PL204301B1 - Pretreatment process for coating of aluminium materials - Google Patents

Abstract

The invention relates to a method for applying electro-deposited metal coatings (3) upon aluminium or aluminium alloy components (1). According to said method, the surface (4) of the component is cleaned in an appropriate solution, in particular a solution of oils, fats, emulsions, pigments, etc. Said surface (4 ) is then etched in an appropriate solution, such that a certain quantity of material or near-surface alloy constituents is dissolved. After cleaning and dissolution, water rinsing is carried out. Immediately after the dissolution of the near-surface regions, the surface (4) of said component (1) is activated in a solution, containing iron ions, with a sulphate base by the anodic coupling of said component (1). The functional layer (3) is then applied by the cathodic coupling of said component (1), without intermediate rinsing, in the same electrolyte or in a similar or equivalent electrolyte, said functional layer (3) being made of iron (5).

Description

Description of the invention

A method of applying iron layers electroplated on structural elements made of aluminum or aluminum alloy, in which the surface of the structural element is cleaned in a suitable solution, especially from oils, fats, emulsions, pigments and the like, and then the surface is etched in a suitable solution such that certain amounts of the material or components of the alloy that are near the surface are dissolved and that after cleaning and dissolving, there is a rinsing with water.

In order to protect components that are exposed to high loads and / or high wear, these components may be subjected to various measures. Countermeasures for increasing wear resistance include fusing, tempering and coating. In particular, the deposition of coatings plays a significant role in the case of materials containing aluminum and its alloys, as there may be positive characteristics of these coated materials in combination systems.

In engines and in particular tribological systems, the production of both components from aluminum has long been standardized as engine manufacturers aim to reduce the weight of the components. If the piston and cylinder liner were made of aluminum or aluminum alloys, the tribological system could fail and seizure phenomena could occur on the contact surfaces. In order to prevent these galling phenomena and in order to increase the wear resistance of the friction pairs, it has been state of the art for many years to coat aluminum pistons with coatings.

The problem that arises when applying coatings to aluminum is the chemically very stable and naturally formed oxide layer on the aluminum surface. In order to improve the adhesion of coatings applied to aluminum, or to make it only possible, the oxide layer must be broken off and removed. In order that the oxide layer does not re-build after it has been removed and before the subsequent coating, it is customary to apply an intermediate layer to the aluminum surface, which then enables the deposition of so-called functional layers. The functional layer can be made of, for example, iron and increases the wear resistance among others.

DE 19 15 762 discloses a method of applying electroplated metal coatings to structural elements made of aluminum or aluminum alloys. The surface of the material is then cleaned, then activated and provided with an adhesive intermediate layer and immediately afterwards plated with a coating material, in which case the coating would be the functional layer. Intermediate layers used here can be made of zinc, nickel, tin or copper. After the cleaning and activation process, the parts to be metallized are immersed in a solution consisting of hydrochloric acid, cupric chloride and metallic copper powder until an interlayer of monovalent copper is formed on the aluminum surface in this bath.

A disadvantage of this method is the high aggressiveness of the chloride electrolytes, the use of this method is also costly and involves high outlays, for example in terms of work safety.

The refinement of the zinc-based interlayer is described in the article by Peter Volk and Dr. Karl Brunn, "Fortschritte in der Zinkatbehandlung von Aluminum" in JOT, Jahrgang 04/2001. The article describes the zinc treatment of aluminum as an important step in the development of the pre-treatment of metal or metal alloy coatings on aluminum. The article points out that the methods of direct plating with copper, direct plating with nickel and direct plating with chromium have limitations in the process and cannot be used as a stable process in industrial series production. More specifically, it is generally recommended to perform a pretreatment on the aluminum surface in which the surface is activated and the natural aluminum oxide layer is removed. Immediately thereafter, a thin conductive intermediate layer is deposited which inhibits the re-oxidation of the surface during insertion into the coating bath and causes good coating adhesion (functional layer). The improvement of the method is directed to replacing the cyanide zinc etching by cyanide etching. This is done by using organic nickel and copper complexing additives instead of cyanide and iron. A special complexing additive system has been developed for etching with cyanide-free zinc. The metal ions are thoroughly complexed in such a way that the additive results in a uniform and controlled deposition having excellent adhesion. At the same time, the complexing additive allows a rapid ion exchange and ensures a rapid formation of the layer. It is not apparent from the article whether an intermediate layer can be dispensed with entirely for the deposition of a functional layer, which is described below with the example of a nickel layer. It is also impossible to find out from the article whether it is possible to directly deposit iron layers on the aluminum surface.

The object of the invention is to provide such a method for applying a coating to an aluminum-based material, an aluminum alloy or a multilayer material based on an aluminum material, that when a sulfate-based solution is used, a metallic or oxide intermediate layer on the aluminum surface is dispensed with as a base for the deposition of the layer. functional and thus the method of applying the coating is significantly accelerated and at the same time the costs of its production are minimized.

The idea according to the invention achieves the formulated aim by the fact that in the method of applying iron layers electroplated on aluminum alloy structural elements, in which the surface of the structural element is cleaned in a suitable solution, in particular from oils, fats, emulsions, pigments and the like , and then the surface is etched in a suitable solution, so that certain amounts of material or alloy components that are near the surface dissolve and without intermediate rinsing in the same electrolyte the functional layer is applied by including the structural element in The cathodic junction system according to the invention is activated in a sulphate-based solution containing 5 to 500 g / l of ferrous sulphate heptahydrate at a pH value of 0.5 to 2.5.

Due to the method according to the invention and the sequence of processes used, it is achieved that the number of process steps which are required hitherto in the art can be substantially minimized.

Until today, it has been common knowledge to remove the natural oxide layer on aluminum and to deposit the reoxidation layer on the aluminum, so that this intermediate step or the intermediate layer formed in it could now be completely dispensed with.

The structural elements are cleaned and freed from harmful fats, oils, emulsions, pigments or similar contaminants in the production process. After cleaning, it is thoroughly rinsed with water. Immediately thereafter, the surface of the structural elements is etched in a suitable solution, i.e. some amounts of aluminum or alloy components near the surface are dissolved. The component is then thoroughly rinsed in the water again.

Now, according to the invention, no intermediate layer is deposited, but the component is inserted directly into the sulfate-based electrolyte. Commonly used electrolytes work with chloride, fluoroborate, or ammonium sulfate. Chloride electrolytes, as described above, have a high aggressiveness, electrolytes based on fluoroborate are highly aggressive and toxic, and electrolytes based on ammonium sulphate have poor compatibility with the components of the waste water.

The invention preferably takes as its starting point a sulfate-based electrolyte which is neither aggressive nor toxic nor harmful as an effluent. According to the invention, the surface is first activated in the electrolyte by integrating the component into the anodic connection system. Activation takes place, for example, in a solution with the following parameters: at a temperature of 70 ° C in a solution containing 300 g / l of ferrous sulphate heptahydrate (FeSO4 * 7H2O) with a pH value of 2, with an activation current density of 2 A / dm ² and during processing for 20 seconds.

According to the invention, the functional layer is then applied to the component without intermediate rinsing by integrating the component into the cathodic connection system by means of a sulphate-based iron electrolyte. This can occur in a similar as well as in an equivalent electrolyte.

In example 1, a very hard material ranging in size from 0.5 to 2.0 µm is added to the electrolyte of a solution containing 300 g / l of ferrous sulfate heptahydrate (FeSO ₄ * 7H ₂ O) having a pH value of 2. As very hard materials, for example, aluminum oxide, silicon nitride, chromium nitride, titanium carbide, cubic bromine nitride and diamond particles can be used. The invention relates not only to these very hard materials mentioned, but includes all hard materials containing oxides or ceramics made of pure oxides, carbides and nitrides.

PL 204 301 B1

These very hard materials can in particular be used individually, but also as mixtures or mixtures.

Under the conditions according to the invention, an iron layer is formed which contains about 15% by weight of very hard materials that are comminuted. The deposited functional layer has excellent wear resistance and has a hardness of about 400 HV 0.05.

In another example 2, to the electrolyte, a solution containing 300 g / L of ferrous sulfate heptahydrate (FeSO4 * 7H2O) having a pH value of 2, solid lubricants ranging in size from 0.5 to

2.0 μm. Possible solid lubricants are: hexagonal boron nitride, carbon fluoride, graphite, molybdenum sulphate, Teflon, steel particles or oil-filled microcapsules. These solid lubricants can be used individually, but also as a mixture or mixtures.

Studies have shown that solid lubricants have an extremely favorable effect on the tribological system and that more favorable values of the friction coefficients are obtained. A functional layer is formed in which the solid lubricants are ground with a content of about 20% by volume.

In another embodiment of the invention, mentioned here as example 3, the electrolyte contains grease and very hard materials together according to example 1 and 2 so that the favorable properties of both materials can be combined.

Under these conditions, an iron layer or a functional layer is deposited in which both materials exist in a finely divided form. The hardness of this layer is 350 HV 0.05.

In a series of tests for example 4, a proportion of 5 ml / l of hypophosphorous acid, for example H3PO2, was added to the sulfate electrolyte of the invention containing 300 g / l of ferrous sulfate heptahydrate (FeSO4 * 7H2O) with a value of pH 2. The functional layer formed according to the invention has a hardness of 700 HV 0.05. The hardness of the layer can be influenced in an intended manner by the phosphorus content of the electrolyte.

In example 5, to the phosphorus-containing electrolyte of example 4, a very hard material according to example 1 was added, ie a very hard material ranging in size from 0.5 to 2.0 µm. As very hard materials, for example, aluminum oxide, silicon nitride, chromium nitride, titanium carbide, cubic bromine nitride and diamond particles can be used. The invention relates not only to these very hard materials mentioned, but includes all hard materials containing oxides or ceramics made of pure oxides, carbides and nitrides. The hardness of the produced layer was 750 HV 0.05, which means that the hardness could increase further. The wear tests gave similar values as in example 1.

In embodiment 6 according to the invention, the solid lubricant according to example 2 was added to the phosphorus-containing electrolyte of example 4, i.e. among the solid lubricants having a particle size of 0.5 to 2.0 µm. Possible solid lubricants are: hexagonal boron nitride, carbon fluoride, graphite, molybdenum sulphate, Teflon, steel particles or oil-filled microcapsules. These solid lubricants can be used individually, but also as a mixture or mixtures. Under these conditions, a functional layer was deposited as an iron layer, which in the particulate form contained approximately 20% by volume of solid lubricants.

The hardness of this layer was 650 HV 0.05. The results of the friction coefficient tests were better than in the layers without phosphorus content. However, the wear test results were comparable.

In a series of tests up to Example 7, mixtures of solid lubricants and very hard materials were added to the phosphorus-containing electrolyte according to Examples 5 and 6, respectively. Thereafter, a functional layer was formed which contained these material mixtures in particulate form. The hardness of this layer was 700 HV 0.05. The values of the friction and wear coefficients were comparable to those obtained in Example 4.

The applied functional layers were characterized by an excellent connection with the basic material of the structural element. The functional layer applied in accordance with the examples of the invention, as an iron layer, during the adhesion test under extreme conditions, such as, for example, thermal shock, blasting of glass spheres and during the spray test, showed an excellent bond with the base material and was comparable to the functional layers which were applied using a zinc-copper-based intermediate coat and even surpassed them in partial areas.

By means of the method according to the invention and the sequence of processes resulting therefrom, it is possible that the number of usually necessary process steps is substantially minimized, the quality of the products to be coated is improved, the manufacturing costs are reduced and environmental resources are protected.

PL 204 301 B1

These advantages make it possible to coat products in a wide variety of applications also in market segments which until now could not be served due to costs.

The subject of the invention in an exemplary embodiment is illustrated in the drawing, in which Fig. 1 shows a cross section of the surface of a construction element coated according to example 3 in the description.

1 shows a section of a component 1 covered with a coating according to the invention. The figure shows the base material 2 with the functional layer 3 applied thereon. In the activation phase, the natural oxide layer was removed from the base material 2 and the components near the surface dissolved so that the clean surface 4 was ready for the coating. On this clean surface 4, by means of an electrolyte, a functional layer 3 has been directly deposited without an intermediate layer. According to example 3, the functional layer 3 is made, in particular, of iron 5; it contains shredded very hard materials 6 and solid lubricants 7.

Claims (11)

1. A method of applying iron layers, electroplated on structural elements made of aluminum alloy, in which the surface of the structural element is cleaned in an appropriate solution, in particular from oils, fats, emulsions, pigments - and the like, then the surface is etched in an appropriate solution, so that certain amounts of the material or alloy components that are near the surface are dissolved and, after cleaning and dissolving, they are rinsed in water, and then the surface of the structural element is activated in a solution containing iron ions immediately after dissolution of the areas near the surface. incorporation of the structural element into the anodic connection system and without inter-rinsing, the functional layer is applied in the same electrolyte by incorporating the structural element into the cathodic connection system, characterized in that the activation is carried out in a sulphate-based solution containing from 50 to 500 g / l of ferrous sulphate heptahydrate, at a pH value of 0.5 - 2.5. 2. The method according to p. A method as claimed in claim 1, characterized in that the activation of the component (1) is carried out in the solution with a duration of immersion in the electrolyte from 5 seconds to 5 minutes. 3. The method according to p. A method as claimed in claim 1 or 2, characterized in that the surface activation (4) and the functional layer (3) coating of the component (1) are performed at a direct current density of 2 to 20 A / dm ² . 4. The method according to p. The process of claim 3, characterized in that the activation is carried out in a solution at a temperature ranging from 20 ° C to 95 ° C. 5. The method according to p. 4. The method of claim 4, characterized in that at least one very hard material (6) with a particle size of about 0.2 to 5 μm is added to the electrolyte, whereby aluminum oxide, silicon nitride, chromium nitride are used as the very hard material (6). , titanium carbide, cubic boron nitride as well as diamond particles. 6. The method according to p. 4, characterized in that at least one solid lubricant (7) is added to the electrolyte, such as hexagonal boron nitride, carbon fluoride, graphite, molybdenum sulfate, Teflon, but also microcapsules filled with oil, with the solid lubricant particles having a size of about 0, 2 to 5 μm. 7. The method according to p. The method of claim 4, characterized in that at least one very hard material (6) and / or at least one solid lubricant (7) are added to the electrolyte, the particles of the very hard material (6) having a size of about 0.2 to 5 μm. , and as a very hard material, aluminum oxide, silicon nitride, titanium carbide, cubic bromine nitride and diamond particles are provided, and as a solid lubricant (7) are provided: hexagonal boron nitride, carbon fluoride, graphite, molybdenum sulfate, Teflon, but also oil-filled microcapsules and that the lubricant particles are about 0.2 to 5 µm in size. 8. The method according to p. The method according to claim 4, characterized in that hypophosphorous acid is added to the electrolyte in an amount of 0.25 to 5 ml / l, preferably as H3PO2, preferably as 50% H3PO2. 9. The method according to p. 8. A method according to claim 8, characterized in that at least one very hard material (6) with a particle size of about 0.2 to 5 μm is added to the electrolyte, being very hard In the material (6), aluminum oxide, silicon nitride, titanium carbide, cubic boron nitride and diamond particles are used. 10. The method according to p. 8. The method according to claim 8, characterized in that at least one solid lubricant (7) with a particle size of about 0.2 to 5 μm is added to the electrolyte, whereby hexagonal boron nitride, carbon fluoride, graphite are used as the solid lubricant (7), molybdenum sulphate, Teflon, but also oil-filled microcapsules. 11. The method according to p. The method of claim 8, characterized in that at least one very hard material (6) and at least one solid lubricant (7) are added to the electrolyte, the particles of the very hard material (6) having a size of about 0.2 to 5 μm, and aluminum oxide, silicon nitride, titanium carbide, cubic bromine nitride and diamond particles are provided as very hard materials, whereby hexagonal boron nitride, carbon fluoride, graphite, molybdenum sulphate, Teflon, but also microcapsules are provided as solid lubricant (7) filled with oil and that the lubricant particles are about 0.2 to 5 µm in size.