WO2018192715A1 - Compositions containing primary aromatic amines for the corrosion-preventive pretreatment of metal parts - Google Patents

Abstract

The invention relates to a method for the corrosion-preventive pretreatment of metal parts comprising, on at least some of the surfaces thereof, a metal material predominantly consisting of one or more of the elements iron, zinc and/or aluminum; in said method, an acidic aqueous composition containing free fluroide and primary aromatic amines is used in the presence of a compound which is dissolved in water and is a source of nitrite ions.

Description

 Compositions containing primary aromatic amines for corrosion protection

 Pretreatment of metallic components

The present invention relates to a method for the corrosion-protective pretreatment of metallic components, which at least partially comprises surfaces of a metallic material consisting predominantly of one or more of iron, zinc and / or aluminum, using an acidic aqueous composition containing free fluoride and primary aromatic Amines in the presence of a compound dissolved in water, which is a source of nitrite ions.

The prior art discloses a multiplicity of pretreatment methods of components made of metals, in particular of aluminum, for imparting corrosion protection and as a paint primer based on acidic compositions. Usually, the aluminum surface is freed in a first step by the natural or caused by the manufacturing process oxide layer by pickling or pickling. The pickling not only involves the removal of the oxide layer, but typically includes pickling of the aluminum-made component itself to provide a homogeneous reproducible metallic surface for subsequent passivation. In the recent past, chromium (VI) -free compositions, as disclosed in WO2001 / 066827 A1, based on water-soluble inorganic compounds of the elements Zr, Ti and Cr (III), which undergo metal surface conversion, have become increasingly established in the art produce a coating a few nanometers thick, amorphous and at least temporarily protective against corrosion. However, these conversion layers represent a good paint adhesion base for further organic cover layers and in this way also improve the protection against corrosion of finished surface-treated components (so-called "permanent corrosion protection").

The self-deposition of organic coatings on metallic substrates using acidic aqueous binder dispersions in the presence of iron (III) ions and fluoride-containing is known for imparting a permanent corrosion protection and described for example in WO201 1/029680 A1. Such an autodeposition of an organic first coating followed by a reaction rinse, in which layer defects are cured, but has been able to prevail so far only for steel and or galvanized steel surfaces, since the high fluoride levels on aluminum surfaces cause a strong pickling reaction, the deposition of a prevents homogeneous organic Erstbeschichtung.

Also, given the variety of different pretreatment methods available in the art, there is still a need for alternative or improved methods to give metallic components, in particular made of aluminum components, a corrosion protection. However, it would be advantageous if, on the one hand, the separate pickling step before the actual treatment process could be dispensed with and an organic first coating takes place, which has good temporary corrosion protection and, moreover, represents a good primer for the application of further organic coating layers.

It is known that arylamines can be converted into diazonium ions in solution at low pH and in the presence of nitrite. For example, it is known from CN 102352501 A that these diazonium compounds can be attached to metallic surfaces in order to provide them with corrosion protection. However, it has not hitherto been possible to attach the diazonium ions directly to metals which have an oxide layer.

Furthermore, the stability of compositions is critical, which contain arylamine and nitrite at a low pH, since the formation of diazonium ions takes place spontaneously and in solution and there is a degradation to phenols with nitrogen elimination. The yield of diazonium ions which are deposited on the metal surfaces is usually low in such compositions and therefore in need of improvement.

Surprisingly, it has now been found that starting from a composition containing arylamines, free fluoride and a water-soluble compound, which is a source of nitrite ions, diazotized arylamines can be selectively deposited on the metallic surface of the components in a self-initiated process, without the Removal of the oxide layer is necessary and without the inside of the solution is already a degradation of the arylamines. Surprisingly, the attached diazotized arylamines couple with further diazonium ions present in the immediate interface with the metal surface and thus provide organic primary coatings with corrosion protection that is comparable or even improved over known processes.

The prerequisite for the formation of such an organic first coating which protects against corrosion and the conversion of the arylamines which takes place only selectively on the metal surfaces is the establishment of a concentration gradient for nitrite ions at the phase boundary to the metal surface. Therefore, the water-soluble compounds, which should fulfill their function of a source of nitrite ions, the condition that they contain at least one nitrogen atom in the oxidation state greater than + III and with nitrite ions as reduced species, a redox couple with a standard reduction potential E ° (Ox / Red) above zero volts (SHE).

In a first aspect, the present invention therefore relates to a method for corrosion-protective pretreatment of a component which at least partially surfaces of a metallic material, which consists predominantly of one or more of the elements aluminum, iron and zinc, by contacting the component with an aqueous treatment solution having a pH below 3 containing

a) at least 0.5 mmol / kg of an aromatic primary amine,

b) at least 1 mg / kg free fluoride, and

c) at least one compound dissolved in water as a source of nitrite ions, which has at least one nitrogen atom in the oxidation state greater than + III and with nitrite ions a redox couple with a standard reduction potential E ° (Ox / Red) above zero volts (SHE ).

The components treated according to the present invention can be any arbitrarily shaped and configured spatial structures originating from a fabrication process, in particular also semi-finished products such as strips, sheets, rods, tubes, etc., and composite structures joined together from the aforementioned semifinished products, wherein the semifinished products preferably by gluing, welding and / or flanging to the composite structure are connected together.

A metallic material consists predominantly of the elements iron, zinc and / or aluminum if the atomic proportion of these elements in the material as a whole is greater than 50 at.%.

The metallic material can also be a metallically coated substrate, insofar as the metallic coating has a layer thickness of at least 1 μm and more than 50 at.% Consists of the constituent elements defined above. Such materials are all plated iron materials such as electrolytically or hot dip galvanized steel, preferably platings in the form of zinc (Z), aluminum-silicon (AS), zinc-magnesium (ZM), zinc-aluminum (ZA), aluminum-zinc (AZ). or zinc-iron (ZF).

The oxidation state of an atom which is part of a compound is defined in the sense of the present invention as the hypothetical charge of the atom which would be present if only those bonding electrons were completely attributed to the atom shared with atoms having a lower electronegativity while bonding electrons shared with atoms of equal electronegativity would be attributed to the atom assuming homolytic bond separation, with general IUPAC oxidation state determination rules ("Oxidation State", IUPAC, Compendium of Chemical Terminology, Gold Book, Vol. Version 2.3.3, page 1049).

The standard reduction potential of a redox couple E ° (Ox / Red) is defined in the sense of the present invention as the electrochemical voltage between the electrochemical half cell containing the redox couple each with the thermodynamic activity of 1 at pH = 0 and the half cell of the standard hydrogen electrode (SHE) at one Temperature in the half cells of 25 ° C. By way of example, it should be mentioned at this point that redox couple is called nitrate / nitrite, which is linked to one another via the following electrochemical partial reaction, so that nitrates represent a suitable source of nitrite ions for the purposes of the present invention, since the nitrogen atom in the nitrate also has the oxidation state + V :

NO3 - + 3H ⁺ + 2e ^" -> HNO2 + H2O E ° (N0 ₃ / HN0 ₂ ) = + 0.94 V (SHE)

In the method according to the invention, it is achieved that the metal surfaces are freed from the oxide layer due to the production process in one process step and provided with a corrosion-resistant organic primary coating. In various embodiments, therefore, no previous step of removing the oxide layer, for example by means of pickling, is provided. Furthermore, the treatment solutions are stable and a degradation of the primary amines via a diazotization already taking place in the interior of the solution in the presence of nitrite ions does not occur. The diazotization takes place in a thin diffusion layer, within which the source of nitrite ions is oxidatively converted to nitrites, exclusively at the phase boundary of metal surface to the treatment solution, so that the addition of diazotized arylamines on the metal surface can be particularly effective. In further preferred embodiments, it is also possible to dispense with the use of an external current source or the application of an electrical voltage.

The source of nitrite ions to be used in the process according to the invention is preferably selected from nitric acid and its salts or organic compounds which have at least one nitro group bonded to a nitrogen atom.

Suitable representatives of the organic compounds having at least one nitro group bonded to a nitrogen atom are nitroguanidine, 1-methyl-3-nitroguanidine, 1-nitropyrazole, 2-nitroamino-2-imidazoline, diisopropylnitramine, propyl 2-oxohydrazinecarboxylate 2-oxide, ethyl 2-oxohydrazinecarboxylate 2-oxide, methyl (1-methyl-2-oxido-2-oxohydrazino) acetate, 3,3-

(Nitroazanediyl) dipropanoic acid and methyl 2- (1-methyl-2-oxido-2-oxohydrazino) ethylcarbamate.

The organic compounds having at least one nitro group bonded to a nitrogen atom and therefore constituting a source of nitrite ions in the first aspect of the present invention are further preferably selected from those in which the nitro group bonded nitrogen atom, the oxidation state -II or -I, particularly preferably the oxidation state -II having.

In a particularly preferred embodiment of the process according to the invention, the organic compound which is at least one nitro group bonded to a nitrogen atom selected from nitramines (RR ² N-NO ² with R and R ² , which independently of one another may be hydrogen or aliphatic branched, unbranched and / or bridging radicals), such as diisopropylnitramine or 3,3- (nitroazanediyl) dipropanoic acid, from nitroamides ( have the structural unit -C (= O) -NH-NO 2), such as ethyl 2-oxohydrazinecarboxylate-2-oxide, and / or from nitroimines (have the structural unit> C = N-NO 2), particularly preferably from nitroimines, again nitroimines of the following structural formula (I) are preferred,

wherein R2 is selected from R1 and / or -NH-R1; and each R1 independently of the other R1 radicals is selected from hydrogen, an aliphatic branched or unbranched alkyl radical having not more than 6 carbon atoms or a bridging alkylene radical bridging a heterocycle of from five to seven atoms comprising the nitrogen atom which is not covalent bound with the nitro group forms.

Preferred representatives of the nitroimines according to structural formula (I) are 2-nitroamino-2-imidazoline, nitroguanidine and / or 1-methyl-3-nitroguanidine, most preferably nitroguanidine and / or 1-methyl-3-nitroguanidine, wherein the nitroguanidines each have highest nitrite formation rates.

Treatment solutions in methods according to the invention are preferred for rapid attachment, in which the amount of compounds dissolved in water, which are a source of nitrite ions, in the treatment solution is at least 1 mmol / kg, preferably at least 2 mmol / kg, particularly preferred a total of at least 4 mmol / kg, but preferably not exceed a total of 10 mmol / kg for reasons of economy, insofar as nitric acid or its salts are excluded, since these can also be used to adjust the pH and therefore in a concentration of 10 may be contained in mmol / kg exceeding amount.

The aromatic primary amine of the aqueous treatment solution of the process according to the invention may be substituted or unsubstituted, preferably having only those further substituents directly covalently linking an atom selected from carbon, silicon, nitrogen, phosphorus, oxygen or sulfur with the aromatic nucleus these substituents are very particularly preferably selected from -R, -COOR ² , - (C =NR ² ) -N (R ² ) 2, - (C =O) -N (R ² ) ₂ , -CH = 0, - Si (OR ² ) ₃ , -N (R ² ) ₂ , -OR ² , -NO ² , -NR ² - (N = NR ² ) -N (R ² ) ₂ , - (SO 2) -, - (S0 ₂ ) -NR ² - (N = NR ² ) -N (R ² ) ₂ , -SO 3 R ² and - (P = O) - (OR ² ) ₂ , where R is an alkyl radical of less than 6 carbon atoms and R ^{2 is} hydrogen or R, and most preferably having a nucleus-substituted one carboxyl and / or sulfonyl group.

In a preferred embodiment of the invention, the aromatic amine as the active component of the aqueous treatment solution according to the first aspect of the present invention is thus a compound of the formula (I)

wherein R may be absent or replace one or more H atoms on the aromatic ring and wherein each R is independently selected from those substituents which directly covalently link an atom selected from carbon, silicon, nitrogen, phosphorus, oxygen or sulfur with the aromatic nucleus , where these substituents are preferably selected from -R, - COOR ^2, - (C = NR ²⁾ -N (R ²⁾ _2, - (C = 0) -N (R ²⁾ _2, -CH = 0, - Si (OR ² ) ₃ , -N (R ² ) ₂ , -OR ² , -NO ² , -NR ² - (N = NR ² ) - N (R ² ) ₂ , - (SO 2) -, - (S0 ₂ ) -NR ² - (N = NR ² ) -N (R ² ) ₂ , -SO 3 R ² and - (P = O) - (OR ² ) ₂ , where R is an alkyl radical of less than 6 carbon atoms and R ^{2 is} hydrogen or R is. The radicals R, if present, are preferably bonded in the para position relative to the amino group. Alternatively, two or more R together with the carbon atoms to which they are attached may also form a 5-8 membered (hetero) alicyclic or (hetero) aromatic ring, which in turn may be substituted with one or more Rs, which may in turn be further Can combine wrestling. As a result, as a core structure, for example, naphthalene, anthracene and phenanthrene rings can result. Particularly preferred is 4-aminobenzoic acid, sulfanilic acid and / or sulfaguanidine as the aromatic amine in the context of the present invention.

In the various embodiments of the process of the present invention, it is preferred that the molar ratio of aromatic primary amine groups to water-soluble compounds that is a source of nitrite ions in accordance with the first aspect of the invention is no greater than 5: 1, however, preferably greater than 1:10.

The aqueous treatment solution in the process according to the invention contains free fluoride. Accordingly, an aqueous processing solution according to the first aspect of the present invention contains a source of fluoride ions. The source of fluoride ions is any inorganic compound that is capable of being dissolved or dispersed in water to liberate fluoride ions. A preferred source of fluoride ions are complex or simple fluorides. The term "simple fluorides" is understood to mean hydrofluoric acid and its salts, such as alkali fluorides, ammonium fluoride or ammonium bifluoride, while complex fluorides are according to the invention Represent coordination compounds in which fluorides are coordinated as ligands of one or more central atoms. Preferred representatives of the complex fluorides are fluorine-containing complex compounds of the elements Zr, Ti or Si.

The proportion of free fluoride in an aqueous treatment solution in the method according to the invention is preferably at least 2 mg / kg, more preferably at least 4 mg / kg, but preferably not more than 100 mg / kg, more preferably not more than 40 mg / kg, especially preferably not more than 20 mg / kg in order to set a moderate pickling effect especially on surfaces of the material aluminum and thus to ensure a homogeneous organic primary coating. The free fluoride content can be determined by means of calibrated fluoride-sensitive electrode directly in the acidic aqueous treatment solution at 20 ° C.

In various embodiments of the process according to the invention, the aqueous treatment solution may contain water-soluble compounds of the elements Zr, Ti and / or Si, which during the addition phase of the diazonium ions and the further layer structure cause an inorganic conversion of the still wet-chemically accessible regions of the metal surfaces or additionally the object fulfill for components that consist of a mix of different metallic materials, on the surfaces on which comparatively slow accumulation of diazonium ions, yet to ensure adequate corrosion protection in a time window, in which on surfaces of another metallic material already a complete organic Erstbeschichtung is trained. The water-soluble compounds of the elements Zr, Ti and / or Si can be used, for example, as complex fluorides, as already described above. Accordingly, the aqueous treatment solution preferably contains a total of at least 5 mg / kg, more preferably at least 10 mg / kg, of water-soluble compounds of the elements Zr, Ti and / or Si calculated as the amount of Zr in the aqueous composition, but preferably not more than 500 in total mg / kg, more preferably not more than 200 mg / kg of water-soluble compounds of the elements Zr, Ti and / or Si calculated as the amount of Zr.

According to the invention, a compound of the elements Zr, Ti and / or Si is water-soluble if their solubility in water (κ = 1 μ8αττ ¹ ) at 60 ° C is at least 1 g / L calculated as dissolved in water amount of Zr.

For this purpose, for example, fluorometalates of the elements Zr, Ti and / or Si, preferably hexafluorozirconates, hexafluorotitanates and / or hexafluorosilicates, particularly preferably hexafluorozirconates and / or hexafluorotitanates, or their free acids can be added to the aqueous treatment solution. Suitable representatives of the water-soluble compounds of the elements Zr and / or Ti are, for example, compounds such as hhZrFe, IZFQ, Na2ZrF6 and (NH4) 2ZrF6 and the analogous titanium compounds.

Alternatively or additionally, however, fluorine-free compounds of the elements Si, Zr or Ti, in particular of the element Zr, can also be used as water-soluble compounds according to the invention, for example (NH 4) 2 Zr (OH) 2 (CO 3) 2 or TiO (SO 4).

In general, for optimum conversion of a metal surface, in particular those of the material iron, by contacting with an aqueous treatment solution, it is preferred that the molar ratio of total fluoride content to the total amount of the compounds of the elements Si, Zr or Ti based on the elements Zr, Ti and Si is greater than 4.5, preferably greater than 5.0, more preferably greater than 5.5. The total fluoride content can be determined with a fluoride-sensitive electrode in a TISAB-buffered aliquot of the acidic aqueous treatment solution at 20 ° C (TISAB: Total Lonic Strength Adjustment Buffer), where the volume-related mixing ratio of buffer to the aliquot of the acidic The TISAB buffer is prepared by dissolving 58 g of NaCl, 1 g of sodium citrate and 50 ml of glacial acetic acid in 500 ml of deionized water (κ <Ι μβαττ ¹ ) and setting a pH of 5.3 by means of 5 N NaOH and filling to a total volume of 1000 ml again with deionized water (κ <Ι μβαττ ¹ ).

In various preferred embodiments according to the first aspect of the present invention, the aqueous treatment solution has a pH below 2.5, more preferably below 2.0, but preferably above 1.0. In this case, the aqueous treatment solution may in particular be sulfur-acidic and / or nitric acid, i. Sulfuric acid and / or nitric acid but not more than 0.001 mol / L of another strong acid with pKsi value of less than 2 included.

For the method according to the invention, in particular, the treatment of such components has proved to be advantageous, which at least partially consist of metallic materials of the elements iron, zinc and / or aluminum, in particular aluminum. On the surfaces of these metallic materials, in particular those made of aluminum, a further improvement in the corrosion protection and the mediation of a corrosion-resistant paint adhesion base can be determined in comparison to the other metallic materials. A metallic material of the elements iron, zinc and / or aluminum is characterized in that its content of said metals is more than 50 at .-%. Preferred iron materials are steel, the steel comprising metallic materials whose mass fraction of iron is greater than that of any other element, and whose carbon content is less than 2.06 wt .-% without regard to carbides.

In the method according to the invention, metal components which at least partially have surfaces of such a material which predominantly consists of aluminum are particularly preferably treated.

In the processes according to the invention, in preferred embodiments, immediately after the component is brought into contact with the aqueous treatment solution-with or without intermediate rinsing and / or drying step-an at least partial coating of the areas of the component which have previously been carried out with the aqueous treatment solution were brought into contact, preferably a dip or powder coating. In various embodiments, the inventive method therefore comprise one or more rinsing and / or drying steps after bringing the component into contact with the aqueous treatment solution.

A "rinsing step" in the sense of the present invention denotes a process which is intended solely to remove as far as possible active components from an immediately preceding wet-chemical treatment step, which are dissolved in a wet film adhering to the component, by means of a rinsing solution from the surface of the component. Other active components are compounds dissolved in water, which are already consumed by the mere bringing into contact of the metallic surfaces of the component with the rinsing liquid, so that the rinsing liquid can only be city water.

A "drying step" in the context of the present invention refers to a process in which the surfaces of the metallic component having a wet film are to be dried with the aid of technical measures, for example supplying thermal energy or passing an air stream.

With the method according to the invention described, layers of at least 0.01 μm can be achieved within a normal treatment time of 30-180 seconds by immersion in the aqueous treatment solution.

The processes according to the invention can be carried out at temperatures of 20 to 60, preferably 30 to 50 ° C. The inventive methods described herein have the advantage of allowing the grafting of diazonium ions onto oxidized metal surfaces without the need to remove the oxides in a preceding step, ie in a single step, without the need for an external power source and without that a degradation of the active components of the immersion bath takes place. Furthermore, a homogenous organic primary coating is obtained even on complex structures and in cavities which are difficult to access in comparison to current-assisted deposition, insofar as the mere contact of the material surfaces with the aqueous treatment solution is ensured.

In a second aspect, the invention also relates to an aqueous chromium (VI) and phosphate-free composition having a pH below 3.0

a) 0.5-10 mmol / kg of an aromatic primary amine,

b) 2-100 mg / kg, preferably at least 4 mg / kg, but preferably less than 40 mg / kg, more preferably less than 20 mg / kg, free fluoride, and

c) 1 -10 mmol / kg of organic compounds which have at least one nitro group bonded to a nitrogen atom.

The aqueous composition according to the second aspect of the present invention is particularly suitable homogeneous coatings based on the aromatic primary amines on metallic surfaces of materials, which are predominantly formed of metals of the elements iron, zinc and / or aluminum, in particular the element aluminum, deposit.

All components of the aqueous treatment solution which are preferred and specified in connection with the process according to the invention also constitute preferred chromium (VI) and phosphate-free compositions according to the second aspect of the present invention. This also applies to preferred primary aromatic amines, particular sources of free fluoride and those preferred sources of nitrite ions containing at least one organic compound having at least one nitro group bonded to a nitrogen atom, as well as all in preferred embodiments of the present invention process according to the invention discussed additional components of the aqueous treatment solution, their total fluoride content, their pH and the type of predominantly used to adjust the pH acid.

According to the invention, a composition is "phosphate-free" if the proportion of phosphates dissolved in water is less than 100 mg / kg, preferably less than 20 mg / kg calculated as the amount of phosphorus. According to the invention, a composition is "chromium (VI) free" if the proportion of compounds of the element chromium dissolved in water in the oxidation state + VI is less than 100 mg / kg, preferably less than 20 mg / kg, particularly preferably less than 1 mg / kg is.

Examples

Degreased and cleaned aluminum alloy AA6014 sheets were treated with treatment solutions as listed in Table 1. All treatment solutions also contained 8 g / LH ₂ S0 ₄ and 1.39 g / LH ₂ TiF ₆ .

Infrared reflection absorption spectroscopy (IRRAS) was used to detect the attachment of diazotized arylamines to the aluminum surfaces. As IRRAS reference, a degreased and cleaned plate of the aluminum alloy AA6014 was used without further treatment. First, it appears that the diazotized aryl amines accumulate but, compared to an addition from a treatment solution that already contains nitrite ions, provides less layer coverage (Figure 1: CE1 vs E1). However, an addition from a nitrite-containing treatment solution after aging of the solution of 168 hours no longer takes place, this takes place without problems from a treated under the same conditions nitroguanidine-containing treatment solution (Figure 2: CE2 vs. E2).

Tab. 1

 Overview of the coating tests of aluminum sheets (AA6014)

 PH value; Treatment temperature 40 ° C; Treatment time 180 seconds

 after application of the treatment solution in hours until the time of coating, the treatment solution was stored at 40 ° C with the exclusion of light

Claims

claims

Anspruch [en] A method of anticorrosive pretreatment of a component having, at least in part, surfaces of a metallic material consisting predominantly of one or more of aluminum, iron and zinc by contacting the component with an aqueous treatment solution having a pH containing below 3

 a) at least 0.5 mmol / kg of an aromatic primary amine,

 b) at least 1 mg / kg free fluoride, and

 c) at least one compound dissolved in water as a source of nitrite ions which has at least one nitrogen atom in the oxidation state greater than + III and with nitrite ions a redox couple with a standard reduction potential E ° (Ox / Red) above zero volts (SHE ).

2. The method according to claim 1, characterized in that the dissolved in water compound, which is a source of nitrite ions, is selected from nitric acid and its salts or organic compounds having at least one nitrogen atom bonded to a nitro group ,

3. The method according to one or both of the preceding claims, characterized in that the amount of dissolved in water compounds, which are a source of nitrite ions, in the aqueous treatment solution in total at least 1 mmol / kg, preferably at least a total of 2 mmol / kg , particularly preferably at least 4 mmol / kg in total, but preferably does not exceed 10 mmol / kg in total, in so far as nitric acid or its salts are excluded.

4. The method according to one or more of the preceding claims, characterized in that the metallic component comprises at least partially surfaces of a material which consists predominantly of the metal aluminum.

5. The method according to one or more of the preceding claims, characterized in that immediately after contacting the component with the aqueous treatment solution - with or without intervening rinsing and / or drying step - at least partially painting the areas of the component takes place which have been previously contacted with the aqueous treatment solution, preferably a dip or powder coating.

6. Aqueous phosphate and chromium-free composition having a pH below 3 containing a total of 0.5-10 mmol / kg of one or more aromatic primary amines, 2-100 mg / kg of free fluoride, and

 1-10 mmol / kg of organic compounds dissolved in water which have at least one nitro group bonded to a nitrogen atom.

A method or composition according to any one of the preceding claims 2-6, characterized in that the dissolved in water organic compounds having at least one nitrogen atom bonded to a nitro group, a nitrogen atom bonded to the nitro group in the oxidation state -II or -I, particularly preferably in the oxidation state -II, and are preferably selected from nitramines, nitroamides and / or nitroimines, more preferably from nitroimines.

A method or composition according to claim 7, characterized in that the nitroimines satisfy the following general structural formula (I):

wherein R2 is selected from Ri and / or -NH-R1; and each Ri is independently selected from hydrogen, an aliphatic branched or unbranched alkyl group having not more than 6 carbon atoms, or a bridging alkylene group bridged to form a heterocycle of from five to seven atoms comprising the nitrogen atom which is not covalent is attached to the nitro group, and the nitroimines are preferably selected from 2-nitroamino-2-imidazoline, nitroguanidine and / or 1-methyl-3-nitroguanidine, more preferably from nitroguanidine and / or 1-methyl-3-nitroguanidine.

Process or composition according to one or more of the preceding claims, characterized in that the aromatic primary amine has only such further substituents which directly covalently link an atom selected from carbon, silicon, nitrogen, phosphorus, oxygen or sulfur with the aromatic nucleus, wherein these substituents are preferably selected from -R 1 -COOR ² , - (C =NH ² ) -N (R ² ) ₂ , - (C =O) -N (R ² ) ₂ , -CH =O, -Si (OR ² ) ₃ , -N (R ² ) ₂ , -OR ² , -NO ² , -NR ² - (N = NR ² ) -N (R ² ) ₂ , - (SO ² ) -, - (S 0 ₂ ) -NR ² - (N = NR ² ) -N (R ² ) ₂ , -SO 3 R ² and - (P = O) - (OR ² ) ₂ , wherein R is an alkyl radical of less than 6 carbon atoms and R ^{2 is} hydrogen or R is, and more preferably nuclear substituted, having a carboxyl and / or sulfonyl group.

10. A method or composition according to one or more of the preceding claims, characterized in that the amount of aromatic primary amines in the aqueous composition is at least 1 mmol / kg, preferably at least 2 mmol / kg, more preferably at least 4 mmol / kg, however, preferably does not exceed 10 mmol / kg.

1 1. A method or composition according to one or more of the preceding claims, characterized in that the proportion of free fluoride in the aqueous composition is at least 2 mg / kg, preferably at least 4 mg / kg, but preferably 100 mg / kg, especially preferably does not exceed 40 mg / kg, more preferably 20 mg / kg.

12. A method or composition according to one or more of the preceding claims, characterized in that the aqueous composition additionally contains water-soluble compounds of the elements Zr, Ti and / or Si.

13. The method according to claim 12, characterized in that the aqueous composition contains a total of at least 5 mg / kg, preferably at least 10 mg / kg of water-soluble compounds of the elements Zr, Ti and / or Si calculated as amount Zr in the aqueous composition, however, preferably not more than 500 mg / kg in total, more preferably not more than 200 mg / kg of water-soluble compounds of the elements Zr, Ti and / or Si calculated as the amount of Zr.

14. A method or composition according to one or more of the preceding claims, characterized in that the aqueous composition has a pH below 2.5, more preferably below 2.0, but preferably above 1.0.

15. A method or composition according to one or more of the preceding claims, characterized in that the aqueous composition is sulfur and / or nitric acid.