WO2011020556A2 - Aluminium or aluminium alloy formed part and/or structural part and method for protecting the surface thereof - Google Patents

Abstract

The invention relates to an aluminium or aluminium alloy (4) formed part and/or structural part (1) comprising an anti-corrosion layer (2) formed from a sol-gel system. The invention also relates to an anti-corrosion layer (2) which is applied directly to the aluminium or the aluminium alloy (4) and can be produced by integrated hardening or drying during an optimised process sequence, that is, a shortened process sequence.

Description

 Shaped and / or structural part made of aluminum

 or an aluminum alloy and process for its surface protection

The invention relates to a shaped and / or structured part made of aluminum or an aluminum alloy according to the preamble of claim 1 and a method for producing such a molded and / or structural part according to the preamble of claim 7.

Such structural and structural parts are manufactured using manufacturing processes or combinations of different manufacturing processes according to DIN 8580. These include, in particular, methods of the main groups altering primary forms, forming, separating and material properties. By combining different moldings such manufactured parts can also be connected to each other by assemblies of the main group joining to assemblies or structures. On the basis of intended for load-bearing forgings, which represent a significant product group within the invention relating to the form and structural parts, the prior art and the problem and its solution according to the invention is shown.

Forging particular forgings (forged moldings) made of aluminum and its alloys are known. For the production of such, usually safety-related forgings blanks (forging stock), for example cast, rolled or extruded blanks, in bars, as rods, bar sections, billets or slabs of aluminum or aluminum alloy in a die via one or more forming stages processed forging. Forming stages include preforming such as upsetting, bending, stretching, stretch and cross wedge rolling, pre-forging, finish forging, post-forming and calibrating. The actual forging process can be followed by metal and alloy-specific heat treatments, in particular in order to achieve the technological state (for example T4, T5, T6 or T73) in accordance with DIN EN 515. About that In addition, it is known to subject the forgings to a surface treatment such as pickling or blasting.

Known, claimable on load forgings have various disadvantages in terms of their susceptibility to corrosion. They may be exposed to improper storage, transport or use in adverse, especially humid or pollutant, environment, corrosion attacks, u.a. lead to optical, dimensional and / or mechanical quality losses on the component surface. Forgings which, in addition, are operatively corrosive media, e.g. Salt solutions, brake dust or the like are exposed to an intensified and accelerated corrosion attack. The nature of the corrosion attack, for example stress corrosion cracking, intergranular corrosion or layer corrosion is dependent on the alloy and its technological state and on the type and concentration of the corrosion-causing media and the prevailing process parameters, such as temperature. Conventionally manufactured forgings, which are not used primarily for decorative purposes are usually not or only slightly, for example by surface blasting, protected against a corrosion attack described above. Previously known coating processes are characterized by comparatively greater layer thicknesses, poorer environmental compatibility, significantly extended process chains and / or increased investment costs and are consequently hardly used in load-bearing aluminum forgings.

It is known in the technical field of reflector body production (not intended for load bearing), as is apparent from EP 1 287 389 B1, to coat reflector bodies formed from aluminum with a sol-gel lacquer, the sol-gel lacquer not being is applied directly to the aluminum, but on a provided on this reflection layer.

The invention is based on the object, a cost-effective and easy to manufacture weatherproof and corrosion-protected, with a Specify against mechanical influences sufficiently resistant surface protection provided molding and / or structural part of aluminum or an aluminum alloy and a method for its preparation. Preferably, the part should be characterized by a very good surface finish, homogeneous topography and low roughness. In particular, the appearance should be visually appealing even after long-term use, especially under harsher environmental conditions. Moreover, it is preferred if the molded and / or structural parts are distinguished by good mechanical properties and equally good machinability. Furthermore, it would be advantageous if the shaped and / or structural parts could be tested with the same non-destructive test methods as are used in conventionally produced molded and / or structural parts.

This object is achieved in terms of the forging with the features of claim 1 and in terms of the manufacturing method with the features of claim 7.

Advantageous developments of the invention are specified in the subclaims. All combinations of at least two features disclosed in the description, the claims and / or the figures fall within the scope of the invention. In order to avoid repetition, features disclosed according to the method should be regarded as disclosed in accordance with the device and should be able to be claimed. Likewise, devices disclosed according to the device should be regarded as disclosed according to the method and be able to be claimed.

The invention is based on the idea to provide the mold and / or structural part with a corrosion protection layer, which is made of a sol-gel system, ie created, wherein the corrosion protection layer is realized directly on the aluminum or aluminum alloy. In other words, any intermediate layer between the anticorrosion layer and the aluminum or the aluminum alloy is dispensed with. The invention is based on the finding that the corrosion layer in such components surprisingly without a considered necessary in the prior art Intermediate layer (there reflection layer) firmly adheres directly to the aluminum or aluminum alloy. Thus, the application of an intermediate layer, for example a reflection layer, as in the case of known reflection aluminum parts, for example by means of pre-anodizing, chromating or phosphating, can be dispensed with for improved adhesion of the cover layer. As a result, the process chain (transport of parts, logistics, quality assurance) can be reduced to a minimum. Likewise, the absence of an intermediate layer leads to low material and energy costs.

The corrosion layer realized directly on the aluminum or the aluminum alloy is a sol-gel lacquer which has developed from a sol-gel system applied directly to the aluminum or the aluminum alloy. Gels are dimensionally stable, easily deformable, fluid-rich disperse systems consisting of a solid, irregular, three-dimensional network and a liquid. A sol-gel system is to be understood as a sol-gel lacquer prepared by sol-gel technology which, after product-appropriate application and curing, has a substrate, in this case a molded or structural part, firmly bonded to the substrate, hardened, protective layer forms. The protective layer is preferably a transparent curing sol-gel lacquer, which reveals the color tone of the metallic substrate. By transparent hardening sol-gel lacquer is to be understood in particular a clear, colorless, transparent protective layer. The protective layer applied to the cleaned surface of the substrate is preferably a sol-gel lacquer, in particular a sol-gel lacquer of a polysiloxane and advantageously a sol-gel lacquer of one of an alcoholic silane solution, in particular an alkoxysilane Solution and an aqueous colloidal silica solution prepared polysiloxane. Polysiloxane is the term for polymers of crosslinked siloxanes. The polysiloxane is produced in particular by a condensation reaction between hydrolyzed and crosslinkable silanes, in particular alkoxysilanes, and colloidal silicic acid. The condensation reaction between hydrolyzed silanes, in particular alkoxysilanes, with one another and hydrolyzed silanes, in particular alkoxysilanes, and colloidal silicic acid results in the formation of an inorganic network of polysiloxanes. At the same time, organic groups, in particular alkyl groups or simple alkyl groups, are incorporated into the inorganic network via carbon bonds. However, the organic groups, or the alkyl groups, do not participate directly in the polymerization or the crosslinking of the siloxanes, ie they do not serve to form an organic polymer system but merely for functionalization. The function is that the organic groups, in particular the alkyl groups, are attached to the outsides of the polysiloxanes during the sol-gel process and thereby form an outwardly water-repellent layer, which gives the sol-gel coating a pronounced hydrophobic property.

The sol-gel process described leads, as mentioned, by targeted hydrolysis and condensation of alkoxides of silicon and silica to a sol-gel lacquer of an inorganic network with incorporated alkyl groups. The polysiloxanes obtained thereby are more likely to be assigned to the inorganic polymers.

In the preparation of a preferred embodiment of a sol-gel lacquer as a protective layer, it is expedient to use two base solutions A and B.

The solution A is an alcoholic solution of one or more different alkoxysilanes, wherein the alkoxysilanes are present in an anhydrous medium in non-hydrolyzed form. As the solvent, an alcohol such as methyl, ethyl, propyl or butyl alcohol and preferably isopropyl alcohol is suitably used.

The alkoxysilanes are described by the general formula X _n Si (OR) _4-H in which "R" is a simple alkyl, preferably from the group comprising Methyl, ethyl, propyl and butyl "X" is suitably likewise an alkyl, preferably from the group comprising methyl, ethyl, propyl and butyl Suitable alkoxysilanes are, for example, tetramethoxysilanes (TMOS) and preferably tetraethoxysilane (TEOS) and methyltrimethoxysilane (MTMOS) and further alkoxysilanes.

In a particularly preferred embodiment, the solution A is prepared from tetraethoxysilane (TEOS) and / or methyltrimethoxysilane (MTMOS) with a methyl, ethyl or propyl alcohol and in particular with an isopropyl alcohol as solvent. The solution A may e.g. 25-35 wt.% (Wt.%), In particular 30 wt.%, TEOS and 15-25 wt.%, In particular 20 wt.%, Containing MTMOS, both dissolved in 40-60 wt. , in particular 50% by weight, isopropyl alcohol.

Solution B contains colloidal silica dissolved in water. In an expedient embodiment, the solution B is adjusted by means of acid, preferably by means of nitric acid (HNO ₃ ), to a pH of between 2.0 and 4, preferably between 2.5 and 3.0 and in particular of 2.7.

The silicic acid used is expediently a silicic acid stabilized in an acidic medium, the pH of the silicic acid advantageously being 2 -4. The silicic acid is advantageously as low in alkali as possible. The alkali content (eg Na ₂ O) of the silica is preferably below 0.04% by weight.

The solution B contains, for example, 70-80% by weight, in particular 75% by weight, of water as solvent and 20-30% by weight, in particular 25% by weight, of colloidal silica. The solution B is expediently adjusted by means of nitric acid (HNO ₃ ) to a pH of between 2.0-3.5, preferably between 2.5-3.0 and in particular of 2.7.

The combining and mixing of the two base solutions A and B in the presence of nitric acid leads to a hydrolysis reaction between the water contained in solution B and the alkoxysilanes contained in solution A. Hydrolysis reaction: Si (OR) _n + nH ₂ O → Si (OH) _n + nR (OH)

At the same time, a condensation reaction occurs in which, with the elimination of water, a siloxane bond (Si-O-Si) is built up from two Si-OH groups in each case. Progressive polymerization results in a network of polysiloxanes to which alkyl groups are attached. The new mixed solution is in a gel state.

 The two solutions A and B are preferably mixed in a weight ratio of 7: 3 parts.

The sol-gel lacquer is expediently applied or deposited in gel form onto the mold or structural part, or onto the corresponding surface, and then dried or cured. The drying process consists in expelling the water and alcohols remaining in the sol-gel lacquer, whereby the sol-gel lacquer cures and a corrosion-resistant and weather-resistant protective layer is formed on the molded part or structural part surface.

The coating is carried out, for example, by applying, spinning or spraying, expediently in a continuous process, which is suitable for the treatment of mold or structural parts described above, even in very large quantities (large series). Particularly preferred coating methods are spraying, spraying, dipping or dip coating.

In particular, sol-gel systems which are available, for example, under the trade name CERAPAINT of the company Akzo Nobel are suitable for the formation of the corrosion protection layer.

Corrosion protection layers (sol-gel coatings), which are created by applying a SoI-GeI system, ie the coating of the actual mold and / or structural part with a sol-gel system, require for their production a curing or drying process in which the sol-gel system is converted into the durable sol-gel varnish.

The mold or structural part coated with the sol-gel lacquer is expediently obtained by means of radiation, such as UV radiation, electron radiation, laser radiation, or by thermal radiation, such as IR radiation (infrared), or by convection heating or a combination of the aforementioned Drying or hardening process, dried or hardened.

The convection heating can be carried out expediently by exposure to heated gases, such as air, nitrogen, noble gases or mixtures thereof. The sol-gel lacquer layer is preferably dried or hardened in a continuous oven.

However, it is particularly preferred if, however, in the production process for producing the molded and / or structural part, such an additional curing or drying process is dispensed with and instead this curing or drying process is part of an already realized process step, for example a heat treatment to optimize the Component properties is realized. In other words, it is preferable to harden the sol-gel system by a heat treatment step provided for optimizing the component properties, so that a separate (additional) curing step can be dispensed with. If such a heat treatment, as is useful in particular for forgings intended or designed for load bearing, is not realized, a corresponding hardening step must be integrated into the production process. The application of the sol-gel system can be integrated in particular in the formation of the molded and / or structural part as for load-bearing forging in an existing production environment inline or as a bypass process stage with little effort.

The molded and structural parts formed according to the concept of the invention may consist of pure aluminum or an aluminum alloy. Prefers The forgings contain aluminum alloys of the material groups 2xxx, 6xxx or 7xxx or consist of these. For cast structural and / or structural parts, preference is given to aluminum alloys of the type AISiMg, AISiCu, Al-Cu and AIZnMg. For wrought alloys of the 2xxx material group, the alloys AA 2014, AA 2014A, AA 2017A, AA 2024 and 2618A are preferably used; in the wrought alloys of material group 7xxx, the alloys AA 7003, AA 7018, AA 7020, AA 7022 and AA 7075 are preferred Use, particularly preferably AA 7075. For wrought alloys of the material group 6xxx are preferably the alloys AA 6005, AA 6005A, AA 6008, AA 6014, AA 6060, AA 6061, AA 6063, AA 6063A, AA 6056, AA 6066, AA 6110, AA 6110A, AA 6182, AA 6401 and AA 6463 are used, particularly preferably the alloys AA 6060, AA 6063 and AA 6082 and AA 6110, in particular AA 6082. In addition, molded and structural parts according to the invention can also be made from magnesium and magnesium casting and kneading alloys be.

The molded and / or structural parts according to the invention with a corrosion protection layer which have emerged from a sol-gel system are distinguished by a smooth, extremely thin, homogeneous, decorative and transparent protective layer which satisfies the static and dynamic requirement profile of high-quality forgings becomes. Such coated parts that are subjected to static loading in a corrosive environment have a flawless surface appearance even after long term exposure. The molded or structural parts according to the invention show no signs of corrosion after 1000 hours salt spray test (test DIN 50021 -SS) according to DIN 50021. In addition, the Formbzw invention. Structural parts under these conditions no Filiformkorrosion in the sense of DIN EN ISO 3665 on. Coated shaped and / or structural parts, in particular forgings, which are subjected to dynamic-corrosive stress, allow higher numbers of cycles than uncoated molded and / or structural parts due to a delayed corrosion attack. In addition, the coated according to the concept of the invention mold and structural parts, in particular due to the small thickness of the corrosion protection layer and the sufficiently plastic material behavior and the consistency of the molded and / or structural parts, in particular corrosion protection layer, as well as non-coated molding and / or structural parts, in particular forgings of a non-destructive component test, for example, measurement of the conductivity or the Brinellhärte be subjected. In mechanical finishing or destructive static or dynamic component testing, the fracture surface of the surface coating is congruent with the fracture surface of the base material; This means that there are no protruding or released particles or splinters, which could cause a risk of injury if touched. Due to the congruence of the fracture surfaces and the excellent adhesion of the corrosion protection layer, migration of liquid media is also prevented, whereby the risk of filiform corrosion, which is known from various other coating systems, can be avoided. Consequently, in the event of partial destruction of the coating, the forming and structural member does not undergo progressive damage along the boundary layer due to liquid spreading and resulting corrosion attacks. The molded and / or structural parts with a corrosion coating formed according to the concept of the invention can thus be machined even after a surface finish with high dimensional accuracy. The coated forged parts described above can be excellently machined, have very good, ie very high, static mechanical and dynamic mechanical characteristics and have a high degree of environmental compatibility.

The structural design of the formed according to the concept of the invention mold and / or structural parts can be made according to customer requirements, especially those of the automotive industry. A significant advantage of the parts, in particular the forgings intended for load bearing, is that constructive safety margins and load-bearing cross-sections can be reduced in comparison to forged parts according to the prior art, since the occurrence of corrosion phenomena is at least considerably delayed.

In summary, the following advantages can be achieved in the case of a molded part and / or structural part designed according to the concept of the invention or by the use of the sol-gel coating method according to the invention:

A very high resistance to corrosion and corrosion fatigue,

• a good protection against weather influences,

A negligible weight increase due to extremely thin corrosion protection coatings,

A very good layer adhesion of the sol-gel system to aluminum materials,

A very good temperature resistance of the corrosion protection coating,

• a very high dimensional accuracy,

• very homogeneous, decorative surface properties,

• very good, i. high, static-mechanical characteristics,

A very high ductility and high energy absorption properties,

• a very high dynamic load capacity,

High resistance to crack initiation, High scratch resistance and high resistance to mechanical degradation and abrasion,

• a very good, uniform machinability,

• excellent, homogeneous structural properties,

• a high UV radiation resistance.

• Environmentally friendly, melt-technological recyclability without prior chemical and / or mechanical removal of the protective layer.

In a further development of the invention, it is advantageously provided that the molded and / or structural parts are forgings, even more preferably forged (supporting) forgings. In other words, the forgings are designed for load-bearing, i. in the installed state (load-) bearing. The forgings (load-bearing parts) intended for receiving loads are preferably drop-forged parts. As will be explained later, the forged parts in question for load bearing are supporting and / or heavily stressed parts in vehicles, in particular motor vehicles. Alternatively, the shaped and / or structured part is, for example, a cast part, a pressed part, an extrusion part or a part produced by forming a sheet metal.

Forging intended certain forgings are preferably made of hardenable aluminum alloys and provided for the purpose of their use determination with a strength-increasing heat treatment. In this case, the component is depending on the material at temperatures of 46o C ⁰ - quenched 550 ° C in the annealed condition, for example with air or water, and subsequently at temperatures of 80 ⁰ C - 200 ⁰ C artificially aged. A typical example are forgings in the material EN AW-6082, which are Condition T5 or T6 or T64 often has a minimum tensile _strength R _m > 340 MPa, a minimum _{yield strength} R _p0 , ₂ ≥310 MPa and a minimum bronchial hardness HBW _{2.5 / 62} , ₅ ≥100 with a minimum elongation at break A ₅ ≥10% must have.

Sol-gel systems which are distinguished by at least one of the following parameters and / or substances are particularly suitable for the preparation of the anticorrosion layer (sol-gel lacquer): An aqueous colloidal silica which, in an appropriate combination with an alcoholic silane solution, in particular an alkoxysilane solution by hydrolysis, condensation and drying leads to the formation of a sol-gel lacquer of crosslinked polysiloxanes.

Particular preference is given to sol-gel systems which are obtainable, for example, under the trade name CERAPAINT from Akzo Nobel. The abovementioned sol-gel systems and the anticorrosive layers produced therefrom are distinguished by a chemical composition which permits immediate melt-technological recycling of the coated forgings, without it being necessary to remove the corrosion protection layer chemically or mechanically. It can therefore be avoided additional environmental measures before recycling. All of the aforementioned sol-gel types are non-toxic, odorless and non-corrosive and thus processable without increased safety and protective measures.

It is very particularly preferred if, as already mentioned, the corrosion protection layer has an extremely small thickness. The thickness is preferably less than 10 μm, more preferably less than 5 μm, in particular 2 μm to 4 μm. Preferably, a minimum thickness of 0.5 microns is not exceeded. Among other advantages, a small thickness of the corrosion protection layer leads to a minimized weight gain. Thus, an increased lightweight construction potential is offered compared to conventional coating systems. In a development of the invention, it is advantageously provided that the structural and / or structural part is a motor vehicle component, very particularly preferably a safety-related, ie load-bearing, and / or force-absorbing, motor vehicle component, in particular a bumper, a side impact beam or to a component of the chassis of the motor vehicle, such as a trailing arm, semi-trailing arm, support arm or wishbone. It is also possible to form the forging as part of a wheel or engine mount of a motor vehicle. Other applications are also conceivable. Thus, the form and / or structural part, for example, as a link, expediently be designed as a hinge or fitting. Alternatively, training as a hydraulic component or as a fitting or seat attachment can be realized. Likewise, the molded and / or structural part can be formed as a decorative automotive component, in particular for the vehicle interior. The realization of the molded and / or structural part is also possible as an exterior automotive component, for example as exterior mirror housing, door handle or roof railing.

It is particularly expedient to design the molded and / or structural part, in particular the forging, as a load-bearing part for applications in the construction industry. In addition, an anti-corrosion forged load-bearing forging is suitable for offshore applications where very harsh environmental conditions prevail. The forgings can also be used, in particular as load-bearing parts, in aviation, the electrical industry or the transport industry.

As already indicated, the invention also leads to a method for producing a shaped and / or structured part, in particular a forged part, which is characterized by a corrosion protection layer (sol-gel lacquer) which consists of a sol-gel System emerged. The core of the method is to wet or coat the component, preferably forged, in particular drop-forged, made of aluminum or an aluminum alloy with a sol-gel system from which the corrosion protection layer is then formed, if necessary by means of a the coating process downstream curing or drying and / or heat treatment process.

The process can be integrated inline or as a bypass process stage with little effort into an existing production line.

It is particularly preferable to harden the sol-gel system for forming the corrosion layer by a heat treatment. It is particularly preferred if the accelerated curing takes place combinatorially with the heat treatment used for forgings in the hot-outsided state. The increased temperature door for combinatorial drying or curing of the sol-gel coating and the material-specific thermal treatment is advantageously greater than 80 ⁰ C, preferably greater than 115 ° C and in particular greater than 140 ⁰ C. The elevated temperature is also advantageous less than 360 ⁰ C, preferably less than 250 ° C and in particular less than 210 ⁰ C. The elevated temperature is more preferably between 150 ° C and 200 ⁰ C.

Advantageously, the application of the sol-gel lacquer before or during the heat aging, so that can be dispensed with a separate curing step.

With regard to the coating methods for applying the SoI-GeI system to the aluminum or aluminum alloy component, which may have a smooth, blasted or structured surface, there are various possibilities, for example painting. Spraying, spraying and / or immersion or immersion drawing processes are preferred here.

It is particularly expedient if the expediently degreased or pickled and subsequently rinsed or cleaned component made of aluminum or an aluminum alloy before and / or after the application and / or curing of the sol-gel system is post-processed, for example by means of a cutting separation process with geometric indeterminate or particular cutting or a non-cutting separation process in which no formless substance in the Result of chips is obtained (eg shearing, fine blanking). Also, a post-processing by thermal, chemical and / or electro-chemical removal methods, for example, in the sense of DIN standard 8580, possible. In particular, the anti-corrosive layer made of a sol-gel system allows the processing after the formation of the corrosion protection layer, ie after curing of the sol-gel system, since the corrosion protection layer due to the arrangement directly on the aluminum or the aluminum alloy does not flake off in the Processing tends and insofar as the non-directly processed areas remain optimally protected against corrosion attacks.

The invention also leads to the use of a sol-gel system, in particular of sol-gel lacquer of a polysiloxane and advantageously a sol-gel lacquer of one of an alcoholic silane solution, in particular an alkoxysilane solution and a polysiloxane prepared to aqueous colloidal silica solution to form a corrosion protection layer, preferably with a decorative appearance, on a forged component made of aluminum or an aluminum alloy.

Preferably, a post-processed or destructively tested component has no filiform corrosion due to the good layer adhesion and the congruence of the separating surfaces of the coating and the base material.

More preferably, a post-processed or destructively tested component due to the good layer adhesion and the congruence of the separation surfaces of the coating and the base material no risk of injury (such as by scharkantige particles or edge overhang) on.

Most preferably, a molded and / or structural part produced by means of the method according to the invention is characterized by a chemical composition of the anticorrosive coating, which is a direct melting-technological recycling of the coated molded or structural parts allows, without prior chemical and / or mechanical removal of the corrosion protection layer.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawings.

These show in:

1 is a schematic representation of a trained as a support arm forgings for a motor vehicle,

2 shows a schematic representation of a forged as a control arm for a motor vehicle,

3 shows the forging part according to FIG. 1 in a sectional view, FIG.

Fig. 4: the forging of FIG. 2 in a sectional view, and

5 shows a schematic representation of an enlarged detail from FIGS. 3 and 4, from which it can be seen that the corrosion protection layer without intermediate layer is applied directly on the aluminum alloy of the molded and / or structural part.

In the figures, like elements and elements having the same function are denoted by the same reference numerals.

Fig. 1 shows a schematic representation of a designed as a support arm of a motor vehicle, designed for load receiving mold and / or structural part 1, here a forging. 3 shows a sectional view of this forging 1. In Fig. 2 exemplified as a wishbone shaped and / or structural part 1 is shown for a motor vehicle, in Fig. 4, the associated sectional view is reproduced.

Fig. 5 shows a detail from the sectional views according to Figs. 3 and 4 of the forging 1. It can be seen that the mold and / or structural part 1 comprises a body 3 made of an aluminum alloy 4, the aluminum alloy 4 being directly, i. without providing an intermediate layer is provided with a corrosion protection layer 2 having a thickness of about 2 microns.

The anticorrosive layer 2 results from a sol-gel system, which was preferably applied by spraying, spraying, dipping or immersion of the forged component on this. Hardened, i. is converted into the corrosion protection layer 2, the sol-gel system by a heat treatment of the molded and / or structural part 1, here the forging, which simultaneously leads to an optimization of the mechanical characteristics, such as the strength of the component. An additional curing step can thus be dispensed with with advantage.

Claims

claims

1. Form and / or structural part made of aluminum or an aluminum alloy (4) with a resulting from a sol-gel system corrosion protection layer (2), characterized in that the corrosion layer (2) directly on the aluminum or the aluminum alloy (4 ) is arranged.

2. Part according to claim 1,

 characterized,

 in that the shaped and / or structured part (1) is a forged part, or a cast part, or a pressing part, or an extrusion part, or a sheet metal part or an assembly made of such parts.

3. Part according to one of claims 1 or 2,

 characterized,

 in that the sol-gel system comprises an aqueous colloidal silica which, in suitable combination with an alcoholic silane solution, in particular an alkoxysilane solution, leads to the formation of a sol-gel lacquer of crosslinked polysiloxanes by hydrolysis, condensation and drying.

4. Part according to one of the preceding claims,

 characterized,

 the corrosion protection layer is arranged directly on the aluminum or aluminum alloy (4).

5. Part according to one of the preceding claims,

characterized, the anticorrosive layer (2) has a thickness from a thickness range between about 0.5 μm and about 10 μm, preferably between about 1 μm and 5 μm, preferably between about 2.0 μm and about 4 μm.

6. Part according to one of the preceding claims,

 characterized,

 that the part (1) is a preferably safety-relevant motor vehicle component, in particular a chassis part, preferably a trailing arm, a trailing arm, a support arm or wishbone, or is part of a suspension or the engine mount, or part of the body, in particular bumper or side impact or that Part (1) is a link, in particular a hinge part or a fitting part, or that the part (1) is a hydraulic component, or that the part (1) is a fitting or seat attachment part, or that the part (1) is a decorative automotive component , in particular for the vehicle interior, for example a switch panel, an operating element, a ventilation nozzle, a seat fitting, a dashboard, a door trim, a shift knob, an instrument enclosure or a handle, or that the part of an automobile component on the exterior, preferably a mirrors housing, a Türgr iff or a roof railing is.

7. Part according to one of the preceding claims,

 characterized,

 the part (1) is a load-carrying part for motor vehicle applications, or for building applications, or for offshore applications or for aviation applications or for electrical industrial applications or for transport applications.

8. A method for producing a molded and / or structural part (1) according to one of the preceding claims, wherein first a component made of aluminum or an aluminum alloy (4) is produced, characterized in that a sol-gel system is applied directly to the aluminum or the aluminum alloy (4) and converted into a corrosion protection layer.

9. The method according to claim 8,

 characterized,

 that the component is formed from a blank by manufacturing processes in accordance with DIN 8580 et seq., preferably by forging, in particular drop forging.

10. The method according to any one of claims 8 or 9,

 characterized,

 that the sol-gel system is hardened to form the anticorrosion layer (2).

11. The method according to claim 10,

 characterized,

that is carried out the curing of the sol-gel system by the heat treatment of the preferably forged component to optimize the device characteristics, in particular the properties of the microstructure in the artificially aged state, preferably at a temperature between about 150 ^c C and about 200 ⁰ C.

12. The method according to any one of claims 8 to 11,

 characterized,

 that the sol-gel system is applied by spraying, spraying, dipping or dipping the component or a combination of at least two of the aforementioned methods.

13. The method according to any one of claims 8 to 12,

characterized, that the component is post-processed before and / or after the application and / or hardening of the sol-gel system, in particular by means of a metal-cutting or non-cutting, separation process and / or by thermal, chemical and / or electrochemical removal processes.

14. The method according to any one of claims 8 to 13,

 characterized,

 that the component is surface-treated prior to the application of the sol-gel system, in particular by pickling or blasting.

15. Use of a sol-gel system for forming a corrosion protection layer (2) directly on a, in particular forged, component made of aluminum or an aluminum alloy (4).

16. Use of a molded and / or structural part (1) according to one of claims 1 to 7 for load-bearing, in particular in a motor vehicle, a rail vehicle, an aircraft and / or a watercraft.