DE19924687A1 - Protecting light metals and their alloys from corrosion damage, especially for use in the vehicle construction industry - Google Patents

Abstract

The present invention relates to a corrosion-resistant light metal layer system that a substrate made of a light metal, such as. As aluminum, titanium or magnesium, on which a protective layer is applied, in which microparticles are incorporated which contain a liquid active ingredient, the active ingredient being distributed over the surface of damage in the layer system when released and thus this surface from the outside Protects influences.

Description

The invention relates to a layer system for the corrosion protection of metallic Surfaces, especially those made of light metals and light metal alloys. The layer system according to the invention can advantageously in the Korro protection of metallic components used in the automotive industry become.

Corrosion protection of metals is an extremely important topic for metall working industry in general and especially for the motor vehicle Industry. The standards for the automotive industry place high demands changes in the durability of vehicles and vehicle parts in relation to Corrosion and pitting.

Light metals such as aluminum and magnesium and their alloys can be found in industry and automotive use. The disadvantage is that these materials due to their negative electrochemical potential are very susceptible to corrosion. Different methods were therefore developed wraps to protect these metals from corrosion.

For example, light metal sheets with conversion layers based on chromate were used see that in connection with KTL (cathaphoretic dip painting) - or Powder coatings work. These conversion layers are especially for the Visible area used, i.e. for surfaces that are visible to an observer are. However, if there is mechanical damage to the protective layer The base material is the underlying substrate made of light metal unprotected and exposed to corrosive influences.

As corrosion protection for steel sheets, EP 0 323 756 A1 proposes to galvanically deposit a protective layer of zinc or a zinc alloy on these steel sheets, this protective layer containing corrosion-preventing solid particles which are coated with a thin coating of, for example, SiO ₂ , Al ₂ O ₃ , ZrO ₂ or TiO _{2 are} encapsulated. Chromates, aluminum compounds, phosphates, molybdenum compounds and titanium compounds are used as corrosion-preventing solid particles.

However, due to their surface potential, such connections can only be insufficiently deposited galvanically on steel sheets. Therefore, according to the European patent application, these particles are coated with a material such as e.g. B. SiO ₂ , Al ₂ O ₃ , ZrO ₂ or TiO ₂ encapsulated, this material being used to control the surface potential of the corrosion-inhibiting particles and to support their galvanic deposition on a steel sheet. It is further described that the encapsulation increases the resistance to pitting, since the corrosion-preventing ions can diffuse through the capsule material only slowly, and so a continuous and uniform release takes place over a longer period of time.

According to the invention, corrosion protection is to be made available with the mechanical damage to the surfaces of light metal components can be securely sealed and protected against corrosive influences.

The invention is therefore based on the object of a light metal substrate mechanical damage to the workpiece in a self-healing manner protect against corrosion.

This task is accomplished through a corrosion-resistant light metal layer system solved, which contains a substrate made of a light metal and at least a protective layer is applied to a surface of the light metal substrate, wherein the protective layer has microparticles that have a liquid active ingredient contain.

According to the invention it was recognized that the surface of light metals Corrosion can be protected by placing a metal matrix on the surface  is applied, which contains microcapsules. These microcapsules are made from a polymer shell with an active ingredient contained therein. In the case of a me mechanical damage to the layer, the microcapsules are destroyed and release the active ingredient contained therein, which penetrates the damaged area Formation of a layer against external influences and thus against corrosion protects.

Substances are used as the active ingredient after the microcapsules have been destroyed and release protect the damaged area from external influences by they form a protective layer on it. Examples of this are lacquers and inhi bitters. The active ingredients must be sufficiently thin to be quick and to be able to spread it safely over the damaged area and there the To be able to form a protective layer.

Preferred active ingredients are liquid paints. Examples include alkyd resins long-chain unsaturated fatty acids that cure only through air oxidation can, and a two-component epoxy resin by the addition of Amine compounds can cure, the two components through the Microencapsulation is present separately in the layer.

Any polymer can be used as the capsule shell, which with the Matrix material is compatible and together with the matrix layer material can be applied to the substrate. The polymer can be a plastic. A preferred capsule material is e.g. B. a melamine formaldehyde resin. The capsules can have a diameter in a range from 0.5 to 7 µm.

The production of the microcapsules is generally known and can be carried out using conventional methods Encapsulation techniques are done.

In principle, all are de-energized or gal as materials for the protective layer Metals that can be deposited vanically on the relevant light metal substrate special copper, nickel and titanium and their alloys, nickel and Nickel alloys are particularly preferred.  

According to the invention, these metals form dispersion layers in which the Microparticles or microcapsules are dispersed.

Because a direct deposition of the protective layer on a light metal substrate due to the electrical potentials is not possible in most cases an intermediate layer, usually made of zinc or a zinc alloy see. In the case of zinc or zinc alloy, the intermediate layer is by means of a zincate stain applied.

In addition, further layers can be provided, such as further intermediate layers layers between the substrate and the protective layer or cover layers z. B. as a further protective layer or for decorative purposes. According to one Another embodiment contains the layer system according to the invention as Top layer a decorative chrome layer.

The thickness of the protective layer according to the invention can be ge depending on the application to be selected and is usually between 3 µm and 50 µm.

The microcapsules are present in this protective layer in a concentration of above normal usually 5 to 50% by volume. If necessary, this preferred value can itself are understandably exceeded or not reached. However, the concentration is too low, the self-healing effect according to the invention can no longer be certain be put.  

The layer system according to the invention is illustrated in the accompanying figures illustrated by specific embodiments. Show it:

Fig. 1 shows an inventive system layer substrate with a magnesium;

FIG. 2a shows an inventive intact layer system with an aluminum miniumsubstrat; such as

FIG. 2b shows a layer system according to FIG. 2a with damage and a thin layer of released lacquer which has laid over the surface of the damage.

In Fig. 1, a layer system is shown with a magnesium substrate (1). An intermediate layer ( 2 ) is applied to the substrate, on which a nickel layer ( 3 ) with microcapsules ( 4 ) contained therein is deposited. As a top layer, this layer system contains a bright nickel layer ( 5 ) and a top layer made of bright chrome ( 6 ).

The mode of action of the present invention is shown in FIGS. 2a and 2b. The embodiment shown in FIGS. 2a and 2b also contains an intermediate layer ( 2 ), which has however been omitted in the illustration.

Fig. 2a shows an intact layer system having an aluminum substrate (1) and provided thereon a protective layer of nickel (3), the microcapsules (4) containing a drug. Cover layers made of bright nickel ( 5 ) and bright chrome ( 6 ) are provided as additional layers. In Fig. 2b, the layer system according to Fig. 2a shows a crack-shaped damage ( 7 ) which extends into the aluminum substrate ( 1 ) and makes the substrate accessible to external influences. The mechanical action that leads to the tear-shaped damage ( 7 ) destroys the microcapsules in the area of the damage and releases their liquid active ingredients. These liquid active ingredients can lie over the surface of the damage and form a layer there that prevents the entry of, for example, moisture and salt. In this way, the layer system according to the invention is quickly and effectively protected against corrosion in a simple manner.

Since the active ingredients are encapsulated in liquid form, they can be freely immediately settle over the damaged surface and take effect, without an upstream dissolving process, as required for solid particles which also presupposes the presence of sufficient liquid.

The corrosion-resistant light metal layer system according to the invention can advantageously for light metal components in the automotive industry or Sanitary industry can be used. It is particularly suitable for construction parts that are exposed to high mechanical stress, such as rims. It is Z. B. known that conventional aluminum rims by stone chips or unvor Visible touching of curbs quickly mechanical damage have that can corrode. With the layer system according to the invention can damage such areas quickly and reliably against corrosion be protected.

In the following, the invention will be further explained using exemplary embodiments vividly.

First example

A thin zinc layer ( 2 ) is applied to a substrate made of magnesium ( 1 ) using a zincate stain. Then a nickel dispersion layer ( 3 ) with a thickness of 20 µm is electroplated, in which there are microcapsules ( 4 ). A leveling bright nickel layer ( 5 ) with a thickness of 10 µm is applied, followed by a decorative bright chrome layer ( 6 ).

If the surface is mechanically damaged, the microcapsules ( 4 ) are destroyed and release their active ingredient. The released active ingredient protects the magnesium substrate ( 1 ) effectively against corrosion without further action, ie in a self-healing manner, by forming a protective layer that covers the damaged area.

Second example

A thin zinc layer ( 2 ) is applied to an aluminum rim using a zincate stain. A nickel dispersion layer is then electroplated on the visible side of the rim with a thickness of 20 µm, which contains microcapsules.

The microcapsules also contain an anti-corrosion varnish made from an alkyd resin long-chain unsaturated fatty acids that harden through air oxidation can. The viscosity of the paint is adjusted so that the paint adapts easily released on the surface.

A melamine-formaldehyde resin was used as the capsule shell. The capsules had a diameter of 5 µm and were in the layer in an amount of 10 wt .-% included.

A leveling shiny nickel layer was deposited on the nickel dispersion layer applied a thickness of 10 microns, followed by a decorative bright chrome layer.

As long as the applied coating system was intact, there was no corrosion of the Aluminum. If the layer system is damaged, the micro capsules destroyed, and the contents of the capsules, the anti-corrosion varnish, distributed over the damaged surface. This made both the layer and The aluminum is also protected against corrosion at this point, as it is neither damp the corrosion accelerating salt from the environment to the damaged surface.  

Reference list

1

Metal substrate

2nd

Intermediate layer

3rd

Protective layer

4th

Microcapsules

5

,

6

Top layer / top layers

7

damage

8th

Layer of active ingredient

Claims (16)

1. Corrosion-resistant light metal layer system, characterized in that the layer system contains a substrate made of a light metal ( 1 ), where a protective layer ( 3 ) is applied to at least one surface of the substrate ( 1 ), which contains microparticles ( 4 ) with a liquid active ingredient . 2. Layer system according to claim 1, characterized, that the light metal is selected from aluminum, magnesium, titanium so like their alloys. 3. Layer system according to claim 1 or 2, characterized in that the protective layer ( 3 ) is formed from a galvanically or electrolessly separable metal. 4. Layer system according to one of claims 1 to 3, characterized in that the protective layer ( 3 ) consists of a metal selected from nickel, copper or their alloys. 5. Layer system according to one of claims 1 to 4, characterized in that between the substrate ( 1 ) and the protective layer ( 3 ) at least one intermediate layer ( 2 ) is provided. 6. Layer system according to claim 5, characterized in that the at least one intermediate layer ( 2 ) is formed from zinc or a zinc alloy. 7. Layer system according to one of the preceding claims, characterized in that on the protective layer ( 3 ) at least one further layer ( 5 , 6 ) is brought up. 8. Layer system according to claim 7, characterized in that this is at least one cover layer ( 5 , 6 ) a bright nickel layer ( 5 ) and / or a bright chrome layer ( 6 ). 9. Layer system according to one of the preceding claims, characterized, that the liquid active ingredient is a lacquer or an inhibitor. 10. Layer system according to claim 9, characterized, that ver as an alkyd resin varnish with long-chain unsaturated fatty acids is applied, which is curable in air. 11. Layer system according to claim 9, characterized in that a two-component epoxy resin is used as the lacquer, and the two components are separate from one another in the microcapsules ( 4 ). 12. Layer system according to one of the preceding claims, characterized, that the shell of the microparticles is formed from a plastic material. 13. Layer system according to one of the preceding claims, characterized in that a melamine-formaldehyde resin is used as a shell for the microparticles ( 4 ). 14. Layer system according to one of the preceding claims, comprising a substrate made of a light metal ( 1 ) applied thereon, an intermediate layer made of zinc ( 2 ), a protective layer made of nickel ( 3 ) containing microparticles ( 4 ) with a liquid active substance, a first cover layer ( 5 ) made of bright nickel and a second cover layer ( 6 ) made of bright chrome in this order. 15. Use of a layer system according to one of the preceding An sayings in the automotive or sanitary industry. 16. Use of a layer system according to one of claims 1 to 14 with an aluminum substrate for the production of aluminum car rims.