by an electrolyte-filled contact cell (contact zone) in which there is at least one anode. The strip itself is then fed as a central conductor into a second electrolyte-filled cell (zone) in which at least one cathode is arranged (see also FIG. 4 in the attached drawing). The order of the cells (zones) can be interchanged in different variations of this arrangement and the use of different electrolytes is also possible. The aluminum strip is anodized on the side facing the cathode.

Both variants 1 and 2 are described for example in DE-A 16 21 115 (= US-A 3 632 486 and 3 766 043). Variant 1 or modifications thereof are also known from the following publications: DE-B 12 98 823 (= US-A 3 296 114) with contact electrode blocks outside the zone filled with electrolyte; DE-B 19 06 538 (= GB-A 1 260 505) with contact brush outside the anodizing chamber; DE-C 20 45 787 (= US-A 3 692 640) with contacting electrolyte current from a hollow cathode provided with openings, no direct statement being made about the type of anodic circuit; DE-C 22 34 424 (= US-A 3 871 982) or DE-A 26 19 821 each with a contact roller outside the anodizing chamber.

Variant 2 or modifications thereof are also known from the following publications: DE-B 14 96 714 (= US Pat. Nos. 3,471,375 and 3,359,189) with anode (s) in an electrolyte-filled contact and cleaning zone in front of the anodizing zone, which is also electrolyte-filled Cathode (s) and electrolyte flow against the strip direction; DE-A 21 56 677 (= US-A 3 718 547) with a similar arrangement, but additionally with a downstream electrolyte-filled contact zone with anode (s); DE-A 24 20 704 (= US-A 3 865 700) with the cells in reverse order, ie the anodizing cell with cathode is followed by the contact cell with anode; DE-B 25 07 063 (= US-A 4 226 680) or DE-C 25 34 028 (= US-A 3 959 090) with an anodic oxidation step and coloring step, the first step also having a contact zone with anode (s) and has an anodizing zone with cathode (s); DE-A 28 53 609 (= GB-A 2 012 305) with anode (s) in a contact zone and cathode (s) in an anodizing zone, a special arrangement of the connections on the cathodes being specified; EP-B 0 007 233 with anode in a contact cell filled with aqueous H ₃ PO ₄ solution and with cathode in an anodizing cell filled with aqueous H ₂ SO ₄ solution.

Variant 1 has the following disadvantages: the aluminum strip - despite previous treatment steps in solutions as a rule - must hit the contact roller as dry as possible, which means additional construction and energy costs for intermediate drying. In addition, when the tape is separated from the contact roller, arc discharges can take place which cover the surface of the Destroy the aluminum strip irreversibly and form defects in the subsequent anodic oxidation or even make the strip completely unusable. These disadvantages can have a particularly negative effect at the high working speeds of 300 m / min and more required in conjunction with the high current densities required for this. In variant 2, these disadvantages do not occur, but the use of a contact cell or contact zone means an additional extension of the anodic oxidation step to almost double, which is very uneconomical in view of the required working speeds and the long electrolyte baths which are inevitably associated therewith.

DE-A 29 17 383 (= US-A 4 214 961) describes a process for the continuous electrochemical vertical treatment (roughening or anodic oxidation) of aluminum strips. The aluminum strip is in each case guided vertically over deflection rollers and between separating devices within an electrolyte, these separating devices at least partially also being electrodes. According to FIG. 4, all separating devices can also be connected as electrodes; two adjacent separating devices are then always anodes or cathodes and thus effect a bilateral treatment of the aluminum surface. In this variant, this method cannot be used for one-sided treatment and is also not transferable to an essentially horizontal tape guide.

The object of the present invention is to find a method and a device for the continuous one-sided anodic oxidation of aluminum strips, which make it possible to get by with reasonable lengths of the electrolyte bath or the electrolyte baths in the actual anodizing zone, even at high strip speeds, without negatively influencing the strip surface .

The invention is based on a process for the continuous one-sided anodic oxidation of strips made of aluminum or one of its alloys in an aqueous electrolyte using direct current, which comes into effect through at least one anode and cathode arranged in the electrolyte. The method according to the invention is then characterized in that the anode (s) and the cathode (s) act from opposite sides and at the same time electrochemically on the strip moving past them. In preferred embodiments, the strip is guided essentially horizontally past the electrodes arranged essentially horizontally, the aqueous electrolyte contains sulfuric acid and / or phosphoric acid and mechanical, chemical and / or electrochemical roughening is carried out before the anodic oxidation. By "substantially horizontal" it is to be understood that angular deviations of up to 30 ° from the horizontal should also be included.

Another solution to the problem is one Device for the continuous one-sided anodic oxidation of strips of aluminum or one of its alloys using direct current containing a) at least one treatment bath which is filled with an aqueous electrolyte, b) at least one anode below and c) at least one cathode, which are arranged above the strip to be treated in the electrolyte. A device according to the invention can consist of only one treatment bath, but it can also have several such baths in a row, but each bath contains at least one of the specified pairs of electrodes; The baths can then be the same, but different aqueous electrolytes can also be present. The strip to be treated can be introduced and / or carried out in the bath or guided in the bath in a known manner via deflection rollers (rollers); However, other transport variants are also possible, for example the insertion and / or removal of the band into the bath through sealed slots or one of the other variants mentioned in the prior art described at the beginning.

In preferred embodiments of the device according to the invention, the width of an anode is smaller and the width of a cathode is greater than the width of the strip, and the length of an anode is greater than the length of a cathode. "Length" is to be understood as the extent of the respective electrode surface in the tape transport direction and "width" is the extent of the electrode surface perpendicular to the tape transport direction.

The band to be treated does not touch the electrode surface during the process, it is preferably closer to the anode than to the cathode. The terms "anode" or "cathode" or "electrode" are generally to be understood as an integral, electrically conductive body; However, arrangements are also possible in which the electrically conductive body consists of several partial bodies, so that several partial anodes connected to the same pole of a current source are then opposed, for example, in a treatment bath of a one-piece cathode. The relative dimensions in the above explanations then relate not only to one-piece electrodes, but also to an electrode consisting of several partial bodies. The aqueous electrolytes to be used are those known from the prior art (see also introduction to the description), ie in particular aqueous H ₂ SO ₄ or H ₃ PO ₄ solutions, but also oxalic acid, chromic acid etc., mixtures thereof or two or more baths with different electrolytes. The concentrations of acid are generally between 2 and 60% by weight, the temperature of the electrolyte between 5 and 60 ° C, the current densities of the direct current to be used or modifications thereof between 0.5 and 150 A / dm ² and the anodizing times between 5 and 240 sec. The layer weights of aluminum oxide range from 0.5 to 10 g / m ² , corresponding to a layer thickness of approximately 0.15 to 3.0 µm. The process according to the invention is preferably carried out so that the aqueous electrolyte is parallel to the surface of the treating tape is moved, for example at a speed of 5 to 100 cm / sec, in particular the direction of movement of the electrolyte is opposite to the tape transport direction.

Suitable base materials for the material to be oxidized according to the invention include those made of aluminum or one of its alloys, which have, for example, a content of more than 98.5% by weight of Al and proportions of Si, Fe, Ti, Cu and Zn. These aluminum strips are still, optionally after pre-cleaning, mechanical (e.g. by brushing and / or with abrasive treatments), chemical (e.g. by etching agents) and / or electrochemical (e.g. by AC treatment in aqueous HC1 -, HN0 ₃ - and / or in salt solutions) roughened. In the process according to the invention, tapes with electrochemical or a combination of mechanical and electrochemical roughening are used in particular.

In general, the process parameters for continuous process control in an electrochemical roughening stage are in the following ranges: the temperature of the electrolyte between 20 and 60 ° C., the active substance (acid, salt) concentration between 2 and 100 g / 1 (even higher for salts) , the current density between 15 and 250 A / dm ² , the residence time between 3 and 100 sec and the electrolyte flow rate on the surface of the workpiece to be treated between 5 and 100 cm / sec; change is usually the type of current Current used, but modified types of current such as alternating current with different amplitudes of the current strength for the anode and cathode current are possible. The average roughness depth R _{z of} the roughened surface is in the range from about 1 to 15 μm. The roughness depth is determined in accordance with DIN 4768 in the version from October 1970, the roughness depth R is then the arithmetic mean of the individual roughness depths of five adjacent individual measuring sections.

Pre-cleaning includes, for example, treatment with aqueous NaOH solution with or without degreasing agent and / or complexing agents, trichlorethylene, acetone, methanol or other commercially available aluminum stains. The roughening or, in the case of several roughening stages, also between the individual stages, an abrasive treatment can additionally be carried out, in particular a maximum of 2 g / m ^{2 being} removed (up to 5 g / m ² between the stages); In general, aqueous solutions of alkali metal hydroxide or aqueous solutions of alkaline salts or aqueous acid solutions based on HN0 ₃ , H ₂ SO ₄ or H ₃ PO ₄ are used as abrasive solutions. In addition to an abrasive treatment stage between the roughening stage and the anodic oxidation stage, non-electrochemical treatments are also known which only have a rinsing and / or cleaning effect and, for example, for removing deposits formed during roughening ("Schmant") or simply for Removal of electrical serve lytic residues; For example, dilute aqueous alkali hydroxide solutions or water are used for these purposes.

The stage of anodic oxidation of the aluminum strip can also be followed by one or more post-treatment stages. Aftertreatment is understood to mean in particular a hydrophilizing chemical or electrochemical treatment of the aluminum oxide layer, for example an immersion treatment of the strip in an aqueous polyvinylphosphonic acid solution according to DE-C 16 21 478 (= GB-A 1 230 447), an immersion treatment in an aqueous alkali silicate Solution according to DE-B 14 71 707 (= US-A 3 181 461) or an electrochemical treatment (anodization) in an aqueous alkali silicate solution according to DE-A 25 32 769 (= US-A 3 902 976). These post-treatment stages serve in particular to additionally increase the hydrophilicity of the aluminum oxide layer, which is already sufficient for many areas of application, the remaining known properties of this layer being at least retained.

The ribbons produced according to the invention are used in particular as carriers in the production of offset printing plates, ie a radiation-sensitive coating is applied to the carrier material on one or both sides either at the manufacturer of presensitized printing plates or directly from the consumer. In principle, all layers that are suitable for radiation (light) are suitable the irradiation (exposure), optionally with a subsequent development and / or fixation, provide an image-like area from which printing can take place.

In addition to the layers containing silver halides used in many fields, various others are also known, such as e.g. As described in "Light-Sensitive Systems" by Jaromir Kosar, John Wiley & Sons Verlag, New York 1965: the colloid layers containing chromates and dichromates (Kosar, Chapter 2); the layers containing unsaturated compounds in which these compounds are isomerized, rearranged, cyclized or crosslinked during exposure (Kosar, Chapter 4); the layers containing photopolymerizable compounds, in which monomers or prepolymers optionally polymerize during exposure by means of an initiator (Kosar, Chapter 5); and the layers containing o-diazo-quinones such as naphthoquinonediazides, p-diazo-quinones or diazonium salt condensates (Kosar, Chapter 7). Suitable layers also include the electrophotographic layers, i.e. H. those containing an inorganic or organic photoconductor. In addition to the light-sensitive substances, these layers can of course also other components such. B. contain resins, dyes or plasticizers. With regard to the types of radiation-sensitive layers that can preferably be used, reference is made, for example, to DE-A 28 11 396 (= US Pat. No. 4,211,619).

He with the tapes produced according to the invention Tested coated offset printing plates are converted into the desired printing form in a known manner by imagewise exposure or irradiation and washing out of the non-image areas with a developer, preferably an aqueous developer solution.

• Fig. 1 eine Seitenansicht einer Anodisiervorrichtung gemäß der Erfindung im Schnitt,
• Fig. 2 einen Querschnitt durch die Vorrichtung in Höhe der Linie I-I der Fig. 1,
• Fig. 3 eine Seitenansicht einer Anodisiervorrichtung nach dem Stand der Technik (Variante 1) im Schnitt, und
• Fig. 4 eine Seitenansicht einer Anodisiervorrichtung nach dem Stand der Technik (Variante 2) im Schnitt.

In the drawing, an embodiment of the device according to the invention is shown, which is compared with two embodiments from the prior art. It shows in

• 1 is a side view of an anodizing device according to the invention in section,
• 2 shows a cross section through the device at the level of line II of FIG. 1,
• Fig. 3 is a side view of an anodizing device according to the prior art (variant 1) in section, and
• Fig. 4 is a side view of an anodizing device according to the prior art (variant 2) in section.

The already roughened aluminum strip 1 (FIGS. 1 and 2) is introduced via a roller 7 into the treatment bath _2, which is filled with the aqueous electrolyte 3 (for example an 'aqueous H ₂ SO ₄ solution). Further changes in direction of the belt 1 are brought about by further rollers 7 and 8. The tape 1 is guided horizontally between the horizontally arranged electrodes 4, 5. The electrodes 4, 5 have the shape of a plate or one Grid on; the cathode 4 consists for example of lead, the anode 5 of aluminum or a titanium modified with noble metal or noble metal oxide.

In contrast to the device according to the invention, variant 1 of the prior art (FIG. 3) has the anode 6 outside the aqueous electrolyte and has the shape of a roller, rod or roller. In variant 2 of the prior art (FIG. 4), the anode 5 'is in a first treatment bath 2' and the cathode 4 'in a second treatment bath 2 ", which are filled with the same or different aqueous electrolytes 3', 3" are.

The advantages of the method and the device according to the invention are therefore not only that the disadvantages of the anode arranged outside the aqueous electrolyte do not work, but in particular that a large space and investment cost requirement for the second electrolyte bath (s) is saved. It is particularly surprising that this last-mentioned advantage does not come at the expense of the surface quality, especially since the prior art clearly only deals with and refers to variants 1 and 2.

In the following examples, parts by weight relate to parts by volume such as kg to dm ³ , percentages relate to the weight.

example 1

An electrochemically roughened aluminum strip with a width of 650 mm is anodized as follows. An aluminum plate with the dimensions 6000 mm x 500 mm x 0.5 mm (length x width x height) serves as the anode on the underside of the strip, which is coated with gauze with a mesh width of 0.2 mm to protect against contact by the moving strip is. The distance between the strip and the anode is 5 mm. Several smaller lead cathodes with the total dimensions of 3000 mm x 1000 mm x 100 mm are arranged above the belt at a distance of 50 mm. A 20% aqueous _H2 S0 ₄ solution containing 1% of aluminum sulfate is used as the electrolyte, the temperature is 40 ° C., the anodizing time is 20 seconds and the current density is 10 A / dm ² (voltage 30 V). The oxide layer weight is 1.5 g _{/ m} 2.

After rinsing with water and drying, the belt is provided with the following positive-working light-sensitive layer:

The layer weight is about 2 g / m ² . To produce the printing form, test pieces are exposed in a known manner and developed with an aqueous alkaline solution. From such a printing form, approximately 150,000 to 200,000 prints can be produced in practical quality.

Example 2

In order to simulate the continuous process under various conditions, a grid anode (120 mm x 80 mm) made of platinum-coated titanium and a lead sheet cathode (100 mm x 100 mm) are placed in a container filled with the electrolyte according to Example 1 Arranged 80 mm apart. An aluminum sheet is dipped between the anode and cathode, which is 90 mm wide and is closer to the anode than to the cathode. At a current density of 15 A / dm ² (voltage 14 V) and a temperature of 50 ° C, anodizing is carried out for 60 seconds. The ^{weight of the} oxide layer is ^{3.6 g} / _m2 .

Example 3

The procedure of Example 2 is followed, but a titanium lattice coated with activated noble metal oxide (Ru0 ₂ ) is used as the anode. The results correspond to those of Example 2.

Example 4

The procedure is as described in Example 2, but a solid aluminum sheet is used as the anode, the voltage increases from 14 to 26 V. The results correspond to those of Example 2.

Example 5

The procedure is as described in Example 2, but a 10% aqueous H ₃ PO ₄ solution is used as the electrolyte at 55 ° C., a current density of 10 A / dm ² (voltage 30 V). The results correspond to those of Example 2.

Claims (8)

1 method for continuous one-sided anodic oxidation of strips of aluminum or one of its alloys in an aqueous electrolyte using direct current, which comes into effect by at least one anode and cathode arranged in the electrolyte, characterized in that the anode (s) and cathode (n) from opposite sides and at the same time act electrochemically on the tape moving past them. 2 The method according to claim 1, characterized in that the band is guided substantially horizontally past the substantially horizontally arranged electrodes. 3 The method according to claim 1 or 2, characterized in that the aqueous electrolyte contains sulfuric acid and / or phosphoric acid. 4 The method according to any one of claims 1 to 3, characterized in that a mechanical, chemical and / or electrochemical roughening is carried out before the anodic oxidation. 5 Device for the continuous one-sided anodic oxidation of strips made of aluminum or one its alloys using direct current, containing a) at least one treatment bath (2) which is filled with an aqueous electrolyte (3), b) at least one anode (5) each, which below and c) at least one cathode (4) , which are arranged above the band to be treated (1) in the electrolyte. 6 Apparatus according to claim 5, characterized in that the width of an anode (5) is smaller and the width of a cathode (4) is greater than the width of the strip (1). 7 Device according to claim 5 or 6, characterized in that the length of an anode (5) is greater than the length of a cathode (4). 8 Use of an anodized tape according to claim 1 to 7 as a carrier material in the production of a radiation-sensitive layer bearing offset printing plates.

Images