EP1298232B1 - Process of repairing steel surfaces on flat and/or structured press plates or endless bands - Google Patents

Abstract

Process for improving smaller surface damage in large pressing plate or an endless strip made from sheet steel having structured surface comprises micro-galvanizing damaged surface using iron-containing electrolyte solution containing metal ions to form coating of iron, nickel and/or chromium ions. Mixing ratio of metal ions in solution is based on base material of pressing plate or endless strip. <??>An Independent claim is also included for a micro-galvanizing device for carrying out the above process. <??>Preferred Features: The electrolyte solution contains iron (II) (Fe<2+>) and iron (III) (Fe<3+>) in a ratio of 2: 1. The damaged surface is treated using an electrode. After structuring, a repair process is carried out involving etching and mechanical polishing. The damaged surface is nickel-plated before further treatment.

Description

The invention relates to a method for repair and / or repair of minor surface damage in a large format press plate or a Endless band made of sheet steel with a structured surface for surface embossing Holzwerkstoffen- or laminate panels, with the defective Surface is subjected to a microgalvanic treatment.

In the manufacture of furniture, such as kitchen furniture, be Structured surfaces needed, on the one hand a pleasing appearance and on the other hand are easy to treat. To this end are plastic-coated wood-based or laminate boards used, which receive an embossed structure on its surface, the Imprinting of such a structure by means of large-size press plates or endless tapes. For the reasons mentioned above are subject to the Press plates or endless belts therefore a very heavy duty and It can happen again and again that, for example, in the wood material or laminate hard inclusions are present, which the press plates or Slightly damage endless belts on their surface.

The finished press plates are installed in a pressing device, with which the plastic-coated furniture boards or the like are made. For this purpose, for example, circulating endless belts are used, which enable a continuous production, wherein pressed between the endless belts, the pressed material to plates and the surface is structured. For this purpose, the endless belts or press plates have the already mentioned surface structure which is impressed into the press laminate. Existing surface damage are so far impressed in the pressed material, if any, so that the manufactured possibly damaged plates can not be used to the full extent for further production. For this reason, it is particularly important that the press plates or endless belts used have absolutely flawless surfaces in order to keep the resulting blanks as small as possible. However, it can not always be avoided that minor surface damage occurs during the production of the press plates or endless belts or during use in the press shop, for example cracks; Impressions, voids or the like. The surface damage of this kind is usually very small with a damage area of 1 to 14 mm ² and can occur in the steel sheet itself, in the structured metal coating, in the hard chrome layer or optionally in all layers.

Such damage will be immediate in later pressing operations transferred the wood-based or laminate boards, so that the surface structure is faulty and, if appropriate, cut to size becomes visible in exposed position. To avoid a bigger one It is therefore necessary to avoid existing damages in the To repair pressing plates or endless belts. Because of the press plates for example, made of steel or brass sheet with a textured Surface consist of or coated with a copper or brass Steel plate, with the surface texture in the softer coating is incorporated, which is then provided with a hard chrome plating is a costly process required to eliminate the damage.

The process is used for large format press plates or endless belts applied to rework these surface defects or damaged areas, so that the relatively expensive press plates or endless belts continue can be used. For example, surface damage already exists arise in the structuring of the press plates or endless belts or during later work assignment. For this purpose, the press plates or Endless belts, if necessary, for reworking in the manufacturing plant returned. Preferably, these are press plates or endless bands of sheet steel or brass sheet, directly on have their surface structuring. The surface structuring is here according to the customer wishes from a variety of Patterns selected.

A remedy during the production of press plates or endless belts is either not possible or very time consuming and thus corresponding expensive. Is it damage in the not yet coated If necessary, a damage repair by Repeated or repeated etching done, but this will incur repair costs which are approximately equal to or higher than the new procurement costs Press plates or endless belts. Rich the existing damage to the Hard chromium layer or optionally in the steel layer, can be Although these improve, by the chrome layer and the steel layer over the entire surface is pickled completely and then the last surface newly coated with copper or brass and chrome plated, but this is Measure also very expensive and expensive.

To eliminate such damage, it is known for example from the paperback for electroplating, Volume 1, 1988, page 472, to connect an anode with a tampon, which is impregnated with electrolyte. The tampon is constantly supplied with fresh electrolyte and must constantly be moved intensively. However, smaller defect areas between about 1 and 14 mm ² can not be repaired or repaired properly with this method.

Furthermore, for the electrolytic metal deposition from DE 81 29 270 U1 a Hand tool known that is provided with a plastic fiber electrode, in anodized cuff made of platinum. The fiber electrode is soaked in electrolyte and rubbed on the damaged area. From the WO 900 40 52 A1 is also a hand-held device with a metal electrode known via a placed on the damaged area and impregnated with electrolyte Filter paper is rubbed. Both devices are used for tampon plating, in which the devices must be moved rubbing over the damaged area.

Furthermore, from German Patent DE 195 48 198 a method for After and / or repair of minor surface damage known, at each damaged area is framed by a mask, pickled and galvanized is coppered. The coppering takes place here mikrogalvanisch by each framed and embossed damaged spot of the cathodically connected Plated a galvanic copper solution and in this anodic immersed electrode tip is immersed. After filling the damaged area can this structured according to existing surface structure and other machining operations, such as a hard chrome plating, be subjected. However, it has proved to be disadvantageous that at repeated repair operations and in particular a removal of Hard chrome plating also washed out the copper-filled damaged areas and thus a further treatment of the already existing damage is required: Thus, over time, the Number of damaged areas and required after-treatment continuously and can therefore no longer be repaired economically.

EP 0 031 613 A1 discloses a method for producing embossing engraving on a metallic endless belt connected by a weld known. For this purpose, a covering is on the endless belt and the weld Galvanized metal layer before etching wherein the thickness of the metal layer is greater than the depth of the etching engraving. Special measures, for example to repair large-scale endless belts or press plates, however, are not removable from this document.

Object of the present invention is to provide a new method for after and / or Repair of surface damage show, in which a Repair of damaged areas with a longer service life is possible.

a) Eisen und Nickel oder

b) Eisen und Chrom oder

c) Eisen, Nickel und Chrom enthaltenen Elektrolytlösung erfolgt, welche ein Mischungsverhältnis der in Lösung befindlichen Metallionen aufweist, dass der Legierungszusammensetzung der Metalle des Basismaterials der Pressplatte oder des Endlosbandes entspricht.

According to the invention is provided to solve the problem that the use of a

a) iron and nickel or

b) iron and chromium or

c) electrolytic solution containing iron, nickel and chromium, which has a mixing ratio of the metal ions in solution, that corresponds to the alloy composition of the metals of the base material of the press plate or the endless belt.

Iron-containing electrolyte solutions, for example, have the advantage that no color deviations, compared to the non-defective sites arise and conventional chrome plating can be applied without the damaged area is washed out in subsequent chrome plating and thus becomes visible again. The provided for filling the damaged layer layer structure with iron-containing electrolyte solutions causes further increased resistance and thus a much longer life of the press plate or the endless belt. By the electrolyte or the electrolyte solution in this case an accumulation of iron, nickel and / or chromium metal ions caused, so that the existing damage by an addition of a mixture of iron, nickel and chromium are compensated and thus the method preferably in the Treatment of steel existing press plates or endless belts can be used. The mixing ratio of the metal ions present in the electrolyte solution is in each case matched to the base material of the press plate or the endless belt. Preferably, for the electrolyte solution di- and trivalent metal ions Fe ² , Fe ³ in the ratio 2: 1 are used.

The method according to the invention is therefore preferably suitable for filling damage on directly structured steel press plates or steel endless belts, according to the further processing operations different electrolytes under different boundary conditions can be used, for example, different degrees of hardness of Fill layer or protective layer can be reached. The procedure can also be For example, be used where already a replenishment with copper is carried out, namely, a nickel layer is applied for this purpose, followed by one of iron, chromium and / or nickel ions provided existing coating and subjected to a hard chrome plating becomes.

The best method for metal fillings on directly structured ribbons must deposit a medium-hard and, above all, chrome-plated layer, which can still be post-processed mechanically (hand structuring). For On the other hand, protective repairs on directly structured tapes must have a thin, soft and chrome-plated layer are deposited, if necessary still machinable. For finishing repairs on processing belts a thin and hard layer must be deposited while in case of protection repairs before a standard chrome plating also a thin and at the same time soft layer must be deposited, which is still mechanically workable.

For the attachment of iron, nickel, chromium compounds, a fixed electrode, for example a tamponate electrode, is used here up to a damage area of at most 30 mm ² . In this case, the repair process takes place after the end of the surface structuring, that is to say an etching carried out and optionally a mechanical polishing of the pressing plate or of the endless belt. A pretreatment of the defective surface can be carried out, for example, by a mechanical cleaning and purification by methanol, then a modified cleaning electrolyte with the aid of the microgalvanizing device is used for degreasing. Thereafter, a modified electrolyte is used for further pretreatment of the defective surface, which is used to activate steel or chrome surfaces. For degreasing, a potash and caustic soda solution in a mixing ratio of 1: 1 and a hydrogenbifluridhaltige solution used to activate. In the repair of already aufgekuppferten damage is then preferably a nickel electrolyte used to make a nickel coating, so that further workup can be done with a steel electrolyte and later in a hard chrome plating leads to no leaching. Depending on how the further treatment of the defective surface must be carried out, a selection of the electrolytes used can be made. In the case of a required post-structuring, it is possible, for example, to use a soft chrome electrolyte which is subjected to a subsequent after-treatment after the structuring has taken place.

In the event that a post - structuring is not required, may Treat the damaged surface with a modified hard chrome or Steel electrolyte can be used, wherein the modified hard chrome electrolyte sulphate-metansulphonic acid and a proportion of 290 ± 5 g / liter of chromic acid with 1.0 ± 0.1% sulfuric acid concentrate and the modified Steel electrolyte is ammonium fomiathaltig and from, for example, an 82% Iron solution, 13% chromium solution and a 5% nickel solution. The modified hard chrome electrolyte is an extended one Electrolyte consisting of chromic and sulfuric acid, the mixing ratio and, for example, 290 ± 5 g / liter of chromic acid and a sulfuric acid concentrate of 1.2 ± 0.1% is present. This composition is similar to that of a bright chrome electrolyte and can be used with others Current densities are used. As a modified steel electrolyte is not one storable and new to be added solution from an 82% Iron solution, 13% chromium solution and 5% nickel solution. ever after application, a deposition of about 20 to microns thick and about 47 to 60 HRC soft or hard steel-like filling or protective layer made, the one underlying the base material composition of iron, chromium and nickel. After the done The surface is partially restructured by hand to fill it up For example, make a hard chrome plating, wherein the press plate or the endless belt after post-structuring hard chrome plated over the entire surface and polished.

In an embodiment of the invention, it is provided that different electrolytes are used individually or in combination successively for the treatment of the defective surface. For example, a steel electrolyte may be used at a temperature of 47 to 50 ° C with a current density of 6 mA / mm ² . The steel electrolyte consists for example of 50 ml of iron solution, 5 ml of chromium solution and 2.5 ml of nickel solution. On the other hand, a sulfate-containing soft chromium electrolyte may be used at a temperature of 58 to 60 ° C and a current density of 0.3 mA / mm ² . Further, a sulfate-sulfonic acid hard chromium electrolyte may be used at a temperature of 70 to 73 ° C with a current density of 4 mA / mm ² , while an electrolyte used for filling the defective surface may be used, for example, with a current density between 1.5 to 4 mA / mm ^{2 is used} at a temperature of 47 to 50 ° C.

Due to the different electrolytes allows the invention Method a very simple and inexpensive partial post-treatment or Repair of minor surface damage in the press plates and Endless tapes, to the due to the electrolyte used with a Addition of iron, nickel and chromium leads to the mentioned advantages and also a repeated hard chrome plating according to known methods, For example, the Brunner method allows without the refilled Materials are washed out.

For the application of the method is also a Mikrogalvanisierungsvorrichtung suggested, with each defective surface through a mask is framed so that the electrolyte solution used the damaged area completely wetted, with a fixed electrode in the electrolyte solution dips and where a reversible rectifier is used, on the one hand via an electrode and on the other hand with a terminal with the Steel sheet is connected and wherein for carrying out the method the Electrode consists of a temponate electrode fixed in the Electrolyte immersed and the plate-shaped anode surface to the cathode surface Ratio 1: 0.9. The mask protects the undamaged Edge zones of the damaged areas before the galvanic solutions and limits the defective area to be filled. Here, the mask takes the used Electrolytes in sufficient quantity, which, for example, by a multilayer structure of the mask is guaranteed. Opposite so far become known method, the electrolytic treatment accordingly limited to the deposition process and after termination of the Procedure removes the remaining electrolyte and the formerly damaged site Rinsed by rinsing, so that the press plates or endless belts of further processing can be supplied. This can, for example, in a post-structuring or a hard chrome plating exist. The mask consists of a lower adhesive layer, directly on the Pressing plate or the endless belt is glued and one on the adhesive layer attached multilayer mask structure, so that the electrolyte in sufficient amount can be received. The prerequisite for this is that the material of the mask is temperature resistant, because the used Electrolytes are used at a temperature of 47 to 73 ° C. The actual mikrogalvanische treatment of the damaged places takes place in Dependence on the amperage and is limited in time, the duration of the Treatment is not determined by the amount of electrolyte, but the Electrolyte is available in sufficient quantity or optionally is refilled.

The micro-galvanic repair process allows the press plates and endless belts in an advantageous manner during their production in all processing states rectify or it may be in use damaged pressed sheets and endless belts subjected to a post-treatment become. A post-structuring always takes place according to the existing surface structuring, so that for a viewer the Damage after treatment are no longer recognizable and in particular by the use of adapted electrolytes also no color deviation is visible before and after the chrome plating.

The invention will be described hereinafter by the examples given below explained in more detail:

Example 1:

Reworking is a press plate or an endless belt with a directly structured and mechanically polished steel surface layer, with a defect depth> 25 μm due to etching defects, mechanical damage or material defects. The damaged area is first cleaned mechanically and deoxidized and cleaned with methanol and then pasted a multi-layer mask in the vicinity of the defect, which framing the damaged area, the overlap should be no more than 0.5 mm around. Subsequently, the mask is filled with a cleaning electrolyte and a Mikrogalvanisierungsvorrichtung attached, wherein a fixed tamponate electrode is immersed in the cleaning electrolyte, which is connected cathodically. At a current density of about 4 mA / mm ² at a voltage of 10 volts, the microplating apparatus is used for degreasing at room temperature for about 60 seconds. Thereafter, the remaining electrolyte is removed and the damaged area rinsed.

After rinsing, the damaged area is activated with another electrolyte, the activation electrolyte, for example a hydrogenbifluoride-containing activation solution, being filled into the existing mask. The activation is cathodic with a current density of 4 mA / mm ² and a voltage of 8 volts for 60 seconds at room temperature and then in the de-energized state for a period of 180 seconds at room temperature. After rinsing, nickel nickel electroplating takes place using the tamponate electrode used cathodically connected at a current density of 4 mA / mm ² and a voltage of 8 volts for a period of 45 seconds at room temperature. Here, the deposition of a layer thickness of about 0.4 microns. After completion of the nickel plating, the nickel electrolyte is removed without further rinsing.

A filling of the defect takes place after the attachment of a new mask with a steel-like electrolyte and a tamponate electrode at a distance of min. 3 mm to the metal surface, wherein a cathodic polarity occurs and at a current density of 4 mA / mm ² and a voltage of 10 volts, the current is slowly up-regulated in a period of 8 minutes. The filling takes place at an electrolyte temperature of 48-50 ° and causes a deposited layer thickness of about 25 microns. Subsequently, a rinsing of the damaged area takes place and a mechanical check, whether the metal filling is sufficient for a hand structuring to be applied. If the layer thickness is not yet sufficient, the last process steps must be repeated again until a sufficient layer thickness is available. If the depression is sufficiently filled with a steel coating, the electrolyte is dabbed, the mask removed and the filled-in damaged area thoroughly washed. This is followed by a hand structuring and mechanical polishing. The rectified press plate or endless belt is then hard chromium-plated in the usual manner over the entire surface, for example after the Brunner chrome plating process.

The new repair method is based on deposition of a 20-30 μm thick layer and about 47 HRC soft steel-like filler layer, resulting in anodic Polarity in the chrome bath after the Brunner chromium plating process similar to the Band steel behaves and in the subsequent chromium metallization optically give matching surfaces. The chemical composition of the steel electrolyte was set so tight that the metal deposition occurred a similar alloy composition as the steel strip in Form of iron, chromium and nickel possesses. The aforementioned repair method becomes after the end of the structuring, thus an etching and mechanical Polished, wherein the hardness of the steel filling layer is not affected can be. In a later necessary electrolytic dechroming In this case, the filling layer is not attacked, so that the press plate used or the endless belt can be chrome plated several times.

Example 2

Reworking is a press plate or an endless belt with a directly structured and mechanically polished steel surface layer, which are caused by etching defects, mechanical damage or material defects, with a previous filling with copper and a post-structuring by hand with subsequent polishing has taken place. The damaged area is first cleaned with methanol and then adhered to a multilayer mask according to Example 1. Subsequently, the mask is filled with a cleaning electrolyte and a Mikrogalvanisierungsvorrichtung attached, wherein a fixed tamponate electrode is immersed in the cleaning electrolyte, which is connected cathodically. At a current density of about 4 mA / mm ² and a voltage of 10 volts, the microplating apparatus is used for degreasing at room temperature for about 60 seconds. Thereafter, the remaining electrolyte is removed and the damaged area rinsed.

After rinsing, the damaged area is treated with another electrolyte according to Example 1 is activated. After rinsing, an under-nickeling also comes along a nickel electrolyte according to Example 1 instead.

A post-processing of the defect is done after attaching a new mask and a tamponate electrode at a distance of min. 3 mm to the metal surface, wherein a cathodic polarity occurs and at a current density of 6 mA / mm ² and a voltage of 10 volts, the current is slowly upshifted in a period of 10 seconds. The post-processing takes place at an electrolyte temperature of 48 - 50 ° and causes a deposited layer thickness of about 2.5 - 2.8 microns. Subsequently, a rinsing of the damaged area takes place and the steel tamponade is carefully polished with polishing paste. This is followed by a mechanical polishing. The rectified press plate or endless belt is then hard chromium-plated in the usual manner over the entire surface, for example after the Brunner chrome plating process.

The repair process is based on deposition of a 2.5 - 2.8 μm thick and about 47 HRC soft steel-like protective layer, resulting in anodic Polarity in the chrome bath after the Brunner chromium plating process similar to the Band steel behaves and in the subsequent chromium metallization optically give matching surfaces. The chemical composition of the steel electrolyte was set so tight that the metal deposition occurred a similar alloy composition as the steel strip in Form of iron, chromium and nickel possesses. The aforementioned repair method becomes after the end of the structuring, thus an etching and mechanical Polish, carried out using as filler copper substituted by steel can be. In a later necessary electrolytic dechroming In this case, the Füllschicht nicht.gripped, so that the press plate used or the endless belt can be chrome plated several times.

Example 3

a) Nach dem Spülen wird die mit Kupfer aufgefüllte Schadstelle mit einem weiteren Elektrolyten aktiviert, wobei der Aktivierungselektrolyt, beispielsweise eine hydrogenbifluoridhaltige Aktivierungslösung in die bestehende Maske gefüllt wird. Die Aktivierung erfolgt kathodisch mit einer Stromdichte von 4 mA/mm² für die Dauer von 60 Sekunden bei Raumtemperatur und anschließend im stromlosen Zustand für die Dauer von 180 Sekunden ebenfalls bei Raumtemperatur.

b) Nach dem Spülen wird die mit Stahl aufgefüllte Schadstelle mit einem weiteren Elektrolyten aktiviert, wobei der Aktivierungselektrolyt, beispielsweise eine hydrogenbifluoridhaltige Aktivierungslösung in die bestehende Maske gefüllt wird. Die Aktivierung erfolgt kathodisch mit einer Stromdichte von 3 mA/mm² für die Dauer von 60 Sekunden bei Raumtemperatur und anschließend im stromlosen Zustand für die Dauer von 180 Sekunden ebenfalls bei Raumtemperatur.

Reworking is a press plate or an endless belt with a directly structured and mechanically polished steel surface or in aufgekuppferten tapes, where a defect was caused by mechanical damage and they were already filled with copper or steel and textured by hand and matted and repaired before the gloss level , The damaged area is first cleaned with methanol and then adhered to a multilayer mask according to Example 1. Subsequently, the mask is filled with a cleaning electrolyte and a Mikrogalvanisierungsvorrichtung attached, wherein a fixed tamponate electrode is immersed in the cleaning electrolyte, which is connected cathodically. At a current density of about 4 mA / mm ² and a voltage of 8 volts, the microplating apparatus is used at room temperature for about 60 seconds. Thereafter, the remaining electrolyte is removed and the damaged area rinsed.

a) After rinsing, the patch filled with copper damaged spot is activated with another electrolyte, wherein the activation electrolyte, for example, a hydrogenbifluoride-containing activation solution is filled into the existing mask. The activation takes place cathodically with a current density of 4 mA / mm ² for 60 seconds at room temperature and then in the de-energized state for a period of 180 seconds also at room temperature.

b) After rinsing, the damaged area filled with steel is activated with a further electrolyte, wherein the activation electrolyte, for example a hydrogenbifluoride-containing activation solution, is filled into the existing mask. The activation takes place cathodically with a current density of 3 mA / mm ² for 60 seconds at room temperature and then in the de-energized state for a period of 180 seconds also at room temperature.

After rinsing, in cases a and b, an under-nickeling takes place Nickel electrolyte according to Example 1 instead. Here, the addition of a Layer thickness of about 0.5 microns. After completion of the sub-nickelation of the Nickel electrolyte removed without further rinsing takes place.

A post-processing of the defect is done after attaching a new mask and a tamponate electrode at a distance of min. 3 mm to the metal surface, wherein a cathodic polarity occurs and at a current density of 3 mA / mm ² and a voltage of 10 volts, the current is slowly up-regulated in a period of 80 seconds. The post-processing takes place at an electrolyte temperature of 70 - 73 ° and causes a deposited layer thickness of about 2.7 microns. Subsequently, a rinsing of the damaged area takes place and the deposited chromium is pre-polished by hand. A modified chromium electrolyte containing sulphate and methanesulphonic acid is used. The rectified press plate or endless strip is then polished to final gloss.

The new repair method is based on deposition of a 3 μm thin and about 60 HRC hard chrome layer. The deposited chrome (finish) can do so be polished, that a uniform chrome-colored repair site arises. The defects repaired by the new method are obvious longer lifespan, such as cobalt-finish repaired bands.

Example 4

Reworking is a press plate or an endless belt with a directly structured and mechanically polished surface layer, using as a substrate chromed, possibly unterkupferter steel strip. Structuring takes place directly in the steel or in the copper-plating, with etching defects, mechanical damage or material defects being present. The damaged area is first cleaned with methanol and then adhered to a multilayer mask according to Example 1. Subsequently, the mask is filled with a cleaning electrolyte and a Mikrogalvanisierungsvorrichtung attached, wherein a fixed tamponate electrode is immersed in the cleaning electrolyte, which is connected cathodically. At a current density of about 4 mA / mm ² , the microplating apparatus is used at room temperature for about 60 seconds. Thereafter, the remaining electrolyte is removed and the damaged area rinsed.

After rinsing, the damaged area is activated with another electrolyte, the activation electrolyte, for example a hydrogenbifluoride-containing activation solution, being filled into the existing mask. The activation is cathodic with a current density of 4 mA / mm ² and a voltage of 10 volts for 60 seconds at room temperature and then in the de-energized state for a period of 180 seconds at room temperature. After rinsing, an under-nickeling with a nickel electrolyte according to Example 1 takes place. Here, the deposition of a layer thickness of about 0.5 microns. After completion of the nickel plating, the nickel electrolyte is removed without further rinsing.

A post-processing of the defect is done after attaching a new mask and a tamponate electrode at a distance of min. 3 mm to the metal surface, wherein a cathodic polarity occurs and at a current density of 0.45 mA / mm ² at a voltage of 8 volts, the current flows in a period of 180 seconds. The post-processing takes place at an electrolyte temperature of 58 - 60 ° and causes a deposited layer thickness of about 1.7 microns. Subsequently, a rinsing of the damaged area takes place and a mechanical reworking of the transitions between the repair site and the steel layer. The rectified press plate or endless belt is then hard chromium-plated in the usual manner over the entire surface, for example after the Brunner chrome plating process.

The new repair method is based on the deposition of an approximately 2 μm thin and about 50 HRC soft steel-like protective layer using a sulphate-containing electrolytes.

The microplating apparatus used will be described below with reference to FIGS single figure explained in more detail.

Figure 1 shows a Microgalvanisierungsvorrichtung 1, which for repair a damaged area 2 on the surface of a press plate or an endless belt 3 caused by mechanical damage. The surface 4 the press plate or the endless belt 3 has a structure 5, which after Application of the Microgalvanisierungsvorrichtung 1 according to mechanical must be restructured. For this purpose, first a mask 6 immediately glued to the structure 5, and a second mask 7, for example twelve layers of tape (tape) attached. The mask 6 and 7 are here arranged around the damaged area 2 in so far, the only a small Overlap of about 0.5 mm is present. Due to the used It is electrolyte with an application temperature of up to 73 ° required that the masks 6, 7 are temperature resistant. The masks 6, 7 extend around the damaged area 2 and serve in the further to Recording of the electrolyte used 8, in which a plate-shaped Tamponatelektrode 9 is immersed. The tamponate electrode 9 and the pressing plate or the endless belt 3 are used to apply the method either switched cathodically or anodically.

List of reference numbers:

1.

Microgalvanisierungsvorrichtung

Second

damaged area

Third

endless belt

4th

surface

5th

structure

6th

mask

7th

mask

8th.

electrolytes

9th

Tamponatelektrode

Claims (22)

1. Method for improving and/or repairing minor surface damage in a large press plate or continuous strip of steel sheet having a structured surface for embossing the surface of wood-base material boards or laminate boards, the damaged surface being subjected to a microelectroplating treatment,
   characterized by the use of an electrolyte solution containing

   a) iron and nickel or

   b) iron and chromium or

   c) iron, nickel and chromium,

   which electrolyte solution has a mixing ratio of the metal ions present in the solution that corresponds to the alloy composition of the metals of the base material of the press plate or of the continuous strip.
2. Method according to Claim 1, characterized in that the electrolyte solution used contains divalent and trivalent metal ions Fe², Fe³ in the ratio 2:1.
3. Method according to Claim 1 or 2, characterized in that a damaged surface of not more than 30 mm² is treated using a fixed electrode, for example a pad electrode.
4. Method according to Claim 1, 2 or 3, characterized in that the repair method is carried out after the end of the structuring, i.e. an etching and optionally a mechanical polishing.
5. Method according to one or more of Claims 1 to 4, characterized in that mechanical cleaning and cleaning with methanol are effected for the pretreatment of the damaged surface.
6. Method according to one or more of Claims 1 to 5, characterized in that a modified cleaning electrolyte for degreasing or for activating steel or chromium surfaces is used for the pretreatment of the damaged surface, which cleaning electrolyte consists of potassium hydroxide and sodium hydroxide solution in the mixing ratio 1:1 for degreasing and of a hydrogen bifluoride-containing solution for activation.
7. Method according to one or more of Claims 1 to 6, characterized in that the damaged surface is nickel-plated before the further processing.
8. Method according to one or more of Claims 1 to 7, characterized in that a soft chromium electrolyte is used for the further treatment of the damaged surface in the case of restructuring.
9. Method according to one or more of Claims 1 to 8, characterized in that a modified hard chromium or steel electrolyte is used for the further treatment of the damaged surface without restructuring, the modified hard chromium electrolyte containing sulphate/methanesulphonic acid and having a proportion of 290 ± 5 g/litre of chromic acid with 1.0 ± 0.1 % sulphuric acid concentrate and the modified steel electrolyte containing ammonium formate and consisting of, for example, an 82% iron solution, 13% chromium solution and a 5% nickel solution.
10. Method according to one or more of Claims 1 to 9, characterized in that deposition of an approx. 20-30 µm thick and approx. 47 to 60 HRC soft or hard steel-like filling layer which has an iron, chromium and nickel composition on which the base material is based is effected.
11. Method according to Claim 8, characterized in that the surface in the damaged areas is partially restructured after filling.
12. Method according to one or more of Claims 1 to 11, characterized in that the press plate or the continuous strip is hard chromium-plated over the whole surface after the restructuring.
13. Method according to one or more of Claims 1 to 12, characterized in that different electrolytes are used individually or in combination in succession for the treatment of the damaged surface.
14. Method according to one or more of Claims 1 to 13, characterized in that a steel electrolyte is used at a temperature of 47° to 50° with a current density of 6 mA per mm², the steel electrolyte consisting of, for example, 50 ml of iron solution, 5 ml of chromium solution and 2.5 ml of nickel solution.
15. Method according to one or more of Claims 1 to 14, characterized in that a sulphate-containing soft chromium electrolyte is used at a temperature of 58° to 60° and a current density of 0.3 mA per mm².
16. Method according to one or more of Claims 1 to 15, characterized in that a hard chromium electrolyte containing sulphate/sulphonic acid is used at a temperature of 70° to 73° with a current density of 4 mA per mm².
17. Method according to one or more of Claims 1 to 16, characterized in that an electrolyte used for filling the damaged surface is used with a current density of between 1.5 and 4 mA per mm² at a temperature of 47° to 50°.
18. Microelectroplating apparatus for carrying out the method according to one or more of Claims 1 to 17, each damaged surface being framed by a mask so that the electrolyte solution used completely wets the damaged area, and a fixed electrode dipping into the electrolyte solution and a rectifier which can be subjected to pole reversal and which is connected on the one hand via an electrode and on the other hand by a terminal to the steel sheet being used, characterized in that the electrode consists of a pad electrode which dips in a fixed manner into the electrolyte, and the plate-like anode area has a ratio of 1:0.9 relative to the cathode area.
19. Microelectroplating apparatus according to Claim 18, characterized in that the mask takes up the electrolyte used in a sufficient amount and has a multilayer structure.
20. Microelectroplating apparatus according to Claim 18, characterized in that the mask consists of a lower adhesive layer which is fastened directly to the press plate or the continuous strip, and that a multilayer mask structure is mounted on the adhesive layer.
21. Microelectroplating apparatus according to Claim 18, characterized in that the material of the mask is thermally stable.
22. Microelectroplating apparatus according to Claim 18, characterized in that the microelectroplating treatment is carried out for a limited time depending on the intensity of the current, the duration of the treatment not being dependent on the amount of electrolyte.

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